Single-preparation unsupervised quantum machine learning: concepts and
applications
- URL: http://arxiv.org/abs/2101.01442v1
- Date: Tue, 5 Jan 2021 10:31:05 GMT
- Title: Single-preparation unsupervised quantum machine learning: concepts and
applications
- Authors: Yannick Deville, Alain Deville
- Abstract summary: We first analyze the connections between all problems, in the classical and quantum frameworks.
We then focus on their most challenging versions, involving quantum data and/or quantum processing means.
We propose the quite general concept of SIngle-Preparation Quantum Information Processing.
- Score: 1.7056768055368385
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: The term "machine learning" especially refers to algorithms that derive
mappings, i.e. intput/output transforms, by using numerical data that provide
information about considered transforms. These transforms appear in many
problems, related to classification/clustering, regression, system
identification, system inversion and input signal restoration/separation. We
here first analyze the connections between all these problems, in the classical
and quantum frameworks. We then focus on their most challenging versions,
involving quantum data and/or quantum processing means, and unsupervised, i.e.
blind, learning. Moreover, we propose the quite general concept of
SIngle-Preparation Quantum Information Processing (SIPQIP). The resulting
methods only require a single instance of each state, whereas usual methods
have to very accurately create many copies of each fixed state. We apply our
SIPQIP concept to various tasks, related to system identification (blind
quantum process tomography or BQPT, blind Hamiltonian parameter estimation or
BHPE, blind quantum channel identification/estimation, blind phase estimation),
system inversion and state estimation (blind quantum source separation or BQSS,
blind quantum entangled state restoration or BQSR, blind quantum channel
equalization) and classification. Numerical tests show that our framework
moreover yields much more accurate estimation than the standard
multiple-preparation approach. Our methods are especially useful in a quantum
computer, that we propose to more briefly call a "quamputer": BQPT and BHPE
simplify the characterization of the gates of quamputers; BQSS and BQSR allow
one to design quantum gates that may be used to compensate for the
non-idealities that alter states stored in quantum registers, and they open the
way to the much more general concept of self-adaptive quantum gates (see longer
version of abstract in paper).
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