S. M. Patomäki, M. F. Gonzalez-Zalba, M. A. Fogarty, Z. Cai, S. C. Benjamin, J. J. L. Morton
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引用次数: 0
摘要
我们提出了一种量子处理器架构--量子比特 "流水线",其运行时间与电路深度和运行重复次数成加法关系。运行时间控制是全局性的,从而降低了控制和互连资源的复杂性。这种简化是通过将 N 个量子比特状态穿梭于分阶段实现量子逻辑门的大型分层物理结构阵列来实现的。因此,电路深度与结构层数相对应。随后的 N-qubit 状态通过密集的结构 "流水线 "传输,从而有效利用物理资源进行重复运行。因此,流水线技术适用于噪声中量子(NISQ)应用,例如需要多次重复相同或类似计算的变分量子求解器。我们通过描述在天然高密度和可扩展硅自旋量子比特平台上的实现来说明该架构,其中包括在量子比特可变性的现实假设下具有足够保真度的通用门集。
Pipeline quantum processor architecture for silicon spin qubits
We propose a quantum processor architecture, the qubit ‘pipeline’, in which run-time scales additively as functions of circuit depth and run repetitions. Run-time control is applied globally, reducing the complexity of control and interconnect resources. This simplification is achieved by shuttling N-qubit states through a large layered physical array of structures which realise quantum logic gates in stages. Thus, the circuit depth corresponds to the number of layers of structures. Subsequent N-qubit states are ‘pipelined’ densely through the structures to efficiently wield the physical resources for repeated runs. Pipelining thus lends itself to noisy intermediate-scale quantum (NISQ) applications, such as variational quantum eigensolvers, which require numerous repetitions of the same or similar calculations. We illustrate the architecture by describing a realisation in the naturally high-density and scalable silicon spin qubit platform, which includes a universal gate set of sufficient fidelity under realistic assumptions of qubit variability.
期刊介绍:
The scope of npj Quantum Information spans across all relevant disciplines, fields, approaches and levels and so considers outstanding work ranging from fundamental research to applications and technologies.
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