Numerical study of computational cost of maintaining adiabaticity for long paths

Abstract

Recent work argued that the scaling of a dimensionless quantity QD with path length is a better proxy for quantifying the scaling of the computational cost of maintaining adiabaticity than the timescale. It also conjectured that generically the scaling will be superlinear (although special cases exist in which it is linear). The quantity QD depends only on the properties of ground states along the Hamiltonian path and the rate at which the path is followed. In this paper, we demonstrate that this conjecture holds for simple Hamiltonian systems that can be studied numerically. In particular, the systems studied exhibit the behavior that QD grows approximately as L L where L is the path length when the threshold error is fixed.

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