English

Localizing Weak Convergence in $\boldsymbol{ L_\infty}$

Functional Analysis 2018-09-18 v2

Abstract

In a general measure space (X,L,λ)(X,\mathcal L,\lambda), a characterization of weakly null sequences in L(X,L,λ)L_\infty (X,\mathcal L,\lambda) (uk0u_k \rightharpoonup 0) in terms of their pointwise behaviour almost everywhere is derived from the Yosida-Hewitt identification of L(X,L,λ)L_\infty (X,\mathcal L,\lambda)^* with finitely additive measures, and extreme points of the unit ball in L(X,L,λ)L_\infty (X,\mathcal L,\lambda)^* with ±G\pm \mathfrak G, where G\mathfrak G denotes the set of finitely additive measures that take only values 0 or 1 1. When (X,τ)(X,\tau) is a locally compact Hausdorff space with Borel σ\sigma-algebra B\mathcal B, the well-known identification of G\mathfrak G with ultrafilters means that this criterion for nullity is equivalent to localized behaviour on open neighbourhoods of points x0x_0 in the one-point compactification of XX. Notions of weak convergence at x0x_0 and the essential range of uu at x0x_0 are natural consequences.When a finitely additive measure ν\nu represents fL(X,B,λ)f \in L_\infty(X, \mathcal B, \lambda)^* and ν^\hat \nu is the Borel measure representing ff restricted to C0(X,τ)C_0(X,\tau), a minimax formula for ν^\hat \nu in terms ν\nu is derived and those ν\nu for which ν^\hat \nu is singular with respect to λ\lambda are characterized.

Keywords

Cite

@article{arxiv.1802.01878,
  title  = {Localizing Weak Convergence in $\boldsymbol{ L_\infty}$},
  author = {J F Toland},
  journal= {arXiv preprint arXiv:1802.01878},
  year   = {2018}
}

Comments

Theorem 3.6, Corollary 3.7 and Section 3.1 are significant developments

R2 v1 2026-06-23T00:12:43.752Z