Network Restoration Games With Quotas (Student abstract)

Philip Bogaars; Argyrios Deligkas; Eduard Eiben; Michail Fasoulakis

Network Restoration Games With Quotas (Student abstract)

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution

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Abstract

In a game of NETWORK RESTORATION GAMES WITH QUOTAS, there is an underlying graph where a subset of its edges have to be restored by a set of agents. Each agent has a creation cost for each such edge, a traversal cost for every edge of the graph, and in addition they have a quota on the number of edges they have to restore. Then, given a set of edges that fulfill the quota, the cost of an agent is the cost of creating these edges, plus the cost of reaching them, i.e., the traversal cost. We prove that any cost-minimizing allocation is swap-stable, i.e., there is no profitable exchange of edges between any pair of agents, but computing one is hard even on trees. We complement this by designing an algorithm that finds a swap-stable allocation on trees in polynomial time and we quantify its cost against the optimal one.

Original language	English
Title of host publication	Proceedings of the AAAI Conference on Artificial Intelligence, AAAI 2026
Publisher	AAAI Press
Number of pages	3
Publication status	Accepted/In press - 21 Dec 2025

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Accepted ManuscriptAccepted author manuscript, 167 KB

Cite this

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title = "Network Restoration Games With Quotas (Student abstract)",

abstract = "In a game of NETWORK RESTORATION GAMES WITH QUOTAS, there is an underlying graph where a subset of its edges have to be restored by a set of agents. Each agent has a creation cost for each such edge, a traversal cost for every edge of the graph, and in addition they have a quota on the number of edges they have to restore. Then, given a set of edges that fulfill the quota, the cost of an agent is the cost of creating these edges, plus the cost of reaching them, i.e., the traversal cost. We prove that any cost-minimizing allocation is swap-stable, i.e., there is no profitable exchange of edges between any pair of agents, but computing one is hard even on trees. We complement this by designing an algorithm that finds a swap-stable allocation on trees in polynomial time and we quantify its cost against the optimal one.",

author = "Philip Bogaars and Argyrios Deligkas and Eduard Eiben and Michail Fasoulakis",

year = "2025",

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day = "21",

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T1 - Network Restoration Games With Quotas (Student abstract)

AU - Bogaars, Philip

AU - Deligkas, Argyrios

AU - Eiben, Eduard

AU - Fasoulakis, Michail

PY - 2025/12/21

Y1 - 2025/12/21

N2 - In a game of NETWORK RESTORATION GAMES WITH QUOTAS, there is an underlying graph where a subset of its edges have to be restored by a set of agents. Each agent has a creation cost for each such edge, a traversal cost for every edge of the graph, and in addition they have a quota on the number of edges they have to restore. Then, given a set of edges that fulfill the quota, the cost of an agent is the cost of creating these edges, plus the cost of reaching them, i.e., the traversal cost. We prove that any cost-minimizing allocation is swap-stable, i.e., there is no profitable exchange of edges between any pair of agents, but computing one is hard even on trees. We complement this by designing an algorithm that finds a swap-stable allocation on trees in polynomial time and we quantify its cost against the optimal one.

AB - In a game of NETWORK RESTORATION GAMES WITH QUOTAS, there is an underlying graph where a subset of its edges have to be restored by a set of agents. Each agent has a creation cost for each such edge, a traversal cost for every edge of the graph, and in addition they have a quota on the number of edges they have to restore. Then, given a set of edges that fulfill the quota, the cost of an agent is the cost of creating these edges, plus the cost of reaching them, i.e., the traversal cost. We prove that any cost-minimizing allocation is swap-stable, i.e., there is no profitable exchange of edges between any pair of agents, but computing one is hard even on trees. We complement this by designing an algorithm that finds a swap-stable allocation on trees in polynomial time and we quantify its cost against the optimal one.

M3 - Conference contribution

BT - Proceedings of the AAAI Conference on Artificial Intelligence, AAAI 2026

PB - AAAI Press

ER -