English

Online Social Welfare Function-based Resource Allocation

Machine Learning 2026-02-03 v1 Machine Learning

Abstract

In many real-world settings, a centralized decision-maker must repeatedly allocate finite resources to a population over multiple time steps. Individuals who receive a resource derive some stochastic utility; to characterize the population-level effects of an allocation, the expected individual utilities are then aggregated using a social welfare function (SWF). We formalize this setting and present a general confidence sequence framework for SWF-based online learning and inference, valid for any monotonic, concave, and Lipschitz-continuous SWF. Our key insight is that monotonicity alone suffices to lift confidence sequences from individual utilities to anytime-valid bounds on optimal welfare. Building on this foundation, we propose SWF-UCB, a SWF-agnostic online learning algorithm that achieves near-optimal O~(n+nkT)\tilde{O}(n+\sqrt{nkT}) regret (for kk resources distributed among nn individuals at each of TT time steps). We instantiate our framework on three normatively distinct SWF families: Weighted Power Mean, Kolm, and Gini, providing bespoke oracle algorithms for each. Experiments confirm T\sqrt{T} scaling and reveal rich interactions between kk and SWF parameters. This framework naturally supports inference applications such as sequential hypothesis testing, optimal stopping, and policy evaluation.

Keywords

Cite

@article{arxiv.2602.01400,
  title  = {Online Social Welfare Function-based Resource Allocation},
  author = {Kanad Pardeshi and Samsara Foubert and Aarti Singh},
  journal= {arXiv preprint arXiv:2602.01400},
  year   = {2026}
}
R2 v1 2026-07-01T09:30:29.711Z