English

Polynomials, Quantum Query Complexity, and Grothendieck's Inequality

Quantum Physics 2016-07-01 v3 Computational Complexity

Abstract

We show an equivalence between 1-query quantum algorithms and representations by degree-2 polynomials. Namely, a partial Boolean function ff is computable by a 1-query quantum algorithm with error bounded by ϵ<1/2\epsilon<1/2 iff ff can be approximated by a degree-2 polynomial with error bounded by ϵ<1/2\epsilon'<1/2. This result holds for two different notions of approximation by a polynomial: the standard definition of Nisan and Szegedy and the approximation by block-multilinear polynomials recently introduced by Aaronson and Ambainis (STOC'2015, arxiv:1411.5729). We also show two results for polynomials of higher degree. First, there is a total Boolean function which requires Ω~(n)\tilde{\Omega}(n) quantum queries but can be represented by a block-multilinear polynomial of degree O~(n)\tilde{O}(\sqrt{n}). Thus, in the general case (for an arbitrary number of queries), block-multilinear polynomials are not equivalent to quantum algorithms. Second, for any constant degree kk, the two notions of approximation by a polynomial (the standard and the block-multilinear) are equivalent. As a consequence, we solve an open problem of Aaronson and Ambainis, showing that one can estimate the value of any bounded degree-kk polynomial p:{0,1}n[1,1]p:\{0, 1\}^n \rightarrow [-1, 1] with O(n112k)O(n^{1-\frac{1}{2k}}) queries.

Keywords

Cite

@article{arxiv.1511.08682,
  title  = {Polynomials, Quantum Query Complexity, and Grothendieck's Inequality},
  author = {Scott Aaronson and Andris Ambainis and Jānis Iraids and Martins Kokainis and Juris Smotrovs},
  journal= {arXiv preprint arXiv:1511.08682},
  year   = {2016}
}

Comments

24 pages

R2 v1 2026-06-22T11:55:34.735Z