Differentially private multi-agent constraint optimization

IF 2.6 3区计算机科学 Q3 AUTOMATION & CONTROL SYSTEMS

Autonomous Agents and Multi-Agent Systems Pub Date : 2024-03-02 DOI:10.1007/s10458-024-09636-x

Sankarshan Damle, Aleksei Triastcyn, Boi Faltings, Sujit Gujar

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Abstract

Distributed constraint optimization (DCOP) is a framework in which multiple agents with private constraints (or preferences) cooperate to achieve a common goal optimally. DCOPs are applicable in several multi-agent coordination/allocation problems, such as vehicle routing, radio frequency assignments, and distributed scheduling of meetings. However, optimization scenarios may involve multiple agents wanting to protect their preferences’ privacy. Researchers propose privacy-preserving algorithms for DCOPs that provide improved privacy protection through cryptographic primitives such as partial homomorphic encryption, secret-sharing, and secure multiparty computation. These privacy benefits come at the expense of high computational complexity. Moreover, such an approach does not constitute a rigorous privacy guarantee for optimization outcomes, as the result of the computation may compromise agents’ preferences. In this work, we show how to achieve privacy, specifically Differential Privacy, by randomizing the solving process. In particular, we present P-Gibbs, which adapts the current state-of-the-art algorithm for DCOPs, namely SD-Gibbs, to obtain differential privacy guarantees with much higher computational efficiency. Experiments on benchmark problems such as Ising, graph-coloring, and meeting-scheduling show P-Gibbs’ privacy and performance trade-off for varying privacy budgets and the SD-Gibbs algorithm. More concretely, we empirically show that P-Gibbs provides fair solutions for competitive privacy budgets.

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差分私有多代理约束优化

分布式约束优化（DCOP）是一个框架，在这个框架中，具有私人约束（或偏好）的多个代理进行合作，以最优方式实现共同目标。DCOP 适用于多个多代理协调/分配问题，如车辆路由、无线电频率分配和分布式会议安排。然而，优化场景可能涉及多个希望保护其偏好隐私的代理。研究人员提出了针对 DCOP 的隐私保护算法，通过部分同态加密、秘密共享和安全多方计算等加密原语提供更好的隐私保护。这些隐私保护的好处是以高计算复杂性为代价的。此外，这种方法并不能为优化结果提供严格的隐私保证，因为计算结果可能会损害代理的偏好。在这项工作中，我们展示了如何通过随机化求解过程来实现隐私，特别是差分隐私。我们特别介绍了 P-Gibbs，它对当前最先进的 DCOP 算法（即 SD-Gibbs）进行了调整，从而以更高的计算效率获得差分隐私保证。在伊辛、图着色和会议调度等基准问题上的实验表明，P-Gibbs 在不同的隐私预算和 SD-Gibbs 算法下的隐私和性能权衡。更具体地说，我们通过经验证明，P-Gibbs 能为具有竞争力的隐私预算提供公平的解决方案。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Autonomous Agents and Multi-Agent Systems 工程技术-计算机：人工智能

CiteScore

6.00

自引率

5.30%

发文量

审稿时长

>12 weeks

期刊介绍： This is the official journal of the International Foundation for Autonomous Agents and Multi-Agent Systems. It provides a leading forum for disseminating significant original research results in the foundations, theory, development, analysis, and applications of autonomous agents and multi-agent systems. Coverage in Autonomous Agents and Multi-Agent Systems includes, but is not limited to: Agent decision-making architectures and their evaluation, including: cognitive models; knowledge representation; logics for agency; ontological reasoning; planning (single and multi-agent); reasoning (single and multi-agent) Cooperation and teamwork, including: distributed problem solving; human-robot/agent interaction; multi-user/multi-virtual-agent interaction; coalition formation; coordination Agent communication languages, including: their semantics, pragmatics, and implementation; agent communication protocols and conversations; agent commitments; speech act theory Ontologies for agent systems, agents and the semantic web, agents and semantic web services, Grid-based systems, and service-oriented computing Agent societies and societal issues, including: artificial social systems; environments, organizations and institutions; ethical and legal issues; privacy, safety and security; trust, reliability and reputation Agent-based system development, including: agent development techniques, tools and environments; agent programming languages; agent specification or validation languages Agent-based simulation, including: emergent behavior; participatory simulation; simulation techniques, tools and environments; social simulation Agreement technologies, including: argumentation; collective decision making; judgment aggregation and belief merging; negotiation; norms Economic paradigms, including: auction and mechanism design; bargaining and negotiation; economically-motivated agents; game theory (cooperative and non-cooperative); social choice and voting Learning agents, including: computational architectures for learning agents; evolution, adaptation; multi-agent learning. Robotic agents, including: integrated perception, cognition, and action; cognitive robotics; robot planning (including action and motion planning); multi-robot systems. Virtual agents, including: agents in games and virtual environments; companion and coaching agents; modeling personality, emotions; multimodal interaction; verbal and non-verbal expressiveness Significant, novel applications of agent technology Comprehensive reviews and authoritative tutorials of research and practice in agent systems Comprehensive and authoritative reviews of books dealing with agents and multi-agent systems.