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L M McMillin

Showing results (1-10 of 7) with videos related to

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Applied Optics|February 20, 2010
Atmospheric transmittance of an absorbing gas. 2: A computationally fast and accurate transmittance model for slant paths at different zenith anglesH E Fleming, L M McMillin
Applied Optics|February 19, 2010
Atmospheric transmittance of an absorbing gas: a computationally fast and accurate transmittance model for absorbing gases with constant mixing ratios in inhomogeneous atmospheresL M McMillin, H E Fleming
Applied Optics|November 12, 2010
Atmospheric transmittance of an absorbing gas. 5. Improvements to the OPTRAN approachL M McMillin, L J Crone, T J Kleespies
Applied Optics|March 10, 2010
Atmospheric transmittance of an absorbing gas. 3: A computationally fast and accurate transmittance model for absorbing gases with variable mixing ratiosL M McMillin, H E Fleming, M L Hill
Applied Optics|March 18, 2010
Accuracies of three computationally efficient algorithms for computing atmospheric transmittancesL M McMillin, H E Fleming, A Arking, et al.
Applied Optics|November 10, 2010
Atmospheric transmittance of an absorbing gas. 4. OPTRAN: a computationally fast and accurate transmittance model for absorbing gases with fixed and with variable mixing ratios at variable viewing anglesL M McMillin, L J Crone, M D Goldberg, et al.
Applied Optics|February 15, 2008
Forward calculation for interferometers: method and validationL M McMillin, M D Goldberg, H Ding, et al.
Pageof 1

Showing results (1-10 of 7) with videos related to

Sort By:
Pageof 1
Applied Optics|February 20, 2010
Atmospheric transmittance of an absorbing gas. 2: A computationally fast and accurate transmittance model for slant paths at different zenith anglesH E Fleming, L M McMillin
Applied Optics|February 19, 2010
Atmospheric transmittance of an absorbing gas: a computationally fast and accurate transmittance model for absorbing gases with constant mixing ratios in inhomogeneous atmospheresL M McMillin, H E Fleming
Applied Optics|November 12, 2010
Atmospheric transmittance of an absorbing gas. 5. Improvements to the OPTRAN approachL M McMillin, L J Crone, T J Kleespies
Applied Optics|March 10, 2010
Atmospheric transmittance of an absorbing gas. 3: A computationally fast and accurate transmittance model for absorbing gases with variable mixing ratiosL M McMillin, H E Fleming, M L Hill
Applied Optics|March 18, 2010
Accuracies of three computationally efficient algorithms for computing atmospheric transmittancesL M McMillin, H E Fleming, A Arking, et al.
Applied Optics|November 10, 2010
Atmospheric transmittance of an absorbing gas. 4. OPTRAN: a computationally fast and accurate transmittance model for absorbing gases with fixed and with variable mixing ratios at variable viewing anglesL M McMillin, L J Crone, M D Goldberg, et al.
Applied Optics|February 15, 2008
Forward calculation for interferometers: method and validationL M McMillin, M D Goldberg, H Ding, et al.
Pageof 1