Quantum Machine Learning
Quantum machine learning (QML) aims to leverage the unique properties of quantum computers to enhance machine learning algorithms, primarily focusing on improving speed, accuracy, and data efficiency. Current research emphasizes the development and application of quantum algorithms like variational quantum circuits (VQCs), quantum kernels, and quantum neural networks (QNNs), including variations such as quantum LSTMs and GANs, often in hybrid quantum-classical architectures. This field is significant because it explores the potential for quantum speedups in various machine learning tasks, with applications ranging from image classification and drug discovery to materials science and anomaly detection, although the extent of practical quantum advantage remains an active area of investigation. Challenges include mitigating noise in quantum hardware and understanding the generalization capabilities of QML models.
Papers
Exploiting symmetry in variational quantum machine learning
Johannes Jakob Meyer, Marian Mularski, Elies Gil-Fuster, Antonio Anna Mele, Francesco Arzani, Alissa Wilms, Jens Eisert
Equivariant quantum circuits for learning on weighted graphs
Andrea Skolik, Michele Cattelan, Sheir Yarkoni, Thomas Bäck, Vedran Dunjko
Dynamical simulation via quantum machine learning with provable generalization
Joe Gibbs, Zoë Holmes, Matthias C. Caro, Nicholas Ezzell, Hsin-Yuan Huang, Lukasz Cincio, Andrew T. Sornborger, Patrick J. Coles
Out-of-distribution generalization for learning quantum dynamics
Matthias C. Caro, Hsin-Yuan Huang, Nicholas Ezzell, Joe Gibbs, Andrew T. Sornborger, Lukasz Cincio, Patrick J. Coles, Zoë Holmes