Your search keyword '"Prahladh Harsha"' showing total 2 results

1. Super-Polylogarithmic Hypergraph Coloring Hardness via Low-Degree Long Codes

Author

Srikanth Srinivasan, Venkatesan Guruswami, Prahladh Harsha, Girish Varma, and Johan Håstad

Subjects

FOS: Computer and information sciences, Hypergraph, Code (set theory), Hardness Of Approximation, General Computer Science, Polynomial code, General Mathematics, Short Code, 0102 computer and information sciences, 02 engineering and technology, Computational Complexity (cs.CC), Computer Science::Computational Complexity, Hardness of approximation, 01 natural sciences, Omega, Graph, Combinatorics, Computer Science::Discrete Mathematics, 0202 electrical engineering, electronic engineering, information engineering, computer.programming_language, Mathematics, Discrete mathematics, Degree (graph theory), Multiplicative function, Pcps, 020206 networking & telecommunications, Complete coloring, Binary logarithm, Chromatic Number, Computer Science - Computational Complexity, Multipartite, 3-Uniform Hypergraphs, 010201 computation theory & mathematics, Cover, Hypergraph Coloring, computer

Abstract

We prove improved inapproximability results for hypergraph coloring using the low-degree polynomial code (aka, the 'short code' of Barak et. al. [FOCS 2012]) and the techniques proposed by Dinur and Guruswami [FOCS 2013] to incorporate this code for inapproximability results. In particular, we prove quasi-NP-hardness of the following problems on $n$-vertex hyper-graphs: * Coloring a 2-colorable 8-uniform hypergraph with $2^{2^{\Omega(\sqrt{\log\log n})}}$ colors. * Coloring a 4-colorable 4-uniform hypergraph with $2^{2^{\Omega(\sqrt{\log\log n})}}$ colors. * Coloring a 3-colorable 3-uniform hypergraph with $(\log n)^{\Omega(1/\log\log\log n)}$ colors. In each of these cases, the hardness results obtained are (at least) exponentially stronger than what was previously known for the respective cases. In fact, prior to this result, polylog n colors was the strongest quantitative bound on the number of colors ruled out by inapproximability results for O(1)-colorable hypergraphs. The fundamental bottleneck in obtaining coloring inapproximability results using the low- degree long code was a multipartite structural restriction in the PCP construction of Dinur-Guruswami. We are able to get around this restriction by simulating the multipartite structure implicitly by querying just one partition (albeit requiring 8 queries), which yields our result for 2-colorable 8-uniform hypergraphs. The result for 4-colorable 4-uniform hypergraphs is obtained via a 'query doubling' method. For 3-colorable 3-uniform hypergraphs, we exploit the ternary domain to design a test with an additive (as opposed to multiplicative) noise function, and analyze its efficacy in killing high weight Fourier coefficients via the pseudorandom properties of an associated quadratic form., Comment: 25 pages

Published

2017

2. Robust PCPs of Proximity, Shorter PCPs, and Applications to Coding

Author

Eli Ben-Sasson, Madhu Sudan, Prahladh Harsha, Salil Vadhan, and Oded Goldreich

Subjects

Property testing, Discrete mathematics, PCP theorem, TheoryofComputation_COMPUTATIONBYABSTRACTDEVICES, General Computer Science, General Mathematics, Multiplicative function, Code word, Computer Science::Computational Complexity, Locally decodable code, Mathematical proof, Binary logarithm, Satisfiability, Combinatorics, Log-log plot, TheoryofComputation_ANALYSISOFALGORITHMSANDPROBLEMCOMPLEXITY, Probability distribution, Mathematics, Coding (social sciences)

Abstract

We continue the study of the trade-off between the length of probabilistically checkable proofs (PCPs) and their query complexity, establishing the following main results (which refer to proofs of satisfiability of circuits of size $n$): 1. We present PCPs of length $\exp(o(\log\log n)^2)\cdot n$ that can be verified by making $o(\log\log n)$ Boolean queries. 2. For every \epsilon>0, we present PCPs of length $\exp(\log^\epsilon n)\cdot n$ that can be verified by making a constant number of Boolean queries. In both cases, false assertions are rejected with constant probability (which may be set to be arbitrarily close to 1). The multiplicative overhead on the length of the proof, introduced by transforming a proof into a probabilistically checkable one, is just quasi polylogarithmic in the first case (of query complexity $o(\log\log n)$), and is $2^{(\log n)^\epsilon}$, for any $\epsilon > 0$, in the second case (of constant query complexity). Our techniques include the introduction of a new variant of PCPs that we call “robust PCPs of proximity.” These new PCPs facilitate proof composition, which is a central ingredient in the construction of PCP systems. (A related notion and its composition properties were discovered independently by Dinur and Reingold.) Our main technical contribution is a construction of a “length-efficient” robust PCP of proximity. While the new construction uses many of the standard techniques used in PCP constructions, it does differ from previous constructions in fundamental ways, and in particular does not use the “parallelization” step of Arora et al. [J. ACM, 45 (1998), pp. 501-555]. The alternative approach may be of independent interest. We also obtain analogous quantitative results for locally testable codes. In addition, we introduce a relaxed notion of locally decodable codes and present such codes mapping $k$ information bits to codewords of length $k^{1+\epsilon}$ for any $\epsilon>0$.

Published

2006