in Figure 3(b), the increased posterior probability pertaining to 
the right type is still not predominant to exceed the decreased 
probability pertaining to the confusing types. However, the 
effect that the SK method helps to improve the predicted 
probability of the right land cover type is still traceable. 
In Figure 3(d) the SK method fails to further improve the 
originally prevailing posterior probabilities pertaining to the 
right type, but instead meets the exact reverse. It may come 
down to two reasons: (1) the input vectors are prone to 
confusion which results in the slight advantage in the posterior 
probability of the right type; (2) the training samples in a local 
domain are sparse and unevenly distributed which results in an 
unfaithful modelling of residual variation and a naive spatial 
interpolation. That is, the less accurate residual variogram 
models would easily reverse the slight advantage. However, 
samples of this kind in Figure 3(b) only occupy 1.1 percent of 
the total samples. On the contrary, samples of the kind in Figure 
3(a), which are poorly classified but correctly revised, occupy 
58 percent. 
Moreover, compared to the producer's and user's accuracy 
acquired by the SVM classification, as are listed in Table 2, the 
corresponding accuracy fluctuations after the application of the 
SK method may not equivalent to mean that the kriging method 
is particularly suitable to some certain land cover types. 
In order to further testify the efficiency of the kriging paradigm, 
another TM image including 17 land cover types is adopted. A 
total of ten variables were available: Landsat TM channels 1-5, 
7, modified normalized difference vegetation index (MNDVI), 
scaled elevation, slope in degrees, and a combined slope-aspect 
variable. Further detail of this data set is documented in Zhang 
and Goodchild (2007). The estimated Arif index manifests a 
corresponding highest classification accuracy of 72.2296. The 
overall accuracy and kappa coefficient achieved by generalized 
linear model (abbreviated to GLM) are 65.55% and 0.62, 
respectively. After residual corrections, the former is improved 
to 75.45% and the latter is increased to 0.73. It is interesting to 
notice that the revised accuracy of 75.45% is larger than the 
estimated potential highest accuracy of 72.22%. The is that the 
potential highest is just estimated by the input vectors without 
considering the introduced spatial information during the post- 
classification corrections. 
4. CONCLUSION 
The proposed two kriging methods are independent of the 
specific classifiers initially adopted for image classification. 
Hence, these methods may be treated as post-classification 
approaches. They aim at compensating part of the information 
consumed by classifiers due to the insufficient learning process. 
Moreover, these methods are independent of the land cover 
types, although the improvements vary in the producer’s and 
user’s accuracies of different land covers. The factors, including 
the sampling methods, sample sizes, and sample distributions, 
need to be further investigated, for they are close related to the 
spatial information of the training samples. 
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ACKNOWLEDGEMENT 
The research is partially supported by “973 Program” grants 
(No. 41071286) and (No. 41171346 ).