Regret Bounds for Adversarial Contextual Bandits with General Function Approximation and Delayed Feedback
Abstract
We present regret minimization algorithms for the contextual multi-armed bandit (CMAB) problem over K actions in the presence of delayed feedback, a scenario where loss observations arrive with delays chosen by an adversary. As a preliminary result, assuming direct access to a finite policy class we establish an optimal expected regret bound of O (KT || + D ||) where D is the sum of delays. For our main contribution, we study the general function approximation setting over a (possibly infinite) contextual loss function class F with access to an online least-square regression oracle O over F. In this setting, we achieve an expected regret bound of O(KTRT(O) + d D β) assuming FIFO order, where d is the maximal delay, RT(O) is an upper bound on the oracle's regret and β is a stability parameter associated with the oracle. We complement this general result by presenting a novel stability analysis of a Hedge-based version of Vovk's aggregating forecaster as an oracle implementation for least-square regression over a finite function class F and show that its stability parameter β is bounded by |F|, resulting in an expected regret bound of O(KT |F| + d D |F|) which is a d factor away from the lower bound of (KT |F| + D |F|) that we also present.
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