Entangled Games Are Hard to Approximate
Abstract
We establish the first hardness results for the problem of computing the value of one-round games played by a verifier and a team of provers who can share quantum entanglement. In particular, we show that it is NP-hard to approximate within an inverse polynomial the value of a one-round game with (i) a quantum verifier and two entangled provers or (ii) a classical verifier and three entangled provers. Previously it was not even known if computing the value exactly is NP-hard. We also describe a mathematical conjecture, which, if true, would imply hardness of approximation of entangled-prover games to within a constant. Using our techniques we also show that every language in PSPACE has a two-prover one-round interactive proof system with perfect completeness and soundness 1-1/poly even against entangled provers. We start our proof by describing two ways to modify classical multiprover games to make them resistant to entangled provers. We then show that a strategy for the modified game that uses entanglement can be "rounded" to one that does not. The results then follow from classical inapproximability bounds. Our work implies that, unless P=NP, the values of entangled-prover games cannot be computed by semidefinite programs that are polynomial in the size of the verifier's system, a method that has been successful for more restricted quantum games.
Additional Information
© 2011 Society for Industrial and Applied Mathematics. Received March 02, 2009; Accepted October 01, 2010; Published online June 23, 2011. We thank Tsuyoshi Ito, Jaikumar Radhakrishnan, Oded Regev, Amnon Ta-Shma, Mario Szegedy, and Andy Yao for helpful discussions and John Watrous for pointing out that the optimal quantum value of a game might not be achievable with finite-dimensional entanglement. This author's work was partially supported by the European Commission under the Integrated Project Qubit Applications (QAP) funded by the IST directorate as contract 015848, by an Alon Fellowship of the Israeli Higher Council of Academic Research, by a grant of the Israeli Science Foundation, by an ERC Starting Researcher grant, and by a grant from the Wolfson Family Charitable Trust. Support by Michel Cukierman is also gratefully acknowledged. The work of these authors was supported by the Strategic Information and Communications R&D Promotion Programme 031303020 of the Ministry of Internal Affairs and Communications of Japan. This author's work was supported by the National Science Foundation under grants PHY-0456720 and CCF-0524828, by EU project QAP, by NWO VICI project 639-023-302, and by the Dutch BSIK/BRICKS project. This author's work was supported by ARO grant W911NF-09-1-0440 and NSF grant CCF-0905626.Attached Files
Published - Kempe2011p14620Siam_J_Comput.pdf
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Additional details
- Eprint ID
- 24413
- Resolver ID
- CaltechAUTHORS:20110713-155400829
- European Commission under the Integrated Project Qubit Applications (QAP) funded by the IST directorate
- Israeli Higher Council of Academic Research Alon Fellowship
- Israel Science Foundation
- European Research Council (ERC)
- Wolfson Family Charitable Trust
- Strategic Information and Communications R&D Promotion Programme 031303020 of the Ministry of Internal Affairs and Communications of Japan
- PHY-0456720
- NSF
- CCF-0524828
- NSF
- EU project QAP
- 639-023-302
- Nederlandse Organisatie voor Wetenschappelijk Onderzoek (NWO)
- Dutch BSIK/BRICKS project
- W911NF-09-1-0440
- Army Research Office (ARO)
- CCF-0905626
- NSF
- Created
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2011-07-14Created from EPrint's datestamp field
- Updated
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2021-11-09Created from EPrint's last_modified field