Experimental Realization of a Quantum Autoencoder: The Compression of Qutrits via Machine Learning
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Tischler, Nora
Pryde, Geoff J
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Abstract
With quantum resources a precious commodity, their efficient use is highly desirable. Quantum autoencoders have been proposed as a way to reduce quantum memory requirements. Generally, an autoencoder is a device that uses machine learning to compress inputs, that is, to represent the input data in a lower-dimensional space. Here, we experimentally realize a quantum autoencoder, which learns how to compress quantum data using a classical optimization routine. We demonstrate that when the inherent structure of the dataset allows lossless compression, our autoencoder reduces qutrits to qubits with low error levels. We also show that the device is able to perform with minimal prior information about the quantum data or physical system and is robust to perturbations during its optimization routine.
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Physical Review Letters
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122
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6
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© 2019 American Physical Society. The attached file is reproduced here in accordance with the copyright policy of the publisher. Please refer to the journal's website for access to the definitive, published version.
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Mathematical sciences
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Physics, Multidisciplinary
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Pepper, A; Tischler, N; Pryde, GJ, Experimental Realization of a Quantum Autoencoder: The Compression of Qutrits via Machine Learning, Physical Review Letters, 2019, 122 (6)