Quantum state preparation and nonunitary evolution with diagonal operators

Anthony W. Schlimgen, Kade Head-Marsden, Lee Ann M. Sager-Smith, Prineha Narang, David A. Mazziotti

Research output: Contribution to journalArticlepeer-review

14 Scopus citations

Abstract

Realizing nonunitary transformations on unitary-gate-based quantum devices is critically important for simulating a variety of physical problems, including open quantum systems and subnormalized quantum states. We present a dilation-based algorithm to simulate nonunitary operations using probabilistic quantum computing with only one ancilla qubit. We utilize the singular-value decomposition (SVD) to decompose any general quantum operator into a product of two unitary operators and a diagonal nonunitary operator, which we show can be implemented by a diagonal unitary operator in a one-qubit dilated space. While dilation techniques increase the number of qubits in the calculation, and thus the gate complexity, our algorithm limits the operations required in the dilated space to a diagonal unitary operator, which has known circuit decompositions. We use this algorithm to prepare random subnormalized two-level states on a quantum device with high fidelity. Furthermore, we present the accurate nonunitary dynamics of two-level open quantum systems in a dephasing channel and an amplitude-damping channel computed on a quantum device. The algorithm presented will be most useful for implementing general nonunitary operations when the SVD can be readily computed, which is the case for most operators in the noisy intermediate-scale quantum computing era.

Original languageEnglish (US)
Article number022414
JournalPhysical Review A
Volume106
Issue number2
DOIs
StatePublished - Aug 2022
Externally publishedYes

Bibliographical note

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© 2022 American Physical Society.

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