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Elvidge, C. D., Keith, D. M., Tuttle, B. T., & Baugh, K. E. (2010). Spectral identification of lighting type and character. Sensors, 10, 3961–3988. Added by: Sarina (2021-04-09 08:43:21) Last edited by: Sarina (2024-02-16 15:18:21) |
Resource type: Journal Article DOI: 10.3390/s100403961 BibTeX citation key: Elvidge2010 View all bibliographic details |
Categories: Englisch = English Keywords: Halogenmetalldampflampe = Metal Halide Lamp, Kompaktleuchtstofflampe = Compact Fluorescent Lamp, Lampen = Lamps, Leuchtdiode = Light-emitting Diode, Leuchtstofflampe = Fluorescent Lamp Creators: Baugh, Elvidge, Keith, Tuttle Collection: Sensors |
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Meine Sichtweise (Keine vollständige Zusammenfassung des Artikels! Meine Meinung muss nicht mit der Meinung der Autoren übereinstimmen! Bitte lesen Sie auch die Originalarbeit!)
Lesenswert. Enthält Spektren zahlreicher Lampen, auch als Excel-Download von https://www.ngdc.noaa.gov/eog/night_sat/nightsat.html Added by: Sarina Last edited by: Sarina |
Abstract |
Abstract: We investigated the optimal spectral bands for the identification of lighting types and the estimation of four major indices used to measure the efficiency or character of lighting. To accomplish these objectives we collected high-resolution emission spectra (350 to 2,500 nm) for forty-three different lamps, encompassing nine of the major types of lamps used worldwide. The narrow band emission spectra were used to simulate radiances in eight spectral bands including the human eye photoreceptor bands (photopic, scotopic, and “meltopic”) plus five spectral bands in the visible and near-infrared modeled on bands flown on the Landsat Thematic Mapper (TM). The high-resolution continuous spectra are superior to the broad band combinations for the identification of lighting type and are the standard for calculation of Luminous Efficacy of Radiation (LER), Correlated Color Temperature (CCT) and Color Rendering Index (CRI). Given the high cost that would be associated with building and flying a hyperspectral sensor with detection limits low enough to observe nighttime lights we conclude that it would be more feasible to fly an instrument with a limited number of broad spectral bands in the visible to near infrared. The best set of broad spectral bands among those tested is blue, green, red and NIR bands modeled on the band set flown on the Landsat Thematic Mapper. This set provides low errors on the identification of lighting types and reasonable estimates of LER and CCT when compared to the other broad band set tested. None of the broad band sets tested could make reasonable estimates of Luminous Efficacy (LE) or CRI. The photopic band proved useful for the estimation of LER. However, the three photoreceptor bands performed poorly in the identification of lighting types when compared to the bands modeled on the Landsat Thematic Mapper. Our conclusion is that it is feasible to identify lighting type and make reasonable estimates of LER and CCT using four or more spectral bands with minimal spectral overlap spanning the 0.4 to 1.0 um region. Keywords: lighting types; lighting efficiency; photopic band; nighttime lights; Nightsat; LED
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