Quantum error mitigation for fault-tolerant quantum computing

ORAL

Abstract

Fault-tolerant quantum computing (FTQC) implements universal quantum computing while suppressing physical errors via quantum error correction. Although the effective error rate decreases exponentially with the code distance, it is expected that the number of available physical qubits is restricted even after FTQC is realized in some form. Meanwhile, quantum error mitigation (QEM) was recently introduced for suppressing errors in Noisy Intermediate-Scale Quantum (NISQ) devices for improving computation accuracy of near-term quantum algorithms with its overhead being a greater number of samples. In this work, we show QEM can compensate dominant errors in FTQC without increasing the number of qubits. This scheme will dramatically alleviate required overheads of FTQC for achieving a high-accuracy quantum computing.

*This work is supported by PRESTO, JST, Grant No. JPMJPR1916; ERATO, JST, Grant No. JPMJER1601; CREST, JST, Grant No. JPMJCR1771; MEXT Q-LEAP Grant No. JPMXS0120319794 and JPMXS0118068682.

Presenters

  • Yasunari Suzuki

    • NTT Corporation

Authors

  • Yasunari Suzuki

    • NTT Corporation

  • Suguru Endo

    • NTT Secure Platform Laboratories, NTT Corporation
    • NTT Corporation

  • Yuuki Tokunaga

    • NTT Corporation