A method of extracting operating parameters of a quantum circuit

ORAL

Abstract

Rigorous simulation-driven design methods are an essential component of traditional integrated circuit design. We adapt these techniques to the design and development of superconducting quantum integrated circuits by combining classical finite element analysis in the microwave domain with Brune circuit synthesis by Solgun [PhD thesis 2014] and BKD Hamiltonian analysis by Burkard et al. [Phys. Rev. B \textbf{69}, 064503 (2004)]. Using the Hamiltonian of the quantum circuit, constructed using the synthesized equivalent linear circuit and the nonlinear Josephson junctions' contributions, we extract operating parameters of the quantum circuit such as resonance coupling strength, dispersive shift, qubit anharmonicitiy, and decoherence rates for single-and multi-port quantum circuits. This approach has been experimentally validated and allows the closed-loop iterative simulation-driven development of quantum information processing devices.

Authors

  • Eyob A. Sete

    • Rigetti Quantum Computing
    • Rigetti Quantum Computing, Berkeley, CA

  • Maxwell Block

    • Rigetti Quantum Computing, Berkeley, CA

  • Michael Scheer

    • Rigetti Quantum Computing, Berkeley, CA

  • Cris Zanoci

    • Rigetti Quantum Computing, Berkeley, CA

  • Mehrnoosh Vahidpour

    • Rigetti Quantum Computing, Berkeley, CA

  • Dane Thompson

    • Rigetti Quantum Computing
    • Rigetti Quantum Computing, Berkeley, CA

  • Chad Rigetti

    • Rigetti Quantum Computing
    • Rigetti Quantum Computing, Berkeley, CA