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Autori principali: Wang, Feng-ao, Chen, Shaobo, Xuan, Yao, Liu, Junwei, Gao, Qi, Zhu, Hongdong, Hou, Junjie, Yuan, Lixin, Cheng, Jinyu, Yi, Chenxin, Wei, Hai, Ma, Yin, Xu, Tao, Wen, Kai, Li, Yixue
Natura: Preprint
Pubblicazione: 2025
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Accesso online:https://arxiv.org/abs/2508.11190
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author Wang, Feng-ao
Chen, Shaobo
Xuan, Yao
Liu, Junwei
Gao, Qi
Zhu, Hongdong
Hou, Junjie
Yuan, Lixin
Cheng, Jinyu
Yi, Chenxin
Wei, Hai
Ma, Yin
Xu, Tao
Wen, Kai
Li, Yixue
author_facet Wang, Feng-ao
Chen, Shaobo
Xuan, Yao
Liu, Junwei
Gao, Qi
Zhu, Hongdong
Hou, Junjie
Yuan, Lixin
Cheng, Jinyu
Yi, Chenxin
Wei, Hai
Ma, Yin
Xu, Tao
Wen, Kai
Li, Yixue
contents A fundamental limitation of probabilistic deep learning is its predominant reliance on Gaussian priors. This simplistic assumption prevents models from accurately capturing the complex, non-Gaussian landscapes of natural data, particularly in demanding domains like complex biological data, severely hindering the fidelity of the model for scientific discovery. The physically-grounded Boltzmann distribution offers a more expressive alternative, but it is computationally intractable on classical computers. To date, quantum approaches have been hampered by the insufficient qubit scale and operational stability required for the iterative demands of deep learning. Here, we bridge this gap by introducing the Quantum Boltzmann Machine-Variational Autoencoder (QBM-VAE), a large-scale and long-time stable hybrid quantum-classical architecture. Our framework leverages a quantum processor for efficient sampling from the Boltzmann distribution, enabling its use as a powerful prior within a deep generative model. Applied to million-scale single-cell datasets from multiple sources, the QBM-VAE generates a latent space that better preserves complex biological structures, consistently outperforming conventional Gaussian-based deep learning models like VAE and SCVI in essential tasks such as omics data integration, cell-type classification, and trajectory inference. It also provides a typical example of introducing a physics priori into deep learning to drive the model to acquire scientific discovery capabilities that breaks through data limitations. This work provides the demonstration of a practical quantum advantage in deep learning on a large-scale scientific problem and offers a transferable blueprint for developing hybrid quantum AI models.
format Preprint
id arxiv_https___arxiv_org_abs_2508_11190
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Quantum-Boosted High-Fidelity Deep Learning
Wang, Feng-ao
Chen, Shaobo
Xuan, Yao
Liu, Junwei
Gao, Qi
Zhu, Hongdong
Hou, Junjie
Yuan, Lixin
Cheng, Jinyu
Yi, Chenxin
Wei, Hai
Ma, Yin
Xu, Tao
Wen, Kai
Li, Yixue
Machine Learning
Artificial Intelligence
Genomics
A fundamental limitation of probabilistic deep learning is its predominant reliance on Gaussian priors. This simplistic assumption prevents models from accurately capturing the complex, non-Gaussian landscapes of natural data, particularly in demanding domains like complex biological data, severely hindering the fidelity of the model for scientific discovery. The physically-grounded Boltzmann distribution offers a more expressive alternative, but it is computationally intractable on classical computers. To date, quantum approaches have been hampered by the insufficient qubit scale and operational stability required for the iterative demands of deep learning. Here, we bridge this gap by introducing the Quantum Boltzmann Machine-Variational Autoencoder (QBM-VAE), a large-scale and long-time stable hybrid quantum-classical architecture. Our framework leverages a quantum processor for efficient sampling from the Boltzmann distribution, enabling its use as a powerful prior within a deep generative model. Applied to million-scale single-cell datasets from multiple sources, the QBM-VAE generates a latent space that better preserves complex biological structures, consistently outperforming conventional Gaussian-based deep learning models like VAE and SCVI in essential tasks such as omics data integration, cell-type classification, and trajectory inference. It also provides a typical example of introducing a physics priori into deep learning to drive the model to acquire scientific discovery capabilities that breaks through data limitations. This work provides the demonstration of a practical quantum advantage in deep learning on a large-scale scientific problem and offers a transferable blueprint for developing hybrid quantum AI models.
title Quantum-Boosted High-Fidelity Deep Learning
topic Machine Learning
Artificial Intelligence
Genomics
url https://arxiv.org/abs/2508.11190