Laser Remote Sensing: Fundamentals and ApplicationsPresents a concise, self-contained monograph on laser remote sensing and its applications. Discusses the ways in which lasers can be used to remotely measure the atmosphere and the hydrosphere. Provides an historical perspective and reviews the basic physics needed. |
Contents
Introduction | 1 |
Electromagnetic Theory of Radiation | 11 |
Quantum Physics and Radiation Processes | 59 |
Copyright | |
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absorption optical aerosol aeroticulate altitude angle assume atmospheric atoms attenuation coefficient backscattering backscattering coefficient band chlorophyll cm² CO₂ concentration constituents corresponding cross section detection detector DIAL measurements DIAL system differential absorption differential-absorption dye laser electron emission evaluated excitation factor field of view filter frequency function H₂O infrared integration irradiance laser beam laser pulse laser radiation laser remote laser wavelength laser-induced fluorescence layer lidar equation lidar system linewidth medium Megie mode molecular molecules monitoring N₂ Nd-YAG laser nitrogen nitrogen laser number density observed operating optical depth output ozone parameter photocathode photomultiplier photon plume polarized pollution presented as Fig Q-switched quantum R₁ radiative radius Raman scattering Raman signal range ratio Rayleigh receiver optics remote sensing represents resonance retroreflector return signal rotational SO₂ sodium sodium layer species spectral spectrum stratosphere target plane technique telescope temperature transition tunable vibrational water Raman wavelength