时变哈密顿量的量子模拟——应用于非自治常微分方程和偏微分方程

Yu Cao, Shi Jin, Nana Liu
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引用次数: 0

摘要

非自治动力系统出现在非常广泛的有趣的应用中,无论是在经典动力学还是量子动力学中,在后一种情况下,它对应于具有时间相关的哈密顿量。然而,这些系统的量子模拟通常需要诉诸相当复杂的程序,涉及戴森级数、时间顺序的考虑、时间步长的离散要求和/或需要多次测量和后选择。这些程序通常比时间无关的哈密顿量的量子模拟复杂得多。在这里,我们提出了一种替代形式,将任何非自治的单一动力系统在一个更高的维度上变成一个自治的单一系统,即具有时间无关的量子系统,同时保持时间连续。这使得与时间相关的哈密顿量的模拟并不比与时间无关的哈密顿量的模拟困难得多,并且也可以用模拟量子系统在时间上连续进化的方式来构建。我们展示了我们的时间相关哈密顿量的新量子协议如何以资源高效的方式执行,而无需测量,并且可以在连续变量,量子比特或混合系统上实现。结合一种叫做薛定化的技术,这种膨胀技术可以应用于任何线性ode和偏微分方程,非线性ode和某些非线性偏微分方程的量子模拟,具有时间相关系数。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Quantum simulation for time-dependent Hamiltonians -- with applications to non-autonomous ordinary and partial differential equations
Non-autonomous dynamical systems appear in a very wide range of interesting applications, both in classical and quantum dynamics, where in the latter case it corresponds to having a time-dependent Hamiltonian. However, the quantum simulation of these systems often needs to appeal to rather complicated procedures involving the Dyson series, considerations of time-ordering, requirement of time steps to be discrete and/or requiring multiple measurements and postselection. These procedures are generally much more complicated than the quantum simulation of time-independent Hamiltonians. Here we propose an alternative formalism that turns any non-autonomous unitary dynamical system into an autonomous unitary system, i.e., quantum system with a time-independent Hamiltonian, in one higher dimension, while keeping time continuous. This makes the simulation with time-dependent Hamiltonians not much more difficult than that of time-independent Hamiltonians, and can also be framed in terms of an analogue quantum system evolving continuously in time. We show how our new quantum protocol for time-dependent Hamiltonians can be performed in a resource-efficient way and without measurements, and can be made possible on either continuous-variable, qubit or hybrid systems. Combined with a technique called Schrodingerisation, this dilation technique can be applied to the quantum simulation of any linear ODEs and PDEs, and nonlinear ODEs and certain nonlinear PDEs, with time-dependent coefficients.
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