Quantum Adversarial Machine Learning and Defense Strategies: Challenges and Opportunities
This addresses the need for quantum-secure machine learning models to prevent adversarial threats as quantum computing advances, but it appears incremental as it builds on existing quantum and adversarial defense concepts.
The paper tackles the problem of securing neural networks against adversarial attacks in the quantum computing era by proposing three quantum-secure design principles, such as using post-quantum cryptography and quantum-resistant architectures, to ensure model integrity and reliability.
As quantum computing continues to advance, the development of quantum-secure neural networks is crucial to prevent adversarial attacks. This paper proposes three quantum-secure design principles: (1) using post-quantum cryptography, (2) employing quantum-resistant neural network architectures, and (3) ensuring transparent and accountable development and deployment. These principles are supported by various quantum strategies, including quantum data anonymization, quantum-resistant neural networks, and quantum encryption. The paper also identifies open issues in quantum security, privacy, and trust, and recommends exploring adaptive adversarial attacks and auto adversarial attacks as future directions. The proposed design principles and recommendations provide guidance for developing quantum-secure neural networks, ensuring the integrity and reliability of machine learning models in the quantum era.