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Main Authors: Zhang, Shi-Xin, Chen, Yu-Qin, Li, Weitang, Sun, Jiace, Ma, Wei-Guo, Zheng, Pei-Lin, Huang, Yu-Xiang, Wang, Qi-Xiang, Yu, Hui, Li, Zhuo, Huang, Xuyang, Li, Zong-Liang, Wan, Zhou-Quan, Liu, Shuo, Qiu, Jiezhong, Miao, Jiaqi, Song, Zixuan, Yan, Yuxuan, Tsuoka, Kazuki, Zhang, Pan, Wang, Lei, Fan, Heng, Hsieh, Chang-Yu, Yao, Hong, Xiang, Tao
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2602.14167
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author Zhang, Shi-Xin
Chen, Yu-Qin
Li, Weitang
Sun, Jiace
Ma, Wei-Guo
Zheng, Pei-Lin
Huang, Yu-Xiang
Wang, Qi-Xiang
Yu, Hui
Li, Zhuo
Huang, Xuyang
Li, Zong-Liang
Wan, Zhou-Quan
Liu, Shuo
Qiu, Jiezhong
Miao, Jiaqi
Song, Zixuan
Yan, Yuxuan
Tsuoka, Kazuki
Zhang, Pan
Wang, Lei
Fan, Heng
Hsieh, Chang-Yu
Yao, Hong
Xiang, Tao
author_facet Zhang, Shi-Xin
Chen, Yu-Qin
Li, Weitang
Sun, Jiace
Ma, Wei-Guo
Zheng, Pei-Lin
Huang, Yu-Xiang
Wang, Qi-Xiang
Yu, Hui
Li, Zhuo
Huang, Xuyang
Li, Zong-Liang
Wan, Zhou-Quan
Liu, Shuo
Qiu, Jiezhong
Miao, Jiaqi
Song, Zixuan
Yan, Yuxuan
Tsuoka, Kazuki
Zhang, Pan
Wang, Lei
Fan, Heng
Hsieh, Chang-Yu
Yao, Hong
Xiang, Tao
contents We present TensorCircuit-NG, a next-generation quantum software platform designed to bridge the gap between quantum physics, artificial intelligence, and high-performance computing. Moving beyond the scope of traditional circuit simulators, TensorCircuit-NG establishes a unified, tensor-native programming paradigm where quantum circuits, tensor networks, and neural networks fuse into a single, end-to-end differentiable computational graph. Built upon industry-standard machine learning backends (JAX, TensorFlow, PyTorch), the framework introduces comprehensive capabilities for approximate circuit simulation, analog dynamics, fermion Gaussian states, qudit systems, and scalable noise modeling. To tackle the exponential complexity of deep quantum circuits, TensorCircuit-NG implements advanced distributed computing strategies, including automated data parallelism and model-parallel tensor network slicing. We validate these capabilities on GPU clusters, demonstrating a near-linear speedup in distributed variational quantum algorithms. TensorCircuit-NG enables flagship applications, including end-to-end QML for CIFAR-100 computer vision, efficient pipelines from quantum states to neural networks via classical shadows, and differentiable optimization of tensor network states for many-body physics.
format Preprint
id arxiv_https___arxiv_org_abs_2602_14167
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle TensorCircuit-NG: A Universal, Composable, and Scalable Platform for Quantum Computing and Quantum Simulation
Zhang, Shi-Xin
Chen, Yu-Qin
Li, Weitang
Sun, Jiace
Ma, Wei-Guo
Zheng, Pei-Lin
Huang, Yu-Xiang
Wang, Qi-Xiang
Yu, Hui
Li, Zhuo
Huang, Xuyang
Li, Zong-Liang
Wan, Zhou-Quan
Liu, Shuo
Qiu, Jiezhong
Miao, Jiaqi
Song, Zixuan
Yan, Yuxuan
Tsuoka, Kazuki
Zhang, Pan
Wang, Lei
Fan, Heng
Hsieh, Chang-Yu
Yao, Hong
Xiang, Tao
Quantum Physics
We present TensorCircuit-NG, a next-generation quantum software platform designed to bridge the gap between quantum physics, artificial intelligence, and high-performance computing. Moving beyond the scope of traditional circuit simulators, TensorCircuit-NG establishes a unified, tensor-native programming paradigm where quantum circuits, tensor networks, and neural networks fuse into a single, end-to-end differentiable computational graph. Built upon industry-standard machine learning backends (JAX, TensorFlow, PyTorch), the framework introduces comprehensive capabilities for approximate circuit simulation, analog dynamics, fermion Gaussian states, qudit systems, and scalable noise modeling. To tackle the exponential complexity of deep quantum circuits, TensorCircuit-NG implements advanced distributed computing strategies, including automated data parallelism and model-parallel tensor network slicing. We validate these capabilities on GPU clusters, demonstrating a near-linear speedup in distributed variational quantum algorithms. TensorCircuit-NG enables flagship applications, including end-to-end QML for CIFAR-100 computer vision, efficient pipelines from quantum states to neural networks via classical shadows, and differentiable optimization of tensor network states for many-body physics.
title TensorCircuit-NG: A Universal, Composable, and Scalable Platform for Quantum Computing and Quantum Simulation
topic Quantum Physics
url https://arxiv.org/abs/2602.14167