from Optical Depth GeometryB – May2014.docx
Abshire, J. B., Riris, H., Allan, G. R., Weaver, C. J., Mao, J., Sun, X., Hasselbrack, W. E., Kawa, S. R. and Biraud, S., “Pulsed airborne lidar measurements of atmospheric CO2 column absorption.“ Tellus B, (2010).
Abshire J, Riris H, Allan G, Weaver C, Mao J, Sun X, Hasselbrack W, Yu A, Amediek A, Choi Y, et al. “A Lidar Approach to Measure CO2 Concentrations from Space for the ASCENDS Mission”. Conference on Lidar Technologies, Techniques, and Measurements for Atmospheric Remote Sensing VI; SEP 20-21, 2010; Toulouse, FRANCE. 2010.
Browell, et al, 2010, “Airborne Validation of LASER Remote Measurements of Atmospheric Carbon Dioxide”, EGU General Assembly 2010, Vienna, Austria and related presentations
NIST: Physical Constants
http://physics.nist.gov/cuu/Constants/index.html
Standard Atmosphere
http://modelweb.gsfc.nasa.gov/atmos/about_atmos.html
http://www.atmosculator.com/The%20Standard%20Atmosphere.html?
T. Machida, K. Kita, Y. Kondo, D. Blake, S. Kawakami, G. Inoue, and T. Ogawa, “Vertical and meridional distributions of the atmospheric CO2 mixing ratio between northern midlatitudes and southern subtropics”, Jour Geo R, v108, nD3, 2003
Michael E. Webber, Suhong Kim, Scott T. Sanders, Douglas S. Baer, Ronald K. Hanson, and Yuji Ikeda, “In situ combustion measurements of CO2 by use of a distributed-feedback diode-laser sensor near 2.0 um”, Applied Optics, v40, n6, Feb 2001
Schwartz, S E, “Feedback and sensitivity in an electrical circuit: an analog for climate models”, Climatic Change (2011) 106:315–326
Shumpei Kameyama, et al, “Feasibility study on 1:6 μm continuous-wave modulation laser absorption spectrometer system for measurement of global CO2 concentration from a satellite”, Applied Optics, v50, n14 Sun, X., Abshire, J. B., “Comparison of IPDA lidar receiver sensitivity for coherent detection and for direct detection using sine-wave and pulsed modulation “, Optics Express, 2012
That’s a wrap
Back 10: Ranging Radar
Up: Articles
