Validating a Koopman-Quantum Hybrid Paradigm for Diagnostic Denoising of Fusion Devices

• URL: http://arxiv.org/abs/2602.03113v1
• Date: Tue, 03 Feb 2026 05:14:15 GMT
• Title: Validating a Koopman-Quantum Hybrid Paradigm for Diagnostic Denoising of Fusion Devices
• Authors: Tie-Jun Wang, Run-Qing Zhang, Ling Qian, Yun-Tao Song, Ting Lan, Hai-Qing Liu, Keren Li,
• Abstract summary: We introduce a physics-informed Koopman-Quantum hybrid framework, theoretically grounded in a representation-level structural isomorphism.<n>We design a realizable NISQ-friendly pipeline: the Koopman operator functions as a physics-aware "data distiller," compressing waveforms into compact, "quantum-ready" features.<n>We validated this framework on 4,763 labeled channel sequences from 433 discharges of the tokamak system.
• Score: 5.8040520327789835
• License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
• Abstract: The potential of Quantum Machine Learning (QML) in data-intensive science is strictly bottlenecked the difficulty of interfacing high-dimensional, chaotic classical data into resource-limited, noisy quantum processors. To bridge this gap, we introduce a physics-informed Koopman-Quantum hybrid framework, theoretically grounded in a representation-level structural isomorphism we establish between the Koopman operator, which linearizes nonlinear dynamics, and quantum evolution. Based on this theoretical foundation, we design a realizable NISQ-friendly pipeline: the Koopman operator functions as a physics-aware "data distiller," compressing waveforms into compact, "quantum-ready" features, which are subsequently processed by a modular, parallel quantum neural network. We validated this framework on 4,763 labeled channel sequences from 433 discharges of the tokamak system. The results demonstrate that our model achieves 97.0\% accuracy in screening corrupted diagnostic data, matching the performance of state-of-the-art deep classical CNNs while using orders-of-magnitude fewer trainable parameters. This work establishes a practical, physics-grounded paradigm for leveraging quantum processing in constrained environments, offering a scalable path for quantum-enhanced edge computing.

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