Updates to Hybrid Quantum-Classical Annealing

ORAL

Abstract

Last year. we proposed an efficient gap-independent cooling scheme for a quantum annealer that benefits from finite temperatures. We chose a system based on superconducting flux qubits as a prominent example of current quantum annealing platforms and proposed coupling the qubit systemtransversely to a coplanar waveguide to counter noise and heating that arise from always-present longitudinal thermal noise. We provide a schematic circuit layout for the system and showed we achieve global performance enhancements. However, the work covered only single-qubit annealing. In this work, we discuss different strategies to generalize HQCA to larger qubit numbers.

*The research is based upon work (partially) supportedby the Office of the Director of National Intelligence(ODNI), Intelligence Advanced Research Projects Activ-ity (IARPA), via the U.S. Army Research Office con-tract W911NF-17-C-0050. The views and conclusionscontained herein are those of the authors and shouldnot be interpreted as necessarily representing the officialpolicies or endorsements, either expressed or implied, ofthe ODNI, IARPA, or the U.S. Government. The U.S.Government is authorized to reproduce and distributereprints for Governmental purposes notwithstanding anycopyright annotation thereon.

Presenters

  • Peter Schuhmacher

    • Univ des Saarlandes

Authors

  • Peter Schuhmacher

    • Univ des Saarlandes

  • Aditi Misra

    • Univ des Saarlandes

  • Salil Bedkihal

    • University of Waterloo

  • Xi Dai

    • University of Waterloo

  • Adrian Lupascu

    • University of Waterloo

  • Frank Wilhelm

    • Universität des Saarlandes
    • Saarland University
    • Univ des Saarlandes
    • Univ Saarland
    • Theoretical Physics, Saarland University