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引用次数: 0
摘要
格罗弗自适应搜索(GAS)是一种量子穷举搜索算法,旨在解决二进制优化问题。在本文中,我们提出了能同时减少 GAS 所需的量子比特和门数量的高阶二进制公式。具体来说,我们考虑了两种新策略:一种是通过多项式因式分解减少门的数量,另一种是将目标函数的阶数减半,从而减少电路运行时间和实现成本。我们的分析表明,通过减少搜索空间大小和量子门数量,所提出的高阶公式改善了 GAS 的收敛性能。我们的策略也适用于使用单次编码的一般组合优化问题。
Accelerating Grover Adaptive Search: Qubit and Gate Count Reduction Strategies With Higher Order Formulations
Grover adaptive search (GAS) is a quantum exhaustive search algorithm designed to solve binary optimization problems. In this article, we propose higher order binary formulations that can simultaneously reduce the numbers of qubits and gates required for GAS. Specifically, we consider two novel strategies: one that reduces the number of gates through polynomial factorization, and the other that halves the order of the objective function, subsequently decreasing circuit runtime and implementation cost. Our analysis demonstrates that the proposed higher order formulations improve the convergence performance of GAS by reducing both the search space size and the number of quantum gates. Our strategies are also beneficial for general combinatorial optimization problems using one-hot encoding.
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