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2019 | OriginalPaper | Chapter

Uncertainty Analysis of Rainfall Spatial Interpolation in Urban Small Area

Authors : Jie Huang, Changfeng Jing, Jiayun Fu, Zejun Huang

Published in: Testbeds and Research Infrastructures for the Development of Networks and Communities

Publisher: Springer International Publishing

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Abstract

Uncertainty analysis have attracted increasing attention of both theory and application over the last decades. Owing to the complex of surrounding, uncertainty analysis of rainfall in urban area is very little. Existing literatures on uncertainty analysis paid less attention on gauge density and rainfall intensity. Therefore, this study focuses on urban area, which a good complement to uncertainty research. In this study, gauge density was investigated with carefully selecting of gauge to covering evenly. Rainfall intensity data were extracted from one rainfall event at begin, summit and ending phases of rainfall process. Three traditional methods (Ordinary Kriging, RBF and IDW) and three machine methods (RF, ANN and SVM) were investigated for the uncertainty analysis. The result shows that (1) gauge density has important influence on the interpolation accuracy, and the higher gauge density means the higher accuracy. (2) The uncertainty is progressively stable with the increasing of rainfall intensity. (3) Geostatistic methods has better result than the IDW and RBF owing to considering spatial variability. The selected machine learning methods have good performance than traditional methods. However, the complex training processing and without spatial variability may reduce its practicability in modern flood management. Therefore, the combining of traditional methods and machine learning will be the good paradigm for spatial interpolation and uncertainty analysis.

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Bárdossy, A., Pegram, G.: Interpolation of precipitation under topographic influence at different time scales. Water Resour. Res. 49(8), 4545–4565 (2013)CrossRef

Goovaerts, P.: Geostatistical approaches for incorporating elevation into the spatial interpolation of rainfall. J. Hydrol. 228(1–2), 113–129 (2000)CrossRef

Jeffrey, S.J., Carter, J.O., Moodie, K.B., Beswick, A.R.: Using spatial interpolation to construct a comprehensive archive of Australian climate data. Environ. Model Softw. 16(4), 309–330 (2001)CrossRef

Li, J., Heap, A.D.: Spatial interpolation methods applied in the environmental sciences: a review. Environ. Model Softw. 53, 173–189 (2014)CrossRef

Muthusamy, M., Schellart, A., Tait, S., Heuvelink, G.B.M.: Geostatistical upscaling of rain gauge data to support uncertainty analysis of lumped urban hydrological models. Hydrol. Earth Syst. Sci. 21(2), 1077–1091 (2017)CrossRef

Wagner, P.D., Fiener, P., Wilken, F., Kumar, S., Schneider, K.: Comparison and evaluation of spatial interpolation schemes for daily rainfall in data scarce regions. J. Hydrol. 464–465, 388–400 (2012)CrossRef

Courty, L., Rico-Ramirez, M., Pedrozo-Acuña, A.: The significance of the spatial variability of rainfall on the numerical simulation of urban floods. Water 10(2), 207 (2018)CrossRef

Hall, J., Solomatine, D.: A framework for uncertainty analysis in flood risk management decisions. Int. J. River Basin Manag. 6(2), 85–98 (2008)CrossRef

Hutter, G., Schanze, J.: Learning how to deal with uncertainty of flood risk in long-term planning. Int. J. River Basin Manag. 6(2), 175–184 (2008)CrossRef

10.

Hrachowitz, M., Weiler, M.: Uncertainty of precipitation estimates caused by sparse gauging networks in a small. Mountainous Watershed. J. Hydrol. Eng. 16(5), 460–471 (2011)CrossRef

11.

Tsintikidis, D., Georgakakos, K.R., Sperfslage, J.A., Smith, D.E., Carpenter, T.M.: Precipitation uncertainty and raingauge network design within Folsom Lake watershed. J. Hydrol. Eng. 7(2), 175–184 (2002)CrossRef

12.

Cheng, M., et al.: Performance assessment of spatial interpolation of precipitation for hydrological process simulation in the Three Gorges Basin. Water 9(11), 838 (2017)CrossRef

13.

Rupa, C., Mujumdar, P.P.: Quantification of uncertainty in spatial return levels of urban precipitation extremes. J. Hydrol. Eng. 23(1), 04017053(2018)CrossRef

14.

Yang, L., Tian, F., Niyogi, D.: A need to revisit hydrologic responses to urbanization by incorporating the feedback on spatial rainfall patterns. Urban Clim. 12, 128–140 (2015)CrossRef

15.

Liu, M., Bárdossy, A., Zehe, E.: Interaction of valleys and circulation patterns (CPs) on spatial precipitation patterns in southern Germany. Hydrol. Earth Syst. Sci. 17(11), 4685–4699 (2013)CrossRef

16.

Otieno, H., Yang, J., Liu, W., Han, D.: Influence of rain gauge density on interpolation method selection. J. Hydrol. Eng. 19(11), 04014024(2014)CrossRef

17.

Jing, C., Yu, J., Dai, P., Wei, H., Du, M.: Rule-based rain gauge network design in urban areas aided by spatial kernel density. Water Pract. Technol. 11(1), 166–175 (2016)CrossRef

18.

Moulin, L., Gaume, E., Obled, C.: Uncertainties on mean areal precipitation: assessment and impact on streamflow simulations. Hydrol. Earth Syst. Sci. 13(2), 99–114 (2009)CrossRef

19.

Kobold, M., Sušelj, K.: Precipitation forecasts and their uncertainty as input into hydrological models. Hydrol. Earth Syst. Sci. 9(4), 322–332 (2005)CrossRef

20.

Ly, S., Charles, C., Degré, A.: Different methods for spatial interpolation of rainfall data for operational hydrology and hydrological modeling at watershed scale: a review. Base 17(2), 392–406 (2013)

21.

Li, J., Heap, A.D.: A review of comparative studies of spatial interpolation methods in environmental sciences: performance and impact factors. Ecol. Inform. 6(3–4), 228–241 (2011)CrossRef

22.

de Amorim Borges, P., Franke, J., da Anunciação, Y.M.T., Weiss, H., Bernhofer, C.: Comparison of spatial interpolation methods for the estimation of precipitation distribution in Distrito Federal, Brazil. Theor. Appl. Climatol. 123(1–2), 335–348 (2016)CrossRef

23.

Appelhans, T., Mwangomo, E., Hardy, D.R., Hemp, A., Nauss, T.: Evaluating machine learning approaches for the interpolation of monthly air temperature at Mt. Kilimanjaro, Tanzania. Spat. Stat. 14, 91–113 (2015)MathSciNetCrossRef

24.

Gilardi, S., Begio, N.: Local machine learning models for spatial data analysis. J. Geogr. Inf. Decis. Anal. 4(EPFL-ARTICLE-82651), 11–28 (2000)

25.

Li, J., Heap, A.D., Potter, A., Daniell, J.J.: Application of machine learning methods to spatial interpolation of environmental variables. Environ. Model Softw. 26(12), 1647–1659 (2011)CrossRef

26.

Hengl, T., Heuvelink, G.B.M., Rossiter, D.G.: About regression-Kriging: from equations to case studies. Comput. Geosci. 33(10), 1301–1315 (2007)CrossRef

27.

Bhargava, N., Bhargava, R., Tanwar, P.S., Narooka, P.C.: Comparative study of inverse power of IDW interpolation method in inherent error analysis of aspect variable. In: Mishra, D., Nayak, M., Joshi, A. (eds.) Information and Communication Technology for Sustainable Development, pp. 521–529. Springer, Singapore (2018). https://doi.org/10.1007/978-981-10-3920-1_52CrossRef

28.

Maciej, T.: Spatial interpolation and its uncertainty using automated anisotropic inverse distance weighting (IDW) - cross-validation/Jackknife approach. J. Geogr. Inf. Decis. Anal. 2(2), 18–30 (1998)

29.

Adhikary, S.K., Muttil, N., Yilmaz, A.G.: Genetic programming-based Ordinary Kriging for spatial interpolation of rainfall. J. Hydrol. Eng. 21(2), 1–14 (2016)CrossRef

30.

Berndt, C., Rabiei, E., Haberlandt, U.: Geostatistical merging of rain gauge and radar data for high temporal resolutions and various station density scenarios. J. Hydrol. 508, 88–101 (2014)CrossRef

31.

ESRI: How radial basis functions work (2013)

32.

Xie, Y., et al.: Spatial distribution of soil heavy metal pollution estimated by different interpolation methods: accuracy and uncertainty analysis. Chemosphere 82(3), 468–476 (2011)CrossRef

33.

Breiman, L.: Random forests. Mach. Learn. 45(1), 5–32 (2001)MATHCrossRef

34.

Genuer, R., Poggi, J.M., Tuleau-Malot, C., Villa-Vialaneix, N.: Random forests for big data. Big Data Res. 9, 28–46 (2017)CrossRef

35.

Kühnlein, M., Appelhans, T., Thies, B., Nauss, T.: Improving the accuracy of rainfall rates from optical satellite sensors with machine learning - a random forests-based approach applied to MSG SEVIRI. Remote Sens. Environ. 141, 129–143 (2014)CrossRef

36.

Basheer, I.A., Hajmeer, M.: Artificial neural networks: fundamentals, computing, design, and application. J. Microbiol. Methods 43(1), 3–31 (2000)CrossRef

37.

Prasad, R., Deo, R.C., Li, Y., Maraseni, T.: Input selection and performance optimization of ANN-based streamflow forecasts in the drought-prone Murray Darling Basin region using IIS and MODWT algorithm. Atmos. Res. 197, 42–63 (2017)CrossRef

38.

Cortes, C., Cortes, C., Vapnik, V., Vapnik, V.: Support vector networks. Mach. Learn. 20(3), 273–297 (1995)MATH

39.

Kavzoglu, T., Colkesen, I.: A kernel functions analysis for support vector machines for land cover classification. Int. J. Appl. Earth Obs. Geoinf. 11(5), 352–359 (2009)CrossRef

40.

Sadler, J.M., Goodall, J.L., Morsy, M.M.: Effect of rain gauge proximity on rainfall estimation for problematic urban coastal watersheds in Virginia Beach, Virginia. J. Hydrol. Eng. 22(9), 04017036(2017)CrossRef

41.

Cox, J.C., Sadiraj, V.: On the coefficient of variation as a measure of risk sensitivity. SSRN 3(3), (2011)

42.

Reed, G.F., Lynn, F., Meade, B.D.: Quantitative assays. Clin. Diagn. Lab. Immunol. 9(6), 1235–1239 (2002)

43.

Cristiano, E., Veldhuis, M.-C., Van De Giesen, N.: Spatial and temporal variability of rainfall and their effects on hydrological response in urban areas-a review. Hydrol. Earth Syst. Sci. 21, 3859–3878 (2017)CrossRef

44.

WMO: Guide to Meteorological Instruments and Methods of observation (WMO-No.8), Seven edit. Geneva, Switzerland (2008)

45.

Goovaerts, P.: Geostatistics in soil science: state-of-the-art and perspectives. Geoderma 89(1–2), 1–45 (1999)CrossRef

46.

Ma, L., Chi, X., Zuo, C.: Evaluation of interpolation models for rainfall erosivity on a large scale. In: First International Conference on Agro-Geoinformatics (Agro-Geoinformatics), pp. 1–5. IEEE, Shanghai (2012)

47.

Zhang, P., Liu, R., Bao, Y., Wang, J., Yu, W., Shen, Z.: Uncertainty of SWAT model at different DEM resolutions in a large mountainous watershed. Water Res. 53, 132–144 (2014)CrossRef

Title: Uncertainty Analysis of Rainfall Spatial Interpolation in Urban Small Area
Authors: Jie Huang
Changfeng Jing
Jiayun Fu
Zejun Huang
Publisher: Springer International Publishing
Book: Testbeds and Research Infrastructures for the Development of Networks and Communities
Print ISBN: 978-3-030-12970-5

Electronic ISBN: 978-3-030-12971-2

Copyright Year: 2019
DOI: https://doi.org/10.1007/978-3-030-12971-2_5

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