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On the Parallel Repetition of Multi-Player Games: The No-Signaling Case

Authors Harry Buhrman, Serge Fehr, Christian Schaffner

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Harry Buhrman
Serge Fehr
Christian Schaffner

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Harry Buhrman, Serge Fehr, and Christian Schaffner. On the Parallel Repetition of Multi-Player Games: The No-Signaling Case. In 9th Conference on the Theory of Quantum Computation, Communication and Cryptography (TQC 2014). Leibniz International Proceedings in Informatics (LIPIcs), Volume 27, pp. 24-35, Schloss Dagstuhl – Leibniz-Zentrum für Informatik (2014) https://doi.org/10.4230/LIPIcs.TQC.2014.24

Abstract

We consider the natural extension of two-player nonlocal games to an arbitrary number of players. An important question for such nonlocal games is their behavior under parallel repetition. For two-player nonlocal games, it is known that both the classical and the non-signaling value of any game converges to zero exponentially fast under parallel repetition, given that the game is non-trivial to start with (i.e., has classical/non-signaling value < 1). Very recent results show similar behavior of the quantum value of a two-player game under parallel repetition. For nonlocal games with three or more players, very little is known up to present on their behavior under parallel repetition; this is true for the classical, the quantum and the non-signaling value. 

In this work, we show a parallel repetition theorem for the non-signaling value of a large class of multi-player games, for an arbitrary number of players. Our result applies to all multi-player games for which all possible combinations of questions have positive probability; this class in particular includes all free games, in which the questions to the players are chosen independently. Specifically, we prove that if the original game G has a non-signaling value v_{ns}(G) < 1, then the non-signaling value of the n-fold parallel repetition is exponentially small in n. Stronger than that, we prove that the probability of winning more than (v_{ns}(G) + delta) * n parallel repetitions is exponentially small in n (for any delta > 0). 

Our parallel repetition theorem for multi-player games is weaker than the known parallel repetition results for two-player games in that the rate at which the non-signaling value of the game decreases not only depends on the non-signaling value of the original game (and the  number of possible responses), but on the complete description of the game. Nevertheless, we feel that our result is a first step towards a better understanding of the parallel repetition of nonlocal games with more than two players.

Subject Classification

Keywords
  • Parallel repetition
  • non-signaling value
  • multi-player non-local games

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References

  1. Boaz Barak, Anup Rao, Ran Raz, Ricky Rosen, and Ronen Shaltiel. Strong parallel repetition theorem for free projection games. In Irit Dinur, Klaus Jansen, Joseph Naor, and José D. P. Rolim, editors, Approximation, Randomization, and Combinatorial Optimization. Algorithms and Techniques, 12th International Workshop, APPROX 2009, and 13th International Workshop, RANDOM 2009, Berkeley, CA, USA, August 21-23, 2009. Proceedings, volume 5687 of Lecture Notes in Computer Science, pages 352-365. Springer, 2009. Google Scholar
  2. Jop Briët, Harry Buhrman, Troy Lee, and Thomas Vidick. Multipartite entanglement in xor games. Quantum Information & Computation, 13(3-4):334-360, March 2013. Google Scholar
  3. Harry Buhrman, Nishanth Chandran, Serge Fehr, Ran Gelles, Vipul Goyal, Rafail Ostrovsky, and Christian Schaffner. Position-based quantum cryptography: Impossibility and constructions. In Phillip Rogaway, editor, Advances in Cryptology – CRYPTO 2011, volume 6841 of Lecture Notes in Computer Science, pages 429-446. Springer Berlin / Heidelberg, 2011. Google Scholar
  4. Harry Buhrman, Serge Fehr, Christian Schaffner, and Florian Speelman. The garden-hose model. In Innovations in Theoretical Computer Science, ITCS'13, Berkeley, CA, USA, January 9-12, 2013, pages 145-158. ACM, 2013. Google Scholar
  5. A. Chailloux and G. Scarpa. Parallel Repetition of Entangled Games with Exponential Decay via the Superposed Information Cost. arxiv:1310.7787, 2013. Google Scholar
  6. Richard Cleve, William Slofstra, Falk Unger, and Sarvagya Upadhyay. Perfect parallel repetition theorem for quantum xor proof systems. Computational Complexity, 17(2):282-299, 2008. Google Scholar
  7. I. Dinur, D. Steurer, and T. Vidick. A parallel repetition theorem for entangled projection games. arxiv:1310.4113, 2013. Google Scholar
  8. Wassily Hoeffding. Probability inequalities for sums of bounded random variables. Journal of the American Statistical Association, 58(301):13-30, March 1963. Google Scholar
  9. Thomas Holenstein. Parallel repetition: Simplification and the no-signaling case. Theory of Computing, 5(1):141-172, 2009. Google Scholar
  10. R. Jain, A. Pereszlényi, and P. Yao. A parallel repetition theorem for entangled two-player one-round games under product distributions. arxiv:1311.6309, 2013. Google Scholar
  11. Julia Kempe, Oded Regev, and Ben Toner. Unique games with entangled provers are easy. SIAM J. Comput., 39(7):3207-3229, July 2010. Google Scholar
  12. Julia Kempe and Thomas Vidick. Parallel repetition of entangled games. In Proceedings of the 43rd annual ACM symposium on Theory of computing, STOC'11, pages 353-362, New York, NY, USA, 2011. ACM. Google Scholar
  13. Anup Rao. Parallel repetition in projection games and a concentration bound. SIAM J. Comput., 40(6):1871-1891, 2011. Google Scholar
  14. Ran Raz. A parallel repetition theorem. SIAM J. Comput., 27(3):763-803, June 1998. Google Scholar
  15. Ricky Rosen. A k-provers parallel repetition theorem for a version of no-signaling model. Discrete Math., Alg. and Appl., 2(4):457-468, 2010. Google Scholar
  16. A. Schrijver. Theory of Linear and Integer Programming. Wiley Series in Discrete Mathematics & Optimization. John Wiley & Sons, 1998. Google Scholar
  17. Marco Tomamichel, Serge Fehr, Jędrzej Kaniewski, and Stephanie Wehner. A monogamy-of-entanglement game with applications to device-independent quantum cryptography. New Journal of Physics, 15(10):103002, 2013. Google Scholar
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