English

Fractional Pseudorandom Generators from Any Fourier Level

Computational Complexity 2020-11-10 v3

Abstract

We prove new results on the polarizing random walk framework introduced in recent works of Chattopadhyay {et al.} [CHHL19,CHLT19] that exploit L1L_1 Fourier tail bounds for classes of Boolean functions to construct pseudorandom generators (PRGs). We show that given a bound on the kk-th level of the Fourier spectrum, one can construct a PRG with a seed length whose quality scales with kk. This interpolates previous works, which either require Fourier bounds on all levels [CHHL19], or have polynomial dependence on the error parameter in the seed length [CHLT10], and thus answers an open question in [CHLT19]. As an example, we show that for polynomial error, Fourier bounds on the first O(logn)O(\log n) levels is sufficient to recover the seed length in [CHHL19], which requires bounds on the entire tail. We obtain our results by an alternate analysis of fractional PRGs using Taylor's theorem and bounding the degree-kk Lagrange remainder term using multilinearity and random restrictions. Interestingly, our analysis relies only on the \emph{level-k unsigned Fourier sum}, which is potentially a much smaller quantity than the L1L_1 notion in previous works. By generalizing a connection established in [CHH+20], we give a new reduction from constructing PRGs to proving correlation bounds. Finally, using these improvements we show how to obtain a PRG for F2\mathbb{F}_2 polynomials with seed length close to the state-of-the-art construction due to Viola [Vio09], which was not known to be possible using this framework.

Keywords

Cite

@article{arxiv.2008.01316,
  title  = {Fractional Pseudorandom Generators from Any Fourier Level},
  author = {Eshan Chattopadhyay and Jason Gaitonde and Chin Ho Lee and Shachar Lovett and Abhishek Shetty},
  journal= {arXiv preprint arXiv:2008.01316},
  year   = {2020}
}
R2 v1 2026-06-23T17:37:21.116Z