%------------------------------------------------------------------------------
% File     : SuperZenon---0.0.1
% Problem  : NUM394+1 : TPTP v8.1.0. Released v3.2.0.
% Transfm  : none
% Format   : tptp:raw
% Command  : run_super_zenon -p0 -itptp -om -max-time %d %s

% Computer : n013.cluster.edu
% Model    : x86_64 x86_64
% CPU      : Intel(R) Xeon(R) CPU E5-2620 v4 2.10GHz
% Memory   : 8042.1875MB
% OS       : Linux 3.10.0-693.el7.x86_64
% CPULimit : 300s
% WCLimit  : 600s
% DateTime : Mon Jul 18 14:42:08 EDT 2022

% Result   : Theorem 0.60s 0.79s
% Output   : Proof 0.60s
% Verified : 
% SZS Type : -

% Comments : 
%------------------------------------------------------------------------------
%----WARNING: Could not form TPTP format derivation
%------------------------------------------------------------------------------
%----ORIGINAL SYSTEM OUTPUT
% 0.00/0.12  % Problem  : NUM394+1 : TPTP v8.1.0. Released v3.2.0.
% 0.12/0.13  % Command  : run_super_zenon -p0 -itptp -om -max-time %d %s
% 0.13/0.34  % Computer : n013.cluster.edu
% 0.13/0.34  % Model    : x86_64 x86_64
% 0.13/0.34  % CPU      : Intel(R) Xeon(R) CPU E5-2620 v4 @ 2.10GHz
% 0.13/0.34  % Memory   : 8042.1875MB
% 0.13/0.34  % OS       : Linux 3.10.0-693.el7.x86_64
% 0.13/0.34  % CPULimit : 300
% 0.13/0.34  % WCLimit  : 600
% 0.13/0.34  % DateTime : Thu Jul  7 17:01:59 EDT 2022
% 0.13/0.34  % CPUTime  : 
% 0.60/0.79  % SZS status Theorem
% 0.60/0.79  (* PROOF-FOUND *)
% 0.60/0.79  (* BEGIN-PROOF *)
% 0.60/0.79  % SZS output start Proof
% 0.60/0.79  1. (ordinal T_0) (-. (ordinal T_0))   ### Axiom
% 0.60/0.79  2. (ordinal T_0) (-. (ordinal T_0))   ### Axiom
% 0.60/0.79  3. (ordinal T_0) (-. (ordinal T_0))   ### Axiom
% 0.60/0.79  4. (ordinal T_1) (-. (ordinal T_1))   ### Axiom
% 0.60/0.79  5. (ordinal T_0) (-. (ordinal T_0))   ### Axiom
% 0.60/0.79  6. (-. (in T_1 T_0)) (in T_1 T_0)   ### Axiom
% 0.60/0.79  7. (T_0 != T_1) (T_1 = T_0)   ### Sym(=)
% 0.60/0.79  8. (ordinal T_0) (-. (ordinal T_0))   ### Axiom
% 0.60/0.79  9. (-. (in T_0 T_1)) (in T_0 T_1)   ### Axiom
% 0.60/0.79  10. (ordinal T_1) (-. (in T_0 T_1)) (ordinal T_0) (T_0 != T_1) (-. (in T_1 T_0))   ### Extension/test/t24_ordinal1_inst 6 7 8 9
% 0.60/0.79  11. (-. (subset T_1 T_0)) (subset T_1 T_0)   ### Axiom
% 0.60/0.79  12. (epsilon_transitive T_0) (-. (subset T_1 T_0)) (T_0 != T_1) (ordinal T_0) (-. (in T_0 T_1)) (ordinal T_1)   ### Extension/test/d2_ordinal1_inst 10 11
% 0.60/0.79  13. (T_0 != T_0)   ### Refl(=)
% 0.60/0.79  14. (-. (ordinal_subset T_1 T_0)) (ordinal_subset T_0 T_0) (ordinal T_1) (-. (in T_0 T_1)) (ordinal T_0) (-. (subset T_1 T_0)) (epsilon_transitive T_0)   ### P-NotP 12 13
% 0.60/0.79  15. (-. (ordinal_subset T_1 T_0)) (ordinal_subset T_1 T_0)   ### Axiom
% 0.60/0.79  16. ((ordinal_subset T_1 T_0) <=> (subset T_1 T_0)) (epsilon_transitive T_0) (ordinal T_0) (-. (in T_0 T_1)) (ordinal T_1) (ordinal_subset T_0 T_0) (-. (ordinal_subset T_1 T_0))   ### Equiv 14 15
% 0.60/0.79  17. (((ordinal T_1) /\ (ordinal T_0)) => ((ordinal_subset T_1 T_0) <=> (subset T_1 T_0))) (-. (ordinal_subset T_1 T_0)) (ordinal_subset T_0 T_0) (-. (in T_0 T_1)) (epsilon_transitive T_0) (ordinal T_0) (ordinal T_1)   ### DisjTree 4 5 16
% 0.60/0.79  18. (All B, (((ordinal T_1) /\ (ordinal B)) => ((ordinal_subset T_1 B) <=> (subset T_1 B)))) (ordinal T_1) (ordinal T_0) (epsilon_transitive T_0) (-. (in T_0 T_1)) (ordinal_subset T_0 T_0) (-. (ordinal_subset T_1 T_0))   ### All 17
% 0.60/0.79  19. (All A, (All B, (((ordinal A) /\ (ordinal B)) => ((ordinal_subset A B) <=> (subset A B))))) (-. (ordinal_subset T_1 T_0)) (ordinal_subset T_0 T_0) (-. (in T_0 T_1)) (epsilon_transitive T_0) (ordinal T_0) (ordinal T_1)   ### All 18
% 0.60/0.79  20. (((ordinal T_0) /\ (ordinal T_0)) => (ordinal_subset T_0 T_0)) (ordinal T_1) (epsilon_transitive T_0) (-. (in T_0 T_1)) (-. (ordinal_subset T_1 T_0)) (All A, (All B, (((ordinal A) /\ (ordinal B)) => ((ordinal_subset A B) <=> (subset A B))))) (ordinal T_0)   ### DisjTree 2 3 19
% 0.60/0.79  21. (All B, (((ordinal T_0) /\ (ordinal B)) => (ordinal_subset T_0 T_0))) (ordinal T_0) (All A, (All B, (((ordinal A) /\ (ordinal B)) => ((ordinal_subset A B) <=> (subset A B))))) (-. (ordinal_subset T_1 T_0)) (-. (in T_0 T_1)) (epsilon_transitive T_0) (ordinal T_1)   ### All 20
% 0.60/0.79  22. (All A, (All B, (((ordinal A) /\ (ordinal B)) => (ordinal_subset A A)))) (ordinal T_1) (epsilon_transitive T_0) (-. (in T_0 T_1)) (-. (ordinal_subset T_1 T_0)) (All A, (All B, (((ordinal A) /\ (ordinal B)) => ((ordinal_subset A B) <=> (subset A B))))) (ordinal T_0)   ### All 21
% 0.60/0.79  23. ((epsilon_transitive T_0) /\ (epsilon_connected T_0)) (ordinal T_0) (All A, (All B, (((ordinal A) /\ (ordinal B)) => ((ordinal_subset A B) <=> (subset A B))))) (-. (ordinal_subset T_1 T_0)) (-. (in T_0 T_1)) (ordinal T_1) (All A, (All B, (((ordinal A) /\ (ordinal B)) => (ordinal_subset A A))))   ### And 22
% 0.60/0.79  24. ((ordinal T_0) => ((epsilon_transitive T_0) /\ (epsilon_connected T_0))) (All A, (All B, (((ordinal A) /\ (ordinal B)) => (ordinal_subset A A)))) (ordinal T_1) (-. (in T_0 T_1)) (-. (ordinal_subset T_1 T_0)) (All A, (All B, (((ordinal A) /\ (ordinal B)) => ((ordinal_subset A B) <=> (subset A B))))) (ordinal T_0)   ### Imply 1 23
% 0.60/0.79  25. (All A, ((ordinal A) => ((epsilon_transitive A) /\ (epsilon_connected A)))) (ordinal T_0) (All A, (All B, (((ordinal A) /\ (ordinal B)) => ((ordinal_subset A B) <=> (subset A B))))) (-. (ordinal_subset T_1 T_0)) (-. (in T_0 T_1)) (ordinal T_1) (All A, (All B, (((ordinal A) /\ (ordinal B)) => (ordinal_subset A A))))   ### All 24
% 0.60/0.79  26. (-. ((ordinal T_0) => ((ordinal_subset T_1 T_0) \/ (in T_0 T_1)))) (All A, (All B, (((ordinal A) /\ (ordinal B)) => (ordinal_subset A A)))) (ordinal T_1) (All A, (All B, (((ordinal A) /\ (ordinal B)) => ((ordinal_subset A B) <=> (subset A B))))) (All A, ((ordinal A) => ((epsilon_transitive A) /\ (epsilon_connected A))))   ### ConjTree 25
% 0.60/0.79  27. (-. (All B, ((ordinal B) => ((ordinal_subset T_1 B) \/ (in B T_1))))) (All A, ((ordinal A) => ((epsilon_transitive A) /\ (epsilon_connected A)))) (All A, (All B, (((ordinal A) /\ (ordinal B)) => ((ordinal_subset A B) <=> (subset A B))))) (ordinal T_1) (All A, (All B, (((ordinal A) /\ (ordinal B)) => (ordinal_subset A A))))   ### NotAllEx 26
% 0.60/0.79  28. (-. ((ordinal T_1) => (All B, ((ordinal B) => ((ordinal_subset T_1 B) \/ (in B T_1)))))) (All A, (All B, (((ordinal A) /\ (ordinal B)) => (ordinal_subset A A)))) (All A, (All B, (((ordinal A) /\ (ordinal B)) => ((ordinal_subset A B) <=> (subset A B))))) (All A, ((ordinal A) => ((epsilon_transitive A) /\ (epsilon_connected A))))   ### NotImply 27
% 0.60/0.79  29. (-. (All A, ((ordinal A) => (All B, ((ordinal B) => ((ordinal_subset A B) \/ (in B A))))))) (All A, ((ordinal A) => ((epsilon_transitive A) /\ (epsilon_connected A)))) (All A, (All B, (((ordinal A) /\ (ordinal B)) => ((ordinal_subset A B) <=> (subset A B))))) (All A, (All B, (((ordinal A) /\ (ordinal B)) => (ordinal_subset A A))))   ### NotAllEx 28
% 0.60/0.79  % SZS output end Proof
% 0.60/0.79  (* END-PROOF *)
%------------------------------------------------------------------------------