Development of Method for LST (Land Surface Temperature) Detection Using Big Data of Landsat TM Images and AWS Myung-Hee Jo¹, Sung Jae Kim², Jin-Ho Lee 3 ¹ Department of Aeronautical Satellite System Engineering, Kyungpook National University, Gajangdong Sangju, Gyeongsangbuk-do, Korea,mhjo@knu.ac.kr ² Institute of Spatial Information Technology Research, GEO C&I Co., Ltd, Daegu, Korea 3 School of Mechanical Engineering at Yonsei University, Seoul, Korea ABSTRACT Worldwide climate change phenomena and rapid industrialization caused serious environmental problem. One of the major implications of urbanization is the increase of surface temperature and development of Urban Heat Island. Surface temperature is increased by anthropogenic heat discharges due to energy consumption, increased land surface coverage by artificial materials having high heat capacities and conductivities, and the associated decrease in vegetation and water pervious surfaces which reduce the surface temperature through evapotranspiration. Landsat ETM images are widely used to observe and model the biophysical characteristics of the land surface. In addition to the development of Land use/cover maps band 6 of the landsat imagery is useful for deriving the surface temperature. In this paper we analyze the results of the LST estimation from landsat data and discuss the associates constraints and challenges. In this study, land surface temperature derived from landsat TM satellite imagery (145 scenes) and meteorological data observed at the Automatic Weather Observation (AWS) from 1984-2009 were used as input variables for the evaluation of LST in Seoul City, Korea. For the landsat images data and AWS date where link and pre-processing such as geometric correction was performed. AWS observed surface heat converted data correlated with temperature and atmospheric temperature and wind direction, humidity, sea level pressure, and multiple regression analysis obtained by setting the interval of highly variable surface temperature with landsat images correlation analysis was performed. For accurate indicator analysis NASA model was utilized to extract the surface heat. This research is to analyze and identify the correlation between the surface temperature and the linear equations obtain to calculate the correction factor to develop a model for LST in Korea. The results of this study will contribute to the strategies necessary for the sustainable management in urban revitalization planning in the future. Keyword: Land surface temperature, Landsat, Urban Heat Island, NASA Model INTRODUCTION Large scale changes in surface temperature partially due to urban development and population centralization are now increasing the air pollution substances by essentially causing landscape changes, increase of temperature, and wind field in the city. In addition, urban heat island effect of forming high temperature in the city causes social issues in the city development and public hygiene. Eventually a study dealing with urban heat analysis by utilizing GIS as well as satellite remote sensing has been actively conducted. Therefore, it is now feasible to perform characteristics of heat distribution via cutting-edge image and AWS data mining techniques. Data mining techniques were applied based on the heat ultraviolet rays temperature data on the surface and air temperature resources of large scaled AWS in the research area intending to clarify relation between air temperature and earth surface temperature, acquire accuracy of modification factor, and ultimately suggest the optimal environmental factors. MATERIALS AND METHODS Subject of Study and Data Seoul, a targeted research place, has a total area of 605.28 km² acquiring 30 AWSs. In addition, it is also available to extract information and apply data mining by using large scaled climate observing
data that have been accumulated for the multiple years in the past. In addition, Seoul is also an urbanized area that acquired extracted data of earth surface temperature for previously accumulated ultraviolet rays landsat images and urban heat island effect. This study utilized landsat TM images (145 scenes) that had been recorded for 26 years (1984~2009) in the area of Seoul with less than 30% of cloudy cover and precipitation, temperature, wind direction, wind speed, moisture, and air pressure observed in 30 AWSs in the area of Seoul for the 26 years (1984~2009) as input variables for the evaluation. RESULTS AND DISCUSSIONS Extracting Earth Surface Temperature by Using Satellite Ultraviolet Sensor First of all, entire-process procedures on the image are required in order to use satellite image data. Entire-process procedures are a phase prior to work analysis that removes radiation-related geometric and radioactive error and processes or converts into the form for making it feasible to process resource in the steps of acquiring resources. Landsat TM resources provide items corrected with basic radioactive errors correction and geometric error were used in this study. As for the first phase, a targeted research area was selected within 500m of radius of AWS observatory without sheath changes in the area of Seoul followed by implementation of GIS analysis in order to select a particular structure for site sheath in each AWS. Figure 1: Procedures of Selecting Structure for Representing Earth Surface in Each AWS As for the second phase, spectrum intensity of radiation was converted from the landsat TM band 6 preparing for earth surface temperature distribution by using NASA model. In addition, Julian calendar was used for applying NASA model intending to utilize corrective factor in an astronomical unit considering the distance between the earth and the sun.
Figure 2: Example of Earth Surface Heat Based on NASA Model As for the third phase, raster data earth surface temperature data were converted to numerical form in order to analyze an accurate interrelationship with AWS data. Up to one decimal was represented in a range of AWS data for efficient analysis by rounding up the second or later decimals of the value. Figure 3: Example of Data Conversion of Earth Surface Heat Development of AWS Data Mining Technique Analysis Data mining is a procedure of extracting new and meaningful information from large scaled resources to be utilized for decision-making process. In this study, the following AWS data mining procedures were implemented to acquire improved correction factor in the AWS observation resources and satellite observed data.
Figure 4: Data Mining of AWS Resources For the fourth phase, interrelated variables were analyzed via multiple regression analysis. Multiple regression analysis was used when there are two or more quantitative data with one qualitative data as an outcome variable leading to identify cause-and-effect relations of a variable with other variables to interrelations of previously observed earth surface temperature and other factors. Figure 5: Example of Interrelation of Temperature, Moisture, Precipitation, Wind Speed, and Pressure on the Earth Surface For the fifth phase, interval analyses were selected depending on the interrelated variables. Air temperature in the AWS observation location and earth surface might influence on the temperature value that specific intervals were selected for each air environment condition. In addition, intervals were divided into 3 sub-intervals on a consistent manner according to the frequency on the normal distribution curve.
Figure 6: Selection of Intervals for Analysis of Interrelated Variables Finally, corrective variables were calculated via correlation analysis. Corrective factors are required for preparing heat distribution via interrelation analysis between AWS observed resources and satellite ultraviolet rays sensor observed resources were calculated. Improved corrective factors are expected to provide and enhanced accuracy in the statistical perspective over corrective factors obtained in the short term period in the previous studies and also to be applied for establishing heat distribution chart in Seoul by area using KOMPSAT-3A in the future. Figure 7: Calculation of Corrective Factors via Correlation Analysis CONCLUSIONS This study is available to be incorporated to most studies dealing with preparation for precise earth surface temperature map, urban heat island effect, and heat energy distribution via improvement of earth surface heat environment analysis by utilizing corrective factors. In addition, it is anticipated to
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