Abstract
We consider the problem of testing if a given function \(f : \mathbb{F}_2^n \rightarrow \mathbb{F}_2\) is close to any degree d polynomial in n variables, also known as the problem of testing Reed-Muller codes. We are interested in determining the query-complexity of distinguishing with constant probablity between the case where f is a degree d polynomial and the case where f is Ω(1)-far from all degree d polynomials. Alon et al. [AKK+05] proposed and analyzed a natural 2d + 1-query test T 0, and showed that it accepts every degree d polynomial with probability 1, while rejecting functions that are Ω(1)-far with probability Ω(1/(d 2d)). This leads to a O(d 4d)-query test for degree d Reed-Muller codes.
We give an asymptotically optimal analysis of T 0, showing that it rejects functions that are Ω(1)-far with Ω(1)-probability (so the rejection probability is a universal constant independent of d and n). In particular, this implies that the query complexity of testing degree d Reed-Muller codes is O(2d).
Our proof works by induction on n, and yields a new analysis of even the classical Blum-Luby-Rubinfeld [BLR93] linearity test, for the setting of functions mapping \(\mathbb{F}_2^n\) to \(\mathbb{F}_2\). Our results also imply a “query hierarchy” result for property testing of affine-invariant properties: For every function q(n), it gives an affine-invariant property that is testable with O(q(n))-queries, but not with o(q(n))-queries, complementing an analogous result of [GKNR08] for graph properties.
This is a brief overview of the results in the paper [BKS+09].
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References
Alon, N., Beigel, R.: Lower bounds for approximations by low degree polynomials over Z m . In: IEEE Conference on Computational Complexity, pp. 184–187 (2001)
Alon, N., Kaufman, T., Krivelevich, M., Litsyn, S., Ron, D.: Testing Reed-Muller codes. IEEE Transactions on Information Theory 51(11), 4032–4039 (2005)
Bellare, M., Coppersmith, D., Håstad, J., Kiwi, M., Sudan, M.: Linearity testing over characteristic two. IEEE Transactions on Information Theory 42(6), 1781–1795 (1996)
Brown, M.V., Calkin, N.J., James, K., King, A.J., Lockard, S., Rhoades, R.C.: Trivial Selmer groups and even partitions of a graph. INTEGERS 6 (December 2006)
Babai, L., Fortnow, L., Lund, C.: Non-deterministic exponential time has two-prover interactive protocols. Computational Complexity 1(1), 3–40 (1991)
Babai, L., Fortnow, L., Levin, L.A., Szegedy, M.: Checking computations in polylogarithmic time. In: Proceedings of the 23rd ACM Symposium on the Theory of Computing, pp. 21–32. ACM Press, New York (1991)
Bhattacharyya, A., Kopparty, S., Schoenebeck, G., Sudan, M., Zuckerman, D.: Optimal testing of Reed-Muller codes. ECCC Technical Report, TR09-086 (October 2009)
Blum, M., Luby, M., Rubinfeld, R.: Self-testing/correcting with applications to numerical problems. J. Comp. Sys. Sci. 47, 549–595 (1993); Earlier version in STOC 1990 (1990)
Brent, R.P., McKay, B.D.: On determinants of random symmetric matrices over ℤ m . ARS Combinatoria 26A, 57–64 (1988)
Feige, U., Goldwasser, S., Lovász, L., Safra, S., Szegedy, M.: Interactive proofs and the hardness of approximating cliques. Journal of the ACM 43(2), 268–292 (1996)
Goldreich, O., Goldwasser, S., Ron, D.: Property testing and its connection to learning and approximation. Journal of the ACM 45, 653–750 (1998)
Goldreich, O., Krivelevich, M., Newman, I., Rozenberg, E.: Hierarchy theorems for property testing. Electronic Colloquium on Computational Complexity (ECCC) 15(097) (2008)
Gowers, W.T.: A new proof of Szeméredi’s theorem for arithmetic progressions of length four. Geometric Functional Analysis 8(3), 529–551 (1998)
Gowers, W.T.: A new proof of Szeméredi’s theorem. Geometric Functional Analysis 11(3), 465–588 (2001)
Green, B., Tao, T.: An inverse theorem for the Gowers U3 norm. arXiv.org:math/0503014 (2005)
Green, B., Tao, T.: The distribution of polynomials over finite fields, i with applications to the Gowers norms. Technical report (November 2007), http://arxiv.org/abs/0711.3191v1
Kaufman, T., Sudan, M.: Algebraic property testing: the role of invariance. In: STOC 2008: Proceedings of the 40th annual ACM symposium on Theory of computing, pp. 403–412. ACM, New York (2008)
Lovett, S., Meshulam, R., Samorodnitsky, A.: Inverse conjecture for the Gowers norm is false. In: Ladner, R.E., Dwork, C. (eds.) STOC, pp. 547–556. ACM, New York (2008)
Rubinfeld, R., Sudan, M.: Robust characterizations of polynomials with applications to program testing. SIAM J. on Comput. 25, 252–271 (1996)
Viola, E., Wigderson, A.: Norms, XOR lemmas, and lower bounds for GF(2) polynomials and multiparty protocols. In: Twenty-Second Annual IEEE Conference on Computational Complexity, CCC 2007, pp. 141–154 (June 2007)
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Bhattacharyya, A., Kopparty, S., Schoenebeck, G., Sudan, M., Zuckerman, D. (2010). Optimal Testing of Reed-Muller Codes. In: Goldreich, O. (eds) Property Testing. Lecture Notes in Computer Science, vol 6390. Springer, Berlin, Heidelberg. https://doi.org/10.1007/978-3-642-16367-8_19
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