research-article

Interactive shallow Clifford circuits: Quantum advantage against NC¹ and beyond

Authors:

Luke SchaefferAuthors Info & Claims

STOC 2020: Proceedings of the 52nd Annual ACM SIGACT Symposium on Theory of Computing

Pages 875 - 888

https://doi.org/10.1145/3357713.3384332

Published: 22 June 2020 Publication History

Abstract

Recent work of Bravyi et al. and follow-up work by Bene Watts et al. demonstrates a quantum advantage for shallow circuits: constant-depth quantum circuits can perform a task which constant-depth classical (i.e., ⁰) circuits cannot. Their results have the advantage that the quantum circuit is fairly practical, and their proofs are free of hardness assumptions (e.g., factoring is classically hard, etc.). Unfortunately, constant-depth classical circuits are too weak to yield a convincing real-world demonstration of quantum advantage. We attempt to hold on to the advantages of the above results, while increasing the power of the classical model. Our main result is a two-round interactive task which is solved by a constant-depth quantum circuit (using only Clifford gates, between neighboring qubits of a 2D grid, with Pauli measurements), but such that any classical solution would necessarily solve -hard problems. This implies a more powerful class of constant-depth classical circuits (e.g., ⁰[p] for any prime p) unconditionally cannot perform the task. Furthermore, under standard complexity-theoretic conjectures, log-depth circuits and log-space Turing machines cannot perform the task either. Using the same techniques, we prove hardness results for weaker complexity classes under more restrictive circuit topologies. Specifically, we give ⁰ interactive tasks on 2 × n and 1 × n grids which require classical simulations of power ¹ and ⁰[6], respectively. Moreover, these hardness results are robust to a small constant fraction of error in the classical simulation.

We use ideas and techniques from the theory of branching programs, quantum contextuality, measurement-based quantum computation, and Kilian randomization.

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Cited By

Oliveira MBarbosa LGalvão E(2024)Quantum advantage in temporally flat measurement-based quantum computationQuantum10.22331/q-2024-04-09-13128(1312)Online publication date: 9-Apr-2024
https://doi.org/10.22331/q-2024-04-09-1312
Gosset DGrier DKerzner ASchaeffer L(2024)Fast simulation of planar Clifford circuitsQuantum10.22331/q-2024-02-12-12518(1251)Online publication date: 12-Feb-2024
https://doi.org/10.22331/q-2024-02-12-1251
Kane DOstuni AWu KMohar BShinkar IO'Donnell R(2024)Locality Bounds for Sampling Hamming SlicesProceedings of the 56th Annual ACM Symposium on Theory of Computing10.1145/3618260.3649670(1279-1286)Online publication date: 10-Jun-2024
https://dl.acm.org/doi/10.1145/3618260.3649670
Show More Cited By

Index Terms

Interactive shallow Clifford circuits: Quantum advantage against NC¹ and beyond
1. Theory of computation
  1. Computational complexity and cryptography
    1. Quantum complexity theory

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cover image ACM Conferences

STOC 2020: Proceedings of the 52nd Annual ACM SIGACT Symposium on Theory of Computing

June 2020

1429 pages

ISBN:9781450369794

DOI:10.1145/3357713

General Chairs:
Konstantin Makarychev
Northwestern University, USA
,
Yury Makarychev
Toyota Technological Institute at Chicago, USA
,
Madhur Tulsiani
Toyota Technological Institute at Chicago, USA
,
Gautam Kamath
University of Waterloo, Canada
,
Program Chair:
Julia Chuzhoy
Toyota Technological Institute at Chicago, USA

Copyright © 2020 ACM.

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SIGACT: ACM Special Interest Group on Algorithms and Computation Theory

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Association for Computing Machinery

New York, NY, United States

Publication History

Published: 22 June 2020

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STOC '20

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SIGACT

STOC '20: 52nd Annual ACM SIGACT Symposium on Theory of Computing

June 22 - 26, 2020

IL, Chicago, USA

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Overall Acceptance Rate 1,469 of 4,586 submissions, 32%

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Cited By

Oliveira MBarbosa LGalvão E(2024)Quantum advantage in temporally flat measurement-based quantum computationQuantum10.22331/q-2024-04-09-13128(1312)Online publication date: 9-Apr-2024
https://doi.org/10.22331/q-2024-04-09-1312
Gosset DGrier DKerzner ASchaeffer L(2024)Fast simulation of planar Clifford circuitsQuantum10.22331/q-2024-02-12-12518(1251)Online publication date: 12-Feb-2024
https://doi.org/10.22331/q-2024-02-12-1251
Kane DOstuni AWu KMohar BShinkar IO'Donnell R(2024)Locality Bounds for Sampling Hamming SlicesProceedings of the 56th Annual ACM Symposium on Theory of Computing10.1145/3618260.3649670(1279-1286)Online publication date: 10-Jun-2024
https://dl.acm.org/doi/10.1145/3618260.3649670
Morimae TYamakawa T(2024)Quantum Advantage from One-Way FunctionsAdvances in Cryptology – CRYPTO 202410.1007/978-3-031-68388-6_13(359-392)Online publication date: 18-Aug-2024
https://dl.acm.org/doi/10.1007/978-3-031-68388-6_13
Bene Watts AHelton J(2023)3XOR Games with Perfect Commuting Operator Strategies Have Perfect Tensor Product Strategies and are Decidable in Polynomial TimeCommunications in Mathematical Physics10.1007/s00220-022-04615-3400:2(731-791)Online publication date: 10-Feb-2023
https://doi.org/10.1007/s00220-022-04615-3
Zhang SBao JSun YLi LSun HZhang X(2023)An Exact and Practical Classical Strategy for 2D Graph State SamplingAnnalen der Physik10.1002/andp.202200531535:2Online publication date: 15-Jan-2023
https://doi.org/10.1002/andp.202200531
Daniel AMiyake A(2021)Quantum Computational Advantage with String Order Parameters of One-Dimensional Symmetry-Protected Topological OrderPhysical Review Letters10.1103/PhysRevLett.126.090505126:9Online publication date: 5-Mar-2021
https://doi.org/10.1103/PhysRevLett.126.090505
Maslov DKim JBravyi SYoder TSheldon S(2021)Quantum advantage for computations with limited spaceNature Physics10.1038/s41567-021-01271-7Online publication date: 28-Jun-2021
https://doi.org/10.1038/s41567-021-01271-7

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