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Main Authors: Li, Xiao-Yu, Zhu, Qin-Sheng, Hu, Yong, Wu, Hao, Yang, Guo-Wu, Yu, Lian-Hui, Chen, Geng
Format: Preprint
Published: 2023
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Online Access:https://arxiv.org/abs/2307.08640
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author Li, Xiao-Yu
Zhu, Qin-Sheng
Hu, Yong
Wu, Hao
Yang, Guo-Wu
Yu, Lian-Hui
Chen, Geng
author_facet Li, Xiao-Yu
Zhu, Qin-Sheng
Hu, Yong
Wu, Hao
Yang, Guo-Wu
Yu, Lian-Hui
Chen, Geng
contents The Hidden Quantum Markov Model (HQMM) has significant potential for analyzing time-series data and studying stochastic processes in the quantum domain as an upgrading option with potential advantages over classical Markov models. In this paper, we introduced the split HQMM (SHQMM) for implementing the hidden quantum Markov process, utilizing the conditional master equation with a fine balance condition to demonstrate the interconnections among the internal states of the quantum system. The experimental results suggest that our model outperforms previous models in terms of scope of applications and robustness. Additionally, we establish a new learning algorithm to solve parameters in HQMM by relating the quantum conditional master equation to the HQMM. Finally, our study provides clear evidence that the quantum transport system can be considered a physical representation of HQMM. The SHQMM with accompanying algorithms present a novel method to analyze quantum systems and time series grounded in physical implementation.
format Preprint
id arxiv_https___arxiv_org_abs_2307_08640
institution arXiv
publishDate 2023
record_format arxiv
spellingShingle A new quantum machine learning algorithm: split hidden quantum Markov model inspired by quantum conditional master equation
Li, Xiao-Yu
Zhu, Qin-Sheng
Hu, Yong
Wu, Hao
Yang, Guo-Wu
Yu, Lian-Hui
Chen, Geng
Quantum Physics
The Hidden Quantum Markov Model (HQMM) has significant potential for analyzing time-series data and studying stochastic processes in the quantum domain as an upgrading option with potential advantages over classical Markov models. In this paper, we introduced the split HQMM (SHQMM) for implementing the hidden quantum Markov process, utilizing the conditional master equation with a fine balance condition to demonstrate the interconnections among the internal states of the quantum system. The experimental results suggest that our model outperforms previous models in terms of scope of applications and robustness. Additionally, we establish a new learning algorithm to solve parameters in HQMM by relating the quantum conditional master equation to the HQMM. Finally, our study provides clear evidence that the quantum transport system can be considered a physical representation of HQMM. The SHQMM with accompanying algorithms present a novel method to analyze quantum systems and time series grounded in physical implementation.
title A new quantum machine learning algorithm: split hidden quantum Markov model inspired by quantum conditional master equation
topic Quantum Physics
url https://arxiv.org/abs/2307.08640