English

Hardware optimized parity check gates for superconducting surface codes

Quantum Physics 2022-11-14 v1

Abstract

Error correcting codes use multi-qubit measurements to realize fault-tolerant quantum logic steps. In fact, the resources needed to scale-up fault-tolerant quantum computing hardware are largely set by this task. Tailoring next-generation processors for joint measurements, therefore, could result in improvements to speed, accuracy, or cost -- accelerating the development large-scale quantum computers. Here, we motivate such explorations by analyzing an unconventional surface code based on multi-body interactions between superconducting transmon qubits. Our central consideration, Hardware Optimized Parity (HOP) gates, achieves stabilizer-type measurements through simultaneous multi-qubit conditional phase accumulation. Despite the multi-body effects that underpin this approach, our estimates of logical faults suggest that this design can be at least as robust to realistic noise as conventional designs. We show a higher threshold of 1.25×1031.25 \times 10^{-3} compared to the standard code's 0.79×1030.79 \times 10^{-3}. However, in the HOP code the logical error rate decreases more slowly with decreasing physical error rate. Our results point to a fruitful path forward towards extending gate-model platforms for error correction at the dawn of its empirical development.

Keywords

Cite

@article{arxiv.2211.06382,
  title  = {Hardware optimized parity check gates for superconducting surface codes},
  author = {Matthew J. Reagor and Thomas C. Bohdanowicz and David Rodriguez Perez and Eyob A. Sete and William J. Zeng},
  journal= {arXiv preprint arXiv:2211.06382},
  year   = {2022}
}

Comments

13 page manuscript (21 total), 10 manuscript figures (12 total)

R2 v1 2026-06-28T05:41:54.131Z