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Main Authors: Lin, Huiping, Deng, Ruixuan, Yao, Chris Z., Ji, Zhengfeng, Ying, Mingsheng
Format: Preprint
Published: 2024
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Online Access:https://arxiv.org/abs/2412.08956
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author Lin, Huiping
Deng, Ruixuan
Yao, Chris Z.
Ji, Zhengfeng
Ying, Mingsheng
author_facet Lin, Huiping
Deng, Ruixuan
Yao, Chris Z.
Ji, Zhengfeng
Ying, Mingsheng
contents Quantum network research at both the software stack and hardware implementation level has become an exciting area of quantum information science. Although demonstrations of small-scale quantum networks have emerged in the past decade, quantum communication and computation hardware remain scarce resources today. As a result, the evaluation and validation of quantum network protocols primarily rely on classical simulators rather than real quantum networks. This paper introduces a novel quantum network simulation method called control flow adaptation, which enhances standard tensor network simulations. This method enables accurate and efficient simulations of many important quantum network protocols by carefully leveraging the control flow structures of them. Furthermore, we have developed a prototype quantum network simulator, qns-3, as a module for ns-3. This new module implements the control flow adaptation technique and applies it to a wide range of protocols. All related code is open-sourced. We believe the development of the control flow adaptation method and the qns-3 simulator represents a step forward in quantum network research, offering a versatile and scalable platform for testing and verifying quantum network protocols on classical computers.
format Preprint
id arxiv_https___arxiv_org_abs_2412_08956
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Control Flow Adaption: An Efficient Simulation Method For Noisy Quantum Networks
Lin, Huiping
Deng, Ruixuan
Yao, Chris Z.
Ji, Zhengfeng
Ying, Mingsheng
Quantum Physics
Quantum network research at both the software stack and hardware implementation level has become an exciting area of quantum information science. Although demonstrations of small-scale quantum networks have emerged in the past decade, quantum communication and computation hardware remain scarce resources today. As a result, the evaluation and validation of quantum network protocols primarily rely on classical simulators rather than real quantum networks. This paper introduces a novel quantum network simulation method called control flow adaptation, which enhances standard tensor network simulations. This method enables accurate and efficient simulations of many important quantum network protocols by carefully leveraging the control flow structures of them. Furthermore, we have developed a prototype quantum network simulator, qns-3, as a module for ns-3. This new module implements the control flow adaptation technique and applies it to a wide range of protocols. All related code is open-sourced. We believe the development of the control flow adaptation method and the qns-3 simulator represents a step forward in quantum network research, offering a versatile and scalable platform for testing and verifying quantum network protocols on classical computers.
title Control Flow Adaption: An Efficient Simulation Method For Noisy Quantum Networks
topic Quantum Physics
url https://arxiv.org/abs/2412.08956