English

On Restricting No-Junta Boolean Function and Degree Lower Bounds by Polynomial Method

Computational Complexity 2015-02-05 v2

Abstract

Let Fn\mathcal{F}_{n}^* be the set of Boolean functions depending on all nn variables. We prove that for any fFnf\in \mathcal{F}_{n}^*, fxi=0f|_{x_i=0} or fxi=1f|_{x_i=1} depends on the remaining n1n-1 variables, for some variable xix_i. This existent result suggests a possible way to deal with general Boolean functions via its subfunctions of some restrictions. As an application, we consider the degree lower bound of representing polynomials over finite rings. Let fFnf\in \mathcal{F}_{n}^* and denote the exact representing degree over the ring Zm\mathbb{Z}_m (with the integer m>2m>2) as dm(f)d_m(f). Let m=Πi=1rpieim=\Pi_{i=1}^{r}p_i^{e_i}, where pip_i's are distinct primes, and rr and eie_i's are positive integers. If ff is symmetric, then mdp1e1(f)...dprer(f)>nm\cdot d_{p_1^{e_1}}(f)... d_{p_r^{e_r}}(f) > n. If ff is non-symmetric, by the second moment method we prove almost always mdp1e1(f)...dprer(f)>lgn1m\cdot d_{p_1^{e_1}}(f)... d_{p_r^{e_r}}(f) > \lg{n}-1. In particular, as m=pqm=pq where pp and qq are arbitrary distinct primes, we have dp(f)dq(f)=Ω(n)d_p(f)d_q(f)=\Omega(n) for symmetric ff and dp(f)dq(f)=Ω(lgn1)d_p(f)d_q(f)=\Omega(\lg{n}-1) almost always for non-symmetric ff. Hence any nn-variate symmetric Boolean function can have exact representing degree o(n)o(\sqrt{n}) in at most one finite field, and for non-symmetric functions, with o(lgn)o(\sqrt{\lg{n}})-degree in at most one finite field.

Keywords

Cite

@article{arxiv.1502.00357,
  title  = {On Restricting No-Junta Boolean Function and Degree Lower Bounds by Polynomial Method},
  author = {Chia-Jung Lee and Satya V. Lokam and Shi-Chun Tsai and Ming-Chuan Yang},
  journal= {arXiv preprint arXiv:1502.00357},
  year   = {2015}
}

Comments

5 pages, ISIT 2015. Simplified proof

R2 v1 2026-06-22T08:18:32.764Z