2.3 Method
The research involved two main steps. In the first step, a broad classification of the general land cover, including
mangroves was made (Figure1). This indicated the best approach to dealing with the various types of imagery in
order to detect the mangrove deforestation. The second step concentrated on the specific problem of detecting
changes in the mangrove areas (Figure2). It examined different approaches for monitoring the nature of the changes
in order to produce maps showing the current and former conditions in the study area.
Figure 1. Method
3. Results and Discussions
The classes identified on each image using supervised classification are summarized in Table 2..
Table 2 Classes detected in each image through supervised classification and visual interpretation
| Landsat MSS |
SPOT |
Landsat TM |
ERS-1 |
JERS-1 |
Radarsat |
Broad-leaved
Nypa
Water
Ponds
-
-
agriculture
-
-
-
- |
Broad-leaved
nypa
water
dry pond
orchard
mixed
agriculture
-
-
-
- |
broad-leaved
nypa
water
fish pond
orchard
mixed
agriculture
clear-cut
half-cut
swampy
- |
-
nypa
water
fish pond
-
mixed
-
clear cut
-
-
oil pipeline |
-
nypa
water
fish pond
-
mixed
-
clear-cut
half-cut
-
oil pipeline |
-
nypa
water
fish pond
-
mixed
-
clear-cut
half-cut
oil pipeline
|
Figure 2. Mangrove forest area change detection procedure
Three types of mangrove deforestation were found to occur in the study area:
- deforestation caused by the establishment of agriculture and/or orchards;
- deforestation caused by the establishment of oil pipeline networks;
- deforestation caused by the establishment of shrimp ponds.
Deforestation resulting from the establishment of agriculture crops or orchards can be detected on the Landsat TM
image of 1994 and on the SPOT_XS of 1987. Radar data (JERS-1, ERS-1 and Radarsat) cannot, however, detect
this type of deforestation. Mangrove deforestation caused by the establishment of oil pipeline networks cannot be
detected on any of the optical images. This is because the width of the oil pipelines is around 15m and because water
and swampy vegetation surround them. The spectral and spatial resolutions therefore prevent them from being
imaged on optical images. However, pipelines are visible on all the radar images because they behave as corner
reflectors as a vertically standing object on the ground. Mangrove deforestation caused by establishment of shrimp
ponds can be detected on all optical and radar images, although ponds under construction, in which only about half
of Nypa palm have been cut, can be detected only on the Landsat TM, JERS-1 and Radarsat images. ERS-1 image
was not able to detect the process of deforestation in Nypah palm because of its short wavelength, small incidence
angle and it is VV polarization. However, JERS-1 radar image is collected with longer wavelength, HH polarization
and medium incidence angle. While Radarsat image is collected using the same short wavelength of ERS-1, but with
HH polarization and a medium incidence angle. It is believed that incidence angle (e.g., in this case) played an
important role to detect the process of deforestation in the Nypah palm. As Table 2 shows that SPOT_XS image was
not able to detect this process of deforestation in the Nypah palm because this image does not cover any areas with
this deforestation process from Nypah palm to fish ponds.
The accuracy of each classification was assessed by comparison with data collected at sample points on the ground
and compiling error matrices. Based on data collected at sample sites in the field, the classification accuracy of each
image to detect deforested mangrove area was as follows:
| Landsat MSS |
1982 |
5 classes |
76% |
| SPOT_XS |
1987 |
7 classes |
89% |
| Landsat TM |
1994 |
9 classes |
88% |
| ERS |
1996 |
6 classes |
83% |
| JERS |
1996 |
7 classes |
85% |
| Radarsat |
1997 |
7 classes |
84%v
|
