Sparsity-Based Interpolation of External, Internal and Swap Regret

Abstract

Focusing on the expert problem in online learning, this paper studies the interpolation of several performance metrics via φ-regret minimization, which measures the total loss of an algorithm by its regret with respect to an arbitrary action modification rule φ. With d experts and T d rounds in total, we present a single algorithm achieving the instance-adaptive φ-regret bound equation* O(\d-dunifφ+1,d-dselfφ\·T), equation* where dunifφ is the maximum amount of experts modified identically by φ, and dselfφ is the amount of experts that φ trivially modifies to themselves. By recovering the optimal O(T d) external regret bound when dunifφ=d, the standard O(T) internal regret bound when dselfφ=d-1 and the optimal O(dT) swap regret bound in the worst case, we improve upon existing algorithms in the intermediate regimes. In addition, the computational complexity of our algorithm matches that of the standard swap-regret minimization algorithm due to (Blum and Mansour, 2007). Technically, building on the well-known reduction from φ-regret minimization to external regret minimization on stochastic matrices, our main idea is to further convert the latter to online linear regression using Haar-wavelet-inspired matrix features. Then, by associating the complexity of each φ instance with its sparsity under the feature representation, we apply techniques from comparator-adaptive online learning to exploit the sparsity in this regression subroutine.

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