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

2025-06-29

1182: For Topological Space and Subset of Subspace, Closure of Subset on Subspace Is Contained in Closure of Subset on Base Space

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description/proof of that for topological space and subset of subspace, closure of subset on subspace is contained in closure of subset on base space

Topics


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 topological space and any subset of any subspace, the closure of the subset on the subspace is contained in the closure of the subset on the base space.

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:
T: { the topological spaces }
T: { the topological subspaces of T}
S: T
//

Statements:
STST, where ST is the closure of S on T and ST is the closure of S on T
//


2: Note


The equality does not necessarily hold.

For example, let T=R with the Euclidean topology, T=(1,1), and S=(1,1), then, ST=(1,1)[1,1]=ST.


3: Proof


Whole Strategy: Step 1: see that SSTT and STT is closed on T, and see that STSTTST.

Step 1:

SST.

As ST, SSTT.

As ST is closed on T, STT is closed on T, by the proposition that any subset on any topological subspace is closed if and only if there is a closed set on the base space whose intersection with the subspace is the subset.

As ST is the intersection of all the closed subsets of T that contain S, STSTT.

But STSTTST.


References


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

1181: For Continuous Map Between Topological Spaces, Image of Closure of Subset Is Contained in Closure of Image of Subset

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

description/proof of that for continuous map between topological spaces, image of closure of subset is contained in closure of image of subset

Topics


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 continuous map between any topological spaces, the image of the closure of any subset of the domain is contained in the closure of the image of the subset.

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 }
f: :T1T2, { the continuous maps }
S1: T1
//

Statements:
f(S1)f(S1)
//


2: Proof


Whole Strategy: Step 1: let pS1 be any and see that pS1 or pS1S1; Step 2: when pS1, see that f(p)f(S1)f(S1); Step 3: when pS1S1, see that f(p)f(S1).

Step 1:

Let pS1 be any.

pS1 or pS1S1.

Step 2:

Let us suppose that pS1.

f(p)f(S1)f(S1).

Step 3:

Let us suppose that pS1S1.

That means that p is an accumulation point of S1, by the proposition that the closure of any subset is the union of the subset and the accumulation points set of the subset.

f(p)f(S1) (which is possible because f is not supposed to be injective) or f(p)f(S1).

When f(p)f(S1), f(p)f(S1)f(S1).

Let us suppose that f(p)f(S1) hereafter.

Let any open neighborhood of f(p) be Uf(p)T2.

As f is continuous, f1(Uf(p))T1 is open, and contains p, so, is an open neighborhood of p.

As p is an accumulation point of S1, there is a point, pf1(Uf(p))S1.

f(p)Uf(p)f(S1), which implies that f(p) is an accumulation point of f(S1).

So, f(p)f(S1), by the proposition that the closure of any subset is the union of the subset and the accumulation points set of the subset.

So, f(p)f(S1) anyway.


3: Note


If f is a homeomorphism, f(S1)=f(S1), because f1 is a continuous map and f1(f(S1))=S1, and so, f1(f(S1))f1(f(S1))=S1, and so, f(f1(f(S1)))=f(S1)f(S1).


References


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

1180: For Net with Directed Index Set on Subset of Topological Space That Converges on Space, Convergence Is on Closure of Subset

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

description/proof of that for net with directed index set on subset of topological space that converges on space, convergence is on closure of subset

Topics


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 net with directed index set on any subset of any topological space that converges on the space, the convergence is on the closure of the subset.

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:
T: { the topological spaces }
S: T
D: { the directed index sets }
N: :DT, N(D)S
p: T
//

Statements:
N converges to p

pS.
//


2: Proof


Whole Strategy: Step 1: suppose that pS and find a contradiction.

Step 1:

Let us suppose that N converges to p.

Let us suppose that pS.

By a local characterization of closure: any point on any topological space is on the closure of any subset if and only if its every neighborhood intersects the subset, there would be a neighborhood of p, NpT, such that NpS=.

But there would be an index, j0D, such that N(j)Np for every jD such that j0j, but N(j)S, which would mean that NpS, a contradiction.

So, pS.


References


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

1179: For Disjoint Union Topological Space, Closure of Disjoint Union of Subsets Is Disjoint Union of Closures of Subsets

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

description/proof of that for disjoint union topological space, closure of disjoint union of subsets is disjoint union of closures of subsets

Topics


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 disjoint union topological space, the closure of the disjoint union of any subsets is the disjoint union of the closures of the subsets.

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:
J: { the possibly uncountable index sets }
{Tj|jJ}: Tj{ the topological spaces }
T: =jJTj
{SjTj|jJ}:
//

Statements:
jJSj=jJSj, where the 1st overline is the closure on T and the 2nd overline is the closure on Tj
//


2: Proof


Whole Strategy: Step 1: see that jJSjjJSj; Step 2: see that jJSjjJSj.

Step 1:

jJSjjJSj, and the right hand side is closed on T, by the definition of disjoint union topology.

So, jJSjjJSj, by the definition of closure of subset of topological space.

Step 2:

Let pjJSj be any.

pSj for a j.

Let UpT be any open neighborhood of p.

UpTj is open on Tj, by the definition of disjoint union topology, and pUpTj.

So, UpTj is an open neighborhood of p on Tj.

UpTjSj, because pSj, by the proposition that the closure of any subset is the union of the subset and the accumulation points set of the subset.

So, UpjJSj.

So, pjJSj, by the proposition that the closure of any subset is the union of the subset and the accumulation points set of the subset.

So, jJSjjJSj.

So, αASα=αASα.


References


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

1178: For Topological Space and Subset of Subspace, if Subspace Is Closed, Closure of Subset on Subspace Is Closure on Base Space

<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 space and subset of subspace, if subspace is closed, closure of subset on subspace is closure on base space

Topics


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 topological space and any subset of any subspace, if the subspace is closed on the base space, the closure of the subset on the subspace is the closure of the subset on the base space.

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:
T: { the topological spaces }
T: { the topological subspaces of T}
S: T
//

Statements:
T{ the closed subspaces of T}

ST=ST, where ST is the closure of S on T and ST is the closure of S on T
//


2: Proof


Whole Strategy: Step 1: see that ST=STT; Step 2: see that ST=ST.

Step 1:

ST=STT, by the proposition that for any topological space and any subset of any subspace, the closure of the subset on the subspace is the intersection of the closure of the subset on the base space and the subspace.

STT is closed on T as an intersection of closed subsets.

Step 2:

ST=ST, by the proposition that for any topological space and any subset of any subspace, if the closure of the subset on the subspace is closed on the base space, the closure is the closure of the subset on the base space.


References


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

1177: For Topological Space and Subset of Subspace, Closure of Subset on Subspace Is Intersection of Closure of Subset on Base Space and Subspace

<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 space and subset of subspace, closure of subset on subspace is intersection of closure of subset on base space and subspace

Topics


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 topological space and any subset of any subspace, the closure of the subset on the subspace is the intersection of the closure of the subset on the base space and the subspace.

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:
T: { the topological spaces }
T: { the topological subspaces of T}
S: T
//

Statements:
ST=STT, where ST is the closure of S on T and ST is the closure of S on T
//


2: Proof


Whole Strategy: Step 1: see that ST=jJCj where {Cj|jJ} is the set of the closed subsets of T that contain S; Step 2: see that STT=jJCjT is the intersection of the closed subsets of T that contain S.

Step 1:

ST is the intersection of the closed subsets of T that contain S.

So, letting {Cj|jJ} be the set of the closed subsets of T that contain S where J is a possibly uncountable index set, ST=jJCj.

Step 2:

STT=(jJCj)T=jJ(CjT).

CjT is a closed subset of T by the definition of subspace topology and SCjT, and any closed subset of T that contains S, C, appears as C=CjT for a j, because there is a closed subset of T, CT, such that C=CT, but SCC, so, C is a closed subset of T that contains S, so, C=Cj for a j.

So, jJ(CjT) is the intersection of all the closed subsets of T that contain S, which is ST.

So, ST=STT.


References


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

1176: For Topological Space and Subset of Subspace, if Its Closure on Subspace Is Closed on Base Space, the Closure Is Closure on Base Space

<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 space and subset of subspace, if its closure on subspace is closed on base space, the closure is closure on base space

Topics


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 topological space and any subset of any subspace, if the closure of the subset on the subspace is closed on the base space, the closure is the closure of the subset on the base space.

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:
T: { the topological spaces }
T: { the topological subspaces of T}
S: T
//

Statements:
ST{ the closed subsets of T}, where ST denotes the closure of S on T

ST=ST, where ST denotes the closure of S on T
//


2: Proof


Whole Strategy: Step 1: see that STST; Step 2: see that STST; Step 3: conclude the proposition.

Step 1:

STST, because ST is the smallest closed subset of T that (the closed subset) contains S while ST is a closed subset of T that (the closed subset) contains S, by the supposition.

Step 2:

SSTT, which is closed on T, so, STSTT, because ST is the smallest closed subset of T that (the closed subset) contains S while STT is a closed subset of T that (the closed subset) contains S, so, STST.

Step 3:

So, ST=ST.


References


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

1175: For Topological Space, if Intersection of Subset and Open Subset Is Closed on Open Subset Subspace, Intersection Equals Intersection of Closure of Subset and Open Subset

<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 space, if intersection of subset and open subset is closed on open subset subspace, intersection equals intersection of closure of subset and open subset

Topics


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 topological space, any subset, and any open subset, if the intersection of the subset and the open subset is closed on the open subset subspace, the intersection equals the intersection of the closure of the subset and the open subset.

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:
T: { the topological spaces }
S: T
U: { the open subsets of T} with the subspace topology
//

Statements:
SU{ the closed subsets of U}

SU=SU, where S is the closure of S on T
//


2: Proof


Whole Strategy: Step 1: see that SU=SUU; Step 2: see that SUSUSU; Step 3: see that SUSUSUU.

Step 1:

There is a closed subset, CT, such that SU=CU, by the definition of subspace topology.

SUC and SUC where the closure is on T, because the closure is the smallest closed subset that contains the concerned subset.

Then, C can be taken to be SU, which is a closed subset of T, contains SU, so, the replacement does not lose any point on SU, and is contained in C, so the replacement does not add any extra point. So, SU=SUU.

Step 2:

On the other hand, SUSUSU, by the proposition that for any topological space, the intersection of the closure of any subset and any open subset is contained in the closure of the intersection of the subset and the open subset.

Step 3:

By taking the intersection of it with U, SUU=SUSUU=SUSUU. But as the 1st term and the last term equal, the middle term equals them, so, SU=SU.


3: Note


U has to be open for this proposition: for example, if U is not open, here is a counterexample: T=R with the Euclidean topology, U=[0,1], and S=(1,0), then SU=, closed, but SU=[1,0][0,1]={0}. Such a counterexample does not work for when U is open, because if U=(0,1), SU=(1,0)(0,1)= and SU=[1,0](0,1)=, and if U=(p,1) for any 0<p<1, SU=(1,0)(p,1)=(p,0), which is not closed.


References


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

2025-06-22

1174: For Topological Space, Closure of Intersection of Subsets Is Contained in Intersection of Closures of Subsets

<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 space, closure of intersection of subsets is contained in intersection of closures of subsets

Topics


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 topological space, the closure of the intersection of any subsets is contained in the intersection of the closures of the subsets.

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:
T: { the topological spaces }
J: { the possibly uncountable index sets }
{SjT|jJ}:
//

Statements:
jJSjjJSj
//


2: Note


Equality does not necessarily hold even if J is finite.

For example, let T=R with the Euclidean topology and {S1=(1,0),S2=(0,1)}, then, jJSj=(1,0)(0,1)==jJSj=(1,0)(0,1)=[1,0][0,1]={0}.


3: Proof


Whole Strategy: Step 1: see that jJSjjJSj and jJSj is closed.

Step 1:

As SjSj, jJSjjJSj.

jJSj is closed as an intersection of closed subsets.

So, jJSj is a closed subset that contains jJSj.

As jJSj is the intersection of all the closed subsets that contains jJSj, jJSjjJSj.


References


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

1173: C 1-Form Operated on C Vectors Field Along C Curve Is C Function over Domain of Curve

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

description/proof of that C 1-Form operated on C vector field along C curve is C function over domain of curve

Topics


About: C manifold

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 C manifold with boundary and any C curve on it, any C 1-form operated on any C vector field along the curve is a C function over the domain of the curve.

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 }
I: =(s1,s2)R as the open submanifold of the Euclidean C manifold
λ: :IM, { the C curves }
V: :Iλ(I)TM, { the C vectors fields along λ}
t: :MT10(TM), { the C1 -forms }
//

Statements:
t(V):IR{ the C maps }
//


2: Proof


For each sI, let us take a chart, (Uλ(s)M,ϕλ(s)), and the induced chart, (π1(Uλ(s))TM,ϕλ(s)~).

As λ is continuous, there is an open neighborhood of s, UsI, such that λ(Us)Uλ(s).

Over Us, V(λ(s))=Vj(λ(s))/xj, where Vj(λ(s)) s are C as some functions of s, because V is C.

t(V(λ(s)))=t(Vj(λ(s))/xj)=Vj(λ(s))t(/xj), but as /xj is a C vectors field over Uλ(s), t(/xj) is a C function over Uλ(s), by the proposition that any (0,q)-tensors field over C manifold with boundary is C if and only if the operation result on any C vectors fields is C, and Vj(λ(s))t(/xj)=Vj(λ(s))(t(/xj))(λ(s)), and (t(/xj))(λ(s)) is a C function of s because λ is C, so, t(V(λ(s))) is a C function of s.


References


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

1172: For C Manifold with Boundary, Wedge Product of C Forms Is C Form

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

description/proof of that for C manifold with boundary, wedge product of C forms is C form

Topics


About: C manifold

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 C manifold with boundary, the wedge product of any C forms is a C form.

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 }
f1: :MΛq1(TM), { the Cq1 -forms }
f2: :MΛq2(TM), { the Cq2 -forms }
//

Statements:
f1f2{ the C(q1+q2) -forms }
//


2: Proof


Whole Strategy: Step 1: apply the proposition that any q-form over any C manifold with boundary is C if and only if the operation result on any C vectors fields is C.

Step 1:

No matter whether f1f2 is regarded to be :MTq10(TM) or :MΛq1(TM), the proposition that any q-form over any C manifold with boundary is C if and only if the operation result on any C vectors fields is C can be applied.

Let V1:MTM,...,Vq1+q2:MTM be any C vectors fields.

f1f2(V1,...,Vq1+q2)=(q1+q2)!/(q1!q2!)Asym(f1f2)(V1,...,Vq1+q2)=(q1+q2)!/(q1!q2!)1/(q1+q2)!σ(f1f2)(Vσ1,...,Vσq1+q2)=1/(q1!q2!)σ(f1(Vσ1,...,Vσq1)f2(Vσq1+1,...,Vσq1+q2), but each f1(Vσ1,...,Vσq1) and f2(Vσq1+1,...,Vσq1+q2) are C, by the proposition that any q-form over any C manifold with boundary is C if and only if the operation result on any C vectors fields is C.

So, f1f2(V1,...,Vq1+q2) is C.


References


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

1171: q-Form over C Manifold with Boundary Is C iff Operation Result on Any C Vectors Fields Is C

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

description/proof of that q-form over C manifold with boundary is C iff operation result on any C vectors fields is C

Topics


About: C manifold

The table of contents of this article


Starting Context



Target Context


  • The reader will have a description and a proof of the proposition that any q-form over any C manifold with boundary is C if and only if the operation result on any C vectors fields is C.

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 }
q: N{0}
(Tq0(TM),M,π): =(0,q) -tensors bundle over M
(Λq(TM),M,π): =q -covectors bundle over M
f: :MTq0(TM) such that Ran(f)Λq(TM) or :MΛq(TM), { the sections of π}
//

Statements:
f{ the C maps }

V1,...,Vq{ the C vectors fields over M}(f(V1,...,Vq):MR{ the C maps })
//


2: Proof


Whole Strategy: Step 1: when :MTq0(TM), see that the proposition holds; Step 2: suppose that :MΛq(TM); Step 3: suppose that f(V1,...,Vq){ the C maps }, and see that f is C, by taking an r-r-open-balls charts pair or an r-r-open-half-balls charts pair around each mM, (UmM,ϕm) and (UmM,ϕm), and the induced chart, (π1(Um)Λq(TM),ϕm~), and seeing that the components function of f is C; Step 4: suppose that f is C, and see that f(V1,...,Vq) is C over a chart, (UmM,ϕm), around each mM.

Step 1:

When f is :MTq0(TM), f is really just a special type of (0,q)-tensors field, so, the proposition that any (0,q)-tensors field over C manifold with boundary is C if and only if the operation result on any C vectors fields is C applies.

Step 2:

Let us suppose that f is :MΛq(TM).

Step 3:

Let us suppose that f(V1,...,Vq){ the C maps }.

Let mM be any.

Let us take any r-r-open-balls charts pair or any r-r-open-half-balls charts pair around m, (UmM,ϕm) and (UmM,ϕm), which is possible by the proposition that for any C manifold with boundary, each interior point has an r-r-open-balls charts pair and each boundary point has an r-r-open-half-balls charts pair for any positive r and r, and take the induced chart, (π1(Um)Λq(TM),ϕm~).

Let us take Vj=Vjlj/xlj over Um as Vjlj1 and Vjlj0 for each ljlj where l1<...<lq. Vj is C over Um. Vj is C over UmUm. By the proposition that for any C vectors bundle, any C section along any closed subset of the base space can be extended to over the whole base space with the support contained in any open neighborhood of the subset, Vj is extended to over M. The extended Vj equals the original Vj over Um especially over Um.

Let mUm be any.

f(m)=j1<...<jqfj1,...,jq(m)dxj1...dxjq.

f(m)(V1,...,Vq)=j1<...<jqfj1,...,jq(m)dxj1...dxjq(V1l1/xl1,...,Vqlq/xlq)=j1<...<jqfj1,...,jq(m)q!Asymdxj1...dxjq(V1l1/xl1,...,Vqlq/xlq)=j1<...<jqfj1,...,jq(m)q!1/q!σP{1,...,q}sgnσdxj1...dxjq(Vσ1lσ1/xlσ1,...,Vσqlσq/xlσq)=j1<...<jqfj1,...,jq(m)σP{1,...,q}sgnσdxj1(Vσ1lσ1/xlσ1)...dxjq(Vσqlσq/xlσq)=j1<...<jqfj1,...,jq(m)σP{1,...,q}sgnσVσ1lσ1δlσ1j1...Vσqlσqδlσqjq=j1<...<jqfj1,...,jq(m)σP{1,...,q}sgnσVσ1j1...Vσqjq=j1<...<jqfj1,...,jq(m)σP{1,...,q}sgnσV1jσ1(1)...Vqjσ1(q): Vσ1j1...Vσqjq is reordered to V1m1...Vqmq, then, Vσnjn=Vsms, which means that σn=s, so, n=σ1(s).

V1jσ1(1)...Vqjσ1(q) can be nonzero only for σ=id, because l1<...<lq.

So, =j1<...<jqfj1,...,jq(m)V1j1...Vqjq=fl1,...,lq(m).

f(V1,...,Vq):UmR is C by the supposition, so, fl1,...,lq:UmR is C.

So, each fj1,...,jq is C over Um, which means that the components function of f with respect to (UmM,ϕm) and (π1(Um)Λq(TM),ϕm~), ϕm~fϕm1 whose components are fj1,...,jqϕm1 s, is C.

So, f is C.

Step 4:

Let us suppose that f is C.

Let mM be any.

Let us take any chart around m, (UmM,ϕm), and the induced chart, (π1(Um)Λq(TM),ϕm~).

Over Um, f=fj1,...,jqdxj1...dxjq, where fj1,...,jq:UmR is C, because it is a component of ϕm~fϕm1ϕm, while the components function of f with respect to (UmM,ϕm) and (π1(Um)Λq(TM),ϕm~), ϕm~fϕm1, is C and ϕm is C.

Vj=Vjlj/xlj, where Vjlj:UmR is C.

f(V1,...,Vq)=j1<...<jqfj1,...,jqdxj1...dxjq(V1l1/xl1,...,Vqlq/xlq)=j1<...<jqfj1,...,jq(m)σP{1,...,q}sgnσVσ1j1...Vσqjq as before, which is C.

As f(V1,...,Vq) is C over a neighborhood of each mM, f(V1,...,Vq) is C over M.


References


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