Social Learning in Multi Agent Multi Armed Bandits
October 04, 2019 ยท Declared Dead ยท ๐ Proceedings of the ACM on Measurement and Analysis of Computing Systems
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Authors
Abishek Sankararaman, Ayalvadi Ganesh, Sanjay Shakkottai
arXiv ID
1910.02100
Category
cs.LG: Machine Learning
Cross-listed
cs.DC,
cs.NI,
cs.SI,
math.PR,
stat.ML
Citations
94
Venue
Proceedings of the ACM on Measurement and Analysis of Computing Systems
Last Checked
4 months ago
Abstract
In this paper, we introduce a distributed version of the classical stochastic Multi-Arm Bandit (MAB) problem. Our setting consists of a large number of agents $n$ that collaboratively and simultaneously solve the same instance of $K$ armed MAB to minimize the average cumulative regret over all agents. The agents can communicate and collaborate among each other \emph{only} through a pairwise asynchronous gossip based protocol that exchange a limited number of bits. In our model, agents at each point decide on (i) which arm to play, (ii) whether to, and if so (iii) what and whom to communicate with. Agents in our model are decentralized, namely their actions only depend on their observed history in the past. We develop a novel algorithm in which agents, whenever they choose, communicate only arm-ids and not samples, with another agent chosen uniformly and independently at random. The per-agent regret scaling achieved by our algorithm is $O \left( \frac{\lceil\frac{K}{n}\rceil+\log(n)}ฮ \log(T) + \frac{\log^3(n) \log \log(n)}{ฮ^2} \right)$. Furthermore, any agent in our algorithm communicates only a total of $ฮ(\log(T))$ times over a time interval of $T$. We compare our results to two benchmarks - one where there is no communication among agents and one corresponding to complete interaction. We show both theoretically and empirically, that our algorithm experiences a significant reduction both in per-agent regret when compared to the case when agents do not collaborate and in communication complexity when compared to the full interaction setting which requires $T$ communication attempts by an agent over $T$ arm pulls.
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