Compilation of Fault-Tolerant Quantum Heuristics for Combinatorial
Optimization
- URL: http://arxiv.org/abs/2007.07391v2
- Date: Wed, 5 Aug 2020 15:27:44 GMT
- Title: Compilation of Fault-Tolerant Quantum Heuristics for Combinatorial
Optimization
- Authors: Yuval R. Sanders, Dominic W. Berry, Pedro C. S. Costa, Louis W.
Tessler, Nathan Wiebe, Craig Gidney, Hartmut Neven and Ryan Babbush
- Abstract summary: We explore which quantum algorithms for optimization might be most practical to try out on a small fault-tolerant quantum computer.
Our results discourage the notion that any quantum optimization realizing only a quadratic speedup will achieve an advantage over classical algorithms.
- Score: 0.14755786263360526
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Here we explore which heuristic quantum algorithms for combinatorial
optimization might be most practical to try out on a small fault-tolerant
quantum computer. We compile circuits for several variants of quantum
accelerated simulated annealing including those using qubitization or Szegedy
walks to quantize classical Markov chains and those simulating spectral gap
amplified Hamiltonians encoding a Gibbs state. We also optimize fault-tolerant
realizations of the adiabatic algorithm, quantum enhanced population transfer,
the quantum approximate optimization algorithm, and other approaches. Many of
these methods are bottlenecked by calls to the same subroutines; thus,
optimized circuits for those primitives should be of interest regardless of
which heuristic is most effective in practice. We compile these bottlenecks for
several families of optimization problems and report for how long and for what
size systems one can perform these heuristics in the surface code given a range
of resource budgets. Our results discourage the notion that any quantum
optimization heuristic realizing only a quadratic speedup will achieve an
advantage over classical algorithms on modest superconducting qubit surface
code processors without significant improvements in the implementation of the
surface code. For instance, under quantum-favorable assumptions (e.g., that the
quantum algorithm requires exactly quadratically fewer steps), our analysis
suggests that quantum accelerated simulated annealing would require roughly a
day and a million physical qubits to optimize spin glasses that could be solved
by classical simulated annealing in about four CPU-minutes.
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