stress. 
51-70%, labeled Marginal (M), which warrants further 
investigation. 
71-100%, labeled High (H), and was considered a 
satisfactory development. 
The above categories were chosen for illustrative purposes 
only. The results are summarized in Table 1. 
Finally, the percentage of correctly classified pixels in 
each polygon together with the agreement code were entered 
into the database. 
In the polygon specific statistics generation method the 
image statistics were computed within every plantation 
polygon to be assessed, one-by-one. These statistics were 
then compared with those obtained from the training 
samples that matched the age class of the polygon being 
assessed. For example, the image statistics obtained within 
a polygon with attribute PL1-77 was compared to the 
training statistics obtained for the PL1-77 age class. 
Ranges were set in terms of the standard deviation (0) of the 
training samples for the agreements between the polygon 
and the training values for the mean, median, and mode 
statistical expressions, to judge the degree of compliance of 
the individual polygons with the normal development of the 
plantation. Table 2 shows the number of polygons whose 
image statistics agreed with the control value at the 30 
level. 
An additional testing mechanism devised was the ratio by 
which the 36 ranges of the training and the tested polygons 
overlapped. The count of the polygons that passed this test 
above the 0.6 ratio are also shown in Table 2, under the 
heading: Ratio. 
A comparison of Tables 1 and 2 indicates a good 
agreement of the results obtained by the image statistics 
based assessment at the 360 level, with the 70-100% class 
agreement in the per-pixel classification. The 36 
agreement level was, however, chosen for illustrative 
purposes only. 
4. CONCLUSIONS 
Polygon specific image analysis in a GIS is a powerful tool 
for monitoring changes and assessing prevailing land cover 
conditions. It has numerous advantages: 
The monitoring is performed within known geographic 
boundaries which are stored in the GIS and can be queried 
through the database management system. 
* This monitoring scheme provides for an immediate update 
of the database. 
* Problems caused by overlaps of spectral response patterns 
of the various themes, which often plague traditional 
image classification, are largely overcome. 
* In the per-pixel classification method, the parallelepiped 
classification performed on a few carefully selected bands 
can provide satisfactory results. This classifier is 
computationally the least demanding. 
* Satisfactory results can also be expected if image 
classification is bypassed entirely and change detection 
is based solely on comparing image statistics. 
Table 1 
NUMBER OF POLYGONS FALLING INTO EACH OF THE 
FOUR CATEGORIES OF AGREEMENT WITH APRIORI 
EXPECTATION IN THE MODIFIED PER-PIXEL 
CLASSIFICATION MONITORING METHOD. 
  
Polygon Total 
Code 0-30% 31-50% 51-70% 71-100% Polygon 
PL1-77 1 2 6 9 18 
PL1-78 1 1 6 22 30 
PL1-79 -- 1 -- 9 10 
PL1-81 3 2 11 22 38 
PL1-87 S -- 2 9 16 
PL1-90 1 -- 3 15 19 
PL1-93 1 1 4 -- 6 
PL2-77 -- -- 1 7 8 
PL2-78 -- -- -- 15 15 
PL2-79 -- 1 3 20 24 
PL2-80 5 2 -- 3 10 
PL2-81 -- -- 1 23 24 
PL2-92 2 -- 1 4 7 
Table 2 
NUMBER OF POLYGONS IN AGREEMENT WITH APRIORI 
EXPECTATION WITH 30 RANGE IN VARIOUS IMAGE 
STATISTICS COMPARISONS. 
Polygon Total 
M Rati i M Polygon 
PL1-77 9 9 13 16 18 
PL1-78 27 23 28 28 30 
PL1-79 9 7 9 9 10 
PL1-81 35 20 35 35 38 
PL1-87 12 10 11 11 16 
PL1-90 18 18 18 17 19 
PL1-93 5 1 5 4 6 
PL2-77 7 7 8 8 8 
PL2-78 15 13 15 :415 15 
PL2-79 24 17 24 22 24 
PL2-80 3 3 3 3 10 
PL2-81 24 22 24 23 24 
PL2-92 5 4 5 5 7 
The objective of this paper was to introduce and explain 
the concept of polygon specific image analysis as applied 
to monitoring changes. The example of monitoring the 
development of forest plantations was presented only to 
illustrate this concept, and the quality of the results should 
not be judged from a forest management point of view. The 
real success of this method depends on the decision rules set 
at the assessment stage. These rules must be formulated by 
discipline oriented experts, on a case-by-case basis through 
careful consideration of the specific project. Further testing 
and refinement of the ideas presented here are in progress. 
Polygon specific image analysis in a UGIS is an 
advantageous approach in a wide range of applications such 
as monitoring land use changes, updating forest 
inventories, agricultural crop classification on a yearly 
basis, monitoring compliances with environmental 
regulations, etc. 
214 
International Archives of Photogrammetry and Remote Sensing. Vol. XXXI, Part B4. Vienna 1996 
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