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Auteurs principaux: Cao, Shuxiang, Shao, Zhen, Zheng, Jian-Qing, Alghadeer, Mohammed, Fasciati, Simone D, Piscitelli, Michele, Spring, Peter A, Wang, Shiyu, Tamate, Shuhei, Vora, Neel, Xu, Yilun, Huang, Gang, Nowrouzi, Kasra, Nakamura, Yasunobu, Siddiqi, Irfan, Leek, Peter, Lyons, Terry, Bakr, Mustafa
Format: Preprint
Publié: 2024
Sujets:
Accès en ligne:https://arxiv.org/abs/2402.09532
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author Cao, Shuxiang
Shao, Zhen
Zheng, Jian-Qing
Alghadeer, Mohammed
Fasciati, Simone D
Piscitelli, Michele
Spring, Peter A
Wang, Shiyu
Tamate, Shuhei
Vora, Neel
Xu, Yilun
Huang, Gang
Nowrouzi, Kasra
Nakamura, Yasunobu
Siddiqi, Irfan
Leek, Peter
Lyons, Terry
Bakr, Mustafa
author_facet Cao, Shuxiang
Shao, Zhen
Zheng, Jian-Qing
Alghadeer, Mohammed
Fasciati, Simone D
Piscitelli, Michele
Spring, Peter A
Wang, Shiyu
Tamate, Shuhei
Vora, Neel
Xu, Yilun
Huang, Gang
Nowrouzi, Kasra
Nakamura, Yasunobu
Siddiqi, Irfan
Leek, Peter
Lyons, Terry
Bakr, Mustafa
contents Quantum non-demolition measurement plays an essential role in quantum technology, crucial for quantum error correction, metrology, and sensing. Conventionally, the qubit state is classified from the raw or integrated time-domain measurement record. Here, we demonstrate a method to enhance the assignment fidelity of the readout by considering the "path signature" of this measurement record, where the path signature is a mathematical tool for analyzing stochastic time series. We evaluate this approach across five different hardware setups, including those with and without readout multiplexing and parametric amplifiers, and demonstrate a significant improvement in assignment fidelity across all setups. Moreover, we show that the path signature of the measurement record provides an expressive feature set that can be used to detect and classify state transitions that occurred during the measurement, improving the prediction of the qubit state at the end of the measurement. This method has the potential to become a foundational tool for quantum technology.
format Preprint
id arxiv_https___arxiv_org_abs_2402_09532
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Superconducting qubit readout enhanced by path signature
Cao, Shuxiang
Shao, Zhen
Zheng, Jian-Qing
Alghadeer, Mohammed
Fasciati, Simone D
Piscitelli, Michele
Spring, Peter A
Wang, Shiyu
Tamate, Shuhei
Vora, Neel
Xu, Yilun
Huang, Gang
Nowrouzi, Kasra
Nakamura, Yasunobu
Siddiqi, Irfan
Leek, Peter
Lyons, Terry
Bakr, Mustafa
Quantum Physics
Quantum non-demolition measurement plays an essential role in quantum technology, crucial for quantum error correction, metrology, and sensing. Conventionally, the qubit state is classified from the raw or integrated time-domain measurement record. Here, we demonstrate a method to enhance the assignment fidelity of the readout by considering the "path signature" of this measurement record, where the path signature is a mathematical tool for analyzing stochastic time series. We evaluate this approach across five different hardware setups, including those with and without readout multiplexing and parametric amplifiers, and demonstrate a significant improvement in assignment fidelity across all setups. Moreover, we show that the path signature of the measurement record provides an expressive feature set that can be used to detect and classify state transitions that occurred during the measurement, improving the prediction of the qubit state at the end of the measurement. This method has the potential to become a foundational tool for quantum technology.
title Superconducting qubit readout enhanced by path signature
topic Quantum Physics
url https://arxiv.org/abs/2402.09532