A quantum analogue of convex optimization

Abstract

Convex optimization is the powerhouse behind the theory and practice of optimization. We introduce a quantum analogue of unconstrained convex optimization: computing the minimum eigenvalue of a Schr\"odinger operator h = - + V with convex potential V: Rn → R 0 such that V(x)→∞ as \|x\|→∞. For this problem, we present an efficient quantum algorithm, called the Fundamental Gap Algorithm (FGA), that computes the minimum eigenvalue of h up to error ε in polynomial time in n, 1/ε, and parameters that depend on V. Adiabatic evolution of the ground state is used as a key subroutine, which we analyze with novel techniques that allow us to focus on the low-energy space. We apply the FGA to give the first known polynomial-time algorithm for finding the lowest frequency of an n-dimensional convex drum, or mathematically, the minimum eigenvalue of the Dirichlet Laplacian on an n-dimensional region that is defined by m linear constraints in polynomial time in n, m, 1/ε and the radius R of a ball encompassing the region.

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