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http://dx.doi.org/10.7780/kjrs.2020.36.1.3

Detection of Wildfire-Damaged Areas Using Kompsat-3 Image: A Case of the 2019 Unbong Mountain Fire in Busan, South Korea  

Lee, Soo-Jin (Major of Spatial Information Engineering, Division of Earth Environmental System Science, Pukyong National University)
Lee, Yang-Won (Department of Spatial Information Engineering, Pukyong National University)
Publication Information
Korean Journal of Remote Sensing / v.36, no.1, 2020 , pp. 29-39 More about this Journal
Abstract
Forest fire is a critical disaster that causes massive destruction of forest ecosystem and economic loss. Hence, accurate estimation of the burned area is important for evaluation of the degree of damage and for preparing baseline data for recovery. Since most of the area size damaged by wildfires in Korea is less than 1 ha, it is necessary to use satellite or drone images with a resolution of less than 10m for detecting the damage area. This paper aims to detect wildfire-damaged area from a Kompsat-3 image using the indices such as NDVI (normalized difference vegetation index) and FBI (fire burn index) and to examine the classification characteristics according to the methods such as Otsu thresholding and ISODATA(iterative self-organizing data analysis technique). To mitigate the salt-and-pepper phenomenon of the pixel-based classification, a gaussian filter was applied to the images of NDVI and FBI. Otsu thresholding and ISODATA could distinguish the burned forest from normal forest appropriately, and the salt-and-pepper phenomenon at the boundaries of burned forest was reduced by the gaussian filter. The result from ISODATA with gaussian filter using NDVI was closest to the official record of damage area (56.9 ha) published by the Korea Forest Service. Unlike Otsu thresholding for binary classification,since the ISODATA categorizes the images into multiple classes such as(1)severely burned area, (2) moderately burned area, (3) mixture of burned and unburned areas, and (4) unburned area, the characteristics of the boundaries consisting of burned and normal forests can be better expressed. It is expected that our approach can be utilized for the high-resolution images obtained from other satellites and drones.
Keywords
Wildfire-damaged area; Kompsat-3; Otsu thresholding; ISODATA; Gaussian filter;
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Times Cited By KSCI : 2  (Citation Analysis)
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1 Axel, A. C., 2018. Burned area mapping of an escaped fire into tropical dry forest in western Madagascar using multi-season Landsat OLI data, Remote Sensing, 10(3): 371.   DOI
2 Bin, W., L. Ming, J. Dan, L. Suju, C. Qiang, W. Chao, Z. Yang, Y. Huan, and Z. Jun, 2019. A method of automatically extracting forest fire burned areas using Gf-1 remote sensing images, Proc. of 2019 IEEE International Geoscience and Remote Sensing Symposium, Yokohama, Jul. 28-Aug. 2, pp. 9953-9955.
3 Bonan, G. B., 2008. Forests and climate change: forcings, feedbacks, and the climate benefits of forests, Science, 320(5882): 1444-1449.   DOI
4 Davis, K. T., S. Z. Dobrowski, Z. A. Holden, P. E. Higuera, and J. T. Abatzoglou, 2019. Microclimatic buffering in forests of the future: the role of local water balance, Ecography, 42(1): 1-11.   DOI
5 Deng, G. and L. W. Cahill, 1993. An adaptive Gaussian filter for noise reduction and edge detection, Proc. of 1993 IEEE conference record nuclear science symposium and medical imaging conference, San Francisco, CA, Oct. 31-Nov. 6, pp. 1615-1619.
6 Dhodhi, M. K., J. A. Saghri, I. Ahmad, and R. Ul-Mustafa, 1999. D-ISODATA: A distributed algorithm for unsupervised classification of remotely sensed data on network of workstations, Journal of Parallel and Distributed Computing, 59(2): 280-301.   DOI
7 Escuin, S., R. Navarro, and P. Fernandez, 2008. Fire severity assessment by using NBR (Normalized Burn Ratio) and NDVI (Normalized Difference Vegetation Index) derived from LANDSAT TM/ETM images, International Journal of Remote Sensing, 29(4): 1053-1073.   DOI
8 Fawwaz, I., M. Zarlis, and R. F. Rahmat, 2018. The edge detection enhancement on satellite image using bilateral filter, IOP Conference Series: Materials Science and Engineering, 308: 1-9.
9 Iverson, L. R., R. L. Graham, and E. A. Cook, 1989. Applications of satellite remote sensing to forested ecosystems, Landscape Ecology, 3(2): 131-143.   DOI
10 Holmgren, P. and T. Thuresson, 1998. Satellite remote sensing for forestry planning-a review, Scandinavian Journal of Forest Research, 13(1-4): 90-110.   DOI
11 Korea Forest Service (KFS), 2009. Climate Change & Forest, KFS, Daejeon, Republic of Korea.
12 Korea Forest Service (KFS), 2017. Forest Fire Statistics Statistical Information Report, KFS, Daejeon, Republic of Korea.
13 Korea Forest Service (KFS), 2019. 2018 Statistical yearbook of forest fire, KFS, Daejeon, Republic of Korea.
14 Korea Joongang Daily, 2019. Unbong Mountain forest fire in Haeundae, Busan is suppressed over 90%, 20ha forest disappeared, https://news.joins.com/article/23430354, Accessed on Apr. 3, 2019.
15 Lasaponara, R. and B. Tucci, 2019. Identification of burned areas and severity using SAR sentinel-1, IEEE Geoscience and Remote Sensing Letters, 16(6): 917-921.   DOI
16 Lee, H., D. Seo, K. Ahn, and D. Jeong, 2013. Positioning accuracy analysis of KOMPSAT-3 satellite imagery by RPC adjustment, Journal of the Korean Society of Surveying, Geodesy, Photogrammetry and Cartography, 31(6-1): 503-509 (in Korean with English abstract).   DOI
17 Nayar, A., 2009. Carbon trading: How to save a forest, Nature, 462(7269): 26-29.   DOI
18 Lee, S.-J., K.-J. Kim, Y.-H. Kim, J.-W. Kim, and Y.-W. Lee, 2017. Development of FBI (Fire Burn Index) for Sentinel-2 images and an experiment for detection of burned areas in Korea, Journal of Photo Geography, 27(4): 187-202 (in Korean with English abstract).
19 Lee, S., S. K. Choi, S. Noh, N. Lim, and J. Choi, 2015. Automatic extraction of initial training data using national land cover map and unsupervised classification and updating land cover map, Journal of the Korean Society of Surveying, Geodesy, Photogrammetry and Cartography, 33(4): 267-275 (in Korean with English abstract).   DOI
20 Mahajan, U. and B. Raj, 2016. Drones for normalized difference vegetation index (NDVI), to estimate crop health for precision agriculture: A cheaper alternative for spatial satellite sensors, Proc. of International Conference on Innovative Research in Agriculture, Food Science, Forestry, Horticulture, Aquaculture, Animal Sciences, Biodiversity, Ecological Sciences and Climate Change (AFHABEC-2016), New Delhi, Oct. 22, pp. 38-41.
21 Otsu, N., 1979. A threshold selection method from gray-level histograms, IEEE Transactions on Systems, Man, and Cybernetics, 9(1): 62-66.   DOI
22 Park, S.-W., S.-J. Lee, C.-Y. Chung, S.-R. Chung, I. Shin, W.-C. Jung, H.-S. Mo, S.-I. Kim, and Y.-W. Lee, 2019. Satellite-based forest withering index for detection of fire burn area: its development and application to 2019 Kangwon wildfires, Korean Journal of Remote Sensing, 35(2): 343-346 (in Korean with English abstract).   DOI
23 Reszka, P. and A. Fuentes, 2015. The great Valparaiso fire and fire safety management in Chile, Fire Technology, 51(4): 753-758.   DOI
24 Yang, T. and Y.H. Qiu, 2015. Improvement and implementation for Canny edge detection algorithm, Proc. of 7th International Conference on Digital Image Processing (ICDIP 2015), Los Angeles, CA, Apr. 9-10, vol. 9631, p. 96310H.
25 Roldan Zamarron, A., S. Merino de Miguel, F. Gonzalez Alonso, S. Garcia Gigorro, and J. M. Cuevas, 2006. Minas de Riotinto (south Spain) forest fire: Burned area assessment and fire severity mapping using Landsat 5 TM, Envisat MERIS, and Terra MODIS postfire images, Journal of Geophysical Research: Biogeosciences, 111(G4).
26 Seddik, H., 2014. A new family of Gaussian filters with adaptive lobe location and smoothing strength for efficient image restoration, EURASIP Journal on Advances in Signal Processing, 25: 1-11.
27 Won, M., K. Kim, and S. Lee, 2014. Analysis of burn severity in large-fire area using SPOT5 images and field survey data, Korean Journal of Agricultural and Forest Meteorology, 16(2): 114-124 (in Korean with English abstract).   DOI