English

Vanishing-Error Approximate Degree and QMA Complexity

Computational Complexity 2019-09-18 v1

Abstract

The ϵ\epsilon-approximate degree of a function f ⁣:X{0,1}f\colon X \to \{0, 1\} is the least degree of a multivariate real polynomial pp such that p(x)f(x)ϵ|p(x)-f(x)| \leq \epsilon for all xXx \in X. We determine the ϵ\epsilon-approximate degree of the element distinctness function, the surjectivity function, and the permutation testing problem, showing they are Θ(n2/3log1/3(1/ϵ))\Theta(n^{2/3} \log^{1/3}(1/\epsilon)), Θ~(n3/4log1/4(1/ϵ))\tilde\Theta(n^{3/4} \log^{1/4}(1/\epsilon)), and Θ(n1/3log2/3(1/ϵ))\Theta(n^{1/3} \log^{2/3}(1/\epsilon)), respectively. Previously, these bounds were known only for constant ϵ.\epsilon. We also derive a connection between vanishing-error approximate degree and quantum Merlin--Arthur (QMA) query complexity. We use this connection to show that the QMA complexity of permutation testing is Ω(n1/4)\Omega(n^{1/4}). This improves on the previous best lower bound of Ω(n1/6)\Omega(n^{1/6}) due to Aaronson (Quantum Information & Computation, 2012), and comes somewhat close to matching a known upper bound of O(n1/3)O(n^{1/3}).

Cite

@article{arxiv.1909.07498,
  title  = {Vanishing-Error Approximate Degree and QMA Complexity},
  author = {Alexander A. Sherstov and Justin Thaler},
  journal= {arXiv preprint arXiv:1909.07498},
  year   = {2019}
}
R2 v1 2026-06-23T11:17:18.990Z