Estimation of the area of sealed soil using GIS technology and remote sensing

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From the SelectedWorks of Przemysław Kupidura 2010 Estimation of the area of sealed soil using GIS technology and remote sensing Stanisław Białousz Przemysław Kupidura Available at: https://works.bepress.com/przemyslaw_kupidura/14/

DATA Białousz S., Kupidura P., 2010. Estimation of the area of sealed soil using GIS technology and remote sensing. The Problems of Landscape Ecology, Vol. XXVIII. 253 259. Estimation of the area of sealed soil using GIS technology and remote sensing Stanisław Białousz 1, Przemysław Kupidura 2 Warsaw University of Technology, Department of Photogrammetry, Remote Sensing and GIS, Address: Pl. Politechniki 1, 00-661, Warsaw, Poland e-mail: 1 s.bialousz@gik.pw.edu.pl, 2 p.kupidura@gik.pw.edu.pl Abstract: Soil sealing can be defined as the destruction or covering of soil by buildings, constructions and artificial layers completely or partly impermeable (asphalt, concrete, etc.) It is the most intense form of land consumption and is essentially an irreversible process. Soil is sealed when agricultural or other biologically land is taken into the built environment. It is also a continuing process within existing urban areas, especially where urban population and the density of built structures is increasing and residual inner-city green zones are reduced. The paper concerns the methodology for an estimation of the area of sealed soil using GIS technology. Remote sensing data (aerial and satellite images) and cartographic data (city base maps, topographic maps) are used for that purpose. The proposed methodology is used for an estimation of sealed soil in two case studies: city of Warsaw and Lomianki municipality. First case study, city of Warsaw concerns the comparison of accuracy of different cartographic data (city base maps and topographic maps) as a data set for an estimation of sealed soil. Second case study, Lomianki municipality case study concerns a dynamic, multi-temporal approach. The multi-temporal set of aerial and satellite images is used for that purpose. The research results are changes of sealed soil in years 1977 2007. Key words: soil sealing, Geographic Information System, remote sensing Introduction Soil sealing may be defined as a destruction or covering of soil by buildings, constructions and artificial layers of material which may be very slowly permeable to water (e.g. asphalt, concrete, etc). According to the proposal for a Directive of European Parliament and of the Council establishing a framework for the protection of soil and amending Directive 2004/35/EC Art. 2, concluded in ENVASSO (Environmental Assessment of Soil for Monitoring) EU project (Six Framework Research Programme), soil sealing means the permanent covering of the soil with an impermeable material (Working Glossary..., 2007). It has been mentioned by one of ten threats to soil by the report of the ENVASSO project (others are: soil erosion, decline in soil organic matter, contamination, compaction, salinisation, decline in soil biodiversity, landslides, desertification) (Indicator and Criteria Report, 2007). Several different indicators for different aspects of the soil sealing threat have been developed with EN- VASSO project (Indicator and Criteria Report, 2007). This paper concerns a calculation of two indicators among them: 253

Białousz S., Kupidura P. sealed area the indicator quantifying an absolute area of sealed soil, land take the indicator quantifying how much, in what proportions and at what growth rate soil is lost by converting agricultural, forest, semi-natural and natural land to urban and other artificial land covers. The main problem is to measure or calculate an area of sealed soil within an area of interest. One of the proposition submitted during the works of the ENVASSO project was to use cadastral maps for a calculation of a percentage of built-up and non-built-up area. However, differences in cadastral data between European countries are significant and this solution cannot be applied in most of the EU countries. For example, in Germany there is an information about percentage of sealed soil area for different types of built-up area in cadastral maps, so the mentioned proposition may be applied directly there. In other countries (e.g. Poland), there is no such an information (figure 1), so cadastral data has restricted usefulness for sealed soil area evaluation. Fig. 1. Built-up area marked in the cadastral map on the left and real situation measured in the city map (sealed soil marked with grey) on the right This paper concerns the proposition of a methodology to evaluate an area of sealed soil and to calculate the values of proposed soil sealing indicators. They are based on the idea of sampling different built-up area classes are indentified in remote sensing data and the total area of sealed soil is calculated using the percentage of sealed soil in each class measured on topographic maps or on images. Two pilot areas: Warsaw city and Lomianki municipality have been used for a methodology testing. Two slightly different approaches have been applied for each one of them. Also different indicators have been calculated: Sealed Area for Warsaw city using a single Spot satellite image and Land Take for Lomianki municipality using multi-temporal set of aerial and satellite images. Methodology and results The process of sealed soil area estimation according to the proposed methodology includes following steps (Białousz et al., 2007): 254

Estimation of the area of sealed... 1. Determination of built-up area classes according to an intensity of terrain cover and by functions It should rely on a specific of the area of interest. 2. Measure of a percentage of sealed soil for mentioned classes using several representative examples might be completed using aerial or satellite images, management plans and base maps or topographic maps. 3. Identification of borders of zones of different built-up classes and measure of their areas preferably using satellite images. 4. Calculation of the area of sealed soil for different zones and then for total area. Warsaw city pilot area Seven different classes of built-up area according to an intensity of terrain cover and by functions have been extracted: very high intensity old cities, traditional bordering buildings (tenement-houses with annexes, with wells ), high intensity bordering buildings along streets and with green areas inside, high intensity industrial areas, medium density blocks scattered in green areas, medium density public domain, low density residential housing, very low density green areas. A percentage of sealed soil for each class have been determined using topographic maps (scale 1 : 10 000) and, independently, base city maps (scale 1 : 500). Several samples for different built-up area classes are presented in figures 2 5. The comparison of the results obtained using these different scale maps showed an insignificant differences between them. They are presented in the table 1. Table 1. The percentage of sealed soil in different built-up area classes according to the samples measured on the base city maps and topographic maps Class of built-up area Sealed area after city map [%] Sealed area after topographic map [%] Absolute difference [%] Very high density 96 97 1 Very high density (industrial zones) 91 98 7 High density (bordering buildings) 74 79 5 High density (public domain) 75 78 3 Medium density (blocks) 52 47 5 Low density 26 23 3 Very low density 20 20 0 255

Białousz S., Kupidura P. Legend buildings roads, paved foot-paths, squares non-sealed area Fig. 2. Very high density built-up area class. Sealed area extracted using a city map (left) and a topographic map (right) Legend buildings roads, paved foot-paths, squares non-sealed area Fig. 3. High density built-up area class (bordering buildings). Sealed area extracted using a city map (left) and a topographic map (right) Legend buildings roads, paved foot-paths, squares non-sealed area Fig. 4. Medium density built-up area class (blocks). Sealed area extracted using a city map (left) and a topographic map (right) 256

Estimation of the area of sealed... Legend buildings roads, paved foot-paths, squares non-sealed area Fig. 5. Very low density built-up area class. Sealed area extracted using a city map (left) and a topographic map (right) Using a percentage of sealed soil for each class, the borders of different zones in Warsaw have been determined as well as their areas, using Spot 5 image. The results of the calculation are presented in the figure 6 and in the table 2. Fig. 6. Built-up area zones in Warsaw extracted in Spot 5 satellite image 257

Białousz S., Kupidura P. Table 2. The area of different built-up zones measured on the satellite image Class of built-up area Area of the class [km 2 ] Total sealed area [km 2 ] Very high density 6.19 5.94 Very high density (industrial zones) 17.29 15.73 High density (bordering buildings) 29.23 21.63 High density (public domain) 2.86 2.15 Medium density (blocks) 80.23 41.72 Low density 63.13 16.61 Very low density 48.16 9.63 Summarizing, according to the presented methodology total sealed area in Warsaw is c.a. 113 km 2 what gives 43% out of 247 km 2 of built-up area and 22% out of total area of Warsaw (518 km 2 ). Lomianki municipality pilot area The same methodology has been applied in the second pilot area Lomianki municipality. There were two differences in the process: different classes of built-up area have been determined and the satellite image of very high resolution have been used for a determination of percentage of sealed soil in these built-up classes. Also, the use of multi-temporal set of images allowed to calculate Land Take indicator. The following built-up area classes have been determined: residential, industrial and commercial, public domain, recreational. As mentioned above, a percentage of sealed area in these classes have been determined in a satellite Quickbird image. Table 3 presents a percentage measured for the samples of the determined built-up area classes. Table 3. The percentage of sealed soil in different built-up classes according to the samples measured on the satellite image Class of built-up area Sealed area after satellite image [%] Residential 35 Industrial and commercial 93 Public domain 64 Recreational 9 The measurement of the area of different classes has been made using remote sensing data. Four aerial and satellite images of different dates of acquisition have been used: aerial photo from 1977, aerial photo from 1987, aerial photo from 1997, satellite Quickbird image from 2007. 258

Estimation of the area of sealed... This image set allowed to collect data on land cover in Lomianki in different dates, to calculate the area of sealed soil and, finally, to calculate Land Take indicator. Table 4 presents the results of the measure and calculations. Table 4. Total area of sealed soil and calculated Land Take indicator Year Residential zone area [ha] Industrial and commercial zone area [ha] Public domain zone area [ha] Recreational zone area [ha] Total area of sealed soil [ha] Land Take [ha/10y] 1977 369.4 65.2 7.0 0.0 194.4 1987 448.5 89.5 8.7 34.8 248.9 54.5 1997 502.1 102.5 9.6 34.8 280.3 31.4 2007 783.7 159.6 15.5 35.3 435.8 155.5 Total area of Lomianki municipality is 38.06 km 2 (3806 ha), so 784 ha of sealed soil in 2007 is c.a. 21% out of total area of the whole municipality. It can be clearly seen, that 241 ha 6% of total area, have been sealed since 1977 and 177 ha 4% since 1997. The soil sealing process becomes more and more intensive. Conclusions The proposed methodology is a compromise between an accuracy of the measurement of an area of sealed soil and an efficiency of this process. Using the sampling approach it is possible to estimate the values of soil sealing indicators fast and with relatively high precision. This methodology is also universal, it may be used regardless to the differences in cadastral data in different countries. References Indicators and Criteria Report, 2007. ENVASSO project report. Working Glossary of Key Terms For a European Soil Monitoring System, 2007. ENVASSO Work Package 4, ENVASSO project report. Białousz S., Kupidura P., Neite H., Dobos A., Kozak J., Penizek V., Heilman H. 2007. ENVASSO, Threat Report Soil Sealing, ENVASSO project report. 259

260 Białousz S., Kupidura P.

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