Performance of a 1319 nm laser radar using RF pulse compression

Spaceborne lidars have been shown to provide data on surface elevation, vegetation canopy heights, and aerosol characteristics. Satellites carrying lidars for measuring ice sheet surface elevation and vegetation canopy heights are scheduled to be launched in the next few years. To achieve the necess...

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Bibliographic Details
Main Authors: Christopher Allen Yanki, Christopher Allen, Yanki Cobanoglu, Sekken Kenny Chong, Sivaprasad Gogineni
Other Authors: The Pennsylvania State University CiteSeerX Archives
Format: Text
Language:English
Published: 2001
Subjects:
Online Access:http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.21.1079
http://rsl.ukans.edu/publications/documents/Allen2001_IGARSS01paper.pdf
Description
Summary:Spaceborne lidars have been shown to provide data on surface elevation, vegetation canopy heights, and aerosol characteristics. Satellites carrying lidars for measuring ice sheet surface elevation and vegetation canopy heights are scheduled to be launched in the next few years. To achieve the necessary resolution and sensitivity, lidars on these satellites will use short duration, high peak power transmit pulses. Because of their high peak power, these lidars must be operated with a low pulse repetition frequency (PRF). The high peak power operation results in limited lidar lifetime and the low PRF provides insufficient spatial samples along the satellite track. To overcome these limitations of high peak power systems, at The University of Kansas we have developed a low peak power laser radar using modern RF techniques and fiber-optic technologies developed in support of the communication industry. We used RF pulse compression to achieve the sensitivity needed for spaceborne applicatons and have increased the PRF to provide more dense sampling. We have developed and reported (IGARSS 99 [1], 00 [2]) preliminary results of a fiber-optic-based, laser radar that applies RF pulse compression and digital signal processing techniques to improve receiver sensitivity and range measurement capabilities. With our improved super-heterodyne receiver, we have achieved receiver sensitivities below-100 dBm with transmit pulses with 40 s duration, 260 MHz bandwidth, and a 4 kHz PRF. These parameters are sufficient for altimeter operation from a satellite. Over the last six months we have modified the receiver architecture, performed detailed system simulations, developed a new data acquisition system, and conducted laboratory tests to verify simulation results. In this paper we will.