ACKNOWLEDGEMENTS
The MARS project, coordinated by the Joint Research Centre (JCR) of Ispra, is acknowledged for supplying
SPOT data. We gratefully thank SOTEMA (SOciété de TElédétection en Matière Agricole) for prov iding
many information concerning the study site, and processing SPOT data. The authors also thank J. R. Porter for
providing the code of the AFRCWHEAT2 model, J. Goudriaan and B.A.M. Bourn an for EXTRAD model and
A Kuusk for Nilson-Kuusk model.
REFERENCES
Baret, F., 1986. Contribution au suivi radiométrique de cultures de céréales, Thèse de Doctorat, Université
Paris-Sud-Orsay, n° d'ordre : 98,182 p.
Baret, F., 1988. Un modèle simplifié de reflectance et d'absorptance d'un couvert végétal. Proceedings of the
4th International Colloquium on Spectral Signatures of Objects in Remote sensing, 18-22 January 1988,
Aussois, France, ESA SP-287.
Bouman, BAM, 1992. Growth models to simulate crop growth, optical reflectance and radar backscatter of
sugar beet and winter wheat, calibrated for Flevoland, Centre for Agrobiological Research, Report 163,
August 1992.
Delécolle, R., Maas, SJ., Guérif, M., and Baret, F„ 1992. Remote Sensing and Crop Production Models.
Present trends. ISPRS Journal of Photo grammetry and Remote Sensing 47:145-161.
Fischer, A., 1993. A model for the seasonal variations of vegetation indices in coarse resolution data and its
inversion to extract crop parameters. Remote Sens. Environ., forthcoming.
Goel, N.S., 1988. Models of vegetation canopy reflectance and their use in estimation of biophysical
parameters from reflectance data, Remote Sens. Rev. 4:1-212.
Goudriaan, J., 1977. Crop micrometeorology : a simulation study (PUDOC, Wageningen, The Netherlands),
pp/249.
Idso, B. and de Wit, C.T., 1970. Light relations in plant canopies, Appl. Opt., 9,177-184.
Monteith, JX., 1972. Solar radiation and productivity in tropical ecosystems, Journal of Applied Ecology,
9:744-766.
Moulin, S. and Fischer, A, 1993. Simulation of the temporal variations of NOAA/AVHRR reflectances.
Coupling of functional model and satellite data, in Proceedings 6th European AVHRR Data Users’
Meeting, 29th June - 2nd July 1993, Belgirate, Italy, EUM P 12:277-283.
Nilson, T„ and Kuusk, A., 1989. A reflectance model for homogeneous plant canopy and its inversion, Remote
Sens. Environ., 27:157-167.
Porter, J.R., Janison P.D. and Wilson DJI., 1992. A comparison of the wheat simulation models
AFRCWHEAT2, CERES-Wheat and SWHEAT for non-limiting conditions of crop growth. Field Crop
Res., forthcoming.
SCEES, 1985. Stades phénologiques des principales cultures et télédétection, SCEES, Méthodes et
Applications Scientifiques, n°12. Décembre 1985.
Seguin, B., Fischer, A, Kerdiles, H., Louhala, S., Podaire, A, 1991. Suivi agroclimatique des cultures en
France à partir des données NOAA METEOS AT et SPOT. Proceedings of the Conference on the
Application of Remote Sensing to Agricultural Statistics, 26-27 November 1991, Belgirate, Italy, pp
339-342.
Sharman, M. and Boissezon, H., 1992. Action IV, de l'image aux statistiques : Bilan opérationnel après deux
années d'estimations rapides des superficies et des rendements potentiels au niveau européen,
Proceedings of the Conference on the Application of Remote Sensing to Agricultural Statistics, 26-27
November 1991, Belgirate, Italy, pp 177-186.
Suits, G.H., 1972. The calculation of the directional reflectance of a vegetative canopy. Remote Sens.
Environ., 2,117-125.
Tucker, CJ., Fung, I.Y., Keeling, C.D. and R.H., Gammon, 1986. Relationships between atmospheric C02
variations and a satellite-derived vegetation index, Nature, 319:195-199.
Verhoef, W., 1984. Light scattering by leaf layers with application to canopy reflectance modeling : the SAIL
model. Remote Sens. Environ., 16, 125-141.
Weir, AH., Bragg, PX., Porter, J.R., and Rayner, J.H., 1984. A winter wheat crop simulation model without
water or nutrient limitations. J. Agri. Sci., Camb., 1984,102:371-382.
1134
