Uniform direct product theorems

Subscribe (Full Service)


	Search: The ACM Digital Library The Guide

	Feedback

Uniform direct product theorems: simplified, optimized, and derandomized

Full text

Pdf (322 KB)

Source

Annual ACM Symposium on Theory of Computing archive
Proceedings of the 40th annual ACM symposium on Theory of computing table of contents

Victoria, British Columbia, Canada

SESSION: 13A table of contents

Pages 579-588

Year of Publication: 2008

ISBN:978-1-60558-047-0

Authors

Russell Impagliazzo	University of California San Diego, La Jolla, CA, USA
Ragesh Jaiswal	University of California San Diego, La Jolla, CA, USA
Valentine Kabanets	Simon Fraser University, Vancouver, BC, Canada
Avi Wigderson	Institute of Advanced Studies, Princeton, NJ, USA

Sponsors

ACM: Association for Computing Machinery
SIGACT: ACM Special Interest Group on Algorithms and Computation Theory

Publisher

ACM New York, NY, USA

Bibliometrics

Downloads (6 Weeks): 5, Downloads (12 Months): 73, Citation Count: 4

Additional Information:

abstract references cited by index terms collaborative colleagues

Tools and Actions:	Request Permissions Review this Article Save this Article to a Binder Display Formats: BibTeX EndNote ACM Ref

DOI Bookmark:	Use this link to bookmark this Article: http://doi.acm.org/10.1145/1374376.1374460 What is a DOI?

ABSTRACT

The classical Direct-Product Theorem for circuits says that if a Boolean function f: {0,1}ⁿ -> {0,1} is somewhat hard to compute on average by small circuits, then the corresponding k-wise direct product function f^k(x₁,...,x_k)=(f(x₁),...,f(x_k)) (where each x_i -> {0,1}ⁿ) is significantly harder to compute on average by slightly smaller circuits. We prove a fully uniform version of the Direct-Product Theorem with information-theoretically optimal parameters, up to constant factors. Namely, we show that for given k and ε, there is an efficient randomized algorithm A with the following property. Given a circuit C that computes f^k on at least ε fraction of inputs, the algorithm A outputs with probability at least 3/4 a list of O(1/ε) circuits such that at least one of the circuits on the list computes f on more than 1-δ fraction of inputs, for δ = O((log 1/ε)/k). Moreover, each output circuit is an AC⁰ circuit (of size poly(n,k,log 1/δ,1/ε)), with oracle access to the circuit C. Using the Goldreich-Levin decoding algorithm [5], we also get a fully uniform version of Yao's XOR Lemma [18] with optimal parameters, up to constant factors. Our results simplify and improve those in [10]. Our main result may be viewed as an efficient approximate, local, list-decoding algorithm for direct-product codes (encoding a function by its values on all k-tuples) with optimal parameters. We generalize it to a family of "derandomized" direct-product codes, which we call intersection codes, where the encoding provides values of the function only on a subfamily of k-tuples. The quality of the decoding algorithm is then determined by sampling properties of the sets in this family and their intersections. As a direct consequence of this generalization we obtain the first derandomized direct product result in the uniform setting, allowing hardness amplification with only constant (as opposed to a factor of k) increase in the input length. Finally, this general setting naturally allows the decoding of concatenated codes, which further yields nearly optimal derandomized amplification.

REFERENCES

Note: OCR errors may be found in this Reference List extracted from the full text article. ACM has opted to expose the complete List rather than only correct and linked references.

	1	S. Arora and M. Sudan. Improved low-degree testing and its applications. Combinatorica, 23(3):365--426, 2003.
	2	Mihir Bellare , Oded Goldreich , Shafi Goldwasser, Randomness in interactive proofs, Computational Complexity, v.3 n.4, p.319-354, Oct. 1993 [doi>10.1007/BF01275487]
	3	Joshua Buresh-Oppenheim , Rahul Santhanam, Making Hard Problems Harder, Proceedings of the 21st Annual IEEE Conference on Computational Complexity, p.73-87, July 16-20, 2006 [doi>10.1109/CCC.2006.26]
	4	Irit Dinur , Omer Reingold, Assignment Testers: Towards a Combinatorial Proof of the PCP Theorem, SIAM Journal on Computing, v.36 n.4, p.975-1024, December 2006 [doi>10.1137/S0097539705446962]
	5	O. Goldreich , L. A. Levin, A hard-core predicate for all one-way functions, Proceedings of the twenty-first annual ACM symposium on Theory of computing, p.25-32, May 14-17, 1989, Seattle, Washington, United States [doi>10.1145/73007.73010]
	6	O. Goldreich, N. Nisan, and A. Wigderson. On Yao's XOR-Lemma. Electronic Col loquium on Computational Complexity, TR95-050, 1995.
	7	Oded Goldreich , Shmuel Safra, A Combinatorial Consistency Lemma with Application to Proving the PCP Theorem, SIAM Journal on Computing, v.29 n.4, p.1132-1154, Feb. 2000 to March 2000 [doi>10.1137/S0097539797315744]
	8	W. Hoeding. Probability inequalities for sums of bounded random variables. American Statistical Journal, pages 13--30, 1963.
	9	R. Impagliazzo, Hard-core distributions for somewhat hard problems, Proceedings of the 36th Annual Symposium on Foundations of Computer Science (FOCS'95), p.538, October 23-25, 1995
	10	Russell Impagliazzo , Ragesh Jaiswal , Valentine Kabanets, Approximately List-Decoding Direct Product Codes and Uniform Hardness Amplification, Proceedings of the 47th Annual IEEE Symposium on Foundations of Computer Science, p.187-196, October 21-24, 2006 [doi>10.1109/FOCS.2006.13]
	11	R. Impagliazzo, R. Jaiswal, and V. Kabanets. Cherno-type direct product theorems. In Proceeding of the Twenty-Seventh Annual International Cryptology Conference (CRYPTO'07), pages 500--516, 2007.
	12	Russell Impagliazzo , Avi Wigderson, P = BPP if E requires exponential circuits: derandomizing the XOR lemma, Proceedings of the twenty-ninth annual ACM symposium on Theory of computing, p.220-229, May 04-06, 1997, El Paso, Texas, United States [doi>10.1145/258533.258590]
	13	Leonid A. Levin, One-way functions and Pseudorandom generators, Combinatorica, v.7 n.4, p.357-363, Dec, 1987 [doi>10.1007/BF02579323]
	14	Ran Raz , Shmuel Safra, A sub-constant error-probability low-degree test, and a sub-constant error-probability PCP characterization of NP, Proceedings of the twenty-ninth annual ACM symposium on Theory of computing, p.475-484, May 04-06, 1997, El Paso, Texas, United States [doi>10.1145/258533.258641]
	15	Madhu Sudan , Luca Trevisan , Salil Vadhan, Pseudorandom generators without the XOR lemma, Journal of Computer and System Sciences, v.62 n.2, p.236-266, March 2001 [doi>10.1006/jcss.2000.1730]
	16	Luca Trevisan, On uniform amplification of hardness in NP, Proceedings of the thirty-seventh annual ACM symposium on Theory of computing, May 22-24, 2005, Baltimore, MD, USA [doi>10.1145/1060590.1060595]
	17	Luca Trevisan , Salil Vadhan, Pseudorandomness and Average-Case Complexity via Uniform Reductions, Proceedings of the 17th IEEE Annual Conference on Computational Complexity, p.129, May 21-24, 2002
	18	Andrew C. Yao, Theory and application of trapdoor functions, Proceedings of the 23rd Annual Symposium on Foundations of Computer Science (sfcs 1982), p.80-91, November 03-05, 1982
	19	David Zuckerman, Randomness-optimal oblivious sampling, Random Structures & Algorithms, v.11 n.4, p.345-367, Dec. 1997

CITED BY 4

	Ronen Shaltiel , Emanuele Viola, Hardness amplification proofs require majority, Proceedings of the 40th annual ACM symposium on Theory of computing, May 17-20, 2008, Victoria, British Columbia, Canada
	Boaz Barak , Moritz Hardt , Satyen Kale, The uniform hardcore lemma via approximate Bregman projections, Proceedings of the Nineteenth Annual ACM -SIAM Symposium on Discrete Algorithms, p.1193-1200, January 04-06, 2009, New York, New York
	Cynthia Dwork , Moni Naor , Omer Reingold , Guy N. Rothblum , Salil Vadhan, On the complexity of differentially private data release: efficient algorithms and hardness results, Proceedings of the 41st annual ACM symposium on Theory of computing, May 31-June 02, 2009, Bethesda, MD, USA
	Russell Impagliazzo , Valentine Kabanets , Avi Wigderson, New direct-product testers and 2-query PCPs, Proceedings of the 41st annual ACM symposium on Theory of computing, May 31-June 02, 2009, Bethesda, MD, USA