Development of a photon-counting deadtime noise model that extends dynamic range and resolution in atmospheric lidar

Grant J. Kirchhoff; Matthew Hayman; Willem J. Marais; Jeffrey P. Thayer; Rory A. Barton-Grimley

doi:10.1364/AO.543305

Development of a photon-counting deadtime noise model that extends dynamic range and resolution in atmospheric lidar

Grant J. Kirchhoff, Matthew Hayman, Willem J. Marais, Jeffrey P. Thayer, Rory A. Barton-Grimley

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

Abstract

This work derives and validates a noise model that encapsulates the deadtime of non-paralyzable detectors with random photon arrivals to enable advanced processing, such as maximum-likelihood estimation, of high-resolution atmospheric lidar profiles, while accounting for deadtime bias. This estimator was validated across a wide dynamic range at high resolution (4 mm in range and 17 ms in time). Experiments demonstrate that the noise model outperforms the current state-of-the-art for very short time-of-flight (2 ns) and extended targets (1 µs). The proposed noise model also produces accurate deadtime correction for very short integration times. This work sets the foundation for further study into accurate retrievals of high flux and dynamic atmospheric features, e.g., clouds and aerosol layers.

Original language	English
Pages (from-to)	4568-4581
Number of pages	14
Journal	Applied Optics
Volume	64
Issue number	16
DOIs	https://doi.org/10.1364/AO.543305
State	Published - Jun 1 2025
Externally published	Yes

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title = "Development of a photon-counting deadtime noise model that extends dynamic range and resolution in atmospheric lidar",

abstract = "This work derives and validates a noise model that encapsulates the deadtime of non-paralyzable detectors with random photon arrivals to enable advanced processing, such as maximum-likelihood estimation, of high-resolution atmospheric lidar profiles, while accounting for deadtime bias. This estimator was validated across a wide dynamic range at high resolution (4 mm in range and 17 ms in time). Experiments demonstrate that the noise model outperforms the current state-of-the-art for very short time-of-flight (2 ns) and extended targets (1 µs). The proposed noise model also produces accurate deadtime correction for very short integration times. This work sets the foundation for further study into accurate retrievals of high flux and dynamic atmospheric features, e.g., clouds and aerosol layers.",

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doi = "10.1364/AO.543305",

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T1 - Development of a photon-counting deadtime noise model that extends dynamic range and resolution in atmospheric lidar

AU - Kirchhoff, Grant J.

AU - Hayman, Matthew

AU - Marais, Willem J.

AU - Thayer, Jeffrey P.

AU - Barton-Grimley, Rory A.

PY - 2025/6/1

Y1 - 2025/6/1

N2 - This work derives and validates a noise model that encapsulates the deadtime of non-paralyzable detectors with random photon arrivals to enable advanced processing, such as maximum-likelihood estimation, of high-resolution atmospheric lidar profiles, while accounting for deadtime bias. This estimator was validated across a wide dynamic range at high resolution (4 mm in range and 17 ms in time). Experiments demonstrate that the noise model outperforms the current state-of-the-art for very short time-of-flight (2 ns) and extended targets (1 µs). The proposed noise model also produces accurate deadtime correction for very short integration times. This work sets the foundation for further study into accurate retrievals of high flux and dynamic atmospheric features, e.g., clouds and aerosol layers.

AB - This work derives and validates a noise model that encapsulates the deadtime of non-paralyzable detectors with random photon arrivals to enable advanced processing, such as maximum-likelihood estimation, of high-resolution atmospheric lidar profiles, while accounting for deadtime bias. This estimator was validated across a wide dynamic range at high resolution (4 mm in range and 17 ms in time). Experiments demonstrate that the noise model outperforms the current state-of-the-art for very short time-of-flight (2 ns) and extended targets (1 µs). The proposed noise model also produces accurate deadtime correction for very short integration times. This work sets the foundation for further study into accurate retrievals of high flux and dynamic atmospheric features, e.g., clouds and aerosol layers.

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Development of a photon-counting deadtime noise model that extends dynamic range and resolution in atmospheric lidar

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