算法的多项式

Proceedings of the 50th Annual ACM SIGACT Symposium on Theory of Computing Pub Date : 2018-01-14 DOI:10.1145/3188745.3188958

Alexander A. Sherstov

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引用次数: 21

摘要

布尔函数f(x1,x2，…，xn)的近似度数是在1/3以内逐点逼近f的实多项式的最小度数。近似度的上界通常在学习理论、微分隐私和算法设计中有各种各样的应用。几乎所有已知的近似度的上界都是由量子查询复杂度的上界产生的。我们开发了一个第一性原理，经典的方法来多项式逼近布尔函数。我们利用它给出了几个基本问题的近似度的第一建设性上界:(i)对于k元明显性问题的O(n3/4−1/(4(2k−1)));(ii)对于k子集和问题，O(n1−1/(k+1));(iii)对于任何k- dnf或k- cnf公式，O(n1−1/(k+1));(iv) O(n3/4)对于满性问题。在所有的情况下，我们得到显式的，封闭形式的近似多项式，这些多项式与以前工作中的量子参数无关。我们的前三个结果符合量子查询复杂度的界限。我们的第四个结果多项式地提高了问题的Θ(n)量子查询复杂度，并反驳了几位专家关于满性近似度Ω(n)的猜想。特别地，我们展示了在近似度和量子查询复杂度之间具有多项式差距的第一个自然问题。

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Algorithmic polynomials

The approximate degree of a Boolean function f(x1,x2,…,xn) is the minimum degree of a real polynomial that approximates f pointwise within 1/3. Upper bounds on approximate degree have a variety of applications in learning theory, differential privacy, and algorithm design in general. Nearly all known upper bounds on approximate degree arise in an existential manner from bounds on quantum query complexity. We develop a first-principles, classical approach to the polynomial approximation of Boolean functions. We use it to give the first constructive upper bounds on the approximate degree of several fundamental problems: (i) O(n3/4−1/(4(2k−1))) for the k-element distinctness problem; (ii) O(n1−1/(k+1)) for the k-subset sum problem; (iii) O(n1−1/(k+1)) for any k-DNF or k-CNF formula; (iv) O(n3/4) for the surjectivity problem. In all cases, we obtain explicit, closed-form approximating polynomials that are unrelated to the quantum arguments from previous work. Our first three results match the bounds from quantum query complexity. Our fourth result improves polynomially on the Θ(n) quantum query complexity of the problem and refutes the conjecture by several experts that surjectivity has approximate degree Ω(n). In particular, we exhibit the first natural problem with a polynomial gap between approximate degree and quantum query complexity.

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Proceedings of the 50th Annual ACM SIGACT Symposium on Theory of Computing

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