Nhat A. Nghiem
Published 2024-10-18Version 1
We propose a new method for simulating certain type of time-dependent Hamiltonian $H(t) = \sum_{i=1}^m \gamma_i(t) H_i$ where $\gamma_i(t)$ (and its higher order derivatives) is bounded, computable function of time $t$, and each $H_i$ is time-independent, and could be efficiently simulated. Our quantum algorithms are based on high-order Runge-Kutta method and forward Euler method, where the time interval is divided into subintervals. Then in an iterative manner, the evolution operator at given time step is built upon the evolution operator at previous time step, utilizing algorithmic operations from the recently introduced quantum singular value transformation framework.
Explicit Form of the Evolution Operator of Tavis-Cummings Model : Three and Four Atoms Cases
A perturbative expansion of the evolution operator associated with time-dependent quantum Hamiltonians
Optimal statistical ensembles for quantum thermal state preparation within the quantum singular value transformation framework
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