Bounded Independence Plus Noise Fools Products

Haramaty, Elad; Lee, Chin Ho; Viola, Emanuele

doi:10.1137/17m1129088

Cited by 11 publications

(17 citation statements)

References 50 publications

(69 reference statements)

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“…In their construction, the seed length is (1 − Ω(1))n, whereas our seed length is sublinear in n. However, an advantage of their construction is that it works even when the reading order of the bits is unknown, while we require it to be known in advance. Haramaty, Lee and Viola obtained some improved bounds for the related model of product tests [HLV17].…”

Section: Related Workmentioning

confidence: 99%

Pseudorandom Bits for Oblivious Branching Programs

Gurjar

Volk

2020

ACM Trans. Comput. Theory

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We construct a pseudorandom generator which fools read-k oblivious branching programs and, more generally, any linear length oblivious branching program, assuming that the sequence according to which the bits are read is known in advance. For polynomial width branching programs, the seed lengths in our constructions areÕ(n 1−1/2 k−1 ) (for the read-k case) and O(n/ log log n) (for the linear length case). Previously, the best construction for these models required seed length (1 − Ω(1))

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Section: Related Workmentioning

confidence: 99%

Pseudorandom Bits for Oblivious Branching Programs

Gurjar

Volk

2020

ACM Trans. Comput. Theory

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“…Handling arbitrary order is significantly more challenging, because the classical space-bounded generators [31,22] only work in fixed order [37,5]. Our previous work with Haramaty [20] gave the first generators for this class, but its dependence on k is poor: the seed length is always ≥ √ k. In this paper we improve the dependence on k exponentially, though the results in [20] remain unsurpassed when k is very small, e. g., k = O(1). We actually obtain two incomparable generators.…”

Section: Definition 14 (Product Tests)mentioning

confidence: 99%

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Lee¹,

Viola²

2020

ToC

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We construct pseudorandom generators with improved seed length for several classes of tests. First, we consider the class of read-once polynomials over GF(2) in m variables. For error ε we obtain seed lengthÕ(log(m/ε) log(1/ε)). This is optimal up to a factor of log(1/ε) • poly log log(m/ε). The previous best seed length was polylogarithmic in m and 1/ε. Second, we consider product tests f : {0, 1} m → C ≤1. These tests are the product of k functions f i : {0, 1} → C ≤1 , where the inputs of the f i are disjoint subsets of the m variables and C ≤1 is the complex unit disk. Here we obtain seed length • polylog(m/ε). This implies better generators for other classes of tests. If moreover the f i have output range {−1, 0, 1} then we obtain seed lengthÕ((log(k/ε) +)(log(1/ε) + log log m)). This is again optimal up to a factor of log(1/ε) • polylog(, log k, log m, log(1/ε)), while the previous best seed length was ≥ √ k. A main component of our proofs is showing that these classes of tests are fooled by almost d-wise independent distributions perturbed with noise.

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“…PRGs for product-functions were constructed in previous work, however none achieve the parameters we need. Haramaty, Lee and Viola [HLV17] and Lee and Viola [LV17] constructed PRGs with seed length O(b + mb log(1/ε)) and O((b + log(m/ε)) · log(1/ε)) respectively for such functions. While the latter is nearly optimal for constant ε, we require ε to be smaller than 1/m, since the reduction in the previous section from [BDVY13] incurs a multiplicative factor of m on the error.…”

Section: Pseudorandom Restrictions For the Xor Of Short Width-3 Robpsmentioning

confidence: 99%

Pseudorandom generators for width-3 branching programs

Meka

Reingold

Tal

2019

Proceedings of the 51st Annual ACM SIGACT Symposium on Theory of Computing

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We construct pseudorandom generators of seed length O(log(n)·log(1/ε)) that ε-fool ordered read-once branching programs (ROBPs) of width 3 and length n. For unordered ROBPs, we construct pseudorandom generators with seed length O(log(n) · poly(1/ε)). This is the first improvement for pseudorandom generators fooling width 3 ROBPs since the work of Nisan [Nis92].Our constructions are based on the "iterated milder restrictions" approach of [GMR + 12] (which further extends the Ajtai-Wigderson framework [AW85]), combined with the INW-generator [INW94] at the last step (as analyzed by [BRRY14]). For the unordered case we combine iterated milder restrictions with the generator of [CHHL18].Two conceptual ideas that play an important role in our analysis are: *

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Bounded Independence Plus Noise Fools Products

Cited by 11 publications

References 50 publications

Pseudorandom Bits for Oblivious Branching Programs

Pseudorandom Bits for Oblivious Branching Programs

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Pseudorandom generators for width-3 branching programs

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