let M be non empty set ;
assume A1: not {} in M ;
mode Choice_Function of M -> Function of M, union M means :Def1: :: ORDERS_1:def 1
for X being set st X in M holds
it . X in X;
existence
ex b₁ being Function of M, union M st
for X being set st X in M holds
b₁ . X in X

let D be set ;
func BOOL D -> set equals :: ORDERS_1:def 2
(bool D) \ {{} };
coherence
(bool D) \ {{} } is set ;

let D be non empty set ;
cluster BOOL D -> non empty ;
coherence
not BOOL D is empty

let X be set ;
mode Order of X is reflexive antisymmetric transitive total Relation of X;

let R be Relation;
attr R is being_quasi-order means :: ORDERS_1:def 3
( R is reflexive & R is transitive );
attr R is being_partial-order means :Def4: :: ORDERS_1:def 4
( R is reflexive & R is transitive & R is antisymmetric );
attr R is being_linear-order means :Def5: :: ORDERS_1:def 5
( R is reflexive & R is transitive & R is antisymmetric & R is connected );

let R be Relation;
synonym R is_quasi-order for being_quasi-order R;
synonym R is_partial-order for being_partial-order R;
synonym R is_linear-order for being_linear-order R;

let R be Relation;
let X be set ;
pred R quasi_orders X means :Def6: :: ORDERS_1:def 6
( R is_reflexive_in X & R is_transitive_in X );
pred R partially_orders X means :Def7: :: ORDERS_1:def 7
( R is_reflexive_in X & R is_transitive_in X & R is_antisymmetric_in X );
pred R linearly_orders X means :: ORDERS_1:def 8
( R is_reflexive_in X & R is_transitive_in X & R is_antisymmetric_in X & R is_connected_in X );

let R be Relation;
let X be set ;
pred X has_upper_Zorn_property_wrt R means :Def9: :: ORDERS_1:def 9
for Y being set st Y c= X & R |_2 Y is_linear-order holds
ex x being set st
( x in X & ( for y being set st y in Y holds
[y,x] in R ) );
pred X has_lower_Zorn_property_wrt R means :: ORDERS_1:def 10
for Y being set st Y c= X & R |_2 Y is_linear-order holds
ex x being set st
( x in X & ( for y being set st y in Y holds
[x,y] in R ) );

let R be Relation; :: thesis: R |_2 {} = {}
thus R |_2 {} = ({} | R) | {} by WELLORD1:17
.= {} by RELAT_1:110 ; :: thesis: verum

let R be Relation;
let x be set ;
pred x is_maximal_in R means :Def11: :: ORDERS_1:def 11
( x in field R & ( for y being set holds
( not y in field R or not y <> x or not [x,y] in R ) ) );
pred x is_minimal_in R means :Def12: :: ORDERS_1:def 12
( x in field R & ( for y being set holds
( not y in field R or not y <> x or not [y,x] in R ) ) );
pred x is_superior_of R means :Def13: :: ORDERS_1:def 13
( x in field R & ( for y being set st y in field R & y <> x holds
[y,x] in R ) );
pred x is_inferior_of R means :Def14: :: ORDERS_1:def 14
( x in field R & ( for y being set st y in field R & y <> x holds
[x,y] in R ) );

ex x being Element of F₁() st
for y being Element of F₁() st x <> y holds
not P₁[x,y]

A1: for x being Element of F₁() holds P₁[x,x] and
A2: for x, y being Element of F₁() st P₁[x,y] & P₁[y,x] holds
x = y and
A3: for x, y, z being Element of F₁() st P₁[x,y] & P₁[y,z] holds
P₁[x,z] and
A4: for X being set st X c= F₁() & ( for x, y being Element of F₁() st x in X & y in X & P₁[x,y] holds
P₁[y,x] ) holds
ex y being Element of F₁() st
for x being Element of F₁() st x in X holds
P₁[x,y]

ex x being Element of F₁() st
for y being Element of F₁() st x <> y holds
not P₁[y,x]

A1: for x being Element of F₁() holds P₁[x,x] and
A2: for x, y being Element of F₁() st P₁[x,y] & P₁[y,x] holds
x = y and
A3: for x, y, z being Element of F₁() st P₁[x,y] & P₁[y,z] holds
P₁[x,z] and
A4: for X being set st X c= F₁() & ( for x, y being Element of F₁() st x in X & y in X & P₁[x,y] holds
P₁[y,x] ) holds
ex y being Element of F₁() st
for x being Element of F₁() st x in X holds
P₁[y,x]