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NTIS 바로가기한국농공학회논문집 = Journal of the Korean Society of Agricultural Engineers, v.63 no.5, 2021년, pp.95 - 105
우승범 (School of Social Safety and Systems Engineering, Hankyong National University) , 남원호 (School of Social Safety and Systems Engineering, Institute of Agricultural Environmental Science, National Agricultural Water Research Center, Hankyong National University) , 전민기 (Department of Convergence of Information and Communication Engineering, Hankyong National University) , 윤동현 (Department of Convergence of Information and Communication Engineering, Hankyong National University) , 김태곤 (Department of Smart Farm, Jeonbuk National University) , 성재훈 (Korea Rural Economic Institute) , 김한중 (School of Social Safety and Systems Engineering, Hankyong National University)
Drought is a disaster that causes prolonged and wide scale damage. Recently, the severity and frequency of drought occurrences, and drought damage have been increased significantly due to climate change. As a result, a quantitative study of drought factors is needed to better understand and prevent ...
Bae, D. H., J. M. So, and S. H. Kim, 2015. 2015 drought analysis and countermeasures. Korea Disaster Prevention Association 17(4): 14-22.
Bang, N. K., W. H. Nam, E. M. Hong, M. J. Hayes, and M. D. Svoboda, 2018. Assessment of the meteorological characteristics and statistical drought frequency for the extreme 2017 spring drought event across South Korea. Journal of the Korean Society of Agricultural Engineers 60(4): 37-48. doi:10.5389/KSAE.2018.60.4.037.
Burke, M., and K. Emerick, 2016. Adaptation to climate change: Evidence from US agriculture, American Economic Journal: Economic Policy 8(3): 106-140.
Dell, M., B. F. Jones, and B. A. Olken, 2014. What do we learn from the weather? The new climate-economy literature. Journal of Economic Literature 52(3): 740-798.
Edward, D. C., and T. B. Mckee, 1997. Characteristics of 20th century drought in the United States at multiple time scales. Department of Atmospheric Science, Atmospheric Science Paper No. 634, Climatology Report No. 97-2, Colorado State University.
Kang, J. K., S. K. Jung, S. J. Maeng, and C. D. Jang, 2015. Analysis for drought resilience of monoculture on climate change. Discussion of Crisis Management in Korea 11(1):63-81.
Korea Meteorological Administration (KMA) weather data service open MET data portal, Automated Synoptic Observing System (ASOS). https://data.kma.go.kr/. Accessed 4 Mar. 2021.
Korea Rural Community Corporation, Rural Agricultural Water Resource Information System (RAWRIS). https://rawris.ekr.or.kr/. Accessed 5 Mar. 2021.
Korea Rural Economic Institute (KREI), 2016. Measurement of agricultural damage due to drought. Korea Rural Economic Institute, Naju, South Korea.
Korean Statistical Information Service (KOSIS). https://kosis.kr/. Accessed 19 Jan. 2021.
Lee, H. J., W. H. Nam, D. H. Yoon, E. M. Hong, D. E. Kim, M. D. Svoboda, T. Tadesse, and B. D. Wardlow, 2019. Satellite-based evaporative stress index (ESI) as an indicator of agricultural drought in North Korea. Journal of the Korean Society of Agricultural Engineers 61(3):1-14. doi:10.5389/KSAE.2019.61.3.001.
Lee, H. J., W. H. Nam, D. H. Yoon, E. M. Hong, T. G. Kim, J. H. Park, and D. E. Kim, 2020. Percentile approach of drought severity classification in evaporative stress index for South Korea. Journal of the Korean Society of Agricultural Engineers 62(2): 63-73. doi:10.5389/KSAE.2020.62.2.063.
Mckee, T. B., M. J. Doesken, and J. Kleist, 1993. The relationship of drought frequency and duration to time scales. In Proceedings of the 8th Conference of Applied Climatology, 17-22 January, Anaheim, CA. American Meteorological Society, Boston, MA. 179-184.
Mun, Y. S., W. H. Nam, M. G. Jeon, H. J. Kim, K. Kang, J. C. Lee, T. H. Ha, and K. Y. Lee, 2020. Evaluation of regional drought vulnerability assessment based on agricultural water and reservoirs. Journal of the Korean Society of Agricultural Engineers 62(2): 97-109. doi:10.5389/KSAE.2020.62.2.97.
Myeong, S. J., 2018. Impact of climate change related natural disasters on rice production in South Korea. Journal of the Korean Society of Hazard Mitigation 18(7): 53-60. doi:10.9798/KOSHAM.2018.18.7.53.
Nam, W. H., M. J. Hayes, M. D. Svoboda, T. Tadesse, and D. A. Wilhite, 2015. Drought hazard assessment in the context of climate change for South Korea. Agricultural Water Management 160: 106-117. doi:10.1016/j.agwat.2015.06.029.
Nam, W. H., H. J. Kwon, and K. S. Choi, 2018. Reevaluation of design frequency of drought and water supply safety for agricultural reservoirs under changing climate and farming methods in paddy field. Journal of the Korean Society of Agricultural Engineers 60(1): 121-131. doi:10.5389/KSAE.2018.60.1.121.
Ryu, M. H., S. W. Jang, and D. H. Park, 2011. Climate change and drought: Study on shadow price and damage cost of water under drought. Journal of Wetlands Researh 13(2): 209-218.
Seo, S. S., D. G. Kim, K. H. Lee, H. S. Kim, and T. W. Kim, 2009. Estimation of drought damage based on agricultural and domestic water use. Journal of Wetlands Researh 11(2): 77-87.
Schlenker, W., and M. J. Roberts. 2009. Nonlinear temperature effects indicate severe damages to US crop yields under climate change, Proceedings of the National Academy of Sciences 106(37): 15594-15598.
Schlenker, W., W. M. Hanemann, and A. C. Fisher, 2005. Will U.S. agriculture really benefit from global warming? Accounting for irrigation in the hedonic approach, American Economic Review 95(1): 395-406.
Yoon, D. H., W. H. Nam, H. J. Lee, E. M. Hong, T. G. Kim, D. E. Kim, A. K. Shin, and M. D. Svoboda, 2018. Application of evaporative stress index (ESI) for satellite-based agricultural drought monitoring in South Korea. Journal of the Korean Society of Agricultural Engineers 60(6): 121-131. doi:10.5389/KSAE.2018.60.6.121.
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