20 ÍSLENZKAR LANDBÚNAÐARRANNSÓKNIR radiance asymptote occurred at ~300 g/m2 total dry biomass. In addition, the red radiance asymptote was reached at much lower levels of total dry biomass than the IR, IR/red ratio, IR-red differ- ence, and VI asymptotes (Figures 3 and 4). The IR radiance aslo approached a radiance asymptote but this occurred at much higher amounts of total dry biomass than the red radiance asymptote (Figures 3b and 4b). The IR radiance asymptote occurred at ~600 + g/m2 total dry biomass. This is consistent with other work on asymptotic properties of spectral reflectance or radiance from grass canopies where the senior author has found that two to three times die arnount of biomass can be estimated in the photo- graphic infrared region (0.74 to 0.9 tim) than can in the red region (0.60 to 0.70 íim). The biological basis for the different asymptotic spectral responses is of use in explaining the results of the data analysis and will be reviewed briefly. The red and IR asymptotic spectral radiances in a grass canopy context are related to the penetration of incident light within ihe canopy. When the radiance in the red or IR has asymptoted, the addition of more vegetation per unit area effects no change in the canopy radiance because the incident light is incapable of addi- tional canopy penetration and escape to the measuring instrument. The red radiance asymptotes at much lower levels of total dry biomass than the IR radiance because of the absorption of red light by chlorophyll present in the green vegeta- tion. The greater the chlorophyll density, the lower the red radiance and hence the inverse relationship seen in Figures 3a and 4a. The situation in the near infrared re- gion is quite different, however. Little or no absorption occurs in this waveiength region, and because of the eff-ct of reilec- tance enhancement by the various ieaf layers, high levels of reflectance are possi- ble (Tucker 1977). The transparency of leaves in this wavelength region results in a gradual increase in radiance or reflec- tance as the biomass (multiple leaf layers) increases (Figures 3b and 4b). The red and IR radiances were meas- ured as radiances in /iW/cm-2 units. The radiance, in this case a spectral radiance, was the product of the spectral reflectance and the solar spectral irradiance. Because the spectral irradiance va"ies greatlv with clouds, timeofday, timeofyear, and other weather conditions, the spectral radiance can also vary greatly. To compensate for this possible (and frequent) variation, a ratio approach was used to normalize the red and IR radiances. This allows for the uncorrected use of these spectral meas- urements. (Note: An alternative would be to carry around a 20 X 20 cm reference panel lo adjust each reading to the refer- ence panel.) Transgenerated variables In an attempt to avoid a cumbersome and lime consuming calibration procedure, various transgenerationsofthe red and IR radiances were used. It has been found that the IR/red ratio, the IR-red dilfer- ence, and the vegetation index are some- what similar (Figures 3 and 4) and that these three transgenerated variables ef- fectiveiy normalize varying solar irradi- tional conditions under many cir- cumstances. (Figure 5).

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