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Energy Games with Resource-Bounded Environments

Authors Orna Kupferman, Naama Shamash Halevy

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Author Details

Orna Kupferman
  • School of Computer Science and Engineering, Hebrew University of Jerusalem, Israel
Naama Shamash Halevy
  • School of Computer Science and Engineering, Hebrew University of Jerusalem, Israel

Funding

Supported by the Israel Science Foundation, grant No. 2357/19.

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Orna Kupferman and Naama Shamash Halevy. Energy Games with Resource-Bounded Environments. In 33rd International Conference on Concurrency Theory (CONCUR 2022). Leibniz International Proceedings in Informatics (LIPIcs), Volume 243, pp. 19:1-19:23, Schloss Dagstuhl – Leibniz-Zentrum für Informatik (2022)
https://doi.org/10.4230/LIPIcs.CONCUR.2022.19

Abstract

An energy game is played between two players, modeling a resource-bounded system and its environment. The players take turns moving a token along a finite graph. Each edge of the graph is labeled by an integer, describing an update to the energy level of the system that occurs whenever the edge is traversed. The system wins the game if it never runs out of energy. Different applications have led to extensions of the above basic setting. For example, addressing a combination of the energy requirement with behavioral specifications, researchers have studied richer winning conditions, and addressing systems with several bounded resources, researchers have studied games with multi-dimensional energy updates. All extensions, however, assume that the environment has no bounded resources. We introduce and study both-bounded energy games (BBEGs), in which both the system and the environment have multi-dimensional energy bounds. In BBEGs, each edge in the game graph is labeled by two integer vectors, describing updates to the multi-dimensional energy levels of the system and the environment. A system wins a BBEG if it never runs out of energy or if its environment runs out of energy. We show that BBEGs are determined, and that the problem of determining the winner in a given BBEG is decidable iff both the system and the environment have energy vectors of dimension 1. We also study how restrictions on the memory of the system and/or the environment as well as upper bounds on their energy levels influence the winner and the complexity of the problem.

Subject Classification

ACM Subject Classification
  • Theory of computation
Keywords
  • Energy Games
  • Infinite-State Systems
  • Decidability

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