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Quantum machine learning beyond kernel methods
Sofiene Jerbi,Lukas J. Fiderer,Hendrik Poulsen Nautrup,Jonas M. Kübler,Hans J. Briegel,Vedran Dunjko +5 more
TL;DR: In this article, the authors extend the applicability of this result to a more general family of parametrized quantum circuit models called data re-uploading circuits and show that models defined and trained variationally can exhibit a critically better generalization performance than their kernel formulations.
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Abstract: With noisy intermediate-scale quantum computers showing great promise for near-term applications, a number of machine learning algorithms based on parametrized quantum circuits have been suggested as possible means to achieve learning advantages. Yet, our understanding of how these quantum machine learning models compare, both to existing classical models and to each other, remains limited. A big step in this direction has been made by relating them to so-called kernel methods from classical machine learning. By building on this connection, previous works have shown that a systematic reformulation of many quantum machine learning models as kernel models was guaranteed to improve their training performance. In this work, we first extend the applicability of this result to a more general family of parametrized quantum circuit models called data re-uploading circuits. Secondly, we show, through simple constructions and numerical simulations, that models defined and trained variationally can exhibit a critically better generalization performance than their kernel formulations, which is the true figure of merit of machine learning tasks. Our results constitute another step towards a more comprehensive theory of quantum machine learning models next to kernel formulations.
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Citations
Quantum machine learning for image classification
Arsenii Senokosov,Alexander Sedykh,A. B. Sagingalieva,Basil Kyriacou,Alexey A. Melnikov +4 more
- 20 Feb 2024
TL;DR: Two Quantum Machine Learning models that leverage the principles of quantum mechanics for effective computations are introduced, enabling the execution of computations even in the Noisy Intermediate-Scale Quantum era, where circuits with a large number of qubits are currently infeasible.
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Generalization despite overfitting in quantum machine learning models
TL;DR: Benign overfitting in quantum machine learning models characterized. Quantum models exhibit analogous features to classical models, linking overparameterization and overfitting to circuit structure.
Quantum Kernels for Real-World Predictions Based on Electronic Health Records
TL;DR: In this paper , the authors report the first systematic investigation of empirical quantum advantage (EQA) in healthcare and life sciences and propose an end-to-end framework to study EQA.
Quantum Phase Recognition via Quantum Kernel Methods
TL;DR: In this article , the power of quantum learning algorithms in solving an important class of Quantum Phase Recognition (QPR) problems, which are crucially important in understanding many-particle quantum systems, was explored.
Accurate Image Multi-Class Classification Neural Network Model with Quantum Entanglement Approach
TL;DR: In this article , a neural network with quantum entanglement (NNQE) was proposed for image classification neural networks for colored and complex data, which uses a strongly entangled quantum circuit combined with Hadamard gates.
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