English

sQueeze: Accelerated Quantum Pulse Schedules

Quantum Physics 2023-11-16 v1

Abstract

Quantum devices in the Noisy Intermediate-Scale Quantum (NISQ) era are limited by high error rates and short decoherence times. Typically, compiler optimisations have provided solutions at the gate level. Alternatively, we exploit the finest level of quantum control and introduce a set of pulse level quantum compiler optimisations: sQueeze. Instead of relying on existing calibration that may be inaccurate, we provide a method for the live calibration of two new parameterised basis gates Rx(θ)R_{x}(\theta) and Rzx(θ)R_{zx}(\theta) using an external server. We validate our techniques using the IBM quantum devices and the OpenPulse control interface over more than 8 billion shots. The Rx(θ)R_{x}(\theta) gates are on average 52.7% more accurate than their current native Qiskit decompositions, while Rzx(θ)R_{zx}(\theta) are 22.6% more accurate on average. These more accurate pulses also provide up to a 4.1×\times speed-up for single-qubit operations and 3.1×\times speed-up for two-qubit gates. Then sQueeze demonstrates up to a 39.6% improvement in the fidelity of quantum benchmark algorithms compared to conventional approaches.

Keywords

Cite

@article{arxiv.2311.08742,
  title  = {sQueeze: Accelerated Quantum Pulse Schedules},
  author = {Lilian Hunt Alan Robertson},
  journal= {arXiv preprint arXiv:2311.08742},
  year   = {2023}
}
R2 v1 2026-06-28T13:21:44.074Z