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Statement List for Metamath Proof Explorer - 4101-4200 - Page 42 of 107
TypeLabelDescription
Statement
 
Theoremelxp7 4101 Membership in a cross product. This version requires no quantifiers or dummy variables. See also elxp4 3451.
|- (A e. (B X. C) <-> (A e. (V X. V) /\ ((1st` A) e. B /\ (2nd` A) e. C)))
 
Theoremeqop 4102 Two ways to express equality with an ordered pair.
|- C e. V   =>   |- (A e. (V X. V) -> (A = <.B, C>. <-> ((1st` A) = B /\ (2nd` A) = C)))
 
Theoremxp2 4103 Representation of cross product based on ordered pair component functions.
|- (A X. B) = {x e. (V X. V) | ((1st` x) e. A /\ (2nd` x) e. B)}
 
Theoremxpopth 4104 An ordered pair theorem for members of cross products.
|- ((A e. (C X. D) /\ B e. (R X. S)) -> (((1st` A) = (1st` B) /\ (2nd` A) = (2nd` B)) <-> A = B))
 
Theoremunielxp 4105 The membership relation for a cross product is inherited by union.
|- (A e. (B X. C) -> U.A e. U.(B X. C))
 
Theorem1st2nd 4106 Reconstruction of a member of a relation in terms of its ordered pair components.
|- ((Rel B /\ A e. B) -> A = <.(1st` A), (2nd` A)>.)
 
Theorem1stdm 4107 The first ordered pair component of a member of a relation belongs to the domain of the relation.
|- ((Rel R /\ A e. R) -> (1st` A) e. dom R)
 
Theorem2ndrn 4108 The second ordered pair component of a member of a relation belongs to the range of the relation.
|- ((Rel R /\ A e. R) -> (2nd` A) e. ran R)
 
Theoremsbcopeq1a 4109 Equality theorem for substitution of a class for an ordered pair (analog of sbceq1a 1942, that avoids the existential quantifiers of copsexg 2790).
|- (<.x, y>. = A -> (ph <-> [(1st` A) / x][(2nd` A) / y]ph))
 
Theoremcsbopeq1a 4110 Equality theorem for substitution of a class A for an ordered pair <.x, y>. in B (analog of csbeq1a 2004).
|- (<.x, y>. = A -> B = [_(1st` A) / x]_[_(2nd` A) / y]_B)
 
Theoremdfopab2 4111 A way to define an ordered-pair class abstraction without using existential quantifiers.
|- {<.x, y>. | ph} = {z | (z e. (V X. V) /\ [(1st` z) / x][(2nd` z) / y]ph)}
 
Theoremdfoprab3 4112 A way to define an operation class abstraction without using existential quantifiers.
|- {<.<.x, y>., z>. | ph} = {<.w, z>. | (w e. (V X. V) /\ [(1st` w) / x][(2nd` w) / y]ph)}
 
Theoremdfoprab5 4113 A way to define an operation class abstraction without using existential quantifiers.
|- (<.x, y>. = w -> C = D)   =>   |- {<.<.x, y>., z>. | ((x e. A /\ y e. B) /\ z = C)} = {<.w, z>. | (w e. (A X. B) /\ z = D)}
 
Theoremdfoprab4 4114 A way to define an operation class abstraction without using existential quantifiers.
|- ((x = (1st` w) /\ y = (2nd` w)) -> C = D)   =>   |- {<.<.x, y>., z>. | ((x e. A /\ y e. B) /\ z = C)} = {<.w, z>. | (w e. (A X. B) /\ z = D)}
 
Theoremelopabi 4115 A consequence of membership in an ordered-pair class abstraction, using ordered pair extractors.
|- (x = (1st` A) -> (ph <-> ps))   &   |- (y = (2nd` A) -> (ps <-> ch))   =>   |- (A e. {<.x, y>. | ph} -> ch)
 
Theoremeloprabi 4116 A consequence of membership in an operation class abstraction, using ordered pair extractors.
|- (x = (1st` (1st` A)) -> (ph <-> ps))   &   |- (y = (2nd` (1st` A)) -> (ps <-> ch))   &   |- (z = (2nd` A) -> (ch <-> th))   =>   |- (A e. {<.<.x, y>., z>. | ph} -> th)
 
Theoremfoprab2 4117 Mapping of an operation class abstraction.
|- F = {<.<.x, y>., z>. | ((x e. A /\ y e. B) /\ z = C)}   =>   |- (A.x e. A A.y e. B C e. D <-> F:(A X. B)-->D)
 
Theoremfoprab 4118 Mapping of an operation class abstraction.
|- F = {<.<.x, y>., z>. | ((x e. A /\ y e. B) /\ z = C)}   &   |- ((x e. A /\ y e. B) -> C e. D)   =>   |- F:(A X. B)-->D
 
Theoremfnoprab2g 4119 Functionality and domain of an operation class abstraction.
|- F = {<.<.x, y>., z>. | ((x e. A /\ y e. B) /\ z = C)}   =>   |- (A.x e. A A.y e. B C e. V <-> F Fn (A X. B))
 
Theoremfnoprab2 4120 Functionality and domain of an operation class abstraction.
|- C e. V   &   |- F = {<.<.x, y>., z>. | ((x e. A /\ y e. B) /\ z = C)}   =>   |- F Fn (A X. B)
 
Theoremdmoprab2 4121 Domain of an operation class abstraction.
|- C e. V   &   |- F = {<.<.x, y>., z>. | ((x e. A /\ y e. B) /\ z = C)}   =>   |- dom F = (A X. B)
 
Theoremelrnoprabg 4122 Membership in the range of an operation class abstraction.
|- F = {<.<.x, y>., z>. | ((x e. A /\ y e. B) /\ z = C)}   =>   |- (A.x e. A A.y e. B C e. R -> (D e. ran F <-> E.x e. A E.y e. B D = C))
 
Theoremelrnoprab 4123 Membership in the range of an operation class abstraction.
|- C e. V   &   |- F = {<.<.x, y>., z>. | ((x e. A /\ y e. B) /\ z = C)}   =>   |- (D e. ran F <-> E.x e. A E.y e. B D = C)
 
Theoremdf1st2 4124 An alternate possible definition of the 1st function.
|- {<.<.x, y>., z>. | z = x} = (1st |` (V X. V))
 
Theoremdf2nd2 4125 An alternate possible definition of the 2nd function.
|- {<.<.x, y>., z>. | z = y} = (2nd |` (V X. V))
 
Ordinal arithmetic
 
Syntaxc1o 4126 Extend the definition of a class to include the ordinal number 1.
class 1o
 
Syntaxc2o 4127 Extend the definition of a class to include the ordinal number 2.
class 2o
 
Syntaxcoa 4128 Extend the definition of a class to include the ordinal addition operation.
class +o
 
Syntaxcomu 4129 Extend the definition of a class to include the ordinal multiplication operation.
class .o
 
Syntaxcoe 4130 Extend the definition of a class to include the ordinal exponentiation operation.
class ^o
 
Definitiondf-1o 4131 Define the ordinal number 1.
|- 1o = suc (/)
 
Definitiondf-2o 4132 Define the ordinal number 2.
|- 2o = suc 1o
 
Definitiondf-oadd 4133 Define the ordinal addition operation.
|- +o = {<.<.x, y>., z>. | ((x e. On /\ y e. On) /\ z = (rec({<.w, v>. | v = suc w}, x)` y))}
 
Definitiondf-omul 4134 Define the ordinal multiplication operation.
|- .o = {<.<.x, y>., z>. | ((x e. On /\ y e. On) /\ z = (rec({<.w, v>. | v = (w +o x)}, (/))` y))}
 
Definitiondf-oexp 4135 Define the ordinal exponentiation operation.
|- ^o = {<.<.x, y>., z>. | ((x e. On /\ y e. On) /\ z = if(x = (/), (1o \ y), (rec({<.w, v>. | v = (w .o x)}, 1o)` y)))}
 
Theorem1on 4136 Ordinal 1 is an ordinal number.
|- 1o e. On
 
Theorem2on 4137 Ordinal 2 is an ordinal number.
|- 2o e. On
 
Theoremdf1o2 4138 Expanded value of the ordinal number 1.
|- 1o = {(/)}
 
Theoremdf2o2 4139 Expanded value of the ordinal number 2.
|- 2o = {(/), {(/)}}
 
Theorem1ne0 4140 Ordinal one is not equal to ordinal zero.
|- 1o =/= (/)
 
Theoremxp01disj 4141 Cross products with the singletons of ordinals 0 and 1 are disjoint.
|- ((A X. {(/)}) i^i (C X. {1o})) = (/)
 
Theoremordgt0ge1 4142 Two ways to express that an ordinal class is positive.
|- (Ord A -> ((/) e. A <-> 1o (_ A))
 
Theoremordge1n0 4143 An ordinal greater than or equal to 1 is nonzero.
|- (Ord A -> (1o (_ A <-> A =/= (/)))
 
Theoremel1o 4144 Membership in ordinal one.
|- (A e. 1o <-> A = (/))
 
Theorem0lt1o 4145 Ordinal zero is less than ordinal one.
|- (/) e. 1o
 
Theoremfnoa 4146 Functionality and domain of ordinal addition.
|- +o Fn (On X. On)
 
Theoremfnom 4147 Functionality and domain of ordinal multiplication.
|- .o Fn (On X. On)
 
Theoremoav 4148 Value of ordinal addition.
|- ((A e. On /\ B e. On) -> (A +o B) = (rec({<.x, y>. | y = suc x}, A)` B))
 
Theoremomv 4149 Value of ordinal multiplication.
|- ((A e. On /\ B e. On) -> (A .o B) = (rec({<.x, y>. | y = (x +o A)}, (/))` B))
 
Theoremoe0lem 4150 A helper lemma for oe0 4159 and others.
|- ((ph /\ A = (/)) -> ps)   &   |- (((A e. On /\ ph) /\ (/) e. A) -> ps)   =>   |- ((A e. On /\ ph) -> ps)
 
Theoremoev 4151 Value of ordinal exponentiation.
|- ((A e. On /\ B e. On) -> (A ^o B) = if(A = (/), (1o \ B), (rec({<.x, y>. | y = (x .o A)}, 1o)` B)))
 
Theoremoevn0 4152 Value of ordinal exponentiation at a nonzero mantissa.
|- (((A