Quantum-enhanced bosonic learning machine
Abstract
Quantum processors enable computational speedups for machine learning through parallel manipulation of high-dimensional vectors. Early demonstrations of quantum machine learning have focused on processing information with qubits. In such systems, a larger computational space is provided by the collective space of multiple physical qubits. Alternatively, we can encode and process information in the infinite-dimensional Hilbert space of bosonic systems such as quantum harmonic oscillators. This approach offers a hardware-efficient solution with potential quantum speedups to practical machine learning problems. Here we demonstrate a quantum-enhanced bosonic learning machine operating on quantum data with a system of trapped ions. Core elements of the learning processor are the universal feature-embedding circuit that encodes data into the motional states of ions, and the constant-depth circuit that estimates overlap between two quantum states. We implement the unsupervised K-means algorithm to recognize a pattern in a set of high-dimensional quantum states and use the discovered knowledge to classify unknown quantum states with the supervised k-NN algorithm. These results provide building blocks for exploring machine learning with bosonic processors.
Cite
@article{arxiv.2104.04168,
title = {Quantum-enhanced bosonic learning machine},
author = {Chi-Huan Nguyen and Ko-Wei Tseng and Gleb Maslennikov and H. C. J. Gan and Dzmitry Matsukevich},
journal= {arXiv preprint arXiv:2104.04168},
year = {2021}
}
Comments
10 pages, 8 figures