Quantum lower bounds by polynomials 论文

2001Journal of the ACM引用 656
Quantum Computing Algorithms and ArchitectureComplexity and Algorithms in GraphsQuantum Information and Cryptography

详细信息

发表期刊/会议
Journal of the ACM
发表日期
2001-07-01
发表年份
2001

关键词

Quantum Computing Algorithms and ArchitectureComplexity and Algorithms in GraphsQuantum Information and Cryptography

摘要

We examine the number of queries to input variables that a quantum algorithm requires to compute Boolean functions on {0,1} N in the black-box model. We show that the exponential quantum speed-up obtained for partial functions (i.e., problems involving a promise on the input) by Deutsch and Jozsa, Simon, and Shor cannot be obtained for any total function: if a quantum algorithm computes some total Boolean function f with small error probability using T black-box queries, then there is a classical deterministic algorithm that computes f exactly with O ( Ts 6 ) queries. We also give asymptotically tight characterizations of T for all symmetric f in the exact, zero-error, and bounded-error settings. Finally, we give new precise bounds for AND, OR, and PARITY. Our results are a quantum extension of the so-called polynomial method, which has been successfully applied in classical complexity theory, and also a quantum extension of results by Nisan about a polynomial relationship between randomized and deterministic decision tree complexity.