Add to ORKGRecently, quantum classifiers have been known to be vulnerable to adversarial attacks, where quantum classifiers are fooled by imperceptible noises to have misclassification. In this paper, we propose one first theoretical study that utilizing the added quantum random rotation noise can improve the robustness of quantum classifiers against adversarial attacks. We connect the definition of differential privacy and demonstrate the quantum classifier trained with the natural presence of additive noise is differentially private. Lastly, we derive a certified robustness bound to enable quantum classifiers to defend against adversarial examples supported by experimental results.Comment: Submitted to IEEE ICASSP 202
We present a formalism that captures the process of proving quantum superiority to skeptics as an in...
Studies addressing the question “Can a learner complete the learning securely?” have recently been s...
Due to the beyond-classical capability of quantum computing, quantum machine learning is applied ind...
Noise in quantum information processing is often viewed as a disruptive and difficult-to-avoid featu...
Quantum computing promises to enhance machine learning and artificial intelligence. Different quantu...
Machine learning (ML) methods such as artificial neural networks are rapidly becoming ubiquitous in ...
Several important models of machine learning algorithms have been successfully generalized to the qu...
State-of-the-art classical neural networks are observed to be vulnerable to small crafted adversaria...
State-of-the-art classical neural networks are observed to be vulnerable to small crafted adversaria...
In this work, we propose a novel architecture (and several variants thereof) based on quantum crypto...
Differential privacy has been an exceptionally successful concept when it comes to providing provabl...
Current noisy intermediate-scale quantum devices suffer from various sources of intrinsic quantum no...
We give a protocol for producing certifiable randomness from a single untrusted quantum device that ...
We give a protocol for producing certifiable randomness from a single untrusted quantum device that ...
We give a protocol for producing certifiable randomness from a single untrusted quantum device that ...
We present a formalism that captures the process of proving quantum superiority to skeptics as an in...
Studies addressing the question “Can a learner complete the learning securely?” have recently been s...
Due to the beyond-classical capability of quantum computing, quantum machine learning is applied ind...
Noise in quantum information processing is often viewed as a disruptive and difficult-to-avoid featu...
Quantum computing promises to enhance machine learning and artificial intelligence. Different quantu...
Machine learning (ML) methods such as artificial neural networks are rapidly becoming ubiquitous in ...
Several important models of machine learning algorithms have been successfully generalized to the qu...
State-of-the-art classical neural networks are observed to be vulnerable to small crafted adversaria...
State-of-the-art classical neural networks are observed to be vulnerable to small crafted adversaria...
In this work, we propose a novel architecture (and several variants thereof) based on quantum crypto...
Differential privacy has been an exceptionally successful concept when it comes to providing provabl...
Current noisy intermediate-scale quantum devices suffer from various sources of intrinsic quantum no...
We give a protocol for producing certifiable randomness from a single untrusted quantum device that ...
We give a protocol for producing certifiable randomness from a single untrusted quantum device that ...
We give a protocol for producing certifiable randomness from a single untrusted quantum device that ...
We present a formalism that captures the process of proving quantum superiority to skeptics as an in...
Studies addressing the question “Can a learner complete the learning securely?” have recently been s...
Due to the beyond-classical capability of quantum computing, quantum machine learning is applied ind...