Algorithms achieve adaptive calibration bounds of order min{sqrt(T) + (T C)^{1/3}, sqrt(K T)} for l1 error and min{(1+C)^{1/3}, K} for l2 and pseudo-KL error, where K and C are unknown non-stationarity measures.
Instance-Adaptive Online Multicalibration
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abstract
We study online multicalibration beyond the worst-case. We give a single, efficient algorithm which dynamically interpolates between benign and worst-case sequences by adaptively refining a dyadic grid of prediction values. Its error is controlled by the number of leaves in the refinement tree. Our analysis recovers the known $\widetilde O(T^{2/3})$ worst-case-optimal rate for online multicalibration, while simultaneously automatically adapting to easier instances: in the marginal stochastic setting it obtains a rate of $\widetilde O(\sqrt T)$, and for piecewise-stationary means with $J$ segments its rate is $\widetilde O(\sqrt{JT})$. More generally, the rate depends on a threshold-complexity measure of the predictable mean process relative to the group family. We show that this dependence is tight up to logarithmic factors.
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cs.LG 1years
2026 1verdicts
UNVERDICTED 1representative citing papers
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Adaptive Calibration in Non-Stationary Environments
Algorithms achieve adaptive calibration bounds of order min{sqrt(T) + (T C)^{1/3}, sqrt(K T)} for l1 error and min{(1+C)^{1/3}, K} for l2 and pseudo-KL error, where K and C are unknown non-stationarity measures.