Optimized Quantum Compilation for Near-Term Algorithms with OpenPulse

Quantum computers are traditionally operated by programmers at the granularity of a gate-based instruction set. However, the actual device-level control of a quantum computer is performed via analog pulses. We introduce a compiler that exploits direct control at this microarchitectural level to achi...

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Bibliographic Details
Published in2020 53rd Annual IEEE/ACM International Symposium on Microarchitecture (MICRO) pp. 186 - 200
Main Authors Gokhale, Pranav, Javadi-Abhari, Ali, Earnest, Nathan, Shi, Yunong, Chong, Frederic T.
Format Conference Proceeding
LanguageEnglish
Published IEEE 01.10.2020
Subjects
OpenPulse
pulse control
quantum computing
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Summary:Quantum computers are traditionally operated by programmers at the granularity of a gate-based instruction set. However, the actual device-level control of a quantum computer is performed via analog pulses. We introduce a compiler that exploits direct control at this microarchitectural level to achieve significant improvements for quantum programs. Unlike quantum optimal control, our approach is bootstrapped from existing gate calibrations and the resulting pulses are simple. Our techniques are applicable to any quantum computer and realizable on current devices. We validate our techniques with millions of experimental shots on IBM quantum computers, controlled via the OpenPulse control interface. For representative benchmarks, our pulse control techniques achieve both 1.6x lower error rates and 2x faster execution time, relative to standard gate-based compilation. These improvements are critical in the near-term era of quantum computing, which is bottlenecked by error rates and qubit lifetimes.
DOI:10.1109/MICRO50266.2020.00027