New Reservoir Computing Kernel Based on Chaotic Chua Circuit and Investigating Application to Post-Quantum Cryptography

Matthew John Cossins, Sendy Phang
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Abstract

The aim of this project was to develop a new Reservoir Computer implementation, based on a chaotic Chua circuit. In addition to suitable classification and regression benchmarks, the Reservoir Computer was applied to Post-Quantum Cryptography, with its suitability for this application investigated and assessed. The cryptographic algorithm utilised was the Learning with Errors problem, for both encryption and decryption. To achieve this, the Chua circuit was characterised, in simulation, and by physical circuit testing. The Reservoir Computer was designed and implemented using the results of the characterisation. As part of this development, noise was considered and mitigated. The benchmarks demonstrate that the Reservoir Computer can achieve current literature benchmarks with low error. However, the results with Learning with Errors suggest that a Chua-based Reservoir Computer is not sufficiently complex to tackle the high non-linearity in Post-Quantum Cryptography. Future work would involve researching the use of different combinations of multiple Chua Reservoir Computers in larger neural network architectures. Such architectures may produce the required high-dimensional behaviour to achieve the Learning with Errors problem. This project is believed to be only the second instance of a Chua-based Reservoir Computer in academia, and it is the first to be applied to challenging real-world tasks such as Post-Quantum Cryptography. It is also original by its investigation of hitherto unexplored parameters, and their impact on performance. It demonstrates a proof-of-concept for a mass-producible, inexpensive, low-power consumption hardware neural network. It also enables the next stages in research to occur, paving the road for using Chua-based Reservoir Computers across various applications.
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基于混沌蔡氏电路的新型水库计算内核及其在后量子密码学中的应用研究
该项目的目的是基于混沌 Chua 电路开发一种新的水库计算机实施方案。除了合适的分类和回归基准外,水库计算机还被应用于后量子密码学,并对其适用性进行了调查和评估。使用的加密算法是 "错误学习 "问题,用于加密和解密。为此,通过模拟和物理电路测试对 Chua 电路进行了鉴定。根据特性分析结果,设计并实现了水库计算机。作为开发工作的一部分,噪音问题也得到了考虑和缓解。基准测试表明,水库计算机能够以较低的误差实现当前的文献基准。不过,带误差学习的结果表明,基于 Chua 的水库计算机还不够复杂,无法处理后量子密码学中的高非线性问题。未来的工作将包括研究在更大的神经网络架构中使用多个 Chua 储层计算机的不同组合。这种架构可能会产生所需的高维行为,以实现带误差学习问题。该项目被认为是学术界使用基于 Chua 的水库计算机的第二个实例,也是第一个应用于后量子密码学等具有挑战性的现实世界任务的实例。它的独创性还在于研究了迄今为止尚未探索的参数及其对性能的影响。它展示了一个可生产、廉价、低功耗硬件神经网络的概念验证。它使下一阶段的研究得以展开,为在各种应用中使用基于 Chua 的水库计算机铺平了道路。
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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