Convergence of Measures and Metrizability: Difference between revisions

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This article should address metrizability for both narrow and wide convergence.
This article addresses narrow and wide convergence of probability measures.
 
==General Functional Analysis Refs==
*Ambrosio, Gigli, Savaré (107-108), Brezis (72-76)
 
==Narrow Convergence==
*Unit ball of dual space of <math>C_b(X)</math> is, in general, not metrizable: [[https://link-springer-com.proxy.library.ucsb.edu:9443/book/10.1007%2F978-1-4757-3828-5 Conway, ''A Course in Functional Analysis'', Theorem 6.6]]
*It is metrizable when restricted to probability measures: Ambrosio, Gigli, Savaré (106-108)
 
 
==Wide Convergence==
*On the other hand, if X is a metrizable locally compact space that is σ-compact, then <math>C_0(X)</math> is separable, [[https://link-springer-com.proxy.library.ucsb.edu:9443/book/10.1007%2F978-1-4757-3828-5 Conway, ''A Course in Functional Analysis'', III. Banach Spaces, exercise 14]]


==Weak-star Topologies==
==Weak-star Topologies==
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Although in general the topology of narrow convergence is not metrizable on the unit ball -- for example, on any compact Hausdorff space which is not metrizable -- it is on the class of probability measures, so long as <math>X</math> is separable. Take, again, a countable dense subset of <math>X</math>, <math>D</math>, and taking the family of functions <math>\mathcal C_2=\{h(x)=(q_1+q_2d(x,y))\wedge k\,|\, q_1,q_2,k\in\mathbb Q, q_2,k\in (0,1), y\in D\}</math>. Let <math>\mathcal C_1</math> be the family of functions generated by taking infima of finitely many elements of <math>\mathcal C_2</math>, and let <math>\mathcal C_0=\{\lambda h\,|\,\lambda\in\mathbb Q,h\in\mathcal C_1</math>. This is still countable, and approximates integrals of elements of <math>C_b</math> well weakly-star, so there is a metric on the probabilities by enumerating <math>\mathcal C_0=\{f_k\}_{k=1}^\infty</math>, and  
Although in general the topology of narrow convergence is not metrizable on the unit ball -- for example, on any compact Hausdorff space which is not metrizable -- it is on the class of probability measures, so long as <math>X</math> is separable. Take, again, a countable dense subset of <math>X</math>, <math>D</math>, and taking the family of functions <math>\mathcal C_2=\{h(x)=(q_1+q_2d(x,y))\wedge k\,|\, q_1,q_2,k\in\mathbb Q, q_2,k\in (0,1), y\in D\}</math>. Let <math>\mathcal C_1</math> be the family of functions generated by taking infima of finitely many elements of <math>\mathcal C_2</math>, and let <math>\mathcal C_0=\{\lambda h\,|\,\lambda\in\mathbb Q,h\in\mathcal C_1</math>. This is still countable, and approximates integrals of elements of <math>C_b</math> well weakly-star, so there is a metric on the probabilities by enumerating <math>\mathcal C_0=\{f_k\}_{k=1}^\infty</math>, and  
<math>d(\mu,\nu)=\sum_{k=1}^\infty 2^{-k}|\int f_k\,d\mu-\int f_k\,d\nu|.</math>
<math>d(\mu,\nu)=\sum_{k=1}^\infty 2^{-k}|\int f_k\,d\mu-\int f_k\,d\nu|.</math>
==Wide Convergence==
Wide convergence is the weak-star convergence with respect to elements of <math>C_0(X)</math> rather than <math>C_b(X)</math>. As such, it is a weaker topology on the class of probability measures. When <math>X</math> is a locally compact separable metric space (in particular, locally compact metric spaces which are <math>\sigma</math>-compact are separable), we can find a separating family of functions which form a countable subalgebra. One way to do this is by taking, for each point <math>x_n</math> in a countable dense subset, a compact neighborhood <math>K_n\ni x_n</math> and taking a partition of unity subordinate to that compact, <math>\varphi_n</math>. Taking the <math>\mathbb Q</math>-algebra generated by this countable family of functions will separate points, which will make it dense in <math>C_0(X)</math> by Stone-Weierstrass. So <math>C_0(X)</math> is separable, which means that the unit ball of the dual is metrizable.

Revision as of 01:01, 8 May 2020

This article addresses narrow and wide convergence of probability measures.

Weak-star Topologies

Given a Banach space and its Banach dual , the dual can be endowed with the weakest topology that makes the evaluation maps at elements of continuous. This is called the weak-star topology relative to . By Banach-Alaoglu, the unit ball of (which we call ) with the weak-star topology is compact.

In the case where is norm separable, the weak-star topology on the unit ball of can, in fact, be metrized. Fix a sequence that is countable and dense in . Define the metric by . This is a sum of pseudometrics, necessarily convergent because each term is less than or equal to , and is nondegenerate because if , then for each , which would imply that the continuous functions agreed on a dense subset of a metric space. The identity map from to is continuous: choose a net . Then for each , perform the following truncation process: choose a large so that . Because , for each , there is some large such that for all , . By the net order axioms, there is some large . So for each , . Now the identity map between the two spaces is a continuous bijection between a compact and a Hausdorff topological space, and is therefore a homeomorphism. So it metrizes the weak-star topology.

Metrizability for duals of -spaces

If is a compact Hausdorff metric space, is separable, due to the following argument: compact metric spaces are always separable. Pick a countable dense subset , and consider the smallest -algebra generated by the functions . This is a countable union of countable sets and therefore countable. As a subalgebra which separates points and contains the constant function, it must be dense by Stone-Weierstrass. So the unit ball of the dual of is metrizable.

Conversely, assume that the unit ball of the dual of is metrizable. Then, because via point evaluation, which is a norm map, and because the topology on is exactly the topology of weak-star convergence in , this means that is metrizable as well. So is a metrizable space which lives inside a compact metrizable space. This is in fact equivalent to the Stone-Cech compactification of being metrizable, which is quite rare.

Narrow Convergence

For every finite signed Radon measure on a locally compact Hausdorff space , there is some element such that . Moreover, letting denote the total variation of the measure, there is a net of functions such that , and . This means that , and can be isometrically identified with a subset of the dual. In particular, because the total variation norm does not increase with respect to continuous bounded functions, . Narrow convergence is weak-star convergence in with respect to : a net of measures converges to narrowly if, for every , .

Although in general the topology of narrow convergence is not metrizable on the unit ball -- for example, on any compact Hausdorff space which is not metrizable -- it is on the class of probability measures, so long as is separable. Take, again, a countable dense subset of , , and taking the family of functions . Let be the family of functions generated by taking infima of finitely many elements of , and let . This is still countable, and approximates integrals of elements of well weakly-star, so there is a metric on the probabilities by enumerating , and

Wide Convergence

Wide convergence is the weak-star convergence with respect to elements of rather than . As such, it is a weaker topology on the class of probability measures. When is a locally compact separable metric space (in particular, locally compact metric spaces which are -compact are separable), we can find a separating family of functions which form a countable subalgebra. One way to do this is by taking, for each point in a countable dense subset, a compact neighborhood and taking a partition of unity subordinate to that compact, . Taking the -algebra generated by this countable family of functions will separate points, which will make it dense in by Stone-Weierstrass. So is separable, which means that the unit ball of the dual is metrizable.