Helly's selection theorem

In mathematics, Helly's selection theorem (also called the Helly selection principle) states that a uniformly bounded sequence of monotone real functions admits a convergent subsequence. In other words, it is a sequential compactness theorem for the space of uniformly bounded monotone functions. It is named for the Austrian mathematician Eduard Helly. A more general version of the theorem asserts compactness of the space BV_loc of functions locally of bounded total variation that are uniformly bounded at a point.

The theorem has applications throughout mathematical analysis. In probability theory, the result implies compactness of a tight family of measures.

Statement of the theorem

Let (f_n)_n ∈ N be a sequence of increasing functions mapping a real interval I into the real line R, and suppose that it is uniformly bounded: there are a,b ∈ R such that a ≤ f_n ≤ b for every n ∈ N. Then the sequence (f_n)_n ∈ N admits a pointwise convergent subsequence.

Proof

Step 1. An increasing function f on an interval I has at most countably many points of discontinuity.

Let $A=\{x\in I:f(y)\not \rightarrow f(x){\text{ as }}y\rightarrow x\}$ , i.e. the set of discontinuities, then since f is increasing, any x in A satisfies $f(x^{-})\leq f(x)\leq f(x^{+})$ , where $f(x^{-})=\lim \limits _{y\uparrow x}f(y)$ , $f(x^{+})=\lim \limits _{y\downarrow x}f(y)$ , hence by discontinuity, $f(x^{-})<f(x^{+})$ . Since the set of rational numbers is dense in R, $\prod _{x\in A}[{\bigl (}f(x^{-}),f(x^{+}){\bigr )}\cap \mathrm {Q} ]$ is non-empty. Thus the axiom of choice indicates that there is a mapping s from A to Q.

It is sufficient to show that s is injective, which implies that A has a non-larger cardinity than Q, which is countable. Suppose x₁,x₂∈A, x₁<x₂, then $f(x_{1}^{-})<f(x_{1}^{+})\leq f(x_{2}^{-})<f(x_{2}^{+})$ , by the construction of s, we have s(x₁)<s(x₂). Thus s is injective.

Step 2. Inductive Construction of a subsequence converging at discontinuities and rationals.

Let $A_{n}=\{x\in I;f_{n}(y)\not \rightarrow f_{n}(x){\text{ as }}y\to x\}$ , i.e. the discontinuities of f_n, $A=(\cup _{n\in \mathrm {N} }A_{n})\cup (\mathrm {I} \cap \mathrm {Q} )$ , then A is countable, and it can be denoted as {a_n: n∈N}.

By the uniform boundedness of (f_n)_n ∈ N and B-W theorem, there is a subsequence (f⁽¹⁾_n)_n ∈ N such that (f⁽¹⁾_n(a₁))_n ∈ N converges. Suppose (f^(k)_n)_n ∈ N has been chosen such that (f^(k)_n(a_i))_n ∈ N converges for i=1,...,k, then by uniform boundedness, there is a subsequence (f^(k+1)_n)_n ∈ N of (f^(k)_n)_n ∈ N, such that (f^(k+1)_n(a_k+1))_n ∈ N converges, thus (f^(k+1)_n)_n ∈ N converges for i=1,...,k+1.

Let $g_{k}=f_{k}^{(k)}$ , then g_k is a subsequence of f_n that converges pointwise in A.

Step 3. g_k converges in I except possibly in an at most countable set.

Let $h_{k}(x)=\sup _{a\leq x,a\in A}g_{k}(a)$ , then , h_k(a)=g_k(a) for a∈A, h_k is increasing, let $h(x)=\limsup \limits _{k\rightarrow \infty }h_{k}(x)$ , then h is increasing, since supremes and limits of increasing functions are increasing, and $h(a)=\lim \limits _{k\rightarrow \infty }g_{k}(a)$ for a∈ A by Step 2. By Step 1, h has at most countably many discontinuities.

We will show that g_k converges at all continuities of h. Let x be a continuity of h, q,r∈ A, q<x<r, then $g_{k}(q)-h(r)\leq g_{k}(x)-h(x)\leq g_{k}(r)-h(q)$ ,hence

$\limsup \limits _{k\rightarrow \infty }{\bigl (}g_{k}(x)-h(x){\bigr )}\leq \limsup \limits _{k\rightarrow \infty }{\bigl (}g_{k}(r)-h(q){\bigr )}=h(r)-h(q)$

$h(q)-h(r)=\liminf \limits _{k\rightarrow \infty }{\bigl (}g_{k}(q)-h(r){\bigr )}\leq \liminf \limits _{k\rightarrow \infty }{\bigl (}g_{k}(x)-h(x){\bigr )}$

Thus,

$h(q)-h(r)\leq \liminf \limits _{k\rightarrow \infty }{\bigl (}g_{k}(x)-h(x){\bigr )}\leq \limsup \limits _{k\rightarrow \infty }{\bigl (}g_{k}(x)-h(x){\bigr )}\leq h(r)-h(q)$

Since h is continuous at x, by taking the limits $q\uparrow x,r\downarrow x$ , we have $h(q),h(r)\rightarrow h(x)$ , thus $\lim \limits _{k\rightarrow \infty }g_{k}(x)=h(x)$

Step 4. Choosing a subsequence of g_k that converges pointwise in I

This can be done with a diagonal process similar to Step 2.

With the above steps we have constructed a subsequence of (f_n)_n ∈ N that converges pointwise in I.

Generalisation to BV_loc

Let U be an open subset of the real line and let f_n : U → R, n ∈ N, be a sequence of functions. Suppose that (f_n) has uniformly bounded total variation on any W that is compactly embedded in U. That is, for all sets W ⊆ U with compact closure W̄ ⊆ U,

\sup _{n\in \mathbf {N} }\left(\|f_{n}\|_{L^{1}(W)}+\|{\frac {\mathrm {d} f_{n}}{\mathrm {d} t}}\|_{L^{1}(W)}\right)<+\infty ,

where the derivative is taken in the sense of tempered distributions.

Then, there exists a subsequence f_{n_k}, k ∈ N, of f_n and a function f : U → R, locally of bounded variation, such that

f_{n_k} converges to f pointwise almost everywhere;
and f_{n_k} converges to f locally in L¹ (see locally integrable function), i.e., for all W compactly embedded in U,

\lim _{k\to \infty }\int _{W}{\big |}f_{n_{k}}(x)-f(x){\big |}\,\mathrm {d} x=0;

^[1]^: 132

and, for W compactly embedded in U,

\left\|{\frac {\mathrm {d} f}{\mathrm {d} t}}\right\|_{L^{1}(W)}\leq \liminf _{k\to \infty }\left\|{\frac {\mathrm {d} f_{n_{k}}}{\mathrm {d} t}}\right\|_{L^{1}(W)}.

^[1]^: 122

Further generalizations

There are many generalizations and refinements of Helly's theorem. The following theorem, for BV functions taking values in Banach spaces, is due to Barbu and Precupanu:

Let X be a reflexive, separable Hilbert space and let E be a closed, convex subset of X. Let Δ : X → [0, +∞) be positive-definite and homogeneous of degree one. Suppose that z_n is a uniformly bounded sequence in BV([0, T]; X) with z_n(t) ∈ E for all n ∈ N and t ∈ [0, T]. Then there exists a subsequence z_{n_k} and functions δ, z ∈ BV([0, T]; X) such that

for all t ∈ [0, T],

\int _{[0,t)}\Delta (\mathrm {d} z_{n_{k}})\to \delta (t);

and, for all t ∈ [0, T],

z_{n_{k}}(t)\rightharpoonup z(t)\in E;

and, for all 0 ≤ s < t ≤ T,

\int _{[s,t)}\Delta (\mathrm {d} z)\leq \delta (t)-\delta (s).

References

^ ^a ^b Ambrosio, Luigi; Fusco, Nicola; Pallara, Diego (2000). Functions of Bounded Variation and Free Discontinuity Problems. Oxford University Press. ISBN 9780198502456.

Rudin, W. (1976). Principles of Mathematical Analysis. International Series in Pure and Applied Mathematics (Third ed.). New York: McGraw-Hill. 167. ISBN 978-0070542358.

Barbu, V.; Precupanu, Th. (1986). Convexity and optimization in Banach spaces. Mathematics and its Applications (East European Series). Vol. 10 (Second Romanian ed.). Dordrecht: D. Reidel Publishing Co. xviii+397. ISBN 90-277-1761-3. MR860772

[10.1093/oso/9780198502456.001.0001-1] Ambrosio, Luigi; Fusco, Nicola; Pallara, Diego (2000). Functions of Bounded Variation and Free Discontinuity Problems. Oxford University Press. ISBN 9780198502456.

[1]

Statement of the theorem

Proof

Step 1. An increasing function f on an interval I has at most countably many points of discontinuity.

Step 2. Inductive Construction of a subsequence converging at discontinuities and rationals.

Step 3. gk converges in I except possibly in an at most countable set.

Step 4. Choosing a subsequence of gk that converges pointwise in I

Generalisation to BVloc

Further generalizations

See also

References

Step 3. g_k converges in I except possibly in an at most countable set.

Step 4. Choosing a subsequence of g_k that converges pointwise in I

Generalisation to BV_loc