Computer Science – Performance
Scientific paper
May 2005
adsabs.harvard.edu/cgi-bin/nph-data_query?bibcode=2005agusmsh11a..02b&link_type=abstract
American Geophysical Union, Spring Meeting 2005, abstract #SH11A-02
Computer Science
Performance
0800 Education
Scientific paper
Researchers at Clark Atlanta University have developed a second-generation LED sun photometer with significant improvements over the LED haze sensor distributed to high schools by NASA. We compared sun photometer results obtained in the Atlanta area with simultaneous observations that used a more expensive, handheld, 5-filter Microtops II Sunphotometer, manufactured by Solar Light Company, Inc. This device measures precipitable water (using a 940 nm filter with 10 nm bandwidth) and aerosol optical depth (using a 1020 nm filter with 10 nm bandwidth). It also measures ozone column depth using 3 filters for wavelengths in the Huggins ozone absorption band. Our most recent sun photometer results agreed within expected errors when comparing LED results at the 3 longest wavelengths (660, 860, and 940 nm) with the Microtops aerosol optical thicknesses. However, some problems were encountered with data obtained at the shortest wavelength (400 nm), and that issue needs to be resolved. We are evaluating the performance of our instrument using a series of computer calculations that address the finite bandwidth of the LED detectors. The Bouguer-Beer law assumes the light source is monochromatic. However, the LED bandwidth varies from 30-50 nm (widest at the longest wavelengths). We must determine whether this bandwidth is narrow enough to justify the use of a standard Langley plot. MODTRAN4 is used to obtain the transmissivity of light at relative high resolution through a variety of atmospheric conditions. By assuming realistic concentrations of water vapor, ozone and aerosol content, the wavelength-dependent overlap between radiation reaching the surface and the spectral response of the LEDs is computed to determine the magnitude of any deviations from Beer's law.
Blyler M. L.
Brown Daniel
Grams Gerald W.
Mandock R. L.
Tucker Dean
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