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Proceedings of the Fourteenth Annual ACM-SIAM Symposium on Discrete Algorithms

A Truthful Cardinal Mechanism for One-Sided Matching

Abstract

We revisit the well-studied problem of designing mechanisms for one-sided matching markets, where a set of n agents needs to be matched to a set of n heterogeneous items. Each agent i has a value νi,j for each item j, and these values are private information that the agents may misreport if doing so leads to a preferred outcome. Ensuring that the agents have no incentive to misreport requires a careful design of the matching mechanism, and mechanisms proposed in the literature mitigate this issue by eliciting only the ordinal preferences of the agents, i.e., their ranking of the items from most to least preferred. However, the efficiency guarantees of these mechanisms are based only on weak measures that are oblivious to the underlying values. In this paper we achieve stronger performance guarantees by introducing a mechanism that truthfully elicits the full cardinal preferences of the agents, i.e., all of the νi,j values. We evaluate the performance of this mechanism using the much more demanding Nash bargaining solution as a benchmark, and we prove that our mechanism significantly outperforms all ordinal mechanisms (even non-truthful ones). To prove our approximation bounds, we also study the population monotonicity of the Nash bargaining solution in the context of matching markets, providing both upper and lower bounds which are of independent interest.

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Published In

cover image Proceedings
Proceedings of the Fourteenth Annual ACM-SIAM Symposium on Discrete Algorithms
Pages: 2096 - 2113
Editor: Shuchi Chawla
ISBN (Online): 978-1-611975-99-4

History

Published online: 23 December 2019

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*
Rediet Abebe was supported in part by a Facebook scholarship. Richard Cole was supported in part by NSF grants CCF-1527568 and CCF-1909538. Vasilis Gkatzelis was supported in part by NSF grant CCF-1755955. Jason Hartline was supported by NSF grant CCF-1618502 and part of this work took place while he was visiting Harvard University.

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