Table 4. Bandwidth in microns and minimum and maximum
radiance values (spectral radiance for TM) for
calibration of Landsat data processed by EROS Data
Center (Landsat 4 & 5, Esrange and Fucino also).
BANDWIDTH Rmin Rmax
Landsat
1
MSS 4
0.5 - 0.6
0
2.48
MSS 5
0.6 - 0.7
0
2.00
MSS 6
0.7 - 0.8
0
1.76
MSS 7
0.8 - 1.1
0
4.00
Landsat
2
(22 January 1975 - 16
July 1975)
MSS 4
0.5 - 0.6
0.10
2.10
MSS 5
0.6 - 0.7
0.07
1.56
MSS 6
0.7 - 0.8
0.07
1.40
MSS 7
0.8 - 1.1
0.14
4.15
Landsat
2
(after 16 July
1975)
MSS 4
0.5 - 0.6
0.08
2.63
MSS 5
0.6 - 0.7
0.06
1.76
MSS 6
0.7 - 0.8
0.06
1.52
MSS 7
0.8 - 1.1
0.11
3.91
Landsat
2
(5 March 1978
- 3_1 May
1978)
MSS 4
0.5 - 0.6
0.04
2.20
MSS 5
0.6 - 0.7
0.03
1.75
MSS 6
0.7 - 0.8
0.03
1.45
MSS 7
0.8 - 1.1
0.03
4.41
Landsat
3
(after 31 May
1978)
MSS 4
0.5 - 0.6
0.04
2.59
MSS 5
0.6 - 0.7
0.03
1.79
MSS 6
0.7 - 0.8
0.03
1.49
MSS 7
0.8 - 1.1
0.03
3.83
Landsat
4
& 1
MSS 4
0.5 - 0.6
0.04
2.38
MSS 5
0.6 - 0.7
0.04
1.64
MSS 6
0.7 - 0.8
0.05
1.42
MSS 7
0.8 - 1.1
0.12
3.49
Landsat
4
& 5 TM (expressed as s
pectral rad:
TM 1
0.45 - 0.52
-0.15
15.21
TM 2
0.52 - 0.60
-0.28
29.68
TM 3
0.63 - 0.69
-0.12
20.43
TM 4
0.76 - 0.90
-0.15
10.62
TM 5
1.55 - 1.75
-0.04
2.72
TM 7
2.09 - 2.38
-0.02
1.44
exist, e.g. nearest neighbour, bilinear interpolation
and cubic convolution. The most important to achieve
with resampling is that every pixel really fit into
the new image or the map. Resampling by cubic convo
lution yields geometrical precision that is superior
to the other algorithms. When resampling a multi
date set of images to a map it is important to do the
things in correct order. If the map is considered to
be poor in geometrical precision, it is important to
carry out the resampling with a minimum of changes of
the internal geometry of the image. The following
procedure is to recommend:
1) Resampling image to image of the multidate image
set. In order to optimize the geometrical
precision, a large number of ground control
points, evenly distributed, and if necessary, in
combination with a high order polynomial trans
formation should be used.
2) Resampling of the multidate set to a map projec
tion. If the map is considered to have poor geo
metrical accuracy, a low order polynomial trans
formation should be used. The image is then
adjusted to the control points, with a minimum of
change of the internal geometry of the image. It
is important to have the ground control points
evenly distributed, and not to resample outside
the points. If using a high order polynomial
transform we will get a false impression of
accuracy, since the residuals at each point may be
rather low. If the map is accurate, a high order
polynomial transform may be be applied.
Resampling of thematic information e.g. classified
images or digitized maps, can not be resampled by
cubic convolution, since the algorithm involves an
interpolation procedure, but require the nearest
neighbour algorithm.
The introduction of high resolution data recorded at
considerable off-nadir view angles, like the SPOT,
necessitates development of new procedures for
geometrical correction than conventional resampling.
A better satellite/sensor viewing geometry descrip
tion will be available in the future and opens new
possibilities for geometrical correction based on
satellite orbital and sensor characteristics (Moccia
& Vetrella 1986).
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NOTE: Landsat MSS-bands are referred to as MSS 4, 5,
6 and 7, instead of Band 1-4.
means that data from some stations can not be
regarded as useful for multitemporal analysis where
radiometric calibration is necessary.
A severe limitation to proper radiometric
correction is atmospheric contamination of the image,
e.g. the presence of haze. A common procedure for
removal of the influence from haze is to assume that
the longest wavelength band (e.g. MSS7) is unaffected
by skylight or haze. A pixel that is supposed to
represent zero DGL (complete shadow or clean water)
is identified. Any offset of this pixel value is then
assumed to represent atmospheric noise, and can be
subtracted from all other bands. This procedure is,
however, only valid under the two assumptions, that
the atmospheric contribution is entirely additive
and wavelength independent.
4.2 Geometric correction
All multidate analyses of imagery require accurate
geometrical correction, carried out by resampling.
The resampling is done either as image to image or
image to map. Several algorithms for resampling
The large quantities of data in modern remotely
sensed images have highlighted the need for data
reduction methods. One of the most commonly applied
ones is the principal components analysis (PCA), or
Karhunen-Loeve transformation. The aim of PCA in
remote sensing is to remove redundancy in the multi-
spectral image. It has been shown in many studies
that the individual wavelength bands are highly
correlated to each other. The reasons to this high
correlation are (Schowengerdt 1983):
1) natural spectral correlation
2) topographic influence
3) overlap in spectral sensitivity of sensors
The first principal component will contain the
largest possible amount of the total variance in the
multidimensional data set. The second component will
contain the largest possible amount of the remaining
variance, and so on. Typical values of variance
content of Landsat MSS data are 90 % in the first
component and 5 % in the second one (Olsson 1985).
This technique may be a valuable instrument in e.g.
multispectral classification of rnultidate data sets.
The dimesionality can often be reduced by 50 % per
multispectral image. There is, however, a risk that
useful information get lost in the transformation.
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