Is R mod 2pi a Compact Manifold?

In summary, R mod 2pi is a compact manifold because it is a circle with the topology of a line modulo the discrete group of integer multiples of 2pi. This topology can be shown to be compact by using the definition of open sets and a finite subcover. Additionally, the quotient topology agrees with the subspace topology of S^1, making R mod 2pi a manifold. This is a result of the quotients of manifolds by certain group actions being manifolds themselves.
  • #1
Bahram_phd
2
0
Hi,
Why R mod 2pi is a Compact Manifold?
Isn't this like a real line which is not compact?
How should we prove it using a finite sub-cover for this manifold?
bah
 
Physics news on Phys.org
  • #2
R mod 2pi doesn't look like the real line; it looks like the interval [0,2pi] except the end points are identified. (So it's a circle...)
 
  • #3
consider the map from R to the circle defined by t-->(cos(t), sin(t)).
 
  • #4
Bahram_phd said:
Hi,
Why R mod 2pi is a Compact Manifold?
Isn't this like a real line which is not compact?
How should we prove it using a finite sub-cover for this manifold?
bah

What is the topology that you want?
If it is R with the topology of a line modulo the discrete group of integer multiples of 2pi, then use the definition of open set in the quotient topology to show that every open cover has a finite subcover. You need to know that a closed interval is compact.
 
  • #5
lavinia said:
What is the topology that you want?
If it is R with the topology of a line modulo the discrete group of integer multiples of 2pi, then use the definition of open set in the quotient topology to show that every open cover has a finite subcover. You need to know that a closed interval is compact.

Isn't the quotient topology assumed when talking about a quotient?

It seems like the open sets here would be the sets (a,b); 0<a,b<2∏ , which lift to

the open sets U(a±2k∏, b± 2k∏ ); for k integer, in ℝ

Then, since compactness is hereditary, and this topology is smaller than the subspace topology in [0,2∏],

(which is a compact space), then the quotient is compact.

EDIT:
Correction: the quotient topology agrees with the subspace topology of S^1 in R^2. By, e.g., mathwonk's map f, which descends to

a homeo f^ between R/~ and S^1, subspace (since the map is constant in R/~) , and which can be shown to be continuous and onto.

Then, by homeo., R/~ is also compact. If you want an argument by subcovers, do the argument in S^1, and pull back to R/~ by the homeo f^
 
Last edited:
  • #6
Actually, to show the manifold part, there are results that the quotients of manifolds by some special types of group actions are themselves manifolds--you can, e.g., show that projective space is a manifold by using this result/theorem.
 
  • #7
Thanks guys,
It helped me a lot. I did some studies on quotient topology and now I have a better understanding of the problem.
 

1. What is a compact manifold?

A compact manifold is a topological space that is locally Euclidean and compact. This means that it can be covered by a finite number of open sets that are homeomorphic to Euclidean space, and that it is a closed and bounded space.

2. How does R mod 2pi relate to a compact manifold?

R mod 2pi is a quotient space that is formed by identifying points on a line that are separated by a distance of 2pi. This creates a circle, which is a common example of a compact manifold.

3. Is R mod 2pi the only compact manifold?

No, there are many other compact manifolds in different dimensions and shapes. Some examples include the sphere, torus, and projective space.

4. What are the characteristics of a compact manifold?

A compact manifold must be Hausdorff, meaning that any two distinct points have disjoint neighborhoods, and second countable, meaning that it has a countable basis for its topology. It must also be paracompact, meaning that its open cover has a locally finite refinement.

5. How is the compactness of a manifold useful in mathematics and science?

The compactness of a manifold allows for various mathematical techniques and theorems to be applied, such as the Brouwer fixed-point theorem and the Hahn-Banach theorem. It also has applications in physics, such as in the study of black holes and cosmology.

Similar threads

A Hilbert spaces and kets "over" manifolds
    • Differential Geometry
Replies
10
Views
2K
A A claim about smooth maps between smooth manifolds
    • Differential Geometry
Replies
20
Views
2K
I A set of numbers as a smooth curved changing manifold.
    • Differential Geometry
Replies
3
Views
2K
I Is There a Distinction Between Riemann Metrics in Physics?
    • Differential Geometry
Replies
16
Views
2K
A Questions about Covering maps, manifolds, compactness
    • Topology and Analysis
Replies
2
Views
2K
I Understanding Integration on an Orientable Manifold
    • Differential Geometry
Replies
1
Views
1K
Why Does a=dB Imply ∫a=0 on Compact Manifolds?
    • Differential Geometry
Replies
5
Views
3K
Is De Rham's first theorem applicable to non-compact manifolds?
    • Differential Geometry
Replies
2
Views
3K
I Are Coordinates on a Manifold Really Functions from R^n to R?
    • Differential Geometry
Replies
17
Views
3K
I Is the Set of Integer Outputs of sin(x) Sequentially Compact in ℝ?
    • Topology and Analysis
Replies
3
Views
826

Hot Threads

Recent Insights

Back
Top