English

Time-Space Lower Bounds for Simulating Proof Systems with Quantum and Randomized Verifiers

Computational Complexity 2021-02-01 v2

Abstract

A line of work initiated by Fortnow in 1997 has proven model-independent time-space lower bounds for the SAT\mathsf{SAT} problem and related problems within the polynomial-time hierarchy. For example, for the SAT\mathsf{SAT} problem, the state-of-the-art is that the problem cannot be solved by random-access machines in ncn^c time and no(1)n^{o(1)} space simultaneously for c<2cos(π7)1.801c < 2\cos(\frac{\pi}{7}) \approx 1.801. We extend this lower bound approach to the quantum and randomized domains. Combining Grover's algorithm with components from SAT\mathsf{SAT} time-space lower bounds, we show that there are problems verifiable in O(n)O(n) time with quantum Merlin-Arthur protocols that cannot be solved in ncn^c time and no(1)n^{o(1)} space simultaneously for c<3+322.366c < \frac{3+\sqrt{3}}{2} \approx 2.366, a super-quadratic time lower bound. This result and the prior work on SAT\mathsf{SAT} can both be viewed as consequences of a more general formula for time lower bounds against small-space algorithms, whose asymptotics we study in full. We also show lower bounds against randomized algorithms: there are problems verifiable in O(n)O(n) time with (classical) Merlin-Arthur protocols that cannot be solved in ncn^c randomized time and no(1)n^{o(1)} space simultaneously for c<1.465c < 1.465, improving a result of Diehl. For quantum Merlin-Arthur protocols, the lower bound in this setting can be improved to c<1.5c < 1.5.

Keywords

Cite

@article{arxiv.2012.00330,
  title  = {Time-Space Lower Bounds for Simulating Proof Systems with Quantum and Randomized Verifiers},
  author = {Abhijit S. Mudigonda and R. Ryan Williams},
  journal= {arXiv preprint arXiv:2012.00330},
  year   = {2021}
}

Comments

38 pages, 5 figures. To appear in ITCS 2021

R2 v1 2026-06-23T20:37:53.677Z