Journal of Formalized Mathematics
Volume 10, 1998
University of Bialystok
Copyright (c) 1998
Association of Mizar Users
The abstract of the Mizar article:
-
- by
- Artur Kornilowicz
- Received September 7, 1998
- MML identifier: TOPGRP_1
- [
Mizar article,
MML identifier index
]
environ
vocabulary PRE_TOPC, SGRAPH1, FUNCT_1, RELAT_1, SUBSET_1, VECTSP_1, REALSET1,
GROUP_1, ORDINAL2, TOPS_2, CONNSP_2, TOPS_1, BOOLE, FUNCT_2, BINOP_1,
UNIALG_1, URYSOHN1, COMPTS_1, SETFAM_1, PCOMPS_1, TARSKI, TOPGRP_1,
RLVECT_3, SEQ_1;
notation TARSKI, XBOOLE_0, ZFMISC_1, SUBSET_1, RELAT_1, TOPS_2, FUNCT_1,
PARTFUN1, BINOP_1, SETFAM_1, GRCAT_1, REALSET1, GROUP_1, GROUP_2,
STRUCT_0, VECTSP_1, PRE_TOPC, TOPS_1, COMPTS_1, PCOMPS_1, URYSOHN1,
BORSUK_1, T_0TOPSP, CANTOR_1, FUNCT_2, YELLOW_8;
constructors REALSET1, TOPS_1, TOPS_2, GRCAT_1, T_0TOPSP, GROUP_7, URYSOHN1,
COMPTS_1, CANTOR_1, YELLOW_8, MEMBERED;
clusters BORSUK_1, BORSUK_2, STRUCT_0, GROUP_1, PRE_TOPC, WAYBEL10, TEX_1,
PCOMPS_1, TOPS_1, RELSET_1, SUBSET_1, FUNCT_2, PARTFUN1, XBOOLE_0;
requirements SUBSET, BOOLE;
begin :: Preliminaries
reserve S for 1-sorted,
R for non empty 1-sorted,
X for Subset of R,
T for non empty TopStruct,
x for set;
definition let X be set;
cluster one-to-one onto Function of X, X;
end;
theorem :: TOPGRP_1:1
rng id S = [#]S;
definition let R be non empty 1-sorted;
cluster (id R)/" -> one-to-one;
end;
theorem :: TOPGRP_1:2
(id R)/" = id R;
theorem :: TOPGRP_1:3
(id R)"X = X;
definition let S be 1-sorted;
cluster one-to-one onto map of S, S;
end;
begin :: On the groups
reserve H for non empty HGrStr,
P, Q, P1, Q1 for Subset of H,
h for Element of H;
theorem :: TOPGRP_1:4
P c= P1 & Q c= Q1 implies P * Q c= P1 * Q1;
theorem :: TOPGRP_1:5
P c= Q implies P * h c= Q * h;
theorem :: TOPGRP_1:6
P c= Q implies h * P c= h * Q;
reserve G for Group,
A, B for Subset of G,
a for Element of G;
theorem :: TOPGRP_1:7
a in A" iff a" in A;
theorem :: TOPGRP_1:8
A"" = A;
theorem :: TOPGRP_1:9
A c= B iff A" c= B";
theorem :: TOPGRP_1:10
(inverse_op G).:A = A";
theorem :: TOPGRP_1:11
(inverse_op G)"A = A";
theorem :: TOPGRP_1:12
inverse_op G is one-to-one;
theorem :: TOPGRP_1:13
rng inverse_op G = the carrier of G;
definition let G be Group;
cluster inverse_op G -> one-to-one onto;
end;
theorem :: TOPGRP_1:14
(inverse_op G)" = inverse_op G;
theorem :: TOPGRP_1:15
(the mult of H).:[:P,Q:] = P*Q;
definition let G be non empty HGrStr, a be Element of G;
func a* -> map of G, G means
:: TOPGRP_1:def 1
for x being Element of G holds it.x = a * x;
func *a -> map of G, G means
:: TOPGRP_1:def 2
for x being Element of G holds it.x = x * a;
end;
definition let G be Group, a be Element of G;
cluster a* -> one-to-one onto;
cluster *a -> one-to-one onto;
end;
theorem :: TOPGRP_1:16
h*.:P = h * P;
theorem :: TOPGRP_1:17
(*h).:P = P * h;
theorem :: TOPGRP_1:18
a*/" = a"*;
theorem :: TOPGRP_1:19
(*a)/" = *(a");
begin :: On the topological spaces
definition let T be non empty TopStruct;
cluster (id T)/" -> continuous;
end;
theorem :: TOPGRP_1:20
id T is_homeomorphism;
definition let T be non empty TopSpace, p be Point of T;
cluster -> non empty a_neighborhood of p;
end;
theorem :: TOPGRP_1:21
for T being non empty TopSpace, p being Point of T holds
[#]T is a_neighborhood of p;
definition let T be non empty TopSpace, p be Point of T;
cluster non empty open a_neighborhood of p;
end;
theorem :: TOPGRP_1:22
for S, T being non empty TopSpace, f being map of S, T st f is open holds
for p being Point of S, P being a_neighborhood of p
ex R being open a_neighborhood of f.p st R c= f.:P;
theorem :: TOPGRP_1:23
for S, T being non empty TopSpace, f being map of S, T st
for p being Point of S, P being open a_neighborhood of p
ex R being a_neighborhood of f.p st R c= f.:P
holds f is open;
theorem :: TOPGRP_1:24
for S, T being non empty TopStruct, f being map of S, T holds
f is_homeomorphism iff dom f = [#]S & rng f = [#]T & f is one-to-one &
for P being Subset of T holds P is closed iff f"P is closed;
theorem :: TOPGRP_1:25
for S, T being non empty TopStruct, f being map of S, T holds
f is_homeomorphism iff dom f = [#]S & rng f = [#]T & f is one-to-one &
for P being Subset of S holds P is open iff f.:P is open;
theorem :: TOPGRP_1:26
for S, T being non empty TopStruct, f being map of S, T holds
f is_homeomorphism iff dom f = [#]S & rng f = [#]T & f is one-to-one &
for P being Subset of T holds P is open iff f"P is open;
theorem :: TOPGRP_1:27
for S being TopSpace, T being non empty TopSpace, f being map of S, T holds
f is continuous iff
for P being Subset of T holds f"(Int P) c= Int(f"P);
definition let T be non empty TopSpace;
cluster non empty dense Subset of T;
end;
theorem :: TOPGRP_1:28
for S, T being non empty TopSpace, f being map of S, T,
A being dense Subset of S st f is_homeomorphism
holds f.:A is dense;
theorem :: TOPGRP_1:29
for S, T being non empty TopSpace, f being map of S, T,
A being dense Subset of T st f is_homeomorphism
holds f"A is dense;
definition let S, T be non empty TopStruct;
cluster being_homeomorphism -> onto one-to-one continuous open map of S, T;
end;
definition let T be non empty TopStruct;
cluster being_homeomorphism map of T, T;
end;
definition let T be non empty TopStruct,
f be being_homeomorphism map of T, T;
cluster f/" -> being_homeomorphism;
end;
begin :: The group of homoemorphisms
definition let T be non empty TopStruct;
mode Homeomorphism of T -> map of T, T means
:: TOPGRP_1:def 3
it is_homeomorphism;
end;
definition let T be non empty TopStruct;
redefine func id T -> Homeomorphism of T;
end;
definition let T be non empty TopStruct;
cluster -> being_homeomorphism Homeomorphism of T;
end;
theorem :: TOPGRP_1:30
for f being Homeomorphism of T holds f/" is Homeomorphism of T;
theorem :: TOPGRP_1:31
for f, g being Homeomorphism of T holds f * g is Homeomorphism of T;
definition let T be non empty TopStruct;
func HomeoGroup T -> strict HGrStr means
:: TOPGRP_1:def 4
(x in the carrier of it iff x is Homeomorphism of T) &
for f, g being Homeomorphism of T holds (the mult of it).(f,g) = g * f;
end;
definition let T be non empty TopStruct;
cluster HomeoGroup T -> non empty;
end;
theorem :: TOPGRP_1:32
for f, g being Homeomorphism of T
for a, b being Element of HomeoGroup T st f = a & g = b holds
a * b = g * f;
definition let T be non empty TopStruct;
cluster HomeoGroup T -> Group-like associative;
end;
theorem :: TOPGRP_1:33
id T = 1.HomeoGroup T;
theorem :: TOPGRP_1:34
for f being Homeomorphism of T
for a being Element of HomeoGroup T st f = a holds a" = f/";
definition let T be non empty TopStruct;
attr T is homogeneous means
:: TOPGRP_1:def 5
for p, q being Point of T ex f being Homeomorphism of T st f.p = q;
end;
definition
cluster trivial -> homogeneous (non empty TopStruct);
end;
definition
cluster strict trivial non empty TopSpace;
end;
theorem :: TOPGRP_1:35
for T being homogeneous (non empty TopSpace) st
ex p being Point of T st {p} is closed holds T is_T1;
theorem :: TOPGRP_1:36
for T being homogeneous (non empty TopSpace) st
ex p being Point of T st for A being Subset of T st A is open & p in A holds
ex B being Subset of T st p in B & B is open & Cl B c= A
holds T is_T3;
begin :: On the topological groups
definition
struct (HGrStr, TopStruct) TopGrStr
(# carrier -> set,
mult -> BinOp of the carrier,
topology -> Subset-Family of the carrier #);
end;
definition let A be non empty set,
R be BinOp of A,
T be Subset-Family of A;
cluster TopGrStr (#A, R, T#) -> non empty;
end;
definition let x be set,
R be BinOp of {x},
T be Subset-Family of {x};
cluster TopGrStr (#{x}, R, T#) -> trivial;
end;
definition
cluster trivial -> Group-like associative commutative (non empty HGrStr);
end;
definition let a be set;
cluster 1TopSp {a} -> trivial;
end;
definition
cluster strict non empty TopGrStr;
end;
definition
cluster strict TopSpace-like trivial (non empty TopGrStr);
end;
definition let G be Group-like associative (non empty TopGrStr);
redefine func inverse_op G -> map of G, G;
end;
definition let G be Group-like associative (non empty TopGrStr);
attr G is UnContinuous means
:: TOPGRP_1:def 6
inverse_op G is continuous;
end;
definition let G be TopSpace-like TopGrStr;
attr G is BinContinuous means
:: TOPGRP_1:def 7
for f being map of [:G,G:], G st f = the mult of G holds f is continuous;
end;
definition
cluster strict commutative trivial UnContinuous BinContinuous
(TopSpace-like Group-like associative (non empty TopGrStr));
end;
definition
mode TopGroup is TopSpace-like Group-like associative (non empty TopGrStr);
end;
definition
mode TopologicalGroup is UnContinuous BinContinuous TopGroup;
end;
theorem :: TOPGRP_1:37
for T being BinContinuous non empty (TopSpace-like TopGrStr),
a, b being Element of T,
W being a_neighborhood of a*b
ex A being open a_neighborhood of a, B being open a_neighborhood of b st
A*B c= W;
theorem :: TOPGRP_1:38
for T being TopSpace-like non empty TopGrStr st
(for a, b being Element of T,
W being a_neighborhood of a*b
ex A being a_neighborhood of a, B being a_neighborhood of b st A*B c= W)
holds T is BinContinuous;
theorem :: TOPGRP_1:39
for T being UnContinuous TopGroup,
a being Element of T,
W being a_neighborhood of a"
ex A being open a_neighborhood of a st A" c= W;
theorem :: TOPGRP_1:40
for T being TopGroup st
for a being Element of T,
W being a_neighborhood of a"
ex A being a_neighborhood of a st A" c= W holds
T is UnContinuous;
theorem :: TOPGRP_1:41
for T being TopologicalGroup, a, b being Element of T
for W being a_neighborhood of a*(b")
ex A being open a_neighborhood of a, B being open a_neighborhood of b st
A*(B") c= W;
theorem :: TOPGRP_1:42
for T being TopGroup st
for a, b being Element of T,
W being a_neighborhood of a*(b")
ex A being a_neighborhood of a, B being a_neighborhood of b st
A*(B") c= W holds
T is TopologicalGroup;
definition let G be BinContinuous non empty (TopSpace-like TopGrStr),
a be Element of G;
cluster a* -> continuous;
cluster *a -> continuous;
end;
theorem :: TOPGRP_1:43
for G being BinContinuous TopGroup,
a being Element of G holds
a* is Homeomorphism of G;
theorem :: TOPGRP_1:44
for G being BinContinuous TopGroup,
a being Element of G holds
*a is Homeomorphism of G;
definition let G be BinContinuous TopGroup,
a be Element of G;
redefine func a* -> Homeomorphism of G;
redefine func *a -> Homeomorphism of G;
end;
theorem :: TOPGRP_1:45
for G being UnContinuous TopGroup holds inverse_op G is Homeomorphism of G;
definition let G be UnContinuous TopGroup;
redefine func inverse_op G -> Homeomorphism of G;
end;
definition
cluster BinContinuous -> homogeneous TopGroup;
end;
theorem :: TOPGRP_1:46
for G being BinContinuous TopGroup, F being closed Subset of G,
a being Element of G holds F * a is closed;
theorem :: TOPGRP_1:47
for G being BinContinuous TopGroup, F being closed Subset of G,
a being Element of G holds a * F is closed;
definition let G be BinContinuous TopGroup,
F be closed Subset of G,
a be Element of G;
cluster F * a -> closed;
cluster a * F -> closed;
end;
theorem :: TOPGRP_1:48
for G being UnContinuous TopGroup, F being closed Subset of G
holds F" is closed;
definition let G be UnContinuous TopGroup,
F be closed Subset of G;
cluster F" -> closed;
end;
theorem :: TOPGRP_1:49
for G being BinContinuous TopGroup, O being open Subset of G,
a being Element of G holds O * a is open;
theorem :: TOPGRP_1:50
for G being BinContinuous TopGroup, O being open Subset of G,
a being Element of G holds a * O is open;
definition let G be BinContinuous TopGroup,
A be open Subset of G,
a be Element of G;
cluster A * a -> open;
cluster a * A -> open;
end;
theorem :: TOPGRP_1:51
for G being UnContinuous TopGroup, O being open Subset of G holds O" is open;
definition let G be UnContinuous TopGroup,
A be open Subset of G;
cluster A" -> open;
end;
theorem :: TOPGRP_1:52
for G being BinContinuous TopGroup, A, O being Subset of G st O is open
holds O * A is open;
theorem :: TOPGRP_1:53
for G being BinContinuous TopGroup, A, O being Subset of G st O is open
holds A * O is open;
definition let G be BinContinuous TopGroup,
A be open Subset of G,
B be Subset of G;
cluster A * B -> open;
cluster B * A -> open;
end;
theorem :: TOPGRP_1:54
for G being UnContinuous TopGroup,
a being Point of G, A being a_neighborhood of a
holds A" is a_neighborhood of a";
theorem :: TOPGRP_1:55
for G being TopologicalGroup, a being Point of G,
A being a_neighborhood of a*a"
ex B being open a_neighborhood of a st B*B" c= A;
theorem :: TOPGRP_1:56
for G being UnContinuous TopGroup, A being dense Subset of G holds
A" is dense;
definition let G be UnContinuous TopGroup,
A be dense Subset of G;
cluster A" -> dense;
end;
theorem :: TOPGRP_1:57
for G being BinContinuous TopGroup, A being dense Subset of G,
a being Point of G holds a*A is dense;
theorem :: TOPGRP_1:58
for G being BinContinuous TopGroup, A being dense Subset of G,
a being Point of G holds A*a is dense;
definition let G be BinContinuous TopGroup,
A be dense Subset of G,
a be Point of G;
cluster A * a -> dense;
cluster a * A -> dense;
end;
theorem :: TOPGRP_1:59
for G being TopologicalGroup, B being Basis of 1.G, M being dense Subset of
G
holds
{ V * x where V is Subset of G, x is Point of G: V in B & x in
M }
is Basis of G;
theorem :: TOPGRP_1:60
for G being TopologicalGroup holds G is_T3;
definition
cluster -> being_T3 TopologicalGroup;
end;
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