Optimal quantum simulation of linear non-unitary dynamics

Abstract

We present a quantum algorithm for simulating the time evolution generated by any bounded, time-dependent operator -A with non-positive logarithmic norm, thereby serving as a natural generalization of the Hamiltonian simulation problem. Our method generalizes the recent Linear-Combination-of-Hamiltonian-Simulation (LCHS) framework. In instances where A is time-independent, we provide a block-encoding of the evolution operator e-At with O(t1ε) queries to the block-encoding oracle for A. We also show how the normalized evolved state can be prepared with O(1/\|e-At|u0\|) queries to the oracle that prepares the normalized initial state |u0. These complexities are optimal in all parameters and improve the error scaling over prior results. Furthermore, we show that any improvement of our approach exceeding a constant factor of approximately 3 is infeasible. For general time-dependent operators A, we also prove that a uniform trapezoidal rule on our LCHS construction yields exponential convergence, leading to simplified quantum circuits with improved gate complexity compared to prior nonuniform-quadrature methods.