Abstract
In order to treat all-to-all connected quadratic binary optimization problems (QUBO) with hardware quantum annealers, an embedding of the original problem is required due to the sparsity of the hardware's topology. Embedding fully-connected graphs - typically found in industrial applications - incurs a quadratic space overhead and thus a significant overhead in the time to solution. Here we investigate this embedding penalty of established planar embedding schemes such as minor embedding on a square lattice, minor embedding on a Chimera graph, and the Lechner-Hauke-Zoller scheme using simulated quantum annealing on classical hardware. Large-scale quantum Monte Carlo simulation suggest a polynomial time-to-solution overhead. Our results demonstrate that standard analog quantum annealing hardware is at a disadvantage in comparison to classical digital annealers, as well as gate-model quantum annealers and could also serve as benchmark for improvements of the standard quantum annealing protocol.
Highlights
The availability of commercial quantum annealing devices [1,2,3] has revolutionized optimization across many disciplines
In this work, we focus on three embedding schemes: embedding on a square lattice, embedding on a chimera lattice, and the parity adiabatic quantum optimization (PAQO) or Lechner-Hauke-Zoller (LHZ) scheme
We study the logical problem directly, the problem embedded in a square lattice, the problem embedded on a chimera lattice, and the problem encoded in the PAQO scheme
Summary
The availability of commercial quantum annealing devices [1,2,3] has revolutionized (quantum) optimization across many disciplines. Both mapping (binary) optimization problems onto 2-local Hamiltonians, as well as the embedding of the resulting 2-local Hamiltonian onto the hardwired topology of the quantum annealer, represent potentially large bottlenecks for solving application problems that typically do not perfectly fit the hardware layout
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