Albert J. Pool, Alejandro D. Somoza, Conor Mc Keever, Michael Lubasch, Birger Horstmann
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引用次数: 0
Abstract
For the solution of time-dependent nonlinear differential equations, we present variational quantum algorithms (VQAs) that encode both space and time in qubit registers. The spacetime encoding enables us to obtain the entire time evolution from a single ground-state computation. We describe a general procedure to construct efficient quantum circuits for the cost function evaluation required by VQAs. To mitigate the barren plateau problem during the optimization, we propose an adaptive multigrid strategy. The approach is illustrated for the nonlinear Burgers equation. We classically optimize quantum circuits to represent the desired ground-state solutions, run them on IBM Q System One and Quantinuum System Model H1, and demonstrate that current quantum computers are capable of accurately reproducing the exact results.
为了求解随时间变化的非线性微分方程,我们提出了在量子位寄存器中同时对空间和时间进行编码的变分量子算法(VQAs)。时空编码使我们能够从一次地面状态计算中获得整个时间演化过程。我们描述了构建高效量子电路的一般程序,以实现 VQAs 所需的代价函数评估。为了缓解优化过程中的贫瘠高原问题,我们提出了一种自适应多网格策略。该方法针对非线性布尔格斯方程进行了说明。我们对量子电路进行了经典优化,以表示所需的基态解,并在 IBM Q System One 和 Quantinuum System Model H1 上运行这些电路,证明当前的量子计算机能够准确地再现精确结果。
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