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With these maps as guides, the Landsat image was displayed on a color video
console and a cursor used to identify the image coordinates of the sample sites.
Twenty of the 25 sites could be reliably identified in the Landsat imagery. The
mean brightness counts for 3 by 3 pixel blocks at these locations were duly
recorded for bands 4, 5, and 6. Using calibration constants tabulated by
Robinove, et al., (1981), the mean brightness counts were converted to radiance
values (mW/cm2-sr).
Measurements of water clarity, by Secchi disc, were available for all 20 sites.
Chlorophyll a concentrations were obtained for 11 of these sites, and at 6 of
them, detailed measurements of conductivity, dissolved oxygen and nutrient
concentrations were made. Using the stepwise linear regression approach of
Draper and Smith (1966), equations were developed with water quality parameters
as dependent variables. Candidate independent variables were radiance values
for bands 4, 5, and 6, band-to-band radiance ratios and chromaticity ratios.
Useful equations were identified for Secchi depth, chlorophyll a concentration
and total phosphorus concentration. The equations are summarized in table 3.
Table 3. - Water quality predictor models based
on Landsat radiance values
Number of
Dependent variable Independent variable(s) r? S sites
In (Secchi depth) R4 0.93 0.05 -1.5m 20
In (chlorophyll a) R6, CR5 0.94. ..1.3.=-59 mg/m3 11
Total phosphorus R6/R4 0.89 8.7 mg/m3 6
R4, R6 are radiances in Landsat bands 4 and 6.
CR5 is the band 5 chromaticity ratio, that is, band 5 radiance divided by
the sum of band 4, 5, and 6 radiances.
Having developed the equations in table 3, water quality maps could be prepared
by applying them to digital images of the entire reservoir. Before this could
be done, however, the band 6 imagery had to be cleaned up to eliminate the
numerous bad data lines present, as shown in figure 3. This was accomplished by
using a linear equation in terms of bands 5 and 7 (r7 20.99, $7 2.1 counts)
to generate synthetic band 6 data. The synthetic data were inserted in the
original band 6 image to replace the bad data lines, the result presented in
figure 4. Once band 6 was cleaned up, cosmetically acceptable color-coded maps
of chlorophyll a and total phosphorus concentrations could be prepared. The
chlorophyll a model was not applied to areas where Secchi depth was less than
1 meter. These areas were reported to have very high suspended sediment concen-
trations. Such conditions retard algae growth by limiting light available for
photosynthesis. Were the regression model applied in these areas, the high
radiance values in band 6 would produce erroneously high estimates of chloro-
phyll a concentration.
ANALYSIS OF AIRBORNE SCANNER DATA
Airborne MSS (multispectral scanner) data was analyzed in much the same fashion
as the Landsat imagery. Water quality sampling sites were located on the video
display and mean brightness counts recorded for 5 by 5 pixel blocks. These mean
counts were converted to radiances by calibration constants supplied with the
digital imagery. Again, a stepwise linear regression procedure was employed to
identify predictor equations for water quality variables. These are summarized
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