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Learning the quantum algorithm for state overlap
release_ilvbm4fvl5d35gimr6smdwvmki
by
Lukasz Cincio,
Yiğit Subaşı,
Andrew T. Sornborger,
Patrick
J. Coles
Released
as a report
.
2018
Abstract
Short-depth algorithms are crucial for reducing computational error on
near-term quantum computers, for which decoherence and gate infidelity remain
important issues. Here we present a machine-learning approach for discovering
such algorithms. We apply our method to a ubiquitous primitive: computing the
overlap Tr(ρσ) between two quantum states ρ and σ.
The standard algorithm for this task, known as the Swap Test, is used in many
applications such as quantum support vector machines, and, when specialized to
ρ = σ, quantifies the Renyi entanglement. Here, we find algorithms
that have shorter depths than the Swap Test, including one that has a constant
depth (independent of problem size). Furthermore, we apply our approach to the
hardware-specific connectivity and gate sets used by Rigetti's and IBM's
quantum computers and demonstrate that the shorter algorithms that we derive
significantly reduce the error - compared to the Swap Test - on these
computers.
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