Modelling Short-range Quantum Teleportation for Scalable Multi-Core Quantum Computing Architectures

Proceedings of the Eight Annual ACM International Conference on Nanoscale Computing and Communication Pub Date : 2021-09-07 DOI:10.1145/3477206.3477461

Santiago Rodrigo, S. Abadal, C. G. Almudever, E. Alarcón

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引用次数: 5

Abstract

Multi-core quantum computing has been identified as a solution to the scalability problem of quantum computing. However, interconnecting quantum chips is not trivial, as quantum communications have their share of quantum weirdness: quantum decoherence and the no-cloning theorem makes transferring qubits a harsh challenge, where every extra nanosecond counts and retransmission is simply impossible. In this paper, we present our first steps towards thorough modeling of quantum communications for multi-core quantum computers, which may be considered as a middle point between the well-known paradigms of Quantum Internet and Network-on-Chip. In particular, we stress the deep entanglement that exists between latency and error rates in quantum computing, and how this affects the quantum network design for this scenario. Moreover, we show the concomitant trade-off between computation and communication resources for a set of parameters out of state-of-the-art experimental research. The observed behavior lets us foresee the potential of multi-core quantum architectures.

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可扩展多核量子计算体系结构的短程量子隐形传态建模

多核量子计算被认为是解决量子计算可扩展性问题的一种方法。然而，连接量子芯片并非易事，因为量子通信有其量子怪异之处:量子退相干和不可克隆定理使得传输量子比特成为一项严峻的挑战，每多纳秒都要计算，重传根本不可能。在本文中，我们提出了对多核量子计算机的量子通信进行全面建模的第一步，多核量子计算机可以被认为是众所周知的量子互联网范式和片上网络之间的中间点。特别地，我们强调量子计算中延迟和错误率之间存在的深度纠缠，以及这如何影响这种情况下的量子网络设计。此外，我们还展示了一组最先进的实验研究参数的计算和通信资源之间的权衡。观察到的行为让我们预见到多核量子架构的潜力。

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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Proceedings of the Eight Annual ACM International Conference on Nanoscale Computing and Communication

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