Mind the gap: Achieving a super-Grover quantum speedup by jumping to the end
Abstract
We present a quantum algorithm that has rigorous runtime guarantees for several families of binary optimization problems, including Quadratic Unconstrained Binary Optimization (QUBO), Ising spin glasses (p-spin model), and k-local constraint satisfaction problems (k-CSP). We show that either (a) the algorithm finds the optimal solution in time O*(2(0.5-c)n) for an n-independent constant c, a 2cn advantage over Grover's algorithm; or (b) there are sufficiently many low-cost solutions such that classical random guessing produces a (1-η) approximation to the optimal cost value in sub-exponential time for arbitrarily small choice of η. Additionally, we show that for a large fraction of random instances from the k-spin model and for any sufficiently close-to-regular, fully satisfiable (or slightly frustrated) k-CSP formula, statement (a) is the case. The algorithm and its analysis is largely inspired by Hastings' short-path algorithm [Quantum 2 (2018) 78].
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