Trotter error bounds and dynamic multi-product formulas for Hamiltonian simulation

Physical Review Research Pub Date : 2024-09-17 DOI:10.1103/physrevresearch.6.033309

Sergiy Zhuk, Niall F. Robertson, Sergey Bravyi

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Abstract

Multi-product formulas (MPFs) are linear combinations of Trotter circuits offering high-quality simulation of Hamiltonian time evolution with fewer Trotter steps. Here we report two contributions aimed at making multi-product formulas more viable for near-term quantum simulations. First, we extend the theory of Trotter error with commutator scaling developed by Childs et al. [A. M. Childs et al., Phys. Rev. X 11, 011020 (2021)] to multi-product formulas. Our result implies that multi-product formulas can achieve a quadratic reduction of Trotter error in 1-norm (nuclear norm) on arbitrary time intervals compared with the regular product formulas without increasing the required circuit depth or qubit connectivity. The number of circuit repetitions grows only by a constant factor. Second, we introduce dynamic multi-product formulas with time-dependent coefficients chosen to minimize a certain efficiently computable proxy for the Trotter error. We use a minimax estimation method to make dynamic multi-product formulas robust to uncertainty from algorithmic errors, sampling, and hardware noise. We call this method the minimax MPF and we provide a rigorous bound on its error.

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哈密顿模拟的特洛特误差边界和动态多乘积公式

多乘积公式（MPF）是特罗特电路的线性组合，能以较少的特罗特步骤高质量地模拟哈密尔顿时间演化。我们在此报告两项贡献，旨在使多积公式在近期量子模拟中更加可行。首先，我们将 Childs 等人[A. M. Childs 等人，Phys. Rev. X 11, 011020 (2021)]开发的具有换向器缩放的特罗特误差理论扩展到多乘积公式。我们的结果意味着，与常规乘积公式相比，多乘积公式可以在任意时间间隔上实现 1-正态（核正态）特罗特误差的四次方减少，而无需增加所需的电路深度或量子比特连接性。电路重复次数只增加一个常数因子。其次，我们引入了动态多乘积公式，并选择了随时间变化的系数，以最小化某种可有效计算的特罗特误差代理。我们采用最小估计法，使动态多乘法公式对算法误差、采样和硬件噪声带来的不确定性具有鲁棒性。我们称这种方法为 minimax MPF，并为其误差提供了严格的约束。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Physical Review Research

CiteScore

8.60

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0.00%

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