Symmetries, Graph Properties, and Quantum Speedups

被引：19

作者：

Ben-David, Shalev ^{[1
]}

Childs, Andrew M. ^{[2
,3
,4
]}

Gilyen, Andras ^{[5
,6
]}

Kretschmer, William ^{[7
]}

Podder, Supartha ^{[8
]}

Wang, Daochen ^{[4
,9
]}

机构：

[1] Univ Waterloo, Cheriton Sch Comp Sci, Waterloo, ON, Canada

[2] Univ Maryland, Dept Comp Sci, Baltimore, MD 21201 USA

[3] Univ Maryland, Inst Adv Comp Studies, Baltimore, MD 21201 USA

[4] Univ Maryland, Joint Ctr Quantum Informat & Comp Sci, Baltimore, MD 21201 USA

[5] CALTECH, Inst Quantum Informat & Matter, Pasadena, CA 91125 USA

[6] Univ Calif Berkeley, Simons Inst Theory Comp, Berkeley, CA 94720 USA

[7] Univ Texas Austin, Dept Comp Sci, Austin, TX 78712 USA

[8] Univ Ottawa, Dept Math & Stat, Ottawa, ON, Canada

[9] Univ Maryland, Dept Math, Baltimore, MD 21201 USA

来源：

2020 IEEE 61ST ANNUAL SYMPOSIUM ON FOUNDATIONS OF COMPUTER SCIENCE (FOCS 2020) | 2020年

基金：

美国国家科学基金会;

关键词：

quantum query complexity; graph properties; property testing; LOWER BOUNDS; COMPLEXITY; COLLISION;

D O I：

10.1109/FOCS46700.2020.00066

中图分类号：

TP301 [理论、方法];

学科分类号：

081202 ;

摘要：

Aaronson and Ambainis (2009) and Chailloux (2018) showed that fully symmetric (partial) functions do not admit exponential quantum query speedups. This raises a natural question: how symmetric must a function be before it cannot exhibit a large quantum speedup? In this work, we prove that hypergraph symmetries in the adjacency matrix model allow at most a polynomial separation between randomized and quantum query complexities. We also show that, remarkably, permutation groups constructed out of these symmetries are essentially the only permutation groups that prevent super-polynomial quantum speedups. We prove this by fully characterizing the primitive permutation groups that allow super-polynomial quantum speedups. In contrast, in the adjacency list model for bounded-degree graphs-where graph symmetry is manifested differently-we exhibit a property testing problem that shows an exponential quantum speedup. These results resolve open questions posed by Ambainis, Childs, and Liu (2010) and Montanaro and de Wolf (2013).

引用

页码：649 / 660

页数：12

共 25 条

[1] Quantum lower bounds for the collision and the element distinctness problems [J].

Aaronson, S ;

Shi, YY .

JOURNAL OF THE ACM, 2004, 51 (04) :595-605

[2]

Aaronson S., 2014, Theory Comput, V10, P133, DOI DOI 10.4086/TOC.2014.V010A006

[3] Sculpting Quantum Speedups [J].

Aaronson, Scott ;

Ben-David, Shalev .

31ST CONFERENCE ON COMPUTATIONAL COMPLEXITY (CCC 2016), 2016, 50

[4]

Aaronson S, 2015, ACM S THEORY COMPUT, P307, DOI [10.1137/15M1050902, 10.1145/2746539.2746547]

[5] Testing κ-colorability [J].

Alon, N ;

Krivelevich, M .

SIAM JOURNAL ON DISCRETE MATHEMATICS, 2002, 15 (02) :211-227

[6]

Ambainis Andris, 2011, Approximation, Randomization, and Combinatorial Optimization Algorithms and Techniques. Proceedings 14th International Workshop, APPROX 2011 and 15th International Workshop, RANDOM 2011, P365, DOI 10.1007/978-3-642-22935-0_31

[7] Quantum lower bounds by polynomials [J].

Beals, R ;

Buhrman, H ;

Cleve, R ;

Mosca, M ;

De Wolf, R .

JOURNAL OF THE ACM, 2001, 48 (04) :778-797

[8]

Belovs A., 2013, P 4 C INNOVATIONS TH, P323

[9]

Ben-David S, 2016, P 11 C THEOR QUANT C

[10] Complexity measures and decision tree complexity: a survey [J].

Buhrman, H ;

de Wolf, R .

THEORETICAL COMPUTER SCIENCE, 2002, 288 (01) :21-43

← 1 2 3 →