Showing posts with label Definitions and Propositions. Show all posts
Showing posts with label Definitions and Propositions. Show all posts

2025-07-13

1205: Determinant of Finite-Dimensional Vectors Space Endomorphism

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definition of determinant of finite-dimensional vectors space endomorphism

Topics


About: vectors space

The table of contents of this article


Starting Context



Target Context


  • The reader will have a definition of determinant of finite-dimensional vectors space endomorphism.

Orientation


There is a list of definitions discussed so far in this site.

There is a list of propositions discussed so far in this site.


Main Body


1: Structured Description


Here is the rules of Structured Description.

Entities:
F: { the fields }
V: { the finite-dimensional F vectors spaces }
f: :VV, { the F vectors space endomorphisms }
B: { the bases of V}
Mf,B: = the matrix for f with respect to B
det(f): =det(Mf,B)
//

Conditions:
//


2: Note


The point is that det(f) does not depend on the choice of B, which is the reason why this definition is well-defined: for any vector, vV, letting the components representation with respect to B of v be v~, the components representation with respect to another basis, B, of v, is Uv~ where U is an invertible matrix; the components representation with respect to B of f(v) is UMf,Bv~=UMf,BU1Uv~, which means that the matrix for f with respect to B is Mf,B:=UMf,BU1; then, det(Mf,B)=det(UMf,BU1)=det(U)det(Mf,B)det(U1)=det(U)det(Mf,B)det(U)1=det(Mf,B).

So, talking about the determinant of any finite-dimensional vectors space endomorphism makes sense, without specifying any basis.

This definition makes sense because f is an endomorphism, instead of just a linear map between 2 different vectors spaces: for the between-2-different-vectors-spaces case, the basis of the codomain is inevitably different from the basis of the domain (in fact, there is no canonical sameness between 2 elements in 2 different vectors spaces), and by changing the basis of the codomain, the determinant of the corresponding matrix can change: for example, make all the elements of the codomain basis half-lengthed, then, the matrix will be the double, and the determinant will be 2d times where d is the dimension.


References


<The previous article in this series | The table of contents of this series |

1204: Rough q-Form over C Manifold with Boundary

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definition of rough q-form over C manifold with boundary

Topics


About: C manifold

The table of contents of this article


Starting Context



Target Context


  • The reader will have a definition of rough q-form over C manifold with boundary.

Orientation


There is a list of definitions discussed so far in this site.

There is a list of propositions discussed so far in this site.


Main Body


1: Structured Description


Here is the rules of Structured Description.

Entities:
M: { the d -dimensional C manifolds with boundary }
q: N
(Tq0(TM),M,π): = the C(0,q) -tensors bundle over M
(Λq(TM),M,π): = the Cq -covectors bundle over M
f: :MTq0(TM) such that Ran(f)Λq(TM) or :MΛq(TM), { the rough sections }
//

Conditions:
//


2: Note


As Description says, "rough q-form" may mean :MTq0(TM) such that Ran(f)Λq(TM) or mean :MΛq(TM), whose difference should not matter in most cases: Λq(TM) is an embedded submanifold with boundary of Tq0(TM).

Usually, we need only (non-rough) forms, but we sometimes need to talk about a rough form in order to 1st introduce a may-be-rough form and then prove that it is really a non-rough form.


References


<The previous article in this series | The table of contents of this series | The next article in this series>

1203: Rough (p,q)-Tensors Field over C Manifold with Boundary

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definition of rough (p,q)-tensors field over C manifold with boundary

Topics


About: C manifold

The table of contents of this article


Starting Context



Target Context


  • The reader will have a definition of rough (p,q)-tensors field over C manifold with boundary.

Orientation


There is a list of definitions discussed so far in this site.

There is a list of propositions discussed so far in this site.


Main Body


1: Structured Description


Here is the rules of Structured Description.

Entities:
M: { the C manifolds with boundary }
p: N
q: N
(Tqp(TM),M,π): = the C(p,q) -tensors bundle over M
f: :MTqp(TM), { the rough sections of π}
//

Conditions:
//


References


<The previous article in this series | The table of contents of this series | The next article in this series>

1202: Rough Vectors Field over C Manifold with Boundary

<The previous article in this series | The table of contents of this series | The next article in this series>

definition of rough vectors field over C manifold with boundary

Topics


About: C manifold

The table of contents of this article


Starting Context



Target Context


  • The reader will have a definition of rough vectors field over C manifold with boundary.

Orientation


There is a list of definitions discussed so far in this site.

There is a list of propositions discussed so far in this site.


Main Body


1: Structured Description


Here is the rules of Structured Description.

Entities:
M: { the C manifolds with boundary }
(TM,M,π): = the tangent vectors bundle over M
V: :MTM
//

Conditions:
V{ the rough sections of π}
//


2: Note


As π is a continuous surjection (in fact, C), the definition is well-defined.

Usually, we need only (non-rough) vectors fields, but we sometimes need to talk about a rough vectors field in order to 1st introduce a may-be-rough vectors field and then prove that it is really a non-rough vectors field.


References


<The previous article in this series | The table of contents of this series | The next article in this series>

1201: Rough Section of Continuous Surjection

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definition of rough section of continuous surjection

Topics


About: topological space

The table of contents of this article


Starting Context



Target Context


  • The reader will have a definition of rough section of continuous surjection.

Orientation


There is a list of definitions discussed so far in this site.

There is a list of propositions discussed so far in this site.


Main Body


1: Structured Description


Here is the rules of Structured Description.

Entities:
T1: { the topological spaces }
T2: { the topological spaces }
π: :T1T2, { the continuous surjections }
s: :T2T1
//

Conditions:
πs:T2T2=id
//

s is called "rough section of π".


3: Note


π needs to be surjective, because otherwise, there would be a tT2 that would not be mapped under π to, and then, πs(t)=t would be impossible whatever s we chose, which means that πs=id would be impossible.

Usually, we need only (non-rough) sections, but we sometimes need to talk about a rough section in order to 1st introduce a may-be-rough section and then prove that it is really a non-rough section.


References


<The previous article in this series | The table of contents of this series | The next article in this series>

1200: For Group, This Set of Subsets Constitutes Topological Basis Constituting Topological Group with This as Neighborhoods Basis at Point

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description/proof of that for group, this set of subsets constitutes topological basis constituting topological group with this as neighborhoods basis at point

Topics


About: topological group

The table of contents of this article


Starting Context



Target Context


  • The reader will have a description and a proof of the proposition that for any group, this set of subsets constitutes a topological basis constituting a topological group with this as a neighborhoods basis at each point.

Orientation


There is a list of definitions discussed so far in this site.

There is a list of propositions discussed so far in this site.


Main Body


1: Structured Description


Here is the rules of Structured Description.

Entities:
G: { the groups }
B1: Pow(G), with the properties specified below
B: =gGgB1
B: =gGB1g
//

Statements:
(
0) B1S1B1(1S1)

1) gG such that g1(S1B1(gS1))

2) S1,S1B1(S1B1(S1S1S1))

3) S1B1(S1B1(S11S1S1))

4) S1B1,gG(S1B1(S1gS1g1))

5) S1B1,sS1(S1B1(S1sS1))
)

(
(
B{ the topological bases for G}

G{ the topological groups with B}

gG(gB{ the neighborhoods bases at g on G})
)

(
B{ the topological bases for G}

G{ the topological groups with B}

gG(Bg{ the neighborhoods bases at g on G})
)
)
//


2: Proof


Whole Strategy: Step 1: see that B satisfies one of some criteria for any collection of open sets to be a basis; Step 2: see that gB1 is a neighborhoods basis at g; Step 3: see that the group operations of G are continuous; Step 4: see that G is Hausdorff; Step 5: see that B satisfies one of some criteria for any collection of open sets to be a basis; Step 6: see that B1g is a neighborhoods basis at g; Step 7: see that the group operations of G are continuous; Step 8: see that G is Hausdorff.

Step 1:

Let us see that B satisfies Description 2 of some criteria for any collection of open sets to be a basis.

1) G=B (refer to the definition of union of set)?

1B, because B1B, so, B1B, there is an S1B1 such that 1S1, S1B1, and 1S1B1B.

For each gG, gB, because gB1B, so, gB1B, as there is an S1B1 such that 1S1, ggS1gB1, gS1gB1, and ggS1gB1B.

So, 1) holds.

2) for each sets, Sj,SlB, and each point, gSjSl, there is a set, SmB, such that gSmSjSl?

Let SjgjB1, SlglB1, and SmgmB1.

Sj=gjS1,j and Sl=gjS1,l where S1,j,S1,lB1.

As ggjS1,j, gj1gS1,j; gl1gS1,l, likewise.

By 5), there is an S1,jB1 such that S1,jgj1gS1,j; there is an S1,lB1 such that S1,lgl1gS1,l, likewise.

S1,jS1,jg1gj and S1,lS1,lg1gl.

By 4), there is an S1,jB1 such that S1,jg1gjS1,jgj1g; there is an S1,lB1 such that S1,lg1glS1,lgl1g, likewise.

So, S1,jg1gjS1,jg1gjgj1g=g1gjS1,j, so, gS1,jgg1gjS1,j=gjS1,j; gS1,lglS1,l, likewise.

By 2), there is an S1B1 such that S1S1,jS1,l.

So, gS1g(S1,jS1,l)=(gS1,j)(gS1,l)gjS1,jglS1,l=SjSl.

ggS1, because 1S1.

So, gS1=Sm will do.

So, G with B is a topological space, by the proposition that any basis of any topological space determines the topology.

Step 2:

Let us see that gB1 is a neighborhoods basis at g.

Let Ng be any neighborhood of g.

There is a gS1B such that ggS1Ng: the point is that g is not guaranteed to be taken to be g, yet.

g1gS1. So, there is an S1B1 such that S1g1gS1, by 5).

S1g1g=g1gg1gS1g1g.

There is an S1B1 such that S1g1gS1g1g, by 4). So, g1gS1g1gg1gS1g1g=S1g1gS1.

So, gg1gS1gS1, but gg1gS1=gS1, so, ggS1gS1Ng.

Step 3:

Let us see that the group operations of G are continuous.

Let us deal with the inverse map.

Let Ng1G be any neighborhood of g1.

There is a g1S1B such that g1g1S1Ng1.

There is an S1B1 such that S1g1S1g, by 4).

So, S1g1g1S1.

There is an S1B1 such that S11S1S1, by 3).

S11S1g1S1g1.

But S11S1g1=(gS11S1)1 and S1S11S1, so, (gS1)1S1g1g1S1Ng1.

The inverse map is a bijection and its inverse is itself, so, the inverse map is a homeomorphism.

Let us deal with the multiplication map.

Let Ng1g2G be any neighborhood of g1g2.

There is a g1g2S1B such that g1g2g1g2S1Ng1g2.

g1g2S1=g1g2S1g21g2.

There is an S1B1 such that S1g2S1g21, by 4), so, g1S1g2g1g2S1g21g2=g1g2S1.

There is an S1B1 such that S11S1S1, by 3), so, g1S11S1g2g1S1g2g1g2S1.

But as the inverse map is a homeomorphism, S11 is an open neighborhood of 1, so, there is an S1B1 such that S1S11, so, g1S1S1g2g1S11S1g2.

g1S1S1g2=g1S1g2g21S1g2.

There is an S1B1 such that S1g21S1g2, by 4), so, g1S1g2S1g1S1S1g2.

So, g1S1g2S1g1S1S1g2g1S11S1g2g1g2S1Ng1g2.

Step 4:

Let us see that G is Hausdorff.

Let g1,g2G be any such that g1g2.

g11g21, so, there is an S1B1 such that g11g2S1, by 1).

There is a symmetric neighborhood of 1, N1G, such that N12S1, by the proposition that for any group with any topology with any continuous operations (especially, topological group), any neighborhood of 1, and any positive natural number, there is a symmetric neighborhood of 1 whose power to the natural number is contained in the neighborhood.

Let us see that N1g11g2N1=.

Let us suppose that N1g11g2N1.

There would be an nN1g11g2N1.

n=g11g2n for an nN1.

g11g2=nn1. But as N1 is symmetric, n1N11=N1, so, g11g2N12S1, a contradiction against g11g2S1.

So, N1g11g2N1=.

There is an S1B1 such that S1N1, and S1g11g2S1N1g11g2N1=.

So, g1(S1g11g2S1)=g1S1g2S1=.

Step 5:

Let us see that B satisfies Description 2 of some criteria for any collection of open sets to be a basis.

1) G=B (refer to the definition of union of set)?

1B, because B1B, so, B1B, there is an S1B1 such that 1S1, S1B1, and 1S1B1B.

For each gG, gB, because B1gB, so, B1gB, as there is an S1B1 such that 1S1, gS1gB1g, S1gB1g, and gS1gB1gB.

So, 1) holds.

2) for each sets, Sj,SlB, and each point, gSjSl, there is a set, SmB, such that gSmSjSl?

Let SjB1gj, SlB1gl, and SmB1gm.

Sj=S1,jgj and Sl=S1,lgj where S1,j,S1,lB1.

As gS1,jgj, ggj1S1,j; ggl1S1,l, likewise.

By 5), there is an S1,jB1 such that S1,jggj1S1,j; there is an S1,lB1 such that S1,lggl1S1,l, likewise.

S1,jS1,jgjg1 and S1,lS1,lglg1.

So, S1,jgS1,jgjg1g=S1,jgj; S1,lgS1,lgl, likewise.

By 2), there is an S1B1 such that S1S1,jS1,l.

So, S1g(S1,jS1,l)g=(S1,jg)(S1,lg)(S1,jgj)(S1,lgl)=SjSl.

gS1g, because 1S1.

So, S1g=Sm will do.

So, G with B is a topological space, by the proposition that any basis of any topological space determines the topology.

Step 6:

Let us see that B1g is a neighborhoods basis at g.

Let Ng be any neighborhood of g.

There is a S1gB such that gS1gNg: the point is that g is not guaranteed to be taken to be g, yet.

gg1S1. So, there is an S1B1 such that S1gg1S1, by 5).

So, S1gg1gS1g, but S1gg1g=S1g, so, gS1gS1gNg.

Step 7:

Let us see that the group operations of G are continuous.

Let us deal with the inverse map.

Let Ng1G be any neighborhood of g1.

There is a S1g1B such that g1S1g1Ng1.

There is an S1B1 such that S1gS1g1, by 4).

So, g1S1S1g1.

There is an S1B1 such that S11S1S1, by 3).

g1S11S1g1S1.

But g1S11S1=(S11S1g)1 and S1S11S1, so, (S1g)1g1S1S1g1Ng1.

The inverse map is a bijection and its inverse is itself, so, the inverse map is a homeomorphism.

Let us deal with the multiplication map.

Let Ng1g2G be any neighborhood of g1g2.

There is a S1g1g2B such that g1g2S1g1g2Ng1g2.

S1g1g2=g1g11S1g1g2.

There is an S1B1 such that S1g11S1g1, by 4), so, g1S1g2g1g11S1g1g2=S1g1g2.

There is an S1B1 such that S11S1S1, by 3), so, g1S11S1g2g1S1g2S1g1g2.

But as the inverse map is a homeomorphism, S11 is an open neighborhood of 1, so, there is an S1B1 such that S1S11, so, g1S1S1g2g1S11S1g2.

g1S1S1g2=g1S1g11g1S1g2.

There is an S1B1 such that S1g1S1g11, by 4), so, S1g1S1g2g1S1S1g2.

So, S1g1S1g2g1S1S1g2g1S11S1g2S1g1g2Ng1g2.

Step 8:

Let us see that G is Hausdorff.

Let g1,g2G be any such that g1g2.

g1g211, so, there is an S1B1 such that g1g21S1, by 1).

There is a symmetric neighborhood of 1, N1G, such that N12S1, by the proposition that for any group with any topology with any continuous operations (especially, topological group), any neighborhood of 1, and any positive natural number, there is a symmetric neighborhood of 1 whose power to the natural number is contained in the neighborhood.

Let us see that N1N1g1g21=.

Let us suppose that N1N1g1g21.

There would be an nN1N1g1g21.

n=ng1g21 for an nN1.

g1g21=n1n. But as N1 is symmetric, n1N11=N1, so, g1g21N12S1, a contradiction against g1g21S1.

So, N1N1g1g21=.

There is an S1B1 such that S1N1, and S1S1g1g21N1N1g1g21=.

So, (S1S1g1g21)g2=S1g2S1g1g21g2=S1g2S1g1=.


References


<The previous article in this series | The table of contents of this series | The next article in this series>

1199: For Topological Group, Closed Subset Is Intersection of Subset Multiplied by Elements of Neighborhoods Basis at 1

<The previous article in this series | The table of contents of this series | The next article in this series>

description/proof of that for topological group, closed subset is intersection of subset multiplied by elements of neighborhoods basis at 1

Topics


About: topological group

The table of contents of this article


Starting Context



Target Context


  • The reader will have a description and a proof of the proposition that for any topological group, any closed subset is the intersection of the subset multiplied by the elements of any neighborhoods basis at 1.

Orientation


There is a list of definitions discussed so far in this site.

There is a list of propositions discussed so far in this site.


Main Body


1: Structured Description


Here is the rules of Structured Description.

Entities:
G: { the topological groups }
B1: { the neighborhoods bases at 1 on G}
C: { the closed subsets of G}
//

Statements:
C=S1B1S1C=S1B1CS1
//


2: Proof


Whole Strategy: Step 1: see that CS1B1S1C; Step 2: see that S1B1S1CC, by seeing that for each gS1B1S1C, gC or g is an accumulation point of C; Step 3: see that CS1B1CS1; Step 4: see that S1B1CS1C, by seeing that for each gS1B1CS1, gC or g is an accumulation point of C.

Step 1:

Let us see that CS1B1S1C.

For each cC, for each S1B1, cS1C, because 1S1, so, cS1B1S1C.

Step 2:

Let us see that S1B1S1CC.

Let gS1B1S1C be any.

Let NgG be any neighborhood of g.

As gB1 is a neighborhood basis at g, by the proposition that for any topological group, any neighborhoods basis at 1 satisfies these properties and each point multiplied by the neighborhoods basis at 1 is a neighborhoods basis at the point, there is an S1B1 such that gS1Ng.

There is an S1B1 such that S1gS1g1, by 4) in the proposition that for any topological group, any neighborhoods basis at 1 satisfies these properties and each point multiplied by the neighborhoods basis at 1 is a neighborhoods basis at the point.

There is a symmetric neighborhood of 1, S1G, such that S1S1, by the proposition that for any group with any topology with any continuous operations (especially, topological group), the set of the symmetric neighborhoods of 1 is a neighborhood basis at 1.

So, S1gS1g1, so, S1ggS1g1g=gS1.

There is an S1B1 such that S1S1.

gS1CS1C, because gS1B1S1C.

That means that g=sc where sS1 and cC.

As S1ggS1, S1scgS1, but as S1 is symmetric, s1S1, so, c=s1scgS1Ng, which means that gC or g is an accumulation point of C, which means that g is in the closure of C, by the proposition that the closure of any subset is the union of the subset and the accumulation points set of the subset, so, gC.

But as C is closed, C=C, so, gC=C.

Step 3:

Let us see that CS1B1CS1.

As is expected, the logic is parallel to Step 1.

For each cC, for each S1B1, cCS1, because 1S1, so, cS1B1CS1.

Step 4:

Let us see that S1B1CS1C.

As is expected, the logic is parallel to Step 2, in fact, this is simpler: S1 is not necessary as it is introduced in order to deal with the S1C order.

Let gS1B1CS1 be any.

Let NgG be any neighborhood of g.

As gB1 is a neighborhood basis at g, by the proposition that for any topological group, any neighborhoods basis at 1 satisfies these properties and each point multiplied by the neighborhoods basis at 1 is a neighborhoods basis at the point, there is an S1B1 such that gS1Ng.

There is a symmetric neighborhood of 1, S1G, such that S1S1, by the proposition that for any group with any topology with any continuous operations (especially, topological group), the set of the symmetric neighborhoods of 1 is a neighborhood basis at 1.

There is an S1B1 such that S1S1.

gCS1CS1, because gS1B1CS1.

That means that g=cs where sS1 and cC.

As S1S1, gS1=csS1gS1, but as S1 is symmetric, s1S1, so, c=css1gS1Ng, which means that gC or g is an accumulation point of C, which means that g is in the closure of C, by the proposition that the closure of any subset is the union of the subset and the accumulation points set of the subset, so, gC.

But as C is closed, C=C, so, gC=C.


References


<The previous article in this series | The table of contents of this series | The next article in this series>

2025-07-06

1198: For Topological Group, Neighborhoods Basis at 1 Satisfies These Properties and Point Multiplied by Neighborhoods Basis at 1 Is Neighborhoods Basis at Point

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description/proof of that for topological group, neighborhoods basis at 1 satisfies these properties and point multiplied by neighborhoods basis at 1 is neighborhoods basis at point

Topics


About: topological group

The table of contents of this article


Starting Context



Target Context


  • The reader will have a description and a proof of the proposition that for any topological group, any neighborhoods basis at 1 satisfies these properties and each point multiplied by the neighborhoods basis at 1 is a neighborhoods basis at the point.

Orientation


There is a list of definitions discussed so far in this site.

There is a list of propositions discussed so far in this site.


Main Body


1: Structured Description


Here is the rules of Structured Description.

Entities:
G: { the topological groups }
B1: { the neighborhoods bases at 1 on G}
//

Statements:
1) gG such that g1(N1B1(gN1))

2) N1,N1B1(N1B1(N1N1N1))

3) N1B1(N1B1(N11N1N1))

4) N1B1,gG(N1B1(N1gN1g1))

5) N1B1,nN1 such that Un{ the open neighborhoods of n}(nUnN1)(N1B1(N1nN1))

gG(gB1{ the neighborhoods bases at g on G})

gG(B1g{ the neighborhoods bases at g on G})
//

gB1 means {gS1|S1B1}; B1g means {S1g|S1B1}.


2: Proof


Whole Strategy: use the Hausdorff-ness and the continuousness of the operations; Step 1: see that 1) holds; Step 2: see that 2) holds; Step 3: see that 3) holds; Step 4: see that 4) holds; Step 5: see that 5) holds; Step 6: see that gB1 is a neighborhoods basis at g; Step 7: see that B1g is a neighborhoods basis at g.

Step 1:

Let us see that 1) holds.

As G is Hausdorff, there is an open neighborhood of 1, U1G, and an open neighborhood of g, UgG, such that U1Ug=.

There is a N1B1 such that N1U1, by the definition of neighborhoods basis at point on topological space.

N1Ug=, so, gN1.

Step 2:

Let us see that 2) holds.

N1N1 is a neighborhood of 1, by the proposition that for any topological space and its any point, the intersection of any finite number of neighborhoods of the point is a neighborhood of the point.

So, there is a N1B1 such that N1N1N1, by the definition of neighborhoods basis at point on topological space.

Step 3:

Let us see that 3) holds.

There is a (symmetric) neighborhood of 1, N1G, such that N111N1N1, by the proposition that for any group with any topology with any continuous operations (especially, topological group), any element, and any neighborhood of the element, there is a symmetric neighborhood of 1 such that the element multiplied from left by the neighborhood of 1 and multiplied from right by the inverse of the neighborhood of 1 is contained in the neighborhood of the element: g in the proposition is taken to be 1 and N111N1=N11N11 because N1 is symmetric.

But N111N1=N11N1.

There is an N1B1 such that N1N1, by the definition of neighborhoods basis at point on topological space.

N11N11, by the proposition that for any group, the inverse of any subset is the image of the subset under the inverse map, and the double inverse of the subset is the subset.

So, N11N1N11N1.

So, N11N1N1.

Step 4:

Let us see that 4) holds.

The conjugation map by g, f:GG,gggg1, is a homeomorphism, by the proposition that for any group with any topology with any continuous operations (especially, topological group) and each element, the inversion map, the multiplication-by-element-from-left-or-right map, and the conjugation-by-element map are homeomorphisms.

1gN1g1, because 1N1 and g1g1=1.

So, gN1g1 is a neighborhood of 1: while N1 contains an open neighborhood of 1, U1, gN1g1=f(N1) contains f(U1), which is an open neighborhood of 1: f(1)=1.

So, there is an N1B1 such that N1gN1g1, by the definition of neighborhoods basis at point on topological space.

Step 5:

Let us see that 5) holds.

The multiplication-by-element-from-right map by n1, f:GG,ggn1, is a homeomorphism, by the proposition that for any group with any topology with any continuous operations (especially, topological group) and each element, the inversion map, the multiplication-by-element-from-left-or-right map, and the conjugation-by-element map are homeomorphisms.

1Unn1N1n1, because nUn and nn1=1.

So, N1n1 is a neighborhood of 1: N1n1=f(N1) contains Unn1=f(Un), which is an open neighborhood of 1.

So, there is an N1B1 such that N1N1n1, by the definition of neighborhoods basis at point on topological space.

So, N1nN1n1n=N1.

Step 6:

Let gG be any.

Let NgG be any neighborhood of g.

g1Ng is a neighborhood of 1, because while the multiplication-by-g1-from-left-map is a homeomorphism by the proposition that for any group with any topology with any continuous operations (especially, topological group) and each element, the inversion map, the multiplication-by-element-from-left-or-right map, and the conjugation-by-element map are homeomorphisms, an open neighborhood of g contained in Ng is mapped into g1Ng as an open neighborhood of 1.

So, there is an S1B1 such that 1S1g1Ng.

So, ggS1gg1Ng=Ng, while gS1 is a neighborhood of g, because while the multiplication-by-g-from-left-map is a homeomorphism by the proposition that for any group with any topology with any continuous operations (especially, topological group) and each element, the inversion map, the multiplication-by-element-from-left-or-right map, and the conjugation-by-element map are homeomorphisms, an open neighborhood of 1 contained in S1 is mapped into gS1 as an open neighborhood of g.

Step 7:

Let gG be any.

Let NgG be any neighborhood of g.

Ngg1 is a neighborhood of 1, because while the multiplication-by-g1-from-right-map is a homeomorphism by the proposition that for any group with any topology with any continuous operations (especially, topological group) and each element, the inversion map, the multiplication-by-element-from-left-or-right map, and the conjugation-by-element map are homeomorphisms, an open neighborhood of g contained in Ng is mapped into Ngg1 as an open neighborhood of 1.

So, there is an S1B1 such that 1S1Ngg1.

So, gS1gNgg1g=Ng, while S1g is a neighborhood of g, because while the multiplication-by-g-from-right-map is a homeomorphism by the proposition that for any group with any topology with any continuous operations (especially, topological group) and each element, the inversion map, the multiplication-by-element-from-left-or-right map, and the conjugation-by-element map are homeomorphisms, an open neighborhood of 1 contained in S1 is mapped into S1g as an open neighborhood of g.


References


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1197: For Group with Topology with Continuous Operations (Especially, Topological Group), Element, and Neighborhood of Element, There Is Symmetric Neighborhood of 1 s.t. Element Multiplied from Left by Neighborhood of 1 and Multiplied from Right by Inverse of Neighborhood of 1 Is Contained in Neighborhood of Element

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description/proof of that for group with topology with continuous operations (especially, topological group), element, and neighborhood of element, there is symmetric neighborhood of 1 s.t. element multiplied from left by neighborhood of 1 and multiplied from right by inverse of neighborhood of 1 is contained in neighborhood of element

Topics


About: group
About: topological space

The table of contents of this article


Starting Context



Target Context


  • The reader will have a description and a proof of the proposition that for any group with any topology with any continuous operations (especially, topological group), any element, and any neighborhood of the element, there is a symmetric neighborhood of 1 such that the element multiplied from left by the neighborhood of 1 and multiplied from right by the inverse of the neighborhood of 1 is contained in the neighborhood of the element.

Orientation


There is a list of definitions discussed so far in this site.

There is a list of propositions discussed so far in this site.


Main Body


1: Structured Description


Here is the rules of Structured Description.

Entities:
G: { the groups } with any topology such that the group operations are continuous
g: G
Ng: { the neighborhoods of g on G}
//

Statements:
N1{ the symmetric neighborhoods of 1 on G}(N1gN11Ng)
//


2: Proof


Whole Strategy: Step 1: think of the continuous f:G×GG,(g1,g2)g1gg2 and see that f((1,1))=g; Step 2: take an open neighborhood of (1,1), U(1,1), such that f(U(1,1))Ng and take an open neighborhood of 1, U1, such that U1×U1U(1,1); Step 3: take a symmetric neighborhood of 1, N1U1, and see that f(N1×N1)Ng and f(N1×N1)=N1gN11.

Step 1:

Let us think of f:G×GG,(g1,g2)g1gg2.

f is the composition of the maps, :G×GG×G,(g1,g2)(g1,gg2) and :G×GG,(g1,g2)g1g2.

The former is continuous, because :g2gg2 is continuous, by the proposition that for any group with any topology with any continuous operations (especially, topological group) and each element, the inversion map, the multiplication-by-element-from-left-or-right map, and the conjugation-by-element map are homeomorphisms, and so :G×GG×G,(g1,g2)(g1,gg2) is continuous, by the proposition that the product map of any finite number of continuous maps is continuous by the product topologies.

The latter is continuous, because it is the multiplication operation.

So, f is continuous as the composition of the continuous maps, by the proposition that for any maps between any arbitrary subspaces of any topological spaces continuous at any corresponding points, the composition is continuous at the point.

f((1,1))=1g1=g.

Step 2:

As f is continuous, there is an open neighborhood of (1,1), U(1,1)G×G, such that f(U(1,1))Ng.

By the definition of product topology, there is an open neighborhood of 1, U1G, such that U1×U1U(1,1): while there are some open neighborhoods of 1, U1,U1G, such that U1×U1U(1,1), we can take U1:=U1U1.

Step 3:

There is a symmetric neighborhood of 1, N1G, such that N1U1, by the proposition that for any topological group, the set of the symmetric neighborhoods of 1 is a neighborhood basis at 1.

As N1×N1U(1,1), f(N1×N1)f(U(1,1))Ng.

Let us see that f(N1×N1)=N1gN1.

For each gf(N1×N1), g=g1gg2 where g1,g2N1, so, gN1gN1; for each gN1gN1, g=g1gg2 where g1,g2N1, but g1gg2=f(g1,g2), so, gf(N1×N1).

But as N1 is symmetric, N1gN1=N1gN11.

So, N1gN11=f(N1×N1)Ng.


References


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