A Micropulse eye-safe all-fiber molecular backscatter coherent temperature lidar

Cyrus F. Abari; Xinzhao Chu; Jakob Mann; Scott Spuler

doi:10.1051/epjconf/201611925005

A Micropulse eye-safe all-fiber molecular backscatter coherent temperature lidar

Cyrus F. Abari, Xinzhao Chu, Jakob Mann, Scott Spuler

Earth Observing Lab

Research output: Contribution to journal › Conference article › peer-review

3 Scopus citations

Abstract

In this paper, we analyze the performance of an all-fiber, micropulse, 1.5 μm coherent lidar for remote sensing of atmospheric temperature. The proposed system benefits from the recent advances in optics/electronics technology, especially an all-fiber image-reject homodyne receiver, where a high resolution spectrum in the baseband can be acquired. Due to the presence of a structured spectra resulting from the spontaneous Rayleigh-Brillouine scattering, associated with the relevant operating regimes, an accurate estimation of the temperature can be carried out. One of the main advantages of this system is the removal of the contaminating Mie backscatter signal by electronic filters at the baseband (before signal conditioning and amplification). The paper presents the basic concepts as well as a Monte-Carlo system simulation as the proof of concept.

Original language	English
Article number	25005
Journal	EPJ Web of Conferences
Volume	119
DOIs	https://doi.org/10.1051/epjconf/201611925005
State	Published - Jun 7 2016
Event	27th International Laser Radar Conference, ILRC 2015 - New York, United States Duration: Jul 5 2015 → Jul 10 2015

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title = "A Micropulse eye-safe all-fiber molecular backscatter coherent temperature lidar",

abstract = "In this paper, we analyze the performance of an all-fiber, micropulse, 1.5 μm coherent lidar for remote sensing of atmospheric temperature. The proposed system benefits from the recent advances in optics/electronics technology, especially an all-fiber image-reject homodyne receiver, where a high resolution spectrum in the baseband can be acquired. Due to the presence of a structured spectra resulting from the spontaneous Rayleigh-Brillouine scattering, associated with the relevant operating regimes, an accurate estimation of the temperature can be carried out. One of the main advantages of this system is the removal of the contaminating Mie backscatter signal by electronic filters at the baseband (before signal conditioning and amplification). The paper presents the basic concepts as well as a Monte-Carlo system simulation as the proof of concept.",

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T1 - A Micropulse eye-safe all-fiber molecular backscatter coherent temperature lidar

AU - Abari, Cyrus F.

AU - Chu, Xinzhao

AU - Mann, Jakob

AU - Spuler, Scott

PY - 2016/6/7

Y1 - 2016/6/7

N2 - In this paper, we analyze the performance of an all-fiber, micropulse, 1.5 μm coherent lidar for remote sensing of atmospheric temperature. The proposed system benefits from the recent advances in optics/electronics technology, especially an all-fiber image-reject homodyne receiver, where a high resolution spectrum in the baseband can be acquired. Due to the presence of a structured spectra resulting from the spontaneous Rayleigh-Brillouine scattering, associated with the relevant operating regimes, an accurate estimation of the temperature can be carried out. One of the main advantages of this system is the removal of the contaminating Mie backscatter signal by electronic filters at the baseband (before signal conditioning and amplification). The paper presents the basic concepts as well as a Monte-Carlo system simulation as the proof of concept.

AB - In this paper, we analyze the performance of an all-fiber, micropulse, 1.5 μm coherent lidar for remote sensing of atmospheric temperature. The proposed system benefits from the recent advances in optics/electronics technology, especially an all-fiber image-reject homodyne receiver, where a high resolution spectrum in the baseband can be acquired. Due to the presence of a structured spectra resulting from the spontaneous Rayleigh-Brillouine scattering, associated with the relevant operating regimes, an accurate estimation of the temperature can be carried out. One of the main advantages of this system is the removal of the contaminating Mie backscatter signal by electronic filters at the baseband (before signal conditioning and amplification). The paper presents the basic concepts as well as a Monte-Carlo system simulation as the proof of concept.

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DO - 10.1051/epjconf/201611925005

M3 - Conference article

AN - SCOPUS:84976291213

SN - 2101-6275

VL - 119

JO - EPJ Web of Conferences

JF - EPJ Web of Conferences

M1 - 25005

T2 - 27th International Laser Radar Conference, ILRC 2015

Y2 - 5 July 2015 through 10 July 2015

ER -

A Micropulse eye-safe all-fiber molecular backscatter coherent temperature lidar

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