Angle-dependent quantum efficiency correction for improved signal accuracy in small-scale Scheimpflug lidar systems

Siying Chen; Jiarui Yin; He Chen; Wangshu Tan; Pan Guo; Yurong Jiang; Qingyue Xu; Daoming Li; Fan Xue; Huiyun Wu

doi:10.1364/AO.523145

Angle-dependent quantum efficiency correction for improved signal accuracy in small-scale Scheimpflug lidar systems

Siying Chen, Jiarui Yin, He Chen^*, Wangshu Tan, Pan Guo, Yurong Jiang, Qingyue Xu, Daoming Li, Fan Xue, Huiyun Wu

^*Corresponding author for this work

School of Optics and Photonics

Research output: Contribution to journal › Article › peer-review

Abstract

Wide-incidence-angle detection in Scheimpflug lidar causes pixel-wise variations in signal intensity due to differences in quantum efficiency across the detector. This study proposes an angular response correction factor and a correction method to address the difference caused by a wide incidence angle. A Scheimpflug lidar system was developed with a 405 nm laser and an array image sensor; it achieved a detection angle of 11.4^◦. Experiments with uniform atmosphere and smoke aerosols demonstrated the effectiveness of the correction method. For uniform atmosphere, it ensured consistent signal intensity. In smoke aerosol detection, the Klett method revealed the correction factor’s role in counteracting small-scale variations in the extinction coefficient. The method improved the extinction coefficient accuracy within 4 m by 4%–75%.

Original language	English
Pages (from-to)	4668-4678
Number of pages	11
Journal	Applied Optics
Volume	63
Issue number	17
DOIs	https://doi.org/10.1364/AO.523145
Publication status	Published - 10 Jun 2024

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title = "Angle-dependent quantum efficiency correction for improved signal accuracy in small-scale Scheimpflug lidar systems",

abstract = "Wide-incidence-angle detection in Scheimpflug lidar causes pixel-wise variations in signal intensity due to differences in quantum efficiency across the detector. This study proposes an angular response correction factor and a correction method to address the difference caused by a wide incidence angle. A Scheimpflug lidar system was developed with a 405 nm laser and an array image sensor; it achieved a detection angle of 11.4◦. Experiments with uniform atmosphere and smoke aerosols demonstrated the effectiveness of the correction method. For uniform atmosphere, it ensured consistent signal intensity. In smoke aerosol detection, the Klett method revealed the correction factor{\textquoteright}s role in counteracting small-scale variations in the extinction coefficient. The method improved the extinction coefficient accuracy within 4 m by 4%–75%.",

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T1 - Angle-dependent quantum efficiency correction for improved signal accuracy in small-scale Scheimpflug lidar systems

AU - Chen, Siying

AU - Yin, Jiarui

AU - Chen, He

AU - Tan, Wangshu

AU - Guo, Pan

AU - Jiang, Yurong

AU - Xu, Qingyue

AU - Li, Daoming

AU - Xue, Fan

AU - Wu, Huiyun

PY - 2024/6/10

Y1 - 2024/6/10

N2 - Wide-incidence-angle detection in Scheimpflug lidar causes pixel-wise variations in signal intensity due to differences in quantum efficiency across the detector. This study proposes an angular response correction factor and a correction method to address the difference caused by a wide incidence angle. A Scheimpflug lidar system was developed with a 405 nm laser and an array image sensor; it achieved a detection angle of 11.4◦. Experiments with uniform atmosphere and smoke aerosols demonstrated the effectiveness of the correction method. For uniform atmosphere, it ensured consistent signal intensity. In smoke aerosol detection, the Klett method revealed the correction factor’s role in counteracting small-scale variations in the extinction coefficient. The method improved the extinction coefficient accuracy within 4 m by 4%–75%.

AB - Wide-incidence-angle detection in Scheimpflug lidar causes pixel-wise variations in signal intensity due to differences in quantum efficiency across the detector. This study proposes an angular response correction factor and a correction method to address the difference caused by a wide incidence angle. A Scheimpflug lidar system was developed with a 405 nm laser and an array image sensor; it achieved a detection angle of 11.4◦. Experiments with uniform atmosphere and smoke aerosols demonstrated the effectiveness of the correction method. For uniform atmosphere, it ensured consistent signal intensity. In smoke aerosol detection, the Klett method revealed the correction factor’s role in counteracting small-scale variations in the extinction coefficient. The method improved the extinction coefficient accuracy within 4 m by 4%–75%.

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U2 - 10.1364/AO.523145

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Angle-dependent quantum efficiency correction for improved signal accuracy in small-scale Scheimpflug lidar systems

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