Metamath Proof Explorer - mmtheorems19

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Statement List for Metamath Proof Explorer - 1801-1900 - Page 19 of 58

Type	Label	Description
Statement
Theorem	elpw 1801	Membership in a power class. Theorem 86 of [Suppes] p. 47.
|- A e. V   =>   |- (A e. P~B <-> A (_ B)
Theorem	elpwg 1802	Membership in a power class. Theorem 86 of [Suppes] p. 47.
|- (A e. C -> (A e. P~B <-> A (_ B))
Theorem	elpw2g 1803	Membership in a power class. Theorem 86 of [Suppes] p. 47.
|- (B e. C -> (A e. P~B <-> A (_ B))
Theorem	hbpw 1804	Bound-variable hypothesis builder for power class.
|- (y e. A -> A.x y e. A)   =>   |- (y e. P~A -> A.x y e. P~A)
Theorem	pwid 1805	A set is a member of its power set. Theorem 87 of [Suppes] p. 47.
|- A e. V   =>   |- A e. P~A
Theorem	pwex 1806	Power set axiom expressed in class notation. Axiom 4 of [TakeutiZaring] p. 17.
|- A e. V   =>   |- P~A e. V
Theorem	pwexg 1807	Power set axiom expressed in class notation, with the sethood requirement as an antecedent. Axiom 4 of [TakeutiZaring] p. 17.
|- (A e. B -> P~A e. V)
Syntax	csn 1808	Extend class notation to include singleton.
class {A}
Syntax	cpr 1809	Extend class notation to include unordered pair.
class {A, B}
Syntax	cop 1810	Extend class notation to include ordered pair.
class <.A, B>.
Definition	df-sn 1811	Define the singleton of a class. Definition 7.1 of [Quine] p. 48. For convenience, it is well-defined for proper classes, i.e., those that are not elements of V, although it is not very meaningful in this case. For an alternate definition see dfsn2 1819.
|- {A} = {x | x = A}
Definition	df-pr 1812	Define unordered pair of classes. Definition 7.1 of [Quine] p. 48. For a more traditional definition, but requiring a dummy variable, see dfpr2 1821.
|- {A, B} = ({A} u. {B})
Syntax	ctp 1813	Extend class notation to include unordered triplet.
class {A, B, C}
Definition	df-tp 1814	Define unordered triple of classes. Definition of [Enderton] p. 19.
|- {A, B, C} = ({A, B} u. {C})
Definition	df-op 1815	Kuratowski's ordered pair definition. Definition 9.1 of [Quine] p. 58. For proper classes it is not meaningful but is well-defined and we allow it for convenience. For the justifying theorem (for sets) see opth 1898. There are other ways to define ordered pairs; the basic requirement is that two ordered pairs are equal iff their respective members are equal. In 1914 Norbert Wiener gave the first successful definition <.A, B>.1 = {{{A}, (/)}, {{B}}}, justified by opthwiener 1914, which was simplified by Kazimierz Kuratowski in 1921 to our present definition. An even simpler definition <.A, B>.2 = {A, {A, B}} is justified by opthreg 3455, but it requires the Axiom of Regularity for its justification and is not commonly used. A definition that also works for proper classes is <.A, B>.3 = ((A X. {(/)}) u. (B X. {{(/)}})), justified by opthprc 2457. If we restrict our sets to nonnegative integers, an ordered pair definition that involves only elementary arithmetic is provided by nn0opth 4724. Finally, an ordered pair of real numbers can be represented by a complex number as shown by cru 4529.
|- <.A, B>. = {{A}, {A, B}}
Theorem	sneq 1816	Equality theorem for singletons. Part of Exercise 4 of [TakeutiZaring] p. 15.
|- (A = B -> {A} = {B})
Theorem	sneqi 1817	Equality inference for singletons.
|- A = B   =>   |- {A} = {B}
Theorem	sneqd 1818	Equality deduction for singletons.
|- (ph -> A = B)   =>   |- (ph -> {A} = {B})
Theorem	dfsn2 1819	Alternate definition of singleton. Definition 5.1 of [TakeutiZaring] p. 15.
|- {A} = {A, A}
Theorem	elsn 1820	There is only one element in a singleton. Exercise 2 of [TakeutiZaring] p. 15.
|- (x e. {A} <-> x = A)
Theorem	dfpr2 1821	Alternate definition of unordered pair. Definition 5.1 of [TakeutiZaring] p. 15.
|- {A, B} = {x | (x = A \/ x = B)}
Theorem	elprg 1822	A member of an unordered pair of classes is one or the other of them. Exercise 1 of [TakeutiZaring] p. 15, generalized.
|- (A e. D -> (A e. {B, C} <-> (A = B \/ A = C)))
Theorem	elpr 1823	A member of an unordered pair of classes is one or the other of them. Exercise 1 of [TakeutiZaring] p. 15.
|- A e. V   =>   |- (A e. {B, C} <-> (A = B \/ A = C))
Theorem	hbpr 1824	Bound-variable hypothesis builder for unordered pairs.
|- (y e. A -> A.x y e. A)   &   |- (y e. B -> A.x y e. B)   =>   |- (y e. {A, B} -> A.x y e. {A, B})
Theorem	elsncg 1825	There is only one element in a singleton. Exercise 2 of [TakeutiZaring] p. 15 (generalized).
|- (A e. C -> (A e. {B} <-> A = B))
Theorem	elsnc 1826	There is only one element in a singleton. Exercise 2 of [TakeutiZaring] p. 15.
|- A e. V   =>   |- (A e. {B} <-> A = B)
Theorem	elsni 1827	There is only one element in a singleton.
|- (A e. {B} -> A = B)
Theorem	snidg 1828	A set is a member of its singleton. Part of Theorem 7.6 of [Quine] p. 49.
|- (A e. B -> A e. {A})
Theorem	snidb 1829	A class is a set iff it is a member of its singleton.
|- (A e. V <-> A e. {A})
Theorem	snid 1830	A set is a member of its singleton. Part of Theorem 7.6 of [Quine] p. 49.
|- A e. V   =>   |- A e. {A}
Theorem	elsnc2g 1831	There is only one element in a singleton. Exercise 2 of [TakeutiZaring] p. 15. This variation requires only that B, rather than A, be a set.
|- (B e. C -> (A e. {B} <-> A = B))
Theorem	elsnc2 1832	There is only one element in a singleton. Exercise 2 of [TakeutiZaring] p. 15. This variation requires only that B, rather than A, be a set.
|- B e. V   =>   |- (A e. {B} <-> A = B)
Theorem	hbsn 1833	Bound-variable hypothesis builder for singletons.
|- (y e. A -> A.x y e. A)   =>   |- (y e. {A} -> A.x y e. {A})
Theorem	eltp 1834	A member of an unordered triple of classes is one of them. Special case of Exercise 1 of [TakeutiZaring] p. 17.
|- A e. V   =>   |- (A e. {B, C, D} <-> (A = B \/ A = C \/ A = D))
Theorem	dftp2 1835	Alternate definition of unordered triple of classes. Special case of Definition 5.3 of [TakeutiZaring] p. 16.
|- {A, B, C} = {x | (x = A \/ x = B \/ x = C)}
Theorem	disjsn 1836	Intersection with singleton of non-member is disjoint.
|- ((A i^i {B}) = (/) <-> -. B e. A)
Theorem	disjsn2 1837	Intersection of distinct singletons is disjoint.
|- (-. A = B -> ({A} i^i {B}) = (/))
Theorem	snprc 1838	The singleton of a proper class (one that doesn't exist) is the empty set. Theorem 7.2 of [Quine] p. 48.
|- (-. A e. V <-> {A} = (/))
Theorem	prprc 1839	An unordered pair containing a proper class equals a singleton.
|- (-. A e. V -> {A, B} = {B})
Theorem	prcom 1840	Commutative law for unordered pairs.
|- {A, B} = {B, A}
Theorem	pri1 1841	One of the two elements of an unordered pair. Part of Theorem 7.6 of [Quine] p. 49.
|- A e. V   =>   |- A e. {A, B}
Theorem	pri2 1842	One of the two elements of an unordered pair. Part of Theorem 7.6 of [Quine] p. 49.
|- B e. V   =>   |- B e. {A, B}
Theorem	tpi1 1843	One of the three elements of an unordered triple.
|- A e. V   =>   |- A e. {A, B, C}
Theorem	tpi2 1844	One of the three elements of an unordered triple.
|- B e. V   =>   |- B e. {A, B, C}
Theorem	tpi3 1845	One of the three elements of an unordered triple.
|- C e. V   =>   |- C e. {A, B, C}
Theorem	snnz 1846	The singleton of a set is not empty.
|- A e. V   =>   |- -. {A} = (/)
Theorem	prnz 1847	A pair containing a set is not empty.
|- A e. V   =>   |- -. {A, B} = (/)
Theorem	tpnz 1848	A triplet containing a set is not empty.
|- A e. V   =>   |- -. {A, B, C} = (/)
Theorem	snss 1849	The singleton of an element of a class is a subset of the class. Theorem 7.4 of [Quine] p. 49.
|- A e. V   =>   |- (A e. B <-> {A} (_ B)
Theorem	snssg 1850	The singleton of an element of a class is a subset of the class. Theorem 7.4 of [Quine] p. 49.
|- (A e. C -> (A e. B <-> {A} (_ B))
Theorem	snssi 1851	The singleton of an element of a class is a subset of the class.
|- (A e. B -> {A} (_ B)
Theorem	sssn 1852	The only subsets of a singleton are the singleton and the empty set.
|- (A (_ {B} <-> (A = (/) \/ A = {B}))
Theorem	snsspr 1853	A singleton is a subset of an unordered pair containing its member.
|- {A} (_ {A, B}
Theorem	prss 1854	A pair of elements of a class is a subset of the class. Theorem 7.5 of [Quine] p. 49.
|- A e. V   &   |- B e. V   =>   |- ((A e. C /\ B e. C) <-> {A, B} (_ C)
Theorem	tpss 1855	A triplet of elements of a class is a subset of the class.
|- A e. V   &   |- B e. V   &   |- C e. V   =>   |- ((A e. D /\ B e. D /\ C e. D) <-> {A, B, C} (_ D)
Theorem	sneqr 1856	If the singletons of two sets are equal, the two sets are equal. Part of Exercise 4 of [TakeutiZaring] p. 15.
|- A e. V   =>   |- ({A} = {B} -> A = B)
Theorem	snsspw 1857	The singleton of a class is a subset of its power class.
|- {A} (_ P~A
Theorem	prsspw 1858	An unordered pair belongs to the power class of a class iff each member belongs to the class.
|- A e. V   &   |- B e. V   =>   |- ({A, B} (_ P~C <-> (A (_ C /\ B (_ C))
Theorem	snex 1859	A singleton is a set. Theorem 7.13 of [Quine] p. 51, but proved using only Extensionality, Power Set, and Separation.
|- {A} e. V
Theorem	el 1860	Every set is a member of some other set.
|- E.y x e. y
Theorem	snelpw 1861	A singleton of a set belongs to the power class of a class containing the set.
|- A e. V   =>   |- (A e. B <-> {A} e. P~B)
Theorem	rext 1862	A theorem similar to extensionality, requiring the existence of a singleton. Exercise 8 of [TakeutiZaring] p. 16.
|- (A.z(x e. z -> y e. z) -> x = y)
Theorem	sspwb 1863	Classes are subclasses if and only if their power classes are subclasses. Exercise 18 of [TakeutiZaring] p. 18.
|- (A (_ B <-> P~A (_ P~B)
Theorem	ssextss 1864	An extensionality-like principle defining subclass in terms of subsets.
|- (A (_ B <-> A.x(x (_ A -> x (_ B))
Theorem	ssext 1865	An extensionality-like principle that uses the subset instead of the membership relation: two classes are equal iff they have the same subsets.
|- (A = B <-> A.x(x (_ A <-> x (_ B))
Theorem	nssss 1866	Negation of subclass relationship. Compare nss 1550.
|- (-. A (_ B <-> E.x(x (_ A /\ -. x (_ B))
Theorem	pweqb 1867	Classes are equal if and only if their power classes are equal. Exercise 19 of [TakeutiZaring] p. 18.
|- (A = B <-> P~A = P~B)
Theorem	moabex 1868	"At most one" existence implies a class abstraction exists.
|- (E*xph -> {x | ph} e. V)
Theorem	euabex 1869	The abstraction of a wff with existential uniqueness exists.
|- (E!xph -> {x | ph} e. V)
Theorem	preq1 1870	An equality theorem for unordered pairs.
|- (A = B -> {A, C} = {B, C})
Theorem	preq2 1871	An equality theorem for unordered pairs.
|- (A = B -> {C, A} = {C, B})
Theorem	preqr1 1872	Reverse equality lemma for unordered pairs. If two unordered pairs have the same second element, the first elements are equal.
|- A e. V   &   |- B e. V   =>   |- ({A, C} = {B, C} -> A = B)
Theorem	prer2 1873	Reverse equality lemma for unordered pairs. If two unordered pairs have the same first element, the second elements are equal.
|- A e. V   &   |- B e. V   =>   |- ({C, A} = {C, B} -> A = B)
Theorem	preq12b 1874	Equality relationship for two unordered pairs.
|- A e. V   &   |- B e. V   &   |- C e. V   &   |- D e. V   =>   |- ({A, B} = {C, D} <-> ((A = C /\ B = D) \/ (A = D /\ B = C)))
Theorem	prel12 1875	Equality of two unordered pairs.
|- A e. V   &   |- B e. V   &   |- C e. V   &   |- D e. V   =>   |- (-. A = B -> ({A, B} = {C, D} <-> (A e. {C, D} /\ B e. {C, D})))
Theorem	opeq1 1876	Equality theorem for ordered pairs.
|- (A = B -> <.A, C>. = <.B, C>.)
Theorem	opeq2 1877	Equality theorem for ordered pairs.
|- (A = B -> <.C, A>. = <.C, B>.)
Theorem	opeq12 1878	Equality theorem for ordered pairs.
|- ((A = C /\ B = D) -> <.A, B>. = <.C, D>.)
Theorem	hbop 1879	Bound-variable hypothesis builder for ordered pairs.