Bu N
ss
.
(D
ble
ac-
oth
a
and display procedures. Rectification may be geometric, in which
the picture elements (pixels)are shifted in position; or radiometric,
in which nonlinearites in the response of detector elements are
compensated. Cosmetic procedures remove image defects or noise
such as banding or sync losses that often are found in Landsat
digital data and seen in radar or optical-mechanical scanner
imagery. Analysis procedures are designed to increase the amount
of information that may be extracted from the data by edge and
contrast enhancement, or normalizing and ratioing specific bands.
The availability of several kinds of remote sensor data in digital
form facilitates their combination into a single image. Harris and
Graham (1976) reported on the synergistical combination of radar
and Landsat imagery.
Automated Classification
The key element of digital classification techniques involves a man/
machine interaction, whereby the analyst/interpreter will "train" the
computer to recognize various combinations of numbers that represent
reflectances in each of several wavelength bands for the particular
cover types or features of interest. This training process usually
involves data obtained over a limited geographic area. After the
computer has been trained and the statistics defining the various
categories of interest have been defined, the computer proceeds to
classify the reflectance values for each resolution element in the
entire data set. The classification algorithms range from relatively
simplistic parallelopiped decision rules to highly camplex statis-
tical discriminant functions based on mean spectral signatures and
covariance between spectral channels for specific classes of information.
Two basic approaches have been developed for training the computer
system, as described by Hoffer (1972). The first approach is referred
to as the "supervised technique” and involves the use of a system of
X-Y coordinates to designate to the computer the location of known
earth surface features. This technique has been used effectively
for classifying and mapping agriculture areas. However, experience
has shown that a "clustering" technique is more useful for developing
training statistics in areas of natural cover types, such as involved
in forestry or geologic studies. In the clustering technique, an
entire block of data is designated to the computer and each of the
spectral vectors contained in this set of data is automatically examined
by the computer and the entire set of data is statistically divided
into a number of groups or clusters, each containing data points
having similar spectral vectors. The number of spectral groups to be
defined is designated by the analyst.
Forest cover maps, rangelands, agricultural soils, snow cover and other
water resource situations, and geologic features of interest have also
been successfully mapped using these techniques, as described by
Hoffer (1975).
-11-
