A Reduction from Delayed to Immediate Feedback for Online Convex Optimization with Improved Guarantees
Abstract
We develop a reduction-based framework for online learning with delayed feedback that recovers and improves upon existing results for both first-order and bandit convex optimization. Our approach introduces a continuous-time model under which regret decomposes into a delay-independent learning term and a delay-induced drift term, yielding a delay-adaptive reduction that converts any algorithm for online linear optimization into one that handles round-dependent delays. For bandit convex optimization, we significantly improve existing regret bounds, with delay-dependent terms matching state-of-the-art first-order rates. For first-order feedback, we recover state-of-the-art regret bounds via a simpler, unified analysis. Quantitatively, for bandit convex optimization we obtain regret, improving the delay-dependent term from in previous work to . Here, , , , and denote the dimension, time horizon, maximum delay, and total delay, respectively. Under strong convexity, we achieve , improving the delay-dependent term from in previous work to , where denotes the maximum number of outstanding observations and may be considerably smaller than .
Cite
@article{arxiv.2602.02634,
title = {A Reduction from Delayed to Immediate Feedback for Online Convex Optimization with Improved Guarantees},
author = {Alexander Ryabchenko and Idan Attias and Daniel M. Roy},
journal= {arXiv preprint arXiv:2602.02634},
year = {2026}
}