Itstrukturelis 
egelung _ in 
Ökologische 
lultispektral- 
Mitteilungen 
1986, Graz. 
ung Band 1 
eitung von 
ungsbericht, 
Stuttgart. 
  
IN SITU BRDF MEASUREMENTS OF SELECTED SURFACE MATERIALS TO IMPROVE ANALYSIS OF 
REMOTELY SENSED MULTISPECTRAL IMAGERY 
Gerhard Meister, Rafael Wiemker, Johann Bienlein, Hartwig Spitzer 
Il. Institut für Experimentalphysik 
Universität Hamburg 
Germany 
Mail: G. Meister / KOGS, Vogt-Kölln-Str. 30, 22527 Hamburg, FRG 
WWW-Page: http://kogs25.informatik.uni-hamburg.de/projects/censis/remotesens.html 
E-mail: meister@kogs.informatik.uni-hamburg.de 
Commission VII, Working Group 1 
KEY WORDS: Radiometry, Multispectral, Infrared, Surface, Classification, Radiometric Measurement, BRDF Measurement, 
Spectralon BRDF 
ABSTRACT 
The spectral bidirectional reflectance distribution function (BRDF) of selected artificial surfaces (e. g. roof materials) was 
measured under natural illumination. Data were obtained with a spectrometer in the wavelength range 600 nm — 900 nm with 
a spectral resolution of 5 nm, using 61 spectral bands. The samples were placed on a goniometer, which allowed to set all 
the desired angles of incidence and reflection. A Spectralon panel (made by Labsphere Inc., Boulder, Colorado) was used as a 
reference target for determining the incoming irradiance. The BRDF of this Spectralon panel was measured in the laboratory. 
The BRDF of the Spectralon panel is not Lambertian, however it obeys Helmholtz's theorem of reciprocity. For the in situ 
measurements, an additional measurement was made for each combination of angles with the samples being shadowed, in order 
to determine the contribution of sky light. The samples could be fitted to a function which was developed by [Walthall, 1985] 
and modified by [Liang, 1994]. In this work, the function was extended by a specular peak, increasing the number of free 
parameters to 7. The diffuse part of the BRDF of the samples does not vary in a systematic way. The intensity of the specular 
peak grows with increasing zenith angles. 
KURZFASSUNG 
Dieser Beitrag beschàftigt sich mit der Messung der winkelabhàngigen, spektralen Reflexionsfunktion (BRDF) von einigen 
ausgewáhlten künstlichen Oberfláchen (z. B. Dachbedeckungen)bei natürlicher Beleuchtung. Als MeBgerát diente ein Spek- 
trometer, welches im Bereich 600 nm — 900 nm Messungen in 61 Kanälen mit einer spektralen Auflösung von 5 nm ermöglicht. 
Die Proben wurden auf einem GoniometermeBtisch plaziert, so daß alle gewünschten Ein- und Ausfallswinkel eingestellt wer- 
den konnten. Zur Bestimmung der einfallenden Strahlungsflußdichte diente ein Reflektanznormal (Spectralon, hergestellt duch 
Labsphere Inc., Boulder, Colorado) als Referenzfläche, dessen BRDF zuvor im Labor bestimmt wurde. Es ergibt sich, daß die 
BRDF des Spectralons nicht dem Lambertstrahler entspricht, wohl aber dem Helmholtzschen Reziprozitätstheorem genügt. 
Bei den Feldmessungen wurde zusätzlich für jede Winkelkombination eine Messung bei beschatteter Probe durchgeführt, um 
den Einfluß des Himmelslichts zu bestimmen. An die Proben konnte eine Funktion angepaßt werden, die von [Walthall, 1985] 
entwickelt, von [Liang, 1994] modifiziert und hier um einen Term zur Modellierung des gespiegelten Anteils erweitert wurde, 
so daß diese Funktion insgesamt 7 freie Parameter besitzt. Während die diffuse Komponente der BRDF der Proben keine Sys- 
tematik erkennen läßt, konnte bei der gespiegelten Komponente ein Anstieg der Intensität mit großen Zenitwinkeln festgestellt 
werden. 
1 INTRODUCTION parameters, and thus finally improving classification of re- 
"OD ; motely sensed multispectral imagery. 
The Bidirectional Reflectance Distribution Function (BRDF) 
as defined by [Nicodemus, 1970] describes the radiance emit- In the line of our research we are interested in the use of 
ted by a reflecting target into the sensor direction, depending ~~ Multispectral imagery of high spatial resolution for purposes 
on the incoming radiation, the angles of incidence and reflec- — of urban planning and treaty verification in the framework 
tion (0;, ®i, 0, ®,) (see fig.1) and wavelength A. of Open Skies. Most BRDF related efforts undertaken so far 
The kno v Mii have been directed at natural surfaces such as vegetation and 
nowledge of the BRDF of surface materials is certainly soils. In contrast to that we have chosen samples of artificial 
crucial for proper analysis and evaluation of remotely sensed materials found in urban areas and man made structures 
multispectral imagery. Spectral signatures change with view- such as tiles, bricks, asphalt, metall, roof materials etc., and 
in illuminati : . : : à uf 
í S ud Illumination geometry, and the BRDF is thus needed „m agsyred their reflective behavior under natural illumintion. 
or correct classification and change detection. 
However, so far most multispectral image processing and clas- 
sification is based on the simplifying assumption of Lamber- 2 EXPERIMENTAL SETUP 
tian reflection, and thus prone to error. One of the rea- 
sons for this may be that only relatively few BRDF data are — The measurements were done with the spectrometer OVID 
available, due to the tremendous effort necessary for its mea- (Optical Visible and Infrared Detector) in cooperation with 
surement. The work described here is aimed at measuring Max-Planck-Institut für Meteorologie, Hamburg, and Institut 
relevant BRDF data, finding proper BRDF models with few für Meteorologie, Universität Hamburg. A description of the 
493 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B7. Vienna 1996