Litcius/Paper detail

NR-QNN: Noise-Resilient Quantum Neural Network

Sohrab Sajadimanesh, Hanieh Aghaee Rad, Jean Paul Latyr Faye, Ehsan Atoofian

2025IEEE Access8 citationsDOIOpen Access PDF

Abstract

Quantum Neural Networks (QNNs) based on parameterized quantum circuits (PQCs) are gaining significant research attention due to their potential to achieve quantum advantages on Near-Term Noisy Intermediate-Scale Quantum (NISQ) computers. However, executing QNNs on NISQ devices is challenging due to quantum noise. To address this, we propose a noise-resilient QNN (NR-QNN) that leverages the unique characteristics of PQCs to perform noise-aware optimizations during the inference stage of QNNs. Specifically, NR-QNN employs two optimization techniques to mitigate the impact of noise on QNNs: quantum pruning and sensitivity-aware qubit mapping. The first technique is quantum pruning which identifies gates with small angle of rotations and removes them to simplify circuit of QNNs. The second optimization technique is sensitivity-aware qubit mapping which maps more important logical qubits to more reliable physical qubits. This technique is based on the observation that there can be variation in the sensitivity of an output to input qubits in a QNN. NR-QNN exploits this variability and guides qubit allocation to use reliable physical qubits for sensitive logical qubits. Our evaluation on a real quantum computer demonstrates that NR-QNN enhances the robustness of QNNs, enabling them to operate effectively on NISQ devices.

Topics & Concepts

Computer scienceArtificial neural networkNoise (video)Artificial intelligenceImage (mathematics)Quantum Computing Algorithms and ArchitectureNeural Networks and ApplicationsNeural Networks and Reservoir Computing