TSTP Solution File: NUM706^4 by cocATP---0.2.0
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- Process Solution
%------------------------------------------------------------------------------
% File : cocATP---0.2.0
% Problem : NUM706^4 : TPTP v7.1.0. Released v7.1.0.
% Transfm : none
% Format : tptp:raw
% Command : python CASC.py /export/starexec/sandbox2/benchmark/theBenchmark.p
% Computer : n050.star.cs.uiowa.edu
% Model : x86_64 x86_64
% CPU : Intel(R) Xeon(R) CPU E5-2609 0 2.40GHz
% Memory : 32218.625MB
% OS : Linux 3.10.0-693.2.2.el7.x86_64
% CPULimit : 300s
% DateTime : Mon Jan 8 13:11:31 EST 2018
% Result : Unknown 208.63s
% Output : None
% Verified :
% SZS Type : None (Parsing solution fails)
% Syntax : Number of formulae : 0
% Comments :
%------------------------------------------------------------------------------
%----No solution output by system
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% 0.00/0.03 % Problem : NUM706^4 : TPTP v7.1.0. Released v7.1.0.
% 0.00/0.04 % Command : python CASC.py /export/starexec/sandbox2/benchmark/theBenchmark.p
% 0.02/0.23 % Computer : n050.star.cs.uiowa.edu
% 0.02/0.23 % Model : x86_64 x86_64
% 0.02/0.23 % CPU : Intel(R) Xeon(R) CPU E5-2609 0 @ 2.40GHz
% 0.02/0.23 % Memory : 32218.625MB
% 0.02/0.23 % OS : Linux 3.10.0-693.2.2.el7.x86_64
% 0.02/0.23 % CPULimit : 300
% 0.02/0.23 % DateTime : Fri Jan 5 13:08:04 CST 2018
% 0.02/0.23 % CPUTime :
% 0.02/0.25 Python 2.7.13
% 0.33/0.52 Using paths ['/home/cristobal/cocATP/CASC/TPTP/', '/export/starexec/sandbox2/benchmark/', '/export/starexec/sandbox2/benchmark/']
% 0.33/0.52 Failed to open /home/cristobal/cocATP/CASC/TPTP/Axioms/NUM007^0.ax, trying next directory
% 0.33/0.52 FOF formula (<kernel.Constant object at 0x2abadd1f92d8>, <kernel.DependentProduct object at 0x2abadd1f96c8>) of role type named typ_is_of
% 0.33/0.52 Using role type
% 0.33/0.52 Declaring is_of:(fofType->((fofType->Prop)->Prop))
% 0.33/0.52 FOF formula (((eq (fofType->((fofType->Prop)->Prop))) is_of) (fun (X0:fofType) (X1:(fofType->Prop))=> (X1 X0))) of role definition named def_is_of
% 0.33/0.52 A new definition: (((eq (fofType->((fofType->Prop)->Prop))) is_of) (fun (X0:fofType) (X1:(fofType->Prop))=> (X1 X0)))
% 0.33/0.52 Defined: is_of:=(fun (X0:fofType) (X1:(fofType->Prop))=> (X1 X0))
% 0.33/0.52 FOF formula (<kernel.Constant object at 0x2abadd1f92d8>, <kernel.DependentProduct object at 0x2abadd1f9ea8>) of role type named typ_all_of
% 0.33/0.52 Using role type
% 0.33/0.52 Declaring all_of:((fofType->Prop)->((fofType->Prop)->Prop))
% 0.33/0.52 FOF formula (((eq ((fofType->Prop)->((fofType->Prop)->Prop))) all_of) (fun (X0:(fofType->Prop)) (X1:(fofType->Prop))=> (forall (X2:fofType), (((is_of X2) X0)->(X1 X2))))) of role definition named def_all_of
% 0.33/0.52 A new definition: (((eq ((fofType->Prop)->((fofType->Prop)->Prop))) all_of) (fun (X0:(fofType->Prop)) (X1:(fofType->Prop))=> (forall (X2:fofType), (((is_of X2) X0)->(X1 X2)))))
% 0.33/0.52 Defined: all_of:=(fun (X0:(fofType->Prop)) (X1:(fofType->Prop))=> (forall (X2:fofType), (((is_of X2) X0)->(X1 X2))))
% 0.33/0.52 FOF formula (<kernel.Constant object at 0x2abadd1f9ea8>, <kernel.DependentProduct object at 0x2abadd1f9170>) of role type named typ_eps
% 0.33/0.52 Using role type
% 0.33/0.52 Declaring eps:((fofType->Prop)->fofType)
% 0.33/0.52 FOF formula (<kernel.Constant object at 0x2abadd1f93f8>, <kernel.DependentProduct object at 0x2abadd1f9290>) of role type named typ_in
% 0.33/0.52 Using role type
% 0.33/0.52 Declaring in:(fofType->(fofType->Prop))
% 0.33/0.52 FOF formula (<kernel.Constant object at 0x2abadd1f9f80>, <kernel.DependentProduct object at 0x2abadd1f9ea8>) of role type named typ_d_Subq
% 0.33/0.52 Using role type
% 0.33/0.52 Declaring d_Subq:(fofType->(fofType->Prop))
% 0.33/0.52 FOF formula (((eq (fofType->(fofType->Prop))) d_Subq) (fun (X0:fofType) (X1:fofType)=> (forall (X2:fofType), (((in X2) X0)->((in X2) X1))))) of role definition named def_d_Subq
% 0.33/0.52 A new definition: (((eq (fofType->(fofType->Prop))) d_Subq) (fun (X0:fofType) (X1:fofType)=> (forall (X2:fofType), (((in X2) X0)->((in X2) X1)))))
% 0.33/0.52 Defined: d_Subq:=(fun (X0:fofType) (X1:fofType)=> (forall (X2:fofType), (((in X2) X0)->((in X2) X1))))
% 0.33/0.52 FOF formula (forall (X0:fofType) (X1:fofType), (((d_Subq X0) X1)->(((d_Subq X1) X0)->(((eq fofType) X0) X1)))) of role axiom named set_ext
% 0.33/0.52 A new axiom: (forall (X0:fofType) (X1:fofType), (((d_Subq X0) X1)->(((d_Subq X1) X0)->(((eq fofType) X0) X1))))
% 0.33/0.52 FOF formula (forall (X0:(fofType->Prop)), ((forall (X1:fofType), ((forall (X2:fofType), (((in X2) X1)->(X0 X2)))->(X0 X1)))->(forall (X1:fofType), (X0 X1)))) of role axiom named k_In_ind
% 0.33/0.52 A new axiom: (forall (X0:(fofType->Prop)), ((forall (X1:fofType), ((forall (X2:fofType), (((in X2) X1)->(X0 X2)))->(X0 X1)))->(forall (X1:fofType), (X0 X1))))
% 0.33/0.52 FOF formula (<kernel.Constant object at 0x2abadd1f9bd8>, <kernel.Single object at 0x2abadd1f9b48>) of role type named typ_emptyset
% 0.33/0.52 Using role type
% 0.33/0.52 Declaring emptyset:fofType
% 0.33/0.52 FOF formula (((ex fofType) (fun (X0:fofType)=> ((in X0) emptyset)))->False) of role axiom named k_EmptyAx
% 0.33/0.52 A new axiom: (((ex fofType) (fun (X0:fofType)=> ((in X0) emptyset)))->False)
% 0.33/0.52 FOF formula (<kernel.Constant object at 0x2abadd1f9950>, <kernel.DependentProduct object at 0x2abadd1f9ea8>) of role type named typ_union
% 0.33/0.52 Using role type
% 0.33/0.52 Declaring union:(fofType->fofType)
% 0.33/0.52 FOF formula (forall (X0:fofType) (X1:fofType), ((iff ((in X1) (union X0))) ((ex fofType) (fun (X2:fofType)=> ((and ((in X1) X2)) ((in X2) X0)))))) of role axiom named k_UnionEq
% 0.33/0.52 A new axiom: (forall (X0:fofType) (X1:fofType), ((iff ((in X1) (union X0))) ((ex fofType) (fun (X2:fofType)=> ((and ((in X1) X2)) ((in X2) X0))))))
% 0.33/0.52 FOF formula (<kernel.Constant object at 0x2abad595c4d0>, <kernel.DependentProduct object at 0x2abadd1f9f80>) of role type named typ_power
% 0.33/0.52 Using role type
% 0.34/0.53 Declaring power:(fofType->fofType)
% 0.34/0.53 FOF formula (forall (X0:fofType) (X1:fofType), ((iff ((in X1) (power X0))) ((d_Subq X1) X0))) of role axiom named k_PowerEq
% 0.34/0.53 A new axiom: (forall (X0:fofType) (X1:fofType), ((iff ((in X1) (power X0))) ((d_Subq X1) X0)))
% 0.34/0.53 FOF formula (<kernel.Constant object at 0x2abad5961950>, <kernel.DependentProduct object at 0x2abadd1f9ea8>) of role type named typ_repl
% 0.34/0.53 Using role type
% 0.34/0.53 Declaring repl:(fofType->((fofType->fofType)->fofType))
% 0.34/0.53 FOF formula (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), ((iff ((in X2) ((repl X0) X1))) ((ex fofType) (fun (X3:fofType)=> ((and ((in X3) X0)) (((eq fofType) X2) (X1 X3))))))) of role axiom named k_ReplEq
% 0.34/0.53 A new axiom: (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), ((iff ((in X2) ((repl X0) X1))) ((ex fofType) (fun (X3:fofType)=> ((and ((in X3) X0)) (((eq fofType) X2) (X1 X3)))))))
% 0.34/0.53 FOF formula (<kernel.Constant object at 0x2abadd1f9ea8>, <kernel.DependentProduct object at 0x2abadd1f90e0>) of role type named typ_d_Union_closed
% 0.34/0.53 Using role type
% 0.34/0.53 Declaring d_Union_closed:(fofType->Prop)
% 0.34/0.53 FOF formula (((eq (fofType->Prop)) d_Union_closed) (fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->((in (union X1)) X0))))) of role definition named def_d_Union_closed
% 0.34/0.53 A new definition: (((eq (fofType->Prop)) d_Union_closed) (fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->((in (union X1)) X0)))))
% 0.34/0.53 Defined: d_Union_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->((in (union X1)) X0))))
% 0.34/0.53 FOF formula (<kernel.Constant object at 0x2abadd1f90e0>, <kernel.DependentProduct object at 0x2abadd1f9dd0>) of role type named typ_d_Power_closed
% 0.34/0.53 Using role type
% 0.34/0.53 Declaring d_Power_closed:(fofType->Prop)
% 0.34/0.53 FOF formula (((eq (fofType->Prop)) d_Power_closed) (fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->((in (power X1)) X0))))) of role definition named def_d_Power_closed
% 0.34/0.53 A new definition: (((eq (fofType->Prop)) d_Power_closed) (fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->((in (power X1)) X0)))))
% 0.34/0.53 Defined: d_Power_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->((in (power X1)) X0))))
% 0.34/0.53 FOF formula (<kernel.Constant object at 0x2abadd1f9dd0>, <kernel.DependentProduct object at 0x2abadd1f91b8>) of role type named typ_d_Repl_closed
% 0.34/0.53 Using role type
% 0.34/0.53 Declaring d_Repl_closed:(fofType->Prop)
% 0.34/0.53 FOF formula (((eq (fofType->Prop)) d_Repl_closed) (fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->(forall (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X1)->((in (X2 X3)) X0)))->((in ((repl X1) X2)) X0))))))) of role definition named def_d_Repl_closed
% 0.34/0.53 A new definition: (((eq (fofType->Prop)) d_Repl_closed) (fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->(forall (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X1)->((in (X2 X3)) X0)))->((in ((repl X1) X2)) X0)))))))
% 0.34/0.53 Defined: d_Repl_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->(forall (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X1)->((in (X2 X3)) X0)))->((in ((repl X1) X2)) X0))))))
% 0.34/0.53 FOF formula (<kernel.Constant object at 0x2abadd1f91b8>, <kernel.DependentProduct object at 0x2abadd1f9ea8>) of role type named typ_d_ZF_closed
% 0.34/0.53 Using role type
% 0.34/0.53 Declaring d_ZF_closed:(fofType->Prop)
% 0.34/0.53 FOF formula (((eq (fofType->Prop)) d_ZF_closed) (fun (X0:fofType)=> ((and ((and (d_Union_closed X0)) (d_Power_closed X0))) (d_Repl_closed X0)))) of role definition named def_d_ZF_closed
% 0.34/0.53 A new definition: (((eq (fofType->Prop)) d_ZF_closed) (fun (X0:fofType)=> ((and ((and (d_Union_closed X0)) (d_Power_closed X0))) (d_Repl_closed X0))))
% 0.34/0.53 Defined: d_ZF_closed:=(fun (X0:fofType)=> ((and ((and (d_Union_closed X0)) (d_Power_closed X0))) (d_Repl_closed X0)))
% 0.34/0.53 FOF formula (<kernel.Constant object at 0x2abadd1f9ea8>, <kernel.DependentProduct object at 0x2abadd1f9878>) of role type named typ_univof
% 0.34/0.53 Using role type
% 0.34/0.53 Declaring univof:(fofType->fofType)
% 0.34/0.53 FOF formula (forall (X0:fofType), ((in X0) (univof X0))) of role axiom named k_UnivOf_In
% 0.34/0.53 A new axiom: (forall (X0:fofType), ((in X0) (univof X0)))
% 0.34/0.53 FOF formula (forall (X0:fofType), (d_ZF_closed (univof X0))) of role axiom named k_UnivOf_ZF_closed
% 0.34/0.55 A new axiom: (forall (X0:fofType), (d_ZF_closed (univof X0)))
% 0.34/0.55 FOF formula (<kernel.Constant object at 0x2abadd1f9b00>, <kernel.DependentProduct object at 0x2abadd1f9a28>) of role type named typ_if
% 0.34/0.55 Using role type
% 0.34/0.55 Declaring if:(Prop->(fofType->(fofType->fofType)))
% 0.34/0.55 FOF formula (((eq (Prop->(fofType->(fofType->fofType)))) if) (fun (X0:Prop) (X1:fofType) (X2:fofType)=> (eps (fun (X3:fofType)=> ((or ((and X0) (((eq fofType) X3) X1))) ((and (X0->False)) (((eq fofType) X3) X2))))))) of role definition named def_if
% 0.34/0.55 A new definition: (((eq (Prop->(fofType->(fofType->fofType)))) if) (fun (X0:Prop) (X1:fofType) (X2:fofType)=> (eps (fun (X3:fofType)=> ((or ((and X0) (((eq fofType) X3) X1))) ((and (X0->False)) (((eq fofType) X3) X2)))))))
% 0.34/0.55 Defined: if:=(fun (X0:Prop) (X1:fofType) (X2:fofType)=> (eps (fun (X3:fofType)=> ((or ((and X0) (((eq fofType) X3) X1))) ((and (X0->False)) (((eq fofType) X3) X2))))))
% 0.34/0.55 FOF formula (forall (X0:Prop) (X1:fofType) (X2:fofType), ((or ((and X0) (((eq fofType) (((if X0) X1) X2)) X1))) ((and (X0->False)) (((eq fofType) (((if X0) X1) X2)) X2)))) of role axiom named if_i_correct
% 0.34/0.55 A new axiom: (forall (X0:Prop) (X1:fofType) (X2:fofType), ((or ((and X0) (((eq fofType) (((if X0) X1) X2)) X1))) ((and (X0->False)) (((eq fofType) (((if X0) X1) X2)) X2))))
% 0.34/0.55 FOF formula (forall (X0:Prop) (X1:fofType) (X2:fofType), ((X0->False)->(((eq fofType) (((if X0) X1) X2)) X2))) of role axiom named if_i_0
% 0.34/0.55 A new axiom: (forall (X0:Prop) (X1:fofType) (X2:fofType), ((X0->False)->(((eq fofType) (((if X0) X1) X2)) X2)))
% 0.34/0.55 FOF formula (forall (X0:Prop) (X1:fofType) (X2:fofType), (X0->(((eq fofType) (((if X0) X1) X2)) X1))) of role axiom named if_i_1
% 0.34/0.55 A new axiom: (forall (X0:Prop) (X1:fofType) (X2:fofType), (X0->(((eq fofType) (((if X0) X1) X2)) X1)))
% 0.34/0.55 FOF formula (forall (X0:Prop) (X1:fofType) (X2:fofType), ((or (((eq fofType) (((if X0) X1) X2)) X1)) (((eq fofType) (((if X0) X1) X2)) X2))) of role axiom named if_i_or
% 0.34/0.55 A new axiom: (forall (X0:Prop) (X1:fofType) (X2:fofType), ((or (((eq fofType) (((if X0) X1) X2)) X1)) (((eq fofType) (((if X0) X1) X2)) X2)))
% 0.34/0.55 FOF formula (<kernel.Constant object at 0x2abadd1f9908>, <kernel.DependentProduct object at 0x2abadd1f91b8>) of role type named typ_nIn
% 0.34/0.55 Using role type
% 0.34/0.55 Declaring nIn:(fofType->(fofType->Prop))
% 0.34/0.55 FOF formula (((eq (fofType->(fofType->Prop))) nIn) (fun (X0:fofType) (X1:fofType)=> (((in X0) X1)->False))) of role definition named def_nIn
% 0.34/0.55 A new definition: (((eq (fofType->(fofType->Prop))) nIn) (fun (X0:fofType) (X1:fofType)=> (((in X0) X1)->False)))
% 0.34/0.55 Defined: nIn:=(fun (X0:fofType) (X1:fofType)=> (((in X0) X1)->False))
% 0.34/0.55 FOF formula (forall (X0:fofType) (X1:fofType), (((in X1) (power X0))->((d_Subq X1) X0))) of role axiom named k_PowerE
% 0.34/0.55 A new axiom: (forall (X0:fofType) (X1:fofType), (((in X1) (power X0))->((d_Subq X1) X0)))
% 0.34/0.55 FOF formula (forall (X0:fofType) (X1:fofType), (((d_Subq X1) X0)->((in X1) (power X0)))) of role axiom named k_PowerI
% 0.34/0.55 A new axiom: (forall (X0:fofType) (X1:fofType), (((d_Subq X1) X0)->((in X1) (power X0))))
% 0.34/0.55 FOF formula (forall (X0:fofType), ((in X0) (power X0))) of role axiom named k_Self_In_Power
% 0.34/0.55 A new axiom: (forall (X0:fofType), ((in X0) (power X0)))
% 0.34/0.55 FOF formula (<kernel.Constant object at 0x2abadd1f9128>, <kernel.DependentProduct object at 0x2abadd2003b0>) of role type named typ_d_UPair
% 0.34/0.55 Using role type
% 0.34/0.55 Declaring d_UPair:(fofType->(fofType->fofType))
% 0.34/0.55 FOF formula (((eq (fofType->(fofType->fofType))) d_UPair) (fun (X0:fofType) (X1:fofType)=> ((repl (power (power emptyset))) (fun (X2:fofType)=> (((if ((in emptyset) X2)) X0) X1))))) of role definition named def_d_UPair
% 0.34/0.55 A new definition: (((eq (fofType->(fofType->fofType))) d_UPair) (fun (X0:fofType) (X1:fofType)=> ((repl (power (power emptyset))) (fun (X2:fofType)=> (((if ((in emptyset) X2)) X0) X1)))))
% 0.34/0.55 Defined: d_UPair:=(fun (X0:fofType) (X1:fofType)=> ((repl (power (power emptyset))) (fun (X2:fofType)=> (((if ((in emptyset) X2)) X0) X1))))
% 0.34/0.55 FOF formula (<kernel.Constant object at 0x2abadd1f9128>, <kernel.DependentProduct object at 0x2abadd200560>) of role type named typ_d_Sing
% 0.34/0.55 Using role type
% 0.34/0.57 Declaring d_Sing:(fofType->fofType)
% 0.34/0.57 FOF formula (((eq (fofType->fofType)) d_Sing) (fun (X0:fofType)=> ((d_UPair X0) X0))) of role definition named def_d_Sing
% 0.34/0.57 A new definition: (((eq (fofType->fofType)) d_Sing) (fun (X0:fofType)=> ((d_UPair X0) X0)))
% 0.34/0.57 Defined: d_Sing:=(fun (X0:fofType)=> ((d_UPair X0) X0))
% 0.34/0.57 FOF formula (<kernel.Constant object at 0x2abadd1f91b8>, <kernel.DependentProduct object at 0x2abadd200a28>) of role type named typ_binunion
% 0.34/0.57 Using role type
% 0.34/0.57 Declaring binunion:(fofType->(fofType->fofType))
% 0.34/0.57 FOF formula (((eq (fofType->(fofType->fofType))) binunion) (fun (X0:fofType) (X1:fofType)=> (union ((d_UPair X0) X1)))) of role definition named def_binunion
% 0.34/0.57 A new definition: (((eq (fofType->(fofType->fofType))) binunion) (fun (X0:fofType) (X1:fofType)=> (union ((d_UPair X0) X1))))
% 0.34/0.57 Defined: binunion:=(fun (X0:fofType) (X1:fofType)=> (union ((d_UPair X0) X1)))
% 0.34/0.57 FOF formula (<kernel.Constant object at 0x2abadd200a28>, <kernel.DependentProduct object at 0x2abadd2005f0>) of role type named typ_famunion
% 0.34/0.57 Using role type
% 0.34/0.57 Declaring famunion:(fofType->((fofType->fofType)->fofType))
% 0.34/0.57 FOF formula (((eq (fofType->((fofType->fofType)->fofType))) famunion) (fun (X0:fofType) (X1:(fofType->fofType))=> (union ((repl X0) X1)))) of role definition named def_famunion
% 0.34/0.57 A new definition: (((eq (fofType->((fofType->fofType)->fofType))) famunion) (fun (X0:fofType) (X1:(fofType->fofType))=> (union ((repl X0) X1))))
% 0.34/0.57 Defined: famunion:=(fun (X0:fofType) (X1:(fofType->fofType))=> (union ((repl X0) X1)))
% 0.34/0.57 FOF formula (<kernel.Constant object at 0x2abadd2005f0>, <kernel.DependentProduct object at 0x2abadd200440>) of role type named typ_d_Sep
% 0.34/0.57 Using role type
% 0.34/0.57 Declaring d_Sep:(fofType->((fofType->Prop)->fofType))
% 0.34/0.57 FOF formula (((eq (fofType->((fofType->Prop)->fofType))) d_Sep) (fun (X0:fofType) (X1:(fofType->Prop))=> (((if ((ex fofType) (fun (X2:fofType)=> ((and ((in X2) X0)) (X1 X2))))) ((repl X0) (fun (X2:fofType)=> (((if (X1 X2)) X2) (eps (fun (X3:fofType)=> ((and ((in X3) X0)) (X1 X3)))))))) emptyset))) of role definition named def_d_Sep
% 0.34/0.57 A new definition: (((eq (fofType->((fofType->Prop)->fofType))) d_Sep) (fun (X0:fofType) (X1:(fofType->Prop))=> (((if ((ex fofType) (fun (X2:fofType)=> ((and ((in X2) X0)) (X1 X2))))) ((repl X0) (fun (X2:fofType)=> (((if (X1 X2)) X2) (eps (fun (X3:fofType)=> ((and ((in X3) X0)) (X1 X3)))))))) emptyset)))
% 0.34/0.57 Defined: d_Sep:=(fun (X0:fofType) (X1:(fofType->Prop))=> (((if ((ex fofType) (fun (X2:fofType)=> ((and ((in X2) X0)) (X1 X2))))) ((repl X0) (fun (X2:fofType)=> (((if (X1 X2)) X2) (eps (fun (X3:fofType)=> ((and ((in X3) X0)) (X1 X3)))))))) emptyset))
% 0.34/0.57 FOF formula (forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) X0)->((X1 X2)->((in X2) ((d_Sep X0) X1))))) of role axiom named k_SepI
% 0.34/0.57 A new axiom: (forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) X0)->((X1 X2)->((in X2) ((d_Sep X0) X1)))))
% 0.34/0.57 FOF formula (forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) ((d_Sep X0) X1))->((in X2) X0))) of role axiom named k_SepE1
% 0.34/0.57 A new axiom: (forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) ((d_Sep X0) X1))->((in X2) X0)))
% 0.34/0.57 FOF formula (forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) ((d_Sep X0) X1))->(X1 X2))) of role axiom named k_SepE2
% 0.34/0.57 A new axiom: (forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) ((d_Sep X0) X1))->(X1 X2)))
% 0.34/0.57 FOF formula (<kernel.Constant object at 0x2abadd200a28>, <kernel.DependentProduct object at 0x2abadd200908>) of role type named typ_d_ReplSep
% 0.34/0.57 Using role type
% 0.34/0.57 Declaring d_ReplSep:(fofType->((fofType->Prop)->((fofType->fofType)->fofType)))
% 0.34/0.57 FOF formula (((eq (fofType->((fofType->Prop)->((fofType->fofType)->fofType)))) d_ReplSep) (fun (X0:fofType) (X1:(fofType->Prop))=> (repl ((d_Sep X0) X1)))) of role definition named def_d_ReplSep
% 0.34/0.57 A new definition: (((eq (fofType->((fofType->Prop)->((fofType->fofType)->fofType)))) d_ReplSep) (fun (X0:fofType) (X1:(fofType->Prop))=> (repl ((d_Sep X0) X1))))
% 0.34/0.57 Defined: d_ReplSep:=(fun (X0:fofType) (X1:(fofType->Prop))=> (repl ((d_Sep X0) X1)))
% 0.34/0.57 FOF formula (<kernel.Constant object at 0x2abadd200560>, <kernel.DependentProduct object at 0x2abadd321950>) of role type named typ_setminus
% 0.34/0.58 Using role type
% 0.34/0.58 Declaring setminus:(fofType->(fofType->fofType))
% 0.34/0.58 FOF formula (((eq (fofType->(fofType->fofType))) setminus) (fun (X0:fofType) (X1:fofType)=> ((d_Sep X0) (fun (X2:fofType)=> ((nIn X2) X1))))) of role definition named def_setminus
% 0.34/0.58 A new definition: (((eq (fofType->(fofType->fofType))) setminus) (fun (X0:fofType) (X1:fofType)=> ((d_Sep X0) (fun (X2:fofType)=> ((nIn X2) X1)))))
% 0.34/0.58 Defined: setminus:=(fun (X0:fofType) (X1:fofType)=> ((d_Sep X0) (fun (X2:fofType)=> ((nIn X2) X1))))
% 0.34/0.58 FOF formula (<kernel.Constant object at 0x2abadd200560>, <kernel.DependentProduct object at 0x2abadd3210e0>) of role type named typ_d_In_rec_G
% 0.34/0.58 Using role type
% 0.34/0.58 Declaring d_In_rec_G:((fofType->((fofType->fofType)->fofType))->(fofType->(fofType->Prop)))
% 0.34/0.58 FOF formula (((eq ((fofType->((fofType->fofType)->fofType))->(fofType->(fofType->Prop)))) d_In_rec_G) (fun (X0:(fofType->((fofType->fofType)->fofType))) (X1:fofType) (X2:fofType)=> (forall (X3:(fofType->(fofType->Prop))), ((forall (X4:fofType) (X5:(fofType->fofType)), ((forall (X6:fofType), (((in X6) X4)->((X3 X6) (X5 X6))))->((X3 X4) ((X0 X4) X5))))->((X3 X1) X2))))) of role definition named def_d_In_rec_G
% 0.34/0.58 A new definition: (((eq ((fofType->((fofType->fofType)->fofType))->(fofType->(fofType->Prop)))) d_In_rec_G) (fun (X0:(fofType->((fofType->fofType)->fofType))) (X1:fofType) (X2:fofType)=> (forall (X3:(fofType->(fofType->Prop))), ((forall (X4:fofType) (X5:(fofType->fofType)), ((forall (X6:fofType), (((in X6) X4)->((X3 X6) (X5 X6))))->((X3 X4) ((X0 X4) X5))))->((X3 X1) X2)))))
% 0.34/0.58 Defined: d_In_rec_G:=(fun (X0:(fofType->((fofType->fofType)->fofType))) (X1:fofType) (X2:fofType)=> (forall (X3:(fofType->(fofType->Prop))), ((forall (X4:fofType) (X5:(fofType->fofType)), ((forall (X6:fofType), (((in X6) X4)->((X3 X6) (X5 X6))))->((X3 X4) ((X0 X4) X5))))->((X3 X1) X2))))
% 0.34/0.58 FOF formula (<kernel.Constant object at 0x2abadd200560>, <kernel.DependentProduct object at 0x2abadd321680>) of role type named typ_d_In_rec
% 0.34/0.58 Using role type
% 0.34/0.58 Declaring d_In_rec:((fofType->((fofType->fofType)->fofType))->(fofType->fofType))
% 0.34/0.58 FOF formula (((eq ((fofType->((fofType->fofType)->fofType))->(fofType->fofType))) d_In_rec) (fun (X0:(fofType->((fofType->fofType)->fofType))) (X1:fofType)=> (eps ((d_In_rec_G X0) X1)))) of role definition named def_d_In_rec
% 0.34/0.58 A new definition: (((eq ((fofType->((fofType->fofType)->fofType))->(fofType->fofType))) d_In_rec) (fun (X0:(fofType->((fofType->fofType)->fofType))) (X1:fofType)=> (eps ((d_In_rec_G X0) X1))))
% 0.34/0.58 Defined: d_In_rec:=(fun (X0:(fofType->((fofType->fofType)->fofType))) (X1:fofType)=> (eps ((d_In_rec_G X0) X1)))
% 0.34/0.58 FOF formula (<kernel.Constant object at 0x2abadd321680>, <kernel.DependentProduct object at 0x2abadd321320>) of role type named typ_ordsucc
% 0.34/0.58 Using role type
% 0.34/0.58 Declaring ordsucc:(fofType->fofType)
% 0.34/0.58 FOF formula (((eq (fofType->fofType)) ordsucc) (fun (X0:fofType)=> ((binunion X0) (d_Sing X0)))) of role definition named def_ordsucc
% 0.34/0.58 A new definition: (((eq (fofType->fofType)) ordsucc) (fun (X0:fofType)=> ((binunion X0) (d_Sing X0))))
% 0.34/0.58 Defined: ordsucc:=(fun (X0:fofType)=> ((binunion X0) (d_Sing X0)))
% 0.34/0.58 FOF formula (forall (X0:fofType), (not (((eq fofType) (ordsucc X0)) emptyset))) of role axiom named neq_ordsucc_0
% 0.34/0.58 A new axiom: (forall (X0:fofType), (not (((eq fofType) (ordsucc X0)) emptyset)))
% 0.34/0.58 FOF formula (forall (X0:fofType) (X1:fofType), ((((eq fofType) (ordsucc X0)) (ordsucc X1))->(((eq fofType) X0) X1))) of role axiom named ordsucc_inj
% 0.34/0.58 A new axiom: (forall (X0:fofType) (X1:fofType), ((((eq fofType) (ordsucc X0)) (ordsucc X1))->(((eq fofType) X0) X1)))
% 0.34/0.58 FOF formula ((in emptyset) (ordsucc emptyset)) of role axiom named k_In_0_1
% 0.34/0.58 A new axiom: ((in emptyset) (ordsucc emptyset))
% 0.34/0.58 FOF formula (<kernel.Constant object at 0x2abadd3212d8>, <kernel.DependentProduct object at 0x2abadd321950>) of role type named typ_nat_p
% 0.34/0.58 Using role type
% 0.34/0.58 Declaring nat_p:(fofType->Prop)
% 0.34/0.58 FOF formula (((eq (fofType->Prop)) nat_p) (fun (X0:fofType)=> (forall (X1:(fofType->Prop)), ((X1 emptyset)->((forall (X2:fofType), ((X1 X2)->(X1 (ordsucc X2))))->(X1 X0)))))) of role definition named def_nat_p
% 0.34/0.60 A new definition: (((eq (fofType->Prop)) nat_p) (fun (X0:fofType)=> (forall (X1:(fofType->Prop)), ((X1 emptyset)->((forall (X2:fofType), ((X1 X2)->(X1 (ordsucc X2))))->(X1 X0))))))
% 0.34/0.60 Defined: nat_p:=(fun (X0:fofType)=> (forall (X1:(fofType->Prop)), ((X1 emptyset)->((forall (X2:fofType), ((X1 X2)->(X1 (ordsucc X2))))->(X1 X0)))))
% 0.34/0.60 FOF formula (forall (X0:fofType), ((nat_p X0)->(nat_p (ordsucc X0)))) of role axiom named nat_ordsucc
% 0.34/0.60 A new axiom: (forall (X0:fofType), ((nat_p X0)->(nat_p (ordsucc X0))))
% 0.34/0.60 FOF formula (nat_p (ordsucc emptyset)) of role axiom named nat_1
% 0.34/0.60 A new axiom: (nat_p (ordsucc emptyset))
% 0.34/0.60 FOF formula (forall (X0:(fofType->Prop)), ((X0 emptyset)->((forall (X1:fofType), ((nat_p X1)->((X0 X1)->(X0 (ordsucc X1)))))->(forall (X1:fofType), ((nat_p X1)->(X0 X1)))))) of role axiom named nat_ind
% 0.34/0.60 A new axiom: (forall (X0:(fofType->Prop)), ((X0 emptyset)->((forall (X1:fofType), ((nat_p X1)->((X0 X1)->(X0 (ordsucc X1)))))->(forall (X1:fofType), ((nat_p X1)->(X0 X1))))))
% 0.34/0.60 FOF formula (forall (X0:fofType), ((nat_p X0)->((or (((eq fofType) X0) emptyset)) ((ex fofType) (fun (X1:fofType)=> ((and (nat_p X1)) (((eq fofType) X0) (ordsucc X1)))))))) of role axiom named nat_inv
% 0.34/0.60 A new axiom: (forall (X0:fofType), ((nat_p X0)->((or (((eq fofType) X0) emptyset)) ((ex fofType) (fun (X1:fofType)=> ((and (nat_p X1)) (((eq fofType) X0) (ordsucc X1))))))))
% 0.34/0.60 FOF formula (<kernel.Constant object at 0x2abadd3219e0>, <kernel.Single object at 0x2abadd321710>) of role type named typ_omega
% 0.34/0.60 Using role type
% 0.34/0.60 Declaring omega:fofType
% 0.34/0.60 FOF formula (((eq fofType) omega) ((d_Sep (univof emptyset)) nat_p)) of role definition named def_omega
% 0.34/0.60 A new definition: (((eq fofType) omega) ((d_Sep (univof emptyset)) nat_p))
% 0.34/0.60 Defined: omega:=((d_Sep (univof emptyset)) nat_p)
% 0.34/0.60 FOF formula (forall (X0:fofType), (((in X0) omega)->(nat_p X0))) of role axiom named omega_nat_p
% 0.34/0.60 A new axiom: (forall (X0:fofType), (((in X0) omega)->(nat_p X0)))
% 0.34/0.60 FOF formula (forall (X0:fofType), ((nat_p X0)->((in X0) omega))) of role axiom named nat_p_omega
% 0.34/0.60 A new axiom: (forall (X0:fofType), ((nat_p X0)->((in X0) omega)))
% 0.34/0.60 FOF formula (<kernel.Constant object at 0x2abadd321290>, <kernel.DependentProduct object at 0x2abadd321710>) of role type named typ_d_Inj1
% 0.34/0.60 Using role type
% 0.34/0.60 Declaring d_Inj1:(fofType->fofType)
% 0.34/0.60 FOF formula (((eq (fofType->fofType)) d_Inj1) (d_In_rec (fun (X0:fofType) (X1:(fofType->fofType))=> ((binunion (d_Sing emptyset)) ((repl X0) X1))))) of role definition named def_d_Inj1
% 0.34/0.60 A new definition: (((eq (fofType->fofType)) d_Inj1) (d_In_rec (fun (X0:fofType) (X1:(fofType->fofType))=> ((binunion (d_Sing emptyset)) ((repl X0) X1)))))
% 0.34/0.60 Defined: d_Inj1:=(d_In_rec (fun (X0:fofType) (X1:(fofType->fofType))=> ((binunion (d_Sing emptyset)) ((repl X0) X1))))
% 0.34/0.60 FOF formula (<kernel.Constant object at 0x2abadd3219e0>, <kernel.DependentProduct object at 0x2abadd321d40>) of role type named typ_d_Inj0
% 0.34/0.60 Using role type
% 0.34/0.60 Declaring d_Inj0:(fofType->fofType)
% 0.34/0.60 FOF formula (((eq (fofType->fofType)) d_Inj0) (fun (X0:fofType)=> ((repl X0) d_Inj1))) of role definition named def_d_Inj0
% 0.34/0.60 A new definition: (((eq (fofType->fofType)) d_Inj0) (fun (X0:fofType)=> ((repl X0) d_Inj1)))
% 0.34/0.60 Defined: d_Inj0:=(fun (X0:fofType)=> ((repl X0) d_Inj1))
% 0.34/0.60 FOF formula (<kernel.Constant object at 0x2abadd321d40>, <kernel.DependentProduct object at 0x2abadd321710>) of role type named typ_d_Unj
% 0.34/0.60 Using role type
% 0.34/0.60 Declaring d_Unj:(fofType->fofType)
% 0.34/0.60 FOF formula (((eq (fofType->fofType)) d_Unj) (d_In_rec (fun (X0:fofType)=> (repl ((setminus X0) (d_Sing emptyset)))))) of role definition named def_d_Unj
% 0.34/0.60 A new definition: (((eq (fofType->fofType)) d_Unj) (d_In_rec (fun (X0:fofType)=> (repl ((setminus X0) (d_Sing emptyset))))))
% 0.34/0.60 Defined: d_Unj:=(d_In_rec (fun (X0:fofType)=> (repl ((setminus X0) (d_Sing emptyset)))))
% 0.34/0.60 FOF formula (<kernel.Constant object at 0x2abadd321290>, <kernel.DependentProduct object at 0x2abadd321710>) of role type named typ_pair
% 0.34/0.60 Using role type
% 0.34/0.60 Declaring pair:(fofType->(fofType->fofType))
% 0.34/0.60 FOF formula (((eq (fofType->(fofType->fofType))) pair) (fun (X0:fofType) (X1:fofType)=> ((binunion ((repl X0) d_Inj0)) ((repl X1) d_Inj1)))) of role definition named def_pair
% 0.43/0.61 A new definition: (((eq (fofType->(fofType->fofType))) pair) (fun (X0:fofType) (X1:fofType)=> ((binunion ((repl X0) d_Inj0)) ((repl X1) d_Inj1))))
% 0.43/0.61 Defined: pair:=(fun (X0:fofType) (X1:fofType)=> ((binunion ((repl X0) d_Inj0)) ((repl X1) d_Inj1)))
% 0.43/0.61 FOF formula (<kernel.Constant object at 0x2abadd321710>, <kernel.DependentProduct object at 0x2abadd321518>) of role type named typ_proj0
% 0.43/0.61 Using role type
% 0.43/0.61 Declaring proj0:(fofType->fofType)
% 0.43/0.61 FOF formula (((eq (fofType->fofType)) proj0) (fun (X0:fofType)=> (((d_ReplSep X0) (fun (X1:fofType)=> ((ex fofType) (fun (X2:fofType)=> (((eq fofType) (d_Inj0 X2)) X1))))) d_Unj))) of role definition named def_proj0
% 0.43/0.61 A new definition: (((eq (fofType->fofType)) proj0) (fun (X0:fofType)=> (((d_ReplSep X0) (fun (X1:fofType)=> ((ex fofType) (fun (X2:fofType)=> (((eq fofType) (d_Inj0 X2)) X1))))) d_Unj)))
% 0.43/0.61 Defined: proj0:=(fun (X0:fofType)=> (((d_ReplSep X0) (fun (X1:fofType)=> ((ex fofType) (fun (X2:fofType)=> (((eq fofType) (d_Inj0 X2)) X1))))) d_Unj))
% 0.43/0.61 FOF formula (<kernel.Constant object at 0x2abadd321518>, <kernel.DependentProduct object at 0x2abadd321440>) of role type named typ_proj1
% 0.43/0.61 Using role type
% 0.43/0.61 Declaring _TPTP_proj1:(fofType->fofType)
% 0.43/0.61 FOF formula (((eq (fofType->fofType)) _TPTP_proj1) (fun (X0:fofType)=> (((d_ReplSep X0) (fun (X1:fofType)=> ((ex fofType) (fun (X2:fofType)=> (((eq fofType) (d_Inj1 X2)) X1))))) d_Unj))) of role definition named def_proj1
% 0.43/0.61 A new definition: (((eq (fofType->fofType)) _TPTP_proj1) (fun (X0:fofType)=> (((d_ReplSep X0) (fun (X1:fofType)=> ((ex fofType) (fun (X2:fofType)=> (((eq fofType) (d_Inj1 X2)) X1))))) d_Unj)))
% 0.43/0.61 Defined: _TPTP_proj1:=(fun (X0:fofType)=> (((d_ReplSep X0) (fun (X1:fofType)=> ((ex fofType) (fun (X2:fofType)=> (((eq fofType) (d_Inj1 X2)) X1))))) d_Unj))
% 0.43/0.61 FOF formula (forall (X0:fofType) (X1:fofType), (((eq fofType) (proj0 ((pair X0) X1))) X0)) of role axiom named proj0_pair_eq
% 0.43/0.61 A new axiom: (forall (X0:fofType) (X1:fofType), (((eq fofType) (proj0 ((pair X0) X1))) X0))
% 0.43/0.61 FOF formula (forall (X0:fofType) (X1:fofType), (((eq fofType) (_TPTP_proj1 ((pair X0) X1))) X1)) of role axiom named proj1_pair_eq
% 0.43/0.61 A new axiom: (forall (X0:fofType) (X1:fofType), (((eq fofType) (_TPTP_proj1 ((pair X0) X1))) X1))
% 0.43/0.61 FOF formula (<kernel.Constant object at 0x2abadd321e18>, <kernel.DependentProduct object at 0x2abadd3218c0>) of role type named typ_d_Sigma
% 0.43/0.61 Using role type
% 0.43/0.61 Declaring d_Sigma:(fofType->((fofType->fofType)->fofType))
% 0.43/0.61 FOF formula (((eq (fofType->((fofType->fofType)->fofType))) d_Sigma) (fun (X0:fofType) (X1:(fofType->fofType))=> ((famunion X0) (fun (X2:fofType)=> ((repl (X1 X2)) (pair X2)))))) of role definition named def_d_Sigma
% 0.43/0.61 A new definition: (((eq (fofType->((fofType->fofType)->fofType))) d_Sigma) (fun (X0:fofType) (X1:(fofType->fofType))=> ((famunion X0) (fun (X2:fofType)=> ((repl (X1 X2)) (pair X2))))))
% 0.43/0.61 Defined: d_Sigma:=(fun (X0:fofType) (X1:(fofType->fofType))=> ((famunion X0) (fun (X2:fofType)=> ((repl (X1 X2)) (pair X2)))))
% 0.43/0.61 FOF formula (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) X0)->(forall (X3:fofType), (((in X3) (X1 X2))->((in ((pair X2) X3)) ((d_Sigma X0) X1)))))) of role axiom named pair_Sigma
% 0.43/0.61 A new axiom: (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) X0)->(forall (X3:fofType), (((in X3) (X1 X2))->((in ((pair X2) X3)) ((d_Sigma X0) X1))))))
% 0.43/0.61 FOF formula (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((and ((and (((eq fofType) ((pair (proj0 X2)) (_TPTP_proj1 X2))) X2)) ((in (proj0 X2)) X0))) ((in (_TPTP_proj1 X2)) (X1 (proj0 X2)))))) of role axiom named k_Sigma_eta_proj0_proj1
% 0.43/0.61 A new axiom: (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((and ((and (((eq fofType) ((pair (proj0 X2)) (_TPTP_proj1 X2))) X2)) ((in (proj0 X2)) X0))) ((in (_TPTP_proj1 X2)) (X1 (proj0 X2))))))
% 0.43/0.61 FOF formula (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->(((eq fofType) ((pair (proj0 X2)) (_TPTP_proj1 X2))) X2))) of role axiom named proj_Sigma_eta
% 0.43/0.63 A new axiom: (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->(((eq fofType) ((pair (proj0 X2)) (_TPTP_proj1 X2))) X2)))
% 0.43/0.63 FOF formula (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((in (proj0 X2)) X0))) of role axiom named proj0_Sigma
% 0.43/0.63 A new axiom: (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((in (proj0 X2)) X0)))
% 0.43/0.63 FOF formula (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((in (_TPTP_proj1 X2)) (X1 (proj0 X2))))) of role axiom named proj1_Sigma
% 0.43/0.63 A new axiom: (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((in (_TPTP_proj1 X2)) (X1 (proj0 X2)))))
% 0.43/0.63 FOF formula (<kernel.Constant object at 0x2abadd321290>, <kernel.DependentProduct object at 0x2abadd321e18>) of role type named typ_setprod
% 0.43/0.63 Using role type
% 0.43/0.63 Declaring setprod:(fofType->(fofType->fofType))
% 0.43/0.63 FOF formula (((eq (fofType->(fofType->fofType))) setprod) (fun (X0:fofType) (X1:fofType)=> ((d_Sigma X0) (fun (X2:fofType)=> X1)))) of role definition named def_setprod
% 0.43/0.63 A new definition: (((eq (fofType->(fofType->fofType))) setprod) (fun (X0:fofType) (X1:fofType)=> ((d_Sigma X0) (fun (X2:fofType)=> X1))))
% 0.43/0.63 Defined: setprod:=(fun (X0:fofType) (X1:fofType)=> ((d_Sigma X0) (fun (X2:fofType)=> X1)))
% 0.43/0.63 FOF formula (<kernel.Constant object at 0x2abadd321e18>, <kernel.DependentProduct object at 0x2abadd321cb0>) of role type named typ_ap
% 0.43/0.63 Using role type
% 0.43/0.63 Declaring ap:(fofType->(fofType->fofType))
% 0.43/0.63 FOF formula (((eq (fofType->(fofType->fofType))) ap) (fun (X0:fofType) (X1:fofType)=> (((d_ReplSep X0) (fun (X2:fofType)=> ((ex fofType) (fun (X3:fofType)=> (((eq fofType) X2) ((pair X1) X3)))))) _TPTP_proj1))) of role definition named def_ap
% 0.43/0.63 A new definition: (((eq (fofType->(fofType->fofType))) ap) (fun (X0:fofType) (X1:fofType)=> (((d_ReplSep X0) (fun (X2:fofType)=> ((ex fofType) (fun (X3:fofType)=> (((eq fofType) X2) ((pair X1) X3)))))) _TPTP_proj1)))
% 0.43/0.63 Defined: ap:=(fun (X0:fofType) (X1:fofType)=> (((d_ReplSep X0) (fun (X2:fofType)=> ((ex fofType) (fun (X3:fofType)=> (((eq fofType) X2) ((pair X1) X3)))))) _TPTP_proj1))
% 0.43/0.63 FOF formula (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) X0)->(((eq fofType) ((ap ((d_Sigma X0) X1)) X2)) (X1 X2)))) of role axiom named beta
% 0.43/0.63 A new axiom: (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) X0)->(((eq fofType) ((ap ((d_Sigma X0) X1)) X2)) (X1 X2))))
% 0.43/0.63 FOF formula (<kernel.Constant object at 0x2abadd321ea8>, <kernel.DependentProduct object at 0x2abadd321440>) of role type named typ_pair_p
% 0.43/0.63 Using role type
% 0.43/0.63 Declaring pair_p:(fofType->Prop)
% 0.43/0.63 FOF formula (((eq (fofType->Prop)) pair_p) (fun (X0:fofType)=> (((eq fofType) ((pair ((ap X0) emptyset)) ((ap X0) (ordsucc emptyset)))) X0))) of role definition named def_pair_p
% 0.43/0.63 A new definition: (((eq (fofType->Prop)) pair_p) (fun (X0:fofType)=> (((eq fofType) ((pair ((ap X0) emptyset)) ((ap X0) (ordsucc emptyset)))) X0)))
% 0.43/0.63 Defined: pair_p:=(fun (X0:fofType)=> (((eq fofType) ((pair ((ap X0) emptyset)) ((ap X0) (ordsucc emptyset)))) X0))
% 0.43/0.63 FOF formula (<kernel.Constant object at 0x2abadd321290>, <kernel.DependentProduct object at 0x2abadd321cb0>) of role type named typ_d_Pi
% 0.43/0.63 Using role type
% 0.43/0.63 Declaring d_Pi:(fofType->((fofType->fofType)->fofType))
% 0.43/0.63 FOF formula (((eq (fofType->((fofType->fofType)->fofType))) d_Pi) (fun (X0:fofType) (X1:(fofType->fofType))=> ((d_Sep (power ((d_Sigma X0) (fun (X2:fofType)=> (union (X1 X2)))))) (fun (X2:fofType)=> (forall (X3:fofType), (((in X3) X0)->((in ((ap X2) X3)) (X1 X3)))))))) of role definition named def_d_Pi
% 0.43/0.63 A new definition: (((eq (fofType->((fofType->fofType)->fofType))) d_Pi) (fun (X0:fofType) (X1:(fofType->fofType))=> ((d_Sep (power ((d_Sigma X0) (fun (X2:fofType)=> (union (X1 X2)))))) (fun (X2:fofType)=> (forall (X3:fofType), (((in X3) X0)->((in ((ap X2) X3)) (X1 X3))))))))
% 0.43/0.63 Defined: d_Pi:=(fun (X0:fofType) (X1:(fofType->fofType))=> ((d_Sep (power ((d_Sigma X0) (fun (X2:fofType)=> (union (X1 X2)))))) (fun (X2:fofType)=> (forall (X3:fofType), (((in X3) X0)->((in ((ap X2) X3)) (X1 X3)))))))
% 0.43/0.65 FOF formula (forall (X0:fofType) (X1:(fofType->fofType)) (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X0)->((in (X2 X3)) (X1 X3))))->((in ((d_Sigma X0) X2)) ((d_Pi X0) X1)))) of role axiom named lam_Pi
% 0.43/0.65 A new axiom: (forall (X0:fofType) (X1:(fofType->fofType)) (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X0)->((in (X2 X3)) (X1 X3))))->((in ((d_Sigma X0) X2)) ((d_Pi X0) X1))))
% 0.43/0.65 FOF formula (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType) (X3:fofType), (((in X2) ((d_Pi X0) X1))->(((in X3) X0)->((in ((ap X2) X3)) (X1 X3))))) of role axiom named ap_Pi
% 0.43/0.65 A new axiom: (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType) (X3:fofType), (((in X2) ((d_Pi X0) X1))->(((in X3) X0)->((in ((ap X2) X3)) (X1 X3)))))
% 0.43/0.65 FOF formula (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Pi X0) X1))->(forall (X3:fofType), (((in X3) ((d_Pi X0) X1))->((forall (X4:fofType), (((in X4) X0)->(((eq fofType) ((ap X2) X4)) ((ap X3) X4))))->(((eq fofType) X2) X3)))))) of role axiom named k_Pi_ext
% 0.43/0.65 A new axiom: (forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Pi X0) X1))->(forall (X3:fofType), (((in X3) ((d_Pi X0) X1))->((forall (X4:fofType), (((in X4) X0)->(((eq fofType) ((ap X2) X4)) ((ap X3) X4))))->(((eq fofType) X2) X3))))))
% 0.43/0.65 FOF formula (forall (X0:fofType) (X1:(fofType->fofType)) (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X0)->(((eq fofType) (X1 X3)) (X2 X3))))->(((eq fofType) ((d_Sigma X0) X1)) ((d_Sigma X0) X2)))) of role axiom named xi_ext
% 0.43/0.65 A new axiom: (forall (X0:fofType) (X1:(fofType->fofType)) (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X0)->(((eq fofType) (X1 X3)) (X2 X3))))->(((eq fofType) ((d_Sigma X0) X1)) ((d_Sigma X0) X2))))
% 0.43/0.65 FOF formula (forall (X0:Prop) (X1:fofType) (X2:fofType), ((X0->((in X1) X2))->((in (((if X0) X1) emptyset)) (((if X0) X2) (ordsucc emptyset))))) of role axiom named k_If_In_01
% 0.43/0.65 A new axiom: (forall (X0:Prop) (X1:fofType) (X2:fofType), ((X0->((in X1) X2))->((in (((if X0) X1) emptyset)) (((if X0) X2) (ordsucc emptyset)))))
% 0.43/0.65 FOF formula (forall (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType), (X0->(((in X1) (((if X0) X2) X3))->((in X1) X2)))) of role axiom named k_If_In_then_E
% 0.43/0.65 A new axiom: (forall (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType), (X0->(((in X1) (((if X0) X2) X3))->((in X1) X2))))
% 0.43/0.65 FOF formula (<kernel.Constant object at 0x2abadd321290>, <kernel.DependentProduct object at 0x2abae097d440>) of role type named typ_imp
% 0.43/0.65 Using role type
% 0.43/0.65 Declaring imp:(Prop->(Prop->Prop))
% 0.43/0.65 FOF formula (((eq (Prop->(Prop->Prop))) imp) (fun (X0:Prop) (X1:Prop)=> (X0->X1))) of role definition named def_imp
% 0.43/0.65 A new definition: (((eq (Prop->(Prop->Prop))) imp) (fun (X0:Prop) (X1:Prop)=> (X0->X1)))
% 0.43/0.65 Defined: imp:=(fun (X0:Prop) (X1:Prop)=> (X0->X1))
% 0.43/0.65 FOF formula (<kernel.Constant object at 0x2abae097d440>, <kernel.DependentProduct object at 0x2abae097d4d0>) of role type named typ_d_not
% 0.43/0.65 Using role type
% 0.43/0.65 Declaring d_not:(Prop->Prop)
% 0.43/0.65 FOF formula (((eq (Prop->Prop)) d_not) (fun (X0:Prop)=> ((imp X0) False))) of role definition named def_d_not
% 0.43/0.65 A new definition: (((eq (Prop->Prop)) d_not) (fun (X0:Prop)=> ((imp X0) False)))
% 0.43/0.65 Defined: d_not:=(fun (X0:Prop)=> ((imp X0) False))
% 0.43/0.65 FOF formula (<kernel.Constant object at 0x2abae097d4d0>, <kernel.DependentProduct object at 0x2abae097d7e8>) of role type named typ_wel
% 0.43/0.65 Using role type
% 0.43/0.65 Declaring wel:(Prop->Prop)
% 0.43/0.65 FOF formula (((eq (Prop->Prop)) wel) (fun (X0:Prop)=> (d_not (d_not X0)))) of role definition named def_wel
% 0.43/0.65 A new definition: (((eq (Prop->Prop)) wel) (fun (X0:Prop)=> (d_not (d_not X0))))
% 0.43/0.65 Defined: wel:=(fun (X0:Prop)=> (d_not (d_not X0)))
% 0.43/0.65 FOF formula (forall (X0:Prop), ((wel X0)->X0)) of role axiom named l_et
% 0.43/0.65 A new axiom: (forall (X0:Prop), ((wel X0)->X0))
% 0.43/0.65 FOF formula (<kernel.Constant object at 0x2abae097d128>, <kernel.Sort object at 0x2abadd6508c0>) of role type named typ_obvious
% 0.43/0.65 Using role type
% 0.43/0.65 Declaring obvious:Prop
% 0.43/0.65 FOF formula (((eq Prop) obvious) ((imp False) False)) of role definition named def_obvious
% 0.43/0.65 A new definition: (((eq Prop) obvious) ((imp False) False))
% 0.43/0.67 Defined: obvious:=((imp False) False)
% 0.43/0.67 FOF formula (<kernel.Constant object at 0x2abae097d320>, <kernel.DependentProduct object at 0x2abae097d050>) of role type named typ_l_ec
% 0.43/0.67 Using role type
% 0.43/0.67 Declaring l_ec:(Prop->(Prop->Prop))
% 0.43/0.67 FOF formula (((eq (Prop->(Prop->Prop))) l_ec) (fun (X0:Prop) (X1:Prop)=> ((imp X0) (d_not X1)))) of role definition named def_l_ec
% 0.43/0.67 A new definition: (((eq (Prop->(Prop->Prop))) l_ec) (fun (X0:Prop) (X1:Prop)=> ((imp X0) (d_not X1))))
% 0.43/0.67 Defined: l_ec:=(fun (X0:Prop) (X1:Prop)=> ((imp X0) (d_not X1)))
% 0.43/0.67 FOF formula (<kernel.Constant object at 0x2abae097d050>, <kernel.DependentProduct object at 0x2abae097d128>) of role type named typ_d_and
% 0.43/0.67 Using role type
% 0.43/0.67 Declaring d_and:(Prop->(Prop->Prop))
% 0.43/0.67 FOF formula (((eq (Prop->(Prop->Prop))) d_and) (fun (X0:Prop) (X1:Prop)=> (d_not ((l_ec X0) X1)))) of role definition named def_d_and
% 0.43/0.67 A new definition: (((eq (Prop->(Prop->Prop))) d_and) (fun (X0:Prop) (X1:Prop)=> (d_not ((l_ec X0) X1))))
% 0.43/0.67 Defined: d_and:=(fun (X0:Prop) (X1:Prop)=> (d_not ((l_ec X0) X1)))
% 0.43/0.67 FOF formula (<kernel.Constant object at 0x2abae097d128>, <kernel.DependentProduct object at 0x2abae097d320>) of role type named typ_l_or
% 0.43/0.67 Using role type
% 0.43/0.67 Declaring l_or:(Prop->(Prop->Prop))
% 0.43/0.67 FOF formula (((eq (Prop->(Prop->Prop))) l_or) (fun (X0:Prop)=> (imp (d_not X0)))) of role definition named def_l_or
% 0.43/0.67 A new definition: (((eq (Prop->(Prop->Prop))) l_or) (fun (X0:Prop)=> (imp (d_not X0))))
% 0.43/0.67 Defined: l_or:=(fun (X0:Prop)=> (imp (d_not X0)))
% 0.43/0.67 FOF formula (<kernel.Constant object at 0x2abae097d320>, <kernel.DependentProduct object at 0x2abae097d6c8>) of role type named typ_orec
% 0.43/0.67 Using role type
% 0.43/0.67 Declaring orec:(Prop->(Prop->Prop))
% 0.43/0.67 FOF formula (((eq (Prop->(Prop->Prop))) orec) (fun (X0:Prop) (X1:Prop)=> ((d_and ((l_or X0) X1)) ((l_ec X0) X1)))) of role definition named def_orec
% 0.43/0.67 A new definition: (((eq (Prop->(Prop->Prop))) orec) (fun (X0:Prop) (X1:Prop)=> ((d_and ((l_or X0) X1)) ((l_ec X0) X1))))
% 0.43/0.67 Defined: orec:=(fun (X0:Prop) (X1:Prop)=> ((d_and ((l_or X0) X1)) ((l_ec X0) X1)))
% 0.43/0.67 FOF formula (<kernel.Constant object at 0x2abae097d6c8>, <kernel.DependentProduct object at 0x2abae097d128>) of role type named typ_l_iff
% 0.43/0.67 Using role type
% 0.43/0.67 Declaring l_iff:(Prop->(Prop->Prop))
% 0.43/0.67 FOF formula (((eq (Prop->(Prop->Prop))) l_iff) (fun (X0:Prop) (X1:Prop)=> ((d_and ((imp X0) X1)) ((imp X1) X0)))) of role definition named def_l_iff
% 0.43/0.67 A new definition: (((eq (Prop->(Prop->Prop))) l_iff) (fun (X0:Prop) (X1:Prop)=> ((d_and ((imp X0) X1)) ((imp X1) X0))))
% 0.43/0.67 Defined: l_iff:=(fun (X0:Prop) (X1:Prop)=> ((d_and ((imp X0) X1)) ((imp X1) X0)))
% 0.43/0.67 FOF formula (<kernel.Constant object at 0x2abae097d128>, <kernel.DependentProduct object at 0x2abae097d878>) of role type named typ_all
% 0.43/0.67 Using role type
% 0.43/0.67 Declaring all:(fofType->((fofType->Prop)->Prop))
% 0.43/0.67 FOF formula (((eq (fofType->((fofType->Prop)->Prop))) all) (fun (X0:fofType)=> (all_of (fun (X1:fofType)=> ((in X1) X0))))) of role definition named def_all
% 0.43/0.67 A new definition: (((eq (fofType->((fofType->Prop)->Prop))) all) (fun (X0:fofType)=> (all_of (fun (X1:fofType)=> ((in X1) X0)))))
% 0.43/0.67 Defined: all:=(fun (X0:fofType)=> (all_of (fun (X1:fofType)=> ((in X1) X0))))
% 0.43/0.67 FOF formula (<kernel.Constant object at 0x2abae097d878>, <kernel.DependentProduct object at 0x2abae097dc68>) of role type named typ_non
% 0.43/0.67 Using role type
% 0.43/0.67 Declaring non:(fofType->((fofType->Prop)->(fofType->Prop)))
% 0.43/0.67 FOF formula (((eq (fofType->((fofType->Prop)->(fofType->Prop)))) non) (fun (X0:fofType) (X1:(fofType->Prop)) (X2:fofType)=> (d_not (X1 X2)))) of role definition named def_non
% 0.43/0.67 A new definition: (((eq (fofType->((fofType->Prop)->(fofType->Prop)))) non) (fun (X0:fofType) (X1:(fofType->Prop)) (X2:fofType)=> (d_not (X1 X2))))
% 0.43/0.67 Defined: non:=(fun (X0:fofType) (X1:(fofType->Prop)) (X2:fofType)=> (d_not (X1 X2)))
% 0.43/0.67 FOF formula (<kernel.Constant object at 0x2abae097dc68>, <kernel.DependentProduct object at 0x2abae097d680>) of role type named typ_l_some
% 0.43/0.67 Using role type
% 0.43/0.67 Declaring l_some:(fofType->((fofType->Prop)->Prop))
% 0.43/0.67 FOF formula (((eq (fofType->((fofType->Prop)->Prop))) l_some) (fun (X0:fofType) (X1:(fofType->Prop))=> (d_not ((all_of (fun (X2:fofType)=> ((in X2) X0))) ((non X0) X1))))) of role definition named def_l_some
% 0.43/0.68 A new definition: (((eq (fofType->((fofType->Prop)->Prop))) l_some) (fun (X0:fofType) (X1:(fofType->Prop))=> (d_not ((all_of (fun (X2:fofType)=> ((in X2) X0))) ((non X0) X1)))))
% 0.43/0.68 Defined: l_some:=(fun (X0:fofType) (X1:(fofType->Prop))=> (d_not ((all_of (fun (X2:fofType)=> ((in X2) X0))) ((non X0) X1))))
% 0.43/0.68 FOF formula (<kernel.Constant object at 0x2abae097d680>, <kernel.DependentProduct object at 0x2abae097dcb0>) of role type named typ_or3
% 0.43/0.68 Using role type
% 0.43/0.68 Declaring or3:(Prop->(Prop->(Prop->Prop)))
% 0.43/0.68 FOF formula (((eq (Prop->(Prop->(Prop->Prop)))) or3) (fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((l_or X0) ((l_or X1) X2)))) of role definition named def_or3
% 0.43/0.68 A new definition: (((eq (Prop->(Prop->(Prop->Prop)))) or3) (fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((l_or X0) ((l_or X1) X2))))
% 0.43/0.68 Defined: or3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((l_or X0) ((l_or X1) X2)))
% 0.43/0.68 FOF formula (<kernel.Constant object at 0x2abae097dcb0>, <kernel.DependentProduct object at 0x2abae097da70>) of role type named typ_and3
% 0.43/0.68 Using role type
% 0.43/0.68 Declaring and3:(Prop->(Prop->(Prop->Prop)))
% 0.43/0.68 FOF formula (((eq (Prop->(Prop->(Prop->Prop)))) and3) (fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((d_and X0) ((d_and X1) X2)))) of role definition named def_and3
% 0.43/0.68 A new definition: (((eq (Prop->(Prop->(Prop->Prop)))) and3) (fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((d_and X0) ((d_and X1) X2))))
% 0.43/0.68 Defined: and3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((d_and X0) ((d_and X1) X2)))
% 0.43/0.68 FOF formula (<kernel.Constant object at 0x2abae097da70>, <kernel.DependentProduct object at 0x2abae097dcf8>) of role type named typ_ec3
% 0.43/0.68 Using role type
% 0.43/0.68 Declaring ec3:(Prop->(Prop->(Prop->Prop)))
% 0.43/0.68 FOF formula (((eq (Prop->(Prop->(Prop->Prop)))) ec3) (fun (X0:Prop) (X1:Prop) (X2:Prop)=> (((and3 ((l_ec X0) X1)) ((l_ec X1) X2)) ((l_ec X2) X0)))) of role definition named def_ec3
% 0.43/0.68 A new definition: (((eq (Prop->(Prop->(Prop->Prop)))) ec3) (fun (X0:Prop) (X1:Prop) (X2:Prop)=> (((and3 ((l_ec X0) X1)) ((l_ec X1) X2)) ((l_ec X2) X0))))
% 0.43/0.68 Defined: ec3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> (((and3 ((l_ec X0) X1)) ((l_ec X1) X2)) ((l_ec X2) X0)))
% 0.43/0.68 FOF formula (<kernel.Constant object at 0x2abae097dcf8>, <kernel.DependentProduct object at 0x2abae097dd40>) of role type named typ_orec3
% 0.43/0.68 Using role type
% 0.43/0.68 Declaring orec3:(Prop->(Prop->(Prop->Prop)))
% 0.43/0.68 FOF formula (((eq (Prop->(Prop->(Prop->Prop)))) orec3) (fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((d_and (((or3 X0) X1) X2)) (((ec3 X0) X1) X2)))) of role definition named def_orec3
% 0.43/0.68 A new definition: (((eq (Prop->(Prop->(Prop->Prop)))) orec3) (fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((d_and (((or3 X0) X1) X2)) (((ec3 X0) X1) X2))))
% 0.43/0.68 Defined: orec3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((d_and (((or3 X0) X1) X2)) (((ec3 X0) X1) X2)))
% 0.43/0.68 FOF formula (<kernel.Constant object at 0x2abae097dd40>, <kernel.DependentProduct object at 0x2abae097dcb0>) of role type named typ_e_is
% 0.43/0.68 Using role type
% 0.43/0.68 Declaring e_is:(fofType->(fofType->(fofType->Prop)))
% 0.43/0.68 FOF formula (((eq (fofType->(fofType->(fofType->Prop)))) e_is) (fun (X0:fofType) (X:fofType) (Y:fofType)=> (((eq fofType) X) Y))) of role definition named def_e_is
% 0.43/0.68 A new definition: (((eq (fofType->(fofType->(fofType->Prop)))) e_is) (fun (X0:fofType) (X:fofType) (Y:fofType)=> (((eq fofType) X) Y)))
% 0.43/0.68 Defined: e_is:=(fun (X0:fofType) (X:fofType) (Y:fofType)=> (((eq fofType) X) Y))
% 0.43/0.68 FOF formula (forall (X0:fofType), ((all_of (fun (X1:fofType)=> ((in X1) X0))) (fun (X1:fofType)=> (((e_is X0) X1) X1)))) of role axiom named refis
% 0.43/0.68 A new axiom: (forall (X0:fofType), ((all_of (fun (X1:fofType)=> ((in X1) X0))) (fun (X1:fofType)=> (((e_is X0) X1) X1))))
% 0.43/0.68 FOF formula (forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X0))) (fun (X3:fofType)=> ((X1 X2)->((((e_is X0) X2) X3)->(X1 X3)))))))) of role axiom named e_isp
% 0.43/0.68 A new axiom: (forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X0))) (fun (X3:fofType)=> ((X1 X2)->((((e_is X0) X2) X3)->(X1 X3))))))))
% 0.50/0.70 FOF formula (<kernel.Constant object at 0x2abae097dcf8>, <kernel.DependentProduct object at 0x2abae097d6c8>) of role type named typ_amone
% 0.50/0.70 Using role type
% 0.50/0.70 Declaring amone:(fofType->((fofType->Prop)->Prop))
% 0.50/0.70 FOF formula (((eq (fofType->((fofType->Prop)->Prop))) amone) (fun (X0:fofType) (X1:(fofType->Prop))=> ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X0))) (fun (X3:fofType)=> ((X1 X2)->((X1 X3)->(((e_is X0) X2) X3))))))))) of role definition named def_amone
% 0.50/0.70 A new definition: (((eq (fofType->((fofType->Prop)->Prop))) amone) (fun (X0:fofType) (X1:(fofType->Prop))=> ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X0))) (fun (X3:fofType)=> ((X1 X2)->((X1 X3)->(((e_is X0) X2) X3)))))))))
% 0.50/0.70 Defined: amone:=(fun (X0:fofType) (X1:(fofType->Prop))=> ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X0))) (fun (X3:fofType)=> ((X1 X2)->((X1 X3)->(((e_is X0) X2) X3))))))))
% 0.50/0.70 FOF formula (<kernel.Constant object at 0x2abae097d6c8>, <kernel.DependentProduct object at 0x2abae097df80>) of role type named typ_one
% 0.50/0.70 Using role type
% 0.50/0.70 Declaring one:(fofType->((fofType->Prop)->Prop))
% 0.50/0.70 FOF formula (((eq (fofType->((fofType->Prop)->Prop))) one) (fun (X0:fofType) (X1:(fofType->Prop))=> ((d_and ((amone X0) X1)) ((l_some X0) X1)))) of role definition named def_one
% 0.50/0.70 A new definition: (((eq (fofType->((fofType->Prop)->Prop))) one) (fun (X0:fofType) (X1:(fofType->Prop))=> ((d_and ((amone X0) X1)) ((l_some X0) X1))))
% 0.50/0.70 Defined: one:=(fun (X0:fofType) (X1:(fofType->Prop))=> ((d_and ((amone X0) X1)) ((l_some X0) X1)))
% 0.50/0.70 FOF formula (<kernel.Constant object at 0x2abae097df80>, <kernel.DependentProduct object at 0x2abae097dd88>) of role type named typ_ind
% 0.50/0.70 Using role type
% 0.50/0.70 Declaring ind:(fofType->((fofType->Prop)->fofType))
% 0.50/0.70 FOF formula (((eq (fofType->((fofType->Prop)->fofType))) ind) (fun (X0:fofType) (X1:(fofType->Prop))=> (eps (fun (X2:fofType)=> ((and ((in X2) X0)) (X1 X2)))))) of role definition named def_ind
% 0.50/0.70 A new definition: (((eq (fofType->((fofType->Prop)->fofType))) ind) (fun (X0:fofType) (X1:(fofType->Prop))=> (eps (fun (X2:fofType)=> ((and ((in X2) X0)) (X1 X2))))))
% 0.50/0.70 Defined: ind:=(fun (X0:fofType) (X1:(fofType->Prop))=> (eps (fun (X2:fofType)=> ((and ((in X2) X0)) (X1 X2)))))
% 0.50/0.70 FOF formula (forall (X0:fofType) (X1:(fofType->Prop)), (((one X0) X1)->((is_of ((ind X0) X1)) (fun (X2:fofType)=> ((in X2) X0))))) of role axiom named ind_p
% 0.50/0.70 A new axiom: (forall (X0:fofType) (X1:(fofType->Prop)), (((one X0) X1)->((is_of ((ind X0) X1)) (fun (X2:fofType)=> ((in X2) X0)))))
% 0.50/0.70 FOF formula (forall (X0:fofType) (X1:(fofType->Prop)), (((one X0) X1)->(X1 ((ind X0) X1)))) of role axiom named oneax
% 0.50/0.70 A new axiom: (forall (X0:fofType) (X1:(fofType->Prop)), (((one X0) X1)->(X1 ((ind X0) X1))))
% 0.50/0.70 FOF formula (<kernel.Constant object at 0x2abae097dcf8>, <kernel.DependentProduct object at 0x2abae097dfc8>) of role type named typ_injective
% 0.50/0.70 Using role type
% 0.50/0.70 Declaring injective:(fofType->(fofType->(fofType->Prop)))
% 0.50/0.70 FOF formula (((eq (fofType->(fofType->(fofType->Prop)))) injective) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((all X0) (fun (X4:fofType)=> ((imp (((e_is X1) ((ap X2) X3)) ((ap X2) X4))) (((e_is X0) X3) X4)))))))) of role definition named def_injective
% 0.50/0.70 A new definition: (((eq (fofType->(fofType->(fofType->Prop)))) injective) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((all X0) (fun (X4:fofType)=> ((imp (((e_is X1) ((ap X2) X3)) ((ap X2) X4))) (((e_is X0) X3) X4))))))))
% 0.50/0.70 Defined: injective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((all X0) (fun (X4:fofType)=> ((imp (((e_is X1) ((ap X2) X3)) ((ap X2) X4))) (((e_is X0) X3) X4)))))))
% 0.50/0.70 FOF formula (<kernel.Constant object at 0x2abae097dd88>, <kernel.DependentProduct object at 0x2abae097d560>) of role type named typ_image
% 0.50/0.70 Using role type
% 0.50/0.70 Declaring image:(fofType->(fofType->(fofType->(fofType->Prop))))
% 0.50/0.70 FOF formula (((eq (fofType->(fofType->(fofType->(fofType->Prop))))) image) (fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((l_some X0) (fun (X4:fofType)=> (((e_is X1) X3) ((ap X2) X4)))))) of role definition named def_image
% 0.50/0.71 A new definition: (((eq (fofType->(fofType->(fofType->(fofType->Prop))))) image) (fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((l_some X0) (fun (X4:fofType)=> (((e_is X1) X3) ((ap X2) X4))))))
% 0.50/0.71 Defined: image:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((l_some X0) (fun (X4:fofType)=> (((e_is X1) X3) ((ap X2) X4)))))
% 0.50/0.71 FOF formula (<kernel.Constant object at 0x2abae097dcf8>, <kernel.DependentProduct object at 0x2abae0983050>) of role type named typ_tofs
% 0.50/0.71 Using role type
% 0.50/0.71 Declaring tofs:(fofType->(fofType->(fofType->(fofType->fofType))))
% 0.50/0.71 FOF formula (((eq (fofType->(fofType->(fofType->(fofType->fofType))))) tofs) (fun (X0:fofType) (X1:fofType)=> ap)) of role definition named def_tofs
% 0.50/0.71 A new definition: (((eq (fofType->(fofType->(fofType->(fofType->fofType))))) tofs) (fun (X0:fofType) (X1:fofType)=> ap))
% 0.50/0.71 Defined: tofs:=(fun (X0:fofType) (X1:fofType)=> ap)
% 0.50/0.71 FOF formula (<kernel.Constant object at 0x2abae097dd88>, <kernel.DependentProduct object at 0x2abae0983290>) of role type named typ_soft
% 0.50/0.71 Using role type
% 0.50/0.71 Declaring soft:(fofType->(fofType->(fofType->(fofType->fofType))))
% 0.50/0.71 FOF formula (((eq (fofType->(fofType->(fofType->(fofType->fofType))))) soft) (fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((ind X0) (fun (X4:fofType)=> (((e_is X1) X3) ((ap X2) X4)))))) of role definition named def_soft
% 0.50/0.71 A new definition: (((eq (fofType->(fofType->(fofType->(fofType->fofType))))) soft) (fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((ind X0) (fun (X4:fofType)=> (((e_is X1) X3) ((ap X2) X4))))))
% 0.50/0.71 Defined: soft:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((ind X0) (fun (X4:fofType)=> (((e_is X1) X3) ((ap X2) X4)))))
% 0.50/0.71 FOF formula (<kernel.Constant object at 0x2abae097dd88>, <kernel.DependentProduct object at 0x2abae0983290>) of role type named typ_inverse
% 0.50/0.71 Using role type
% 0.50/0.71 Declaring inverse:(fofType->(fofType->(fofType->fofType)))
% 0.50/0.71 FOF formula (((eq (fofType->(fofType->(fofType->fofType)))) inverse) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X1) (fun (X3:fofType)=> (((if ((((image X0) X1) X2) X3)) ((((soft X0) X1) X2) X3)) emptyset))))) of role definition named def_inverse
% 0.50/0.71 A new definition: (((eq (fofType->(fofType->(fofType->fofType)))) inverse) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X1) (fun (X3:fofType)=> (((if ((((image X0) X1) X2) X3)) ((((soft X0) X1) X2) X3)) emptyset)))))
% 0.50/0.71 Defined: inverse:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X1) (fun (X3:fofType)=> (((if ((((image X0) X1) X2) X3)) ((((soft X0) X1) X2) X3)) emptyset))))
% 0.50/0.71 FOF formula (<kernel.Constant object at 0x2abae097dd88>, <kernel.DependentProduct object at 0x2abae09837e8>) of role type named typ_surjective
% 0.50/0.71 Using role type
% 0.50/0.71 Declaring surjective:(fofType->(fofType->(fofType->Prop)))
% 0.50/0.71 FOF formula (((eq (fofType->(fofType->(fofType->Prop)))) surjective) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X1) (((image X0) X1) X2)))) of role definition named def_surjective
% 0.50/0.71 A new definition: (((eq (fofType->(fofType->(fofType->Prop)))) surjective) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X1) (((image X0) X1) X2))))
% 0.50/0.71 Defined: surjective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X1) (((image X0) X1) X2)))
% 0.50/0.71 FOF formula (<kernel.Constant object at 0x2abae09837e8>, <kernel.DependentProduct object at 0x2abae09833b0>) of role type named typ_bijective
% 0.50/0.71 Using role type
% 0.50/0.71 Declaring bijective:(fofType->(fofType->(fofType->Prop)))
% 0.50/0.71 FOF formula (((eq (fofType->(fofType->(fofType->Prop)))) bijective) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_and (((injective X0) X1) X2)) (((surjective X0) X1) X2)))) of role definition named def_bijective
% 0.50/0.71 A new definition: (((eq (fofType->(fofType->(fofType->Prop)))) bijective) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_and (((injective X0) X1) X2)) (((surjective X0) X1) X2))))
% 0.50/0.71 Defined: bijective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_and (((injective X0) X1) X2)) (((surjective X0) X1) X2)))
% 0.50/0.73 FOF formula (<kernel.Constant object at 0x2abae09833b0>, <kernel.DependentProduct object at 0x2abae09833f8>) of role type named typ_invf
% 0.50/0.73 Using role type
% 0.50/0.73 Declaring invf:(fofType->(fofType->(fofType->fofType)))
% 0.50/0.73 FOF formula (((eq (fofType->(fofType->(fofType->fofType)))) invf) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X1) (((soft X0) X1) X2)))) of role definition named def_invf
% 0.50/0.73 A new definition: (((eq (fofType->(fofType->(fofType->fofType)))) invf) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X1) (((soft X0) X1) X2))))
% 0.50/0.73 Defined: invf:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X1) (((soft X0) X1) X2)))
% 0.50/0.73 FOF formula (<kernel.Constant object at 0x2abae09833f8>, <kernel.DependentProduct object at 0x2abae0983128>) of role type named typ_inj_h
% 0.50/0.73 Using role type
% 0.50/0.73 Declaring inj_h:(fofType->(fofType->(fofType->(fofType->(fofType->fofType)))))
% 0.50/0.73 FOF formula (((eq (fofType->(fofType->(fofType->(fofType->(fofType->fofType)))))) inj_h) (fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_Sigma X0) (fun (X5:fofType)=> ((ap X4) ((ap X3) X5)))))) of role definition named def_inj_h
% 0.50/0.74 A new definition: (((eq (fofType->(fofType->(fofType->(fofType->(fofType->fofType)))))) inj_h) (fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_Sigma X0) (fun (X5:fofType)=> ((ap X4) ((ap X3) X5))))))
% 0.50/0.74 Defined: inj_h:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_Sigma X0) (fun (X5:fofType)=> ((ap X4) ((ap X3) X5)))))
% 0.50/0.74 FOF formula (forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Pi X0) (fun (X3:fofType)=> X1))))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) ((d_Pi X0) (fun (X4:fofType)=> X1))))) (fun (X3:fofType)=> (((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> (((e_is X1) ((ap X2) X4)) ((ap X3) X4))))->(((e_is ((d_Pi X0) (fun (X4:fofType)=> X1))) X2) X3))))))) of role axiom named e_fisi
% 0.50/0.74 A new axiom: (forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Pi X0) (fun (X3:fofType)=> X1))))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) ((d_Pi X0) (fun (X4:fofType)=> X1))))) (fun (X3:fofType)=> (((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> (((e_is X1) ((ap X2) X4)) ((ap X3) X4))))->(((e_is ((d_Pi X0) (fun (X4:fofType)=> X1))) X2) X3)))))))
% 0.50/0.74 FOF formula (<kernel.Constant object at 0x2abae0983998>, <kernel.DependentProduct object at 0x2abae09831b8>) of role type named typ_e_in
% 0.50/0.74 Using role type
% 0.50/0.74 Declaring e_in:(fofType->((fofType->Prop)->(fofType->fofType)))
% 0.50/0.74 FOF formula (((eq (fofType->((fofType->Prop)->(fofType->fofType)))) e_in) (fun (X0:fofType) (X1:(fofType->Prop)) (X2:fofType)=> X2)) of role definition named def_e_in
% 0.50/0.74 A new definition: (((eq (fofType->((fofType->Prop)->(fofType->fofType)))) e_in) (fun (X0:fofType) (X1:(fofType->Prop)) (X2:fofType)=> X2))
% 0.50/0.74 Defined: e_in:=(fun (X0:fofType) (X1:(fofType->Prop)) (X2:fofType)=> X2)
% 0.50/0.74 FOF formula (forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Sep X0) X1)))) (fun (X2:fofType)=> ((is_of (((e_in X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X0)))))) of role axiom named e_in_p
% 0.50/0.74 A new axiom: (forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Sep X0) X1)))) (fun (X2:fofType)=> ((is_of (((e_in X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X0))))))
% 0.50/0.74 FOF formula (forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Sep X0) X1)))) (fun (X2:fofType)=> (X1 (((e_in X0) X1) X2))))) of role axiom named e_inp
% 0.50/0.74 A new axiom: (forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Sep X0) X1)))) (fun (X2:fofType)=> (X1 (((e_in X0) X1) X2)))))
% 0.50/0.74 FOF formula (forall (X0:fofType) (X1:(fofType->Prop)), (((injective ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1)))) of role axiom named otax1
% 0.50/0.74 A new axiom: (forall (X0:fofType) (X1:(fofType->Prop)), (((injective ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1))))
% 0.50/0.74 FOF formula (forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((X1 X2)->((((image ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1))) X2))))) of role axiom named otax2
% 0.50/0.75 A new axiom: (forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((X1 X2)->((((image ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1))) X2)))))
% 0.50/0.75 FOF formula (<kernel.Constant object at 0x2abae0983170>, <kernel.DependentProduct object at 0x2abae0983cf8>) of role type named typ_out
% 0.50/0.75 Using role type
% 0.50/0.75 Declaring out:(fofType->((fofType->Prop)->(fofType->fofType)))
% 0.50/0.75 FOF formula (((eq (fofType->((fofType->Prop)->(fofType->fofType)))) out) (fun (X0:fofType) (X1:(fofType->Prop))=> (((soft ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1))))) of role definition named def_out
% 0.50/0.75 A new definition: (((eq (fofType->((fofType->Prop)->(fofType->fofType)))) out) (fun (X0:fofType) (X1:(fofType->Prop))=> (((soft ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1)))))
% 0.50/0.75 Defined: out:=(fun (X0:fofType) (X1:(fofType->Prop))=> (((soft ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1))))
% 0.50/0.75 FOF formula (<kernel.Constant object at 0x2abae0983cf8>, <kernel.DependentProduct object at 0x2abae0983638>) of role type named typ_d_pair
% 0.50/0.75 Using role type
% 0.50/0.75 Declaring d_pair:(fofType->(fofType->(fofType->(fofType->fofType))))
% 0.50/0.75 FOF formula (((eq (fofType->(fofType->(fofType->(fofType->fofType))))) d_pair) (fun (X0:fofType) (X1:fofType)=> pair)) of role definition named def_d_pair
% 0.50/0.75 A new definition: (((eq (fofType->(fofType->(fofType->(fofType->fofType))))) d_pair) (fun (X0:fofType) (X1:fofType)=> pair))
% 0.50/0.75 Defined: d_pair:=(fun (X0:fofType) (X1:fofType)=> pair)
% 0.50/0.75 FOF formula (forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> ((is_of ((((d_pair X0) X1) X2) X3)) (fun (X4:fofType)=> ((in X4) ((setprod X0) X1))))))))) of role axiom named e_pair_p
% 0.50/0.75 A new axiom: (forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> ((is_of ((((d_pair X0) X1) X2) X3)) (fun (X4:fofType)=> ((in X4) ((setprod X0) X1)))))))))
% 0.50/0.75 FOF formula (<kernel.Constant object at 0x2abae09839e0>, <kernel.DependentProduct object at 0x2abae0983b48>) of role type named typ_first
% 0.50/0.75 Using role type
% 0.50/0.75 Declaring first:(fofType->(fofType->(fofType->fofType)))
% 0.50/0.75 FOF formula (((eq (fofType->(fofType->(fofType->fofType)))) first) (fun (X0:fofType) (X1:fofType)=> proj0)) of role definition named def_first
% 0.50/0.75 A new definition: (((eq (fofType->(fofType->(fofType->fofType)))) first) (fun (X0:fofType) (X1:fofType)=> proj0))
% 0.50/0.75 Defined: first:=(fun (X0:fofType) (X1:fofType)=> proj0)
% 0.50/0.75 FOF formula (forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> ((is_of (((first X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X0)))))) of role axiom named first_p
% 0.50/0.75 A new axiom: (forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> ((is_of (((first X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X0))))))
% 0.50/0.75 FOF formula (<kernel.Constant object at 0x2abae09832d8>, <kernel.DependentProduct object at 0x2abae0983a28>) of role type named typ_second
% 0.50/0.75 Using role type
% 0.50/0.75 Declaring second:(fofType->(fofType->(fofType->fofType)))
% 0.50/0.75 FOF formula (((eq (fofType->(fofType->(fofType->fofType)))) second) (fun (X0:fofType) (X1:fofType)=> _TPTP_proj1)) of role definition named def_second
% 0.50/0.75 A new definition: (((eq (fofType->(fofType->(fofType->fofType)))) second) (fun (X0:fofType) (X1:fofType)=> _TPTP_proj1))
% 0.50/0.75 Defined: second:=(fun (X0:fofType) (X1:fofType)=> _TPTP_proj1)
% 0.50/0.75 FOF formula (forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> ((is_of (((second X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X1)))))) of role axiom named second_p
% 0.50/0.75 A new axiom: (forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> ((is_of (((second X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X1))))))
% 0.58/0.77 FOF formula (forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> (((e_is ((setprod X0) X1)) ((((d_pair X0) X1) (((first X0) X1) X2)) (((second X0) X1) X2))) X2)))) of role axiom named pairis1
% 0.58/0.77 A new axiom: (forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> (((e_is ((setprod X0) X1)) ((((d_pair X0) X1) (((first X0) X1) X2)) (((second X0) X1) X2))) X2))))
% 0.58/0.77 FOF formula (forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> (((e_is X0) (((first X0) X1) ((((d_pair X0) X1) X2) X3))) X2)))))) of role axiom named firstis1
% 0.58/0.77 A new axiom: (forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> (((e_is X0) (((first X0) X1) ((((d_pair X0) X1) X2) X3))) X2))))))
% 0.58/0.77 FOF formula (forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> (((e_is X1) (((second X0) X1) ((((d_pair X0) X1) X2) X3))) X3)))))) of role axiom named secondis1
% 0.58/0.77 A new axiom: (forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> (((e_is X1) (((second X0) X1) ((((d_pair X0) X1) X2) X3))) X3))))))
% 0.58/0.77 FOF formula (<kernel.Constant object at 0x2abae09837a0>, <kernel.DependentProduct object at 0x2abae0983fc8>) of role type named typ_prop1
% 0.58/0.77 Using role type
% 0.58/0.77 Declaring prop1:(Prop->(fofType->(fofType->(fofType->(fofType->Prop)))))
% 0.58/0.77 FOF formula (((eq (Prop->(fofType->(fofType->(fofType->(fofType->Prop)))))) prop1) (fun (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_and ((imp X0) (((e_is X1) X4) X2))) ((imp (d_not X0)) (((e_is X1) X4) X3))))) of role definition named def_prop1
% 0.58/0.77 A new definition: (((eq (Prop->(fofType->(fofType->(fofType->(fofType->Prop)))))) prop1) (fun (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_and ((imp X0) (((e_is X1) X4) X2))) ((imp (d_not X0)) (((e_is X1) X4) X3)))))
% 0.58/0.77 Defined: prop1:=(fun (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_and ((imp X0) (((e_is X1) X4) X2))) ((imp (d_not X0)) (((e_is X1) X4) X3))))
% 0.58/0.77 FOF formula (<kernel.Constant object at 0x2abae0983fc8>, <kernel.DependentProduct object at 0x2abae09837a0>) of role type named typ_ite
% 0.58/0.77 Using role type
% 0.58/0.77 Declaring ite:(Prop->(fofType->(fofType->(fofType->fofType))))
% 0.58/0.77 FOF formula (((eq (Prop->(fofType->(fofType->(fofType->fofType))))) ite) (fun (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType)=> ((ind X1) ((((prop1 X0) X1) X2) X3)))) of role definition named def_ite
% 0.58/0.77 A new definition: (((eq (Prop->(fofType->(fofType->(fofType->fofType))))) ite) (fun (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType)=> ((ind X1) ((((prop1 X0) X1) X2) X3))))
% 0.58/0.77 Defined: ite:=(fun (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType)=> ((ind X1) ((((prop1 X0) X1) X2) X3)))
% 0.58/0.77 FOF formula (<kernel.Constant object at 0x2abae09837a0>, <kernel.DependentProduct object at 0x2abae0983dd0>) of role type named typ_wissel_wa
% 0.58/0.77 Using role type
% 0.58/0.77 Declaring wissel_wa:(fofType->(fofType->(fofType->(fofType->fofType))))
% 0.58/0.77 FOF formula (((eq (fofType->(fofType->(fofType->(fofType->fofType))))) wissel_wa) (fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((((ite (((e_is X0) X3) X1)) X0) X2) X3))) of role definition named def_wissel_wa
% 0.58/0.77 A new definition: (((eq (fofType->(fofType->(fofType->(fofType->fofType))))) wissel_wa) (fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((((ite (((e_is X0) X3) X1)) X0) X2) X3)))
% 0.58/0.77 Defined: wissel_wa:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((((ite (((e_is X0) X3) X1)) X0) X2) X3))
% 0.58/0.77 FOF formula (<kernel.Constant object at 0x2abae0983dd0>, <kernel.DependentProduct object at 0x2abae09835a8>) of role type named typ_wissel_wb
% 0.59/0.79 Using role type
% 0.59/0.79 Declaring wissel_wb:(fofType->(fofType->(fofType->(fofType->fofType))))
% 0.59/0.79 FOF formula (((eq (fofType->(fofType->(fofType->(fofType->fofType))))) wissel_wb) (fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((((ite (((e_is X0) X3) X2)) X0) X1) ((((wissel_wa X0) X1) X2) X3)))) of role definition named def_wissel_wb
% 0.59/0.79 A new definition: (((eq (fofType->(fofType->(fofType->(fofType->fofType))))) wissel_wb) (fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((((ite (((e_is X0) X3) X2)) X0) X1) ((((wissel_wa X0) X1) X2) X3))))
% 0.59/0.79 Defined: wissel_wb:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((((ite (((e_is X0) X3) X2)) X0) X1) ((((wissel_wa X0) X1) X2) X3)))
% 0.59/0.79 FOF formula (<kernel.Constant object at 0x2abae09835a8>, <kernel.DependentProduct object at 0x2abae0983f38>) of role type named typ_wissel
% 0.59/0.79 Using role type
% 0.59/0.79 Declaring wissel:(fofType->(fofType->(fofType->fofType)))
% 0.59/0.79 FOF formula (((eq (fofType->(fofType->(fofType->fofType)))) wissel) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X0) (((wissel_wb X0) X1) X2)))) of role definition named def_wissel
% 0.59/0.79 A new definition: (((eq (fofType->(fofType->(fofType->fofType)))) wissel) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X0) (((wissel_wb X0) X1) X2))))
% 0.59/0.79 Defined: wissel:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X0) (((wissel_wb X0) X1) X2)))
% 0.59/0.79 FOF formula (<kernel.Constant object at 0x2abae0983f38>, <kernel.DependentProduct object at 0x2abae09833b0>) of role type named typ_changef
% 0.59/0.79 Using role type
% 0.59/0.79 Declaring changef:(fofType->(fofType->(fofType->(fofType->(fofType->fofType)))))
% 0.59/0.79 FOF formula (((eq (fofType->(fofType->(fofType->(fofType->(fofType->fofType)))))) changef) (fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_Sigma X0) (fun (X5:fofType)=> ((ap X2) ((ap (((wissel X0) X3) X4)) X5)))))) of role definition named def_changef
% 0.59/0.79 A new definition: (((eq (fofType->(fofType->(fofType->(fofType->(fofType->fofType)))))) changef) (fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_Sigma X0) (fun (X5:fofType)=> ((ap X2) ((ap (((wissel X0) X3) X4)) X5))))))
% 0.59/0.79 Defined: changef:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_Sigma X0) (fun (X5:fofType)=> ((ap X2) ((ap (((wissel X0) X3) X4)) X5)))))
% 0.59/0.79 FOF formula (<kernel.Constant object at 0x2abae0983e60>, <kernel.DependentProduct object at 0x2abae09837a0>) of role type named typ_r_ec
% 0.59/0.79 Using role type
% 0.59/0.79 Declaring r_ec:(Prop->(Prop->Prop))
% 0.59/0.79 FOF formula (((eq (Prop->(Prop->Prop))) r_ec) (fun (X0:Prop) (X1:Prop)=> (X0->(d_not X1)))) of role definition named def_r_ec
% 0.59/0.79 A new definition: (((eq (Prop->(Prop->Prop))) r_ec) (fun (X0:Prop) (X1:Prop)=> (X0->(d_not X1))))
% 0.59/0.79 Defined: r_ec:=(fun (X0:Prop) (X1:Prop)=> (X0->(d_not X1)))
% 0.59/0.79 FOF formula (<kernel.Constant object at 0x2abae09837a0>, <kernel.DependentProduct object at 0x2abae0983fc8>) of role type named typ_esti
% 0.59/0.79 Using role type
% 0.59/0.79 Declaring esti:(fofType->(fofType->(fofType->Prop)))
% 0.59/0.79 FOF formula (((eq (fofType->(fofType->(fofType->Prop)))) esti) (fun (X0:fofType)=> in)) of role definition named def_esti
% 0.59/0.79 A new definition: (((eq (fofType->(fofType->(fofType->Prop)))) esti) (fun (X0:fofType)=> in))
% 0.59/0.79 Defined: esti:=(fun (X0:fofType)=> in)
% 0.59/0.79 FOF formula (forall (X0:fofType) (X1:(fofType->Prop)), ((is_of ((d_Sep X0) X1)) (fun (X2:fofType)=> ((in X2) (power X0))))) of role axiom named setof_p
% 0.59/0.79 A new axiom: (forall (X0:fofType) (X1:(fofType->Prop)), ((is_of ((d_Sep X0) X1)) (fun (X2:fofType)=> ((in X2) (power X0)))))
% 0.59/0.79 FOF formula (forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((X1 X2)->(((esti X0) X2) ((d_Sep X0) X1)))))) of role axiom named estii
% 0.59/0.79 A new axiom: (forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((X1 X2)->(((esti X0) X2) ((d_Sep X0) X1))))))
% 0.59/0.79 FOF formula (forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((((esti X0) X2) ((d_Sep X0) X1))->(X1 X2))))) of role axiom named estie
% 0.59/0.80 A new axiom: (forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((((esti X0) X2) ((d_Sep X0) X1))->(X1 X2)))))
% 0.59/0.80 FOF formula (<kernel.Constant object at 0x2abae0983fc8>, <kernel.DependentProduct object at 0x2abae0983ea8>) of role type named typ_empty
% 0.59/0.80 Using role type
% 0.59/0.80 Declaring empty:(fofType->(fofType->Prop))
% 0.59/0.80 FOF formula (((eq (fofType->(fofType->Prop))) empty) (fun (X0:fofType) (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) X0))) ((non X0) (fun (X2:fofType)=> (((esti X0) X2) X1)))))) of role definition named def_empty
% 0.59/0.80 A new definition: (((eq (fofType->(fofType->Prop))) empty) (fun (X0:fofType) (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) X0))) ((non X0) (fun (X2:fofType)=> (((esti X0) X2) X1))))))
% 0.59/0.80 Defined: empty:=(fun (X0:fofType) (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) X0))) ((non X0) (fun (X2:fofType)=> (((esti X0) X2) X1)))))
% 0.59/0.80 FOF formula (<kernel.Constant object at 0x2abae09838c0>, <kernel.DependentProduct object at 0x2abae0989050>) of role type named typ_nonempty
% 0.59/0.80 Using role type
% 0.59/0.80 Declaring nonempty:(fofType->(fofType->Prop))
% 0.59/0.80 FOF formula (((eq (fofType->(fofType->Prop))) nonempty) (fun (X0:fofType) (X1:fofType)=> ((l_some X0) (fun (X2:fofType)=> (((esti X0) X2) X1))))) of role definition named def_nonempty
% 0.59/0.80 A new definition: (((eq (fofType->(fofType->Prop))) nonempty) (fun (X0:fofType) (X1:fofType)=> ((l_some X0) (fun (X2:fofType)=> (((esti X0) X2) X1)))))
% 0.59/0.80 Defined: nonempty:=(fun (X0:fofType) (X1:fofType)=> ((l_some X0) (fun (X2:fofType)=> (((esti X0) X2) X1))))
% 0.59/0.80 FOF formula (<kernel.Constant object at 0x2abae0983f80>, <kernel.DependentProduct object at 0x2abae0989248>) of role type named typ_incl
% 0.59/0.80 Using role type
% 0.59/0.80 Declaring incl:(fofType->(fofType->(fofType->Prop)))
% 0.59/0.80 FOF formula (((eq (fofType->(fofType->(fofType->Prop)))) incl) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((imp (((esti X0) X3) X1)) (((esti X0) X3) X2)))))) of role definition named def_incl
% 0.59/0.80 A new definition: (((eq (fofType->(fofType->(fofType->Prop)))) incl) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((imp (((esti X0) X3) X1)) (((esti X0) X3) X2))))))
% 0.59/0.80 Defined: incl:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((imp (((esti X0) X3) X1)) (((esti X0) X3) X2)))))
% 0.59/0.80 FOF formula (<kernel.Constant object at 0x2abae0983f80>, <kernel.DependentProduct object at 0x2abae09891b8>) of role type named typ_st_disj
% 0.59/0.80 Using role type
% 0.59/0.80 Declaring st_disj:(fofType->(fofType->(fofType->Prop)))
% 0.59/0.80 FOF formula (((eq (fofType->(fofType->(fofType->Prop)))) st_disj) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((l_ec (((esti X0) X3) X1)) (((esti X0) X3) X2)))))) of role definition named def_st_disj
% 0.59/0.80 A new definition: (((eq (fofType->(fofType->(fofType->Prop)))) st_disj) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((l_ec (((esti X0) X3) X1)) (((esti X0) X3) X2))))))
% 0.59/0.80 Defined: st_disj:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((l_ec (((esti X0) X3) X1)) (((esti X0) X3) X2)))))
% 0.59/0.80 FOF formula (forall (X0:fofType), ((all_of (fun (X1:fofType)=> ((in X1) (power X0)))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) (power X0)))) (fun (X2:fofType)=> ((((incl X0) X1) X2)->((((incl X0) X2) X1)->(((e_is (power X0)) X1) X2)))))))) of role axiom named isseti
% 0.59/0.80 A new axiom: (forall (X0:fofType), ((all_of (fun (X1:fofType)=> ((in X1) (power X0)))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) (power X0)))) (fun (X2:fofType)=> ((((incl X0) X1) X2)->((((incl X0) X2) X1)->(((e_is (power X0)) X1) X2))))))))
% 0.59/0.80 FOF formula (<kernel.Constant object at 0x2abae0983f80>, <kernel.DependentProduct object at 0x2abae09895f0>) of role type named typ_nissetprop
% 0.59/0.80 Using role type
% 0.59/0.80 Declaring nissetprop:(fofType->(fofType->(fofType->(fofType->Prop))))
% 0.59/0.80 FOF formula (((eq (fofType->(fofType->(fofType->(fofType->Prop))))) nissetprop) (fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((d_and (((esti X0) X3) X1)) (d_not (((esti X0) X3) X2))))) of role definition named def_nissetprop
% 0.62/0.82 A new definition: (((eq (fofType->(fofType->(fofType->(fofType->Prop))))) nissetprop) (fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((d_and (((esti X0) X3) X1)) (d_not (((esti X0) X3) X2)))))
% 0.62/0.82 Defined: nissetprop:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((d_and (((esti X0) X3) X1)) (d_not (((esti X0) X3) X2))))
% 0.62/0.82 FOF formula (<kernel.Constant object at 0x2abae09895f0>, <kernel.DependentProduct object at 0x2abae09891b8>) of role type named typ_unmore
% 0.62/0.82 Using role type
% 0.62/0.82 Declaring unmore:(fofType->(fofType->(fofType->fofType)))
% 0.62/0.82 FOF formula (((eq (fofType->(fofType->(fofType->fofType)))) unmore) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sep X0) (fun (X3:fofType)=> ((l_some X1) (fun (X4:fofType)=> (((esti X0) X3) ((ap X2) X4)))))))) of role definition named def_unmore
% 0.62/0.82 A new definition: (((eq (fofType->(fofType->(fofType->fofType)))) unmore) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sep X0) (fun (X3:fofType)=> ((l_some X1) (fun (X4:fofType)=> (((esti X0) X3) ((ap X2) X4))))))))
% 0.62/0.82 Defined: unmore:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sep X0) (fun (X3:fofType)=> ((l_some X1) (fun (X4:fofType)=> (((esti X0) X3) ((ap X2) X4)))))))
% 0.62/0.82 FOF formula (<kernel.Constant object at 0x2abae09891b8>, <kernel.DependentProduct object at 0x2abae09897e8>) of role type named typ_ecelt
% 0.62/0.82 Using role type
% 0.62/0.82 Declaring ecelt:(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 0.62/0.82 FOF formula (((eq (fofType->((fofType->(fofType->Prop))->(fofType->fofType)))) ecelt) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> ((d_Sep X0) (X1 X2)))) of role definition named def_ecelt
% 0.62/0.82 A new definition: (((eq (fofType->((fofType->(fofType->Prop))->(fofType->fofType)))) ecelt) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> ((d_Sep X0) (X1 X2))))
% 0.62/0.82 Defined: ecelt:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> ((d_Sep X0) (X1 X2)))
% 0.62/0.82 FOF formula (<kernel.Constant object at 0x2abae09897e8>, <kernel.DependentProduct object at 0x2abae09897a0>) of role type named typ_ecp
% 0.62/0.82 Using role type
% 0.62/0.82 Declaring ecp:(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))
% 0.62/0.82 FOF formula (((eq (fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))) ecp) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> (((e_is (power X0)) X2) (((ecelt X0) X1) X3)))) of role definition named def_ecp
% 0.62/0.82 A new definition: (((eq (fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))) ecp) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> (((e_is (power X0)) X2) (((ecelt X0) X1) X3))))
% 0.62/0.82 Defined: ecp:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> (((e_is (power X0)) X2) (((ecelt X0) X1) X3)))
% 0.62/0.82 FOF formula (<kernel.Constant object at 0x2abae09897a0>, <kernel.DependentProduct object at 0x2abae0989b00>) of role type named typ_anec
% 0.62/0.82 Using role type
% 0.62/0.82 Declaring anec:(fofType->((fofType->(fofType->Prop))->(fofType->Prop)))
% 0.62/0.82 FOF formula (((eq (fofType->((fofType->(fofType->Prop))->(fofType->Prop)))) anec) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> ((l_some X0) (((ecp X0) X1) X2)))) of role definition named def_anec
% 0.62/0.82 A new definition: (((eq (fofType->((fofType->(fofType->Prop))->(fofType->Prop)))) anec) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> ((l_some X0) (((ecp X0) X1) X2))))
% 0.62/0.82 Defined: anec:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> ((l_some X0) (((ecp X0) X1) X2)))
% 0.62/0.82 FOF formula (<kernel.Constant object at 0x2abae0989b00>, <kernel.DependentProduct object at 0x2abae09897e8>) of role type named typ_ect
% 0.62/0.82 Using role type
% 0.62/0.82 Declaring ect:(fofType->((fofType->(fofType->Prop))->fofType))
% 0.62/0.82 FOF formula (((eq (fofType->((fofType->(fofType->Prop))->fofType))) ect) (fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((d_Sep (power X0)) ((anec X0) X1)))) of role definition named def_ect
% 0.62/0.82 A new definition: (((eq (fofType->((fofType->(fofType->Prop))->fofType))) ect) (fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((d_Sep (power X0)) ((anec X0) X1))))
% 0.64/0.83 Defined: ect:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((d_Sep (power X0)) ((anec X0) X1)))
% 0.64/0.83 FOF formula (<kernel.Constant object at 0x2abae09897e8>, <kernel.DependentProduct object at 0x2abae0989200>) of role type named typ_ectset
% 0.64/0.83 Using role type
% 0.64/0.83 Declaring ectset:(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 0.64/0.83 FOF formula (((eq (fofType->((fofType->(fofType->Prop))->(fofType->fofType)))) ectset) (fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((out (power X0)) ((anec X0) X1)))) of role definition named def_ectset
% 0.64/0.83 A new definition: (((eq (fofType->((fofType->(fofType->Prop))->(fofType->fofType)))) ectset) (fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((out (power X0)) ((anec X0) X1))))
% 0.64/0.83 Defined: ectset:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((out (power X0)) ((anec X0) X1)))
% 0.64/0.83 FOF formula (<kernel.Constant object at 0x2abae0989200>, <kernel.DependentProduct object at 0x2abae0989050>) of role type named typ_ectelt
% 0.64/0.83 Using role type
% 0.64/0.83 Declaring ectelt:(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 0.64/0.83 FOF formula (((eq (fofType->((fofType->(fofType->Prop))->(fofType->fofType)))) ectelt) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> (((ectset X0) X1) (((ecelt X0) X1) X2)))) of role definition named def_ectelt
% 0.64/0.83 A new definition: (((eq (fofType->((fofType->(fofType->Prop))->(fofType->fofType)))) ectelt) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> (((ectset X0) X1) (((ecelt X0) X1) X2))))
% 0.64/0.83 Defined: ectelt:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> (((ectset X0) X1) (((ecelt X0) X1) X2)))
% 0.64/0.83 FOF formula (<kernel.Constant object at 0x2abae0989050>, <kernel.DependentProduct object at 0x2abae09899e0>) of role type named typ_ecect
% 0.64/0.83 Using role type
% 0.64/0.83 Declaring ecect:(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 0.64/0.83 FOF formula (((eq (fofType->((fofType->(fofType->Prop))->(fofType->fofType)))) ecect) (fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((e_in (power X0)) ((anec X0) X1)))) of role definition named def_ecect
% 0.64/0.83 A new definition: (((eq (fofType->((fofType->(fofType->Prop))->(fofType->fofType)))) ecect) (fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((e_in (power X0)) ((anec X0) X1))))
% 0.64/0.83 Defined: ecect:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((e_in (power X0)) ((anec X0) X1)))
% 0.64/0.83 FOF formula (<kernel.Constant object at 0x2abae09899e0>, <kernel.DependentProduct object at 0x2abae09893f8>) of role type named typ_fixfu
% 0.64/0.83 Using role type
% 0.64/0.83 Declaring fixfu:(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))
% 0.64/0.83 FOF formula (((eq (fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))) fixfu) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> ((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> ((all_of (fun (X5:fofType)=> ((in X5) X0))) (fun (X5:fofType)=> (((X1 X4) X5)->(((e_is X2) ((ap X3) X4)) ((ap X3) X5))))))))) of role definition named def_fixfu
% 0.64/0.83 A new definition: (((eq (fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))) fixfu) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> ((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> ((all_of (fun (X5:fofType)=> ((in X5) X0))) (fun (X5:fofType)=> (((X1 X4) X5)->(((e_is X2) ((ap X3) X4)) ((ap X3) X5)))))))))
% 0.64/0.83 Defined: fixfu:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> ((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> ((all_of (fun (X5:fofType)=> ((in X5) X0))) (fun (X5:fofType)=> (((X1 X4) X5)->(((e_is X2) ((ap X3) X4)) ((ap X3) X5))))))))
% 0.64/0.83 FOF formula (<kernel.Constant object at 0x2abae09893f8>, <kernel.DependentProduct object at 0x2abae0989878>) of role type named typ_d_10_prop1
% 0.64/0.83 Using role type
% 0.64/0.83 Declaring d_10_prop1:(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->(fofType->Prop)))))))
% 0.64/0.83 FOF formula (((eq (fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->(fofType->Prop)))))))) d_10_prop1) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType) (X5:fofType) (X6:fofType)=> ((d_and (((esti X0) X6) (((ecect X0) X1) X4))) (((e_is X2) ((ap X3) X6)) X5)))) of role definition named def_d_10_prop1
% 0.64/0.85 A new definition: (((eq (fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->(fofType->Prop)))))))) d_10_prop1) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType) (X5:fofType) (X6:fofType)=> ((d_and (((esti X0) X6) (((ecect X0) X1) X4))) (((e_is X2) ((ap X3) X6)) X5))))
% 0.64/0.85 Defined: d_10_prop1:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType) (X5:fofType) (X6:fofType)=> ((d_and (((esti X0) X6) (((ecect X0) X1) X4))) (((e_is X2) ((ap X3) X6)) X5)))
% 0.64/0.85 FOF formula (<kernel.Constant object at 0x2abae0989878>, <kernel.DependentProduct object at 0x2abae0989ab8>) of role type named typ_prop2
% 0.64/0.85 Using role type
% 0.64/0.85 Declaring prop2:(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->Prop))))))
% 0.64/0.85 FOF formula (((eq (fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->Prop))))))) prop2) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType) (X5:fofType)=> ((l_some X0) ((((((d_10_prop1 X0) X1) X2) X3) X4) X5)))) of role definition named def_prop2
% 0.64/0.85 A new definition: (((eq (fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->Prop))))))) prop2) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType) (X5:fofType)=> ((l_some X0) ((((((d_10_prop1 X0) X1) X2) X3) X4) X5))))
% 0.64/0.85 Defined: prop2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType) (X5:fofType)=> ((l_some X0) ((((((d_10_prop1 X0) X1) X2) X3) X4) X5)))
% 0.64/0.85 FOF formula (<kernel.Constant object at 0x2abae0989ab8>, <kernel.DependentProduct object at 0x2abae09891b8>) of role type named typ_indeq
% 0.64/0.85 Using role type
% 0.64/0.85 Declaring indeq:(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->fofType)))))
% 0.64/0.85 FOF formula (((eq (fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->fofType)))))) indeq) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType)=> ((ind X2) (((((prop2 X0) X1) X2) X3) X4)))) of role definition named def_indeq
% 0.64/0.85 A new definition: (((eq (fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->fofType)))))) indeq) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType)=> ((ind X2) (((((prop2 X0) X1) X2) X3) X4))))
% 0.64/0.85 Defined: indeq:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType)=> ((ind X2) (((((prop2 X0) X1) X2) X3) X4)))
% 0.64/0.85 FOF formula (<kernel.Constant object at 0x2abae09891b8>, <kernel.DependentProduct object at 0x2abae0989680>) of role type named typ_fixfu2
% 0.64/0.85 Using role type
% 0.64/0.85 Declaring fixfu2:(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))
% 0.64/0.85 FOF formula (((eq (fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))) fixfu2) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> ((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> ((all_of (fun (X5:fofType)=> ((in X5) X0))) (fun (X5:fofType)=> ((all_of (fun (X6:fofType)=> ((in X6) X0))) (fun (X6:fofType)=> ((all_of (fun (X7:fofType)=> ((in X7) X0))) (fun (X7:fofType)=> (((X1 X4) X5)->(((X1 X6) X7)->(((e_is X2) ((ap ((ap X3) X4)) X6)) ((ap ((ap X3) X5)) X7)))))))))))))) of role definition named def_fixfu2
% 0.64/0.85 A new definition: (((eq (fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))) fixfu2) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> ((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> ((all_of (fun (X5:fofType)=> ((in X5) X0))) (fun (X5:fofType)=> ((all_of (fun (X6:fofType)=> ((in X6) X0))) (fun (X6:fofType)=> ((all_of (fun (X7:fofType)=> ((in X7) X0))) (fun (X7:fofType)=> (((X1 X4) X5)->(((X1 X6) X7)->(((e_is X2) ((ap ((ap X3) X4)) X6)) ((ap ((ap X3) X5)) X7))))))))))))))
% 0.64/0.85 Defined: fixfu2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> ((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> ((all_of (fun (X5:fofType)=> ((in X5) X0))) (fun (X5:fofType)=> ((all_of (fun (X6:fofType)=> ((in X6) X0))) (fun (X6:fofType)=> ((all_of (fun (X7:fofType)=> ((in X7) X0))) (fun (X7:fofType)=> (((X1 X4) X5)->(((X1 X6) X7)->(((e_is X2) ((ap ((ap X3) X4)) X6)) ((ap ((ap X3) X5)) X7)))))))))))))
% 0.64/0.86 FOF formula (<kernel.Constant object at 0x2abae0989680>, <kernel.DependentProduct object at 0x2abae0989440>) of role type named typ_d_11_i
% 0.64/0.86 Using role type
% 0.64/0.86 Declaring d_11_i:(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->fofType)))))
% 0.64/0.86 FOF formula (((eq (fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->fofType)))))) d_11_i) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> (((indeq X0) X1) ((d_Pi X0) (fun (X3:fofType)=> X2))))) of role definition named def_d_11_i
% 0.64/0.86 A new definition: (((eq (fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->fofType)))))) d_11_i) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> (((indeq X0) X1) ((d_Pi X0) (fun (X3:fofType)=> X2)))))
% 0.64/0.86 Defined: d_11_i:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> (((indeq X0) X1) ((d_Pi X0) (fun (X3:fofType)=> X2))))
% 0.64/0.86 FOF formula (<kernel.Constant object at 0x2abae0989440>, <kernel.DependentProduct object at 0x2abae0989a70>) of role type named typ_indeq2
% 0.64/0.86 Using role type
% 0.64/0.86 Declaring indeq2:(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->fofType))))))
% 0.64/0.86 FOF formula (((eq (fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->fofType))))))) indeq2) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType)=> ((((indeq X0) X1) X2) (((((d_11_i X0) X1) X2) X3) X4)))) of role definition named def_indeq2
% 0.64/0.86 A new definition: (((eq (fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->fofType))))))) indeq2) (fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType)=> ((((indeq X0) X1) X2) (((((d_11_i X0) X1) X2) X3) X4))))
% 0.64/0.86 Defined: indeq2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType)=> ((((indeq X0) X1) X2) (((((d_11_i X0) X1) X2) X3) X4)))
% 0.64/0.86 FOF formula (<kernel.Constant object at 0x2abae0989a70>, <kernel.Single object at 0x2abae0989440>) of role type named typ_nat
% 0.64/0.86 Using role type
% 0.64/0.86 Declaring nat:fofType
% 0.64/0.86 FOF formula (((eq fofType) nat) ((d_Sep omega) (fun (X0:fofType)=> (not (((eq fofType) X0) emptyset))))) of role definition named def_nat
% 0.64/0.86 A new definition: (((eq fofType) nat) ((d_Sep omega) (fun (X0:fofType)=> (not (((eq fofType) X0) emptyset)))))
% 0.64/0.86 Defined: nat:=((d_Sep omega) (fun (X0:fofType)=> (not (((eq fofType) X0) emptyset))))
% 0.64/0.86 FOF formula (<kernel.Constant object at 0x2abae0989440>, <kernel.DependentProduct object at 0x2abae0989050>) of role type named typ_n_is
% 0.64/0.86 Using role type
% 0.64/0.86 Declaring n_is:(fofType->(fofType->Prop))
% 0.64/0.86 FOF formula (((eq (fofType->(fofType->Prop))) n_is) (e_is nat)) of role definition named def_n_is
% 0.64/0.86 A new definition: (((eq (fofType->(fofType->Prop))) n_is) (e_is nat))
% 0.64/0.86 Defined: n_is:=(e_is nat)
% 0.64/0.86 FOF formula (<kernel.Constant object at 0x2abae0989f38>, <kernel.DependentProduct object at 0x2abae0989cb0>) of role type named typ_nis
% 0.64/0.86 Using role type
% 0.64/0.86 Declaring nis:(fofType->(fofType->Prop))
% 0.64/0.86 FOF formula (((eq (fofType->(fofType->Prop))) nis) (fun (X0:fofType) (X1:fofType)=> (d_not ((n_is X0) X1)))) of role definition named def_nis
% 0.64/0.86 A new definition: (((eq (fofType->(fofType->Prop))) nis) (fun (X0:fofType) (X1:fofType)=> (d_not ((n_is X0) X1))))
% 0.64/0.86 Defined: nis:=(fun (X0:fofType) (X1:fofType)=> (d_not ((n_is X0) X1)))
% 0.64/0.86 FOF formula (<kernel.Constant object at 0x2abae0989cb0>, <kernel.DependentProduct object at 0x2abae0989050>) of role type named typ_n_in
% 0.64/0.86 Using role type
% 0.64/0.86 Declaring n_in:(fofType->(fofType->Prop))
% 0.64/0.86 FOF formula (((eq (fofType->(fofType->Prop))) n_in) (esti nat)) of role definition named def_n_in
% 0.64/0.86 A new definition: (((eq (fofType->(fofType->Prop))) n_in) (esti nat))
% 0.64/0.88 Defined: n_in:=(esti nat)
% 0.64/0.88 FOF formula (<kernel.Constant object at 0x2abae09899e0>, <kernel.DependentProduct object at 0x2abae0989050>) of role type named typ_n_some
% 0.64/0.88 Using role type
% 0.64/0.88 Declaring n_some:((fofType->Prop)->Prop)
% 0.64/0.88 FOF formula (((eq ((fofType->Prop)->Prop)) n_some) (l_some nat)) of role definition named def_n_some
% 0.64/0.88 A new definition: (((eq ((fofType->Prop)->Prop)) n_some) (l_some nat))
% 0.64/0.88 Defined: n_some:=(l_some nat)
% 0.64/0.88 FOF formula (<kernel.Constant object at 0x2abae0989f80>, <kernel.DependentProduct object at 0x2abae0989050>) of role type named typ_n_all
% 0.64/0.88 Using role type
% 0.64/0.88 Declaring n_all:((fofType->Prop)->Prop)
% 0.64/0.88 FOF formula (((eq ((fofType->Prop)->Prop)) n_all) (all nat)) of role definition named def_n_all
% 0.64/0.88 A new definition: (((eq ((fofType->Prop)->Prop)) n_all) (all nat))
% 0.64/0.88 Defined: n_all:=(all nat)
% 0.64/0.88 FOF formula (<kernel.Constant object at 0x2abae0989c68>, <kernel.DependentProduct object at 0x2abae0989050>) of role type named typ_n_one
% 0.64/0.88 Using role type
% 0.64/0.88 Declaring n_one:((fofType->Prop)->Prop)
% 0.64/0.88 FOF formula (((eq ((fofType->Prop)->Prop)) n_one) (one nat)) of role definition named def_n_one
% 0.64/0.88 A new definition: (((eq ((fofType->Prop)->Prop)) n_one) (one nat))
% 0.64/0.88 Defined: n_one:=(one nat)
% 0.64/0.88 FOF formula (<kernel.Constant object at 0x2abae0989cb0>, <kernel.Single object at 0x2abae0989c68>) of role type named typ_n_1
% 0.64/0.88 Using role type
% 0.64/0.88 Declaring n_1:fofType
% 0.64/0.88 FOF formula (((eq fofType) n_1) (ordsucc emptyset)) of role definition named def_n_1
% 0.64/0.88 A new definition: (((eq fofType) n_1) (ordsucc emptyset))
% 0.64/0.88 Defined: n_1:=(ordsucc emptyset)
% 0.64/0.88 FOF formula ((is_of n_1) (fun (X0:fofType)=> ((in X0) nat))) of role axiom named n_1_p
% 0.64/0.88 A new axiom: ((is_of n_1) (fun (X0:fofType)=> ((in X0) nat)))
% 0.64/0.88 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((is_of (ordsucc X0)) (fun (X1:fofType)=> ((in X1) nat))))) of role axiom named suc_p
% 0.64/0.88 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((is_of (ordsucc X0)) (fun (X1:fofType)=> ((in X1) nat)))))
% 0.64/0.88 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((nis (ordsucc X0)) n_1))) of role axiom named n_ax3
% 0.64/0.88 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((nis (ordsucc X0)) n_1)))
% 0.64/0.88 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((n_is (ordsucc X0)) (ordsucc X1))->((n_is X0) X1)))))) of role axiom named n_ax4
% 0.64/0.88 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((n_is (ordsucc X0)) (ordsucc X1))->((n_is X0) X1))))))
% 0.64/0.88 FOF formula (<kernel.Constant object at 0x2abae0989878>, <kernel.DependentProduct object at 0x2abae0990878>) of role type named typ_cond1
% 0.64/0.88 Using role type
% 0.64/0.88 Declaring cond1:(fofType->Prop)
% 0.64/0.88 FOF formula (((eq (fofType->Prop)) cond1) (n_in n_1)) of role definition named def_cond1
% 0.64/0.88 A new definition: (((eq (fofType->Prop)) cond1) (n_in n_1))
% 0.64/0.88 Defined: cond1:=(n_in n_1)
% 0.64/0.88 FOF formula (<kernel.Constant object at 0x2abae0989878>, <kernel.DependentProduct object at 0x2abae09903b0>) of role type named typ_cond2
% 0.64/0.88 Using role type
% 0.64/0.88 Declaring cond2:(fofType->Prop)
% 0.64/0.88 FOF formula (((eq (fofType->Prop)) cond2) (fun (X0:fofType)=> (n_all (fun (X1:fofType)=> ((imp ((n_in X1) X0)) ((n_in (ordsucc X1)) X0)))))) of role definition named def_cond2
% 0.64/0.88 A new definition: (((eq (fofType->Prop)) cond2) (fun (X0:fofType)=> (n_all (fun (X1:fofType)=> ((imp ((n_in X1) X0)) ((n_in (ordsucc X1)) X0))))))
% 0.64/0.88 Defined: cond2:=(fun (X0:fofType)=> (n_all (fun (X1:fofType)=> ((imp ((n_in X1) X0)) ((n_in (ordsucc X1)) X0)))))
% 0.64/0.88 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) (power nat)))) (fun (X0:fofType)=> ((cond1 X0)->((cond2 X0)->((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_in X1) X0))))))) of role axiom named n_ax5
% 0.64/0.88 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) (power nat)))) (fun (X0:fofType)=> ((cond1 X0)->((cond2 X0)->((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_in X1) X0)))))))
% 0.64/0.88 FOF formula (<kernel.Constant object at 0x2abae0990248>, <kernel.DependentProduct object at 0x2abae0990758>) of role type named typ_i1_s
% 0.64/0.89 Using role type
% 0.64/0.89 Declaring i1_s:((fofType->Prop)->fofType)
% 0.64/0.89 FOF formula (((eq ((fofType->Prop)->fofType)) i1_s) (d_Sep nat)) of role definition named def_i1_s
% 0.64/0.89 A new definition: (((eq ((fofType->Prop)->fofType)) i1_s) (d_Sep nat))
% 0.64/0.89 Defined: i1_s:=(d_Sep nat)
% 0.64/0.89 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((nis X0) X1)->((nis (ordsucc X0)) (ordsucc X1))))))) of role axiom named satz1
% 0.64/0.89 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((nis X0) X1)->((nis (ordsucc X0)) (ordsucc X1)))))))
% 0.64/0.89 FOF formula (<kernel.Constant object at 0x2abadd5c84d0>, <kernel.DependentProduct object at 0x2abadd1fde60>) of role type named typ_d_22_prop1
% 0.64/0.89 Using role type
% 0.64/0.89 Declaring d_22_prop1:(fofType->Prop)
% 0.64/0.89 FOF formula (((eq (fofType->Prop)) d_22_prop1) (fun (X0:fofType)=> ((nis (ordsucc X0)) X0))) of role definition named def_d_22_prop1
% 0.64/0.89 A new definition: (((eq (fofType->Prop)) d_22_prop1) (fun (X0:fofType)=> ((nis (ordsucc X0)) X0)))
% 0.64/0.89 Defined: d_22_prop1:=(fun (X0:fofType)=> ((nis (ordsucc X0)) X0))
% 0.64/0.89 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((nis (ordsucc X0)) X0))) of role axiom named satz2
% 0.64/0.89 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((nis (ordsucc X0)) X0)))
% 0.64/0.89 FOF formula (<kernel.Constant object at 0x2abad59613f8>, <kernel.DependentProduct object at 0x2abadd1fdef0>) of role type named typ_d_23_prop1
% 0.64/0.89 Using role type
% 0.64/0.89 Declaring d_23_prop1:(fofType->Prop)
% 0.64/0.89 FOF formula (((eq (fofType->Prop)) d_23_prop1) (fun (X0:fofType)=> ((l_or ((n_is X0) n_1)) (n_some (fun (X1:fofType)=> ((n_is X0) (ordsucc X1))))))) of role definition named def_d_23_prop1
% 0.64/0.89 A new definition: (((eq (fofType->Prop)) d_23_prop1) (fun (X0:fofType)=> ((l_or ((n_is X0) n_1)) (n_some (fun (X1:fofType)=> ((n_is X0) (ordsucc X1)))))))
% 0.64/0.89 Defined: d_23_prop1:=(fun (X0:fofType)=> ((l_or ((n_is X0) n_1)) (n_some (fun (X1:fofType)=> ((n_is X0) (ordsucc X1))))))
% 0.64/0.89 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> (((nis X0) n_1)->(n_some (fun (X1:fofType)=> ((n_is X0) (ordsucc X1))))))) of role axiom named satz3
% 0.64/0.89 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> (((nis X0) n_1)->(n_some (fun (X1:fofType)=> ((n_is X0) (ordsucc X1)))))))
% 0.64/0.89 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> (((nis X0) n_1)->(n_one (fun (X1:fofType)=> ((n_is X0) (ordsucc X1))))))) of role axiom named satz3a
% 0.64/0.89 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> (((nis X0) n_1)->(n_one (fun (X1:fofType)=> ((n_is X0) (ordsucc X1)))))))
% 0.64/0.89 FOF formula (<kernel.Constant object at 0x2abadd5c85f0>, <kernel.DependentProduct object at 0x2abadd1fdcb0>) of role type named typ_d_24_prop1
% 0.64/0.89 Using role type
% 0.64/0.89 Declaring d_24_prop1:(fofType->Prop)
% 0.64/0.89 FOF formula (((eq (fofType->Prop)) d_24_prop1) (fun (X0:fofType)=> (n_all (fun (X1:fofType)=> ((n_is ((ap X0) (ordsucc X1))) (ordsucc ((ap X0) X1))))))) of role definition named def_d_24_prop1
% 0.64/0.89 A new definition: (((eq (fofType->Prop)) d_24_prop1) (fun (X0:fofType)=> (n_all (fun (X1:fofType)=> ((n_is ((ap X0) (ordsucc X1))) (ordsucc ((ap X0) X1)))))))
% 0.64/0.89 Defined: d_24_prop1:=(fun (X0:fofType)=> (n_all (fun (X1:fofType)=> ((n_is ((ap X0) (ordsucc X1))) (ordsucc ((ap X0) X1))))))
% 0.64/0.89 FOF formula (<kernel.Constant object at 0x2abadd5c84d0>, <kernel.DependentProduct object at 0x2abadd1d6a28>) of role type named typ_d_24_prop2
% 0.64/0.89 Using role type
% 0.64/0.89 Declaring d_24_prop2:(fofType->(fofType->Prop))
% 0.64/0.89 FOF formula (((eq (fofType->(fofType->Prop))) d_24_prop2) (fun (X0:fofType) (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) (ordsucc X0))) (d_24_prop1 X1)))) of role definition named def_d_24_prop2
% 0.64/0.89 A new definition: (((eq (fofType->(fofType->Prop))) d_24_prop2) (fun (X0:fofType) (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) (ordsucc X0))) (d_24_prop1 X1))))
% 0.64/0.89 Defined: d_24_prop2:=(fun (X0:fofType) (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) (ordsucc X0))) (d_24_prop1 X1)))
% 0.64/0.91 FOF formula (<kernel.Constant object at 0x2abadd1fddd0>, <kernel.DependentProduct object at 0x2abadd1ed290>) of role type named typ_prop3
% 0.64/0.91 Using role type
% 0.64/0.91 Declaring prop3:(fofType->(fofType->(fofType->Prop)))
% 0.64/0.91 FOF formula (((eq (fofType->(fofType->(fofType->Prop)))) prop3) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is ((ap X0) X2)) ((ap X1) X2)))) of role definition named def_prop3
% 0.64/0.91 A new definition: (((eq (fofType->(fofType->(fofType->Prop)))) prop3) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is ((ap X0) X2)) ((ap X1) X2))))
% 0.64/0.91 Defined: prop3:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is ((ap X0) X2)) ((ap X1) X2)))
% 0.64/0.91 FOF formula (<kernel.Constant object at 0x2abadd1ed170>, <kernel.DependentProduct object at 0x2abadd1fda70>) of role type named typ_prop4
% 0.64/0.91 Using role type
% 0.64/0.91 Declaring prop4:(fofType->Prop)
% 0.64/0.91 FOF formula (((eq (fofType->Prop)) prop4) (fun (X0:fofType)=> ((l_some ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_24_prop2 X0)))) of role definition named def_prop4
% 0.64/0.91 A new definition: (((eq (fofType->Prop)) prop4) (fun (X0:fofType)=> ((l_some ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_24_prop2 X0))))
% 0.64/0.91 Defined: prop4:=(fun (X0:fofType)=> ((l_some ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_24_prop2 X0)))
% 0.64/0.91 FOF formula (<kernel.Constant object at 0x2abadd1d6ea8>, <kernel.DependentProduct object at 0x2abadd1f9758>) of role type named typ_d_24_g
% 0.64/0.91 Using role type
% 0.64/0.91 Declaring d_24_g:(fofType->fofType)
% 0.64/0.91 FOF formula (((eq (fofType->fofType)) d_24_g) (fun (X0:fofType)=> ((d_Sigma nat) (fun (X1:fofType)=> (ordsucc ((ap X0) X1)))))) of role definition named def_d_24_g
% 0.64/0.91 A new definition: (((eq (fofType->fofType)) d_24_g) (fun (X0:fofType)=> ((d_Sigma nat) (fun (X1:fofType)=> (ordsucc ((ap X0) X1))))))
% 0.64/0.91 Defined: d_24_g:=(fun (X0:fofType)=> ((d_Sigma nat) (fun (X1:fofType)=> (ordsucc ((ap X0) X1)))))
% 0.64/0.91 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((one ((d_Pi nat) (fun (X1:fofType)=> nat))) (fun (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) (ordsucc X0))) (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) (ordsucc ((ap X1) X2)))))))))) of role axiom named satz4
% 0.64/0.91 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((one ((d_Pi nat) (fun (X1:fofType)=> nat))) (fun (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) (ordsucc X0))) (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) (ordsucc ((ap X1) X2))))))))))
% 0.64/0.91 FOF formula (<kernel.Constant object at 0x2abadd1d6ea8>, <kernel.DependentProduct object at 0x2abadd1f97a0>) of role type named typ_plus
% 0.64/0.91 Using role type
% 0.64/0.91 Declaring plus:(fofType->fofType)
% 0.64/0.91 FOF formula (((eq (fofType->fofType)) plus) (fun (X0:fofType)=> ((ind ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_24_prop2 X0)))) of role definition named def_plus
% 0.64/0.91 A new definition: (((eq (fofType->fofType)) plus) (fun (X0:fofType)=> ((ind ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_24_prop2 X0))))
% 0.64/0.91 Defined: plus:=(fun (X0:fofType)=> ((ind ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_24_prop2 X0)))
% 0.64/0.91 FOF formula (<kernel.Constant object at 0x2abadd1fddd0>, <kernel.DependentProduct object at 0x2abadd1f9518>) of role type named typ_n_pl
% 0.64/0.91 Using role type
% 0.64/0.91 Declaring n_pl:(fofType->(fofType->fofType))
% 0.64/0.91 FOF formula (((eq (fofType->(fofType->fofType))) n_pl) (fun (X0:fofType)=> (ap (plus X0)))) of role definition named def_n_pl
% 0.64/0.91 A new definition: (((eq (fofType->(fofType->fofType))) n_pl) (fun (X0:fofType)=> (ap (plus X0))))
% 0.64/0.91 Defined: n_pl:=(fun (X0:fofType)=> (ap (plus X0)))
% 0.64/0.91 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_pl X0) n_1)) (ordsucc X0)))) of role axiom named satz4a
% 0.64/0.91 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_pl X0) n_1)) (ordsucc X0))))
% 0.64/0.91 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl X0) (ordsucc X1))) (ordsucc ((n_pl X0) X1))))))) of role axiom named satz4b
% 0.64/0.91 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl X0) (ordsucc X1))) (ordsucc ((n_pl X0) X1)))))))
% 0.73/0.93 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_pl n_1) X0)) (ordsucc X0)))) of role axiom named satz4c
% 0.73/0.93 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_pl n_1) X0)) (ordsucc X0))))
% 0.73/0.93 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl (ordsucc X0)) X1)) (ordsucc ((n_pl X0) X1))))))) of role axiom named satz4d
% 0.73/0.93 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl (ordsucc X0)) X1)) (ordsucc ((n_pl X0) X1)))))))
% 0.73/0.93 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is (ordsucc X0)) ((n_pl X0) n_1)))) of role axiom named satz4e
% 0.73/0.93 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is (ordsucc X0)) ((n_pl X0) n_1))))
% 0.73/0.93 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is (ordsucc ((n_pl X0) X1))) ((n_pl X0) (ordsucc X1))))))) of role axiom named satz4f
% 0.73/0.93 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is (ordsucc ((n_pl X0) X1))) ((n_pl X0) (ordsucc X1)))))))
% 0.73/0.93 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is (ordsucc X0)) ((n_pl n_1) X0)))) of role axiom named satz4g
% 0.73/0.93 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is (ordsucc X0)) ((n_pl n_1) X0))))
% 0.73/0.93 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is (ordsucc ((n_pl X0) X1))) ((n_pl (ordsucc X0)) X1)))))) of role axiom named satz4h
% 0.73/0.93 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is (ordsucc ((n_pl X0) X1))) ((n_pl (ordsucc X0)) X1))))))
% 0.73/0.93 FOF formula (<kernel.Constant object at 0x2abadd1f9fc8>, <kernel.DependentProduct object at 0x2abadd1f94d0>) of role type named typ_d_25_prop1
% 0.73/0.93 Using role type
% 0.73/0.93 Declaring d_25_prop1:(fofType->(fofType->(fofType->Prop)))
% 0.73/0.93 FOF formula (((eq (fofType->(fofType->(fofType->Prop)))) d_25_prop1) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is ((n_pl ((n_pl X0) X1)) X2)) ((n_pl X0) ((n_pl X1) X2))))) of role definition named def_d_25_prop1
% 0.73/0.93 A new definition: (((eq (fofType->(fofType->(fofType->Prop)))) d_25_prop1) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is ((n_pl ((n_pl X0) X1)) X2)) ((n_pl X0) ((n_pl X1) X2)))))
% 0.73/0.93 Defined: d_25_prop1:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is ((n_pl ((n_pl X0) X1)) X2)) ((n_pl X0) ((n_pl X1) X2))))
% 0.73/0.93 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((n_is ((n_pl ((n_pl X0) X1)) X2)) ((n_pl X0) ((n_pl X1) X2))))))))) of role axiom named satz5
% 0.73/0.93 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((n_is ((n_pl ((n_pl X0) X1)) X2)) ((n_pl X0) ((n_pl X1) X2)))))))))
% 0.73/0.93 FOF formula (<kernel.Constant object at 0x2abadd1f95a8>, <kernel.DependentProduct object at 0x2abadd1f9e60>) of role type named typ_d_26_prop1
% 0.73/0.93 Using role type
% 0.73/0.93 Declaring d_26_prop1:(fofType->(fofType->Prop))
% 0.73/0.93 FOF formula (((eq (fofType->(fofType->Prop))) d_26_prop1) (fun (X0:fofType) (X1:fofType)=> ((n_is ((n_pl X0) X1)) ((n_pl X1) X0)))) of role definition named def_d_26_prop1
% 0.73/0.93 A new definition: (((eq (fofType->(fofType->Prop))) d_26_prop1) (fun (X0:fofType) (X1:fofType)=> ((n_is ((n_pl X0) X1)) ((n_pl X1) X0))))
% 0.73/0.95 Defined: d_26_prop1:=(fun (X0:fofType) (X1:fofType)=> ((n_is ((n_pl X0) X1)) ((n_pl X1) X0)))
% 0.73/0.95 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl X0) X1)) ((n_pl X1) X0)))))) of role axiom named satz6
% 0.73/0.95 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl X0) X1)) ((n_pl X1) X0))))))
% 0.73/0.95 FOF formula (<kernel.Constant object at 0x2abadd1f96c8>, <kernel.DependentProduct object at 0x2abadd1f9ea8>) of role type named typ_d_27_prop1
% 0.73/0.95 Using role type
% 0.73/0.95 Declaring d_27_prop1:(fofType->(fofType->Prop))
% 0.73/0.95 FOF formula (((eq (fofType->(fofType->Prop))) d_27_prop1) (fun (X0:fofType) (X1:fofType)=> ((nis X1) ((n_pl X0) X1)))) of role definition named def_d_27_prop1
% 0.73/0.95 A new definition: (((eq (fofType->(fofType->Prop))) d_27_prop1) (fun (X0:fofType) (X1:fofType)=> ((nis X1) ((n_pl X0) X1))))
% 0.73/0.95 Defined: d_27_prop1:=(fun (X0:fofType) (X1:fofType)=> ((nis X1) ((n_pl X0) X1)))
% 0.73/0.95 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((nis X1) ((n_pl X0) X1)))))) of role axiom named satz7
% 0.73/0.95 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((nis X1) ((n_pl X0) X1))))))
% 0.73/0.95 FOF formula (<kernel.Constant object at 0x2abadd1f9998>, <kernel.DependentProduct object at 0x2abadd1f93f8>) of role type named typ_d_28_prop1
% 0.73/0.95 Using role type
% 0.73/0.95 Declaring d_28_prop1:(fofType->(fofType->(fofType->Prop)))
% 0.73/0.95 FOF formula (((eq (fofType->(fofType->(fofType->Prop)))) d_28_prop1) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((nis ((n_pl X0) X1)) ((n_pl X0) X2)))) of role definition named def_d_28_prop1
% 0.73/0.95 A new definition: (((eq (fofType->(fofType->(fofType->Prop)))) d_28_prop1) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((nis ((n_pl X0) X1)) ((n_pl X0) X2))))
% 0.73/0.95 Defined: d_28_prop1:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((nis ((n_pl X0) X1)) ((n_pl X0) X2)))
% 0.73/0.95 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((nis X1) X2)->((nis ((n_pl X0) X1)) ((n_pl X0) X2))))))))) of role axiom named satz8
% 0.73/0.95 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((nis X1) X2)->((nis ((n_pl X0) X1)) ((n_pl X0) X2)))))))))
% 0.73/0.95 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X0) X1)) ((n_pl X0) X2))->((n_is X1) X2)))))))) of role axiom named satz8a
% 0.73/0.95 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X0) X1)) ((n_pl X0) X2))->((n_is X1) X2))))))))
% 0.73/0.95 FOF formula (<kernel.Constant object at 0x2abadd1f9e60>, <kernel.DependentProduct object at 0x2abadd1f9830>) of role type named typ_diffprop
% 0.73/0.95 Using role type
% 0.73/0.95 Declaring diffprop:(fofType->(fofType->(fofType->Prop)))
% 0.73/0.95 FOF formula (((eq (fofType->(fofType->(fofType->Prop)))) diffprop) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is X0) ((n_pl X1) X2)))) of role definition named def_diffprop
% 0.73/0.95 A new definition: (((eq (fofType->(fofType->(fofType->Prop)))) diffprop) (fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))))
% 0.73/0.95 Defined: diffprop:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is X0) ((n_pl X1) X2)))
% 0.73/0.95 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((amone nat) (fun (X2:fofType)=> ((n_is X0) ((n_pl X1) X2)))))))) of role axiom named satz8b
% 0.73/0.97 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((amone nat) (fun (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))))))))
% 0.73/0.97 FOF formula (<kernel.Constant object at 0x2abadd1f9ea8>, <kernel.DependentProduct object at 0x2abadd1f9878>) of role type named typ_d_29_ii
% 0.73/0.97 Using role type
% 0.73/0.97 Declaring d_29_ii:(fofType->(fofType->Prop))
% 0.73/0.97 FOF formula (((eq (fofType->(fofType->Prop))) d_29_ii) (fun (X0:fofType) (X1:fofType)=> (n_some ((diffprop X0) X1)))) of role definition named def_d_29_ii
% 0.73/0.97 A new definition: (((eq (fofType->(fofType->Prop))) d_29_ii) (fun (X0:fofType) (X1:fofType)=> (n_some ((diffprop X0) X1))))
% 0.73/0.97 Defined: d_29_ii:=(fun (X0:fofType) (X1:fofType)=> (n_some ((diffprop X0) X1)))
% 0.73/0.97 FOF formula (<kernel.Constant object at 0x2abadd1f9878>, <kernel.DependentProduct object at 0x2abadd1f9830>) of role type named typ_iii
% 0.73/0.97 Using role type
% 0.73/0.97 Declaring iii:(fofType->(fofType->Prop))
% 0.73/0.97 FOF formula (((eq (fofType->(fofType->Prop))) iii) (fun (X0:fofType) (X1:fofType)=> (n_some ((diffprop X1) X0)))) of role definition named def_iii
% 0.73/0.97 A new definition: (((eq (fofType->(fofType->Prop))) iii) (fun (X0:fofType) (X1:fofType)=> (n_some ((diffprop X1) X0))))
% 0.73/0.97 Defined: iii:=(fun (X0:fofType) (X1:fofType)=> (n_some ((diffprop X1) X0)))
% 0.73/0.97 FOF formula (<kernel.Constant object at 0x2abadd1f9830>, <kernel.DependentProduct object at 0x2abadd1f9f80>) of role type named typ_d_29_prop1
% 0.73/0.97 Using role type
% 0.73/0.97 Declaring d_29_prop1:(fofType->(fofType->Prop))
% 0.73/0.97 FOF formula (((eq (fofType->(fofType->Prop))) d_29_prop1) (fun (X0:fofType) (X1:fofType)=> (((or3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1)))) of role definition named def_d_29_prop1
% 0.73/0.97 A new definition: (((eq (fofType->(fofType->Prop))) d_29_prop1) (fun (X0:fofType) (X1:fofType)=> (((or3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))))
% 0.73/0.97 Defined: d_29_prop1:=(fun (X0:fofType) (X1:fofType)=> (((or3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1)))
% 0.73/0.97 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((orec3 ((n_is X0) X1)) (n_some (fun (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))))) (n_some (fun (X2:fofType)=> ((n_is X1) ((n_pl X0) X2))))))))) of role axiom named satz9
% 0.73/0.97 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((orec3 ((n_is X0) X1)) (n_some (fun (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))))) (n_some (fun (X2:fofType)=> ((n_is X1) ((n_pl X0) X2)))))))))
% 0.73/0.97 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((or3 ((n_is X0) X1)) (n_some ((diffprop X0) X1))) (n_some ((diffprop X1) X0))))))) of role axiom named satz9a
% 0.73/0.97 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((or3 ((n_is X0) X1)) (n_some ((diffprop X0) X1))) (n_some ((diffprop X1) X0)))))))
% 0.73/0.97 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((ec3 ((n_is X0) X1)) (n_some ((diffprop X0) X1))) (n_some ((diffprop X1) X0))))))) of role axiom named satz9b
% 0.73/0.97 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((ec3 ((n_is X0) X1)) (n_some ((diffprop X0) X1))) (n_some ((diffprop X1) X0)))))))
% 0.73/0.97 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((orec3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1)))))) of role axiom named satz10
% 0.73/0.97 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((orec3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))))))
% 0.73/0.97 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((or3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1)))))) of role axiom named satz10a
% 0.80/0.99 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((or3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))))))
% 0.80/0.99 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((ec3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1)))))) of role axiom named satz10b
% 0.80/0.99 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((ec3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))))))
% 0.80/0.99 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X0) X1)->((iii X1) X0)))))) of role axiom named satz11
% 0.80/0.99 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X0) X1)->((iii X1) X0))))))
% 0.80/0.99 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X0) X1)->((d_29_ii X1) X0)))))) of role axiom named satz12
% 0.80/0.99 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X0) X1)->((d_29_ii X1) X0))))))
% 0.80/0.99 FOF formula (<kernel.Constant object at 0x2abadd1f9878>, <kernel.DependentProduct object at 0x2abadd1f9f80>) of role type named typ_moreis
% 0.80/0.99 Using role type
% 0.80/0.99 Declaring moreis:(fofType->(fofType->Prop))
% 0.80/0.99 FOF formula (((eq (fofType->(fofType->Prop))) moreis) (fun (X0:fofType) (X1:fofType)=> ((l_or ((d_29_ii X0) X1)) ((n_is X0) X1)))) of role definition named def_moreis
% 0.80/0.99 A new definition: (((eq (fofType->(fofType->Prop))) moreis) (fun (X0:fofType) (X1:fofType)=> ((l_or ((d_29_ii X0) X1)) ((n_is X0) X1))))
% 0.80/0.99 Defined: moreis:=(fun (X0:fofType) (X1:fofType)=> ((l_or ((d_29_ii X0) X1)) ((n_is X0) X1)))
% 0.80/0.99 FOF formula (<kernel.Constant object at 0x2abadd1f9e18>, <kernel.DependentProduct object at 0x2abadd1f9ea8>) of role type named typ_lessis
% 0.80/0.99 Using role type
% 0.80/0.99 Declaring lessis:(fofType->(fofType->Prop))
% 0.80/0.99 FOF formula (((eq (fofType->(fofType->Prop))) lessis) (fun (X0:fofType) (X1:fofType)=> ((l_or ((iii X0) X1)) ((n_is X0) X1)))) of role definition named def_lessis
% 0.80/0.99 A new definition: (((eq (fofType->(fofType->Prop))) lessis) (fun (X0:fofType) (X1:fofType)=> ((l_or ((iii X0) X1)) ((n_is X0) X1))))
% 0.80/0.99 Defined: lessis:=(fun (X0:fofType) (X1:fofType)=> ((l_or ((iii X0) X1)) ((n_is X0) X1)))
% 0.80/0.99 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((moreis X0) X1)->((lessis X1) X0)))))) of role axiom named satz13
% 0.80/0.99 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((moreis X0) X1)->((lessis X1) X0))))))
% 0.80/0.99 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((lessis X0) X1)->((moreis X1) X0)))))) of role axiom named satz14
% 0.80/0.99 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((lessis X0) X1)->((moreis X1) X0))))))
% 0.80/0.99 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((moreis X0) X1)->(d_not ((iii X0) X1))))))) of role axiom named satz10c
% 0.80/0.99 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((moreis X0) X1)->(d_not ((iii X0) X1)))))))
% 0.80/0.99 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((lessis X0) X1)->(d_not ((d_29_ii X0) X1))))))) of role axiom named satz10d
% 0.80/1.02 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((lessis X0) X1)->(d_not ((d_29_ii X0) X1)))))))
% 0.80/1.02 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((d_29_ii X0) X1))->((lessis X0) X1)))))) of role axiom named satz10e
% 0.80/1.02 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((d_29_ii X0) X1))->((lessis X0) X1))))))
% 0.80/1.02 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((iii X0) X1))->((moreis X0) X1)))))) of role axiom named satz10f
% 0.80/1.02 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((iii X0) X1))->((moreis X0) X1))))))
% 0.80/1.02 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X0) X1)->(d_not ((lessis X0) X1))))))) of role axiom named satz10g
% 0.80/1.02 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X0) X1)->(d_not ((lessis X0) X1)))))))
% 0.80/1.02 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X0) X1)->(d_not ((moreis X0) X1))))))) of role axiom named satz10h
% 0.80/1.02 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X0) X1)->(d_not ((moreis X0) X1)))))))
% 0.80/1.02 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((moreis X0) X1))->((iii X0) X1)))))) of role axiom named satz10j
% 0.80/1.02 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((moreis X0) X1))->((iii X0) X1))))))
% 0.80/1.02 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((lessis X0) X1))->((d_29_ii X0) X1)))))) of role axiom named satz10k
% 0.80/1.02 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((lessis X0) X1))->((d_29_ii X0) X1))))))
% 0.80/1.02 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->(((iii X1) X2)->((iii X0) X2))))))))) of role axiom named satz15
% 0.80/1.02 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->(((iii X1) X2)->((iii X0) X2)))))))))
% 0.80/1.02 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->(((iii X1) X2)->((iii X0) X2))))))))) of role axiom named satz16a
% 0.80/1.02 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->(((iii X1) X2)->((iii X0) X2)))))))))
% 0.80/1.02 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->(((lessis X1) X2)->((iii X0) X2))))))))) of role axiom named satz16b
% 0.80/1.02 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->(((lessis X1) X2)->((iii X0) X2)))))))))
% 0.80/1.04 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->(((d_29_ii X1) X2)->((d_29_ii X0) X2))))))))) of role axiom named satz16c
% 0.80/1.04 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->(((d_29_ii X1) X2)->((d_29_ii X0) X2)))))))))
% 0.80/1.04 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->(((moreis X1) X2)->((d_29_ii X0) X2))))))))) of role axiom named satz16d
% 0.80/1.04 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->(((moreis X1) X2)->((d_29_ii X0) X2)))))))))
% 0.80/1.04 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->(((lessis X1) X2)->((lessis X0) X2))))))))) of role axiom named satz17
% 0.80/1.04 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->(((lessis X1) X2)->((lessis X0) X2)))))))))
% 0.80/1.04 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_29_ii ((n_pl X0) X1)) X0))))) of role axiom named satz18
% 0.80/1.04 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_29_ii ((n_pl X0) X1)) X0)))))
% 0.80/1.04 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((iii X0) ((n_pl X0) X1)))))) of role axiom named satz18a
% 0.80/1.04 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((iii X0) ((n_pl X0) X1))))))
% 0.80/1.04 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((d_29_ii (ordsucc X0)) X0))) of role axiom named satz18b
% 0.80/1.04 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((d_29_ii (ordsucc X0)) X0)))
% 0.80/1.04 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((iii X0) (ordsucc X0)))) of role axiom named satz18c
% 0.80/1.04 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((iii X0) (ordsucc X0))))
% 0.80/1.04 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X2))))))))) of role axiom named satz19a
% 0.80/1.04 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 0.80/1.04 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is X0) X1)->((n_is ((n_pl X0) X2)) ((n_pl X1) X2))))))))) of role axiom named satz19b
% 0.80/1.04 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is X0) X1)->((n_is ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 0.88/1.07 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->((iii ((n_pl X0) X2)) ((n_pl X1) X2))))))))) of role axiom named satz19c
% 0.88/1.07 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->((iii ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 0.88/1.07 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->((d_29_ii ((n_pl X2) X0)) ((n_pl X2) X1))))))))) of role axiom named satz19d
% 0.88/1.07 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->((d_29_ii ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 0.88/1.07 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is X0) X1)->((n_is ((n_pl X2) X0)) ((n_pl X2) X1))))))))) of role axiom named satz19e
% 0.88/1.07 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is X0) X1)->((n_is ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 0.88/1.07 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->((iii ((n_pl X2) X0)) ((n_pl X2) X1))))))))) of role axiom named satz19f
% 0.88/1.07 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->((iii ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 0.88/1.07 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))) of role axiom named satz19g
% 0.88/1.07 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 0.88/1.07 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X2) X0)) ((n_pl X3) X1)))))))))))) of role axiom named satz19h
% 0.88/1.07 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X2) X0)) ((n_pl X3) X1))))))))))))
% 0.88/1.07 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))) of role axiom named satz19j
% 0.90/1.10 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 0.90/1.10 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((iii X2) X3)->((iii ((n_pl X2) X0)) ((n_pl X3) X1)))))))))))) of role axiom named satz19k
% 0.90/1.10 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((iii X2) X3)->((iii ((n_pl X2) X0)) ((n_pl X3) X1))))))))))))
% 0.90/1.10 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->((moreis ((n_pl X0) X2)) ((n_pl X1) X2))))))))) of role axiom named satz19l
% 0.90/1.10 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->((moreis ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 0.90/1.10 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->((moreis ((n_pl X2) X0)) ((n_pl X2) X1))))))))) of role axiom named satz19m
% 0.90/1.10 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->((moreis ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 0.90/1.10 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->((lessis ((n_pl X0) X2)) ((n_pl X1) X2))))))))) of role axiom named satz19n
% 0.90/1.10 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->((lessis ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 0.90/1.10 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->((lessis ((n_pl X2) X0)) ((n_pl X2) X1))))))))) of role axiom named satz19o
% 0.90/1.10 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->((lessis ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 0.90/1.10 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X2))->((d_29_ii X0) X1)))))))) of role axiom named satz20a
% 0.90/1.10 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X2))->((d_29_ii X0) X1))))))))
% 0.93/1.12 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X0) X2)) ((n_pl X1) X2))->((n_is X0) X1)))))))) of role axiom named satz20b
% 0.93/1.12 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X0) X2)) ((n_pl X1) X2))->((n_is X0) X1))))))))
% 0.93/1.12 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii ((n_pl X0) X2)) ((n_pl X1) X2))->((iii X0) X1)))))))) of role axiom named satz20c
% 0.93/1.12 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii ((n_pl X0) X2)) ((n_pl X1) X2))->((iii X0) X1))))))))
% 0.93/1.12 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii ((n_pl X2) X0)) ((n_pl X2) X1))->((d_29_ii X0) X1)))))))) of role axiom named satz20d
% 0.93/1.12 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii ((n_pl X2) X0)) ((n_pl X2) X1))->((d_29_ii X0) X1))))))))
% 0.93/1.12 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X2) X0)) ((n_pl X2) X1))->((n_is X0) X1)))))))) of role axiom named satz20e
% 0.93/1.13 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X2) X0)) ((n_pl X2) X1))->((n_is X0) X1))))))))
% 0.93/1.13 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii ((n_pl X2) X0)) ((n_pl X2) X1))->((iii X0) X1)))))))) of role axiom named satz20f
% 0.93/1.13 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii ((n_pl X2) X0)) ((n_pl X2) X1))->((iii X0) X1))))))))
% 0.93/1.13 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((d_29_ii X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))) of role axiom named satz21
% 0.93/1.13 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((d_29_ii X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 0.93/1.13 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((iii X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))) of role axiom named satz21a
% 0.94/1.15 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((iii X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 0.94/1.15 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((moreis X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))) of role axiom named satz22a
% 0.94/1.15 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((moreis X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 0.94/1.15 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((d_29_ii X0) X1)->(((moreis X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))) of role axiom named satz22b
% 0.94/1.15 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((d_29_ii X0) X1)->(((moreis X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 0.94/1.15 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((lessis X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))) of role axiom named satz22c
% 0.94/1.15 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((lessis X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 0.94/1.15 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((iii X0) X1)->(((lessis X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))) of role axiom named satz22d
% 0.94/1.15 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((iii X0) X1)->(((lessis X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 0.94/1.15 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((moreis X0) X1)->(((moreis X2) X3)->((moreis ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))) of role axiom named satz23
% 0.94/1.15 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((moreis X0) X1)->(((moreis X2) X3)->((moreis ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 0.94/1.17 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((lessis X0) X1)->(((lessis X2) X3)->((lessis ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))) of role axiom named satz23a
% 0.94/1.17 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((lessis X0) X1)->(((lessis X2) X3)->((lessis ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 0.94/1.17 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((moreis X0) n_1))) of role axiom named satz24
% 0.94/1.17 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((moreis X0) n_1)))
% 0.94/1.17 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (lessis n_1)) of role axiom named satz24a
% 0.94/1.17 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (lessis n_1))
% 0.94/1.17 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((d_29_ii (ordsucc X0)) n_1))) of role axiom named satz24b
% 0.94/1.17 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((d_29_ii (ordsucc X0)) n_1)))
% 0.94/1.17 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((iii n_1) (ordsucc X0)))) of role axiom named satz24c
% 0.94/1.17 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((iii n_1) (ordsucc X0))))
% 0.94/1.17 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X1) X0)->((moreis X1) ((n_pl X0) n_1))))))) of role axiom named satz25
% 0.94/1.17 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X1) X0)->((moreis X1) ((n_pl X0) n_1)))))))
% 0.94/1.17 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X1) X0)->((moreis X1) (ordsucc X0))))))) of role axiom named satz25a
% 0.94/1.17 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X1) X0)->((moreis X1) (ordsucc X0)))))))
% 0.94/1.17 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) X0)->((lessis ((n_pl X1) n_1)) X0)))))) of role axiom named satz25b
% 0.94/1.17 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) X0)->((lessis ((n_pl X1) n_1)) X0))))))
% 0.94/1.17 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) X0)->((lessis (ordsucc X1)) X0)))))) of role axiom named satz25c
% 0.94/1.17 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) X0)->((lessis (ordsucc X1)) X0))))))
% 0.94/1.17 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) ((n_pl X0) n_1))->((lessis X1) X0)))))) of role axiom named satz26
% 0.94/1.17 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) ((n_pl X0) n_1))->((lessis X1) X0))))))
% 0.94/1.17 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) (ordsucc X0))->((lessis X1) X0)))))) of role axiom named satz26a
% 0.94/1.17 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) (ordsucc X0))->((lessis X1) X0))))))
% 0.94/1.19 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii ((n_pl X1) n_1)) X0)->((moreis X1) X0)))))) of role axiom named satz26b
% 0.94/1.19 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii ((n_pl X1) n_1)) X0)->((moreis X1) X0))))))
% 0.94/1.19 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii (ordsucc X1)) X0)->((moreis X1) X0)))))) of role axiom named satz26c
% 0.94/1.19 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii (ordsucc X1)) X0)->((moreis X1) X0))))))
% 0.94/1.19 FOF formula (<kernel.Constant object at 0x2abadd321d40>, <kernel.DependentProduct object at 0x2abadd321e18>) of role type named typ_lbprop
% 0.94/1.19 Using role type
% 0.94/1.19 Declaring lbprop:((fofType->Prop)->(fofType->(fofType->Prop)))
% 0.94/1.19 FOF formula (((eq ((fofType->Prop)->(fofType->(fofType->Prop)))) lbprop) (fun (X0:(fofType->Prop)) (X1:fofType) (X2:fofType)=> ((imp (X0 X2)) ((lessis X1) X2)))) of role definition named def_lbprop
% 0.94/1.19 A new definition: (((eq ((fofType->Prop)->(fofType->(fofType->Prop)))) lbprop) (fun (X0:(fofType->Prop)) (X1:fofType) (X2:fofType)=> ((imp (X0 X2)) ((lessis X1) X2))))
% 0.94/1.19 Defined: lbprop:=(fun (X0:(fofType->Prop)) (X1:fofType) (X2:fofType)=> ((imp (X0 X2)) ((lessis X1) X2)))
% 0.94/1.19 FOF formula (<kernel.Constant object at 0x2abadd321440>, <kernel.DependentProduct object at 0x2abadd321fc8>) of role type named typ_n_lb
% 0.94/1.19 Using role type
% 0.94/1.19 Declaring n_lb:((fofType->Prop)->(fofType->Prop))
% 0.94/1.19 FOF formula (((eq ((fofType->Prop)->(fofType->Prop))) n_lb) (fun (X0:(fofType->Prop)) (X1:fofType)=> (n_all ((lbprop X0) X1)))) of role definition named def_n_lb
% 0.94/1.19 A new definition: (((eq ((fofType->Prop)->(fofType->Prop))) n_lb) (fun (X0:(fofType->Prop)) (X1:fofType)=> (n_all ((lbprop X0) X1))))
% 0.94/1.19 Defined: n_lb:=(fun (X0:(fofType->Prop)) (X1:fofType)=> (n_all ((lbprop X0) X1)))
% 0.94/1.19 FOF formula (<kernel.Constant object at 0x2abadd321fc8>, <kernel.DependentProduct object at 0x2abadd321518>) of role type named typ_min
% 0.94/1.19 Using role type
% 0.94/1.19 Declaring min:((fofType->Prop)->(fofType->Prop))
% 0.94/1.19 FOF formula (((eq ((fofType->Prop)->(fofType->Prop))) min) (fun (X0:(fofType->Prop)) (X1:fofType)=> ((d_and ((n_lb X0) X1)) (X0 X1)))) of role definition named def_min
% 0.94/1.19 A new definition: (((eq ((fofType->Prop)->(fofType->Prop))) min) (fun (X0:(fofType->Prop)) (X1:fofType)=> ((d_and ((n_lb X0) X1)) (X0 X1))))
% 0.94/1.19 Defined: min:=(fun (X0:(fofType->Prop)) (X1:fofType)=> ((d_and ((n_lb X0) X1)) (X0 X1)))
% 0.94/1.19 FOF formula (forall (X0:(fofType->Prop)), ((n_some X0)->(n_some (min X0)))) of role axiom named satz27
% 0.94/1.19 A new axiom: (forall (X0:(fofType->Prop)), ((n_some X0)->(n_some (min X0))))
% 0.94/1.19 FOF formula (forall (X0:(fofType->Prop)), ((n_some X0)->(n_one (min X0)))) of role axiom named satz27a
% 0.94/1.19 A new axiom: (forall (X0:(fofType->Prop)), ((n_some X0)->(n_one (min X0))))
% 0.94/1.19 FOF formula (<kernel.Constant object at 0x2abadd321638>, <kernel.DependentProduct object at 0x2abae095f3b0>) of role type named typ_d_428_prop1
% 0.94/1.19 Using role type
% 0.94/1.19 Declaring d_428_prop1:(fofType->(fofType->Prop))
% 0.94/1.19 FOF formula (((eq (fofType->(fofType->Prop))) d_428_prop1) (fun (X0:fofType) (X1:fofType)=> (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) ((n_pl ((ap X1) X2)) X0)))))) of role definition named def_d_428_prop1
% 0.94/1.19 A new definition: (((eq (fofType->(fofType->Prop))) d_428_prop1) (fun (X0:fofType) (X1:fofType)=> (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) ((n_pl ((ap X1) X2)) X0))))))
% 0.94/1.19 Defined: d_428_prop1:=(fun (X0:fofType) (X1:fofType)=> (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) ((n_pl ((ap X1) X2)) X0)))))
% 0.94/1.19 FOF formula (<kernel.Constant object at 0x2abadd321518>, <kernel.DependentProduct object at 0x2abae095f128>) of role type named typ_d_428_prop2
% 0.94/1.19 Using role type
% 0.94/1.19 Declaring d_428_prop2:(fofType->(fofType->Prop))
% 0.94/1.21 FOF formula (((eq (fofType->(fofType->Prop))) d_428_prop2) (fun (X0:fofType) (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) X0)) ((d_428_prop1 X0) X1)))) of role definition named def_d_428_prop2
% 0.94/1.21 A new definition: (((eq (fofType->(fofType->Prop))) d_428_prop2) (fun (X0:fofType) (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) X0)) ((d_428_prop1 X0) X1))))
% 0.94/1.21 Defined: d_428_prop2:=(fun (X0:fofType) (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) X0)) ((d_428_prop1 X0) X1)))
% 0.94/1.21 FOF formula (<kernel.Constant object at 0x2abadd321518>, <kernel.DependentProduct object at 0x2abae095f200>) of role type named typ_d_428_prop4
% 0.94/1.21 Using role type
% 0.94/1.21 Declaring d_428_prop4:(fofType->Prop)
% 0.94/1.21 FOF formula (((eq (fofType->Prop)) d_428_prop4) (fun (X0:fofType)=> ((l_some ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_428_prop2 X0)))) of role definition named def_d_428_prop4
% 0.94/1.21 A new definition: (((eq (fofType->Prop)) d_428_prop4) (fun (X0:fofType)=> ((l_some ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_428_prop2 X0))))
% 0.94/1.21 Defined: d_428_prop4:=(fun (X0:fofType)=> ((l_some ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_428_prop2 X0)))
% 0.94/1.21 FOF formula (<kernel.Constant object at 0x2abadd321518>, <kernel.Single object at 0x2abae095f200>) of role type named typ_d_428_id
% 0.94/1.21 Using role type
% 0.94/1.21 Declaring d_428_id:fofType
% 0.94/1.21 FOF formula (((eq fofType) d_428_id) ((d_Sigma nat) (fun (X0:fofType)=> X0))) of role definition named def_d_428_id
% 0.94/1.21 A new definition: (((eq fofType) d_428_id) ((d_Sigma nat) (fun (X0:fofType)=> X0)))
% 0.94/1.21 Defined: d_428_id:=((d_Sigma nat) (fun (X0:fofType)=> X0))
% 0.94/1.21 FOF formula (<kernel.Constant object at 0x2abae095f200>, <kernel.DependentProduct object at 0x2abae095f368>) of role type named typ_d_428_g
% 0.94/1.21 Using role type
% 0.94/1.21 Declaring d_428_g:(fofType->fofType)
% 0.94/1.21 FOF formula (((eq (fofType->fofType)) d_428_g) (fun (X0:fofType)=> ((d_Sigma nat) (fun (X1:fofType)=> ((n_pl ((ap X0) X1)) X1))))) of role definition named def_d_428_g
% 0.94/1.21 A new definition: (((eq (fofType->fofType)) d_428_g) (fun (X0:fofType)=> ((d_Sigma nat) (fun (X1:fofType)=> ((n_pl ((ap X0) X1)) X1)))))
% 0.94/1.21 Defined: d_428_g:=(fun (X0:fofType)=> ((d_Sigma nat) (fun (X1:fofType)=> ((n_pl ((ap X0) X1)) X1))))
% 0.94/1.21 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((one ((d_Pi nat) (fun (X1:fofType)=> nat))) (fun (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) X0)) (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) ((n_pl ((ap X1) X2)) X0))))))))) of role axiom named satz28
% 0.94/1.21 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((one ((d_Pi nat) (fun (X1:fofType)=> nat))) (fun (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) X0)) (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) ((n_pl ((ap X1) X2)) X0)))))))))
% 0.94/1.21 FOF formula (<kernel.Constant object at 0x2abae095f0e0>, <kernel.DependentProduct object at 0x2abae095f050>) of role type named typ_times
% 0.94/1.21 Using role type
% 0.94/1.21 Declaring times:(fofType->fofType)
% 0.94/1.21 FOF formula (((eq (fofType->fofType)) times) (fun (X0:fofType)=> ((ind ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_428_prop2 X0)))) of role definition named def_times
% 0.94/1.21 A new definition: (((eq (fofType->fofType)) times) (fun (X0:fofType)=> ((ind ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_428_prop2 X0))))
% 0.94/1.21 Defined: times:=(fun (X0:fofType)=> ((ind ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_428_prop2 X0)))
% 0.94/1.21 FOF formula (<kernel.Constant object at 0x2abae095f050>, <kernel.DependentProduct object at 0x2abae095f170>) of role type named typ_n_ts
% 0.94/1.21 Using role type
% 0.94/1.21 Declaring n_ts:(fofType->(fofType->fofType))
% 0.94/1.21 FOF formula (((eq (fofType->(fofType->fofType))) n_ts) (fun (X0:fofType)=> (ap (times X0)))) of role definition named def_n_ts
% 0.94/1.21 A new definition: (((eq (fofType->(fofType->fofType))) n_ts) (fun (X0:fofType)=> (ap (times X0))))
% 0.94/1.21 Defined: n_ts:=(fun (X0:fofType)=> (ap (times X0)))
% 0.94/1.21 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_ts X0) n_1)) X0))) of role axiom named satz28a
% 0.94/1.21 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_ts X0) n_1)) X0)))
% 0.94/1.21 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_ts X0) (ordsucc X1))) ((n_pl ((n_ts X0) X1)) X0)))))) of role axiom named satz28b
% 1.03/1.22 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_ts X0) (ordsucc X1))) ((n_pl ((n_ts X0) X1)) X0))))))
% 1.03/1.22 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_ts n_1) X0)) X0))) of role axiom named satz28c
% 1.03/1.22 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_ts n_1) X0)) X0)))
% 1.03/1.22 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_ts (ordsucc X0)) X1)) ((n_pl ((n_ts X0) X1)) X1)))))) of role axiom named satz28d
% 1.03/1.22 A new axiom: ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_ts (ordsucc X0)) X1)) ((n_pl ((n_ts X0) X1)) X1))))))
% 1.03/1.22 FOF formula ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is X0) ((n_ts X0) n_1)))) of role conjecture named satz28e
% 1.03/1.22 Conjecture to prove = ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is X0) ((n_ts X0) n_1)))):Prop
% 1.03/1.22 We need to prove ['((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is X0) ((n_ts X0) n_1))))']
% 1.03/1.22 Parameter fofType:Type.
% 1.03/1.22 Definition is_of:=(fun (X0:fofType) (X1:(fofType->Prop))=> (X1 X0)):(fofType->((fofType->Prop)->Prop)).
% 1.03/1.22 Definition all_of:=(fun (X0:(fofType->Prop)) (X1:(fofType->Prop))=> (forall (X2:fofType), (((is_of X2) X0)->(X1 X2)))):((fofType->Prop)->((fofType->Prop)->Prop)).
% 1.03/1.22 Parameter eps:((fofType->Prop)->fofType).
% 1.03/1.22 Parameter in:(fofType->(fofType->Prop)).
% 1.03/1.22 Definition d_Subq:=(fun (X0:fofType) (X1:fofType)=> (forall (X2:fofType), (((in X2) X0)->((in X2) X1)))):(fofType->(fofType->Prop)).
% 1.03/1.22 Axiom set_ext:(forall (X0:fofType) (X1:fofType), (((d_Subq X0) X1)->(((d_Subq X1) X0)->(((eq fofType) X0) X1)))).
% 1.03/1.22 Axiom k_In_ind:(forall (X0:(fofType->Prop)), ((forall (X1:fofType), ((forall (X2:fofType), (((in X2) X1)->(X0 X2)))->(X0 X1)))->(forall (X1:fofType), (X0 X1)))).
% 1.03/1.22 Parameter emptyset:fofType.
% 1.03/1.22 Axiom k_EmptyAx:(((ex fofType) (fun (X0:fofType)=> ((in X0) emptyset)))->False).
% 1.03/1.22 Parameter union:(fofType->fofType).
% 1.03/1.22 Axiom k_UnionEq:(forall (X0:fofType) (X1:fofType), ((iff ((in X1) (union X0))) ((ex fofType) (fun (X2:fofType)=> ((and ((in X1) X2)) ((in X2) X0)))))).
% 1.03/1.22 Parameter power:(fofType->fofType).
% 1.03/1.22 Axiom k_PowerEq:(forall (X0:fofType) (X1:fofType), ((iff ((in X1) (power X0))) ((d_Subq X1) X0))).
% 1.03/1.22 Parameter repl:(fofType->((fofType->fofType)->fofType)).
% 1.03/1.22 Axiom k_ReplEq:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), ((iff ((in X2) ((repl X0) X1))) ((ex fofType) (fun (X3:fofType)=> ((and ((in X3) X0)) (((eq fofType) X2) (X1 X3))))))).
% 1.03/1.22 Definition d_Union_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->((in (union X1)) X0)))):(fofType->Prop).
% 1.03/1.22 Definition d_Power_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->((in (power X1)) X0)))):(fofType->Prop).
% 1.03/1.22 Definition d_Repl_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->(forall (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X1)->((in (X2 X3)) X0)))->((in ((repl X1) X2)) X0)))))):(fofType->Prop).
% 1.03/1.22 Definition d_ZF_closed:=(fun (X0:fofType)=> ((and ((and (d_Union_closed X0)) (d_Power_closed X0))) (d_Repl_closed X0))):(fofType->Prop).
% 1.03/1.22 Parameter univof:(fofType->fofType).
% 1.03/1.22 Axiom k_UnivOf_In:(forall (X0:fofType), ((in X0) (univof X0))).
% 1.03/1.22 Axiom k_UnivOf_ZF_closed:(forall (X0:fofType), (d_ZF_closed (univof X0))).
% 1.03/1.22 Definition if:=(fun (X0:Prop) (X1:fofType) (X2:fofType)=> (eps (fun (X3:fofType)=> ((or ((and X0) (((eq fofType) X3) X1))) ((and (X0->False)) (((eq fofType) X3) X2)))))):(Prop->(fofType->(fofType->fofType))).
% 1.03/1.22 Axiom if_i_correct:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((or ((and X0) (((eq fofType) (((if X0) X1) X2)) X1))) ((and (X0->False)) (((eq fofType) (((if X0) X1) X2)) X2)))).
% 1.03/1.22 Axiom if_i_0:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((X0->False)->(((eq fofType) (((if X0) X1) X2)) X2))).
% 1.03/1.22 Axiom if_i_1:(forall (X0:Prop) (X1:fofType) (X2:fofType), (X0->(((eq fofType) (((if X0) X1) X2)) X1))).
% 1.03/1.22 Axiom if_i_or:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((or (((eq fofType) (((if X0) X1) X2)) X1)) (((eq fofType) (((if X0) X1) X2)) X2))).
% 1.03/1.22 Definition nIn:=(fun (X0:fofType) (X1:fofType)=> (((in X0) X1)->False)):(fofType->(fofType->Prop)).
% 1.03/1.22 Axiom k_PowerE:(forall (X0:fofType) (X1:fofType), (((in X1) (power X0))->((d_Subq X1) X0))).
% 1.03/1.22 Axiom k_PowerI:(forall (X0:fofType) (X1:fofType), (((d_Subq X1) X0)->((in X1) (power X0)))).
% 1.03/1.22 Axiom k_Self_In_Power:(forall (X0:fofType), ((in X0) (power X0))).
% 1.03/1.22 Definition d_UPair:=(fun (X0:fofType) (X1:fofType)=> ((repl (power (power emptyset))) (fun (X2:fofType)=> (((if ((in emptyset) X2)) X0) X1)))):(fofType->(fofType->fofType)).
% 1.03/1.22 Definition d_Sing:=(fun (X0:fofType)=> ((d_UPair X0) X0)):(fofType->fofType).
% 1.03/1.22 Definition binunion:=(fun (X0:fofType) (X1:fofType)=> (union ((d_UPair X0) X1))):(fofType->(fofType->fofType)).
% 1.03/1.22 Definition famunion:=(fun (X0:fofType) (X1:(fofType->fofType))=> (union ((repl X0) X1))):(fofType->((fofType->fofType)->fofType)).
% 1.03/1.22 Definition d_Sep:=(fun (X0:fofType) (X1:(fofType->Prop))=> (((if ((ex fofType) (fun (X2:fofType)=> ((and ((in X2) X0)) (X1 X2))))) ((repl X0) (fun (X2:fofType)=> (((if (X1 X2)) X2) (eps (fun (X3:fofType)=> ((and ((in X3) X0)) (X1 X3)))))))) emptyset)):(fofType->((fofType->Prop)->fofType)).
% 1.03/1.22 Axiom k_SepI:(forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) X0)->((X1 X2)->((in X2) ((d_Sep X0) X1))))).
% 1.03/1.22 Axiom k_SepE1:(forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) ((d_Sep X0) X1))->((in X2) X0))).
% 1.03/1.22 Axiom k_SepE2:(forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) ((d_Sep X0) X1))->(X1 X2))).
% 1.03/1.22 Definition d_ReplSep:=(fun (X0:fofType) (X1:(fofType->Prop))=> (repl ((d_Sep X0) X1))):(fofType->((fofType->Prop)->((fofType->fofType)->fofType))).
% 1.03/1.22 Definition setminus:=(fun (X0:fofType) (X1:fofType)=> ((d_Sep X0) (fun (X2:fofType)=> ((nIn X2) X1)))):(fofType->(fofType->fofType)).
% 1.03/1.22 Definition d_In_rec_G:=(fun (X0:(fofType->((fofType->fofType)->fofType))) (X1:fofType) (X2:fofType)=> (forall (X3:(fofType->(fofType->Prop))), ((forall (X4:fofType) (X5:(fofType->fofType)), ((forall (X6:fofType), (((in X6) X4)->((X3 X6) (X5 X6))))->((X3 X4) ((X0 X4) X5))))->((X3 X1) X2)))):((fofType->((fofType->fofType)->fofType))->(fofType->(fofType->Prop))).
% 1.03/1.22 Definition d_In_rec:=(fun (X0:(fofType->((fofType->fofType)->fofType))) (X1:fofType)=> (eps ((d_In_rec_G X0) X1))):((fofType->((fofType->fofType)->fofType))->(fofType->fofType)).
% 1.03/1.22 Definition ordsucc:=(fun (X0:fofType)=> ((binunion X0) (d_Sing X0))):(fofType->fofType).
% 1.03/1.22 Axiom neq_ordsucc_0:(forall (X0:fofType), (not (((eq fofType) (ordsucc X0)) emptyset))).
% 1.03/1.22 Axiom ordsucc_inj:(forall (X0:fofType) (X1:fofType), ((((eq fofType) (ordsucc X0)) (ordsucc X1))->(((eq fofType) X0) X1))).
% 1.03/1.22 Axiom k_In_0_1:((in emptyset) (ordsucc emptyset)).
% 1.03/1.22 Definition nat_p:=(fun (X0:fofType)=> (forall (X1:(fofType->Prop)), ((X1 emptyset)->((forall (X2:fofType), ((X1 X2)->(X1 (ordsucc X2))))->(X1 X0))))):(fofType->Prop).
% 1.03/1.22 Axiom nat_ordsucc:(forall (X0:fofType), ((nat_p X0)->(nat_p (ordsucc X0)))).
% 1.03/1.22 Axiom nat_1:(nat_p (ordsucc emptyset)).
% 1.03/1.22 Axiom nat_ind:(forall (X0:(fofType->Prop)), ((X0 emptyset)->((forall (X1:fofType), ((nat_p X1)->((X0 X1)->(X0 (ordsucc X1)))))->(forall (X1:fofType), ((nat_p X1)->(X0 X1)))))).
% 1.03/1.22 Axiom nat_inv:(forall (X0:fofType), ((nat_p X0)->((or (((eq fofType) X0) emptyset)) ((ex fofType) (fun (X1:fofType)=> ((and (nat_p X1)) (((eq fofType) X0) (ordsucc X1)))))))).
% 1.03/1.22 Definition omega:=((d_Sep (univof emptyset)) nat_p):fofType.
% 1.03/1.22 Axiom omega_nat_p:(forall (X0:fofType), (((in X0) omega)->(nat_p X0))).
% 1.03/1.22 Axiom nat_p_omega:(forall (X0:fofType), ((nat_p X0)->((in X0) omega))).
% 1.03/1.22 Definition d_Inj1:=(d_In_rec (fun (X0:fofType) (X1:(fofType->fofType))=> ((binunion (d_Sing emptyset)) ((repl X0) X1)))):(fofType->fofType).
% 1.03/1.22 Definition d_Inj0:=(fun (X0:fofType)=> ((repl X0) d_Inj1)):(fofType->fofType).
% 1.03/1.22 Definition d_Unj:=(d_In_rec (fun (X0:fofType)=> (repl ((setminus X0) (d_Sing emptyset))))):(fofType->fofType).
% 1.03/1.22 Definition pair:=(fun (X0:fofType) (X1:fofType)=> ((binunion ((repl X0) d_Inj0)) ((repl X1) d_Inj1))):(fofType->(fofType->fofType)).
% 1.03/1.22 Definition proj0:=(fun (X0:fofType)=> (((d_ReplSep X0) (fun (X1:fofType)=> ((ex fofType) (fun (X2:fofType)=> (((eq fofType) (d_Inj0 X2)) X1))))) d_Unj)):(fofType->fofType).
% 1.03/1.22 Definition _TPTP_proj1:=(fun (X0:fofType)=> (((d_ReplSep X0) (fun (X1:fofType)=> ((ex fofType) (fun (X2:fofType)=> (((eq fofType) (d_Inj1 X2)) X1))))) d_Unj)):(fofType->fofType).
% 1.03/1.22 Axiom proj0_pair_eq:(forall (X0:fofType) (X1:fofType), (((eq fofType) (proj0 ((pair X0) X1))) X0)).
% 1.03/1.22 Axiom proj1_pair_eq:(forall (X0:fofType) (X1:fofType), (((eq fofType) (_TPTP_proj1 ((pair X0) X1))) X1)).
% 1.03/1.22 Definition d_Sigma:=(fun (X0:fofType) (X1:(fofType->fofType))=> ((famunion X0) (fun (X2:fofType)=> ((repl (X1 X2)) (pair X2))))):(fofType->((fofType->fofType)->fofType)).
% 1.03/1.22 Axiom pair_Sigma:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) X0)->(forall (X3:fofType), (((in X3) (X1 X2))->((in ((pair X2) X3)) ((d_Sigma X0) X1)))))).
% 1.03/1.22 Axiom k_Sigma_eta_proj0_proj1:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((and ((and (((eq fofType) ((pair (proj0 X2)) (_TPTP_proj1 X2))) X2)) ((in (proj0 X2)) X0))) ((in (_TPTP_proj1 X2)) (X1 (proj0 X2)))))).
% 1.03/1.22 Axiom proj_Sigma_eta:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->(((eq fofType) ((pair (proj0 X2)) (_TPTP_proj1 X2))) X2))).
% 1.03/1.22 Axiom proj0_Sigma:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((in (proj0 X2)) X0))).
% 1.03/1.22 Axiom proj1_Sigma:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((in (_TPTP_proj1 X2)) (X1 (proj0 X2))))).
% 1.03/1.22 Definition setprod:=(fun (X0:fofType) (X1:fofType)=> ((d_Sigma X0) (fun (X2:fofType)=> X1))):(fofType->(fofType->fofType)).
% 1.03/1.22 Definition ap:=(fun (X0:fofType) (X1:fofType)=> (((d_ReplSep X0) (fun (X2:fofType)=> ((ex fofType) (fun (X3:fofType)=> (((eq fofType) X2) ((pair X1) X3)))))) _TPTP_proj1)):(fofType->(fofType->fofType)).
% 1.03/1.22 Axiom beta:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) X0)->(((eq fofType) ((ap ((d_Sigma X0) X1)) X2)) (X1 X2)))).
% 1.03/1.22 Definition pair_p:=(fun (X0:fofType)=> (((eq fofType) ((pair ((ap X0) emptyset)) ((ap X0) (ordsucc emptyset)))) X0)):(fofType->Prop).
% 1.03/1.22 Definition d_Pi:=(fun (X0:fofType) (X1:(fofType->fofType))=> ((d_Sep (power ((d_Sigma X0) (fun (X2:fofType)=> (union (X1 X2)))))) (fun (X2:fofType)=> (forall (X3:fofType), (((in X3) X0)->((in ((ap X2) X3)) (X1 X3))))))):(fofType->((fofType->fofType)->fofType)).
% 1.03/1.22 Axiom lam_Pi:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X0)->((in (X2 X3)) (X1 X3))))->((in ((d_Sigma X0) X2)) ((d_Pi X0) X1)))).
% 1.03/1.22 Axiom ap_Pi:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType) (X3:fofType), (((in X2) ((d_Pi X0) X1))->(((in X3) X0)->((in ((ap X2) X3)) (X1 X3))))).
% 1.03/1.22 Axiom k_Pi_ext:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Pi X0) X1))->(forall (X3:fofType), (((in X3) ((d_Pi X0) X1))->((forall (X4:fofType), (((in X4) X0)->(((eq fofType) ((ap X2) X4)) ((ap X3) X4))))->(((eq fofType) X2) X3)))))).
% 1.03/1.22 Axiom xi_ext:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X0)->(((eq fofType) (X1 X3)) (X2 X3))))->(((eq fofType) ((d_Sigma X0) X1)) ((d_Sigma X0) X2)))).
% 1.03/1.22 Axiom k_If_In_01:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((X0->((in X1) X2))->((in (((if X0) X1) emptyset)) (((if X0) X2) (ordsucc emptyset))))).
% 1.03/1.22 Axiom k_If_In_then_E:(forall (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType), (X0->(((in X1) (((if X0) X2) X3))->((in X1) X2)))).
% 1.03/1.22 Definition imp:=(fun (X0:Prop) (X1:Prop)=> (X0->X1)):(Prop->(Prop->Prop)).
% 1.03/1.22 Definition d_not:=(fun (X0:Prop)=> ((imp X0) False)):(Prop->Prop).
% 1.03/1.22 Definition wel:=(fun (X0:Prop)=> (d_not (d_not X0))):(Prop->Prop).
% 1.03/1.22 Axiom l_et:(forall (X0:Prop), ((wel X0)->X0)).
% 1.03/1.22 Definition obvious:=((imp False) False):Prop.
% 1.03/1.22 Definition l_ec:=(fun (X0:Prop) (X1:Prop)=> ((imp X0) (d_not X1))):(Prop->(Prop->Prop)).
% 1.03/1.22 Definition d_and:=(fun (X0:Prop) (X1:Prop)=> (d_not ((l_ec X0) X1))):(Prop->(Prop->Prop)).
% 1.03/1.22 Definition l_or:=(fun (X0:Prop)=> (imp (d_not X0))):(Prop->(Prop->Prop)).
% 1.03/1.22 Definition orec:=(fun (X0:Prop) (X1:Prop)=> ((d_and ((l_or X0) X1)) ((l_ec X0) X1))):(Prop->(Prop->Prop)).
% 1.03/1.22 Definition l_iff:=(fun (X0:Prop) (X1:Prop)=> ((d_and ((imp X0) X1)) ((imp X1) X0))):(Prop->(Prop->Prop)).
% 1.03/1.22 Definition all:=(fun (X0:fofType)=> (all_of (fun (X1:fofType)=> ((in X1) X0)))):(fofType->((fofType->Prop)->Prop)).
% 1.03/1.22 Definition non:=(fun (X0:fofType) (X1:(fofType->Prop)) (X2:fofType)=> (d_not (X1 X2))):(fofType->((fofType->Prop)->(fofType->Prop))).
% 1.03/1.22 Definition l_some:=(fun (X0:fofType) (X1:(fofType->Prop))=> (d_not ((all_of (fun (X2:fofType)=> ((in X2) X0))) ((non X0) X1)))):(fofType->((fofType->Prop)->Prop)).
% 1.03/1.22 Definition or3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((l_or X0) ((l_or X1) X2))):(Prop->(Prop->(Prop->Prop))).
% 1.03/1.22 Definition and3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((d_and X0) ((d_and X1) X2))):(Prop->(Prop->(Prop->Prop))).
% 1.03/1.22 Definition ec3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> (((and3 ((l_ec X0) X1)) ((l_ec X1) X2)) ((l_ec X2) X0))):(Prop->(Prop->(Prop->Prop))).
% 1.03/1.22 Definition orec3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((d_and (((or3 X0) X1) X2)) (((ec3 X0) X1) X2))):(Prop->(Prop->(Prop->Prop))).
% 1.03/1.22 Definition e_is:=(fun (X0:fofType) (X:fofType) (Y:fofType)=> (((eq fofType) X) Y)):(fofType->(fofType->(fofType->Prop))).
% 1.03/1.22 Axiom refis:(forall (X0:fofType), ((all_of (fun (X1:fofType)=> ((in X1) X0))) (fun (X1:fofType)=> (((e_is X0) X1) X1)))).
% 1.03/1.22 Axiom e_isp:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X0))) (fun (X3:fofType)=> ((X1 X2)->((((e_is X0) X2) X3)->(X1 X3)))))))).
% 1.03/1.22 Definition amone:=(fun (X0:fofType) (X1:(fofType->Prop))=> ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X0))) (fun (X3:fofType)=> ((X1 X2)->((X1 X3)->(((e_is X0) X2) X3)))))))):(fofType->((fofType->Prop)->Prop)).
% 1.03/1.22 Definition one:=(fun (X0:fofType) (X1:(fofType->Prop))=> ((d_and ((amone X0) X1)) ((l_some X0) X1))):(fofType->((fofType->Prop)->Prop)).
% 1.03/1.22 Definition ind:=(fun (X0:fofType) (X1:(fofType->Prop))=> (eps (fun (X2:fofType)=> ((and ((in X2) X0)) (X1 X2))))):(fofType->((fofType->Prop)->fofType)).
% 1.03/1.22 Axiom ind_p:(forall (X0:fofType) (X1:(fofType->Prop)), (((one X0) X1)->((is_of ((ind X0) X1)) (fun (X2:fofType)=> ((in X2) X0))))).
% 1.03/1.22 Axiom oneax:(forall (X0:fofType) (X1:(fofType->Prop)), (((one X0) X1)->(X1 ((ind X0) X1)))).
% 1.03/1.22 Definition injective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((all X0) (fun (X4:fofType)=> ((imp (((e_is X1) ((ap X2) X3)) ((ap X2) X4))) (((e_is X0) X3) X4))))))):(fofType->(fofType->(fofType->Prop))).
% 1.03/1.22 Definition image:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((l_some X0) (fun (X4:fofType)=> (((e_is X1) X3) ((ap X2) X4))))):(fofType->(fofType->(fofType->(fofType->Prop)))).
% 1.03/1.22 Definition tofs:=(fun (X0:fofType) (X1:fofType)=> ap):(fofType->(fofType->(fofType->(fofType->fofType)))).
% 1.03/1.22 Definition soft:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((ind X0) (fun (X4:fofType)=> (((e_is X1) X3) ((ap X2) X4))))):(fofType->(fofType->(fofType->(fofType->fofType)))).
% 1.03/1.22 Definition inverse:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X1) (fun (X3:fofType)=> (((if ((((image X0) X1) X2) X3)) ((((soft X0) X1) X2) X3)) emptyset)))):(fofType->(fofType->(fofType->fofType))).
% 1.03/1.22 Definition surjective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X1) (((image X0) X1) X2))):(fofType->(fofType->(fofType->Prop))).
% 1.03/1.22 Definition bijective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_and (((injective X0) X1) X2)) (((surjective X0) X1) X2))):(fofType->(fofType->(fofType->Prop))).
% 1.03/1.22 Definition invf:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X1) (((soft X0) X1) X2))):(fofType->(fofType->(fofType->fofType))).
% 1.03/1.22 Definition inj_h:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_Sigma X0) (fun (X5:fofType)=> ((ap X4) ((ap X3) X5))))):(fofType->(fofType->(fofType->(fofType->(fofType->fofType))))).
% 1.03/1.23 Axiom e_fisi:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Pi X0) (fun (X3:fofType)=> X1))))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) ((d_Pi X0) (fun (X4:fofType)=> X1))))) (fun (X3:fofType)=> (((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> (((e_is X1) ((ap X2) X4)) ((ap X3) X4))))->(((e_is ((d_Pi X0) (fun (X4:fofType)=> X1))) X2) X3))))))).
% 1.03/1.23 Definition e_in:=(fun (X0:fofType) (X1:(fofType->Prop)) (X2:fofType)=> X2):(fofType->((fofType->Prop)->(fofType->fofType))).
% 1.03/1.23 Axiom e_in_p:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Sep X0) X1)))) (fun (X2:fofType)=> ((is_of (((e_in X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X0)))))).
% 1.03/1.23 Axiom e_inp:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Sep X0) X1)))) (fun (X2:fofType)=> (X1 (((e_in X0) X1) X2))))).
% 1.03/1.23 Axiom otax1:(forall (X0:fofType) (X1:(fofType->Prop)), (((injective ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1)))).
% 1.03/1.23 Axiom otax2:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((X1 X2)->((((image ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1))) X2))))).
% 1.03/1.23 Definition out:=(fun (X0:fofType) (X1:(fofType->Prop))=> (((soft ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1)))):(fofType->((fofType->Prop)->(fofType->fofType))).
% 1.03/1.23 Definition d_pair:=(fun (X0:fofType) (X1:fofType)=> pair):(fofType->(fofType->(fofType->(fofType->fofType)))).
% 1.03/1.23 Axiom e_pair_p:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> ((is_of ((((d_pair X0) X1) X2) X3)) (fun (X4:fofType)=> ((in X4) ((setprod X0) X1))))))))).
% 1.03/1.23 Definition first:=(fun (X0:fofType) (X1:fofType)=> proj0):(fofType->(fofType->(fofType->fofType))).
% 1.03/1.23 Axiom first_p:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> ((is_of (((first X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X0)))))).
% 1.03/1.23 Definition second:=(fun (X0:fofType) (X1:fofType)=> _TPTP_proj1):(fofType->(fofType->(fofType->fofType))).
% 1.03/1.23 Axiom second_p:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> ((is_of (((second X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X1)))))).
% 1.03/1.23 Axiom pairis1:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> (((e_is ((setprod X0) X1)) ((((d_pair X0) X1) (((first X0) X1) X2)) (((second X0) X1) X2))) X2)))).
% 1.03/1.23 Axiom firstis1:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> (((e_is X0) (((first X0) X1) ((((d_pair X0) X1) X2) X3))) X2)))))).
% 1.03/1.23 Axiom secondis1:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> (((e_is X1) (((second X0) X1) ((((d_pair X0) X1) X2) X3))) X3)))))).
% 1.03/1.23 Definition prop1:=(fun (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_and ((imp X0) (((e_is X1) X4) X2))) ((imp (d_not X0)) (((e_is X1) X4) X3)))):(Prop->(fofType->(fofType->(fofType->(fofType->Prop))))).
% 1.03/1.23 Definition ite:=(fun (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType)=> ((ind X1) ((((prop1 X0) X1) X2) X3))):(Prop->(fofType->(fofType->(fofType->fofType)))).
% 1.03/1.23 Definition wissel_wa:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((((ite (((e_is X0) X3) X1)) X0) X2) X3)):(fofType->(fofType->(fofType->(fofType->fofType)))).
% 1.03/1.23 Definition wissel_wb:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((((ite (((e_is X0) X3) X2)) X0) X1) ((((wissel_wa X0) X1) X2) X3))):(fofType->(fofType->(fofType->(fofType->fofType)))).
% 1.03/1.23 Definition wissel:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X0) (((wissel_wb X0) X1) X2))):(fofType->(fofType->(fofType->fofType))).
% 1.03/1.23 Definition changef:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_Sigma X0) (fun (X5:fofType)=> ((ap X2) ((ap (((wissel X0) X3) X4)) X5))))):(fofType->(fofType->(fofType->(fofType->(fofType->fofType))))).
% 1.03/1.23 Definition r_ec:=(fun (X0:Prop) (X1:Prop)=> (X0->(d_not X1))):(Prop->(Prop->Prop)).
% 1.03/1.23 Definition esti:=(fun (X0:fofType)=> in):(fofType->(fofType->(fofType->Prop))).
% 1.03/1.23 Axiom setof_p:(forall (X0:fofType) (X1:(fofType->Prop)), ((is_of ((d_Sep X0) X1)) (fun (X2:fofType)=> ((in X2) (power X0))))).
% 1.03/1.23 Axiom estii:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((X1 X2)->(((esti X0) X2) ((d_Sep X0) X1)))))).
% 1.03/1.23 Axiom estie:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((((esti X0) X2) ((d_Sep X0) X1))->(X1 X2))))).
% 1.03/1.23 Definition empty:=(fun (X0:fofType) (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) X0))) ((non X0) (fun (X2:fofType)=> (((esti X0) X2) X1))))):(fofType->(fofType->Prop)).
% 1.03/1.23 Definition nonempty:=(fun (X0:fofType) (X1:fofType)=> ((l_some X0) (fun (X2:fofType)=> (((esti X0) X2) X1)))):(fofType->(fofType->Prop)).
% 1.03/1.23 Definition incl:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((imp (((esti X0) X3) X1)) (((esti X0) X3) X2))))):(fofType->(fofType->(fofType->Prop))).
% 1.03/1.23 Definition st_disj:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((l_ec (((esti X0) X3) X1)) (((esti X0) X3) X2))))):(fofType->(fofType->(fofType->Prop))).
% 1.03/1.23 Axiom isseti:(forall (X0:fofType), ((all_of (fun (X1:fofType)=> ((in X1) (power X0)))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) (power X0)))) (fun (X2:fofType)=> ((((incl X0) X1) X2)->((((incl X0) X2) X1)->(((e_is (power X0)) X1) X2)))))))).
% 1.03/1.23 Definition nissetprop:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((d_and (((esti X0) X3) X1)) (d_not (((esti X0) X3) X2)))):(fofType->(fofType->(fofType->(fofType->Prop)))).
% 1.03/1.23 Definition unmore:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sep X0) (fun (X3:fofType)=> ((l_some X1) (fun (X4:fofType)=> (((esti X0) X3) ((ap X2) X4))))))):(fofType->(fofType->(fofType->fofType))).
% 1.03/1.23 Definition ecelt:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> ((d_Sep X0) (X1 X2))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType))).
% 1.03/1.23 Definition ecp:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> (((e_is (power X0)) X2) (((ecelt X0) X1) X3))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop)))).
% 1.03/1.23 Definition anec:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> ((l_some X0) (((ecp X0) X1) X2))):(fofType->((fofType->(fofType->Prop))->(fofType->Prop))).
% 1.03/1.23 Definition ect:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((d_Sep (power X0)) ((anec X0) X1))):(fofType->((fofType->(fofType->Prop))->fofType)).
% 1.03/1.23 Definition ectset:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((out (power X0)) ((anec X0) X1))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType))).
% 1.03/1.23 Definition ectelt:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> (((ectset X0) X1) (((ecelt X0) X1) X2))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType))).
% 1.03/1.23 Definition ecect:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((e_in (power X0)) ((anec X0) X1))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType))).
% 1.03/1.23 Definition fixfu:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> ((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> ((all_of (fun (X5:fofType)=> ((in X5) X0))) (fun (X5:fofType)=> (((X1 X4) X5)->(((e_is X2) ((ap X3) X4)) ((ap X3) X5)))))))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop)))).
% 1.03/1.23 Definition d_10_prop1:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType) (X5:fofType) (X6:fofType)=> ((d_and (((esti X0) X6) (((ecect X0) X1) X4))) (((e_is X2) ((ap X3) X6)) X5))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->(fofType->Prop))))))).
% 1.03/1.23 Definition prop2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType) (X5:fofType)=> ((l_some X0) ((((((d_10_prop1 X0) X1) X2) X3) X4) X5))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->Prop)))))).
% 1.03/1.23 Definition indeq:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType)=> ((ind X2) (((((prop2 X0) X1) X2) X3) X4))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->fofType))))).
% 1.03/1.23 Definition fixfu2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> ((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> ((all_of (fun (X5:fofType)=> ((in X5) X0))) (fun (X5:fofType)=> ((all_of (fun (X6:fofType)=> ((in X6) X0))) (fun (X6:fofType)=> ((all_of (fun (X7:fofType)=> ((in X7) X0))) (fun (X7:fofType)=> (((X1 X4) X5)->(((X1 X6) X7)->(((e_is X2) ((ap ((ap X3) X4)) X6)) ((ap ((ap X3) X5)) X7))))))))))))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop)))).
% 1.03/1.23 Definition d_11_i:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> (((indeq X0) X1) ((d_Pi X0) (fun (X3:fofType)=> X2)))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->fofType))))).
% 1.03/1.23 Definition indeq2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType)=> ((((indeq X0) X1) X2) (((((d_11_i X0) X1) X2) X3) X4))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->fofType)))))).
% 1.03/1.23 Definition nat:=((d_Sep omega) (fun (X0:fofType)=> (not (((eq fofType) X0) emptyset)))):fofType.
% 1.03/1.23 Definition n_is:=(e_is nat):(fofType->(fofType->Prop)).
% 1.03/1.23 Definition nis:=(fun (X0:fofType) (X1:fofType)=> (d_not ((n_is X0) X1))):(fofType->(fofType->Prop)).
% 1.03/1.23 Definition n_in:=(esti nat):(fofType->(fofType->Prop)).
% 1.03/1.23 Definition n_some:=(l_some nat):((fofType->Prop)->Prop).
% 1.03/1.23 Definition n_all:=(all nat):((fofType->Prop)->Prop).
% 1.03/1.23 Definition n_one:=(one nat):((fofType->Prop)->Prop).
% 1.03/1.23 Definition n_1:=(ordsucc emptyset):fofType.
% 1.03/1.23 Axiom n_1_p:((is_of n_1) (fun (X0:fofType)=> ((in X0) nat))).
% 1.03/1.23 Axiom suc_p:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((is_of (ordsucc X0)) (fun (X1:fofType)=> ((in X1) nat))))).
% 1.03/1.23 Axiom n_ax3:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((nis (ordsucc X0)) n_1))).
% 1.03/1.23 Axiom n_ax4:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((n_is (ordsucc X0)) (ordsucc X1))->((n_is X0) X1)))))).
% 1.03/1.23 Definition cond1:=(n_in n_1):(fofType->Prop).
% 1.03/1.23 Definition cond2:=(fun (X0:fofType)=> (n_all (fun (X1:fofType)=> ((imp ((n_in X1) X0)) ((n_in (ordsucc X1)) X0))))):(fofType->Prop).
% 1.03/1.23 Axiom n_ax5:((all_of (fun (X0:fofType)=> ((in X0) (power nat)))) (fun (X0:fofType)=> ((cond1 X0)->((cond2 X0)->((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_in X1) X0))))))).
% 1.03/1.23 Definition i1_s:=(d_Sep nat):((fofType->Prop)->fofType).
% 1.03/1.23 Axiom satz1:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((nis X0) X1)->((nis (ordsucc X0)) (ordsucc X1))))))).
% 1.03/1.23 Definition d_22_prop1:=(fun (X0:fofType)=> ((nis (ordsucc X0)) X0)):(fofType->Prop).
% 1.03/1.23 Axiom satz2:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((nis (ordsucc X0)) X0))).
% 1.03/1.23 Definition d_23_prop1:=(fun (X0:fofType)=> ((l_or ((n_is X0) n_1)) (n_some (fun (X1:fofType)=> ((n_is X0) (ordsucc X1)))))):(fofType->Prop).
% 1.03/1.23 Axiom satz3:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> (((nis X0) n_1)->(n_some (fun (X1:fofType)=> ((n_is X0) (ordsucc X1))))))).
% 1.03/1.23 Axiom satz3a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> (((nis X0) n_1)->(n_one (fun (X1:fofType)=> ((n_is X0) (ordsucc X1))))))).
% 1.03/1.23 Definition d_24_prop1:=(fun (X0:fofType)=> (n_all (fun (X1:fofType)=> ((n_is ((ap X0) (ordsucc X1))) (ordsucc ((ap X0) X1)))))):(fofType->Prop).
% 1.03/1.23 Definition d_24_prop2:=(fun (X0:fofType) (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) (ordsucc X0))) (d_24_prop1 X1))):(fofType->(fofType->Prop)).
% 1.03/1.23 Definition prop3:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is ((ap X0) X2)) ((ap X1) X2))):(fofType->(fofType->(fofType->Prop))).
% 1.03/1.23 Definition prop4:=(fun (X0:fofType)=> ((l_some ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_24_prop2 X0))):(fofType->Prop).
% 1.03/1.23 Definition d_24_g:=(fun (X0:fofType)=> ((d_Sigma nat) (fun (X1:fofType)=> (ordsucc ((ap X0) X1))))):(fofType->fofType).
% 1.03/1.23 Axiom satz4:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((one ((d_Pi nat) (fun (X1:fofType)=> nat))) (fun (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) (ordsucc X0))) (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) (ordsucc ((ap X1) X2)))))))))).
% 1.03/1.23 Definition plus:=(fun (X0:fofType)=> ((ind ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_24_prop2 X0))):(fofType->fofType).
% 1.03/1.23 Definition n_pl:=(fun (X0:fofType)=> (ap (plus X0))):(fofType->(fofType->fofType)).
% 1.03/1.23 Axiom satz4a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_pl X0) n_1)) (ordsucc X0)))).
% 1.03/1.23 Axiom satz4b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl X0) (ordsucc X1))) (ordsucc ((n_pl X0) X1))))))).
% 1.03/1.23 Axiom satz4c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_pl n_1) X0)) (ordsucc X0)))).
% 1.03/1.23 Axiom satz4d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl (ordsucc X0)) X1)) (ordsucc ((n_pl X0) X1))))))).
% 1.03/1.23 Axiom satz4e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is (ordsucc X0)) ((n_pl X0) n_1)))).
% 1.03/1.23 Axiom satz4f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is (ordsucc ((n_pl X0) X1))) ((n_pl X0) (ordsucc X1))))))).
% 1.03/1.23 Axiom satz4g:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is (ordsucc X0)) ((n_pl n_1) X0)))).
% 1.03/1.23 Axiom satz4h:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is (ordsucc ((n_pl X0) X1))) ((n_pl (ordsucc X0)) X1)))))).
% 1.03/1.23 Definition d_25_prop1:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is ((n_pl ((n_pl X0) X1)) X2)) ((n_pl X0) ((n_pl X1) X2)))):(fofType->(fofType->(fofType->Prop))).
% 1.03/1.23 Axiom satz5:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((n_is ((n_pl ((n_pl X0) X1)) X2)) ((n_pl X0) ((n_pl X1) X2))))))))).
% 1.03/1.23 Definition d_26_prop1:=(fun (X0:fofType) (X1:fofType)=> ((n_is ((n_pl X0) X1)) ((n_pl X1) X0))):(fofType->(fofType->Prop)).
% 1.03/1.23 Axiom satz6:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl X0) X1)) ((n_pl X1) X0)))))).
% 1.03/1.23 Definition d_27_prop1:=(fun (X0:fofType) (X1:fofType)=> ((nis X1) ((n_pl X0) X1))):(fofType->(fofType->Prop)).
% 1.03/1.23 Axiom satz7:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((nis X1) ((n_pl X0) X1)))))).
% 1.03/1.23 Definition d_28_prop1:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((nis ((n_pl X0) X1)) ((n_pl X0) X2))):(fofType->(fofType->(fofType->Prop))).
% 1.03/1.23 Axiom satz8:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((nis X1) X2)->((nis ((n_pl X0) X1)) ((n_pl X0) X2))))))))).
% 1.03/1.23 Axiom satz8a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X0) X1)) ((n_pl X0) X2))->((n_is X1) X2)))))))).
% 1.03/1.23 Definition diffprop:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))):(fofType->(fofType->(fofType->Prop))).
% 1.03/1.24 Axiom satz8b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((amone nat) (fun (X2:fofType)=> ((n_is X0) ((n_pl X1) X2)))))))).
% 1.03/1.24 Definition d_29_ii:=(fun (X0:fofType) (X1:fofType)=> (n_some ((diffprop X0) X1))):(fofType->(fofType->Prop)).
% 1.03/1.24 Definition iii:=(fun (X0:fofType) (X1:fofType)=> (n_some ((diffprop X1) X0))):(fofType->(fofType->Prop)).
% 1.03/1.24 Definition d_29_prop1:=(fun (X0:fofType) (X1:fofType)=> (((or3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))):(fofType->(fofType->Prop)).
% 1.03/1.24 Axiom satz9:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((orec3 ((n_is X0) X1)) (n_some (fun (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))))) (n_some (fun (X2:fofType)=> ((n_is X1) ((n_pl X0) X2))))))))).
% 1.03/1.24 Axiom satz9a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((or3 ((n_is X0) X1)) (n_some ((diffprop X0) X1))) (n_some ((diffprop X1) X0))))))).
% 1.03/1.24 Axiom satz9b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((ec3 ((n_is X0) X1)) (n_some ((diffprop X0) X1))) (n_some ((diffprop X1) X0))))))).
% 1.03/1.24 Axiom satz10:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((orec3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1)))))).
% 1.03/1.24 Axiom satz10a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((or3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1)))))).
% 1.03/1.24 Axiom satz10b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((ec3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1)))))).
% 1.03/1.24 Axiom satz11:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X0) X1)->((iii X1) X0)))))).
% 1.03/1.24 Axiom satz12:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X0) X1)->((d_29_ii X1) X0)))))).
% 1.03/1.24 Definition moreis:=(fun (X0:fofType) (X1:fofType)=> ((l_or ((d_29_ii X0) X1)) ((n_is X0) X1))):(fofType->(fofType->Prop)).
% 1.03/1.24 Definition lessis:=(fun (X0:fofType) (X1:fofType)=> ((l_or ((iii X0) X1)) ((n_is X0) X1))):(fofType->(fofType->Prop)).
% 1.03/1.24 Axiom satz13:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((moreis X0) X1)->((lessis X1) X0)))))).
% 1.03/1.24 Axiom satz14:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((lessis X0) X1)->((moreis X1) X0)))))).
% 1.03/1.24 Axiom satz10c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((moreis X0) X1)->(d_not ((iii X0) X1))))))).
% 1.03/1.24 Axiom satz10d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((lessis X0) X1)->(d_not ((d_29_ii X0) X1))))))).
% 1.03/1.24 Axiom satz10e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((d_29_ii X0) X1))->((lessis X0) X1)))))).
% 1.03/1.24 Axiom satz10f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((iii X0) X1))->((moreis X0) X1)))))).
% 1.03/1.24 Axiom satz10g:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X0) X1)->(d_not ((lessis X0) X1))))))).
% 1.03/1.24 Axiom satz10h:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X0) X1)->(d_not ((moreis X0) X1))))))).
% 1.03/1.24 Axiom satz10j:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((moreis X0) X1))->((iii X0) X1)))))).
% 1.03/1.24 Axiom satz10k:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((lessis X0) X1))->((d_29_ii X0) X1)))))).
% 1.03/1.24 Axiom satz15:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->(((iii X1) X2)->((iii X0) X2))))))))).
% 1.03/1.24 Axiom satz16a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->(((iii X1) X2)->((iii X0) X2))))))))).
% 1.03/1.24 Axiom satz16b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->(((lessis X1) X2)->((iii X0) X2))))))))).
% 1.03/1.24 Axiom satz16c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->(((d_29_ii X1) X2)->((d_29_ii X0) X2))))))))).
% 1.03/1.24 Axiom satz16d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->(((moreis X1) X2)->((d_29_ii X0) X2))))))))).
% 1.03/1.24 Axiom satz17:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->(((lessis X1) X2)->((lessis X0) X2))))))))).
% 1.03/1.24 Axiom satz18:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_29_ii ((n_pl X0) X1)) X0))))).
% 1.03/1.24 Axiom satz18a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((iii X0) ((n_pl X0) X1)))))).
% 1.03/1.24 Axiom satz18b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((d_29_ii (ordsucc X0)) X0))).
% 1.03/1.24 Axiom satz18c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((iii X0) (ordsucc X0)))).
% 1.03/1.24 Axiom satz19a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X2))))))))).
% 1.03/1.24 Axiom satz19b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is X0) X1)->((n_is ((n_pl X0) X2)) ((n_pl X1) X2))))))))).
% 1.03/1.24 Axiom satz19c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->((iii ((n_pl X0) X2)) ((n_pl X1) X2))))))))).
% 1.03/1.24 Axiom satz19d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->((d_29_ii ((n_pl X2) X0)) ((n_pl X2) X1))))))))).
% 1.03/1.24 Axiom satz19e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is X0) X1)->((n_is ((n_pl X2) X0)) ((n_pl X2) X1))))))))).
% 1.03/1.24 Axiom satz19f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->((iii ((n_pl X2) X0)) ((n_pl X2) X1))))))))).
% 1.03/1.24 Axiom satz19g:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))).
% 1.03/1.24 Axiom satz19h:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X2) X0)) ((n_pl X3) X1)))))))))))).
% 1.03/1.24 Axiom satz19j:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))).
% 1.03/1.24 Axiom satz19k:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((iii X2) X3)->((iii ((n_pl X2) X0)) ((n_pl X3) X1)))))))))))).
% 1.03/1.24 Axiom satz19l:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->((moreis ((n_pl X0) X2)) ((n_pl X1) X2))))))))).
% 1.03/1.24 Axiom satz19m:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->((moreis ((n_pl X2) X0)) ((n_pl X2) X1))))))))).
% 1.03/1.24 Axiom satz19n:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->((lessis ((n_pl X0) X2)) ((n_pl X1) X2))))))))).
% 1.03/1.24 Axiom satz19o:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->((lessis ((n_pl X2) X0)) ((n_pl X2) X1))))))))).
% 1.03/1.24 Axiom satz20a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X2))->((d_29_ii X0) X1)))))))).
% 1.03/1.24 Axiom satz20b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X0) X2)) ((n_pl X1) X2))->((n_is X0) X1)))))))).
% 1.03/1.24 Axiom satz20c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii ((n_pl X0) X2)) ((n_pl X1) X2))->((iii X0) X1)))))))).
% 1.03/1.24 Axiom satz20d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii ((n_pl X2) X0)) ((n_pl X2) X1))->((d_29_ii X0) X1)))))))).
% 1.03/1.24 Axiom satz20e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X2) X0)) ((n_pl X2) X1))->((n_is X0) X1)))))))).
% 1.03/1.24 Axiom satz20f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii ((n_pl X2) X0)) ((n_pl X2) X1))->((iii X0) X1)))))))).
% 1.03/1.24 Axiom satz21:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((d_29_ii X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))).
% 1.03/1.24 Axiom satz21a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((iii X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))).
% 1.03/1.24 Axiom satz22a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((moreis X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))).
% 1.03/1.24 Axiom satz22b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((d_29_ii X0) X1)->(((moreis X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))).
% 1.03/1.24 Axiom satz22c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((lessis X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))).
% 1.03/1.24 Axiom satz22d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((iii X0) X1)->(((lessis X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))).
% 1.03/1.24 Axiom satz23:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((moreis X0) X1)->(((moreis X2) X3)->((moreis ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))).
% 1.03/1.24 Axiom satz23a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((lessis X0) X1)->(((lessis X2) X3)->((lessis ((n_pl X0) X2)) ((n_pl X1) X3)))))))))))).
% 1.03/1.24 Axiom satz24:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((moreis X0) n_1))).
% 1.03/1.24 Axiom satz24a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (lessis n_1)).
% 1.03/1.24 Axiom satz24b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((d_29_ii (ordsucc X0)) n_1))).
% 1.03/1.24 Axiom satz24c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((iii n_1) (ordsucc X0)))).
% 1.03/1.24 Axiom satz25:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X1) X0)->((moreis X1) ((n_pl X0) n_1))))))).
% 1.03/1.24 Axiom satz25a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X1) X0)->((moreis X1) (ordsucc X0))))))).
% 1.03/1.24 Axiom satz25b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) X0)->((lessis ((n_pl X1) n_1)) X0)))))).
% 208.54/208.77 Axiom satz25c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) X0)->((lessis (ordsucc X1)) X0)))))).
% 208.54/208.77 Axiom satz26:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) ((n_pl X0) n_1))->((lessis X1) X0)))))).
% 208.54/208.77 Axiom satz26a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) (ordsucc X0))->((lessis X1) X0)))))).
% 208.54/208.77 Axiom satz26b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii ((n_pl X1) n_1)) X0)->((moreis X1) X0)))))).
% 208.54/208.77 Axiom satz26c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii (ordsucc X1)) X0)->((moreis X1) X0)))))).
% 208.54/208.77 Definition lbprop:=(fun (X0:(fofType->Prop)) (X1:fofType) (X2:fofType)=> ((imp (X0 X2)) ((lessis X1) X2))):((fofType->Prop)->(fofType->(fofType->Prop))).
% 208.54/208.77 Definition n_lb:=(fun (X0:(fofType->Prop)) (X1:fofType)=> (n_all ((lbprop X0) X1))):((fofType->Prop)->(fofType->Prop)).
% 208.54/208.77 Definition min:=(fun (X0:(fofType->Prop)) (X1:fofType)=> ((d_and ((n_lb X0) X1)) (X0 X1))):((fofType->Prop)->(fofType->Prop)).
% 208.54/208.77 Axiom satz27:(forall (X0:(fofType->Prop)), ((n_some X0)->(n_some (min X0)))).
% 208.54/208.77 Axiom satz27a:(forall (X0:(fofType->Prop)), ((n_some X0)->(n_one (min X0)))).
% 208.54/208.77 Definition d_428_prop1:=(fun (X0:fofType) (X1:fofType)=> (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) ((n_pl ((ap X1) X2)) X0))))):(fofType->(fofType->Prop)).
% 208.54/208.77 Definition d_428_prop2:=(fun (X0:fofType) (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) X0)) ((d_428_prop1 X0) X1))):(fofType->(fofType->Prop)).
% 208.54/208.77 Definition d_428_prop4:=(fun (X0:fofType)=> ((l_some ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_428_prop2 X0))):(fofType->Prop).
% 208.54/208.77 Definition d_428_id:=((d_Sigma nat) (fun (X0:fofType)=> X0)):fofType.
% 208.54/208.77 Definition d_428_g:=(fun (X0:fofType)=> ((d_Sigma nat) (fun (X1:fofType)=> ((n_pl ((ap X0) X1)) X1)))):(fofType->fofType).
% 208.54/208.77 Axiom satz28:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((one ((d_Pi nat) (fun (X1:fofType)=> nat))) (fun (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) X0)) (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) ((n_pl ((ap X1) X2)) X0))))))))).
% 208.54/208.77 Definition times:=(fun (X0:fofType)=> ((ind ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_428_prop2 X0))):(fofType->fofType).
% 208.54/208.77 Definition n_ts:=(fun (X0:fofType)=> (ap (times X0))):(fofType->(fofType->fofType)).
% 208.54/208.77 Axiom satz28a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_ts X0) n_1)) X0))).
% 208.54/208.77 Axiom satz28b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_ts X0) (ordsucc X1))) ((n_pl ((n_ts X0) X1)) X0)))))).
% 208.54/208.77 Axiom satz28c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_ts n_1) X0)) X0))).
% 208.54/208.77 Axiom satz28d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_ts (ordsucc X0)) X1)) ((n_pl ((n_ts X0) X1)) X1)))))).
% 208.54/208.77 Trying to prove ((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is X0) ((n_ts X0) n_1))))
% 208.54/208.77 --- does not match type in application fofType vs Prop in (((e_in X0) X1) ((all_of (fun X0:fofType=> ((in X0) nat))) (fun X0:fofType=> ((n_is X0) ((n_ts X0) n_1)))))
% 208.54/208.77 ---context
% 208.54/208.77 False:Prop
% 208.54/208.77 False_rect:(forall (P:Type), (False->P))
% 208.54/208.77 I:True
% 208.54/208.77 NNPP:=(fun (P:Prop) (H:(not (not P)))=> ((fun (C:((or P) (not P)))=> ((((((or_ind P) (not P)) P) (fun (H0:P)=> H0)) (fun (N:(not P))=> ((False_rect P) (H N)))) C)) (classic P))):(forall (P:Prop), ((not (not P))->P))
% 208.54/208.77 True:Prop
% 208.54/208.77 _TPTP_proj1:=(fun (X0:fofType)=> (((d_ReplSep X0) (fun (X1:fofType)=> ((ex fofType) (fun (X2:fofType)=> (((eq fofType) (d_Inj1 X2)) X1))))) d_Unj)):(fofType->fofType)
% 208.54/208.77 all:=(fun (X0:fofType)=> (all_of (fun (X1:fofType)=> ((in X1) X0)))):(fofType->((fofType->Prop)->Prop))
% 208.54/208.77 all_of:=(fun (X0:(fofType->Prop)) (X1:(fofType->Prop))=> (forall (X2:fofType), (((is_of X2) X0)->(X1 X2)))):((fofType->Prop)->((fofType->Prop)->Prop))
% 208.54/208.77 amone:=(fun (X0:fofType) (X1:(fofType->Prop))=> ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X0))) (fun (X3:fofType)=> ((X1 X2)->((X1 X3)->(((e_is X0) X2) X3)))))))):(fofType->((fofType->Prop)->Prop))
% 208.54/208.77 and3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((d_and X0) ((d_and X1) X2))):(Prop->(Prop->(Prop->Prop)))
% 208.54/208.77 and:(Prop->(Prop->Prop))
% 208.54/208.77 and_comm_i:=(fun (A:Prop) (B:Prop) (H:((and A) B))=> ((((conj B) A) (((proj2 A) B) H)) (((proj1 A) B) H))):(forall (A:Prop) (B:Prop), (((and A) B)->((and B) A)))
% 208.54/208.77 and_rect:=(fun (A:Prop) (B:Prop) (P:Type) (X:(A->(B->P))) (H:((and A) B))=> ((X (((proj1 A) B) H)) (((proj2 A) B) H))):(forall (A:Prop) (B:Prop) (P:Type), ((A->(B->P))->(((and A) B)->P)))
% 208.54/208.77 anec:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> ((l_some X0) (((ecp X0) X1) X2))):(fofType->((fofType->(fofType->Prop))->(fofType->Prop)))
% 208.54/208.77 ap:=(fun (X0:fofType) (X1:fofType)=> (((d_ReplSep X0) (fun (X2:fofType)=> ((ex fofType) (fun (X3:fofType)=> (((eq fofType) X2) ((pair X1) X3)))))) _TPTP_proj1)):(fofType->(fofType->fofType))
% 208.54/208.77 ap_Pi:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType) (X3:fofType), (((in X2) ((d_Pi X0) X1))->(((in X3) X0)->((in ((ap X2) X3)) (X1 X3)))))
% 208.54/208.77 beta:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) X0)->(((eq fofType) ((ap ((d_Sigma X0) X1)) X2)) (X1 X2))))
% 208.54/208.77 bijective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_and (((injective X0) X1) X2)) (((surjective X0) X1) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.77 binunion:=(fun (X0:fofType) (X1:fofType)=> (union ((d_UPair X0) X1))):(fofType->(fofType->fofType))
% 208.54/208.77 changef:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_Sigma X0) (fun (X5:fofType)=> ((ap X2) ((ap (((wissel X0) X3) X4)) X5))))):(fofType->(fofType->(fofType->(fofType->(fofType->fofType)))))
% 208.54/208.77 choice:=(fun (A:Type) (B:Type) (R:(A->(B->Prop))) (x:(forall (x:A), ((ex B) (fun (y:B)=> ((R x) y)))))=> (((fun (P:Prop) (x0:(forall (x0:(A->(B->Prop))), (((and ((((subrelation A) B) x0) R)) (forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y))))))->P)))=> (((((ex_ind (A->(B->Prop))) (fun (R':(A->(B->Prop)))=> ((and ((((subrelation A) B) R') R)) (forall (x0:A), ((ex B) ((unique B) (fun (y:B)=> ((R' x0) y)))))))) P) x0) ((((relational_choice A) B) R) x))) ((ex (A->B)) (fun (f:(A->B))=> (forall (x0:A), ((R x0) (f x0)))))) (fun (x0:(A->(B->Prop))) (x1:((and ((((subrelation A) B) x0) R)) (forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y)))))))=> (((fun (P:Type) (x2:(((((subrelation A) B) x0) R)->((forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y)))))->P)))=> (((((and_rect ((((subrelation A) B) x0) R)) (forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y)))))) P) x2) x1)) ((ex (A->B)) (fun (f:(A->B))=> (forall (x0:A), ((R x0) (f x0)))))) (fun (x2:((((subrelation A) B) x0) R)) (x3:(forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y))))))=> (((fun (P:Prop) (x4:(forall (x1:(A->B)), ((forall (x10:A), ((x0 x10) (x1 x10)))->P)))=> (((((ex_ind (A->B)) (fun (f:(A->B))=> (forall (x1:A), ((x0 x1) (f x1))))) P) x4) ((((unique_choice A) B) x0) x3))) ((ex (A->B)) (fun (f:(A->B))=> (forall (x0:A), ((R x0) (f x0)))))) (fun (x4:(A->B)) (x5:(forall (x10:A), ((x0 x10) (x4 x10))))=> ((((ex_intro (A->B)) (fun (f:(A->B))=> (forall (x0:A), ((R x0) (f x0))))) x4) (fun (x00:A)=> (((x2 x00) (x4 x00)) (x5 x00))))))))))):(forall (A:Type) (B:Type) (R:(A->(B->Prop))), ((forall (x:A), ((ex B) (fun (y:B)=> ((R x) y))))->((ex (A->B)) (fun (f:(A->B))=> (forall (x:A), ((R x) (f x)))))))
% 208.54/208.77 choice_operator:=(fun (A:Type) (a:A)=> ((((classical_choice (A->Prop)) A) (fun (x3:(A->Prop))=> x3)) a)):(forall (A:Type), (A->((ex ((A->Prop)->A)) (fun (co:((A->Prop)->A))=> (forall (P:(A->Prop)), (((ex A) (fun (x:A)=> (P x)))->(P (co P))))))))
% 208.54/208.77 classic:(forall (P:Prop), ((or P) (not P)))
% 208.54/208.77 classical_choice:=(fun (A:Type) (B:Type) (R:(A->(B->Prop))) (b:B)=> ((fun (C:((forall (x:A), ((ex B) (fun (y:B)=> (((fun (x0:A) (y0:B)=> (((ex B) (fun (z:B)=> ((R x0) z)))->((R x0) y0))) x) y))))->((ex (A->B)) (fun (f:(A->B))=> (forall (x:A), (((fun (x0:A) (y:B)=> (((ex B) (fun (z:B)=> ((R x0) z)))->((R x0) y))) x) (f x)))))))=> (C (fun (x:A)=> ((fun (C0:((or ((ex B) (fun (z:B)=> ((R x) z)))) (not ((ex B) (fun (z:B)=> ((R x) z))))))=> ((((((or_ind ((ex B) (fun (z:B)=> ((R x) z)))) (not ((ex B) (fun (z:B)=> ((R x) z))))) ((ex B) (fun (y:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y))))) ((((ex_ind B) (fun (z:B)=> ((R x) z))) ((ex B) (fun (y:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y))))) (fun (y:B) (H:((R x) y))=> ((((ex_intro B) (fun (y0:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y0)))) y) (fun (_:((ex B) (fun (z:B)=> ((R x) z))))=> H))))) (fun (N:(not ((ex B) (fun (z:B)=> ((R x) z)))))=> ((((ex_intro B) (fun (y:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y)))) b) (fun (H:((ex B) (fun (z:B)=> ((R x) z))))=> ((False_rect ((R x) b)) (N H)))))) C0)) (classic ((ex B) (fun (z:B)=> ((R x) z)))))))) (((choice A) B) (fun (x:A) (y:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y)))))):(forall (A:Type) (B:Type) (R:(A->(B->Prop))), (B->((ex (A->B)) (fun (f:(A->B))=> (forall (x:A), (((ex B) (fun (y:B)=> ((R x) y)))->((R x) (f x))))))))
% 208.54/208.77 cond1:=(n_in n_1):(fofType->Prop)
% 208.54/208.77 cond2:=(fun (X0:fofType)=> (n_all (fun (X1:fofType)=> ((imp ((n_in X1) X0)) ((n_in (ordsucc X1)) X0))))):(fofType->Prop)
% 208.54/208.77 conj:(forall (A:Prop) (B:Prop), (A->(B->((and A) B))))
% 208.54/208.77 d_10_prop1:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType) (X5:fofType) (X6:fofType)=> ((d_and (((esti X0) X6) (((ecect X0) X1) X4))) (((e_is X2) ((ap X3) X6)) X5))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->(fofType->Prop)))))))
% 208.54/208.77 d_11_i:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> (((indeq X0) X1) ((d_Pi X0) (fun (X3:fofType)=> X2)))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->fofType)))))
% 208.54/208.77 d_22_prop1:=(fun (X0:fofType)=> ((nis (ordsucc X0)) X0)):(fofType->Prop)
% 208.54/208.77 d_23_prop1:=(fun (X0:fofType)=> ((l_or ((n_is X0) n_1)) (n_some (fun (X1:fofType)=> ((n_is X0) (ordsucc X1)))))):(fofType->Prop)
% 208.54/208.77 d_24_g:=(fun (X0:fofType)=> ((d_Sigma nat) (fun (X1:fofType)=> (ordsucc ((ap X0) X1))))):(fofType->fofType)
% 208.54/208.77 d_24_prop1:=(fun (X0:fofType)=> (n_all (fun (X1:fofType)=> ((n_is ((ap X0) (ordsucc X1))) (ordsucc ((ap X0) X1)))))):(fofType->Prop)
% 208.54/208.77 d_24_prop2:=(fun (X0:fofType) (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) (ordsucc X0))) (d_24_prop1 X1))):(fofType->(fofType->Prop))
% 208.54/208.77 d_25_prop1:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is ((n_pl ((n_pl X0) X1)) X2)) ((n_pl X0) ((n_pl X1) X2)))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.77 d_26_prop1:=(fun (X0:fofType) (X1:fofType)=> ((n_is ((n_pl X0) X1)) ((n_pl X1) X0))):(fofType->(fofType->Prop))
% 208.54/208.77 d_27_prop1:=(fun (X0:fofType) (X1:fofType)=> ((nis X1) ((n_pl X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.77 d_28_prop1:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((nis ((n_pl X0) X1)) ((n_pl X0) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.77 d_29_ii:=(fun (X0:fofType) (X1:fofType)=> (n_some ((diffprop X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.77 d_29_prop1:=(fun (X0:fofType) (X1:fofType)=> (((or3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.77 d_428_g:=(fun (X0:fofType)=> ((d_Sigma nat) (fun (X1:fofType)=> ((n_pl ((ap X0) X1)) X1)))):(fofType->fofType)
% 208.54/208.77 d_428_id:=((d_Sigma nat) (fun (X0:fofType)=> X0)):fofType
% 208.54/208.77 d_428_prop1:=(fun (X0:fofType) (X1:fofType)=> (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) ((n_pl ((ap X1) X2)) X0))))):(fofType->(fofType->Prop))
% 208.54/208.77 d_428_prop2:=(fun (X0:fofType) (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) X0)) ((d_428_prop1 X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.77 d_428_prop4:=(fun (X0:fofType)=> ((l_some ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_428_prop2 X0))):(fofType->Prop)
% 208.54/208.77 d_In_rec:=(fun (X0:(fofType->((fofType->fofType)->fofType))) (X1:fofType)=> (eps ((d_In_rec_G X0) X1))):((fofType->((fofType->fofType)->fofType))->(fofType->fofType))
% 208.54/208.77 d_In_rec_G:=(fun (X0:(fofType->((fofType->fofType)->fofType))) (X1:fofType) (X2:fofType)=> (forall (X3:(fofType->(fofType->Prop))), ((forall (X4:fofType) (X5:(fofType->fofType)), ((forall (X6:fofType), (((in X6) X4)->((X3 X6) (X5 X6))))->((X3 X4) ((X0 X4) X5))))->((X3 X1) X2)))):((fofType->((fofType->fofType)->fofType))->(fofType->(fofType->Prop)))
% 208.54/208.77 d_Inj0:=(fun (X0:fofType)=> ((repl X0) d_Inj1)):(fofType->fofType)
% 208.54/208.77 d_Inj1:=(d_In_rec (fun (X0:fofType) (X1:(fofType->fofType))=> ((binunion (d_Sing emptyset)) ((repl X0) X1)))):(fofType->fofType)
% 208.54/208.77 d_Pi:=(fun (X0:fofType) (X1:(fofType->fofType))=> ((d_Sep (power ((d_Sigma X0) (fun (X2:fofType)=> (union (X1 X2)))))) (fun (X2:fofType)=> (forall (X3:fofType), (((in X3) X0)->((in ((ap X2) X3)) (X1 X3))))))):(fofType->((fofType->fofType)->fofType))
% 208.54/208.77 d_Power_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->((in (power X1)) X0)))):(fofType->Prop)
% 208.54/208.77 d_ReplSep:=(fun (X0:fofType) (X1:(fofType->Prop))=> (repl ((d_Sep X0) X1))):(fofType->((fofType->Prop)->((fofType->fofType)->fofType)))
% 208.54/208.77 d_Repl_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->(forall (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X1)->((in (X2 X3)) X0)))->((in ((repl X1) X2)) X0)))))):(fofType->Prop)
% 208.54/208.77 d_Sep:=(fun (X0:fofType) (X1:(fofType->Prop))=> (((if ((ex fofType) (fun (X2:fofType)=> ((and ((in X2) X0)) (X1 X2))))) ((repl X0) (fun (X2:fofType)=> (((if (X1 X2)) X2) (eps (fun (X3:fofType)=> ((and ((in X3) X0)) (X1 X3)))))))) emptyset)):(fofType->((fofType->Prop)->fofType))
% 208.54/208.77 d_Sigma:=(fun (X0:fofType) (X1:(fofType->fofType))=> ((famunion X0) (fun (X2:fofType)=> ((repl (X1 X2)) (pair X2))))):(fofType->((fofType->fofType)->fofType))
% 208.54/208.77 d_Sing:=(fun (X0:fofType)=> ((d_UPair X0) X0)):(fofType->fofType)
% 208.54/208.77 d_Subq:=(fun (X0:fofType) (X1:fofType)=> (forall (X2:fofType), (((in X2) X0)->((in X2) X1)))):(fofType->(fofType->Prop))
% 208.54/208.77 d_UPair:=(fun (X0:fofType) (X1:fofType)=> ((repl (power (power emptyset))) (fun (X2:fofType)=> (((if ((in emptyset) X2)) X0) X1)))):(fofType->(fofType->fofType))
% 208.54/208.77 d_Union_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->((in (union X1)) X0)))):(fofType->Prop)
% 208.54/208.77 d_Unj:=(d_In_rec (fun (X0:fofType)=> (repl ((setminus X0) (d_Sing emptyset))))):(fofType->fofType)
% 208.54/208.77 d_ZF_closed:=(fun (X0:fofType)=> ((and ((and (d_Union_closed X0)) (d_Power_closed X0))) (d_Repl_closed X0))):(fofType->Prop)
% 208.54/208.77 d_and:=(fun (X0:Prop) (X1:Prop)=> (d_not ((l_ec X0) X1))):(Prop->(Prop->Prop))
% 208.54/208.77 d_not:=(fun (X0:Prop)=> ((imp X0) False)):(Prop->Prop)
% 208.54/208.77 d_pair:=(fun (X0:fofType) (X1:fofType)=> pair):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.54/208.77 dependent_unique_choice:(forall (A:Type) (B:(A->Type)) (R:(forall (x:A), ((B x)->Prop))), ((forall (x:A), ((ex (B x)) ((unique (B x)) (fun (y:(B x))=> ((R x) y)))))->((ex (forall (x:A), (B x))) (fun (f:(forall (x:A), (B x)))=> (forall (x:A), ((R x) (f x)))))))
% 208.54/208.77 diffprop:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.77 e_fisi:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Pi X0) (fun (X3:fofType)=> X1))))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) ((d_Pi X0) (fun (X4:fofType)=> X1))))) (fun (X3:fofType)=> (((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> (((e_is X1) ((ap X2) X4)) ((ap X3) X4))))->(((e_is ((d_Pi X0) (fun (X4:fofType)=> X1))) X2) X3)))))))
% 208.54/208.77 e_in:=(fun (X0:fofType) (X1:(fofType->Prop)) (X2:fofType)=> X2):(fofType->((fofType->Prop)->(fofType->fofType)))
% 208.54/208.77 e_in_p:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Sep X0) X1)))) (fun (X2:fofType)=> ((is_of (((e_in X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X0))))))
% 208.54/208.77 e_inp:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Sep X0) X1)))) (fun (X2:fofType)=> (X1 (((e_in X0) X1) X2)))))
% 208.54/208.77 e_is:=(fun (X0:fofType) (X:fofType) (Y:fofType)=> (((eq fofType) X) Y)):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.77 e_isp:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X0))) (fun (X3:fofType)=> ((X1 X2)->((((e_is X0) X2) X3)->(X1 X3))))))))
% 208.54/208.77 e_pair_p:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> ((is_of ((((d_pair X0) X1) X2) X3)) (fun (X4:fofType)=> ((in X4) ((setprod X0) X1)))))))))
% 208.54/208.77 ec3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> (((and3 ((l_ec X0) X1)) ((l_ec X1) X2)) ((l_ec X2) X0))):(Prop->(Prop->(Prop->Prop)))
% 208.54/208.77 ecect:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((e_in (power X0)) ((anec X0) X1))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 208.54/208.77 ecelt:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> ((d_Sep X0) (X1 X2))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 208.54/208.77 ecp:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> (((e_is (power X0)) X2) (((ecelt X0) X1) X3))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))
% 208.54/208.77 ect:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((d_Sep (power X0)) ((anec X0) X1))):(fofType->((fofType->(fofType->Prop))->fofType))
% 208.54/208.77 ectelt:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> (((ectset X0) X1) (((ecelt X0) X1) X2))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 208.54/208.77 ectset:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((out (power X0)) ((anec X0) X1))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 208.54/208.77 empty:=(fun (X0:fofType) (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) X0))) ((non X0) (fun (X2:fofType)=> (((esti X0) X2) X1))))):(fofType->(fofType->Prop))
% 208.54/208.77 emptyset:fofType
% 208.54/208.77 eps:((fofType->Prop)->fofType)
% 208.54/208.77 eq:=(fun (T:Type) (a:T) (b:T)=> (forall (P:(T->Prop)), ((P a)->(P b)))):(forall (T:Type), (T->(T->Prop)))
% 208.54/208.77 eq_ref:=(fun (T:Type) (a:T) (P:(T->Prop)) (x:(P a))=> x):(forall (T:Type) (a:T), (((eq T) a) a))
% 208.54/208.77 eq_stepl:=(fun (T:Type) (a:T) (b:T) (c:T) (X:(((eq T) a) b)) (Y:(((eq T) a) c))=> ((((((eq_trans T) c) a) b) ((((eq_sym T) a) c) Y)) X)):(forall (T:Type) (a:T) (b:T) (c:T), ((((eq T) a) b)->((((eq T) a) c)->(((eq T) c) b))))
% 208.54/208.77 eq_substitution:=(fun (T:Type) (U:Type) (a:T) (b:T) (f:(T->U)) (H:(((eq T) a) b))=> ((H (fun (x:T)=> (((eq U) (f a)) (f x)))) ((eq_ref U) (f a)))):(forall (T:Type) (U:Type) (a:T) (b:T) (f:(T->U)), ((((eq T) a) b)->(((eq U) (f a)) (f b))))
% 208.54/208.77 eq_sym:=(fun (T:Type) (a:T) (b:T) (H:(((eq T) a) b))=> ((H (fun (x:T)=> (((eq T) x) a))) ((eq_ref T) a))):(forall (T:Type) (a:T) (b:T), ((((eq T) a) b)->(((eq T) b) a)))
% 208.54/208.77 eq_trans:=(fun (T:Type) (a:T) (b:T) (c:T) (X:(((eq T) a) b)) (Y:(((eq T) b) c))=> ((Y (fun (t:T)=> (((eq T) a) t))) X)):(forall (T:Type) (a:T) (b:T) (c:T), ((((eq T) a) b)->((((eq T) b) c)->(((eq T) a) c))))
% 208.54/208.77 esti:=(fun (X0:fofType)=> in):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.77 estie:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((((esti X0) X2) ((d_Sep X0) X1))->(X1 X2)))))
% 208.54/208.77 estii:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((X1 X2)->(((esti X0) X2) ((d_Sep X0) X1))))))
% 208.54/208.77 eta_expansion:=(fun (A:Type) (B:Type)=> ((eta_expansion_dep A) (fun (x1:A)=> B))):(forall (A:Type) (B:Type) (f:(A->B)), (((eq (A->B)) f) (fun (x:A)=> (f x))))
% 208.54/208.77 eta_expansion_dep:=(fun (A:Type) (B:(A->Type)) (f:(forall (x:A), (B x)))=> (((((functional_extensionality_dep A) (fun (x1:A)=> (B x1))) f) (fun (x:A)=> (f x))) (fun (x:A) (P:((B x)->Prop)) (x0:(P (f x)))=> x0))):(forall (A:Type) (B:(A->Type)) (f:(forall (x:A), (B x))), (((eq (forall (x:A), (B x))) f) (fun (x:A)=> (f x))))
% 208.54/208.77 ex:(forall (A:Type), ((A->Prop)->Prop))
% 208.54/208.77 ex_ind:(forall (A:Type) (F:(A->Prop)) (P:Prop), ((forall (x:A), ((F x)->P))->(((ex A) F)->P)))
% 208.54/208.77 ex_intro:(forall (A:Type) (P:(A->Prop)) (x:A), ((P x)->((ex A) P)))
% 208.54/208.77 famunion:=(fun (X0:fofType) (X1:(fofType->fofType))=> (union ((repl X0) X1))):(fofType->((fofType->fofType)->fofType))
% 208.54/208.77 first:=(fun (X0:fofType) (X1:fofType)=> proj0):(fofType->(fofType->(fofType->fofType)))
% 208.54/208.77 first_p:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> ((is_of (((first X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X0))))))
% 208.54/208.77 firstis1:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> (((e_is X0) (((first X0) X1) ((((d_pair X0) X1) X2) X3))) X2))))))
% 208.54/208.77 fixfu2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> ((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> ((all_of (fun (X5:fofType)=> ((in X5) X0))) (fun (X5:fofType)=> ((all_of (fun (X6:fofType)=> ((in X6) X0))) (fun (X6:fofType)=> ((all_of (fun (X7:fofType)=> ((in X7) X0))) (fun (X7:fofType)=> (((X1 X4) X5)->(((X1 X6) X7)->(((e_is X2) ((ap ((ap X3) X4)) X6)) ((ap ((ap X3) X5)) X7))))))))))))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))
% 208.54/208.77 fixfu:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> ((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> ((all_of (fun (X5:fofType)=> ((in X5) X0))) (fun (X5:fofType)=> (((X1 X4) X5)->(((e_is X2) ((ap X3) X4)) ((ap X3) X5)))))))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))
% 208.54/208.77 fofType:Type
% 208.54/208.77 functional_extensionality:=(fun (A:Type) (B:Type)=> ((functional_extensionality_dep A) (fun (x1:A)=> B))):(forall (A:Type) (B:Type) (f:(A->B)) (g:(A->B)), ((forall (x:A), (((eq B) (f x)) (g x)))->(((eq (A->B)) f) g)))
% 208.54/208.77 functional_extensionality_dep:(forall (A:Type) (B:(A->Type)) (f:(forall (x:A), (B x))) (g:(forall (x:A), (B x))), ((forall (x:A), (((eq (B x)) (f x)) (g x)))->(((eq (forall (x:A), (B x))) f) g)))
% 208.54/208.77 functional_extensionality_double:=(fun (A:Type) (B:Type) (C:Type) (f:(A->(B->C))) (g:(A->(B->C))) (x:(forall (x:A) (y:B), (((eq C) ((f x) y)) ((g x) y))))=> (((((functional_extensionality_dep A) (fun (x2:A)=> (B->C))) f) g) (fun (x0:A)=> (((((functional_extensionality_dep B) (fun (x3:B)=> C)) (f x0)) (g x0)) (x x0))))):(forall (A:Type) (B:Type) (C:Type) (f:(A->(B->C))) (g:(A->(B->C))), ((forall (x:A) (y:B), (((eq C) ((f x) y)) ((g x) y)))->(((eq (A->(B->C))) f) g)))
% 208.54/208.77 i1_s:=(d_Sep nat):((fofType->Prop)->fofType)
% 208.54/208.77 if:=(fun (X0:Prop) (X1:fofType) (X2:fofType)=> (eps (fun (X3:fofType)=> ((or ((and X0) (((eq fofType) X3) X1))) ((and (X0->False)) (((eq fofType) X3) X2)))))):(Prop->(fofType->(fofType->fofType)))
% 208.54/208.77 if_i_0:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((X0->False)->(((eq fofType) (((if X0) X1) X2)) X2)))
% 208.54/208.77 if_i_1:(forall (X0:Prop) (X1:fofType) (X2:fofType), (X0->(((eq fofType) (((if X0) X1) X2)) X1)))
% 208.54/208.77 if_i_correct:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((or ((and X0) (((eq fofType) (((if X0) X1) X2)) X1))) ((and (X0->False)) (((eq fofType) (((if X0) X1) X2)) X2))))
% 208.54/208.77 if_i_or:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((or (((eq fofType) (((if X0) X1) X2)) X1)) (((eq fofType) (((if X0) X1) X2)) X2)))
% 208.54/208.77 iff:=(fun (A:Prop) (B:Prop)=> ((and (A->B)) (B->A))):(Prop->(Prop->Prop))
% 208.54/208.77 iff_refl:=(fun (A:Prop)=> ((((conj (A->A)) (A->A)) (fun (H:A)=> H)) (fun (H:A)=> H))):(forall (P:Prop), ((iff P) P))
% 208.54/208.77 iff_sym:=(fun (A:Prop) (B:Prop) (H:((iff A) B))=> ((((conj (B->A)) (A->B)) (((proj2 (A->B)) (B->A)) H)) (((proj1 (A->B)) (B->A)) H))):(forall (A:Prop) (B:Prop), (((iff A) B)->((iff B) A)))
% 208.54/208.77 iff_trans:=(fun (A:Prop) (B:Prop) (C:Prop) (AB:((iff A) B)) (BC:((iff B) C))=> ((((conj (A->C)) (C->A)) (fun (x:A)=> ((((proj1 (B->C)) (C->B)) BC) ((((proj1 (A->B)) (B->A)) AB) x)))) (fun (x:C)=> ((((proj2 (A->B)) (B->A)) AB) ((((proj2 (B->C)) (C->B)) BC) x))))):(forall (A:Prop) (B:Prop) (C:Prop), (((iff A) B)->(((iff B) C)->((iff A) C))))
% 208.54/208.77 iii:=(fun (X0:fofType) (X1:fofType)=> (n_some ((diffprop X1) X0))):(fofType->(fofType->Prop))
% 208.54/208.77 image:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((l_some X0) (fun (X4:fofType)=> (((e_is X1) X3) ((ap X2) X4))))):(fofType->(fofType->(fofType->(fofType->Prop))))
% 208.54/208.77 imp:=(fun (X0:Prop) (X1:Prop)=> (X0->X1)):(Prop->(Prop->Prop))
% 208.54/208.77 in:(fofType->(fofType->Prop))
% 208.54/208.77 incl:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((imp (((esti X0) X3) X1)) (((esti X0) X3) X2))))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.77 ind:=(fun (X0:fofType) (X1:(fofType->Prop))=> (eps (fun (X2:fofType)=> ((and ((in X2) X0)) (X1 X2))))):(fofType->((fofType->Prop)->fofType))
% 208.54/208.77 ind_p:(forall (X0:fofType) (X1:(fofType->Prop)), (((one X0) X1)->((is_of ((ind X0) X1)) (fun (X2:fofType)=> ((in X2) X0)))))
% 208.54/208.77 indeq2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType)=> ((((indeq X0) X1) X2) (((((d_11_i X0) X1) X2) X3) X4))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->fofType))))))
% 208.54/208.77 indeq:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType)=> ((ind X2) (((((prop2 X0) X1) X2) X3) X4))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->fofType)))))
% 208.54/208.77 inj_h:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_Sigma X0) (fun (X5:fofType)=> ((ap X4) ((ap X3) X5))))):(fofType->(fofType->(fofType->(fofType->(fofType->fofType)))))
% 208.54/208.77 injective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((all X0) (fun (X4:fofType)=> ((imp (((e_is X1) ((ap X2) X3)) ((ap X2) X4))) (((e_is X0) X3) X4))))))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.77 inverse:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X1) (fun (X3:fofType)=> (((if ((((image X0) X1) X2) X3)) ((((soft X0) X1) X2) X3)) emptyset)))):(fofType->(fofType->(fofType->fofType)))
% 208.54/208.77 invf:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X1) (((soft X0) X1) X2))):(fofType->(fofType->(fofType->fofType)))
% 208.54/208.77 is_of:=(fun (X0:fofType) (X1:(fofType->Prop))=> (X1 X0)):(fofType->((fofType->Prop)->Prop))
% 208.54/208.77 isseti:(forall (X0:fofType), ((all_of (fun (X1:fofType)=> ((in X1) (power X0)))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) (power X0)))) (fun (X2:fofType)=> ((((incl X0) X1) X2)->((((incl X0) X2) X1)->(((e_is (power X0)) X1) X2))))))))
% 208.54/208.77 ite:=(fun (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType)=> ((ind X1) ((((prop1 X0) X1) X2) X3))):(Prop->(fofType->(fofType->(fofType->fofType))))
% 208.54/208.77 k_EmptyAx:(((ex fofType) (fun (X0:fofType)=> ((in X0) emptyset)))->False)
% 208.54/208.77 k_If_In_01:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((X0->((in X1) X2))->((in (((if X0) X1) emptyset)) (((if X0) X2) (ordsucc emptyset)))))
% 208.54/208.77 k_If_In_then_E:(forall (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType), (X0->(((in X1) (((if X0) X2) X3))->((in X1) X2))))
% 208.54/208.77 k_In_0_1:((in emptyset) (ordsucc emptyset))
% 208.54/208.77 k_In_ind:(forall (X0:(fofType->Prop)), ((forall (X1:fofType), ((forall (X2:fofType), (((in X2) X1)->(X0 X2)))->(X0 X1)))->(forall (X1:fofType), (X0 X1))))
% 208.54/208.77 k_Pi_ext:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Pi X0) X1))->(forall (X3:fofType), (((in X3) ((d_Pi X0) X1))->((forall (X4:fofType), (((in X4) X0)->(((eq fofType) ((ap X2) X4)) ((ap X3) X4))))->(((eq fofType) X2) X3))))))
% 208.54/208.77 k_PowerE:(forall (X0:fofType) (X1:fofType), (((in X1) (power X0))->((d_Subq X1) X0)))
% 208.54/208.77 k_PowerEq:(forall (X0:fofType) (X1:fofType), ((iff ((in X1) (power X0))) ((d_Subq X1) X0)))
% 208.54/208.77 k_PowerI:(forall (X0:fofType) (X1:fofType), (((d_Subq X1) X0)->((in X1) (power X0))))
% 208.54/208.77 k_ReplEq:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), ((iff ((in X2) ((repl X0) X1))) ((ex fofType) (fun (X3:fofType)=> ((and ((in X3) X0)) (((eq fofType) X2) (X1 X3)))))))
% 208.54/208.77 k_Self_In_Power:(forall (X0:fofType), ((in X0) (power X0)))
% 208.54/208.77 k_SepE1:(forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) ((d_Sep X0) X1))->((in X2) X0)))
% 208.54/208.77 k_SepE2:(forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) ((d_Sep X0) X1))->(X1 X2)))
% 208.54/208.77 k_SepI:(forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) X0)->((X1 X2)->((in X2) ((d_Sep X0) X1)))))
% 208.54/208.77 k_Sigma_eta_proj0_proj1:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((and ((and (((eq fofType) ((pair (proj0 X2)) (_TPTP_proj1 X2))) X2)) ((in (proj0 X2)) X0))) ((in (_TPTP_proj1 X2)) (X1 (proj0 X2))))))
% 208.54/208.77 k_UnionEq:(forall (X0:fofType) (X1:fofType), ((iff ((in X1) (union X0))) ((ex fofType) (fun (X2:fofType)=> ((and ((in X1) X2)) ((in X2) X0))))))
% 208.54/208.77 k_UnivOf_In:(forall (X0:fofType), ((in X0) (univof X0)))
% 208.54/208.77 k_UnivOf_ZF_closed:(forall (X0:fofType), (d_ZF_closed (univof X0)))
% 208.54/208.77 l_ec:=(fun (X0:Prop) (X1:Prop)=> ((imp X0) (d_not X1))):(Prop->(Prop->Prop))
% 208.54/208.77 l_et:(forall (X0:Prop), ((wel X0)->X0))
% 208.54/208.77 l_iff:=(fun (X0:Prop) (X1:Prop)=> ((d_and ((imp X0) X1)) ((imp X1) X0))):(Prop->(Prop->Prop))
% 208.54/208.77 l_or:=(fun (X0:Prop)=> (imp (d_not X0))):(Prop->(Prop->Prop))
% 208.54/208.77 l_some:=(fun (X0:fofType) (X1:(fofType->Prop))=> (d_not ((all_of (fun (X2:fofType)=> ((in X2) X0))) ((non X0) X1)))):(fofType->((fofType->Prop)->Prop))
% 208.54/208.77 lam_Pi:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X0)->((in (X2 X3)) (X1 X3))))->((in ((d_Sigma X0) X2)) ((d_Pi X0) X1))))
% 208.54/208.77 lbprop:=(fun (X0:(fofType->Prop)) (X1:fofType) (X2:fofType)=> ((imp (X0 X2)) ((lessis X1) X2))):((fofType->Prop)->(fofType->(fofType->Prop)))
% 208.54/208.77 lessis:=(fun (X0:fofType) (X1:fofType)=> ((l_or ((iii X0) X1)) ((n_is X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.77 min:=(fun (X0:(fofType->Prop)) (X1:fofType)=> ((d_and ((n_lb X0) X1)) (X0 X1))):((fofType->Prop)->(fofType->Prop))
% 208.54/208.77 moreis:=(fun (X0:fofType) (X1:fofType)=> ((l_or ((d_29_ii X0) X1)) ((n_is X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.77 nIn:=(fun (X0:fofType) (X1:fofType)=> (((in X0) X1)->False)):(fofType->(fofType->Prop))
% 208.54/208.77 n_1:=(ordsucc emptyset):fofType
% 208.54/208.77 n_1_p:((is_of n_1) (fun (X0:fofType)=> ((in X0) nat)))
% 208.54/208.77 n_all:=(all nat):((fofType->Prop)->Prop)
% 208.54/208.77 n_ax3:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((nis (ordsucc X0)) n_1)))
% 208.54/208.77 n_ax4:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((n_is (ordsucc X0)) (ordsucc X1))->((n_is X0) X1))))))
% 208.54/208.77 n_ax5:((all_of (fun (X0:fofType)=> ((in X0) (power nat)))) (fun (X0:fofType)=> ((cond1 X0)->((cond2 X0)->((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_in X1) X0)))))))
% 208.54/208.77 n_in:=(esti nat):(fofType->(fofType->Prop))
% 208.54/208.77 n_is:=(e_is nat):(fofType->(fofType->Prop))
% 208.54/208.77 n_lb:=(fun (X0:(fofType->Prop)) (X1:fofType)=> (n_all ((lbprop X0) X1))):((fofType->Prop)->(fofType->Prop))
% 208.54/208.77 n_one:=(one nat):((fofType->Prop)->Prop)
% 208.54/208.77 n_pl:=(fun (X0:fofType)=> (ap (plus X0))):(fofType->(fofType->fofType))
% 208.54/208.77 n_some:=(l_some nat):((fofType->Prop)->Prop)
% 208.54/208.77 n_ts:=(fun (X0:fofType)=> (ap (times X0))):(fofType->(fofType->fofType))
% 208.54/208.77 nat:=((d_Sep omega) (fun (X0:fofType)=> (not (((eq fofType) X0) emptyset)))):fofType
% 208.54/208.77 nat_1:(nat_p (ordsucc emptyset))
% 208.54/208.77 nat_ind:(forall (X0:(fofType->Prop)), ((X0 emptyset)->((forall (X1:fofType), ((nat_p X1)->((X0 X1)->(X0 (ordsucc X1)))))->(forall (X1:fofType), ((nat_p X1)->(X0 X1))))))
% 208.54/208.77 nat_inv:(forall (X0:fofType), ((nat_p X0)->((or (((eq fofType) X0) emptyset)) ((ex fofType) (fun (X1:fofType)=> ((and (nat_p X1)) (((eq fofType) X0) (ordsucc X1))))))))
% 208.54/208.77 nat_ordsucc:(forall (X0:fofType), ((nat_p X0)->(nat_p (ordsucc X0))))
% 208.54/208.77 nat_p:=(fun (X0:fofType)=> (forall (X1:(fofType->Prop)), ((X1 emptyset)->((forall (X2:fofType), ((X1 X2)->(X1 (ordsucc X2))))->(X1 X0))))):(fofType->Prop)
% 208.54/208.77 nat_p_omega:(forall (X0:fofType), ((nat_p X0)->((in X0) omega)))
% 208.54/208.77 neq_ordsucc_0:(forall (X0:fofType), (not (((eq fofType) (ordsucc X0)) emptyset)))
% 208.54/208.77 nis:=(fun (X0:fofType) (X1:fofType)=> (d_not ((n_is X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.77 nissetprop:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((d_and (((esti X0) X3) X1)) (d_not (((esti X0) X3) X2)))):(fofType->(fofType->(fofType->(fofType->Prop))))
% 208.54/208.77 non:=(fun (X0:fofType) (X1:(fofType->Prop)) (X2:fofType)=> (d_not (X1 X2))):(fofType->((fofType->Prop)->(fofType->Prop)))
% 208.54/208.77 nonempty:=(fun (X0:fofType) (X1:fofType)=> ((l_some X0) (fun (X2:fofType)=> (((esti X0) X2) X1)))):(fofType->(fofType->Prop))
% 208.54/208.77 not:=(fun (P:Prop)=> (P->False)):(Prop->Prop)
% 208.54/208.77 obvious:=((imp False) False):Prop
% 208.54/208.77 omega:=((d_Sep (univof emptyset)) nat_p):fofType
% 208.54/208.77 omega_nat_p:(forall (X0:fofType), (((in X0) omega)->(nat_p X0)))
% 208.54/208.77 one:=(fun (X0:fofType) (X1:(fofType->Prop))=> ((d_and ((amone X0) X1)) ((l_some X0) X1))):(fofType->((fofType->Prop)->Prop))
% 208.54/208.77 oneax:(forall (X0:fofType) (X1:(fofType->Prop)), (((one X0) X1)->(X1 ((ind X0) X1))))
% 208.54/208.77 or3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((l_or X0) ((l_or X1) X2))):(Prop->(Prop->(Prop->Prop)))
% 208.54/208.77 or:(Prop->(Prop->Prop))
% 208.54/208.77 or_comm_i:=(fun (A:Prop) (B:Prop) (H:((or A) B))=> ((((((or_ind A) B) ((or B) A)) ((or_intror B) A)) ((or_introl B) A)) H)):(forall (A:Prop) (B:Prop), (((or A) B)->((or B) A)))
% 208.54/208.77 or_first:=(fun (A:Prop) (B:Prop)=> (((((or_ind A) B) ((B->A)->A)) (fun (x:A) (x0:(B->A))=> x)) (fun (x:B) (x0:(B->A))=> (x0 x)))):(forall (A:Prop) (B:Prop), (((or A) B)->((B->A)->A)))
% 208.54/208.77 or_ind:(forall (A:Prop) (B:Prop) (P:Prop), ((A->P)->((B->P)->(((or A) B)->P))))
% 208.54/208.77 or_introl:(forall (A:Prop) (B:Prop), (A->((or A) B)))
% 208.54/208.77 or_intror:(forall (A:Prop) (B:Prop), (B->((or A) B)))
% 208.54/208.77 or_second:=(fun (A:Prop) (B:Prop) (x:((or A) B))=> (((or_first B) A) (((or_comm_i A) B) x))):(forall (A:Prop) (B:Prop), (((or A) B)->((A->B)->B)))
% 208.54/208.77 ordsucc:=(fun (X0:fofType)=> ((binunion X0) (d_Sing X0))):(fofType->fofType)
% 208.54/208.77 ordsucc_inj:(forall (X0:fofType) (X1:fofType), ((((eq fofType) (ordsucc X0)) (ordsucc X1))->(((eq fofType) X0) X1)))
% 208.54/208.77 orec3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((d_and (((or3 X0) X1) X2)) (((ec3 X0) X1) X2))):(Prop->(Prop->(Prop->Prop)))
% 208.54/208.77 orec:=(fun (X0:Prop) (X1:Prop)=> ((d_and ((l_or X0) X1)) ((l_ec X0) X1))):(Prop->(Prop->Prop))
% 208.54/208.77 otax1:(forall (X0:fofType) (X1:(fofType->Prop)), (((injective ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1))))
% 208.54/208.77 otax2:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((X1 X2)->((((image ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1))) X2)))))
% 208.54/208.77 out:=(fun (X0:fofType) (X1:(fofType->Prop))=> (((soft ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1)))):(fofType->((fofType->Prop)->(fofType->fofType)))
% 208.54/208.77 pair:=(fun (X0:fofType) (X1:fofType)=> ((binunion ((repl X0) d_Inj0)) ((repl X1) d_Inj1))):(fofType->(fofType->fofType))
% 208.54/208.77 pair_Sigma:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) X0)->(forall (X3:fofType), (((in X3) (X1 X2))->((in ((pair X2) X3)) ((d_Sigma X0) X1))))))
% 208.54/208.77 pair_p:=(fun (X0:fofType)=> (((eq fofType) ((pair ((ap X0) emptyset)) ((ap X0) (ordsucc emptyset)))) X0)):(fofType->Prop)
% 208.54/208.77 pairis1:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> (((e_is ((setprod X0) X1)) ((((d_pair X0) X1) (((first X0) X1) X2)) (((second X0) X1) X2))) X2))))
% 208.54/208.77 plus:=(fun (X0:fofType)=> ((ind ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_24_prop2 X0))):(fofType->fofType)
% 208.54/208.77 power:(fofType->fofType)
% 208.54/208.77 proj0:=(fun (X0:fofType)=> (((d_ReplSep X0) (fun (X1:fofType)=> ((ex fofType) (fun (X2:fofType)=> (((eq fofType) (d_Inj0 X2)) X1))))) d_Unj)):(fofType->fofType)
% 208.54/208.77 proj0_Sigma:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((in (proj0 X2)) X0)))
% 208.54/208.77 proj0_pair_eq:(forall (X0:fofType) (X1:fofType), (((eq fofType) (proj0 ((pair X0) X1))) X0))
% 208.54/208.77 proj1:(forall (A:Prop) (B:Prop), (((and A) B)->A))
% 208.54/208.77 proj1_Sigma:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((in (_TPTP_proj1 X2)) (X1 (proj0 X2)))))
% 208.54/208.77 proj1_pair_eq:(forall (X0:fofType) (X1:fofType), (((eq fofType) (_TPTP_proj1 ((pair X0) X1))) X1))
% 208.54/208.77 proj2:(forall (A:Prop) (B:Prop), (((and A) B)->B))
% 208.54/208.77 proj_Sigma_eta:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->(((eq fofType) ((pair (proj0 X2)) (_TPTP_proj1 X2))) X2)))
% 208.54/208.77 prop1:=(fun (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_and ((imp X0) (((e_is X1) X4) X2))) ((imp (d_not X0)) (((e_is X1) X4) X3)))):(Prop->(fofType->(fofType->(fofType->(fofType->Prop)))))
% 208.54/208.77 prop2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType) (X5:fofType)=> ((l_some X0) ((((((d_10_prop1 X0) X1) X2) X3) X4) X5))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->Prop))))))
% 208.54/208.77 prop3:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is ((ap X0) X2)) ((ap X1) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.77 prop4:=(fun (X0:fofType)=> ((l_some ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_24_prop2 X0))):(fofType->Prop)
% 208.54/208.77 r_ec:=(fun (X0:Prop) (X1:Prop)=> (X0->(d_not X1))):(Prop->(Prop->Prop))
% 208.54/208.77 refis:(forall (X0:fofType), ((all_of (fun (X1:fofType)=> ((in X1) X0))) (fun (X1:fofType)=> (((e_is X0) X1) X1))))
% 208.54/208.77 relational_choice:(forall (A:Type) (B:Type) (R:(A->(B->Prop))), ((forall (x:A), ((ex B) (fun (y:B)=> ((R x) y))))->((ex (A->(B->Prop))) (fun (R':(A->(B->Prop)))=> ((and ((((subrelation A) B) R') R)) (forall (x:A), ((ex B) ((unique B) (fun (y:B)=> ((R' x) y))))))))))
% 208.54/208.77 repl:(fofType->((fofType->fofType)->fofType))
% 208.54/208.77 satz10:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((orec3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))))))
% 208.54/208.77 satz10a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((or3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))))))
% 208.54/208.77 satz10b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((ec3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))))))
% 208.54/208.77 satz10c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((moreis X0) X1)->(d_not ((iii X0) X1)))))))
% 208.54/208.77 satz10d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((lessis X0) X1)->(d_not ((d_29_ii X0) X1)))))))
% 208.54/208.77 satz10e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((d_29_ii X0) X1))->((lessis X0) X1))))))
% 208.54/208.77 satz10f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((iii X0) X1))->((moreis X0) X1))))))
% 208.54/208.77 satz10g:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X0) X1)->(d_not ((lessis X0) X1)))))))
% 208.54/208.77 satz10h:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X0) X1)->(d_not ((moreis X0) X1)))))))
% 208.54/208.77 satz10j:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((moreis X0) X1))->((iii X0) X1))))))
% 208.54/208.77 satz10k:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((lessis X0) X1))->((d_29_ii X0) X1))))))
% 208.54/208.77 satz11:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X0) X1)->((iii X1) X0))))))
% 208.54/208.77 satz12:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X0) X1)->((d_29_ii X1) X0))))))
% 208.54/208.77 satz13:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((moreis X0) X1)->((lessis X1) X0))))))
% 208.54/208.77 satz14:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((lessis X0) X1)->((moreis X1) X0))))))
% 208.54/208.77 satz15:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->(((iii X1) X2)->((iii X0) X2)))))))))
% 208.54/208.77 satz16a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->(((iii X1) X2)->((iii X0) X2)))))))))
% 208.54/208.77 satz16b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->(((lessis X1) X2)->((iii X0) X2)))))))))
% 208.54/208.77 satz16c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->(((d_29_ii X1) X2)->((d_29_ii X0) X2)))))))))
% 208.54/208.77 satz16d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->(((moreis X1) X2)->((d_29_ii X0) X2)))))))))
% 208.54/208.77 satz17:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->(((lessis X1) X2)->((lessis X0) X2)))))))))
% 208.54/208.77 satz18:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_29_ii ((n_pl X0) X1)) X0)))))
% 208.54/208.77 satz18a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((iii X0) ((n_pl X0) X1))))))
% 208.54/208.77 satz18b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((d_29_ii (ordsucc X0)) X0)))
% 208.54/208.77 satz18c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((iii X0) (ordsucc X0))))
% 208.54/208.77 satz19a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.54/208.77 satz19b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is X0) X1)->((n_is ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.54/208.77 satz19c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->((iii ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.54/208.77 satz19d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->((d_29_ii ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.54/208.77 satz19e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is X0) X1)->((n_is ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.54/208.77 satz19f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->((iii ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.54/208.77 satz19g:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.77 satz19h:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X2) X0)) ((n_pl X3) X1))))))))))))
% 208.54/208.77 satz19j:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.77 satz19k:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((iii X2) X3)->((iii ((n_pl X2) X0)) ((n_pl X3) X1))))))))))))
% 208.54/208.77 satz19l:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->((moreis ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.54/208.77 satz19m:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->((moreis ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.54/208.77 satz19n:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->((lessis ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.54/208.77 satz19o:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->((lessis ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.54/208.77 satz1:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((nis X0) X1)->((nis (ordsucc X0)) (ordsucc X1)))))))
% 208.54/208.77 satz20a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X2))->((d_29_ii X0) X1))))))))
% 208.54/208.77 satz20b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X0) X2)) ((n_pl X1) X2))->((n_is X0) X1))))))))
% 208.54/208.77 satz20c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii ((n_pl X0) X2)) ((n_pl X1) X2))->((iii X0) X1))))))))
% 208.54/208.77 satz20d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii ((n_pl X2) X0)) ((n_pl X2) X1))->((d_29_ii X0) X1))))))))
% 208.54/208.77 satz20e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X2) X0)) ((n_pl X2) X1))->((n_is X0) X1))))))))
% 208.54/208.77 satz20f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii ((n_pl X2) X0)) ((n_pl X2) X1))->((iii X0) X1))))))))
% 208.54/208.77 satz21:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((d_29_ii X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.77 satz21a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((iii X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.77 satz22a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((moreis X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.77 satz22b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((d_29_ii X0) X1)->(((moreis X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.77 satz22c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((lessis X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.77 satz22d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((iii X0) X1)->(((lessis X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.77 satz23:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((moreis X0) X1)->(((moreis X2) X3)->((moreis ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.77 satz23a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((lessis X0) X1)->(((lessis X2) X3)->((lessis ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.77 satz24:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((moreis X0) n_1)))
% 208.54/208.77 satz24a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (lessis n_1))
% 208.54/208.77 satz24b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((d_29_ii (ordsucc X0)) n_1)))
% 208.54/208.77 satz24c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((iii n_1) (ordsucc X0))))
% 208.54/208.77 satz25:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X1) X0)->((moreis X1) ((n_pl X0) n_1)))))))
% 208.54/208.77 satz25a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X1) X0)->((moreis X1) (ordsucc X0)))))))
% 208.54/208.77 satz25b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) X0)->((lessis ((n_pl X1) n_1)) X0))))))
% 208.54/208.77 satz25c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) X0)->((lessis (ordsucc X1)) X0))))))
% 208.54/208.77 satz26:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) ((n_pl X0) n_1))->((lessis X1) X0))))))
% 208.54/208.77 satz26a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) (ordsucc X0))->((lessis X1) X0))))))
% 208.54/208.77 satz26b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii ((n_pl X1) n_1)) X0)->((moreis X1) X0))))))
% 208.54/208.77 satz26c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii (ordsucc X1)) X0)->((moreis X1) X0))))))
% 208.54/208.77 satz27:(forall (X0:(fofType->Prop)), ((n_some X0)->(n_some (min X0))))
% 208.54/208.77 satz27a:(forall (X0:(fofType->Prop)), ((n_some X0)->(n_one (min X0))))
% 208.54/208.77 satz28:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((one ((d_Pi nat) (fun (X1:fofType)=> nat))) (fun (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) X0)) (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) ((n_pl ((ap X1) X2)) X0)))))))))
% 208.54/208.77 satz28a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_ts X0) n_1)) X0)))
% 208.54/208.77 satz28b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_ts X0) (ordsucc X1))) ((n_pl ((n_ts X0) X1)) X0))))))
% 208.54/208.77 satz28c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_ts n_1) X0)) X0)))
% 208.54/208.77 satz28d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_ts (ordsucc X0)) X1)) ((n_pl ((n_ts X0) X1)) X1))))))
% 208.54/208.77 satz2:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((nis (ordsucc X0)) X0)))
% 208.54/208.77 satz3:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> (((nis X0) n_1)->(n_some (fun (X1:fofType)=> ((n_is X0) (ordsucc X1)))))))
% 208.54/208.77 satz3a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> (((nis X0) n_1)->(n_one (fun (X1:fofType)=> ((n_is X0) (ordsucc X1)))))))
% 208.54/208.77 satz4:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((one ((d_Pi nat) (fun (X1:fofType)=> nat))) (fun (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) (ordsucc X0))) (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) (ordsucc ((ap X1) X2))))))))))
% 208.54/208.77 satz4a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_pl X0) n_1)) (ordsucc X0))))
% 208.54/208.77 satz4b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl X0) (ordsucc X1))) (ordsucc ((n_pl X0) X1)))))))
% 208.54/208.77 satz4c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_pl n_1) X0)) (ordsucc X0))))
% 208.54/208.77 satz4d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl (ordsucc X0)) X1)) (ordsucc ((n_pl X0) X1)))))))
% 208.54/208.77 satz4e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is (ordsucc X0)) ((n_pl X0) n_1))))
% 208.54/208.77 satz4f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is (ordsucc ((n_pl X0) X1))) ((n_pl X0) (ordsucc X1)))))))
% 208.54/208.77 satz4g:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is (ordsucc X0)) ((n_pl n_1) X0))))
% 208.54/208.77 satz4h:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is (ordsucc ((n_pl X0) X1))) ((n_pl (ordsucc X0)) X1))))))
% 208.54/208.77 satz5:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((n_is ((n_pl ((n_pl X0) X1)) X2)) ((n_pl X0) ((n_pl X1) X2)))))))))
% 208.54/208.77 satz6:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl X0) X1)) ((n_pl X1) X0))))))
% 208.54/208.77 satz7:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((nis X1) ((n_pl X0) X1))))))
% 208.54/208.77 satz8:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((nis X1) X2)->((nis ((n_pl X0) X1)) ((n_pl X0) X2)))))))))
% 208.54/208.77 satz8a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X0) X1)) ((n_pl X0) X2))->((n_is X1) X2))))))))
% 208.54/208.77 satz8b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((amone nat) (fun (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))))))))
% 208.54/208.77 satz9:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((orec3 ((n_is X0) X1)) (n_some (fun (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))))) (n_some (fun (X2:fofType)=> ((n_is X1) ((n_pl X0) X2)))))))))
% 208.54/208.80 satz9a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((or3 ((n_is X0) X1)) (n_some ((diffprop X0) X1))) (n_some ((diffprop X1) X0)))))))
% 208.54/208.80 satz9b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((ec3 ((n_is X0) X1)) (n_some ((diffprop X0) X1))) (n_some ((diffprop X1) X0)))))))
% 208.54/208.80 second:=(fun (X0:fofType) (X1:fofType)=> _TPTP_proj1):(fofType->(fofType->(fofType->fofType)))
% 208.54/208.80 second_p:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> ((is_of (((second X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X1))))))
% 208.54/208.80 secondis1:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> (((e_is X1) (((second X0) X1) ((((d_pair X0) X1) X2) X3))) X3))))))
% 208.54/208.80 set_ext:(forall (X0:fofType) (X1:fofType), (((d_Subq X0) X1)->(((d_Subq X1) X0)->(((eq fofType) X0) X1))))
% 208.54/208.80 setminus:=(fun (X0:fofType) (X1:fofType)=> ((d_Sep X0) (fun (X2:fofType)=> ((nIn X2) X1)))):(fofType->(fofType->fofType))
% 208.54/208.80 setof_p:(forall (X0:fofType) (X1:(fofType->Prop)), ((is_of ((d_Sep X0) X1)) (fun (X2:fofType)=> ((in X2) (power X0)))))
% 208.54/208.80 setprod:=(fun (X0:fofType) (X1:fofType)=> ((d_Sigma X0) (fun (X2:fofType)=> X1))):(fofType->(fofType->fofType))
% 208.54/208.80 soft:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((ind X0) (fun (X4:fofType)=> (((e_is X1) X3) ((ap X2) X4))))):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.54/208.80 st_disj:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((l_ec (((esti X0) X3) X1)) (((esti X0) X3) X2))))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.80 subrelation:=(fun (A:Type) (B:Type) (R:(A->(B->Prop))) (R':(A->(B->Prop)))=> (forall (x:A) (y:B), (((R x) y)->((R' x) y)))):(forall (A:Type) (B:Type), ((A->(B->Prop))->((A->(B->Prop))->Prop)))
% 208.54/208.80 suc_p:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((is_of (ordsucc X0)) (fun (X1:fofType)=> ((in X1) nat)))))
% 208.54/208.80 surjective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X1) (((image X0) X1) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.80 times:=(fun (X0:fofType)=> ((ind ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_428_prop2 X0))):(fofType->fofType)
% 208.54/208.80 tofs:=(fun (X0:fofType) (X1:fofType)=> ap):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.54/208.80 union:(fofType->fofType)
% 208.54/208.80 unique:=(fun (A:Type) (P:(A->Prop)) (x:A)=> ((and (P x)) (forall (x':A), ((P x')->(((eq A) x) x'))))):(forall (A:Type), ((A->Prop)->(A->Prop)))
% 208.54/208.80 unique_choice:=(fun (A:Type) (B:Type) (R:(A->(B->Prop))) (x:(forall (x:A), ((ex B) ((unique B) (fun (y:B)=> ((R x) y))))))=> ((((dependent_unique_choice A) (fun (x2:A)=> B)) R) x)):(forall (A:Type) (B:Type) (R:(A->(B->Prop))), ((forall (x:A), ((ex B) ((unique B) (fun (y:B)=> ((R x) y)))))->((ex (A->B)) (fun (f:(A->B))=> (forall (x:A), ((R x) (f x)))))))
% 208.54/208.80 univof:(fofType->fofType)
% 208.54/208.80 unmore:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sep X0) (fun (X3:fofType)=> ((l_some X1) (fun (X4:fofType)=> (((esti X0) X3) ((ap X2) X4))))))):(fofType->(fofType->(fofType->fofType)))
% 208.54/208.80 wel:=(fun (X0:Prop)=> (d_not (d_not X0))):(Prop->Prop)
% 208.54/208.80 wissel:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X0) (((wissel_wb X0) X1) X2))):(fofType->(fofType->(fofType->fofType)))
% 208.54/208.80 wissel_wa:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((((ite (((e_is X0) X3) X1)) X0) X2) X3)):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.54/208.80 wissel_wb:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((((ite (((e_is X0) X3) X2)) X0) X1) ((((wissel_wa X0) X1) X2) X3))):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.54/208.80 xi_ext:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X0)->(((eq fofType) (X1 X3)) (X2 X3))))->(((eq fofType) ((d_Sigma X0) X1)) ((d_Sigma X0) X2))))
% 208.54/208.80 ---termcontext
% 208.54/208.80 [[[False:Prop
% 208.54/208.80 False_rect:(forall (P:Type), (False->P))
% 208.54/208.80 I:True
% 208.54/208.80 NNPP:=(fun (P:Prop) (H:(not (not P)))=> ((fun (C:((or P) (not P)))=> ((((((or_ind P) (not P)) P) (fun (H0:P)=> H0)) (fun (N:(not P))=> ((False_rect P) (H N)))) C)) (classic P))):(forall (P:Prop), ((not (not P))->P))
% 208.54/208.80 True:Prop
% 208.54/208.80 _TPTP_proj1:=(fun (X0:fofType)=> (((d_ReplSep X0) (fun (X1:fofType)=> ((ex fofType) (fun (X2:fofType)=> (((eq fofType) (d_Inj1 X2)) X1))))) d_Unj)):(fofType->fofType)
% 208.54/208.80 all:=(fun (X0:fofType)=> (all_of (fun (X1:fofType)=> ((in X1) X0)))):(fofType->((fofType->Prop)->Prop))
% 208.54/208.80 all_of:=(fun (X0:(fofType->Prop)) (X1:(fofType->Prop))=> (forall (X2:fofType), (((is_of X2) X0)->(X1 X2)))):((fofType->Prop)->((fofType->Prop)->Prop))
% 208.54/208.80 amone:=(fun (X0:fofType) (X1:(fofType->Prop))=> ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X0))) (fun (X3:fofType)=> ((X1 X2)->((X1 X3)->(((e_is X0) X2) X3)))))))):(fofType->((fofType->Prop)->Prop))
% 208.54/208.80 and3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((d_and X0) ((d_and X1) X2))):(Prop->(Prop->(Prop->Prop)))
% 208.54/208.80 and:(Prop->(Prop->Prop))
% 208.54/208.80 and_comm_i:=(fun (A:Prop) (B:Prop) (H:((and A) B))=> ((((conj B) A) (((proj2 A) B) H)) (((proj1 A) B) H))):(forall (A:Prop) (B:Prop), (((and A) B)->((and B) A)))
% 208.54/208.80 and_rect:=(fun (A:Prop) (B:Prop) (P:Type) (X:(A->(B->P))) (H:((and A) B))=> ((X (((proj1 A) B) H)) (((proj2 A) B) H))):(forall (A:Prop) (B:Prop) (P:Type), ((A->(B->P))->(((and A) B)->P)))
% 208.54/208.80 anec:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> ((l_some X0) (((ecp X0) X1) X2))):(fofType->((fofType->(fofType->Prop))->(fofType->Prop)))
% 208.54/208.80 ap:=(fun (X0:fofType) (X1:fofType)=> (((d_ReplSep X0) (fun (X2:fofType)=> ((ex fofType) (fun (X3:fofType)=> (((eq fofType) X2) ((pair X1) X3)))))) _TPTP_proj1)):(fofType->(fofType->fofType))
% 208.54/208.80 ap_Pi:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType) (X3:fofType), (((in X2) ((d_Pi X0) X1))->(((in X3) X0)->((in ((ap X2) X3)) (X1 X3)))))
% 208.54/208.80 beta:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) X0)->(((eq fofType) ((ap ((d_Sigma X0) X1)) X2)) (X1 X2))))
% 208.54/208.80 bijective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_and (((injective X0) X1) X2)) (((surjective X0) X1) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.80 binunion:=(fun (X0:fofType) (X1:fofType)=> (union ((d_UPair X0) X1))):(fofType->(fofType->fofType))
% 208.54/208.80 changef:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_Sigma X0) (fun (X5:fofType)=> ((ap X2) ((ap (((wissel X0) X3) X4)) X5))))):(fofType->(fofType->(fofType->(fofType->(fofType->fofType)))))
% 208.54/208.80 choice:=(fun (A:Type) (B:Type) (R:(A->(B->Prop))) (x:(forall (x:A), ((ex B) (fun (y:B)=> ((R x) y)))))=> (((fun (P:Prop) (x0:(forall (x0:(A->(B->Prop))), (((and ((((subrelation A) B) x0) R)) (forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y))))))->P)))=> (((((ex_ind (A->(B->Prop))) (fun (R':(A->(B->Prop)))=> ((and ((((subrelation A) B) R') R)) (forall (x0:A), ((ex B) ((unique B) (fun (y:B)=> ((R' x0) y)))))))) P) x0) ((((relational_choice A) B) R) x))) ((ex (A->B)) (fun (f:(A->B))=> (forall (x0:A), ((R x0) (f x0)))))) (fun (x0:(A->(B->Prop))) (x1:((and ((((subrelation A) B) x0) R)) (forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y)))))))=> (((fun (P:Type) (x2:(((((subrelation A) B) x0) R)->((forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y)))))->P)))=> (((((and_rect ((((subrelation A) B) x0) R)) (forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y)))))) P) x2) x1)) ((ex (A->B)) (fun (f:(A->B))=> (forall (x0:A), ((R x0) (f x0)))))) (fun (x2:((((subrelation A) B) x0) R)) (x3:(forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y))))))=> (((fun (P:Prop) (x4:(forall (x1:(A->B)), ((forall (x10:A), ((x0 x10) (x1 x10)))->P)))=> (((((ex_ind (A->B)) (fun (f:(A->B))=> (forall (x1:A), ((x0 x1) (f x1))))) P) x4) ((((unique_choice A) B) x0) x3))) ((ex (A->B)) (fun (f:(A->B))=> (forall (x0:A), ((R x0) (f x0)))))) (fun (x4:(A->B)) (x5:(forall (x10:A), ((x0 x10) (x4 x10))))=> ((((ex_intro (A->B)) (fun (f:(A->B))=> (forall (x0:A), ((R x0) (f x0))))) x4) (fun (x00:A)=> (((x2 x00) (x4 x00)) (x5 x00))))))))))):(forall (A:Type) (B:Type) (R:(A->(B->Prop))), ((forall (x:A), ((ex B) (fun (y:B)=> ((R x) y))))->((ex (A->B)) (fun (f:(A->B))=> (forall (x:A), ((R x) (f x)))))))
% 208.54/208.80 choice_operator:=(fun (A:Type) (a:A)=> ((((classical_choice (A->Prop)) A) (fun (x3:(A->Prop))=> x3)) a)):(forall (A:Type), (A->((ex ((A->Prop)->A)) (fun (co:((A->Prop)->A))=> (forall (P:(A->Prop)), (((ex A) (fun (x:A)=> (P x)))->(P (co P))))))))
% 208.54/208.80 classic:(forall (P:Prop), ((or P) (not P)))
% 208.54/208.80 classical_choice:=(fun (A:Type) (B:Type) (R:(A->(B->Prop))) (b:B)=> ((fun (C:((forall (x:A), ((ex B) (fun (y:B)=> (((fun (x0:A) (y0:B)=> (((ex B) (fun (z:B)=> ((R x0) z)))->((R x0) y0))) x) y))))->((ex (A->B)) (fun (f:(A->B))=> (forall (x:A), (((fun (x0:A) (y:B)=> (((ex B) (fun (z:B)=> ((R x0) z)))->((R x0) y))) x) (f x)))))))=> (C (fun (x:A)=> ((fun (C0:((or ((ex B) (fun (z:B)=> ((R x) z)))) (not ((ex B) (fun (z:B)=> ((R x) z))))))=> ((((((or_ind ((ex B) (fun (z:B)=> ((R x) z)))) (not ((ex B) (fun (z:B)=> ((R x) z))))) ((ex B) (fun (y:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y))))) ((((ex_ind B) (fun (z:B)=> ((R x) z))) ((ex B) (fun (y:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y))))) (fun (y:B) (H:((R x) y))=> ((((ex_intro B) (fun (y0:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y0)))) y) (fun (_:((ex B) (fun (z:B)=> ((R x) z))))=> H))))) (fun (N:(not ((ex B) (fun (z:B)=> ((R x) z)))))=> ((((ex_intro B) (fun (y:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y)))) b) (fun (H:((ex B) (fun (z:B)=> ((R x) z))))=> ((False_rect ((R x) b)) (N H)))))) C0)) (classic ((ex B) (fun (z:B)=> ((R x) z)))))))) (((choice A) B) (fun (x:A) (y:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y)))))):(forall (A:Type) (B:Type) (R:(A->(B->Prop))), (B->((ex (A->B)) (fun (f:(A->B))=> (forall (x:A), (((ex B) (fun (y:B)=> ((R x) y)))->((R x) (f x))))))))
% 208.54/208.80 cond1:=(n_in n_1):(fofType->Prop)
% 208.54/208.80 cond2:=(fun (X0:fofType)=> (n_all (fun (X1:fofType)=> ((imp ((n_in X1) X0)) ((n_in (ordsucc X1)) X0))))):(fofType->Prop)
% 208.54/208.80 conj:(forall (A:Prop) (B:Prop), (A->(B->((and A) B))))
% 208.54/208.80 d_10_prop1:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType) (X5:fofType) (X6:fofType)=> ((d_and (((esti X0) X6) (((ecect X0) X1) X4))) (((e_is X2) ((ap X3) X6)) X5))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->(fofType->Prop)))))))
% 208.54/208.80 d_11_i:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> (((indeq X0) X1) ((d_Pi X0) (fun (X3:fofType)=> X2)))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->fofType)))))
% 208.54/208.80 d_22_prop1:=(fun (X0:fofType)=> ((nis (ordsucc X0)) X0)):(fofType->Prop)
% 208.54/208.80 d_23_prop1:=(fun (X0:fofType)=> ((l_or ((n_is X0) n_1)) (n_some (fun (X1:fofType)=> ((n_is X0) (ordsucc X1)))))):(fofType->Prop)
% 208.54/208.80 d_24_g:=(fun (X0:fofType)=> ((d_Sigma nat) (fun (X1:fofType)=> (ordsucc ((ap X0) X1))))):(fofType->fofType)
% 208.54/208.80 d_24_prop1:=(fun (X0:fofType)=> (n_all (fun (X1:fofType)=> ((n_is ((ap X0) (ordsucc X1))) (ordsucc ((ap X0) X1)))))):(fofType->Prop)
% 208.54/208.80 d_24_prop2:=(fun (X0:fofType) (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) (ordsucc X0))) (d_24_prop1 X1))):(fofType->(fofType->Prop))
% 208.54/208.80 d_25_prop1:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is ((n_pl ((n_pl X0) X1)) X2)) ((n_pl X0) ((n_pl X1) X2)))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.80 d_26_prop1:=(fun (X0:fofType) (X1:fofType)=> ((n_is ((n_pl X0) X1)) ((n_pl X1) X0))):(fofType->(fofType->Prop))
% 208.54/208.80 d_27_prop1:=(fun (X0:fofType) (X1:fofType)=> ((nis X1) ((n_pl X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.80 d_28_prop1:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((nis ((n_pl X0) X1)) ((n_pl X0) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.80 d_29_ii:=(fun (X0:fofType) (X1:fofType)=> (n_some ((diffprop X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.80 d_29_prop1:=(fun (X0:fofType) (X1:fofType)=> (((or3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.80 d_428_g:=(fun (X0:fofType)=> ((d_Sigma nat) (fun (X1:fofType)=> ((n_pl ((ap X0) X1)) X1)))):(fofType->fofType)
% 208.54/208.80 d_428_id:=((d_Sigma nat) (fun (X0:fofType)=> X0)):fofType
% 208.54/208.80 d_428_prop1:=(fun (X0:fofType) (X1:fofType)=> (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) ((n_pl ((ap X1) X2)) X0))))):(fofType->(fofType->Prop))
% 208.54/208.80 d_428_prop2:=(fun (X0:fofType) (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) X0)) ((d_428_prop1 X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.80 d_428_prop4:=(fun (X0:fofType)=> ((l_some ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_428_prop2 X0))):(fofType->Prop)
% 208.54/208.80 d_In_rec:=(fun (X0:(fofType->((fofType->fofType)->fofType))) (X1:fofType)=> (eps ((d_In_rec_G X0) X1))):((fofType->((fofType->fofType)->fofType))->(fofType->fofType))
% 208.54/208.80 d_In_rec_G:=(fun (X0:(fofType->((fofType->fofType)->fofType))) (X1:fofType) (X2:fofType)=> (forall (X3:(fofType->(fofType->Prop))), ((forall (X4:fofType) (X5:(fofType->fofType)), ((forall (X6:fofType), (((in X6) X4)->((X3 X6) (X5 X6))))->((X3 X4) ((X0 X4) X5))))->((X3 X1) X2)))):((fofType->((fofType->fofType)->fofType))->(fofType->(fofType->Prop)))
% 208.54/208.80 d_Inj0:=(fun (X0:fofType)=> ((repl X0) d_Inj1)):(fofType->fofType)
% 208.54/208.80 d_Inj1:=(d_In_rec (fun (X0:fofType) (X1:(fofType->fofType))=> ((binunion (d_Sing emptyset)) ((repl X0) X1)))):(fofType->fofType)
% 208.54/208.80 d_Pi:=(fun (X0:fofType) (X1:(fofType->fofType))=> ((d_Sep (power ((d_Sigma X0) (fun (X2:fofType)=> (union (X1 X2)))))) (fun (X2:fofType)=> (forall (X3:fofType), (((in X3) X0)->((in ((ap X2) X3)) (X1 X3))))))):(fofType->((fofType->fofType)->fofType))
% 208.54/208.80 d_Power_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->((in (power X1)) X0)))):(fofType->Prop)
% 208.54/208.80 d_ReplSep:=(fun (X0:fofType) (X1:(fofType->Prop))=> (repl ((d_Sep X0) X1))):(fofType->((fofType->Prop)->((fofType->fofType)->fofType)))
% 208.54/208.80 d_Repl_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->(forall (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X1)->((in (X2 X3)) X0)))->((in ((repl X1) X2)) X0)))))):(fofType->Prop)
% 208.54/208.80 d_Sep:=(fun (X0:fofType) (X1:(fofType->Prop))=> (((if ((ex fofType) (fun (X2:fofType)=> ((and ((in X2) X0)) (X1 X2))))) ((repl X0) (fun (X2:fofType)=> (((if (X1 X2)) X2) (eps (fun (X3:fofType)=> ((and ((in X3) X0)) (X1 X3)))))))) emptyset)):(fofType->((fofType->Prop)->fofType))
% 208.54/208.80 d_Sigma:=(fun (X0:fofType) (X1:(fofType->fofType))=> ((famunion X0) (fun (X2:fofType)=> ((repl (X1 X2)) (pair X2))))):(fofType->((fofType->fofType)->fofType))
% 208.54/208.80 d_Sing:=(fun (X0:fofType)=> ((d_UPair X0) X0)):(fofType->fofType)
% 208.54/208.80 d_Subq:=(fun (X0:fofType) (X1:fofType)=> (forall (X2:fofType), (((in X2) X0)->((in X2) X1)))):(fofType->(fofType->Prop))
% 208.54/208.80 d_UPair:=(fun (X0:fofType) (X1:fofType)=> ((repl (power (power emptyset))) (fun (X2:fofType)=> (((if ((in emptyset) X2)) X0) X1)))):(fofType->(fofType->fofType))
% 208.54/208.80 d_Union_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->((in (union X1)) X0)))):(fofType->Prop)
% 208.54/208.80 d_Unj:=(d_In_rec (fun (X0:fofType)=> (repl ((setminus X0) (d_Sing emptyset))))):(fofType->fofType)
% 208.54/208.80 d_ZF_closed:=(fun (X0:fofType)=> ((and ((and (d_Union_closed X0)) (d_Power_closed X0))) (d_Repl_closed X0))):(fofType->Prop)
% 208.54/208.80 d_and:=(fun (X0:Prop) (X1:Prop)=> (d_not ((l_ec X0) X1))):(Prop->(Prop->Prop))
% 208.54/208.80 d_not:=(fun (X0:Prop)=> ((imp X0) False)):(Prop->Prop)
% 208.54/208.80 d_pair:=(fun (X0:fofType) (X1:fofType)=> pair):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.54/208.80 dependent_unique_choice:(forall (A:Type) (B:(A->Type)) (R:(forall (x:A), ((B x)->Prop))), ((forall (x:A), ((ex (B x)) ((unique (B x)) (fun (y:(B x))=> ((R x) y)))))->((ex (forall (x:A), (B x))) (fun (f:(forall (x:A), (B x)))=> (forall (x:A), ((R x) (f x)))))))
% 208.54/208.80 diffprop:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.80 e_fisi:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Pi X0) (fun (X3:fofType)=> X1))))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) ((d_Pi X0) (fun (X4:fofType)=> X1))))) (fun (X3:fofType)=> (((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> (((e_is X1) ((ap X2) X4)) ((ap X3) X4))))->(((e_is ((d_Pi X0) (fun (X4:fofType)=> X1))) X2) X3)))))))
% 208.54/208.80 e_in:=(fun (X0:fofType) (X1:(fofType->Prop)) (X2:fofType)=> X2):(fofType->((fofType->Prop)->(fofType->fofType)))
% 208.54/208.80 e_in_p:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Sep X0) X1)))) (fun (X2:fofType)=> ((is_of (((e_in X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X0))))))
% 208.54/208.80 e_inp:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Sep X0) X1)))) (fun (X2:fofType)=> (X1 (((e_in X0) X1) X2)))))
% 208.54/208.80 e_is:=(fun (X0:fofType) (X:fofType) (Y:fofType)=> (((eq fofType) X) Y)):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.80 e_isp:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X0))) (fun (X3:fofType)=> ((X1 X2)->((((e_is X0) X2) X3)->(X1 X3))))))))
% 208.54/208.80 e_pair_p:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> ((is_of ((((d_pair X0) X1) X2) X3)) (fun (X4:fofType)=> ((in X4) ((setprod X0) X1)))))))))
% 208.54/208.80 ec3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> (((and3 ((l_ec X0) X1)) ((l_ec X1) X2)) ((l_ec X2) X0))):(Prop->(Prop->(Prop->Prop)))
% 208.54/208.80 ecect:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((e_in (power X0)) ((anec X0) X1))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 208.54/208.80 ecelt:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> ((d_Sep X0) (X1 X2))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 208.54/208.80 ecp:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> (((e_is (power X0)) X2) (((ecelt X0) X1) X3))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))
% 208.54/208.80 ect:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((d_Sep (power X0)) ((anec X0) X1))):(fofType->((fofType->(fofType->Prop))->fofType))
% 208.54/208.80 ectelt:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> (((ectset X0) X1) (((ecelt X0) X1) X2))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 208.54/208.80 ectset:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((out (power X0)) ((anec X0) X1))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 208.54/208.80 empty:=(fun (X0:fofType) (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) X0))) ((non X0) (fun (X2:fofType)=> (((esti X0) X2) X1))))):(fofType->(fofType->Prop))
% 208.54/208.80 emptyset:fofType
% 208.54/208.80 eps:((fofType->Prop)->fofType)
% 208.54/208.80 eq:=(fun (T:Type) (a:T) (b:T)=> (forall (P:(T->Prop)), ((P a)->(P b)))):(forall (T:Type), (T->(T->Prop)))
% 208.54/208.80 eq_ref:=(fun (T:Type) (a:T) (P:(T->Prop)) (x:(P a))=> x):(forall (T:Type) (a:T), (((eq T) a) a))
% 208.54/208.80 eq_stepl:=(fun (T:Type) (a:T) (b:T) (c:T) (X:(((eq T) a) b)) (Y:(((eq T) a) c))=> ((((((eq_trans T) c) a) b) ((((eq_sym T) a) c) Y)) X)):(forall (T:Type) (a:T) (b:T) (c:T), ((((eq T) a) b)->((((eq T) a) c)->(((eq T) c) b))))
% 208.54/208.80 eq_substitution:=(fun (T:Type) (U:Type) (a:T) (b:T) (f:(T->U)) (H:(((eq T) a) b))=> ((H (fun (x:T)=> (((eq U) (f a)) (f x)))) ((eq_ref U) (f a)))):(forall (T:Type) (U:Type) (a:T) (b:T) (f:(T->U)), ((((eq T) a) b)->(((eq U) (f a)) (f b))))
% 208.54/208.80 eq_sym:=(fun (T:Type) (a:T) (b:T) (H:(((eq T) a) b))=> ((H (fun (x:T)=> (((eq T) x) a))) ((eq_ref T) a))):(forall (T:Type) (a:T) (b:T), ((((eq T) a) b)->(((eq T) b) a)))
% 208.54/208.80 eq_trans:=(fun (T:Type) (a:T) (b:T) (c:T) (X:(((eq T) a) b)) (Y:(((eq T) b) c))=> ((Y (fun (t:T)=> (((eq T) a) t))) X)):(forall (T:Type) (a:T) (b:T) (c:T), ((((eq T) a) b)->((((eq T) b) c)->(((eq T) a) c))))
% 208.54/208.80 esti:=(fun (X0:fofType)=> in):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.80 estie:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((((esti X0) X2) ((d_Sep X0) X1))->(X1 X2)))))
% 208.54/208.80 estii:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((X1 X2)->(((esti X0) X2) ((d_Sep X0) X1))))))
% 208.54/208.80 eta_expansion:=(fun (A:Type) (B:Type)=> ((eta_expansion_dep A) (fun (x1:A)=> B))):(forall (A:Type) (B:Type) (f:(A->B)), (((eq (A->B)) f) (fun (x:A)=> (f x))))
% 208.54/208.80 eta_expansion_dep:=(fun (A:Type) (B:(A->Type)) (f:(forall (x:A), (B x)))=> (((((functional_extensionality_dep A) (fun (x1:A)=> (B x1))) f) (fun (x:A)=> (f x))) (fun (x:A) (P:((B x)->Prop)) (x0:(P (f x)))=> x0))):(forall (A:Type) (B:(A->Type)) (f:(forall (x:A), (B x))), (((eq (forall (x:A), (B x))) f) (fun (x:A)=> (f x))))
% 208.54/208.80 ex:(forall (A:Type), ((A->Prop)->Prop))
% 208.54/208.80 ex_ind:(forall (A:Type) (F:(A->Prop)) (P:Prop), ((forall (x:A), ((F x)->P))->(((ex A) F)->P)))
% 208.54/208.80 ex_intro:(forall (A:Type) (P:(A->Prop)) (x:A), ((P x)->((ex A) P)))
% 208.54/208.80 famunion:=(fun (X0:fofType) (X1:(fofType->fofType))=> (union ((repl X0) X1))):(fofType->((fofType->fofType)->fofType))
% 208.54/208.80 first:=(fun (X0:fofType) (X1:fofType)=> proj0):(fofType->(fofType->(fofType->fofType)))
% 208.54/208.80 first_p:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> ((is_of (((first X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X0))))))
% 208.54/208.80 firstis1:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> (((e_is X0) (((first X0) X1) ((((d_pair X0) X1) X2) X3))) X2))))))
% 208.54/208.80 fixfu2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> ((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> ((all_of (fun (X5:fofType)=> ((in X5) X0))) (fun (X5:fofType)=> ((all_of (fun (X6:fofType)=> ((in X6) X0))) (fun (X6:fofType)=> ((all_of (fun (X7:fofType)=> ((in X7) X0))) (fun (X7:fofType)=> (((X1 X4) X5)->(((X1 X6) X7)->(((e_is X2) ((ap ((ap X3) X4)) X6)) ((ap ((ap X3) X5)) X7))))))))))))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))
% 208.54/208.80 fixfu:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> ((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> ((all_of (fun (X5:fofType)=> ((in X5) X0))) (fun (X5:fofType)=> (((X1 X4) X5)->(((e_is X2) ((ap X3) X4)) ((ap X3) X5)))))))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))
% 208.54/208.80 fofType:Type
% 208.54/208.80 functional_extensionality:=(fun (A:Type) (B:Type)=> ((functional_extensionality_dep A) (fun (x1:A)=> B))):(forall (A:Type) (B:Type) (f:(A->B)) (g:(A->B)), ((forall (x:A), (((eq B) (f x)) (g x)))->(((eq (A->B)) f) g)))
% 208.54/208.80 functional_extensionality_dep:(forall (A:Type) (B:(A->Type)) (f:(forall (x:A), (B x))) (g:(forall (x:A), (B x))), ((forall (x:A), (((eq (B x)) (f x)) (g x)))->(((eq (forall (x:A), (B x))) f) g)))
% 208.54/208.80 functional_extensionality_double:=(fun (A:Type) (B:Type) (C:Type) (f:(A->(B->C))) (g:(A->(B->C))) (x:(forall (x:A) (y:B), (((eq C) ((f x) y)) ((g x) y))))=> (((((functional_extensionality_dep A) (fun (x2:A)=> (B->C))) f) g) (fun (x0:A)=> (((((functional_extensionality_dep B) (fun (x3:B)=> C)) (f x0)) (g x0)) (x x0))))):(forall (A:Type) (B:Type) (C:Type) (f:(A->(B->C))) (g:(A->(B->C))), ((forall (x:A) (y:B), (((eq C) ((f x) y)) ((g x) y)))->(((eq (A->(B->C))) f) g)))
% 208.54/208.80 i1_s:=(d_Sep nat):((fofType->Prop)->fofType)
% 208.54/208.80 if:=(fun (X0:Prop) (X1:fofType) (X2:fofType)=> (eps (fun (X3:fofType)=> ((or ((and X0) (((eq fofType) X3) X1))) ((and (X0->False)) (((eq fofType) X3) X2)))))):(Prop->(fofType->(fofType->fofType)))
% 208.54/208.80 if_i_0:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((X0->False)->(((eq fofType) (((if X0) X1) X2)) X2)))
% 208.54/208.80 if_i_1:(forall (X0:Prop) (X1:fofType) (X2:fofType), (X0->(((eq fofType) (((if X0) X1) X2)) X1)))
% 208.54/208.80 if_i_correct:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((or ((and X0) (((eq fofType) (((if X0) X1) X2)) X1))) ((and (X0->False)) (((eq fofType) (((if X0) X1) X2)) X2))))
% 208.54/208.80 if_i_or:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((or (((eq fofType) (((if X0) X1) X2)) X1)) (((eq fofType) (((if X0) X1) X2)) X2)))
% 208.54/208.80 iff:=(fun (A:Prop) (B:Prop)=> ((and (A->B)) (B->A))):(Prop->(Prop->Prop))
% 208.54/208.80 iff_refl:=(fun (A:Prop)=> ((((conj (A->A)) (A->A)) (fun (H:A)=> H)) (fun (H:A)=> H))):(forall (P:Prop), ((iff P) P))
% 208.54/208.80 iff_sym:=(fun (A:Prop) (B:Prop) (H:((iff A) B))=> ((((conj (B->A)) (A->B)) (((proj2 (A->B)) (B->A)) H)) (((proj1 (A->B)) (B->A)) H))):(forall (A:Prop) (B:Prop), (((iff A) B)->((iff B) A)))
% 208.54/208.80 iff_trans:=(fun (A:Prop) (B:Prop) (C:Prop) (AB:((iff A) B)) (BC:((iff B) C))=> ((((conj (A->C)) (C->A)) (fun (x:A)=> ((((proj1 (B->C)) (C->B)) BC) ((((proj1 (A->B)) (B->A)) AB) x)))) (fun (x:C)=> ((((proj2 (A->B)) (B->A)) AB) ((((proj2 (B->C)) (C->B)) BC) x))))):(forall (A:Prop) (B:Prop) (C:Prop), (((iff A) B)->(((iff B) C)->((iff A) C))))
% 208.54/208.80 iii:=(fun (X0:fofType) (X1:fofType)=> (n_some ((diffprop X1) X0))):(fofType->(fofType->Prop))
% 208.54/208.80 image:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((l_some X0) (fun (X4:fofType)=> (((e_is X1) X3) ((ap X2) X4))))):(fofType->(fofType->(fofType->(fofType->Prop))))
% 208.54/208.80 imp:=(fun (X0:Prop) (X1:Prop)=> (X0->X1)):(Prop->(Prop->Prop))
% 208.54/208.80 in:(fofType->(fofType->Prop))
% 208.54/208.80 incl:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((imp (((esti X0) X3) X1)) (((esti X0) X3) X2))))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.80 ind:=(fun (X0:fofType) (X1:(fofType->Prop))=> (eps (fun (X2:fofType)=> ((and ((in X2) X0)) (X1 X2))))):(fofType->((fofType->Prop)->fofType))
% 208.54/208.80 ind_p:(forall (X0:fofType) (X1:(fofType->Prop)), (((one X0) X1)->((is_of ((ind X0) X1)) (fun (X2:fofType)=> ((in X2) X0)))))
% 208.54/208.80 indeq2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType)=> ((((indeq X0) X1) X2) (((((d_11_i X0) X1) X2) X3) X4))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->fofType))))))
% 208.54/208.80 indeq:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType)=> ((ind X2) (((((prop2 X0) X1) X2) X3) X4))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->fofType)))))
% 208.54/208.80 inj_h:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_Sigma X0) (fun (X5:fofType)=> ((ap X4) ((ap X3) X5))))):(fofType->(fofType->(fofType->(fofType->(fofType->fofType)))))
% 208.54/208.80 injective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((all X0) (fun (X4:fofType)=> ((imp (((e_is X1) ((ap X2) X3)) ((ap X2) X4))) (((e_is X0) X3) X4))))))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.80 inverse:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X1) (fun (X3:fofType)=> (((if ((((image X0) X1) X2) X3)) ((((soft X0) X1) X2) X3)) emptyset)))):(fofType->(fofType->(fofType->fofType)))
% 208.54/208.80 invf:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X1) (((soft X0) X1) X2))):(fofType->(fofType->(fofType->fofType)))
% 208.54/208.80 is_of:=(fun (X0:fofType) (X1:(fofType->Prop))=> (X1 X0)):(fofType->((fofType->Prop)->Prop))
% 208.54/208.80 isseti:(forall (X0:fofType), ((all_of (fun (X1:fofType)=> ((in X1) (power X0)))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) (power X0)))) (fun (X2:fofType)=> ((((incl X0) X1) X2)->((((incl X0) X2) X1)->(((e_is (power X0)) X1) X2))))))))
% 208.54/208.80 ite:=(fun (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType)=> ((ind X1) ((((prop1 X0) X1) X2) X3))):(Prop->(fofType->(fofType->(fofType->fofType))))
% 208.54/208.80 k_EmptyAx:(((ex fofType) (fun (X0:fofType)=> ((in X0) emptyset)))->False)
% 208.54/208.80 k_If_In_01:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((X0->((in X1) X2))->((in (((if X0) X1) emptyset)) (((if X0) X2) (ordsucc emptyset)))))
% 208.54/208.80 k_If_In_then_E:(forall (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType), (X0->(((in X1) (((if X0) X2) X3))->((in X1) X2))))
% 208.54/208.80 k_In_0_1:((in emptyset) (ordsucc emptyset))
% 208.54/208.80 k_In_ind:(forall (X0:(fofType->Prop)), ((forall (X1:fofType), ((forall (X2:fofType), (((in X2) X1)->(X0 X2)))->(X0 X1)))->(forall (X1:fofType), (X0 X1))))
% 208.54/208.80 k_Pi_ext:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Pi X0) X1))->(forall (X3:fofType), (((in X3) ((d_Pi X0) X1))->((forall (X4:fofType), (((in X4) X0)->(((eq fofType) ((ap X2) X4)) ((ap X3) X4))))->(((eq fofType) X2) X3))))))
% 208.54/208.80 k_PowerE:(forall (X0:fofType) (X1:fofType), (((in X1) (power X0))->((d_Subq X1) X0)))
% 208.54/208.80 k_PowerEq:(forall (X0:fofType) (X1:fofType), ((iff ((in X1) (power X0))) ((d_Subq X1) X0)))
% 208.54/208.80 k_PowerI:(forall (X0:fofType) (X1:fofType), (((d_Subq X1) X0)->((in X1) (power X0))))
% 208.54/208.80 k_ReplEq:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), ((iff ((in X2) ((repl X0) X1))) ((ex fofType) (fun (X3:fofType)=> ((and ((in X3) X0)) (((eq fofType) X2) (X1 X3)))))))
% 208.54/208.80 k_Self_In_Power:(forall (X0:fofType), ((in X0) (power X0)))
% 208.54/208.80 k_SepE1:(forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) ((d_Sep X0) X1))->((in X2) X0)))
% 208.54/208.80 k_SepE2:(forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) ((d_Sep X0) X1))->(X1 X2)))
% 208.54/208.80 k_SepI:(forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) X0)->((X1 X2)->((in X2) ((d_Sep X0) X1)))))
% 208.54/208.80 k_Sigma_eta_proj0_proj1:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((and ((and (((eq fofType) ((pair (proj0 X2)) (_TPTP_proj1 X2))) X2)) ((in (proj0 X2)) X0))) ((in (_TPTP_proj1 X2)) (X1 (proj0 X2))))))
% 208.54/208.80 k_UnionEq:(forall (X0:fofType) (X1:fofType), ((iff ((in X1) (union X0))) ((ex fofType) (fun (X2:fofType)=> ((and ((in X1) X2)) ((in X2) X0))))))
% 208.54/208.80 k_UnivOf_In:(forall (X0:fofType), ((in X0) (univof X0)))
% 208.54/208.80 k_UnivOf_ZF_closed:(forall (X0:fofType), (d_ZF_closed (univof X0)))
% 208.54/208.80 l_ec:=(fun (X0:Prop) (X1:Prop)=> ((imp X0) (d_not X1))):(Prop->(Prop->Prop))
% 208.54/208.80 l_et:(forall (X0:Prop), ((wel X0)->X0))
% 208.54/208.80 l_iff:=(fun (X0:Prop) (X1:Prop)=> ((d_and ((imp X0) X1)) ((imp X1) X0))):(Prop->(Prop->Prop))
% 208.54/208.80 l_or:=(fun (X0:Prop)=> (imp (d_not X0))):(Prop->(Prop->Prop))
% 208.54/208.80 l_some:=(fun (X0:fofType) (X1:(fofType->Prop))=> (d_not ((all_of (fun (X2:fofType)=> ((in X2) X0))) ((non X0) X1)))):(fofType->((fofType->Prop)->Prop))
% 208.54/208.80 lam_Pi:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X0)->((in (X2 X3)) (X1 X3))))->((in ((d_Sigma X0) X2)) ((d_Pi X0) X1))))
% 208.54/208.80 lbprop:=(fun (X0:(fofType->Prop)) (X1:fofType) (X2:fofType)=> ((imp (X0 X2)) ((lessis X1) X2))):((fofType->Prop)->(fofType->(fofType->Prop)))
% 208.54/208.80 lessis:=(fun (X0:fofType) (X1:fofType)=> ((l_or ((iii X0) X1)) ((n_is X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.80 min:=(fun (X0:(fofType->Prop)) (X1:fofType)=> ((d_and ((n_lb X0) X1)) (X0 X1))):((fofType->Prop)->(fofType->Prop))
% 208.54/208.80 moreis:=(fun (X0:fofType) (X1:fofType)=> ((l_or ((d_29_ii X0) X1)) ((n_is X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.80 nIn:=(fun (X0:fofType) (X1:fofType)=> (((in X0) X1)->False)):(fofType->(fofType->Prop))
% 208.54/208.80 n_1:=(ordsucc emptyset):fofType
% 208.54/208.80 n_1_p:((is_of n_1) (fun (X0:fofType)=> ((in X0) nat)))
% 208.54/208.80 n_all:=(all nat):((fofType->Prop)->Prop)
% 208.54/208.80 n_ax3:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((nis (ordsucc X0)) n_1)))
% 208.54/208.80 n_ax4:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((n_is (ordsucc X0)) (ordsucc X1))->((n_is X0) X1))))))
% 208.54/208.80 n_ax5:((all_of (fun (X0:fofType)=> ((in X0) (power nat)))) (fun (X0:fofType)=> ((cond1 X0)->((cond2 X0)->((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_in X1) X0)))))))
% 208.54/208.80 n_in:=(esti nat):(fofType->(fofType->Prop))
% 208.54/208.80 n_is:=(e_is nat):(fofType->(fofType->Prop))
% 208.54/208.80 n_lb:=(fun (X0:(fofType->Prop)) (X1:fofType)=> (n_all ((lbprop X0) X1))):((fofType->Prop)->(fofType->Prop))
% 208.54/208.80 n_one:=(one nat):((fofType->Prop)->Prop)
% 208.54/208.80 n_pl:=(fun (X0:fofType)=> (ap (plus X0))):(fofType->(fofType->fofType))
% 208.54/208.80 n_some:=(l_some nat):((fofType->Prop)->Prop)
% 208.54/208.80 n_ts:=(fun (X0:fofType)=> (ap (times X0))):(fofType->(fofType->fofType))
% 208.54/208.80 nat:=((d_Sep omega) (fun (X0:fofType)=> (not (((eq fofType) X0) emptyset)))):fofType
% 208.54/208.80 nat_1:(nat_p (ordsucc emptyset))
% 208.54/208.80 nat_ind:(forall (X0:(fofType->Prop)), ((X0 emptyset)->((forall (X1:fofType), ((nat_p X1)->((X0 X1)->(X0 (ordsucc X1)))))->(forall (X1:fofType), ((nat_p X1)->(X0 X1))))))
% 208.54/208.80 nat_inv:(forall (X0:fofType), ((nat_p X0)->((or (((eq fofType) X0) emptyset)) ((ex fofType) (fun (X1:fofType)=> ((and (nat_p X1)) (((eq fofType) X0) (ordsucc X1))))))))
% 208.54/208.80 nat_ordsucc:(forall (X0:fofType), ((nat_p X0)->(nat_p (ordsucc X0))))
% 208.54/208.80 nat_p:=(fun (X0:fofType)=> (forall (X1:(fofType->Prop)), ((X1 emptyset)->((forall (X2:fofType), ((X1 X2)->(X1 (ordsucc X2))))->(X1 X0))))):(fofType->Prop)
% 208.54/208.80 nat_p_omega:(forall (X0:fofType), ((nat_p X0)->((in X0) omega)))
% 208.54/208.80 neq_ordsucc_0:(forall (X0:fofType), (not (((eq fofType) (ordsucc X0)) emptyset)))
% 208.54/208.80 nis:=(fun (X0:fofType) (X1:fofType)=> (d_not ((n_is X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.80 nissetprop:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((d_and (((esti X0) X3) X1)) (d_not (((esti X0) X3) X2)))):(fofType->(fofType->(fofType->(fofType->Prop))))
% 208.54/208.80 non:=(fun (X0:fofType) (X1:(fofType->Prop)) (X2:fofType)=> (d_not (X1 X2))):(fofType->((fofType->Prop)->(fofType->Prop)))
% 208.54/208.80 nonempty:=(fun (X0:fofType) (X1:fofType)=> ((l_some X0) (fun (X2:fofType)=> (((esti X0) X2) X1)))):(fofType->(fofType->Prop))
% 208.54/208.80 not:=(fun (P:Prop)=> (P->False)):(Prop->Prop)
% 208.54/208.80 obvious:=((imp False) False):Prop
% 208.54/208.80 omega:=((d_Sep (univof emptyset)) nat_p):fofType
% 208.54/208.80 omega_nat_p:(forall (X0:fofType), (((in X0) omega)->(nat_p X0)))
% 208.54/208.80 one:=(fun (X0:fofType) (X1:(fofType->Prop))=> ((d_and ((amone X0) X1)) ((l_some X0) X1))):(fofType->((fofType->Prop)->Prop))
% 208.54/208.80 oneax:(forall (X0:fofType) (X1:(fofType->Prop)), (((one X0) X1)->(X1 ((ind X0) X1))))
% 208.54/208.80 or3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((l_or X0) ((l_or X1) X2))):(Prop->(Prop->(Prop->Prop)))
% 208.54/208.80 or:(Prop->(Prop->Prop))
% 208.54/208.80 or_comm_i:=(fun (A:Prop) (B:Prop) (H:((or A) B))=> ((((((or_ind A) B) ((or B) A)) ((or_intror B) A)) ((or_introl B) A)) H)):(forall (A:Prop) (B:Prop), (((or A) B)->((or B) A)))
% 208.54/208.80 or_first:=(fun (A:Prop) (B:Prop)=> (((((or_ind A) B) ((B->A)->A)) (fun (x:A) (x0:(B->A))=> x)) (fun (x:B) (x0:(B->A))=> (x0 x)))):(forall (A:Prop) (B:Prop), (((or A) B)->((B->A)->A)))
% 208.54/208.80 or_ind:(forall (A:Prop) (B:Prop) (P:Prop), ((A->P)->((B->P)->(((or A) B)->P))))
% 208.54/208.80 or_introl:(forall (A:Prop) (B:Prop), (A->((or A) B)))
% 208.54/208.80 or_intror:(forall (A:Prop) (B:Prop), (B->((or A) B)))
% 208.54/208.80 or_second:=(fun (A:Prop) (B:Prop) (x:((or A) B))=> (((or_first B) A) (((or_comm_i A) B) x))):(forall (A:Prop) (B:Prop), (((or A) B)->((A->B)->B)))
% 208.54/208.80 ordsucc:=(fun (X0:fofType)=> ((binunion X0) (d_Sing X0))):(fofType->fofType)
% 208.54/208.80 ordsucc_inj:(forall (X0:fofType) (X1:fofType), ((((eq fofType) (ordsucc X0)) (ordsucc X1))->(((eq fofType) X0) X1)))
% 208.54/208.80 orec3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((d_and (((or3 X0) X1) X2)) (((ec3 X0) X1) X2))):(Prop->(Prop->(Prop->Prop)))
% 208.54/208.80 orec:=(fun (X0:Prop) (X1:Prop)=> ((d_and ((l_or X0) X1)) ((l_ec X0) X1))):(Prop->(Prop->Prop))
% 208.54/208.80 otax1:(forall (X0:fofType) (X1:(fofType->Prop)), (((injective ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1))))
% 208.54/208.80 otax2:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((X1 X2)->((((image ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1))) X2)))))
% 208.54/208.80 out:=(fun (X0:fofType) (X1:(fofType->Prop))=> (((soft ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1)))):(fofType->((fofType->Prop)->(fofType->fofType)))
% 208.54/208.80 pair:=(fun (X0:fofType) (X1:fofType)=> ((binunion ((repl X0) d_Inj0)) ((repl X1) d_Inj1))):(fofType->(fofType->fofType))
% 208.54/208.80 pair_Sigma:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) X0)->(forall (X3:fofType), (((in X3) (X1 X2))->((in ((pair X2) X3)) ((d_Sigma X0) X1))))))
% 208.54/208.80 pair_p:=(fun (X0:fofType)=> (((eq fofType) ((pair ((ap X0) emptyset)) ((ap X0) (ordsucc emptyset)))) X0)):(fofType->Prop)
% 208.54/208.80 pairis1:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> (((e_is ((setprod X0) X1)) ((((d_pair X0) X1) (((first X0) X1) X2)) (((second X0) X1) X2))) X2))))
% 208.54/208.80 plus:=(fun (X0:fofType)=> ((ind ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_24_prop2 X0))):(fofType->fofType)
% 208.54/208.80 power:(fofType->fofType)
% 208.54/208.80 proj0:=(fun (X0:fofType)=> (((d_ReplSep X0) (fun (X1:fofType)=> ((ex fofType) (fun (X2:fofType)=> (((eq fofType) (d_Inj0 X2)) X1))))) d_Unj)):(fofType->fofType)
% 208.54/208.80 proj0_Sigma:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((in (proj0 X2)) X0)))
% 208.54/208.80 proj0_pair_eq:(forall (X0:fofType) (X1:fofType), (((eq fofType) (proj0 ((pair X0) X1))) X0))
% 208.54/208.80 proj1:(forall (A:Prop) (B:Prop), (((and A) B)->A))
% 208.54/208.80 proj1_Sigma:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((in (_TPTP_proj1 X2)) (X1 (proj0 X2)))))
% 208.54/208.80 proj1_pair_eq:(forall (X0:fofType) (X1:fofType), (((eq fofType) (_TPTP_proj1 ((pair X0) X1))) X1))
% 208.54/208.80 proj2:(forall (A:Prop) (B:Prop), (((and A) B)->B))
% 208.54/208.80 proj_Sigma_eta:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->(((eq fofType) ((pair (proj0 X2)) (_TPTP_proj1 X2))) X2)))
% 208.54/208.80 prop1:=(fun (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_and ((imp X0) (((e_is X1) X4) X2))) ((imp (d_not X0)) (((e_is X1) X4) X3)))):(Prop->(fofType->(fofType->(fofType->(fofType->Prop)))))
% 208.54/208.80 prop2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType) (X5:fofType)=> ((l_some X0) ((((((d_10_prop1 X0) X1) X2) X3) X4) X5))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->Prop))))))
% 208.54/208.80 prop3:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is ((ap X0) X2)) ((ap X1) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.80 prop4:=(fun (X0:fofType)=> ((l_some ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_24_prop2 X0))):(fofType->Prop)
% 208.54/208.80 r_ec:=(fun (X0:Prop) (X1:Prop)=> (X0->(d_not X1))):(Prop->(Prop->Prop))
% 208.54/208.80 refis:(forall (X0:fofType), ((all_of (fun (X1:fofType)=> ((in X1) X0))) (fun (X1:fofType)=> (((e_is X0) X1) X1))))
% 208.54/208.80 relational_choice:(forall (A:Type) (B:Type) (R:(A->(B->Prop))), ((forall (x:A), ((ex B) (fun (y:B)=> ((R x) y))))->((ex (A->(B->Prop))) (fun (R':(A->(B->Prop)))=> ((and ((((subrelation A) B) R') R)) (forall (x:A), ((ex B) ((unique B) (fun (y:B)=> ((R' x) y))))))))))
% 208.54/208.80 repl:(fofType->((fofType->fofType)->fofType))
% 208.54/208.80 satz10:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((orec3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))))))
% 208.54/208.80 satz10a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((or3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))))))
% 208.54/208.80 satz10b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((ec3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))))))
% 208.54/208.80 satz10c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((moreis X0) X1)->(d_not ((iii X0) X1)))))))
% 208.54/208.80 satz10d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((lessis X0) X1)->(d_not ((d_29_ii X0) X1)))))))
% 208.54/208.80 satz10e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((d_29_ii X0) X1))->((lessis X0) X1))))))
% 208.54/208.80 satz10f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((iii X0) X1))->((moreis X0) X1))))))
% 208.54/208.80 satz10g:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X0) X1)->(d_not ((lessis X0) X1)))))))
% 208.54/208.80 satz10h:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X0) X1)->(d_not ((moreis X0) X1)))))))
% 208.54/208.80 satz10j:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((moreis X0) X1))->((iii X0) X1))))))
% 208.54/208.80 satz10k:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((lessis X0) X1))->((d_29_ii X0) X1))))))
% 208.54/208.80 satz11:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X0) X1)->((iii X1) X0))))))
% 208.54/208.80 satz12:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X0) X1)->((d_29_ii X1) X0))))))
% 208.54/208.80 satz13:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((moreis X0) X1)->((lessis X1) X0))))))
% 208.54/208.80 satz14:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((lessis X0) X1)->((moreis X1) X0))))))
% 208.54/208.80 satz15:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->(((iii X1) X2)->((iii X0) X2)))))))))
% 208.54/208.80 satz16a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->(((iii X1) X2)->((iii X0) X2)))))))))
% 208.54/208.80 satz16b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->(((lessis X1) X2)->((iii X0) X2)))))))))
% 208.54/208.80 satz16c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->(((d_29_ii X1) X2)->((d_29_ii X0) X2)))))))))
% 208.54/208.80 satz16d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->(((moreis X1) X2)->((d_29_ii X0) X2)))))))))
% 208.54/208.80 satz17:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->(((lessis X1) X2)->((lessis X0) X2)))))))))
% 208.54/208.80 satz18:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_29_ii ((n_pl X0) X1)) X0)))))
% 208.54/208.80 satz18a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((iii X0) ((n_pl X0) X1))))))
% 208.54/208.80 satz18b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((d_29_ii (ordsucc X0)) X0)))
% 208.54/208.80 satz18c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((iii X0) (ordsucc X0))))
% 208.54/208.80 satz19a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.54/208.80 satz19b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is X0) X1)->((n_is ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.54/208.80 satz19c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->((iii ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.54/208.80 satz19d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->((d_29_ii ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.54/208.80 satz19e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is X0) X1)->((n_is ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.54/208.80 satz19f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->((iii ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.54/208.80 satz19g:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.80 satz19h:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X2) X0)) ((n_pl X3) X1))))))))))))
% 208.54/208.80 satz19j:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.80 satz19k:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((iii X2) X3)->((iii ((n_pl X2) X0)) ((n_pl X3) X1))))))))))))
% 208.54/208.80 satz19l:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->((moreis ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.54/208.80 satz19m:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->((moreis ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.54/208.80 satz19n:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->((lessis ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.54/208.80 satz19o:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->((lessis ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.54/208.80 satz1:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((nis X0) X1)->((nis (ordsucc X0)) (ordsucc X1)))))))
% 208.54/208.80 satz20a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X2))->((d_29_ii X0) X1))))))))
% 208.54/208.80 satz20b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X0) X2)) ((n_pl X1) X2))->((n_is X0) X1))))))))
% 208.54/208.80 satz20c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii ((n_pl X0) X2)) ((n_pl X1) X2))->((iii X0) X1))))))))
% 208.54/208.80 satz20d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii ((n_pl X2) X0)) ((n_pl X2) X1))->((d_29_ii X0) X1))))))))
% 208.54/208.80 satz20e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X2) X0)) ((n_pl X2) X1))->((n_is X0) X1))))))))
% 208.54/208.80 satz20f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii ((n_pl X2) X0)) ((n_pl X2) X1))->((iii X0) X1))))))))
% 208.54/208.80 satz21:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((d_29_ii X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.80 satz21a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((iii X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.80 satz22a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((moreis X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.80 satz22b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((d_29_ii X0) X1)->(((moreis X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.80 satz22c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((lessis X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.80 satz22d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((iii X0) X1)->(((lessis X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.80 satz23:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((moreis X0) X1)->(((moreis X2) X3)->((moreis ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.80 satz23a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((lessis X0) X1)->(((lessis X2) X3)->((lessis ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.80 satz24:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((moreis X0) n_1)))
% 208.54/208.80 satz24a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (lessis n_1))
% 208.54/208.80 satz24b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((d_29_ii (ordsucc X0)) n_1)))
% 208.54/208.80 satz24c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((iii n_1) (ordsucc X0))))
% 208.54/208.80 satz25:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X1) X0)->((moreis X1) ((n_pl X0) n_1)))))))
% 208.54/208.80 satz25a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X1) X0)->((moreis X1) (ordsucc X0)))))))
% 208.54/208.80 satz25b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) X0)->((lessis ((n_pl X1) n_1)) X0))))))
% 208.54/208.80 satz25c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) X0)->((lessis (ordsucc X1)) X0))))))
% 208.54/208.80 satz26:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) ((n_pl X0) n_1))->((lessis X1) X0))))))
% 208.54/208.80 satz26a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) (ordsucc X0))->((lessis X1) X0))))))
% 208.54/208.80 satz26b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii ((n_pl X1) n_1)) X0)->((moreis X1) X0))))))
% 208.54/208.80 satz26c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii (ordsucc X1)) X0)->((moreis X1) X0))))))
% 208.54/208.80 satz27:(forall (X0:(fofType->Prop)), ((n_some X0)->(n_some (min X0))))
% 208.54/208.80 satz27a:(forall (X0:(fofType->Prop)), ((n_some X0)->(n_one (min X0))))
% 208.54/208.80 satz28:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((one ((d_Pi nat) (fun (X1:fofType)=> nat))) (fun (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) X0)) (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) ((n_pl ((ap X1) X2)) X0)))))))))
% 208.54/208.80 satz28a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_ts X0) n_1)) X0)))
% 208.54/208.80 satz28b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_ts X0) (ordsucc X1))) ((n_pl ((n_ts X0) X1)) X0))))))
% 208.54/208.80 satz28c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_ts n_1) X0)) X0)))
% 208.54/208.80 satz28d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_ts (ordsucc X0)) X1)) ((n_pl ((n_ts X0) X1)) X1))))))
% 208.54/208.80 satz2:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((nis (ordsucc X0)) X0)))
% 208.54/208.80 satz3:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> (((nis X0) n_1)->(n_some (fun (X1:fofType)=> ((n_is X0) (ordsucc X1)))))))
% 208.54/208.80 satz3a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> (((nis X0) n_1)->(n_one (fun (X1:fofType)=> ((n_is X0) (ordsucc X1)))))))
% 208.54/208.80 satz4:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((one ((d_Pi nat) (fun (X1:fofType)=> nat))) (fun (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) (ordsucc X0))) (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) (ordsucc ((ap X1) X2))))))))))
% 208.54/208.80 satz4a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_pl X0) n_1)) (ordsucc X0))))
% 208.54/208.80 satz4b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl X0) (ordsucc X1))) (ordsucc ((n_pl X0) X1)))))))
% 208.54/208.80 satz4c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_pl n_1) X0)) (ordsucc X0))))
% 208.54/208.80 satz4d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl (ordsucc X0)) X1)) (ordsucc ((n_pl X0) X1)))))))
% 208.54/208.80 satz4e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is (ordsucc X0)) ((n_pl X0) n_1))))
% 208.54/208.80 satz4f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is (ordsucc ((n_pl X0) X1))) ((n_pl X0) (ordsucc X1)))))))
% 208.54/208.80 satz4g:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is (ordsucc X0)) ((n_pl n_1) X0))))
% 208.54/208.80 satz4h:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is (ordsucc ((n_pl X0) X1))) ((n_pl (ordsucc X0)) X1))))))
% 208.54/208.80 satz5:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((n_is ((n_pl ((n_pl X0) X1)) X2)) ((n_pl X0) ((n_pl X1) X2)))))))))
% 208.54/208.80 satz6:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl X0) X1)) ((n_pl X1) X0))))))
% 208.54/208.80 satz7:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((nis X1) ((n_pl X0) X1))))))
% 208.54/208.80 satz8:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((nis X1) X2)->((nis ((n_pl X0) X1)) ((n_pl X0) X2)))))))))
% 208.54/208.80 satz8a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X0) X1)) ((n_pl X0) X2))->((n_is X1) X2))))))))
% 208.54/208.80 satz8b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((amone nat) (fun (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))))))))
% 208.54/208.80 satz9:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((orec3 ((n_is X0) X1)) (n_some (fun (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))))) (n_some (fun (X2:fofType)=> ((n_is X1) ((n_pl X0) X2)))))))))
% 208.54/208.80 satz9a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((or3 ((n_is X0) X1)) (n_some ((diffprop X0) X1))) (n_some ((diffprop X1) X0)))))))
% 208.54/208.80 satz9b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((ec3 ((n_is X0) X1)) (n_some ((diffprop X0) X1))) (n_some ((diffprop X1) X0)))))))
% 208.54/208.80 second:=(fun (X0:fofType) (X1:fofType)=> _TPTP_proj1):(fofType->(fofType->(fofType->fofType)))
% 208.54/208.80 second_p:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> ((is_of (((second X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X1))))))
% 208.54/208.80 secondis1:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> (((e_is X1) (((second X0) X1) ((((d_pair X0) X1) X2) X3))) X3))))))
% 208.54/208.80 set_ext:(forall (X0:fofType) (X1:fofType), (((d_Subq X0) X1)->(((d_Subq X1) X0)->(((eq fofType) X0) X1))))
% 208.54/208.80 setminus:=(fun (X0:fofType) (X1:fofType)=> ((d_Sep X0) (fun (X2:fofType)=> ((nIn X2) X1)))):(fofType->(fofType->fofType))
% 208.54/208.80 setof_p:(forall (X0:fofType) (X1:(fofType->Prop)), ((is_of ((d_Sep X0) X1)) (fun (X2:fofType)=> ((in X2) (power X0)))))
% 208.54/208.80 setprod:=(fun (X0:fofType) (X1:fofType)=> ((d_Sigma X0) (fun (X2:fofType)=> X1))):(fofType->(fofType->fofType))
% 208.54/208.80 soft:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((ind X0) (fun (X4:fofType)=> (((e_is X1) X3) ((ap X2) X4))))):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.54/208.80 st_disj:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((l_ec (((esti X0) X3) X1)) (((esti X0) X3) X2))))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.80 subrelation:=(fun (A:Type) (B:Type) (R:(A->(B->Prop))) (R':(A->(B->Prop)))=> (forall (x:A) (y:B), (((R x) y)->((R' x) y)))):(forall (A:Type) (B:Type), ((A->(B->Prop))->((A->(B->Prop))->Prop)))
% 208.54/208.80 suc_p:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((is_of (ordsucc X0)) (fun (X1:fofType)=> ((in X1) nat)))))
% 208.54/208.80 surjective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X1) (((image X0) X1) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.80 times:=(fun (X0:fofType)=> ((ind ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_428_prop2 X0))):(fofType->fofType)
% 208.54/208.80 tofs:=(fun (X0:fofType) (X1:fofType)=> ap):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.54/208.80 union:(fofType->fofType)
% 208.54/208.80 unique:=(fun (A:Type) (P:(A->Prop)) (x:A)=> ((and (P x)) (forall (x':A), ((P x')->(((eq A) x) x'))))):(forall (A:Type), ((A->Prop)->(A->Prop)))
% 208.54/208.80 unique_choice:=(fun (A:Type) (B:Type) (R:(A->(B->Prop))) (x:(forall (x:A), ((ex B) ((unique B) (fun (y:B)=> ((R x) y))))))=> ((((dependent_unique_choice A) (fun (x2:A)=> B)) R) x)):(forall (A:Type) (B:Type) (R:(A->(B->Prop))), ((forall (x:A), ((ex B) ((unique B) (fun (y:B)=> ((R x) y)))))->((ex (A->B)) (fun (f:(A->B))=> (forall (x:A), ((R x) (f x)))))))
% 208.54/208.80 univof:(fofType->fofType)
% 208.54/208.80 unmore:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sep X0) (fun (X3:fofType)=> ((l_some X1) (fun (X4:fofType)=> (((esti X0) X3) ((ap X2) X4))))))):(fofType->(fofType->(fofType->fofType)))
% 208.54/208.80 wel:=(fun (X0:Prop)=> (d_not (d_not X0))):(Prop->Prop)
% 208.54/208.80 wissel:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X0) (((wissel_wb X0) X1) X2))):(fofType->(fofType->(fofType->fofType)))
% 208.54/208.80 wissel_wa:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((((ite (((e_is X0) X3) X1)) X0) X2) X3)):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.54/208.80 wissel_wb:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((((ite (((e_is X0) X3) X2)) X0) X1) ((((wissel_wa X0) X1) X2) X3))):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.54/208.82 xi_ext:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X0)->(((eq fofType) (X1 X3)) (X2 X3))))->(((eq fofType) ((d_Sigma X0) X1)) ((d_Sigma X0) X2))))]X0:fofType
% 208.54/208.82 X1:(fofType->Prop)
% 208.54/208.82 X2:fofType]x:((is_of X2) (fun (X2:fofType)=> ((in X2) ((d_Sep X0) X1))))]x0:fofType
% 208.54/208.82 ---subcontext
% 208.54/208.82 [False:Prop
% 208.54/208.82 False_rect:(forall (P:Type), (False->P))
% 208.54/208.82 I:True
% 208.54/208.82 NNPP:=(fun (P:Prop) (H:(not (not P)))=> ((fun (C:((or P) (not P)))=> ((((((or_ind P) (not P)) P) (fun (H0:P)=> H0)) (fun (N:(not P))=> ((False_rect P) (H N)))) C)) (classic P))):(forall (P:Prop), ((not (not P))->P))
% 208.54/208.82 True:Prop
% 208.54/208.82 _TPTP_proj1:=(fun (X0:fofType)=> (((d_ReplSep X0) (fun (X1:fofType)=> ((ex fofType) (fun (X2:fofType)=> (((eq fofType) (d_Inj1 X2)) X1))))) d_Unj)):(fofType->fofType)
% 208.54/208.82 all:=(fun (X0:fofType)=> (all_of (fun (X1:fofType)=> ((in X1) X0)))):(fofType->((fofType->Prop)->Prop))
% 208.54/208.82 all_of:=(fun (X0:(fofType->Prop)) (X1:(fofType->Prop))=> (forall (X2:fofType), (((is_of X2) X0)->(X1 X2)))):((fofType->Prop)->((fofType->Prop)->Prop))
% 208.54/208.82 amone:=(fun (X0:fofType) (X1:(fofType->Prop))=> ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X0))) (fun (X3:fofType)=> ((X1 X2)->((X1 X3)->(((e_is X0) X2) X3)))))))):(fofType->((fofType->Prop)->Prop))
% 208.54/208.82 and3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((d_and X0) ((d_and X1) X2))):(Prop->(Prop->(Prop->Prop)))
% 208.54/208.82 and:(Prop->(Prop->Prop))
% 208.54/208.82 and_comm_i:=(fun (A:Prop) (B:Prop) (H:((and A) B))=> ((((conj B) A) (((proj2 A) B) H)) (((proj1 A) B) H))):(forall (A:Prop) (B:Prop), (((and A) B)->((and B) A)))
% 208.54/208.82 and_rect:=(fun (A:Prop) (B:Prop) (P:Type) (X:(A->(B->P))) (H:((and A) B))=> ((X (((proj1 A) B) H)) (((proj2 A) B) H))):(forall (A:Prop) (B:Prop) (P:Type), ((A->(B->P))->(((and A) B)->P)))
% 208.54/208.82 anec:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> ((l_some X0) (((ecp X0) X1) X2))):(fofType->((fofType->(fofType->Prop))->(fofType->Prop)))
% 208.54/208.82 ap:=(fun (X0:fofType) (X1:fofType)=> (((d_ReplSep X0) (fun (X2:fofType)=> ((ex fofType) (fun (X3:fofType)=> (((eq fofType) X2) ((pair X1) X3)))))) _TPTP_proj1)):(fofType->(fofType->fofType))
% 208.54/208.82 ap_Pi:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType) (X3:fofType), (((in X2) ((d_Pi X0) X1))->(((in X3) X0)->((in ((ap X2) X3)) (X1 X3)))))
% 208.54/208.82 beta:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) X0)->(((eq fofType) ((ap ((d_Sigma X0) X1)) X2)) (X1 X2))))
% 208.54/208.82 bijective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_and (((injective X0) X1) X2)) (((surjective X0) X1) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.82 binunion:=(fun (X0:fofType) (X1:fofType)=> (union ((d_UPair X0) X1))):(fofType->(fofType->fofType))
% 208.54/208.82 changef:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_Sigma X0) (fun (X5:fofType)=> ((ap X2) ((ap (((wissel X0) X3) X4)) X5))))):(fofType->(fofType->(fofType->(fofType->(fofType->fofType)))))
% 208.54/208.82 choice:=(fun (A:Type) (B:Type) (R:(A->(B->Prop))) (x:(forall (x:A), ((ex B) (fun (y:B)=> ((R x) y)))))=> (((fun (P:Prop) (x0:(forall (x0:(A->(B->Prop))), (((and ((((subrelation A) B) x0) R)) (forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y))))))->P)))=> (((((ex_ind (A->(B->Prop))) (fun (R':(A->(B->Prop)))=> ((and ((((subrelation A) B) R') R)) (forall (x0:A), ((ex B) ((unique B) (fun (y:B)=> ((R' x0) y)))))))) P) x0) ((((relational_choice A) B) R) x))) ((ex (A->B)) (fun (f:(A->B))=> (forall (x0:A), ((R x0) (f x0)))))) (fun (x0:(A->(B->Prop))) (x1:((and ((((subrelation A) B) x0) R)) (forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y)))))))=> (((fun (P:Type) (x2:(((((subrelation A) B) x0) R)->((forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y)))))->P)))=> (((((and_rect ((((subrelation A) B) x0) R)) (forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y)))))) P) x2) x1)) ((ex (A->B)) (fun (f:(A->B))=> (forall (x0:A), ((R x0) (f x0)))))) (fun (x2:((((subrelation A) B) x0) R)) (x3:(forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y))))))=> (((fun (P:Prop) (x4:(forall (x1:(A->B)), ((forall (x10:A), ((x0 x10) (x1 x10)))->P)))=> (((((ex_ind (A->B)) (fun (f:(A->B))=> (forall (x1:A), ((x0 x1) (f x1))))) P) x4) ((((unique_choice A) B) x0) x3))) ((ex (A->B)) (fun (f:(A->B))=> (forall (x0:A), ((R x0) (f x0)))))) (fun (x4:(A->B)) (x5:(forall (x10:A), ((x0 x10) (x4 x10))))=> ((((ex_intro (A->B)) (fun (f:(A->B))=> (forall (x0:A), ((R x0) (f x0))))) x4) (fun (x00:A)=> (((x2 x00) (x4 x00)) (x5 x00))))))))))):(forall (A:Type) (B:Type) (R:(A->(B->Prop))), ((forall (x:A), ((ex B) (fun (y:B)=> ((R x) y))))->((ex (A->B)) (fun (f:(A->B))=> (forall (x:A), ((R x) (f x)))))))
% 208.54/208.82 choice_operator:=(fun (A:Type) (a:A)=> ((((classical_choice (A->Prop)) A) (fun (x3:(A->Prop))=> x3)) a)):(forall (A:Type), (A->((ex ((A->Prop)->A)) (fun (co:((A->Prop)->A))=> (forall (P:(A->Prop)), (((ex A) (fun (x:A)=> (P x)))->(P (co P))))))))
% 208.54/208.82 classic:(forall (P:Prop), ((or P) (not P)))
% 208.54/208.82 classical_choice:=(fun (A:Type) (B:Type) (R:(A->(B->Prop))) (b:B)=> ((fun (C:((forall (x:A), ((ex B) (fun (y:B)=> (((fun (x0:A) (y0:B)=> (((ex B) (fun (z:B)=> ((R x0) z)))->((R x0) y0))) x) y))))->((ex (A->B)) (fun (f:(A->B))=> (forall (x:A), (((fun (x0:A) (y:B)=> (((ex B) (fun (z:B)=> ((R x0) z)))->((R x0) y))) x) (f x)))))))=> (C (fun (x:A)=> ((fun (C0:((or ((ex B) (fun (z:B)=> ((R x) z)))) (not ((ex B) (fun (z:B)=> ((R x) z))))))=> ((((((or_ind ((ex B) (fun (z:B)=> ((R x) z)))) (not ((ex B) (fun (z:B)=> ((R x) z))))) ((ex B) (fun (y:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y))))) ((((ex_ind B) (fun (z:B)=> ((R x) z))) ((ex B) (fun (y:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y))))) (fun (y:B) (H:((R x) y))=> ((((ex_intro B) (fun (y0:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y0)))) y) (fun (_:((ex B) (fun (z:B)=> ((R x) z))))=> H))))) (fun (N:(not ((ex B) (fun (z:B)=> ((R x) z)))))=> ((((ex_intro B) (fun (y:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y)))) b) (fun (H:((ex B) (fun (z:B)=> ((R x) z))))=> ((False_rect ((R x) b)) (N H)))))) C0)) (classic ((ex B) (fun (z:B)=> ((R x) z)))))))) (((choice A) B) (fun (x:A) (y:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y)))))):(forall (A:Type) (B:Type) (R:(A->(B->Prop))), (B->((ex (A->B)) (fun (f:(A->B))=> (forall (x:A), (((ex B) (fun (y:B)=> ((R x) y)))->((R x) (f x))))))))
% 208.54/208.82 cond1:=(n_in n_1):(fofType->Prop)
% 208.54/208.82 cond2:=(fun (X0:fofType)=> (n_all (fun (X1:fofType)=> ((imp ((n_in X1) X0)) ((n_in (ordsucc X1)) X0))))):(fofType->Prop)
% 208.54/208.82 conj:(forall (A:Prop) (B:Prop), (A->(B->((and A) B))))
% 208.54/208.82 d_10_prop1:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType) (X5:fofType) (X6:fofType)=> ((d_and (((esti X0) X6) (((ecect X0) X1) X4))) (((e_is X2) ((ap X3) X6)) X5))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->(fofType->Prop)))))))
% 208.54/208.82 d_11_i:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> (((indeq X0) X1) ((d_Pi X0) (fun (X3:fofType)=> X2)))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->fofType)))))
% 208.54/208.82 d_22_prop1:=(fun (X0:fofType)=> ((nis (ordsucc X0)) X0)):(fofType->Prop)
% 208.54/208.82 d_23_prop1:=(fun (X0:fofType)=> ((l_or ((n_is X0) n_1)) (n_some (fun (X1:fofType)=> ((n_is X0) (ordsucc X1)))))):(fofType->Prop)
% 208.54/208.82 d_24_g:=(fun (X0:fofType)=> ((d_Sigma nat) (fun (X1:fofType)=> (ordsucc ((ap X0) X1))))):(fofType->fofType)
% 208.54/208.82 d_24_prop1:=(fun (X0:fofType)=> (n_all (fun (X1:fofType)=> ((n_is ((ap X0) (ordsucc X1))) (ordsucc ((ap X0) X1)))))):(fofType->Prop)
% 208.54/208.82 d_24_prop2:=(fun (X0:fofType) (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) (ordsucc X0))) (d_24_prop1 X1))):(fofType->(fofType->Prop))
% 208.54/208.82 d_25_prop1:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is ((n_pl ((n_pl X0) X1)) X2)) ((n_pl X0) ((n_pl X1) X2)))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.82 d_26_prop1:=(fun (X0:fofType) (X1:fofType)=> ((n_is ((n_pl X0) X1)) ((n_pl X1) X0))):(fofType->(fofType->Prop))
% 208.54/208.82 d_27_prop1:=(fun (X0:fofType) (X1:fofType)=> ((nis X1) ((n_pl X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.82 d_28_prop1:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((nis ((n_pl X0) X1)) ((n_pl X0) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.82 d_29_ii:=(fun (X0:fofType) (X1:fofType)=> (n_some ((diffprop X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.82 d_29_prop1:=(fun (X0:fofType) (X1:fofType)=> (((or3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.82 d_428_g:=(fun (X0:fofType)=> ((d_Sigma nat) (fun (X1:fofType)=> ((n_pl ((ap X0) X1)) X1)))):(fofType->fofType)
% 208.54/208.82 d_428_id:=((d_Sigma nat) (fun (X0:fofType)=> X0)):fofType
% 208.54/208.82 d_428_prop1:=(fun (X0:fofType) (X1:fofType)=> (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) ((n_pl ((ap X1) X2)) X0))))):(fofType->(fofType->Prop))
% 208.54/208.82 d_428_prop2:=(fun (X0:fofType) (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) X0)) ((d_428_prop1 X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.82 d_428_prop4:=(fun (X0:fofType)=> ((l_some ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_428_prop2 X0))):(fofType->Prop)
% 208.54/208.82 d_In_rec:=(fun (X0:(fofType->((fofType->fofType)->fofType))) (X1:fofType)=> (eps ((d_In_rec_G X0) X1))):((fofType->((fofType->fofType)->fofType))->(fofType->fofType))
% 208.54/208.82 d_In_rec_G:=(fun (X0:(fofType->((fofType->fofType)->fofType))) (X1:fofType) (X2:fofType)=> (forall (X3:(fofType->(fofType->Prop))), ((forall (X4:fofType) (X5:(fofType->fofType)), ((forall (X6:fofType), (((in X6) X4)->((X3 X6) (X5 X6))))->((X3 X4) ((X0 X4) X5))))->((X3 X1) X2)))):((fofType->((fofType->fofType)->fofType))->(fofType->(fofType->Prop)))
% 208.54/208.82 d_Inj0:=(fun (X0:fofType)=> ((repl X0) d_Inj1)):(fofType->fofType)
% 208.54/208.82 d_Inj1:=(d_In_rec (fun (X0:fofType) (X1:(fofType->fofType))=> ((binunion (d_Sing emptyset)) ((repl X0) X1)))):(fofType->fofType)
% 208.54/208.82 d_Pi:=(fun (X0:fofType) (X1:(fofType->fofType))=> ((d_Sep (power ((d_Sigma X0) (fun (X2:fofType)=> (union (X1 X2)))))) (fun (X2:fofType)=> (forall (X3:fofType), (((in X3) X0)->((in ((ap X2) X3)) (X1 X3))))))):(fofType->((fofType->fofType)->fofType))
% 208.54/208.82 d_Power_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->((in (power X1)) X0)))):(fofType->Prop)
% 208.54/208.82 d_ReplSep:=(fun (X0:fofType) (X1:(fofType->Prop))=> (repl ((d_Sep X0) X1))):(fofType->((fofType->Prop)->((fofType->fofType)->fofType)))
% 208.54/208.82 d_Repl_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->(forall (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X1)->((in (X2 X3)) X0)))->((in ((repl X1) X2)) X0)))))):(fofType->Prop)
% 208.54/208.82 d_Sep:=(fun (X0:fofType) (X1:(fofType->Prop))=> (((if ((ex fofType) (fun (X2:fofType)=> ((and ((in X2) X0)) (X1 X2))))) ((repl X0) (fun (X2:fofType)=> (((if (X1 X2)) X2) (eps (fun (X3:fofType)=> ((and ((in X3) X0)) (X1 X3)))))))) emptyset)):(fofType->((fofType->Prop)->fofType))
% 208.54/208.82 d_Sigma:=(fun (X0:fofType) (X1:(fofType->fofType))=> ((famunion X0) (fun (X2:fofType)=> ((repl (X1 X2)) (pair X2))))):(fofType->((fofType->fofType)->fofType))
% 208.54/208.82 d_Sing:=(fun (X0:fofType)=> ((d_UPair X0) X0)):(fofType->fofType)
% 208.54/208.82 d_Subq:=(fun (X0:fofType) (X1:fofType)=> (forall (X2:fofType), (((in X2) X0)->((in X2) X1)))):(fofType->(fofType->Prop))
% 208.54/208.82 d_UPair:=(fun (X0:fofType) (X1:fofType)=> ((repl (power (power emptyset))) (fun (X2:fofType)=> (((if ((in emptyset) X2)) X0) X1)))):(fofType->(fofType->fofType))
% 208.54/208.82 d_Union_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->((in (union X1)) X0)))):(fofType->Prop)
% 208.54/208.82 d_Unj:=(d_In_rec (fun (X0:fofType)=> (repl ((setminus X0) (d_Sing emptyset))))):(fofType->fofType)
% 208.54/208.82 d_ZF_closed:=(fun (X0:fofType)=> ((and ((and (d_Union_closed X0)) (d_Power_closed X0))) (d_Repl_closed X0))):(fofType->Prop)
% 208.54/208.82 d_and:=(fun (X0:Prop) (X1:Prop)=> (d_not ((l_ec X0) X1))):(Prop->(Prop->Prop))
% 208.54/208.82 d_not:=(fun (X0:Prop)=> ((imp X0) False)):(Prop->Prop)
% 208.54/208.82 d_pair:=(fun (X0:fofType) (X1:fofType)=> pair):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.54/208.82 dependent_unique_choice:(forall (A:Type) (B:(A->Type)) (R:(forall (x:A), ((B x)->Prop))), ((forall (x:A), ((ex (B x)) ((unique (B x)) (fun (y:(B x))=> ((R x) y)))))->((ex (forall (x:A), (B x))) (fun (f:(forall (x:A), (B x)))=> (forall (x:A), ((R x) (f x)))))))
% 208.54/208.82 diffprop:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.82 e_fisi:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Pi X0) (fun (X3:fofType)=> X1))))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) ((d_Pi X0) (fun (X4:fofType)=> X1))))) (fun (X3:fofType)=> (((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> (((e_is X1) ((ap X2) X4)) ((ap X3) X4))))->(((e_is ((d_Pi X0) (fun (X4:fofType)=> X1))) X2) X3)))))))
% 208.54/208.82 e_in:=(fun (X0:fofType) (X1:(fofType->Prop)) (X2:fofType)=> X2):(fofType->((fofType->Prop)->(fofType->fofType)))
% 208.54/208.82 e_in_p:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Sep X0) X1)))) (fun (X2:fofType)=> ((is_of (((e_in X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X0))))))
% 208.54/208.82 e_inp:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Sep X0) X1)))) (fun (X2:fofType)=> (X1 (((e_in X0) X1) X2)))))
% 208.54/208.82 e_is:=(fun (X0:fofType) (X:fofType) (Y:fofType)=> (((eq fofType) X) Y)):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.82 e_isp:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X0))) (fun (X3:fofType)=> ((X1 X2)->((((e_is X0) X2) X3)->(X1 X3))))))))
% 208.54/208.82 e_pair_p:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> ((is_of ((((d_pair X0) X1) X2) X3)) (fun (X4:fofType)=> ((in X4) ((setprod X0) X1)))))))))
% 208.54/208.82 ec3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> (((and3 ((l_ec X0) X1)) ((l_ec X1) X2)) ((l_ec X2) X0))):(Prop->(Prop->(Prop->Prop)))
% 208.54/208.82 ecect:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((e_in (power X0)) ((anec X0) X1))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 208.54/208.82 ecelt:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> ((d_Sep X0) (X1 X2))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 208.54/208.82 ecp:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> (((e_is (power X0)) X2) (((ecelt X0) X1) X3))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))
% 208.54/208.82 ect:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((d_Sep (power X0)) ((anec X0) X1))):(fofType->((fofType->(fofType->Prop))->fofType))
% 208.54/208.82 ectelt:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> (((ectset X0) X1) (((ecelt X0) X1) X2))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 208.54/208.82 ectset:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((out (power X0)) ((anec X0) X1))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 208.54/208.82 empty:=(fun (X0:fofType) (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) X0))) ((non X0) (fun (X2:fofType)=> (((esti X0) X2) X1))))):(fofType->(fofType->Prop))
% 208.54/208.82 emptyset:fofType
% 208.54/208.82 eps:((fofType->Prop)->fofType)
% 208.54/208.82 eq:=(fun (T:Type) (a:T) (b:T)=> (forall (P:(T->Prop)), ((P a)->(P b)))):(forall (T:Type), (T->(T->Prop)))
% 208.54/208.82 eq_ref:=(fun (T:Type) (a:T) (P:(T->Prop)) (x:(P a))=> x):(forall (T:Type) (a:T), (((eq T) a) a))
% 208.54/208.82 eq_stepl:=(fun (T:Type) (a:T) (b:T) (c:T) (X:(((eq T) a) b)) (Y:(((eq T) a) c))=> ((((((eq_trans T) c) a) b) ((((eq_sym T) a) c) Y)) X)):(forall (T:Type) (a:T) (b:T) (c:T), ((((eq T) a) b)->((((eq T) a) c)->(((eq T) c) b))))
% 208.54/208.82 eq_substitution:=(fun (T:Type) (U:Type) (a:T) (b:T) (f:(T->U)) (H:(((eq T) a) b))=> ((H (fun (x:T)=> (((eq U) (f a)) (f x)))) ((eq_ref U) (f a)))):(forall (T:Type) (U:Type) (a:T) (b:T) (f:(T->U)), ((((eq T) a) b)->(((eq U) (f a)) (f b))))
% 208.54/208.82 eq_sym:=(fun (T:Type) (a:T) (b:T) (H:(((eq T) a) b))=> ((H (fun (x:T)=> (((eq T) x) a))) ((eq_ref T) a))):(forall (T:Type) (a:T) (b:T), ((((eq T) a) b)->(((eq T) b) a)))
% 208.54/208.82 eq_trans:=(fun (T:Type) (a:T) (b:T) (c:T) (X:(((eq T) a) b)) (Y:(((eq T) b) c))=> ((Y (fun (t:T)=> (((eq T) a) t))) X)):(forall (T:Type) (a:T) (b:T) (c:T), ((((eq T) a) b)->((((eq T) b) c)->(((eq T) a) c))))
% 208.54/208.82 esti:=(fun (X0:fofType)=> in):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.82 estie:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((((esti X0) X2) ((d_Sep X0) X1))->(X1 X2)))))
% 208.54/208.82 estii:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((X1 X2)->(((esti X0) X2) ((d_Sep X0) X1))))))
% 208.54/208.82 eta_expansion:=(fun (A:Type) (B:Type)=> ((eta_expansion_dep A) (fun (x1:A)=> B))):(forall (A:Type) (B:Type) (f:(A->B)), (((eq (A->B)) f) (fun (x:A)=> (f x))))
% 208.54/208.82 eta_expansion_dep:=(fun (A:Type) (B:(A->Type)) (f:(forall (x:A), (B x)))=> (((((functional_extensionality_dep A) (fun (x1:A)=> (B x1))) f) (fun (x:A)=> (f x))) (fun (x:A) (P:((B x)->Prop)) (x0:(P (f x)))=> x0))):(forall (A:Type) (B:(A->Type)) (f:(forall (x:A), (B x))), (((eq (forall (x:A), (B x))) f) (fun (x:A)=> (f x))))
% 208.54/208.82 ex:(forall (A:Type), ((A->Prop)->Prop))
% 208.54/208.82 ex_ind:(forall (A:Type) (F:(A->Prop)) (P:Prop), ((forall (x:A), ((F x)->P))->(((ex A) F)->P)))
% 208.54/208.82 ex_intro:(forall (A:Type) (P:(A->Prop)) (x:A), ((P x)->((ex A) P)))
% 208.54/208.82 famunion:=(fun (X0:fofType) (X1:(fofType->fofType))=> (union ((repl X0) X1))):(fofType->((fofType->fofType)->fofType))
% 208.54/208.82 first:=(fun (X0:fofType) (X1:fofType)=> proj0):(fofType->(fofType->(fofType->fofType)))
% 208.54/208.82 first_p:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> ((is_of (((first X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X0))))))
% 208.54/208.82 firstis1:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> (((e_is X0) (((first X0) X1) ((((d_pair X0) X1) X2) X3))) X2))))))
% 208.54/208.82 fixfu2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> ((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> ((all_of (fun (X5:fofType)=> ((in X5) X0))) (fun (X5:fofType)=> ((all_of (fun (X6:fofType)=> ((in X6) X0))) (fun (X6:fofType)=> ((all_of (fun (X7:fofType)=> ((in X7) X0))) (fun (X7:fofType)=> (((X1 X4) X5)->(((X1 X6) X7)->(((e_is X2) ((ap ((ap X3) X4)) X6)) ((ap ((ap X3) X5)) X7))))))))))))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))
% 208.54/208.82 fixfu:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> ((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> ((all_of (fun (X5:fofType)=> ((in X5) X0))) (fun (X5:fofType)=> (((X1 X4) X5)->(((e_is X2) ((ap X3) X4)) ((ap X3) X5)))))))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))
% 208.54/208.82 fofType:Type
% 208.54/208.82 functional_extensionality:=(fun (A:Type) (B:Type)=> ((functional_extensionality_dep A) (fun (x1:A)=> B))):(forall (A:Type) (B:Type) (f:(A->B)) (g:(A->B)), ((forall (x:A), (((eq B) (f x)) (g x)))->(((eq (A->B)) f) g)))
% 208.54/208.82 functional_extensionality_dep:(forall (A:Type) (B:(A->Type)) (f:(forall (x:A), (B x))) (g:(forall (x:A), (B x))), ((forall (x:A), (((eq (B x)) (f x)) (g x)))->(((eq (forall (x:A), (B x))) f) g)))
% 208.54/208.82 functional_extensionality_double:=(fun (A:Type) (B:Type) (C:Type) (f:(A->(B->C))) (g:(A->(B->C))) (x:(forall (x:A) (y:B), (((eq C) ((f x) y)) ((g x) y))))=> (((((functional_extensionality_dep A) (fun (x2:A)=> (B->C))) f) g) (fun (x0:A)=> (((((functional_extensionality_dep B) (fun (x3:B)=> C)) (f x0)) (g x0)) (x x0))))):(forall (A:Type) (B:Type) (C:Type) (f:(A->(B->C))) (g:(A->(B->C))), ((forall (x:A) (y:B), (((eq C) ((f x) y)) ((g x) y)))->(((eq (A->(B->C))) f) g)))
% 208.54/208.82 i1_s:=(d_Sep nat):((fofType->Prop)->fofType)
% 208.54/208.82 if:=(fun (X0:Prop) (X1:fofType) (X2:fofType)=> (eps (fun (X3:fofType)=> ((or ((and X0) (((eq fofType) X3) X1))) ((and (X0->False)) (((eq fofType) X3) X2)))))):(Prop->(fofType->(fofType->fofType)))
% 208.54/208.82 if_i_0:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((X0->False)->(((eq fofType) (((if X0) X1) X2)) X2)))
% 208.54/208.82 if_i_1:(forall (X0:Prop) (X1:fofType) (X2:fofType), (X0->(((eq fofType) (((if X0) X1) X2)) X1)))
% 208.54/208.82 if_i_correct:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((or ((and X0) (((eq fofType) (((if X0) X1) X2)) X1))) ((and (X0->False)) (((eq fofType) (((if X0) X1) X2)) X2))))
% 208.54/208.82 if_i_or:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((or (((eq fofType) (((if X0) X1) X2)) X1)) (((eq fofType) (((if X0) X1) X2)) X2)))
% 208.54/208.82 iff:=(fun (A:Prop) (B:Prop)=> ((and (A->B)) (B->A))):(Prop->(Prop->Prop))
% 208.54/208.82 iff_refl:=(fun (A:Prop)=> ((((conj (A->A)) (A->A)) (fun (H:A)=> H)) (fun (H:A)=> H))):(forall (P:Prop), ((iff P) P))
% 208.54/208.82 iff_sym:=(fun (A:Prop) (B:Prop) (H:((iff A) B))=> ((((conj (B->A)) (A->B)) (((proj2 (A->B)) (B->A)) H)) (((proj1 (A->B)) (B->A)) H))):(forall (A:Prop) (B:Prop), (((iff A) B)->((iff B) A)))
% 208.54/208.82 iff_trans:=(fun (A:Prop) (B:Prop) (C:Prop) (AB:((iff A) B)) (BC:((iff B) C))=> ((((conj (A->C)) (C->A)) (fun (x:A)=> ((((proj1 (B->C)) (C->B)) BC) ((((proj1 (A->B)) (B->A)) AB) x)))) (fun (x:C)=> ((((proj2 (A->B)) (B->A)) AB) ((((proj2 (B->C)) (C->B)) BC) x))))):(forall (A:Prop) (B:Prop) (C:Prop), (((iff A) B)->(((iff B) C)->((iff A) C))))
% 208.54/208.82 iii:=(fun (X0:fofType) (X1:fofType)=> (n_some ((diffprop X1) X0))):(fofType->(fofType->Prop))
% 208.54/208.82 image:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((l_some X0) (fun (X4:fofType)=> (((e_is X1) X3) ((ap X2) X4))))):(fofType->(fofType->(fofType->(fofType->Prop))))
% 208.54/208.82 imp:=(fun (X0:Prop) (X1:Prop)=> (X0->X1)):(Prop->(Prop->Prop))
% 208.54/208.82 in:(fofType->(fofType->Prop))
% 208.54/208.82 incl:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((imp (((esti X0) X3) X1)) (((esti X0) X3) X2))))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.82 ind:=(fun (X0:fofType) (X1:(fofType->Prop))=> (eps (fun (X2:fofType)=> ((and ((in X2) X0)) (X1 X2))))):(fofType->((fofType->Prop)->fofType))
% 208.54/208.82 ind_p:(forall (X0:fofType) (X1:(fofType->Prop)), (((one X0) X1)->((is_of ((ind X0) X1)) (fun (X2:fofType)=> ((in X2) X0)))))
% 208.54/208.82 indeq2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType)=> ((((indeq X0) X1) X2) (((((d_11_i X0) X1) X2) X3) X4))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->fofType))))))
% 208.54/208.82 indeq:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType)=> ((ind X2) (((((prop2 X0) X1) X2) X3) X4))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->fofType)))))
% 208.54/208.82 inj_h:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_Sigma X0) (fun (X5:fofType)=> ((ap X4) ((ap X3) X5))))):(fofType->(fofType->(fofType->(fofType->(fofType->fofType)))))
% 208.54/208.82 injective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((all X0) (fun (X4:fofType)=> ((imp (((e_is X1) ((ap X2) X3)) ((ap X2) X4))) (((e_is X0) X3) X4))))))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.82 inverse:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X1) (fun (X3:fofType)=> (((if ((((image X0) X1) X2) X3)) ((((soft X0) X1) X2) X3)) emptyset)))):(fofType->(fofType->(fofType->fofType)))
% 208.54/208.82 invf:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X1) (((soft X0) X1) X2))):(fofType->(fofType->(fofType->fofType)))
% 208.54/208.82 is_of:=(fun (X0:fofType) (X1:(fofType->Prop))=> (X1 X0)):(fofType->((fofType->Prop)->Prop))
% 208.54/208.82 isseti:(forall (X0:fofType), ((all_of (fun (X1:fofType)=> ((in X1) (power X0)))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) (power X0)))) (fun (X2:fofType)=> ((((incl X0) X1) X2)->((((incl X0) X2) X1)->(((e_is (power X0)) X1) X2))))))))
% 208.54/208.82 ite:=(fun (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType)=> ((ind X1) ((((prop1 X0) X1) X2) X3))):(Prop->(fofType->(fofType->(fofType->fofType))))
% 208.54/208.82 k_EmptyAx:(((ex fofType) (fun (X0:fofType)=> ((in X0) emptyset)))->False)
% 208.54/208.82 k_If_In_01:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((X0->((in X1) X2))->((in (((if X0) X1) emptyset)) (((if X0) X2) (ordsucc emptyset)))))
% 208.54/208.82 k_If_In_then_E:(forall (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType), (X0->(((in X1) (((if X0) X2) X3))->((in X1) X2))))
% 208.54/208.82 k_In_0_1:((in emptyset) (ordsucc emptyset))
% 208.54/208.82 k_In_ind:(forall (X0:(fofType->Prop)), ((forall (X1:fofType), ((forall (X2:fofType), (((in X2) X1)->(X0 X2)))->(X0 X1)))->(forall (X1:fofType), (X0 X1))))
% 208.54/208.82 k_Pi_ext:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Pi X0) X1))->(forall (X3:fofType), (((in X3) ((d_Pi X0) X1))->((forall (X4:fofType), (((in X4) X0)->(((eq fofType) ((ap X2) X4)) ((ap X3) X4))))->(((eq fofType) X2) X3))))))
% 208.54/208.82 k_PowerE:(forall (X0:fofType) (X1:fofType), (((in X1) (power X0))->((d_Subq X1) X0)))
% 208.54/208.82 k_PowerEq:(forall (X0:fofType) (X1:fofType), ((iff ((in X1) (power X0))) ((d_Subq X1) X0)))
% 208.54/208.82 k_PowerI:(forall (X0:fofType) (X1:fofType), (((d_Subq X1) X0)->((in X1) (power X0))))
% 208.54/208.82 k_ReplEq:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), ((iff ((in X2) ((repl X0) X1))) ((ex fofType) (fun (X3:fofType)=> ((and ((in X3) X0)) (((eq fofType) X2) (X1 X3)))))))
% 208.54/208.82 k_Self_In_Power:(forall (X0:fofType), ((in X0) (power X0)))
% 208.54/208.82 k_SepE1:(forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) ((d_Sep X0) X1))->((in X2) X0)))
% 208.54/208.82 k_SepE2:(forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) ((d_Sep X0) X1))->(X1 X2)))
% 208.54/208.82 k_SepI:(forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) X0)->((X1 X2)->((in X2) ((d_Sep X0) X1)))))
% 208.54/208.82 k_Sigma_eta_proj0_proj1:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((and ((and (((eq fofType) ((pair (proj0 X2)) (_TPTP_proj1 X2))) X2)) ((in (proj0 X2)) X0))) ((in (_TPTP_proj1 X2)) (X1 (proj0 X2))))))
% 208.54/208.82 k_UnionEq:(forall (X0:fofType) (X1:fofType), ((iff ((in X1) (union X0))) ((ex fofType) (fun (X2:fofType)=> ((and ((in X1) X2)) ((in X2) X0))))))
% 208.54/208.82 k_UnivOf_In:(forall (X0:fofType), ((in X0) (univof X0)))
% 208.54/208.82 k_UnivOf_ZF_closed:(forall (X0:fofType), (d_ZF_closed (univof X0)))
% 208.54/208.82 l_ec:=(fun (X0:Prop) (X1:Prop)=> ((imp X0) (d_not X1))):(Prop->(Prop->Prop))
% 208.54/208.82 l_et:(forall (X0:Prop), ((wel X0)->X0))
% 208.54/208.82 l_iff:=(fun (X0:Prop) (X1:Prop)=> ((d_and ((imp X0) X1)) ((imp X1) X0))):(Prop->(Prop->Prop))
% 208.54/208.82 l_or:=(fun (X0:Prop)=> (imp (d_not X0))):(Prop->(Prop->Prop))
% 208.54/208.82 l_some:=(fun (X0:fofType) (X1:(fofType->Prop))=> (d_not ((all_of (fun (X2:fofType)=> ((in X2) X0))) ((non X0) X1)))):(fofType->((fofType->Prop)->Prop))
% 208.54/208.82 lam_Pi:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X0)->((in (X2 X3)) (X1 X3))))->((in ((d_Sigma X0) X2)) ((d_Pi X0) X1))))
% 208.54/208.82 lbprop:=(fun (X0:(fofType->Prop)) (X1:fofType) (X2:fofType)=> ((imp (X0 X2)) ((lessis X1) X2))):((fofType->Prop)->(fofType->(fofType->Prop)))
% 208.54/208.82 lessis:=(fun (X0:fofType) (X1:fofType)=> ((l_or ((iii X0) X1)) ((n_is X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.82 min:=(fun (X0:(fofType->Prop)) (X1:fofType)=> ((d_and ((n_lb X0) X1)) (X0 X1))):((fofType->Prop)->(fofType->Prop))
% 208.54/208.82 moreis:=(fun (X0:fofType) (X1:fofType)=> ((l_or ((d_29_ii X0) X1)) ((n_is X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.82 nIn:=(fun (X0:fofType) (X1:fofType)=> (((in X0) X1)->False)):(fofType->(fofType->Prop))
% 208.54/208.82 n_1:=(ordsucc emptyset):fofType
% 208.54/208.82 n_1_p:((is_of n_1) (fun (X0:fofType)=> ((in X0) nat)))
% 208.54/208.82 n_all:=(all nat):((fofType->Prop)->Prop)
% 208.54/208.82 n_ax3:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((nis (ordsucc X0)) n_1)))
% 208.54/208.82 n_ax4:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((n_is (ordsucc X0)) (ordsucc X1))->((n_is X0) X1))))))
% 208.54/208.82 n_ax5:((all_of (fun (X0:fofType)=> ((in X0) (power nat)))) (fun (X0:fofType)=> ((cond1 X0)->((cond2 X0)->((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_in X1) X0)))))))
% 208.54/208.82 n_in:=(esti nat):(fofType->(fofType->Prop))
% 208.54/208.82 n_is:=(e_is nat):(fofType->(fofType->Prop))
% 208.54/208.82 n_lb:=(fun (X0:(fofType->Prop)) (X1:fofType)=> (n_all ((lbprop X0) X1))):((fofType->Prop)->(fofType->Prop))
% 208.54/208.82 n_one:=(one nat):((fofType->Prop)->Prop)
% 208.54/208.82 n_pl:=(fun (X0:fofType)=> (ap (plus X0))):(fofType->(fofType->fofType))
% 208.54/208.82 n_some:=(l_some nat):((fofType->Prop)->Prop)
% 208.54/208.82 n_ts:=(fun (X0:fofType)=> (ap (times X0))):(fofType->(fofType->fofType))
% 208.54/208.82 nat:=((d_Sep omega) (fun (X0:fofType)=> (not (((eq fofType) X0) emptyset)))):fofType
% 208.54/208.82 nat_1:(nat_p (ordsucc emptyset))
% 208.54/208.82 nat_ind:(forall (X0:(fofType->Prop)), ((X0 emptyset)->((forall (X1:fofType), ((nat_p X1)->((X0 X1)->(X0 (ordsucc X1)))))->(forall (X1:fofType), ((nat_p X1)->(X0 X1))))))
% 208.54/208.82 nat_inv:(forall (X0:fofType), ((nat_p X0)->((or (((eq fofType) X0) emptyset)) ((ex fofType) (fun (X1:fofType)=> ((and (nat_p X1)) (((eq fofType) X0) (ordsucc X1))))))))
% 208.54/208.82 nat_ordsucc:(forall (X0:fofType), ((nat_p X0)->(nat_p (ordsucc X0))))
% 208.54/208.82 nat_p:=(fun (X0:fofType)=> (forall (X1:(fofType->Prop)), ((X1 emptyset)->((forall (X2:fofType), ((X1 X2)->(X1 (ordsucc X2))))->(X1 X0))))):(fofType->Prop)
% 208.54/208.82 nat_p_omega:(forall (X0:fofType), ((nat_p X0)->((in X0) omega)))
% 208.54/208.82 neq_ordsucc_0:(forall (X0:fofType), (not (((eq fofType) (ordsucc X0)) emptyset)))
% 208.54/208.82 nis:=(fun (X0:fofType) (X1:fofType)=> (d_not ((n_is X0) X1))):(fofType->(fofType->Prop))
% 208.54/208.82 nissetprop:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((d_and (((esti X0) X3) X1)) (d_not (((esti X0) X3) X2)))):(fofType->(fofType->(fofType->(fofType->Prop))))
% 208.54/208.82 non:=(fun (X0:fofType) (X1:(fofType->Prop)) (X2:fofType)=> (d_not (X1 X2))):(fofType->((fofType->Prop)->(fofType->Prop)))
% 208.54/208.82 nonempty:=(fun (X0:fofType) (X1:fofType)=> ((l_some X0) (fun (X2:fofType)=> (((esti X0) X2) X1)))):(fofType->(fofType->Prop))
% 208.54/208.82 not:=(fun (P:Prop)=> (P->False)):(Prop->Prop)
% 208.54/208.82 obvious:=((imp False) False):Prop
% 208.54/208.82 omega:=((d_Sep (univof emptyset)) nat_p):fofType
% 208.54/208.82 omega_nat_p:(forall (X0:fofType), (((in X0) omega)->(nat_p X0)))
% 208.54/208.82 one:=(fun (X0:fofType) (X1:(fofType->Prop))=> ((d_and ((amone X0) X1)) ((l_some X0) X1))):(fofType->((fofType->Prop)->Prop))
% 208.54/208.82 oneax:(forall (X0:fofType) (X1:(fofType->Prop)), (((one X0) X1)->(X1 ((ind X0) X1))))
% 208.54/208.82 or3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((l_or X0) ((l_or X1) X2))):(Prop->(Prop->(Prop->Prop)))
% 208.54/208.82 or:(Prop->(Prop->Prop))
% 208.54/208.82 or_comm_i:=(fun (A:Prop) (B:Prop) (H:((or A) B))=> ((((((or_ind A) B) ((or B) A)) ((or_intror B) A)) ((or_introl B) A)) H)):(forall (A:Prop) (B:Prop), (((or A) B)->((or B) A)))
% 208.54/208.82 or_first:=(fun (A:Prop) (B:Prop)=> (((((or_ind A) B) ((B->A)->A)) (fun (x:A) (x0:(B->A))=> x)) (fun (x:B) (x0:(B->A))=> (x0 x)))):(forall (A:Prop) (B:Prop), (((or A) B)->((B->A)->A)))
% 208.54/208.82 or_ind:(forall (A:Prop) (B:Prop) (P:Prop), ((A->P)->((B->P)->(((or A) B)->P))))
% 208.54/208.82 or_introl:(forall (A:Prop) (B:Prop), (A->((or A) B)))
% 208.54/208.82 or_intror:(forall (A:Prop) (B:Prop), (B->((or A) B)))
% 208.54/208.82 or_second:=(fun (A:Prop) (B:Prop) (x:((or A) B))=> (((or_first B) A) (((or_comm_i A) B) x))):(forall (A:Prop) (B:Prop), (((or A) B)->((A->B)->B)))
% 208.54/208.82 ordsucc:=(fun (X0:fofType)=> ((binunion X0) (d_Sing X0))):(fofType->fofType)
% 208.54/208.82 ordsucc_inj:(forall (X0:fofType) (X1:fofType), ((((eq fofType) (ordsucc X0)) (ordsucc X1))->(((eq fofType) X0) X1)))
% 208.54/208.82 orec3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((d_and (((or3 X0) X1) X2)) (((ec3 X0) X1) X2))):(Prop->(Prop->(Prop->Prop)))
% 208.54/208.82 orec:=(fun (X0:Prop) (X1:Prop)=> ((d_and ((l_or X0) X1)) ((l_ec X0) X1))):(Prop->(Prop->Prop))
% 208.54/208.82 otax1:(forall (X0:fofType) (X1:(fofType->Prop)), (((injective ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1))))
% 208.54/208.82 otax2:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((X1 X2)->((((image ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1))) X2)))))
% 208.54/208.82 out:=(fun (X0:fofType) (X1:(fofType->Prop))=> (((soft ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1)))):(fofType->((fofType->Prop)->(fofType->fofType)))
% 208.54/208.82 pair:=(fun (X0:fofType) (X1:fofType)=> ((binunion ((repl X0) d_Inj0)) ((repl X1) d_Inj1))):(fofType->(fofType->fofType))
% 208.54/208.82 pair_Sigma:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) X0)->(forall (X3:fofType), (((in X3) (X1 X2))->((in ((pair X2) X3)) ((d_Sigma X0) X1))))))
% 208.54/208.82 pair_p:=(fun (X0:fofType)=> (((eq fofType) ((pair ((ap X0) emptyset)) ((ap X0) (ordsucc emptyset)))) X0)):(fofType->Prop)
% 208.54/208.82 pairis1:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> (((e_is ((setprod X0) X1)) ((((d_pair X0) X1) (((first X0) X1) X2)) (((second X0) X1) X2))) X2))))
% 208.54/208.82 plus:=(fun (X0:fofType)=> ((ind ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_24_prop2 X0))):(fofType->fofType)
% 208.54/208.82 power:(fofType->fofType)
% 208.54/208.82 proj0:=(fun (X0:fofType)=> (((d_ReplSep X0) (fun (X1:fofType)=> ((ex fofType) (fun (X2:fofType)=> (((eq fofType) (d_Inj0 X2)) X1))))) d_Unj)):(fofType->fofType)
% 208.54/208.82 proj0_Sigma:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((in (proj0 X2)) X0)))
% 208.54/208.82 proj0_pair_eq:(forall (X0:fofType) (X1:fofType), (((eq fofType) (proj0 ((pair X0) X1))) X0))
% 208.54/208.82 proj1:(forall (A:Prop) (B:Prop), (((and A) B)->A))
% 208.54/208.82 proj1_Sigma:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((in (_TPTP_proj1 X2)) (X1 (proj0 X2)))))
% 208.54/208.82 proj1_pair_eq:(forall (X0:fofType) (X1:fofType), (((eq fofType) (_TPTP_proj1 ((pair X0) X1))) X1))
% 208.54/208.82 proj2:(forall (A:Prop) (B:Prop), (((and A) B)->B))
% 208.54/208.82 proj_Sigma_eta:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->(((eq fofType) ((pair (proj0 X2)) (_TPTP_proj1 X2))) X2)))
% 208.54/208.82 prop1:=(fun (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_and ((imp X0) (((e_is X1) X4) X2))) ((imp (d_not X0)) (((e_is X1) X4) X3)))):(Prop->(fofType->(fofType->(fofType->(fofType->Prop)))))
% 208.54/208.82 prop2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType) (X5:fofType)=> ((l_some X0) ((((((d_10_prop1 X0) X1) X2) X3) X4) X5))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->Prop))))))
% 208.54/208.82 prop3:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is ((ap X0) X2)) ((ap X1) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.82 prop4:=(fun (X0:fofType)=> ((l_some ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_24_prop2 X0))):(fofType->Prop)
% 208.54/208.82 r_ec:=(fun (X0:Prop) (X1:Prop)=> (X0->(d_not X1))):(Prop->(Prop->Prop))
% 208.54/208.82 refis:(forall (X0:fofType), ((all_of (fun (X1:fofType)=> ((in X1) X0))) (fun (X1:fofType)=> (((e_is X0) X1) X1))))
% 208.54/208.82 relational_choice:(forall (A:Type) (B:Type) (R:(A->(B->Prop))), ((forall (x:A), ((ex B) (fun (y:B)=> ((R x) y))))->((ex (A->(B->Prop))) (fun (R':(A->(B->Prop)))=> ((and ((((subrelation A) B) R') R)) (forall (x:A), ((ex B) ((unique B) (fun (y:B)=> ((R' x) y))))))))))
% 208.54/208.82 repl:(fofType->((fofType->fofType)->fofType))
% 208.54/208.82 satz10:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((orec3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))))))
% 208.54/208.82 satz10a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((or3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))))))
% 208.54/208.82 satz10b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((ec3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))))))
% 208.54/208.82 satz10c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((moreis X0) X1)->(d_not ((iii X0) X1)))))))
% 208.54/208.82 satz10d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((lessis X0) X1)->(d_not ((d_29_ii X0) X1)))))))
% 208.54/208.82 satz10e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((d_29_ii X0) X1))->((lessis X0) X1))))))
% 208.54/208.82 satz10f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((iii X0) X1))->((moreis X0) X1))))))
% 208.54/208.82 satz10g:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X0) X1)->(d_not ((lessis X0) X1)))))))
% 208.54/208.82 satz10h:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X0) X1)->(d_not ((moreis X0) X1)))))))
% 208.54/208.82 satz10j:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((moreis X0) X1))->((iii X0) X1))))))
% 208.54/208.82 satz10k:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((lessis X0) X1))->((d_29_ii X0) X1))))))
% 208.54/208.82 satz11:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X0) X1)->((iii X1) X0))))))
% 208.54/208.82 satz12:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X0) X1)->((d_29_ii X1) X0))))))
% 208.54/208.82 satz13:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((moreis X0) X1)->((lessis X1) X0))))))
% 208.54/208.82 satz14:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((lessis X0) X1)->((moreis X1) X0))))))
% 208.54/208.82 satz15:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->(((iii X1) X2)->((iii X0) X2)))))))))
% 208.54/208.82 satz16a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->(((iii X1) X2)->((iii X0) X2)))))))))
% 208.54/208.82 satz16b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->(((lessis X1) X2)->((iii X0) X2)))))))))
% 208.54/208.82 satz16c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->(((d_29_ii X1) X2)->((d_29_ii X0) X2)))))))))
% 208.54/208.82 satz16d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->(((moreis X1) X2)->((d_29_ii X0) X2)))))))))
% 208.54/208.82 satz17:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->(((lessis X1) X2)->((lessis X0) X2)))))))))
% 208.54/208.82 satz18:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_29_ii ((n_pl X0) X1)) X0)))))
% 208.54/208.82 satz18a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((iii X0) ((n_pl X0) X1))))))
% 208.54/208.82 satz18b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((d_29_ii (ordsucc X0)) X0)))
% 208.54/208.82 satz18c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((iii X0) (ordsucc X0))))
% 208.54/208.82 satz19a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.54/208.82 satz19b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is X0) X1)->((n_is ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.54/208.82 satz19c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->((iii ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.54/208.82 satz19d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->((d_29_ii ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.54/208.82 satz19e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is X0) X1)->((n_is ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.54/208.82 satz19f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->((iii ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.54/208.82 satz19g:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.82 satz19h:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X2) X0)) ((n_pl X3) X1))))))))))))
% 208.54/208.82 satz19j:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.82 satz19k:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((iii X2) X3)->((iii ((n_pl X2) X0)) ((n_pl X3) X1))))))))))))
% 208.54/208.82 satz19l:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->((moreis ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.54/208.82 satz19m:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->((moreis ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.54/208.82 satz19n:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->((lessis ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.54/208.82 satz19o:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->((lessis ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.54/208.82 satz1:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((nis X0) X1)->((nis (ordsucc X0)) (ordsucc X1)))))))
% 208.54/208.82 satz20a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X2))->((d_29_ii X0) X1))))))))
% 208.54/208.82 satz20b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X0) X2)) ((n_pl X1) X2))->((n_is X0) X1))))))))
% 208.54/208.82 satz20c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii ((n_pl X0) X2)) ((n_pl X1) X2))->((iii X0) X1))))))))
% 208.54/208.82 satz20d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii ((n_pl X2) X0)) ((n_pl X2) X1))->((d_29_ii X0) X1))))))))
% 208.54/208.82 satz20e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X2) X0)) ((n_pl X2) X1))->((n_is X0) X1))))))))
% 208.54/208.82 satz20f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii ((n_pl X2) X0)) ((n_pl X2) X1))->((iii X0) X1))))))))
% 208.54/208.82 satz21:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((d_29_ii X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.82 satz21a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((iii X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.82 satz22a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((moreis X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.82 satz22b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((d_29_ii X0) X1)->(((moreis X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.82 satz22c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((lessis X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.82 satz22d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((iii X0) X1)->(((lessis X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.82 satz23:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((moreis X0) X1)->(((moreis X2) X3)->((moreis ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.82 satz23a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((lessis X0) X1)->(((lessis X2) X3)->((lessis ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.54/208.82 satz24:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((moreis X0) n_1)))
% 208.54/208.82 satz24a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (lessis n_1))
% 208.54/208.82 satz24b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((d_29_ii (ordsucc X0)) n_1)))
% 208.54/208.82 satz24c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((iii n_1) (ordsucc X0))))
% 208.54/208.82 satz25:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X1) X0)->((moreis X1) ((n_pl X0) n_1)))))))
% 208.54/208.82 satz25a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X1) X0)->((moreis X1) (ordsucc X0)))))))
% 208.54/208.82 satz25b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) X0)->((lessis ((n_pl X1) n_1)) X0))))))
% 208.54/208.82 satz25c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) X0)->((lessis (ordsucc X1)) X0))))))
% 208.54/208.82 satz26:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) ((n_pl X0) n_1))->((lessis X1) X0))))))
% 208.54/208.82 satz26a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) (ordsucc X0))->((lessis X1) X0))))))
% 208.54/208.82 satz26b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii ((n_pl X1) n_1)) X0)->((moreis X1) X0))))))
% 208.54/208.82 satz26c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii (ordsucc X1)) X0)->((moreis X1) X0))))))
% 208.54/208.82 satz27:(forall (X0:(fofType->Prop)), ((n_some X0)->(n_some (min X0))))
% 208.54/208.82 satz27a:(forall (X0:(fofType->Prop)), ((n_some X0)->(n_one (min X0))))
% 208.54/208.82 satz28:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((one ((d_Pi nat) (fun (X1:fofType)=> nat))) (fun (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) X0)) (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) ((n_pl ((ap X1) X2)) X0)))))))))
% 208.54/208.82 satz28a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_ts X0) n_1)) X0)))
% 208.54/208.82 satz28b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_ts X0) (ordsucc X1))) ((n_pl ((n_ts X0) X1)) X0))))))
% 208.54/208.82 satz28c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_ts n_1) X0)) X0)))
% 208.54/208.82 satz28d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_ts (ordsucc X0)) X1)) ((n_pl ((n_ts X0) X1)) X1))))))
% 208.54/208.82 satz2:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((nis (ordsucc X0)) X0)))
% 208.54/208.82 satz3:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> (((nis X0) n_1)->(n_some (fun (X1:fofType)=> ((n_is X0) (ordsucc X1)))))))
% 208.54/208.82 satz3a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> (((nis X0) n_1)->(n_one (fun (X1:fofType)=> ((n_is X0) (ordsucc X1)))))))
% 208.54/208.82 satz4:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((one ((d_Pi nat) (fun (X1:fofType)=> nat))) (fun (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) (ordsucc X0))) (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) (ordsucc ((ap X1) X2))))))))))
% 208.54/208.82 satz4a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_pl X0) n_1)) (ordsucc X0))))
% 208.54/208.82 satz4b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl X0) (ordsucc X1))) (ordsucc ((n_pl X0) X1)))))))
% 208.54/208.82 satz4c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_pl n_1) X0)) (ordsucc X0))))
% 208.54/208.82 satz4d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl (ordsucc X0)) X1)) (ordsucc ((n_pl X0) X1)))))))
% 208.54/208.82 satz4e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is (ordsucc X0)) ((n_pl X0) n_1))))
% 208.54/208.82 satz4f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is (ordsucc ((n_pl X0) X1))) ((n_pl X0) (ordsucc X1)))))))
% 208.54/208.82 satz4g:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is (ordsucc X0)) ((n_pl n_1) X0))))
% 208.54/208.82 satz4h:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is (ordsucc ((n_pl X0) X1))) ((n_pl (ordsucc X0)) X1))))))
% 208.54/208.82 satz5:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((n_is ((n_pl ((n_pl X0) X1)) X2)) ((n_pl X0) ((n_pl X1) X2)))))))))
% 208.54/208.82 satz6:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl X0) X1)) ((n_pl X1) X0))))))
% 208.54/208.82 satz7:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((nis X1) ((n_pl X0) X1))))))
% 208.54/208.82 satz8:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((nis X1) X2)->((nis ((n_pl X0) X1)) ((n_pl X0) X2)))))))))
% 208.54/208.82 satz8a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X0) X1)) ((n_pl X0) X2))->((n_is X1) X2))))))))
% 208.54/208.82 satz8b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((amone nat) (fun (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))))))))
% 208.54/208.82 satz9:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((orec3 ((n_is X0) X1)) (n_some (fun (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))))) (n_some (fun (X2:fofType)=> ((n_is X1) ((n_pl X0) X2)))))))))
% 208.54/208.82 satz9a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((or3 ((n_is X0) X1)) (n_some ((diffprop X0) X1))) (n_some ((diffprop X1) X0)))))))
% 208.54/208.82 satz9b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((ec3 ((n_is X0) X1)) (n_some ((diffprop X0) X1))) (n_some ((diffprop X1) X0)))))))
% 208.54/208.82 second:=(fun (X0:fofType) (X1:fofType)=> _TPTP_proj1):(fofType->(fofType->(fofType->fofType)))
% 208.54/208.82 second_p:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> ((is_of (((second X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X1))))))
% 208.54/208.82 secondis1:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> (((e_is X1) (((second X0) X1) ((((d_pair X0) X1) X2) X3))) X3))))))
% 208.54/208.82 set_ext:(forall (X0:fofType) (X1:fofType), (((d_Subq X0) X1)->(((d_Subq X1) X0)->(((eq fofType) X0) X1))))
% 208.54/208.82 setminus:=(fun (X0:fofType) (X1:fofType)=> ((d_Sep X0) (fun (X2:fofType)=> ((nIn X2) X1)))):(fofType->(fofType->fofType))
% 208.54/208.82 setof_p:(forall (X0:fofType) (X1:(fofType->Prop)), ((is_of ((d_Sep X0) X1)) (fun (X2:fofType)=> ((in X2) (power X0)))))
% 208.54/208.82 setprod:=(fun (X0:fofType) (X1:fofType)=> ((d_Sigma X0) (fun (X2:fofType)=> X1))):(fofType->(fofType->fofType))
% 208.54/208.82 soft:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((ind X0) (fun (X4:fofType)=> (((e_is X1) X3) ((ap X2) X4))))):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.54/208.82 st_disj:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((l_ec (((esti X0) X3) X1)) (((esti X0) X3) X2))))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.82 subrelation:=(fun (A:Type) (B:Type) (R:(A->(B->Prop))) (R':(A->(B->Prop)))=> (forall (x:A) (y:B), (((R x) y)->((R' x) y)))):(forall (A:Type) (B:Type), ((A->(B->Prop))->((A->(B->Prop))->Prop)))
% 208.54/208.82 suc_p:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((is_of (ordsucc X0)) (fun (X1:fofType)=> ((in X1) nat)))))
% 208.54/208.82 surjective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X1) (((image X0) X1) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.54/208.82 times:=(fun (X0:fofType)=> ((ind ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_428_prop2 X0))):(fofType->fofType)
% 208.54/208.82 tofs:=(fun (X0:fofType) (X1:fofType)=> ap):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.54/208.82 union:(fofType->fofType)
% 208.54/208.82 unique:=(fun (A:Type) (P:(A->Prop)) (x:A)=> ((and (P x)) (forall (x':A), ((P x')->(((eq A) x) x'))))):(forall (A:Type), ((A->Prop)->(A->Prop)))
% 208.54/208.82 unique_choice:=(fun (A:Type) (B:Type) (R:(A->(B->Prop))) (x:(forall (x:A), ((ex B) ((unique B) (fun (y:B)=> ((R x) y))))))=> ((((dependent_unique_choice A) (fun (x2:A)=> B)) R) x)):(forall (A:Type) (B:Type) (R:(A->(B->Prop))), ((forall (x:A), ((ex B) ((unique B) (fun (y:B)=> ((R x) y)))))->((ex (A->B)) (fun (f:(A->B))=> (forall (x:A), ((R x) (f x)))))))
% 208.54/208.82 univof:(fofType->fofType)
% 208.54/208.82 unmore:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sep X0) (fun (X3:fofType)=> ((l_some X1) (fun (X4:fofType)=> (((esti X0) X3) ((ap X2) X4))))))):(fofType->(fofType->(fofType->fofType)))
% 208.63/208.85 wel:=(fun (X0:Prop)=> (d_not (d_not X0))):(Prop->Prop)
% 208.63/208.85 wissel:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X0) (((wissel_wb X0) X1) X2))):(fofType->(fofType->(fofType->fofType)))
% 208.63/208.85 wissel_wa:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((((ite (((e_is X0) X3) X1)) X0) X2) X3)):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.63/208.85 wissel_wb:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((((ite (((e_is X0) X3) X2)) X0) X1) ((((wissel_wa X0) X1) X2) X3))):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.63/208.85 xi_ext:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X0)->(((eq fofType) (X1 X3)) (X2 X3))))->(((eq fofType) ((d_Sigma X0) X1)) ((d_Sigma X0) X2))))]
% 208.63/208.85 ---termsubcontext
% 208.63/208.85 [[[[False:Prop
% 208.63/208.85 False_rect:(forall (P:Type), (False->P))
% 208.63/208.85 I:True
% 208.63/208.85 NNPP:=(fun (P:Prop) (H:(not (not P)))=> ((fun (C:((or P) (not P)))=> ((((((or_ind P) (not P)) P) (fun (H0:P)=> H0)) (fun (N:(not P))=> ((False_rect P) (H N)))) C)) (classic P))):(forall (P:Prop), ((not (not P))->P))
% 208.63/208.85 True:Prop
% 208.63/208.85 _TPTP_proj1:=(fun (X0:fofType)=> (((d_ReplSep X0) (fun (X1:fofType)=> ((ex fofType) (fun (X2:fofType)=> (((eq fofType) (d_Inj1 X2)) X1))))) d_Unj)):(fofType->fofType)
% 208.63/208.85 all:=(fun (X0:fofType)=> (all_of (fun (X1:fofType)=> ((in X1) X0)))):(fofType->((fofType->Prop)->Prop))
% 208.63/208.85 all_of:=(fun (X0:(fofType->Prop)) (X1:(fofType->Prop))=> (forall (X2:fofType), (((is_of X2) X0)->(X1 X2)))):((fofType->Prop)->((fofType->Prop)->Prop))
% 208.63/208.85 amone:=(fun (X0:fofType) (X1:(fofType->Prop))=> ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X0))) (fun (X3:fofType)=> ((X1 X2)->((X1 X3)->(((e_is X0) X2) X3)))))))):(fofType->((fofType->Prop)->Prop))
% 208.63/208.85 and3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((d_and X0) ((d_and X1) X2))):(Prop->(Prop->(Prop->Prop)))
% 208.63/208.85 and:(Prop->(Prop->Prop))
% 208.63/208.85 and_comm_i:=(fun (A:Prop) (B:Prop) (H:((and A) B))=> ((((conj B) A) (((proj2 A) B) H)) (((proj1 A) B) H))):(forall (A:Prop) (B:Prop), (((and A) B)->((and B) A)))
% 208.63/208.85 and_rect:=(fun (A:Prop) (B:Prop) (P:Type) (X:(A->(B->P))) (H:((and A) B))=> ((X (((proj1 A) B) H)) (((proj2 A) B) H))):(forall (A:Prop) (B:Prop) (P:Type), ((A->(B->P))->(((and A) B)->P)))
% 208.63/208.85 anec:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> ((l_some X0) (((ecp X0) X1) X2))):(fofType->((fofType->(fofType->Prop))->(fofType->Prop)))
% 208.63/208.85 ap:=(fun (X0:fofType) (X1:fofType)=> (((d_ReplSep X0) (fun (X2:fofType)=> ((ex fofType) (fun (X3:fofType)=> (((eq fofType) X2) ((pair X1) X3)))))) _TPTP_proj1)):(fofType->(fofType->fofType))
% 208.63/208.85 ap_Pi:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType) (X3:fofType), (((in X2) ((d_Pi X0) X1))->(((in X3) X0)->((in ((ap X2) X3)) (X1 X3)))))
% 208.63/208.85 beta:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) X0)->(((eq fofType) ((ap ((d_Sigma X0) X1)) X2)) (X1 X2))))
% 208.63/208.85 bijective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_and (((injective X0) X1) X2)) (((surjective X0) X1) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.63/208.85 binunion:=(fun (X0:fofType) (X1:fofType)=> (union ((d_UPair X0) X1))):(fofType->(fofType->fofType))
% 208.63/208.85 changef:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_Sigma X0) (fun (X5:fofType)=> ((ap X2) ((ap (((wissel X0) X3) X4)) X5))))):(fofType->(fofType->(fofType->(fofType->(fofType->fofType)))))
% 208.63/208.85 choice:=(fun (A:Type) (B:Type) (R:(A->(B->Prop))) (x:(forall (x:A), ((ex B) (fun (y:B)=> ((R x) y)))))=> (((fun (P:Prop) (x0:(forall (x0:(A->(B->Prop))), (((and ((((subrelation A) B) x0) R)) (forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y))))))->P)))=> (((((ex_ind (A->(B->Prop))) (fun (R':(A->(B->Prop)))=> ((and ((((subrelation A) B) R') R)) (forall (x0:A), ((ex B) ((unique B) (fun (y:B)=> ((R' x0) y)))))))) P) x0) ((((relational_choice A) B) R) x))) ((ex (A->B)) (fun (f:(A->B))=> (forall (x0:A), ((R x0) (f x0)))))) (fun (x0:(A->(B->Prop))) (x1:((and ((((subrelation A) B) x0) R)) (forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y)))))))=> (((fun (P:Type) (x2:(((((subrelation A) B) x0) R)->((forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y)))))->P)))=> (((((and_rect ((((subrelation A) B) x0) R)) (forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y)))))) P) x2) x1)) ((ex (A->B)) (fun (f:(A->B))=> (forall (x0:A), ((R x0) (f x0)))))) (fun (x2:((((subrelation A) B) x0) R)) (x3:(forall (x00:A), ((ex B) ((unique B) (fun (y:B)=> ((x0 x00) y))))))=> (((fun (P:Prop) (x4:(forall (x1:(A->B)), ((forall (x10:A), ((x0 x10) (x1 x10)))->P)))=> (((((ex_ind (A->B)) (fun (f:(A->B))=> (forall (x1:A), ((x0 x1) (f x1))))) P) x4) ((((unique_choice A) B) x0) x3))) ((ex (A->B)) (fun (f:(A->B))=> (forall (x0:A), ((R x0) (f x0)))))) (fun (x4:(A->B)) (x5:(forall (x10:A), ((x0 x10) (x4 x10))))=> ((((ex_intro (A->B)) (fun (f:(A->B))=> (forall (x0:A), ((R x0) (f x0))))) x4) (fun (x00:A)=> (((x2 x00) (x4 x00)) (x5 x00))))))))))):(forall (A:Type) (B:Type) (R:(A->(B->Prop))), ((forall (x:A), ((ex B) (fun (y:B)=> ((R x) y))))->((ex (A->B)) (fun (f:(A->B))=> (forall (x:A), ((R x) (f x)))))))
% 208.63/208.85 choice_operator:=(fun (A:Type) (a:A)=> ((((classical_choice (A->Prop)) A) (fun (x3:(A->Prop))=> x3)) a)):(forall (A:Type), (A->((ex ((A->Prop)->A)) (fun (co:((A->Prop)->A))=> (forall (P:(A->Prop)), (((ex A) (fun (x:A)=> (P x)))->(P (co P))))))))
% 208.63/208.85 classic:(forall (P:Prop), ((or P) (not P)))
% 208.63/208.85 classical_choice:=(fun (A:Type) (B:Type) (R:(A->(B->Prop))) (b:B)=> ((fun (C:((forall (x:A), ((ex B) (fun (y:B)=> (((fun (x0:A) (y0:B)=> (((ex B) (fun (z:B)=> ((R x0) z)))->((R x0) y0))) x) y))))->((ex (A->B)) (fun (f:(A->B))=> (forall (x:A), (((fun (x0:A) (y:B)=> (((ex B) (fun (z:B)=> ((R x0) z)))->((R x0) y))) x) (f x)))))))=> (C (fun (x:A)=> ((fun (C0:((or ((ex B) (fun (z:B)=> ((R x) z)))) (not ((ex B) (fun (z:B)=> ((R x) z))))))=> ((((((or_ind ((ex B) (fun (z:B)=> ((R x) z)))) (not ((ex B) (fun (z:B)=> ((R x) z))))) ((ex B) (fun (y:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y))))) ((((ex_ind B) (fun (z:B)=> ((R x) z))) ((ex B) (fun (y:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y))))) (fun (y:B) (H:((R x) y))=> ((((ex_intro B) (fun (y0:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y0)))) y) (fun (_:((ex B) (fun (z:B)=> ((R x) z))))=> H))))) (fun (N:(not ((ex B) (fun (z:B)=> ((R x) z)))))=> ((((ex_intro B) (fun (y:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y)))) b) (fun (H:((ex B) (fun (z:B)=> ((R x) z))))=> ((False_rect ((R x) b)) (N H)))))) C0)) (classic ((ex B) (fun (z:B)=> ((R x) z)))))))) (((choice A) B) (fun (x:A) (y:B)=> (((ex B) (fun (z:B)=> ((R x) z)))->((R x) y)))))):(forall (A:Type) (B:Type) (R:(A->(B->Prop))), (B->((ex (A->B)) (fun (f:(A->B))=> (forall (x:A), (((ex B) (fun (y:B)=> ((R x) y)))->((R x) (f x))))))))
% 208.63/208.85 cond1:=(n_in n_1):(fofType->Prop)
% 208.63/208.85 cond2:=(fun (X0:fofType)=> (n_all (fun (X1:fofType)=> ((imp ((n_in X1) X0)) ((n_in (ordsucc X1)) X0))))):(fofType->Prop)
% 208.63/208.85 conj:(forall (A:Prop) (B:Prop), (A->(B->((and A) B))))
% 208.63/208.85 d_10_prop1:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType) (X5:fofType) (X6:fofType)=> ((d_and (((esti X0) X6) (((ecect X0) X1) X4))) (((e_is X2) ((ap X3) X6)) X5))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->(fofType->Prop)))))))
% 208.63/208.85 d_11_i:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> (((indeq X0) X1) ((d_Pi X0) (fun (X3:fofType)=> X2)))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->fofType)))))
% 208.63/208.85 d_22_prop1:=(fun (X0:fofType)=> ((nis (ordsucc X0)) X0)):(fofType->Prop)
% 208.63/208.85 d_23_prop1:=(fun (X0:fofType)=> ((l_or ((n_is X0) n_1)) (n_some (fun (X1:fofType)=> ((n_is X0) (ordsucc X1)))))):(fofType->Prop)
% 208.63/208.85 d_24_g:=(fun (X0:fofType)=> ((d_Sigma nat) (fun (X1:fofType)=> (ordsucc ((ap X0) X1))))):(fofType->fofType)
% 208.63/208.85 d_24_prop1:=(fun (X0:fofType)=> (n_all (fun (X1:fofType)=> ((n_is ((ap X0) (ordsucc X1))) (ordsucc ((ap X0) X1)))))):(fofType->Prop)
% 208.63/208.85 d_24_prop2:=(fun (X0:fofType) (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) (ordsucc X0))) (d_24_prop1 X1))):(fofType->(fofType->Prop))
% 208.63/208.85 d_25_prop1:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is ((n_pl ((n_pl X0) X1)) X2)) ((n_pl X0) ((n_pl X1) X2)))):(fofType->(fofType->(fofType->Prop)))
% 208.63/208.85 d_26_prop1:=(fun (X0:fofType) (X1:fofType)=> ((n_is ((n_pl X0) X1)) ((n_pl X1) X0))):(fofType->(fofType->Prop))
% 208.63/208.85 d_27_prop1:=(fun (X0:fofType) (X1:fofType)=> ((nis X1) ((n_pl X0) X1))):(fofType->(fofType->Prop))
% 208.63/208.85 d_28_prop1:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((nis ((n_pl X0) X1)) ((n_pl X0) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.63/208.85 d_29_ii:=(fun (X0:fofType) (X1:fofType)=> (n_some ((diffprop X0) X1))):(fofType->(fofType->Prop))
% 208.63/208.85 d_29_prop1:=(fun (X0:fofType) (X1:fofType)=> (((or3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))):(fofType->(fofType->Prop))
% 208.63/208.85 d_428_g:=(fun (X0:fofType)=> ((d_Sigma nat) (fun (X1:fofType)=> ((n_pl ((ap X0) X1)) X1)))):(fofType->fofType)
% 208.63/208.85 d_428_id:=((d_Sigma nat) (fun (X0:fofType)=> X0)):fofType
% 208.63/208.85 d_428_prop1:=(fun (X0:fofType) (X1:fofType)=> (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) ((n_pl ((ap X1) X2)) X0))))):(fofType->(fofType->Prop))
% 208.63/208.85 d_428_prop2:=(fun (X0:fofType) (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) X0)) ((d_428_prop1 X0) X1))):(fofType->(fofType->Prop))
% 208.63/208.85 d_428_prop4:=(fun (X0:fofType)=> ((l_some ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_428_prop2 X0))):(fofType->Prop)
% 208.63/208.85 d_In_rec:=(fun (X0:(fofType->((fofType->fofType)->fofType))) (X1:fofType)=> (eps ((d_In_rec_G X0) X1))):((fofType->((fofType->fofType)->fofType))->(fofType->fofType))
% 208.63/208.85 d_In_rec_G:=(fun (X0:(fofType->((fofType->fofType)->fofType))) (X1:fofType) (X2:fofType)=> (forall (X3:(fofType->(fofType->Prop))), ((forall (X4:fofType) (X5:(fofType->fofType)), ((forall (X6:fofType), (((in X6) X4)->((X3 X6) (X5 X6))))->((X3 X4) ((X0 X4) X5))))->((X3 X1) X2)))):((fofType->((fofType->fofType)->fofType))->(fofType->(fofType->Prop)))
% 208.63/208.85 d_Inj0:=(fun (X0:fofType)=> ((repl X0) d_Inj1)):(fofType->fofType)
% 208.63/208.85 d_Inj1:=(d_In_rec (fun (X0:fofType) (X1:(fofType->fofType))=> ((binunion (d_Sing emptyset)) ((repl X0) X1)))):(fofType->fofType)
% 208.63/208.85 d_Pi:=(fun (X0:fofType) (X1:(fofType->fofType))=> ((d_Sep (power ((d_Sigma X0) (fun (X2:fofType)=> (union (X1 X2)))))) (fun (X2:fofType)=> (forall (X3:fofType), (((in X3) X0)->((in ((ap X2) X3)) (X1 X3))))))):(fofType->((fofType->fofType)->fofType))
% 208.63/208.85 d_Power_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->((in (power X1)) X0)))):(fofType->Prop)
% 208.63/208.85 d_ReplSep:=(fun (X0:fofType) (X1:(fofType->Prop))=> (repl ((d_Sep X0) X1))):(fofType->((fofType->Prop)->((fofType->fofType)->fofType)))
% 208.63/208.85 d_Repl_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->(forall (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X1)->((in (X2 X3)) X0)))->((in ((repl X1) X2)) X0)))))):(fofType->Prop)
% 208.63/208.85 d_Sep:=(fun (X0:fofType) (X1:(fofType->Prop))=> (((if ((ex fofType) (fun (X2:fofType)=> ((and ((in X2) X0)) (X1 X2))))) ((repl X0) (fun (X2:fofType)=> (((if (X1 X2)) X2) (eps (fun (X3:fofType)=> ((and ((in X3) X0)) (X1 X3)))))))) emptyset)):(fofType->((fofType->Prop)->fofType))
% 208.63/208.85 d_Sigma:=(fun (X0:fofType) (X1:(fofType->fofType))=> ((famunion X0) (fun (X2:fofType)=> ((repl (X1 X2)) (pair X2))))):(fofType->((fofType->fofType)->fofType))
% 208.63/208.85 d_Sing:=(fun (X0:fofType)=> ((d_UPair X0) X0)):(fofType->fofType)
% 208.63/208.85 d_Subq:=(fun (X0:fofType) (X1:fofType)=> (forall (X2:fofType), (((in X2) X0)->((in X2) X1)))):(fofType->(fofType->Prop))
% 208.63/208.85 d_UPair:=(fun (X0:fofType) (X1:fofType)=> ((repl (power (power emptyset))) (fun (X2:fofType)=> (((if ((in emptyset) X2)) X0) X1)))):(fofType->(fofType->fofType))
% 208.63/208.85 d_Union_closed:=(fun (X0:fofType)=> (forall (X1:fofType), (((in X1) X0)->((in (union X1)) X0)))):(fofType->Prop)
% 208.63/208.85 d_Unj:=(d_In_rec (fun (X0:fofType)=> (repl ((setminus X0) (d_Sing emptyset))))):(fofType->fofType)
% 208.63/208.85 d_ZF_closed:=(fun (X0:fofType)=> ((and ((and (d_Union_closed X0)) (d_Power_closed X0))) (d_Repl_closed X0))):(fofType->Prop)
% 208.63/208.85 d_and:=(fun (X0:Prop) (X1:Prop)=> (d_not ((l_ec X0) X1))):(Prop->(Prop->Prop))
% 208.63/208.85 d_not:=(fun (X0:Prop)=> ((imp X0) False)):(Prop->Prop)
% 208.63/208.85 d_pair:=(fun (X0:fofType) (X1:fofType)=> pair):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.63/208.85 dependent_unique_choice:(forall (A:Type) (B:(A->Type)) (R:(forall (x:A), ((B x)->Prop))), ((forall (x:A), ((ex (B x)) ((unique (B x)) (fun (y:(B x))=> ((R x) y)))))->((ex (forall (x:A), (B x))) (fun (f:(forall (x:A), (B x)))=> (forall (x:A), ((R x) (f x)))))))
% 208.63/208.85 diffprop:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.63/208.85 e_fisi:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Pi X0) (fun (X3:fofType)=> X1))))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) ((d_Pi X0) (fun (X4:fofType)=> X1))))) (fun (X3:fofType)=> (((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> (((e_is X1) ((ap X2) X4)) ((ap X3) X4))))->(((e_is ((d_Pi X0) (fun (X4:fofType)=> X1))) X2) X3)))))))
% 208.63/208.85 e_in:=(fun (X0:fofType) (X1:(fofType->Prop)) (X2:fofType)=> X2):(fofType->((fofType->Prop)->(fofType->fofType)))
% 208.63/208.85 e_in_p:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Sep X0) X1)))) (fun (X2:fofType)=> ((is_of (((e_in X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X0))))))
% 208.63/208.85 e_inp:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) ((d_Sep X0) X1)))) (fun (X2:fofType)=> (X1 (((e_in X0) X1) X2)))))
% 208.63/208.85 e_is:=(fun (X0:fofType) (X:fofType) (Y:fofType)=> (((eq fofType) X) Y)):(fofType->(fofType->(fofType->Prop)))
% 208.63/208.85 e_isp:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X0))) (fun (X3:fofType)=> ((X1 X2)->((((e_is X0) X2) X3)->(X1 X3))))))))
% 208.63/208.85 e_pair_p:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> ((is_of ((((d_pair X0) X1) X2) X3)) (fun (X4:fofType)=> ((in X4) ((setprod X0) X1)))))))))
% 208.63/208.85 ec3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> (((and3 ((l_ec X0) X1)) ((l_ec X1) X2)) ((l_ec X2) X0))):(Prop->(Prop->(Prop->Prop)))
% 208.63/208.85 ecect:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((e_in (power X0)) ((anec X0) X1))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 208.63/208.85 ecelt:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> ((d_Sep X0) (X1 X2))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 208.63/208.85 ecp:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> (((e_is (power X0)) X2) (((ecelt X0) X1) X3))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))
% 208.63/208.85 ect:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((d_Sep (power X0)) ((anec X0) X1))):(fofType->((fofType->(fofType->Prop))->fofType))
% 208.63/208.85 ectelt:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType)=> (((ectset X0) X1) (((ecelt X0) X1) X2))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 208.63/208.85 ectset:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop)))=> ((out (power X0)) ((anec X0) X1))):(fofType->((fofType->(fofType->Prop))->(fofType->fofType)))
% 208.63/208.85 empty:=(fun (X0:fofType) (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) X0))) ((non X0) (fun (X2:fofType)=> (((esti X0) X2) X1))))):(fofType->(fofType->Prop))
% 208.63/208.85 emptyset:fofType
% 208.63/208.85 eps:((fofType->Prop)->fofType)
% 208.63/208.85 eq:=(fun (T:Type) (a:T) (b:T)=> (forall (P:(T->Prop)), ((P a)->(P b)))):(forall (T:Type), (T->(T->Prop)))
% 208.63/208.85 eq_ref:=(fun (T:Type) (a:T) (P:(T->Prop)) (x:(P a))=> x):(forall (T:Type) (a:T), (((eq T) a) a))
% 208.63/208.85 eq_stepl:=(fun (T:Type) (a:T) (b:T) (c:T) (X:(((eq T) a) b)) (Y:(((eq T) a) c))=> ((((((eq_trans T) c) a) b) ((((eq_sym T) a) c) Y)) X)):(forall (T:Type) (a:T) (b:T) (c:T), ((((eq T) a) b)->((((eq T) a) c)->(((eq T) c) b))))
% 208.63/208.85 eq_substitution:=(fun (T:Type) (U:Type) (a:T) (b:T) (f:(T->U)) (H:(((eq T) a) b))=> ((H (fun (x:T)=> (((eq U) (f a)) (f x)))) ((eq_ref U) (f a)))):(forall (T:Type) (U:Type) (a:T) (b:T) (f:(T->U)), ((((eq T) a) b)->(((eq U) (f a)) (f b))))
% 208.63/208.85 eq_sym:=(fun (T:Type) (a:T) (b:T) (H:(((eq T) a) b))=> ((H (fun (x:T)=> (((eq T) x) a))) ((eq_ref T) a))):(forall (T:Type) (a:T) (b:T), ((((eq T) a) b)->(((eq T) b) a)))
% 208.63/208.85 eq_trans:=(fun (T:Type) (a:T) (b:T) (c:T) (X:(((eq T) a) b)) (Y:(((eq T) b) c))=> ((Y (fun (t:T)=> (((eq T) a) t))) X)):(forall (T:Type) (a:T) (b:T) (c:T), ((((eq T) a) b)->((((eq T) b) c)->(((eq T) a) c))))
% 208.63/208.85 esti:=(fun (X0:fofType)=> in):(fofType->(fofType->(fofType->Prop)))
% 208.63/208.85 estie:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((((esti X0) X2) ((d_Sep X0) X1))->(X1 X2)))))
% 208.63/208.85 estii:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((X1 X2)->(((esti X0) X2) ((d_Sep X0) X1))))))
% 208.63/208.85 eta_expansion:=(fun (A:Type) (B:Type)=> ((eta_expansion_dep A) (fun (x1:A)=> B))):(forall (A:Type) (B:Type) (f:(A->B)), (((eq (A->B)) f) (fun (x:A)=> (f x))))
% 208.63/208.85 eta_expansion_dep:=(fun (A:Type) (B:(A->Type)) (f:(forall (x:A), (B x)))=> (((((functional_extensionality_dep A) (fun (x1:A)=> (B x1))) f) (fun (x:A)=> (f x))) (fun (x:A) (P:((B x)->Prop)) (x0:(P (f x)))=> x0))):(forall (A:Type) (B:(A->Type)) (f:(forall (x:A), (B x))), (((eq (forall (x:A), (B x))) f) (fun (x:A)=> (f x))))
% 208.63/208.85 ex:(forall (A:Type), ((A->Prop)->Prop))
% 208.63/208.85 ex_ind:(forall (A:Type) (F:(A->Prop)) (P:Prop), ((forall (x:A), ((F x)->P))->(((ex A) F)->P)))
% 208.63/208.85 ex_intro:(forall (A:Type) (P:(A->Prop)) (x:A), ((P x)->((ex A) P)))
% 208.63/208.85 famunion:=(fun (X0:fofType) (X1:(fofType->fofType))=> (union ((repl X0) X1))):(fofType->((fofType->fofType)->fofType))
% 208.63/208.85 first:=(fun (X0:fofType) (X1:fofType)=> proj0):(fofType->(fofType->(fofType->fofType)))
% 208.63/208.85 first_p:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> ((is_of (((first X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X0))))))
% 208.63/208.85 firstis1:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> (((e_is X0) (((first X0) X1) ((((d_pair X0) X1) X2) X3))) X2))))))
% 208.63/208.85 fixfu2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> ((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> ((all_of (fun (X5:fofType)=> ((in X5) X0))) (fun (X5:fofType)=> ((all_of (fun (X6:fofType)=> ((in X6) X0))) (fun (X6:fofType)=> ((all_of (fun (X7:fofType)=> ((in X7) X0))) (fun (X7:fofType)=> (((X1 X4) X5)->(((X1 X6) X7)->(((e_is X2) ((ap ((ap X3) X4)) X6)) ((ap ((ap X3) X5)) X7))))))))))))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))
% 208.63/208.85 fixfu:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType)=> ((all_of (fun (X4:fofType)=> ((in X4) X0))) (fun (X4:fofType)=> ((all_of (fun (X5:fofType)=> ((in X5) X0))) (fun (X5:fofType)=> (((X1 X4) X5)->(((e_is X2) ((ap X3) X4)) ((ap X3) X5)))))))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->Prop))))
% 208.63/208.85 fofType:Type
% 208.63/208.85 functional_extensionality:=(fun (A:Type) (B:Type)=> ((functional_extensionality_dep A) (fun (x1:A)=> B))):(forall (A:Type) (B:Type) (f:(A->B)) (g:(A->B)), ((forall (x:A), (((eq B) (f x)) (g x)))->(((eq (A->B)) f) g)))
% 208.63/208.85 functional_extensionality_dep:(forall (A:Type) (B:(A->Type)) (f:(forall (x:A), (B x))) (g:(forall (x:A), (B x))), ((forall (x:A), (((eq (B x)) (f x)) (g x)))->(((eq (forall (x:A), (B x))) f) g)))
% 208.63/208.85 functional_extensionality_double:=(fun (A:Type) (B:Type) (C:Type) (f:(A->(B->C))) (g:(A->(B->C))) (x:(forall (x:A) (y:B), (((eq C) ((f x) y)) ((g x) y))))=> (((((functional_extensionality_dep A) (fun (x2:A)=> (B->C))) f) g) (fun (x0:A)=> (((((functional_extensionality_dep B) (fun (x3:B)=> C)) (f x0)) (g x0)) (x x0))))):(forall (A:Type) (B:Type) (C:Type) (f:(A->(B->C))) (g:(A->(B->C))), ((forall (x:A) (y:B), (((eq C) ((f x) y)) ((g x) y)))->(((eq (A->(B->C))) f) g)))
% 208.63/208.85 i1_s:=(d_Sep nat):((fofType->Prop)->fofType)
% 208.63/208.85 if:=(fun (X0:Prop) (X1:fofType) (X2:fofType)=> (eps (fun (X3:fofType)=> ((or ((and X0) (((eq fofType) X3) X1))) ((and (X0->False)) (((eq fofType) X3) X2)))))):(Prop->(fofType->(fofType->fofType)))
% 208.63/208.85 if_i_0:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((X0->False)->(((eq fofType) (((if X0) X1) X2)) X2)))
% 208.63/208.85 if_i_1:(forall (X0:Prop) (X1:fofType) (X2:fofType), (X0->(((eq fofType) (((if X0) X1) X2)) X1)))
% 208.63/208.85 if_i_correct:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((or ((and X0) (((eq fofType) (((if X0) X1) X2)) X1))) ((and (X0->False)) (((eq fofType) (((if X0) X1) X2)) X2))))
% 208.63/208.85 if_i_or:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((or (((eq fofType) (((if X0) X1) X2)) X1)) (((eq fofType) (((if X0) X1) X2)) X2)))
% 208.63/208.85 iff:=(fun (A:Prop) (B:Prop)=> ((and (A->B)) (B->A))):(Prop->(Prop->Prop))
% 208.63/208.85 iff_refl:=(fun (A:Prop)=> ((((conj (A->A)) (A->A)) (fun (H:A)=> H)) (fun (H:A)=> H))):(forall (P:Prop), ((iff P) P))
% 208.63/208.85 iff_sym:=(fun (A:Prop) (B:Prop) (H:((iff A) B))=> ((((conj (B->A)) (A->B)) (((proj2 (A->B)) (B->A)) H)) (((proj1 (A->B)) (B->A)) H))):(forall (A:Prop) (B:Prop), (((iff A) B)->((iff B) A)))
% 208.63/208.85 iff_trans:=(fun (A:Prop) (B:Prop) (C:Prop) (AB:((iff A) B)) (BC:((iff B) C))=> ((((conj (A->C)) (C->A)) (fun (x:A)=> ((((proj1 (B->C)) (C->B)) BC) ((((proj1 (A->B)) (B->A)) AB) x)))) (fun (x:C)=> ((((proj2 (A->B)) (B->A)) AB) ((((proj2 (B->C)) (C->B)) BC) x))))):(forall (A:Prop) (B:Prop) (C:Prop), (((iff A) B)->(((iff B) C)->((iff A) C))))
% 208.63/208.85 iii:=(fun (X0:fofType) (X1:fofType)=> (n_some ((diffprop X1) X0))):(fofType->(fofType->Prop))
% 208.63/208.85 image:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((l_some X0) (fun (X4:fofType)=> (((e_is X1) X3) ((ap X2) X4))))):(fofType->(fofType->(fofType->(fofType->Prop))))
% 208.63/208.85 imp:=(fun (X0:Prop) (X1:Prop)=> (X0->X1)):(Prop->(Prop->Prop))
% 208.63/208.85 in:(fofType->(fofType->Prop))
% 208.63/208.85 incl:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((imp (((esti X0) X3) X1)) (((esti X0) X3) X2))))):(fofType->(fofType->(fofType->Prop)))
% 208.63/208.85 ind:=(fun (X0:fofType) (X1:(fofType->Prop))=> (eps (fun (X2:fofType)=> ((and ((in X2) X0)) (X1 X2))))):(fofType->((fofType->Prop)->fofType))
% 208.63/208.85 ind_p:(forall (X0:fofType) (X1:(fofType->Prop)), (((one X0) X1)->((is_of ((ind X0) X1)) (fun (X2:fofType)=> ((in X2) X0)))))
% 208.63/208.85 indeq2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType)=> ((((indeq X0) X1) X2) (((((d_11_i X0) X1) X2) X3) X4))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->fofType))))))
% 208.63/208.85 indeq:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType)=> ((ind X2) (((((prop2 X0) X1) X2) X3) X4))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->fofType)))))
% 208.63/208.85 inj_h:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_Sigma X0) (fun (X5:fofType)=> ((ap X4) ((ap X3) X5))))):(fofType->(fofType->(fofType->(fofType->(fofType->fofType)))))
% 208.63/208.85 injective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((all X0) (fun (X4:fofType)=> ((imp (((e_is X1) ((ap X2) X3)) ((ap X2) X4))) (((e_is X0) X3) X4))))))):(fofType->(fofType->(fofType->Prop)))
% 208.63/208.85 inverse:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X1) (fun (X3:fofType)=> (((if ((((image X0) X1) X2) X3)) ((((soft X0) X1) X2) X3)) emptyset)))):(fofType->(fofType->(fofType->fofType)))
% 208.63/208.85 invf:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X1) (((soft X0) X1) X2))):(fofType->(fofType->(fofType->fofType)))
% 208.63/208.85 is_of:=(fun (X0:fofType) (X1:(fofType->Prop))=> (X1 X0)):(fofType->((fofType->Prop)->Prop))
% 208.63/208.85 isseti:(forall (X0:fofType), ((all_of (fun (X1:fofType)=> ((in X1) (power X0)))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) (power X0)))) (fun (X2:fofType)=> ((((incl X0) X1) X2)->((((incl X0) X2) X1)->(((e_is (power X0)) X1) X2))))))))
% 208.63/208.85 ite:=(fun (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType)=> ((ind X1) ((((prop1 X0) X1) X2) X3))):(Prop->(fofType->(fofType->(fofType->fofType))))
% 208.63/208.85 k_EmptyAx:(((ex fofType) (fun (X0:fofType)=> ((in X0) emptyset)))->False)
% 208.63/208.85 k_If_In_01:(forall (X0:Prop) (X1:fofType) (X2:fofType), ((X0->((in X1) X2))->((in (((if X0) X1) emptyset)) (((if X0) X2) (ordsucc emptyset)))))
% 208.63/208.85 k_If_In_then_E:(forall (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType), (X0->(((in X1) (((if X0) X2) X3))->((in X1) X2))))
% 208.63/208.85 k_In_0_1:((in emptyset) (ordsucc emptyset))
% 208.63/208.85 k_In_ind:(forall (X0:(fofType->Prop)), ((forall (X1:fofType), ((forall (X2:fofType), (((in X2) X1)->(X0 X2)))->(X0 X1)))->(forall (X1:fofType), (X0 X1))))
% 208.63/208.85 k_Pi_ext:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Pi X0) X1))->(forall (X3:fofType), (((in X3) ((d_Pi X0) X1))->((forall (X4:fofType), (((in X4) X0)->(((eq fofType) ((ap X2) X4)) ((ap X3) X4))))->(((eq fofType) X2) X3))))))
% 208.63/208.85 k_PowerE:(forall (X0:fofType) (X1:fofType), (((in X1) (power X0))->((d_Subq X1) X0)))
% 208.63/208.85 k_PowerEq:(forall (X0:fofType) (X1:fofType), ((iff ((in X1) (power X0))) ((d_Subq X1) X0)))
% 208.63/208.85 k_PowerI:(forall (X0:fofType) (X1:fofType), (((d_Subq X1) X0)->((in X1) (power X0))))
% 208.63/208.85 k_ReplEq:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), ((iff ((in X2) ((repl X0) X1))) ((ex fofType) (fun (X3:fofType)=> ((and ((in X3) X0)) (((eq fofType) X2) (X1 X3)))))))
% 208.63/208.85 k_Self_In_Power:(forall (X0:fofType), ((in X0) (power X0)))
% 208.63/208.85 k_SepE1:(forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) ((d_Sep X0) X1))->((in X2) X0)))
% 208.63/208.85 k_SepE2:(forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) ((d_Sep X0) X1))->(X1 X2)))
% 208.63/208.85 k_SepI:(forall (X0:fofType) (X1:(fofType->Prop)) (X2:fofType), (((in X2) X0)->((X1 X2)->((in X2) ((d_Sep X0) X1)))))
% 208.63/208.85 k_Sigma_eta_proj0_proj1:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((and ((and (((eq fofType) ((pair (proj0 X2)) (_TPTP_proj1 X2))) X2)) ((in (proj0 X2)) X0))) ((in (_TPTP_proj1 X2)) (X1 (proj0 X2))))))
% 208.63/208.85 k_UnionEq:(forall (X0:fofType) (X1:fofType), ((iff ((in X1) (union X0))) ((ex fofType) (fun (X2:fofType)=> ((and ((in X1) X2)) ((in X2) X0))))))
% 208.63/208.85 k_UnivOf_In:(forall (X0:fofType), ((in X0) (univof X0)))
% 208.63/208.85 k_UnivOf_ZF_closed:(forall (X0:fofType), (d_ZF_closed (univof X0)))
% 208.63/208.85 l_ec:=(fun (X0:Prop) (X1:Prop)=> ((imp X0) (d_not X1))):(Prop->(Prop->Prop))
% 208.63/208.85 l_et:(forall (X0:Prop), ((wel X0)->X0))
% 208.63/208.85 l_iff:=(fun (X0:Prop) (X1:Prop)=> ((d_and ((imp X0) X1)) ((imp X1) X0))):(Prop->(Prop->Prop))
% 208.63/208.85 l_or:=(fun (X0:Prop)=> (imp (d_not X0))):(Prop->(Prop->Prop))
% 208.63/208.85 l_some:=(fun (X0:fofType) (X1:(fofType->Prop))=> (d_not ((all_of (fun (X2:fofType)=> ((in X2) X0))) ((non X0) X1)))):(fofType->((fofType->Prop)->Prop))
% 208.63/208.85 lam_Pi:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X0)->((in (X2 X3)) (X1 X3))))->((in ((d_Sigma X0) X2)) ((d_Pi X0) X1))))
% 208.63/208.85 lbprop:=(fun (X0:(fofType->Prop)) (X1:fofType) (X2:fofType)=> ((imp (X0 X2)) ((lessis X1) X2))):((fofType->Prop)->(fofType->(fofType->Prop)))
% 208.63/208.85 lessis:=(fun (X0:fofType) (X1:fofType)=> ((l_or ((iii X0) X1)) ((n_is X0) X1))):(fofType->(fofType->Prop))
% 208.63/208.85 min:=(fun (X0:(fofType->Prop)) (X1:fofType)=> ((d_and ((n_lb X0) X1)) (X0 X1))):((fofType->Prop)->(fofType->Prop))
% 208.63/208.85 moreis:=(fun (X0:fofType) (X1:fofType)=> ((l_or ((d_29_ii X0) X1)) ((n_is X0) X1))):(fofType->(fofType->Prop))
% 208.63/208.85 nIn:=(fun (X0:fofType) (X1:fofType)=> (((in X0) X1)->False)):(fofType->(fofType->Prop))
% 208.63/208.85 n_1:=(ordsucc emptyset):fofType
% 208.63/208.85 n_1_p:((is_of n_1) (fun (X0:fofType)=> ((in X0) nat)))
% 208.63/208.85 n_all:=(all nat):((fofType->Prop)->Prop)
% 208.63/208.85 n_ax3:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((nis (ordsucc X0)) n_1)))
% 208.63/208.85 n_ax4:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((n_is (ordsucc X0)) (ordsucc X1))->((n_is X0) X1))))))
% 208.63/208.85 n_ax5:((all_of (fun (X0:fofType)=> ((in X0) (power nat)))) (fun (X0:fofType)=> ((cond1 X0)->((cond2 X0)->((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_in X1) X0)))))))
% 208.63/208.85 n_in:=(esti nat):(fofType->(fofType->Prop))
% 208.63/208.85 n_is:=(e_is nat):(fofType->(fofType->Prop))
% 208.63/208.85 n_lb:=(fun (X0:(fofType->Prop)) (X1:fofType)=> (n_all ((lbprop X0) X1))):((fofType->Prop)->(fofType->Prop))
% 208.63/208.85 n_one:=(one nat):((fofType->Prop)->Prop)
% 208.63/208.85 n_pl:=(fun (X0:fofType)=> (ap (plus X0))):(fofType->(fofType->fofType))
% 208.63/208.85 n_some:=(l_some nat):((fofType->Prop)->Prop)
% 208.63/208.85 n_ts:=(fun (X0:fofType)=> (ap (times X0))):(fofType->(fofType->fofType))
% 208.63/208.85 nat:=((d_Sep omega) (fun (X0:fofType)=> (not (((eq fofType) X0) emptyset)))):fofType
% 208.63/208.85 nat_1:(nat_p (ordsucc emptyset))
% 208.63/208.85 nat_ind:(forall (X0:(fofType->Prop)), ((X0 emptyset)->((forall (X1:fofType), ((nat_p X1)->((X0 X1)->(X0 (ordsucc X1)))))->(forall (X1:fofType), ((nat_p X1)->(X0 X1))))))
% 208.63/208.85 nat_inv:(forall (X0:fofType), ((nat_p X0)->((or (((eq fofType) X0) emptyset)) ((ex fofType) (fun (X1:fofType)=> ((and (nat_p X1)) (((eq fofType) X0) (ordsucc X1))))))))
% 208.63/208.85 nat_ordsucc:(forall (X0:fofType), ((nat_p X0)->(nat_p (ordsucc X0))))
% 208.63/208.85 nat_p:=(fun (X0:fofType)=> (forall (X1:(fofType->Prop)), ((X1 emptyset)->((forall (X2:fofType), ((X1 X2)->(X1 (ordsucc X2))))->(X1 X0))))):(fofType->Prop)
% 208.63/208.85 nat_p_omega:(forall (X0:fofType), ((nat_p X0)->((in X0) omega)))
% 208.63/208.85 neq_ordsucc_0:(forall (X0:fofType), (not (((eq fofType) (ordsucc X0)) emptyset)))
% 208.63/208.85 nis:=(fun (X0:fofType) (X1:fofType)=> (d_not ((n_is X0) X1))):(fofType->(fofType->Prop))
% 208.63/208.85 nissetprop:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((d_and (((esti X0) X3) X1)) (d_not (((esti X0) X3) X2)))):(fofType->(fofType->(fofType->(fofType->Prop))))
% 208.63/208.85 non:=(fun (X0:fofType) (X1:(fofType->Prop)) (X2:fofType)=> (d_not (X1 X2))):(fofType->((fofType->Prop)->(fofType->Prop)))
% 208.63/208.85 nonempty:=(fun (X0:fofType) (X1:fofType)=> ((l_some X0) (fun (X2:fofType)=> (((esti X0) X2) X1)))):(fofType->(fofType->Prop))
% 208.63/208.85 not:=(fun (P:Prop)=> (P->False)):(Prop->Prop)
% 208.63/208.85 obvious:=((imp False) False):Prop
% 208.63/208.85 omega:=((d_Sep (univof emptyset)) nat_p):fofType
% 208.63/208.85 omega_nat_p:(forall (X0:fofType), (((in X0) omega)->(nat_p X0)))
% 208.63/208.85 one:=(fun (X0:fofType) (X1:(fofType->Prop))=> ((d_and ((amone X0) X1)) ((l_some X0) X1))):(fofType->((fofType->Prop)->Prop))
% 208.63/208.85 oneax:(forall (X0:fofType) (X1:(fofType->Prop)), (((one X0) X1)->(X1 ((ind X0) X1))))
% 208.63/208.85 or3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((l_or X0) ((l_or X1) X2))):(Prop->(Prop->(Prop->Prop)))
% 208.63/208.85 or:(Prop->(Prop->Prop))
% 208.63/208.85 or_comm_i:=(fun (A:Prop) (B:Prop) (H:((or A) B))=> ((((((or_ind A) B) ((or B) A)) ((or_intror B) A)) ((or_introl B) A)) H)):(forall (A:Prop) (B:Prop), (((or A) B)->((or B) A)))
% 208.63/208.85 or_first:=(fun (A:Prop) (B:Prop)=> (((((or_ind A) B) ((B->A)->A)) (fun (x:A) (x0:(B->A))=> x)) (fun (x:B) (x0:(B->A))=> (x0 x)))):(forall (A:Prop) (B:Prop), (((or A) B)->((B->A)->A)))
% 208.63/208.85 or_ind:(forall (A:Prop) (B:Prop) (P:Prop), ((A->P)->((B->P)->(((or A) B)->P))))
% 208.63/208.85 or_introl:(forall (A:Prop) (B:Prop), (A->((or A) B)))
% 208.63/208.85 or_intror:(forall (A:Prop) (B:Prop), (B->((or A) B)))
% 208.63/208.85 or_second:=(fun (A:Prop) (B:Prop) (x:((or A) B))=> (((or_first B) A) (((or_comm_i A) B) x))):(forall (A:Prop) (B:Prop), (((or A) B)->((A->B)->B)))
% 208.63/208.85 ordsucc:=(fun (X0:fofType)=> ((binunion X0) (d_Sing X0))):(fofType->fofType)
% 208.63/208.85 ordsucc_inj:(forall (X0:fofType) (X1:fofType), ((((eq fofType) (ordsucc X0)) (ordsucc X1))->(((eq fofType) X0) X1)))
% 208.63/208.85 orec3:=(fun (X0:Prop) (X1:Prop) (X2:Prop)=> ((d_and (((or3 X0) X1) X2)) (((ec3 X0) X1) X2))):(Prop->(Prop->(Prop->Prop)))
% 208.63/208.85 orec:=(fun (X0:Prop) (X1:Prop)=> ((d_and ((l_or X0) X1)) ((l_ec X0) X1))):(Prop->(Prop->Prop))
% 208.63/208.85 otax1:(forall (X0:fofType) (X1:(fofType->Prop)), (((injective ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1))))
% 208.63/208.85 otax2:(forall (X0:fofType) (X1:(fofType->Prop)), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((X1 X2)->((((image ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1))) X2)))))
% 208.63/208.85 out:=(fun (X0:fofType) (X1:(fofType->Prop))=> (((soft ((d_Sep X0) X1)) X0) ((d_Sigma ((d_Sep X0) X1)) ((e_in X0) X1)))):(fofType->((fofType->Prop)->(fofType->fofType)))
% 208.63/208.85 pair:=(fun (X0:fofType) (X1:fofType)=> ((binunion ((repl X0) d_Inj0)) ((repl X1) d_Inj1))):(fofType->(fofType->fofType))
% 208.63/208.85 pair_Sigma:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) X0)->(forall (X3:fofType), (((in X3) (X1 X2))->((in ((pair X2) X3)) ((d_Sigma X0) X1))))))
% 208.63/208.85 pair_p:=(fun (X0:fofType)=> (((eq fofType) ((pair ((ap X0) emptyset)) ((ap X0) (ordsucc emptyset)))) X0)):(fofType->Prop)
% 208.63/208.85 pairis1:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> (((e_is ((setprod X0) X1)) ((((d_pair X0) X1) (((first X0) X1) X2)) (((second X0) X1) X2))) X2))))
% 208.63/208.85 plus:=(fun (X0:fofType)=> ((ind ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_24_prop2 X0))):(fofType->fofType)
% 208.63/208.85 power:(fofType->fofType)
% 208.63/208.85 proj0:=(fun (X0:fofType)=> (((d_ReplSep X0) (fun (X1:fofType)=> ((ex fofType) (fun (X2:fofType)=> (((eq fofType) (d_Inj0 X2)) X1))))) d_Unj)):(fofType->fofType)
% 208.63/208.85 proj0_Sigma:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((in (proj0 X2)) X0)))
% 208.63/208.85 proj0_pair_eq:(forall (X0:fofType) (X1:fofType), (((eq fofType) (proj0 ((pair X0) X1))) X0))
% 208.63/208.85 proj1:(forall (A:Prop) (B:Prop), (((and A) B)->A))
% 208.63/208.85 proj1_Sigma:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->((in (_TPTP_proj1 X2)) (X1 (proj0 X2)))))
% 208.63/208.85 proj1_pair_eq:(forall (X0:fofType) (X1:fofType), (((eq fofType) (_TPTP_proj1 ((pair X0) X1))) X1))
% 208.63/208.85 proj2:(forall (A:Prop) (B:Prop), (((and A) B)->B))
% 208.63/208.85 proj_Sigma_eta:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:fofType), (((in X2) ((d_Sigma X0) X1))->(((eq fofType) ((pair (proj0 X2)) (_TPTP_proj1 X2))) X2)))
% 208.63/208.85 prop1:=(fun (X0:Prop) (X1:fofType) (X2:fofType) (X3:fofType) (X4:fofType)=> ((d_and ((imp X0) (((e_is X1) X4) X2))) ((imp (d_not X0)) (((e_is X1) X4) X3)))):(Prop->(fofType->(fofType->(fofType->(fofType->Prop)))))
% 208.63/208.85 prop2:=(fun (X0:fofType) (X1:(fofType->(fofType->Prop))) (X2:fofType) (X3:fofType) (X4:fofType) (X5:fofType)=> ((l_some X0) ((((((d_10_prop1 X0) X1) X2) X3) X4) X5))):(fofType->((fofType->(fofType->Prop))->(fofType->(fofType->(fofType->(fofType->Prop))))))
% 208.63/208.85 prop3:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((n_is ((ap X0) X2)) ((ap X1) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.63/208.85 prop4:=(fun (X0:fofType)=> ((l_some ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_24_prop2 X0))):(fofType->Prop)
% 208.63/208.85 r_ec:=(fun (X0:Prop) (X1:Prop)=> (X0->(d_not X1))):(Prop->(Prop->Prop))
% 208.63/208.85 refis:(forall (X0:fofType), ((all_of (fun (X1:fofType)=> ((in X1) X0))) (fun (X1:fofType)=> (((e_is X0) X1) X1))))
% 208.63/208.85 relational_choice:(forall (A:Type) (B:Type) (R:(A->(B->Prop))), ((forall (x:A), ((ex B) (fun (y:B)=> ((R x) y))))->((ex (A->(B->Prop))) (fun (R':(A->(B->Prop)))=> ((and ((((subrelation A) B) R') R)) (forall (x:A), ((ex B) ((unique B) (fun (y:B)=> ((R' x) y))))))))))
% 208.63/208.85 repl:(fofType->((fofType->fofType)->fofType))
% 208.63/208.85 satz10:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((orec3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))))))
% 208.63/208.85 satz10a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((or3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))))))
% 208.63/208.85 satz10b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((ec3 ((n_is X0) X1)) ((d_29_ii X0) X1)) ((iii X0) X1))))))
% 208.63/208.85 satz10c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((moreis X0) X1)->(d_not ((iii X0) X1)))))))
% 208.63/208.85 satz10d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((lessis X0) X1)->(d_not ((d_29_ii X0) X1)))))))
% 208.63/208.85 satz10e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((d_29_ii X0) X1))->((lessis X0) X1))))))
% 208.63/208.85 satz10f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((iii X0) X1))->((moreis X0) X1))))))
% 208.63/208.85 satz10g:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X0) X1)->(d_not ((lessis X0) X1)))))))
% 208.63/208.85 satz10h:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X0) X1)->(d_not ((moreis X0) X1)))))))
% 208.63/208.85 satz10j:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((moreis X0) X1))->((iii X0) X1))))))
% 208.63/208.85 satz10k:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_not ((lessis X0) X1))->((d_29_ii X0) X1))))))
% 208.63/208.85 satz11:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X0) X1)->((iii X1) X0))))))
% 208.63/208.85 satz12:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X0) X1)->((d_29_ii X1) X0))))))
% 208.63/208.85 satz13:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((moreis X0) X1)->((lessis X1) X0))))))
% 208.63/208.85 satz14:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((lessis X0) X1)->((moreis X1) X0))))))
% 208.63/208.85 satz15:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->(((iii X1) X2)->((iii X0) X2)))))))))
% 208.63/208.85 satz16a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->(((iii X1) X2)->((iii X0) X2)))))))))
% 208.63/208.85 satz16b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->(((lessis X1) X2)->((iii X0) X2)))))))))
% 208.63/208.85 satz16c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->(((d_29_ii X1) X2)->((d_29_ii X0) X2)))))))))
% 208.63/208.85 satz16d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->(((moreis X1) X2)->((d_29_ii X0) X2)))))))))
% 208.63/208.85 satz17:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->(((lessis X1) X2)->((lessis X0) X2)))))))))
% 208.63/208.85 satz18:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((d_29_ii ((n_pl X0) X1)) X0)))))
% 208.63/208.85 satz18a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((iii X0) ((n_pl X0) X1))))))
% 208.63/208.85 satz18b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((d_29_ii (ordsucc X0)) X0)))
% 208.63/208.85 satz18c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((iii X0) (ordsucc X0))))
% 208.63/208.85 satz19a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.63/208.85 satz19b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is X0) X1)->((n_is ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.63/208.85 satz19c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->((iii ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.63/208.85 satz19d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii X0) X1)->((d_29_ii ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.63/208.85 satz19e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is X0) X1)->((n_is ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.63/208.85 satz19f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii X0) X1)->((iii ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.63/208.85 satz19g:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.63/208.85 satz19h:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X2) X0)) ((n_pl X3) X1))))))))))))
% 208.63/208.85 satz19j:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.63/208.85 satz19k:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((n_is X0) X1)->(((iii X2) X3)->((iii ((n_pl X2) X0)) ((n_pl X3) X1))))))))))))
% 208.63/208.85 satz19l:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->((moreis ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.63/208.85 satz19m:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((moreis X0) X1)->((moreis ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.63/208.85 satz19n:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->((lessis ((n_pl X0) X2)) ((n_pl X1) X2)))))))))
% 208.63/208.85 satz19o:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((lessis X0) X1)->((lessis ((n_pl X2) X0)) ((n_pl X2) X1)))))))))
% 208.63/208.85 satz1:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((nis X0) X1)->((nis (ordsucc X0)) (ordsucc X1)))))))
% 208.63/208.85 satz20a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X2))->((d_29_ii X0) X1))))))))
% 208.63/208.85 satz20b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X0) X2)) ((n_pl X1) X2))->((n_is X0) X1))))))))
% 208.63/208.85 satz20c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii ((n_pl X0) X2)) ((n_pl X1) X2))->((iii X0) X1))))))))
% 208.63/208.85 satz20d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((d_29_ii ((n_pl X2) X0)) ((n_pl X2) X1))->((d_29_ii X0) X1))))))))
% 208.63/208.85 satz20e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X2) X0)) ((n_pl X2) X1))->((n_is X0) X1))))))))
% 208.63/208.85 satz20f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((iii ((n_pl X2) X0)) ((n_pl X2) X1))->((iii X0) X1))))))))
% 208.63/208.85 satz21:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((d_29_ii X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.63/208.85 satz21a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((iii X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.63/208.85 satz22a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((moreis X0) X1)->(((d_29_ii X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.63/208.85 satz22b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((d_29_ii X0) X1)->(((moreis X2) X3)->((d_29_ii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.63/208.85 satz22c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((lessis X0) X1)->(((iii X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.63/208.85 satz22d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((iii X0) X1)->(((lessis X2) X3)->((iii ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.63/208.85 satz23:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((moreis X0) X1)->(((moreis X2) X3)->((moreis ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.63/208.85 satz23a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) nat))) (fun (X3:fofType)=> (((lessis X0) X1)->(((lessis X2) X3)->((lessis ((n_pl X0) X2)) ((n_pl X1) X3))))))))))))
% 208.63/208.85 satz24:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((moreis X0) n_1)))
% 208.63/208.85 satz24a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (lessis n_1))
% 208.63/208.85 satz24b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((d_29_ii (ordsucc X0)) n_1)))
% 208.63/208.85 satz24c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((iii n_1) (ordsucc X0))))
% 208.63/208.85 satz25:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X1) X0)->((moreis X1) ((n_pl X0) n_1)))))))
% 208.63/208.85 satz25a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii X1) X0)->((moreis X1) (ordsucc X0)))))))
% 208.63/208.85 satz25b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) X0)->((lessis ((n_pl X1) n_1)) X0))))))
% 208.63/208.85 satz25c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) X0)->((lessis (ordsucc X1)) X0))))))
% 208.63/208.85 satz26:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) ((n_pl X0) n_1))->((lessis X1) X0))))))
% 208.63/208.85 satz26a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((iii X1) (ordsucc X0))->((lessis X1) X0))))))
% 208.63/208.85 satz26b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii ((n_pl X1) n_1)) X0)->((moreis X1) X0))))))
% 208.63/208.85 satz26c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((d_29_ii (ordsucc X1)) X0)->((moreis X1) X0))))))
% 208.63/208.85 satz27:(forall (X0:(fofType->Prop)), ((n_some X0)->(n_some (min X0))))
% 208.63/208.85 satz27a:(forall (X0:(fofType->Prop)), ((n_some X0)->(n_one (min X0))))
% 208.63/208.85 satz28:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((one ((d_Pi nat) (fun (X1:fofType)=> nat))) (fun (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) X0)) (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) ((n_pl ((ap X1) X2)) X0)))))))))
% 208.63/208.85 satz28a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_ts X0) n_1)) X0)))
% 208.63/208.85 satz28b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_ts X0) (ordsucc X1))) ((n_pl ((n_ts X0) X1)) X0))))))
% 208.63/208.85 satz28c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_ts n_1) X0)) X0)))
% 208.63/208.85 satz28d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_ts (ordsucc X0)) X1)) ((n_pl ((n_ts X0) X1)) X1))))))
% 208.63/208.85 satz2:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((nis (ordsucc X0)) X0)))
% 208.63/208.85 satz3:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> (((nis X0) n_1)->(n_some (fun (X1:fofType)=> ((n_is X0) (ordsucc X1)))))))
% 208.63/208.85 satz3a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> (((nis X0) n_1)->(n_one (fun (X1:fofType)=> ((n_is X0) (ordsucc X1)))))))
% 208.63/208.85 satz4:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((one ((d_Pi nat) (fun (X1:fofType)=> nat))) (fun (X1:fofType)=> ((d_and ((n_is ((ap X1) n_1)) (ordsucc X0))) (n_all (fun (X2:fofType)=> ((n_is ((ap X1) (ordsucc X2))) (ordsucc ((ap X1) X2))))))))))
% 208.63/208.85 satz4a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_pl X0) n_1)) (ordsucc X0))))
% 208.63/208.85 satz4b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl X0) (ordsucc X1))) (ordsucc ((n_pl X0) X1)))))))
% 208.63/208.85 satz4c:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is ((n_pl n_1) X0)) (ordsucc X0))))
% 208.63/208.85 satz4d:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl (ordsucc X0)) X1)) (ordsucc ((n_pl X0) X1)))))))
% 208.63/208.85 satz4e:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is (ordsucc X0)) ((n_pl X0) n_1))))
% 208.63/208.85 satz4f:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is (ordsucc ((n_pl X0) X1))) ((n_pl X0) (ordsucc X1)))))))
% 208.63/208.85 satz4g:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is (ordsucc X0)) ((n_pl n_1) X0))))
% 208.63/208.85 satz4h:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is (ordsucc ((n_pl X0) X1))) ((n_pl (ordsucc X0)) X1))))))
% 208.63/208.85 satz5:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> ((n_is ((n_pl ((n_pl X0) X1)) X2)) ((n_pl X0) ((n_pl X1) X2)))))))))
% 208.63/208.85 satz6:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((n_is ((n_pl X0) X1)) ((n_pl X1) X0))))))
% 208.63/208.85 satz7:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((nis X1) ((n_pl X0) X1))))))
% 208.63/208.85 satz8:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((nis X1) X2)->((nis ((n_pl X0) X1)) ((n_pl X0) X2)))))))))
% 208.63/208.85 satz8a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((all_of (fun (X2:fofType)=> ((in X2) nat))) (fun (X2:fofType)=> (((n_is ((n_pl X0) X1)) ((n_pl X0) X2))->((n_is X1) X2))))))))
% 208.63/208.85 satz8b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> ((amone nat) (fun (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))))))))
% 208.63/208.85 satz9:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((orec3 ((n_is X0) X1)) (n_some (fun (X2:fofType)=> ((n_is X0) ((n_pl X1) X2))))) (n_some (fun (X2:fofType)=> ((n_is X1) ((n_pl X0) X2)))))))))
% 208.63/208.85 satz9a:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((or3 ((n_is X0) X1)) (n_some ((diffprop X0) X1))) (n_some ((diffprop X1) X0)))))))
% 208.63/208.85 satz9b:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((all_of (fun (X1:fofType)=> ((in X1) nat))) (fun (X1:fofType)=> (((ec3 ((n_is X0) X1)) (n_some ((diffprop X0) X1))) (n_some ((diffprop X1) X0)))))))
% 208.63/208.85 second:=(fun (X0:fofType) (X1:fofType)=> _TPTP_proj1):(fofType->(fofType->(fofType->fofType)))
% 208.63/208.85 second_p:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) ((setprod X0) X1)))) (fun (X2:fofType)=> ((is_of (((second X0) X1) X2)) (fun (X3:fofType)=> ((in X3) X1))))))
% 208.63/208.85 secondis1:(forall (X0:fofType) (X1:fofType), ((all_of (fun (X2:fofType)=> ((in X2) X0))) (fun (X2:fofType)=> ((all_of (fun (X3:fofType)=> ((in X3) X1))) (fun (X3:fofType)=> (((e_is X1) (((second X0) X1) ((((d_pair X0) X1) X2) X3))) X3))))))
% 208.63/208.85 set_ext:(forall (X0:fofType) (X1:fofType), (((d_Subq X0) X1)->(((d_Subq X1) X0)->(((eq fofType) X0) X1))))
% 208.63/208.85 setminus:=(fun (X0:fofType) (X1:fofType)=> ((d_Sep X0) (fun (X2:fofType)=> ((nIn X2) X1)))):(fofType->(fofType->fofType))
% 208.63/208.85 setof_p:(forall (X0:fofType) (X1:(fofType->Prop)), ((is_of ((d_Sep X0) X1)) (fun (X2:fofType)=> ((in X2) (power X0)))))
% 208.63/208.85 setprod:=(fun (X0:fofType) (X1:fofType)=> ((d_Sigma X0) (fun (X2:fofType)=> X1))):(fofType->(fofType->fofType))
% 208.63/208.85 soft:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((ind X0) (fun (X4:fofType)=> (((e_is X1) X3) ((ap X2) X4))))):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.63/208.85 st_disj:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X0) (fun (X3:fofType)=> ((l_ec (((esti X0) X3) X1)) (((esti X0) X3) X2))))):(fofType->(fofType->(fofType->Prop)))
% 208.63/208.85 subrelation:=(fun (A:Type) (B:Type) (R:(A->(B->Prop))) (R':(A->(B->Prop)))=> (forall (x:A) (y:B), (((R x) y)->((R' x) y)))):(forall (A:Type) (B:Type), ((A->(B->Prop))->((A->(B->Prop))->Prop)))
% 208.63/208.85 suc_p:((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((is_of (ordsucc X0)) (fun (X1:fofType)=> ((in X1) nat)))))
% 208.63/208.85 surjective:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((all X1) (((image X0) X1) X2))):(fofType->(fofType->(fofType->Prop)))
% 208.63/208.85 times:=(fun (X0:fofType)=> ((ind ((d_Pi nat) (fun (X1:fofType)=> nat))) (d_428_prop2 X0))):(fofType->fofType)
% 208.63/208.85 tofs:=(fun (X0:fofType) (X1:fofType)=> ap):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.63/208.85 union:(fofType->fofType)
% 208.63/208.85 unique:=(fun (A:Type) (P:(A->Prop)) (x:A)=> ((and (P x)) (forall (x':A), ((P x')->(((eq A) x) x'))))):(forall (A:Type), ((A->Prop)->(A->Prop)))
% 208.63/208.85 unique_choice:=(fun (A:Type) (B:Type) (R:(A->(B->Prop))) (x:(forall (x:A), ((ex B) ((unique B) (fun (y:B)=> ((R x) y))))))=> ((((dependent_unique_choice A) (fun (x2:A)=> B)) R) x)):(forall (A:Type) (B:Type) (R:(A->(B->Prop))), ((forall (x:A), ((ex B) ((unique B) (fun (y:B)=> ((R x) y)))))->((ex (A->B)) (fun (f:(A->B))=> (forall (x:A), ((R x) (f x)))))))
% 208.63/208.85 univof:(fofType->fofType)
% 208.63/208.85 unmore:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sep X0) (fun (X3:fofType)=> ((l_some X1) (fun (X4:fofType)=> (((esti X0) X3) ((ap X2) X4))))))):(fofType->(fofType->(fofType->fofType)))
% 208.63/208.85 wel:=(fun (X0:Prop)=> (d_not (d_not X0))):(Prop->Prop)
% 208.63/208.85 wissel:=(fun (X0:fofType) (X1:fofType) (X2:fofType)=> ((d_Sigma X0) (((wissel_wb X0) X1) X2))):(fofType->(fofType->(fofType->fofType)))
% 208.63/208.85 wissel_wa:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((((ite (((e_is X0) X3) X1)) X0) X2) X3)):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.63/208.85 wissel_wb:=(fun (X0:fofType) (X1:fofType) (X2:fofType) (X3:fofType)=> ((((ite (((e_is X0) X3) X2)) X0) X1) ((((wissel_wa X0) X1) X2) X3))):(fofType->(fofType->(fofType->(fofType->fofType))))
% 208.63/208.85 xi_ext:(forall (X0:fofType) (X1:(fofType->fofType)) (X2:(fofType->fofType)), ((forall (X3:fofType), (((in X3) X0)->(((eq fofType) (X1 X3)) (X2 X3))))->(((eq fofType) ((d_Sigma X0) X1)) ((d_Sigma X0) X2))))]X0:fofType
% 208.63/208.85 X1:(fofType->Prop)
% 208.63/208.85 X2:fofType]x:((is_of X2) (fun (X2:fofType)=> ((in X2) ((d_Sep X0) X1))))]x0:fofType] (rdef{??}) X2:=((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is X0) ((n_ts X0) n_1)))):Prop
% 208.63/208.85 ---
% 208.63/208.85 self=((all_of (fun (X0:fofType)=> ((in X0) nat))) (fun (X0:fofType)=> ((n_is X0) ((n_ts X0) n_1)))):Prop
% 208.63/208.85 term=(((e_in X0) X1) X2):fofType
% 208.63/208.85 --- does not match type in application fofType vs Prop in (((e_in X0) X1) ((all_of (fun X0:fofType=> ((in X0) nat))) (fun X0:fofType=> ((n_is X0) ((n_ts X0) n_1)))))
% 208.63/208.85 Unexpected exception Does not match type in application fofType vs Prop in (((e_in X0) X1) ((all_of (fun X0:fofType=> ((in X0) nat))) (fun X0:fofType=> ((n_is X0) ((n_ts X0) n_1)))))
% 208.63/208.85
% 208.63/208.85 Traceback (most recent call last):
% 208.63/208.85 File "CASC.py", line 80, in <module>
% 208.63/208.85 proof=problem.solve()
% 208.63/208.85 File "/export/starexec/sandbox2/solver/bin/TPTP.py", line 95, in solve
% 208.63/208.85 for x in self.solveyielding():
% 208.63/208.85 File "/export/starexec/sandbox2/solver/bin/TPTP.py", line 83, in solveyielding
% 208.63/208.85 for proof in proofgen: yield proof
% 208.63/208.85 File "/export/starexec/sandbox2/solver/bin/prover.py", line 422, in proveyielding
% 208.63/208.85 results=node.look() #Can add nodes
% 208.63/208.85 File "/export/starexec/sandbox2/solver/bin/prover.py", line 1221, in look
% 208.63/208.85 matching=target.match(term.body,self.context,termbodycontext,instantiate=True)
% 208.63/208.85 File "/export/starexec/sandbox2/solver/bin/kernel.py", line 576, in match
% 208.63/208.85 atermmatch=s.abstracttermmatch(params,context,termcontext,instantiate=instantiate)
% 208.63/208.85 File "/export/starexec/sandbox2/solver/bin/kernel.py", line 1192, in abstracttermmatch
% 208.63/208.85 print "t=%s:%s" % (t,t.gettype(termsubcontext))
% 208.63/208.85 kernel.TypecheckError: Does not match type in application fofType vs Prop in (((e_in X0) X1) ((all_of (fun X0:fofType=> ((in X0) nat))) (fun X0:fofType=> ((n_is X0) ((n_ts X0) n_1)))))
% 208.63/208.85
%------------------------------------------------------------------------------