The Development of Land Use
Classification Method Combining Remote Sensing Data with Geographical
Data Tim R Mc Vicar, David LB
Jupp, Joe Walker CSIRO Division of Water Resources, Canberra, Australia Ryoichi Kojiroi, Masanori Koide, Tokio Mizuno Yasushi Shimoyama, Tsutomu Otsuka Photogrammetric Research and Development Office Geographical Survey Institute Kitasato – 1, Tsukuba – shi, Ibaraki – Pref., Japan Abstract In the study of on land use survey in the tropics, we had developed the image registration method using multi-season and multi-sensor Remote Sensing data in order to survey land use accurately, and gotten satisfactory results. However, we were not satisfied with the results of the land use classification. To exclude such misclassifications, we have developed the land use classification method combining Remote Sensing data with geographical data. The process of the classification method is as follows.
Introduction The geographical survey institute (GSI) has studied the land use classification method using multi-season and multi-sensor Remote Sensing data in the tropical area. In the 11th Asian Conference on Remote Sensing, we made a report on the image that brought us good results. However, there were many unacceptable misclassifications, when we classified the whole test site. For example, the shaded areas of forest in the mountain area were classified to the category of the mangrove forest. The shallow marine areas were often classified to the category of the city. This reason is that Remote Sensing data is not the land use information itself, but the spectral characteristics of matter on the ground. So far as we use Remote Sensing data only, we can not detect the difference among the matter which have the similar spectral characteristics. As a solution for this problem, there is a classification method combining Remote Sensing data with other data, especially geographical information. Because the geographical information including the topographical and geological data is support to be very effective for the land use classification, we have developed the classification method using the geographical information. In this paper, we describe the classification method combining Remote Sensing data with geographical information which was developed for accurate landuse survey. The land use classification method combining Remote Sensing data with geographical information Point of view Until now, the classification method using geographical data in GSI was that after the classification using Remote Sensing data, the result was reclassified, referring to geographical data. However, there was a weak point in the classification method. After the classification, if land use of some areas was not in accord with the geographical data those areas were looked upon as misclassified areas; therefore the criteria of renewal depended on the using geographical data only. After all, we did not get the final result in which Remote Sensing data was made the best use of. In this study, we have developed the new classification method to improve such a situation. In the new method, in order to make the best use of Remote Sensing and geographical data, the likelihood calculated from Remote Sensing data is combined with the occurrence probability of each category under each geographical condition such as elevation, inclination, soil and so on. Each occurrence probability is set up through human’s experience, knowledge, and so on. Process of classification The process of the classification is shown as follows :
Table 2 :The reference table of inclination and landuse categories
Maximum likelihood method In this study, the classification method is the maximum likelihood method, which assume the normal distribution of the multi-band data. The probability that the observation value of X belong to the category i, is as follows: ĺi : Variance and covariance matrix of category i Mi : mean value of category i n : number of bands The man, variance and covariance matrix is calculated from the training samples. The Pi for every category in a pixel s calculated, a pixel is classified to the category of which the Pi is maximum. In the maximum likelihood method, every pixel is classified to a category in the same way. We can omit the invariable part in formula 1 Combining method In this study, we adopt the product as the combining method. The occurrence probability combining the result of the maximum likelihood method and the reference table is calculated by formula 3 Ai : Occurrence probability BL,ij : possibility of land use i in category j of geographical Information L The pixel is classifed to the category of which Ai is maximum Case Study Study area The study area for the new method is Phuket Island which is located in the southern region of Thailand (figure 1). The topography of the area is the mountain range, covering by tropical rain forest and associated with granitic and limestone outcrops with a few flat landscapes. Existing land use are mainly para rubber plantation and tin mining. Used data
Conclusion We verified the new classification method improved the accuracy of the land use classification in the tropical area. Moreover, the distribution pattern of the land use by this method becomes quite similar to the real pattern. We are anticipating that the result of the land use classification will be more accurate, if we can use various geographical information much more. Acknowledgements We wish to express our greatest gratitude to the researchers of the National Research Council of Thailand (NRCT) and Land Development Department (LDD) for their grate cooperation in this study through the joint project. Also, we would like to give our special thanks to the Science and Technology Agency, not only for affording us a large amount of budget, but also for assisting our joint project from all sides. Reference Shimoyama, Y., Kamiya, I., Koide, M., Mizuno, T. (1990) The study on land use survey in the tropics using multi-season and multi-sensor Remote Sensing Data, Proceedings of 11th ACRS Vol. II Note :
Figure 2-a Land use map using mulit-season and multi-sensor data Figure 2-a Land use map using mulit-season and multi-sensor data Table 3 The error table of classification (using no geographical data)
|