A method of mapping and nearest neighbor optimization for 2-D quantum circuits

Quantum Inf. Comput. Pub Date : 2020-03-01 DOI:10.26421/QIC20.3-4-2

Yu-xin Zhang, Z. Guan, Longyong Ji, Qingbin Luan, Yizhen Wang

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Abstract

In some practical quantum physical architectures, the qubits need to be distributed on 2-dimensional (2-D) grid structure to implement quantum computation. In order to map an 1-dimensional (1-D) quantum circuit into a 2-D grid structure and satisfy the nearest neighbor constraint of qubit interaction in the grid structure, a mapping method from 1-D quantum circuit to 2-D grid structure is proposed in this paper. This method firstly determines the order of placing qubits, and then presents the layout strategy of qubits in 2-D grid. We also proposed an algorithm for establishing interaction paths between non-adjacent qubits in 2-D grid structure, which can satisfy the physical constraints of the interaction of quantum bits in the grid in the process of mapping an 1-D quantum circuit to a 2-D grid structure. For some benchmark circuits, after using the method of this paper to place qubits, it is possible to make every 2-qubit gate in the circuit have a nearest neighbor, so that there is no need to use SWAP gate to establish channel routing. Compared with the latest available methods, the average optimization rate is 82.38%.

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二维量子电路的映射与最近邻优化方法

在一些实际的量子物理架构中，为了实现量子计算，需要将量子比特分布在二维网格结构上。为了将一维量子电路映射到二维网格结构中，并满足网格结构中量子比特相互作用的最近邻约束，本文提出了一种从一维量子电路到二维网格结构的映射方法。该方法首先确定了量子位的放置顺序，然后给出了量子位在二维网格中的布局策略。我们还提出了一种建立二维网格结构中非相邻量子比特之间相互作用路径的算法，该算法可以满足一维量子电路映射到二维网格结构过程中网格中量子比特相互作用的物理约束。对于一些基准电路，在使用本文的方法放置量子比特后，可以使电路中每2个量子比特的门都有一个最近的邻居，这样就不需要使用SWAP门来建立通道路由。与现有方法比较，平均优化率为82.38%。

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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Quantum Inf. Comput.

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