Accuracy and sensitivity analyses of SAIL model-predicted reflectance of maize

Bidirectional reflectance of six maize genotypes was measured on 16 dates in 1984 at the Nebraska Sandhills Laboratory using a modular multiband radiometer. On 10 of the dates, measurements were repeated during the day to obtain a range of solar zenith angles. Plants were sampled approximately weekl...

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Bibliographic Details
Published in:Remote sensing of environment 1992-07, Vol.41 (1), p.61-70
Main Authors: Major, D.J., Schaalje, G.B., Wiegand, C., Blad, B.L.
Format: Article
Language:English
Subjects:
Agronomy. Soil science and plant productions
ANALYSIS
Biological and medical sciences
CANOPY
COUVERT
CROPS
CUBIERTA DE COPAS
CULTIVOS
Earth sciences
Earth, ocean, space
ENERGIA SOLAR
ENERGIE SOLAIRE
ERRORS
Exact sciences and technology
FORECASTING
Fundamental and applied biological sciences. Psychology
Generalities. Biometrics, experimentation. Remote sensing
GENOTIPOS
GENOTYPE
GENOTYPES
INSTRUMENT METEOROLOGIQUE
INSTRUMENTOS METEOROLOGICOS
IRRIGATED CONDITIONS
LEAF AREA
LEAF AREA INDEX
MEASUREMENT
MEDICION
MESURE
METEOROLOGICAL INSTRUMENTS
MODELE
MODELOS
NEBRASKA
OPTICAL PROPERTIES
PLANTE DE CULTURE
PREDICTION
PROPIEDADES OPTICAS
PROPRIETE OPTIQUE
RADIOMETERS
REGIME HYDRIQUE DU SOL
REGIMEN HIDRICO DEL SUELO
Remote sensing
SCATTERING BY ARBITRARILY INCLINED LEAVES MODEL
SOIL WATER REGIMES
Soils
SOLAR ENERGY
SOLAR RADIATION
SOLAR ZENITH ANGLES
SUPERFICIE FOLIAR
SURFACE FOLIAIRE
Surficial geology
TECHNIQUE DE PREVISION
TECNICAS DE PREDICCION
ZEA MAYS
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Description
Summary:Bidirectional reflectance of six maize genotypes was measured on 16 dates in 1984 at the Nebraska Sandhills Laboratory using a modular multiband radiometer. On 10 of the dates, measurements were repeated during the day to obtain a range of solar zenith angles. Plants were sampled approximately weekly to determine leaf area index (LAI) and smoothed to provide LAI values for each of the 560 reflectance measurements. Reflectance in the red and near-infrared (NIR) was predicted by three versions of the SAIL model, a one-dimensional version, a two-dimensional version that took rows into account, and a modified two-dimensional version that accounted for shading caused by rows and crop height, and then evaluated using an accuracy analysis that considered bias, regression, and random errors. The results indicated that the 1-D SAIL model underestimated red and overestimated NIR reflectance at partial canopies because it did not account for exposed bare soil. The 2-D version, which accounted for ground cover, generally overcame this problem. The 2-D′ version, which accounted for shading of soil and canopy due to increasing canopy height, did not improve the results of the 2-D version enough to warrant the increased complexity. Sensitivity analyses, in which the main inputs required to fit the data were varied, revealed that the same leaf angle distribution and the same single leaf reflectance and transmittance values could be used for the whole season. Diurnal, multitemporal reflectance combined with the SAIL model adequately described the radiative transfer properties of the maize crop canopies studied.
ISSN:0034-4257
1879-0704
DOI:10.1016/0034-4257(92)90061-N