The paper introduces Qibocal, an open-source software library for calibration and characterization of superconducting quantum devices. Qibocal is built on top of the Qibo framework, which provides a middleware for quantum computing.
The key highlights of the paper are:
Qibocal offers a modular and flexible design, allowing users to easily launch calibration protocols, retrieve and share results, and update the quantum processing unit (QPU) configuration.
The library includes a suite of calibration protocols for single and two-qubit gates, including spectroscopy, Rabi, Ramsey, and Chevron experiments. These protocols can be used to optimize parameters such as qubit frequency, drive pulse amplitude and duration, and two-qubit interactions.
Qibocal provides tools for benchmarking the calibrated devices, including randomized benchmarking and multi-qubit entanglement tests. These can be used to monitor the performance of the quantum hardware over time.
The authors demonstrate the capabilities of Qibocal through several use cases, including measuring qubit coherence at different bias points, optimizing single-qubit gates using randomized benchmarking, and automatic recalibration in response to changes in the flux background.
Qibocal is designed to be extensible, allowing users to develop custom calibration protocols and integrate them into the framework. The authors plan to expand the library to support a wider range of quantum hardware platforms in the future.
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