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Autores principales: Abramavicius, Vytautas, Mathé, Melvin, Velikova, Gergana V., Moutinho, João P., Dagrada, Mario, Elfving, Vincent E., Dauphin, Alexandre, Vovrosh, Joseph, Guichard, Roland
Formato: Preprint
Publicado: 2025
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Acceso en línea:https://arxiv.org/abs/2505.16744
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author Abramavicius, Vytautas
Mathé, Melvin
Velikova, Gergana V.
Moutinho, João P.
Dagrada, Mario
Elfving, Vincent E.
Dauphin, Alexandre
Vovrosh, Joseph
Guichard, Roland
author_facet Abramavicius, Vytautas
Mathé, Melvin
Velikova, Gergana V.
Moutinho, João P.
Dagrada, Mario
Elfving, Vincent E.
Dauphin, Alexandre
Vovrosh, Joseph
Guichard, Roland
contents Programming analog quantum processing units (QPUs), such as those produced by Pasqal, can be achieved using specialized low-level pulse libraries like Pulser. However, few currently offer the possibility to optimize pulse sequence parameters. In this paper, we introduce PulserDiff, a user-friendly and open-source Pulser extension designed to optimize pulse sequences over a well-defined set of control parameters that drive the quantum computation. We demonstrate its usefulness through several case studies involving analog configurations that emulate digital gates and state preparation. PulserDiff produces hardware-compatible pulses with remarkably high fidelities, showcasing its potential for advancing analog quantum computing applications.
format Preprint
id arxiv_https___arxiv_org_abs_2505_16744
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle PulserDiff: a pulse differentiable extension for Pulser
Abramavicius, Vytautas
Mathé, Melvin
Velikova, Gergana V.
Moutinho, João P.
Dagrada, Mario
Elfving, Vincent E.
Dauphin, Alexandre
Vovrosh, Joseph
Guichard, Roland
Quantum Physics
Programming analog quantum processing units (QPUs), such as those produced by Pasqal, can be achieved using specialized low-level pulse libraries like Pulser. However, few currently offer the possibility to optimize pulse sequence parameters. In this paper, we introduce PulserDiff, a user-friendly and open-source Pulser extension designed to optimize pulse sequences over a well-defined set of control parameters that drive the quantum computation. We demonstrate its usefulness through several case studies involving analog configurations that emulate digital gates and state preparation. PulserDiff produces hardware-compatible pulses with remarkably high fidelities, showcasing its potential for advancing analog quantum computing applications.
title PulserDiff: a pulse differentiable extension for Pulser
topic Quantum Physics
url https://arxiv.org/abs/2505.16744