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Main Authors: Afane, Mohamed, Long, Quanjiang, Shen, Haoting, Mao, Ying, Farooq, Junaid, Wang, Ying, Chen, Juntao
Format: Preprint
Published: 2026
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Online Access:https://arxiv.org/abs/2601.18058
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author Afane, Mohamed
Long, Quanjiang
Shen, Haoting
Mao, Ying
Farooq, Junaid
Wang, Ying
Chen, Juntao
author_facet Afane, Mohamed
Long, Quanjiang
Shen, Haoting
Mao, Ying
Farooq, Junaid
Wang, Ying
Chen, Juntao
contents Current quantum neural networks suffer from extreme sensitivity to both adversarial perturbations and hardware noise, creating a significant barrier to real-world deployment. Existing robustness techniques typically sacrifice clean accuracy or require prohibitive computational resources. We propose a hybrid quantum-classical Differentiable Quantum Architecture Search (DQAS) framework that addresses these limitations by jointly optimizing circuit structure and robustness through gradient-based methods. Our approach enhances traditional DQAS with a lightweight Classical Noise Layer applied before quantum processing, enabling simultaneous optimization of gate selection and noise parameters. This design preserves the quantum circuit's integrity while introducing trainable perturbations that enhance robustness without compromising standard performance. Experimental validation on MNIST, FashionMNIST, and CIFAR datasets shows consistent improvements in both clean and adversarial accuracy compared to existing quantum architecture search methods. Under various attack scenarios, including Fast Gradient Sign Method (FGSM), Projected Gradient Descent (PGD), Basic Iterative Method (BIM), and Momentum Iterative Method (MIM), and under realistic quantum noise conditions, our hybrid framework maintains superior performance. Testing on actual quantum hardware confirms the practical viability of discovered architectures. These results demonstrate that strategic classical preprocessing combined with differentiable quantum architecture optimization can significantly enhance quantum neural network robustness while maintaining computational efficiency.
format Preprint
id arxiv_https___arxiv_org_abs_2601_18058
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Differentiable Architecture Search for Adversarially Robust Quantum Computer Vision
Afane, Mohamed
Long, Quanjiang
Shen, Haoting
Mao, Ying
Farooq, Junaid
Wang, Ying
Chen, Juntao
Quantum Physics
Computer Vision and Pattern Recognition
Current quantum neural networks suffer from extreme sensitivity to both adversarial perturbations and hardware noise, creating a significant barrier to real-world deployment. Existing robustness techniques typically sacrifice clean accuracy or require prohibitive computational resources. We propose a hybrid quantum-classical Differentiable Quantum Architecture Search (DQAS) framework that addresses these limitations by jointly optimizing circuit structure and robustness through gradient-based methods. Our approach enhances traditional DQAS with a lightweight Classical Noise Layer applied before quantum processing, enabling simultaneous optimization of gate selection and noise parameters. This design preserves the quantum circuit's integrity while introducing trainable perturbations that enhance robustness without compromising standard performance. Experimental validation on MNIST, FashionMNIST, and CIFAR datasets shows consistent improvements in both clean and adversarial accuracy compared to existing quantum architecture search methods. Under various attack scenarios, including Fast Gradient Sign Method (FGSM), Projected Gradient Descent (PGD), Basic Iterative Method (BIM), and Momentum Iterative Method (MIM), and under realistic quantum noise conditions, our hybrid framework maintains superior performance. Testing on actual quantum hardware confirms the practical viability of discovered architectures. These results demonstrate that strategic classical preprocessing combined with differentiable quantum architecture optimization can significantly enhance quantum neural network robustness while maintaining computational efficiency.
title Differentiable Architecture Search for Adversarially Robust Quantum Computer Vision
topic Quantum Physics
Computer Vision and Pattern Recognition
url https://arxiv.org/abs/2601.18058