QuaSiMo: A composable library to program hybrid workflows for quantum simulation

Thien Nguyen; Lindsay Bassman Oftelie; Phillip C. Lotshaw; Dmitry Lyakh; Alexander McCaskey; Vicente Leyton‐Ortega; Raphael Pooser; Wael Elwasif; Travis S. Humble; Wibe A. deJong

doi:10.1049/qtc2.12024

IET Quantum Communication (Dec 2021)

QuaSiMo: A composable library to program hybrid workflows for quantum simulation

Thien Nguyen,
Lindsay Bassman Oftelie,
Phillip C. Lotshaw,
Dmitry Lyakh,
Alexander McCaskey,
Vicente Leyton‐Ortega,
Raphael Pooser,
Wael Elwasif,
Travis S. Humble,
Wibe A. deJong

Affiliations

Thien Nguyen: Computer Science and Mathematics Division Oak Ridge National Laboratory Oak Ridge Tennessee USA
Lindsay Bassman Oftelie: Computational Research Division Lawrence Berkeley National Laboratory Berkeley California USA
Phillip C. Lotshaw: Quantum Computing Institute Oak Ridge National Laboratory Oak Ridge Tennessee USA
Dmitry Lyakh: Quantum Computing Institute Oak Ridge National Laboratory Oak Ridge Tennessee USA
Alexander McCaskey: Computer Science and Mathematics Division Oak Ridge National Laboratory Oak Ridge Tennessee USA
Vicente Leyton‐Ortega: Quantum Computing Institute Oak Ridge National Laboratory Oak Ridge Tennessee USA
Raphael Pooser: Quantum Computing Institute Oak Ridge National Laboratory Oak Ridge Tennessee USA
Wael Elwasif: Quantum Computing Institute Oak Ridge National Laboratory Oak Ridge Tennessee USA
Travis S. Humble: Computer Science and Mathematics Division Oak Ridge National Laboratory Oak Ridge Tennessee USA
Wibe A. deJong: Computational Research Division Lawrence Berkeley National Laboratory Berkeley California USA

DOI: https://doi.org/10.1049/qtc2.12024
Journal volume & issue: Vol. 2, no. 4
pp. 160 – 170

Abstract

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Abstract A composable design scheme is presented for the development of hybrid quantum/classical algorithms and workflows for applications of quantum simulation. The proposed object‐oriented approach is based on constructing an expressive set of common data structures and methods that enables programming of a broad variety of complex hybrid quantum simulation applications. The abstract core of the scheme is distilled from the analysis of the current quantum simulation algorithms. Subsequently, it allows synthesis of new hybrid algorithms and workflows via the extension, specialisation, and dynamic customisation of the abstract core classes defined by the proposed design. The design scheme is implemented using the hardware‐agnostic programming language QCOR into the QuaSiMo library. To validate the implementation, the authors test and show its utility on commercial quantum processors from IBM and Rigetti, running some prototypical quantum simulations.

Published in IET Quantum Communication

ISSN: 2632-8925 (Online)
Publisher: Wiley
Country of publisher: United Kingdom
LCC subjects: Technology: Electrical engineering. Electronics. Nuclear engineering: Telecommunication
Website: https://ietresearch.onlinelibrary.wiley.com/journal/26328925

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