Abstract:
In this paper, we introduce ballooning multi-armed bandits (BL-MAB ), a novel extension of the
classical stochastic MAB model. In the BL-MAB model, the set of available arms grows (or balloons) over time. In contrast to the classical MAB setting where the regret is computed with respect
to the best arm overall, the regret in a BL-MAB setting is computed with respect to the best available arm at each time. We first observe that the existing stochastic MAB algorithms result in linear
regret for the BL-MAB model. We prove that, if the best arm is equally likely to arrive at any time
instant, a sub-linear regret cannot be achieved. Next, we show that if the best arm is more likely to
arrive in the early rounds, one can achieve sub-linear regret. Our proposed algorithm determines
(1) the fraction of the time horizon for which the newly arriving arms should be explored and
(2) the sequence of arm pulls in the exploitation phase from among the explored arms. Making
reasonable assumptions on the arrival distribution of the best arm in terms of the thinness of the
distribution’s tail, we prove that the proposed algorithm achieves sub-linear instance-independent
regret. We further quantify explicit dependence of regret on the arrival distribution parameters.
We reinforce our theoretical findings with extensive simulation results. We conclude by showing
that our algorithm would achieve sub-linear regret even if (a) the distributional parameters are
not exactly known, but are obtained using a reasonable learning mechanism or (b) the best arm is
not more likely to arrive early, but a large fraction of arms is likely to arrive relatively early