Initial Results from a Volume Scanning Three Wavelength Polarization Lidar

Document ID: 123

O'Brien, Michael D.
Evanisko, George R.
Philbrick, C. Russell

 The Pennsylvania State University, Department of Electrical Engineering, University Park, PA, U.S.A.
 

Presented: Second Topical Symposium on Combined Optical-Microwave Earth and Atmosphere Sensing, 3-6 April 1995

Abstract

Clouds and aerosols play an important role in the radiative processes affecting the Earth's climate and the thermodynamic properties of the atmosphere (I). Therefore, it is crucial to gain greater insight into the structure and composition of clouds and aerosols. One approach to achieving this consists of employing several different remote sensing systems operating at multiple wavelengths. At Penn State, an interdisciplinary group of researchers following this approach has developed a new research tool called WAVE-LARS (Water Aerosol Vapor Experiment - Lidar And Radar Sounder). This instrument includes a volume scanning 94 GHz radar, a volume scanning multi-wavelength lidar, and a vertically pointing Rayleigh/Raman lidar. The 94 GHz radar was based on a previous radar constructed at Penn State, augmented with new volume scanning and polarization capabilities {2]. The new radar is capable of determining cloud structure, liquid water content, and the presence of ice crystals within a selected volume of the atmosphere. The vertically pointing lidar is the Penn State LAMP Rayleigh/Raman lidar system. This system provides vertical profiles of atmospheric water vapor and temperature f3]. The theory, design, and initial results from the volume scanning lidar will be discussed in this paper [4].

 

  Access pdf copy  

Citation:        "Initial Results from a Volume Scanning Three Wavelength Polarization Lidar", O'Brien, M. D., G. R. Evanisko, C. R. Philbrick, Conference Proceedings, Combined Optical-Microwave Earth and Atmosphere Sensing, IEEE Proceedings, 1995, pp. 135 - 137, DOI: 10.1109/COMEAS. 1995.472385