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Journal of Integrative Environmental Sciences Volume 16, 2019 - Issue 1
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Special Issue: Modelling Water Science for Impact

Evaluation of satellite-based products for extreme rainfall estimations in the eastern coastal areas of China

Qin JiangSchool of Environmental and Geographical Sciences, Shanghai Normal University, Shanghai, China;Key Laboratory of Geographic Information Science (Ministry of Education), East China Normal University, Shanghai, ChinaORCID Iconhttps://orcid.org/0000-0001-6401-9067View further author information
ORCID Icon,
Weiyue LiSchool of Environmental and Geographical Sciences, Shanghai Normal University, Shanghai, China;Institute of Urban Studies, Shanghai Normal University, Shanghai, China;Northwest Institute of Eco-Environment and Resources, Chinese Academy of Sciences, Lanzhou, ChinaCorrespondence[email protected]
ORCID Iconhttps://orcid.org/0000-0002-3928-3998View further author information
ORCID Icon,
Jiahong WenSchool of Environmental and Geographical Sciences, Shanghai Normal University, Shanghai, ChinaView further author information
,
Zedong FanSchool of Environmental and Geographical Sciences, Shanghai Normal University, Shanghai, ChinaView further author information
,
Yunnan ChenDepartment of Geodesy and Geoinformation, Research Division Cartography, TU Vienna, Wien, Austria;Department of Civil, Geo and Environmental Engineering, Technical University of Munich, Munich, GermanyView further author information
,
Marco ScaioniDepartment of Architecture, Built Environment and Construction Engineering, Politecnico di Milano, Milan, ItalyORCID Iconhttps://orcid.org/0000-0003-4058-6176View further author information
ORCID Icon &
Jun WangKey Laboratory of Geographic Information Science (Ministry of Education), East China Normal University, Shanghai, ChinaView further author information
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Pages 191-207 | Received 31 Mar 2019, Accepted 13 Dec 2019, Published online: 29 Dec 2019

References

  • Agarwal A, Babel MS, Maskey S. 2014. Analysis of future precipitation in the Koshi river basin, Nepal. J Hydrol. 513:422–434.
  • Aghakouchak A, Behrangi A, Sorooshian S, Hsu K, Amitai E. 2011. Evaluation of satellite-retrieved extreme precipitation rates across the central United States. J Geophys Res Atmos. 116(D2):D02115.
  • Almazroui M, Islam MN, Jones PD, Athar H, Rahman MA. 2012. Recent climate change in the Arabian Peninsula: seasonal rainfall and temperature climatology of Saudi Arabia for 1979–2009. Atmos Res. 111(32):29–45.
  • Anjum MN, Ding YJ, Shangguan DH, Ijaz MW, Zhang SQ. 2016. Evaluation of high-resolution satellite-based real-time and post-real-time precipitation estimates during 2010 extreme flood event in Swat River Basin, Hindukush Region. Adv Meteorol. 2016:1–8.
  • Ashouri H, Hsu KL, Sorooshian S, Braithwaite DK, Knapp KR, Cecil LD, Nelson BR, Prat OP. 2014. PERSIANN-CDR: daily precipitation climate data record from multisatellite observations for hydrological and climate studies. Bull Am Meteorol Soc. 96(1):197–210.
  • Casse C, Gosset M, Peugeot C, Pedinotti V, Boone A, Tanimoun BA, Decharme B. 2015. Potential of satellite rainfall products to predict Niger River flood events in Niamey. Atmos Res. 163:162–176.
  • Chen XH, Liu BJ, Chen G. 2017. Effects of urbanization on precipitation characteristics. J Nat Resour. 32(9):1591–1601. in Chinese.
  • Dembélé M, Zwart SJ. 2016. Evaluation and comparison of satellite-based rainfall products in Burkina Faso, West Africa AU-Dembélé, Moctar. Int J Remote Sens. 37(17):3995–4014.
  • Gebregiorgis AS, Hossain F. 2013. Understanding the Dependence of Satellite Rainfall Uncertainty on Topography and Climate for Hydrologic Model Simulation. IEEE Trans Geosci Remote Sens. 51(1):704–718.
  • Guo H, Chen S, Bao AM, Behrangi A, Hong Y, Ndayisaba F, Hu JJ, Stepanian PM. 2016. Early assessment of Integrated Multi-satellite Retrievals for Global Precipitation Measurement over China. Atmos Res. 176-177:121–133.
  • Han LF, Xu YP, Pan GB, Deng XJ, Hu CS, Xu HL, Shi HY. 2015. Changing properties of precipitation extremes in the urban areas, Yangtze River Delta, China, during 1957–2013. Nat Hazard. 79(1):437–454.
  • Han WS, Burian SJ, Shepherd JM. 2011. Assessment of satellite-based rainfall estimates in urban areas in different geographic and climatic regions. Nat Hazard. 56(3):733–747.
  • Hermance JF, Sulieman HM. 2018. Adequacy of the daily TMPA 3B42 high-resolution satellite precipitation product for monitoring hydrometeorological hazards in the Southeast Sahel of Africa. Int J Remote Sens. 39(8):2579–2596.
  • Hong Y, Adler RF, Negri A, Huffman GJ. 2007. Flood and landslide applications of near real-time satellite rainfall products. Nat Hazard. 43(2):285–294.
  • Huang XRZ, Wang DS, Liu Y, Feng ZZ, Wang DG. 2018. Evaluation of extreme precipitation based on satellite retrievals over China. Front Earth Sci. 12(4):846–861.
  • Huang Y, Chen S, Cao Q, Hong Y, Wu BW, Huang MY, Qiao L, Zhang ZX, Li Z, Li WY, et al. 2014. Evaluation of Version-7 TRMM Multi-Satellite Precipitation Analysis Product during the Beijing Extreme Heavy Rainfall Event of 21 July 2012. Water. 6(1):32–44.
  • Huffman GJ, Adler RF, Arkin P, Chang A, Ferraro R, Gruber A, Janowiak J, McNab A, Rudolf B, Schneider U. 1997. The Global Precipitation Climatology Project (GPCP) combined precipitation dataset. Bull Am Meteorol Soc. 78(1):5–20.
  • Jamandre CA, Narisma GT. 2013. Spatio-temporal validation of satellite-based rainfall estimates in the Philippines. Atmos Res. 122(3):599–608.
  • Janowiak JE, Kousky VE, Joyce RJ. 2005. Diurnal cycle of precipitation determined from the CMORPH high spatial and temporal resolution global precipitation analyses. J Geophys Res Atmos. 110(D23):D23105.
  • Jenkins GS, Adamou G, Fongang S. 2002. The challenges of modeling climate variability and change in West Africa. Climate Change. 52(3):263–286.
  • Jiang Q, Li WY, Wen JH, Qiu C, Sun WW, Fang QL, Xu M, Tan JG. 2018. Accuracy evaluation of two high-resolution satellite-based rainfall products: TRMM 3B42V7 and CMORPH in Shanghai. Water. 10(1):1–15.
  • Joyce RJ, Janowiak JEAP. 2004. CMORPH: a method that produces global precipitation estimates from passive microwave and infrared data at high spatial and temporal resolution. J Hydrometeorol. 5(3):287–296.
  • Kenawy AME, Lopez-Moreno JI, Mccabe MF, Vicente-Serrano SM. 2015. Evaluation of the TMPA-3B42 precipitation product using a high-density rain gauge network over complex terrain in northeastern Iberia. Global Planet Change. 133:188–200.
  • Khan SI, Yang H, Gourley JJ, Khattak MUK, Yong B, Vergara HJ. 2014. Evaluation of three high-resolution satellite precipitation estimates: potential for monsoon monitoring over Pakistan. Adv Space Res. 54(4):670–684.
  • Kim K, Park J, Baik J, Choi M. 2017. Evaluation of topographical and seasonal feature using GPM IMERG and TRMM 3B42 over Far-East Asia. Atmos Res. 187:95–105.
  • Kong F, Shi PJ, Fang J, Lv LL, Fang JY, Guo JP. 2017. Advances and prospects of spatiotemporal pattern variation of extreme precipitation and its affecting factors under the background of global climate change. J Catastrophol. 32(2):165–174. in Chinese.
  • Kummerow C, Barnes W, Kozu T, Shiue J, Simpson J. 1998. The Tropical Rainfall Measuring Mission (TRMM) sensor package. J Atmos Oceanic Technol. 15(3):809–817.
  • Li L, Yang H, Wang J, Adler RF, Policelli FS, Habib S, Irwn D, Korme T, Okello L. 2009. Evaluation of the real-time TRMM-based multi-satellite precipitation analysis for an operational flood prediction system in Nzoia Basin, Lake Victoria, Africa. Nat Hazard. 50:109–123.
  • Li WY, He XG, Sun WW, Scaioni M, Yao DJ, Fu J, Chen Y, Liu B, Gao J, Li X. 2019. Evaluating three satellite-based precipitation products of different spatial resolutions in Shanghai based on upscaling of rain gauge. Int J Remote Sens. 40(15):1–17.
  • Li Z, Yang DW, Hong Y. 2013. Multi-scale evaluation of high-resolution multi-sensor blended global precipitation products over the Yangtze River. J Hydrol. 500(14):157–169.
  • Liang P, Ding YH. 2017. The long-term variation of extreme heavy precipitation and its link to urbanization effects in Shanghai during 1916–2014. Adv Atmos Sci. 34(3):321–334.
  • Mehran A, AghaKouchak A. 2014. Capabilities of satellite precipitation datasets to estimate heavy precipitation rates at different temporal accumulations. Hydrol Process. 28(4):2262–2270.
  • Miao CY, Ashouri H, Hsu K, Sorooshian S, Duan QY. 2015. Evaluation of the PERSIANN-CDR Daily Rainfall Estimates in Capturing the Behavior of Extreme Precipitation Events over China. J Hydrometeorol. 16(3):1387–1396.
  • Milewski A, Elkadirki R, Durham M. 2015. Assessment and Comparison of TMPA Satellite Precipitation Products in Varying Climatic and Topographic Regimes in Morocco. Remote Sens. 7:5697–5717.
  • Nastos PT, Kapsomenakis J, Douvis KC. 2013. Analysis of precipitation extremes based on satellite and high-resolution gridded data set over Mediterranean basin. Atmos Res. 131:46–59.
  • Shen Y, Xiong AY, Wang Y, Xie PP. 2010. Performance of high-resolution satellite precipitation products over China. J Geophys Res Atmos. 115(D2):D02114.
  • Sillmann J, Roeckner E. 2008. Indices for extreme events in projections of anthropogenic climate change. Climate Change. 86(1–2):83–104.
  • Sohn BJ, Han HJ, Seo EK. 2010. Validation of satellite-based high-resolution rainfall products over the Korean Peninsula using data from a dense rain gauge network. J Appl Meteorol Climatol. 49(2009):367–370.
  • Song XM, Zhang JY, Aghakouchak A, Roy SS, Xuan YQ, Wang GQ, He RM, Wang XJ, Liu CS. 2015. Rapid urbanization and changes in spatiotemporal characteristics of precipitation in Beijing metropolitan area. J Geophys Res. 119(19):11250–11271.
  • Sorooshian S, AghaKouchak A, Arkin P, Eylander J, Foufoula-Georgiou E, Harmon R, Hendrickx JMH, Imam B, Kuligowski R, Skahill B. 2011. Advanced concepts on remote sensing of precipitation at multiple scales. Bull Am Meteorol Soc. 92(10):1353–1357.
  • Stampoulis D, Anagnostou EN, Nikolopoulos EI. 2013. Assessment of high-resolution satellite-based rainfall estimates over the mediterranean during heavy precipitation events. J Hydrometeorol. 14(5):1500–1514.
  • Stanfield RE, Jiang JH, Dong X, Xi BK, Hui S, Donner L, Rotstayn L, Wu TW, Cole J, Shindo E. 2015. A quantitative assessment of precipitation associated with the ITCZ in the CMIP5 GCM simulations. Climate Dyn. 47(5–6):1863–1880.
  • Stisen S, Tumbo M. 2015. Interpolation of daily rain gauge data for hydrological modelling in data sparse regions using pattern information from satellite data. Int Assoc Sci Hydrol Bull. 60(11):1911–1926.
  • Sun XM, Barros AP. 2010. An evaluation of the statistics of rainfall extremes in rain gauge observations, and satellite-based and reanalysis products using universal multifractals. J Hydrometeorol. 5(12):1153–1162.
  • Tan LM, Duan Z. 2017. Assessment of GPM and TRMM precipitation products over Singapore. Remote Sens. 9(7):1–16.
  • Tang GQ, Ma YZ, Long D, Zhong LZ, Hong Y. 2016. Evaluation of GPM Day-1 IMERG and TMPA Version-7 legacy products over Mainland China at multiple spatiotemporal scales. J Hydrol. 533:152–167.
  • Vu TM, Raghavan SV, Liong SY, Mishra AK. 2017. Uncertainties of gridded precipitation observations in characterizing spatio‐temporal drought and wetness over Vietnam. Int J Climatol. 38(4):2067–2081.
  • Yin XD, Dong SY, Han ZY, Wang R. 2018. Projected risk of drought and flood at Yangtze River Delta for the next 50 years. J Meteorol Environ. 34(5):66–75. in Chinese.
  • Yong B, Ren LL, Hong Y, Gourley JJ, Tian YD, Huffman GJ, Xi C, Wang WG, Wen YX. 2013. First evaluation of the climatological calibration algorithm in the real-time TMPA precipitation estimates over two basins at high and low latitudes. Water Resour Res. 49(5):2461–2472.
  • Zhong S, Qian Y, Zhao C, Leung R, Liu DQ. 2017. Urbanization-induced urban heat island and aerosol effects on climate extremes in the Yangtze River Delta region of China. Atmos Chem Phy. 17(8):1–57.

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