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Proceedings Paper

The integrated atmospheric characterization system (IACS)
Author(s): D. W. Roberts; K. R. Albers; E. A. Brown; T. A. Craney; M. M. Hosain; R. K. James; N. D. Meraz; A. J. Mercer; K. D. Nielson; R. L. Ortman; T. W. Pool; J. W. Wood; J. M. Stewart; T. M. Strike; G. G. Gimmestad; D. N. Whiteman
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Paper Abstract

The Georgia Tech Research Institute (GTRI) is developing a transportable multi-lidar instrument known as the Integrated Atmospheric Characterization System (IACS). The system will be housed in two shipping containers that will be transported to remote sites on a low-boy trailer. IACS will comprise three lidars: a 355 nm imaging lidar for profiling refractive turbulence, a 355 nm Raman lidar for profiling water vapor, and an aerosol lidar operating at 355 nm as well as 1.064 and 1.627 µm. All of the lidar transmit/receive optics will be on a common mount, pointable at any elevation angle from 10 degrees below horizontal to vertical. The entire system will be computer controlled to facilitate pointing and automatic data acquisition. The purpose of IACS is to characterize optical propagation paths during outdoor tests of electro-optical systems. The tests are anticipated to include ground-to-ground, air-to-ground, and ground-to-air scenarios, so the system must accommodate arbitrary slant paths through the atmosphere, with maximum measurement ranges of 5-10 km. Elevation angle scans will be used to determine atmospheric extinction profiles at the infrared wavelengths, and data from the three wavelengths will be used to determine the aerosol Angstrom coefficient, enabling interpolation of results to other wavelengths in the 355 nm to 1.627 µm region.

Paper Details

Date Published: 9 June 2014
PDF: 8 pages
Proc. SPIE 9080, Laser Radar Technology and Applications XIX; and Atmospheric Propagation XI, 90801E (9 June 2014); doi: 10.1117/12.2050600
Show Author Affiliations
D. W. Roberts, Georgia Tech Research Institute (United States)
K. R. Albers, Georgia Tech Research Institute (United States)
E. A. Brown, Georgia Tech Research Institute (United States)
T. A. Craney, Georgia Tech Research Institute (United States)
M. M. Hosain, Georgia Tech Research Institute (United States)
R. K. James, Georgia Tech Research Institute (United States)
N. D. Meraz, Georgia Tech Research Institute (United States)
A. J. Mercer, Georgia Tech Research Institute (United States)
K. D. Nielson, Georgia Tech Research Institute (United States)
R. L. Ortman, Georgia Tech Research Institute (United States)
T. W. Pool, Georgia Tech Research Institute (United States)
J. W. Wood, Georgia Tech Research Institute (United States)
J. M. Stewart, Georgia Tech Research Institute (United States)
T. M. Strike, Georgia Tech Research Institute (United States)
G. G. Gimmestad, Georgia Tech Research Institute (United States)
D. N. Whiteman, NASA Goddard Space Flight Ctr. (United States)


Published in SPIE Proceedings Vol. 9080:
Laser Radar Technology and Applications XIX; and Atmospheric Propagation XI
Monte D. Turner; Linda M. Wasiczko Thomas; Gary W. Kamerman; Earl J. Spillar, Editor(s)

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