Research progress on hydrological scaling

Abstract

Abstract: With the development of hydrology and the extending effect of mankind on environment, scale issue has become a great challenge to many hydrologists due to the stochasticism and complexity of hydrological phenomena and natural catchments. More and more concern has been given to the scaling issues to gain a large scale (or small scale) hydrological characteristic from a certain known catchments, but hasn't been solved successfully. The first part of this paper introduced some concepts about hydrological scale, scale issue and scaling. The key problem is the spatial heterogeneity of catchments and the temporal and spatial variability of hydrological fluxes. Three approaches to scale were put forward in the third part, which were distributed modeling, fractal theory and statistical self similarity analyses. Existing problems and future research directions were proposed in the last part.

CLC Number:

S715

LIU Jianmei, PEI Tiefan . Research progress on hydrological scaling[J]. Chinese Journal of Applied Ecology, 2003, (12): 2305-2310.

References

[1] Agnese C, D'Asaro F, Grossi G, et al. 1996. Scaling properties of topologically random channel networks. J Hydrol, 187:183～193
[2] Band LE, Moore ID. 1995. Scale: Landscape attributes and geographical information systems. Hydrol Process, 9: 401～422
[3] Bashford KE, Beven KJ, Young PC. 2002. Observational data and scale-dependent parameterizations: Explorations using a virtual hydrological reality. Hydrol Process, 16: 293～312
[4] Becher A, Braun P. 1999. Disaggregation, aggregation and spatial scaling in hydrological modeling. J Hydrol, 217: 239～252
[5] Bergstrom S, Graham LP. 1998. On the scale problem in hydrological modeling. J Hydrol, 211: 253～265
[6] Beven K. 1995. Linking parameters across scales: Subgrid parameterization and scale dependent hydrological models. Hydrol Process,9 :507～525
[7] Beven KJ, Kerkby MJ. 1979. A physically based, variable contributing model of basin hydrology. Hydrol Sci Bul, 24(1) : 43～69
[8] Bloschl G, Sivapalan M. 1995. Scale issues in hydrological modeling: A review. Hydrol Process, 9. 251～290
[9] Bormann H, Diekkruger B, Renschler C. 1999, Regionaliastion concept for hydrological modelling on different scales using a physically based model: Results and evaluation. Phys Chem Earth (B), 24(7) :799～804
[10] Braun P, Molnar T, Kleeberg HB. 1997. The problem of scaling in grid-related hydrological process modeling. Hydrol Process, 11:1219～1230
[11] Chang F-X(常福直),Ding J(丁晶),Yao J(姚健).2001.Scaling property of the regional variation of annual flood peaks. J Sichuan Univ(Eng Sci)(四川大学学报(工学版)),33(1);5～8(in Chinese)
[12] Chang F-X(常福宣).2001.The application of fractaltheoryinthe study of hydrology and water resources. Ph. Dissertation. Chengdu:Sichuan University. 1～18 (in Chinese)
[13] Chen X(陈喜),Chen Y-Q(陈永勤).2001.Scale issues in the hydrological processes. In: New Issues, Technologies and Methods in 21st Century Chinese Hydrological Research. Beijing: Science Press. 28～37(in Chinese)
[14] Ciarapica L, Todini E. 2002. TOPKAPI: A model for the representation of the rainfall-runoff process at different scales. Hydrol Process, 16:207～229
[15] Connolly RD, Silburn DM. 1995. Distributed parameter hydrology model(ANSWERS) applied to a range of catchment scales using rainfall simulator data Ⅱ . Application to spatially uniform catchments.J Hydrol,172:105～125
[16] Costa-Cabral MC, Burges SJ. 1994. Digital elevation model networks: A model of flow over hillslopes for computation of contributing and dispersal areas. Wat Resour Res, 30(6): 1681～1692
[17] Dooge JCI. 1982. Parameterization of hydrologic processes. In: Eagleson PS ed. Land Surface Processes in Atmospheric General Circulation Models. London: Cambridge University Press. 243～288
[18] Dooge JCI. 1986. Looking for hydrologic laws. Wat Resour Res,22:46s～58s
[19] Dooge JCI. 1997. Scale problems in hydrology. In: Reflections on Hydrology. Washington: American Geophysical Union.
[20] Eaton B, Church M, Ham D. 2002. Scaling and regionalization of flood flows in British Columbia, Canada. Hydrol Process, 16:3245～3263
[21] GuoS-L(郭生练),Li L(李兰),Li D-F(李订芳).2001.The research advance of distributed and physically based watershed hydrological model.In:Liu C-M(刘昌明)ed.Research and Advance of Water Resources Evolvement Rules and Renewable Maintain Mechanism in Yellow River Basin. Zhengzhou: Yellow River Hydraulic Press. 51～57(in Chinese)
[22] GuoS-L(郭生练),Xiong L-H(熊立华),Yang J(杨井).2000.A DEM and physically based distributed hydrological model. J Wuhan Univ HydrElec Eng(武汉水利水电大学学报),33(6):1～5(in Chinese)
[23] Guo S-L(郭生练),Xiong L-H(熊立华),Yang J(杨井).2001.Comparative study and application of distributed hydrophysical model of watersheds.EngJ Wuhan Univ(Eng Edi)(武汉大学学报(工程科学版)),34(1):1～5(in Chinese)
[24] Gupta VK, Castro SL, Over TM. 1996. On scaling exponents of spatial peak flows from rainfall and river network geometry. J Hydrol, 187:81～104
[25] Gupta VK, Dawdy DR. 1995. Physical interpretations of regional variations in the scaling exponents of flood quantiles. Hydrol Process, 9(3/4): 347～361
[26] Gupta VK, Mesa O, Dawdy DR. 1994. Multiscaling theory of flood peaks: Regional quantile analysis. Wat Resour Res, 30(12): 3405～3421
[27] Gupta VK, Rodriguez-Iturbe I, Wood EF, eds. 1986, Scale Problems in Hydrology. Dordrecht: D. Reidel.
[28] Gupta VK, Waymire EC. 1990. multiscaling properties of spatial rainfall and river flow distributions. J Geophys Res, 95 (D3): 1999～2009
[29] Gupta VK, Waymire EC. 1989. Statistical self-similarity in river networks parameterized by elevation. WWat ResourRes, 15: 637～644
[30] Gupta VK, Waymire EC. 1993. A statistical analysis of mesoscale rainfall as a random cascade. J Appl Meterol, 32: 251～267
[31] Hallett PD, Chessell JM, Crawford JW, et al. 1999. Analysis of watersheds using fractals for environmental risk assessment. Progress Environ Sci, 1,2:153～176
[32] Hendrayanto D, Kosugi K, Mizuyama T. 2000. Scaling hydraulic prosperities of forest soils. Hydrol Process, 14: 521～538
[33] Klemes V. 1983. Conceptualisation and scale in hydrology. J Hydrol, 65:1～23
[34] La Barbera P, Rosso E. 1989. On the fractal dimension of stream networks. Wat Resour Res, 25: 735～741
[35] Li C-X(李长兴).1995.On catchment hydrological scale and similarity.J Hydraul(水利学报),1:40～46(in Chinese)
[36] Linden SVD, Woo M. 2003. Transferability of hydrological model parameters between basins in data-sparse areas, subarctic Canada. J Hydrol, 270:182～194
[37] Marceau DJ. 1999. The scale issue in social and natural sciences. J Can Remote Sensing, 25(4): 347～356
[38] Menabde M, Sivapalan M. 2001. Lingking space-time variability of river runoff and rainfall fields: A dynamic approach. Adv Wat Resour, 24:1001～1014
[39] Michael BA, Refsgaard JC. 1996. Distributed Hydrological Modeling. Netherlands: Kluwer Academic Publishers. 17～39
[40] Nykanen DK, Foufoula-Geogiou E, Sapozhnikov VB. 1998. Study of spatial scaling in braided river patterns using synthetic aperture radar imagery. War Resour Res, 34:1795～1807
[41] Pandey GR. 1998. Assessment of scaling behavior of regional floods. J Hydrol Eng, 3:169～173
[42] Ren L-L(任立良),LiuX-R(刘新仁),Han Z-C(郝振纯).1996.Areview on scaleissuesin hdrology.Adv Water Sci(水科学进展),7(supp.):87～99(in Chinese)
[43] Ren L-L(任立良),Liu X-R(刘新仁).1999.Application of digitalelevation model to topological evaluation of drainage system. AdvWater Sci(水科学进展),10(2):129～134(in Chinese)
[44] Ren L-L(任立良).1999.Digital Model Research of Catchment Hydrophysical Process. Ph. Dissertation. Nanjing: Hohai University. 6～23 (in Chinese)
[45] Ren L-L(任立良).2000.A study on Digital Hydrological Modeling.JHohai Univ(河海大学学报),28(4):1～7(in Chinese)
[46] Ribeiro J, Rousselle J. 1996. Robust simple scaling analysis of flood peaks series. Can J Civil Engin, 23:11391145
[47] Rigon R, Rodriguez-Iturbe I, Maritan A, et al. 1996. On Hack's law. Wat Resour Res, 32(11): 3367～3374
[48] Rinaldo A, Rodriguez-Iturbe I, Rigon R, et al. 1992. Minimum energy and fractal structures of drainage networks. Wat Resour Res,28(9): 2183～2195
[49] Rodriguez-Iturbe I, Rinaldo A, Rigon R, et al. 1992. Energy dissipation, runoff producton and three-dimensional structure of river basins. Wat Resour Res, 28(4): 1095～1103
[50] Rosso E, Bacchi B, La Barbera P. 1991. Fractal relation of mainstream length to catchment area in river networks. Wat Resour Res,27:381～387
[51] Rui X-F(芮孝芳),Zhu Q-P(朱庆平).2002.Some issues on distributed catchment hydrological model research. Adv Sci Technol Water Resour(水利水电科技进展),22(3):56～58(in Chinese)
[52] Schertzer D, Lovejoy S. 1987. Physical modeling and analysis of rain and clouds by anisotropic scaling multiplicative processes. J Geophys Res, 92: 9693～9714
[53] Simon AL. 1992. The problem of pattern and scale in ecology. Ecology, 73(6): 1943～1967
[54] Smith JA. 1992. Representation of basin scale in flood peak distributions. Wat Resour Res, 21:1251～1257
[55] Su L-H(苏理宏),Li X-W(李小文),Huang Y-X(黄裕霞).2001.An review on scalein remote sensing.Adv Earth Sci(地球科学进展), 16(4): 544～548(in Chinese)
[56] Veltri M, Veltri P, Maiolo M. 1996. On the fractal description of natural channel networks. J Hydrol, 187:137～144
[57] Wang Z-G(王中根),Liu C-M(刘昌明),Zuo Q-T(左其亭).2002. Methods of constructing distributed hydrological model based on DEM.Progress Geogr(地理科学进展),21(5):430～439(in Chinese)
[58] Wilson BN, Storm DE. 1993. Fractal analysis of surface drainage networks for small upland areas. Trans ASAE,36:1319～1326
[59] Wood EF, Sivapalan M, Beven K, et al. 1988. Effects of spatial variability and scale with implications to hydrologic modeling. J Hydrol,102:29～47
[60] Wood EF, Sivapalan M, Beven K. 1990. Similarity and scale in catchment storm response. Rev Geophys, 28(1): 1～18
[61] Woolhiser DA. 1996. Search for physically based runoff model-A hydrologic EL Dorado? J Hydraul Eng, 122:122～129
[62] WuX-F(吴险峰),LiuC-M(刘昌明).2002.Progressinwatershed hydrological models.Progress Geogr(地理科学进展),21(4):341～348(in Chinese)
[63] XiaJ(夏军),Feng H-L(丰华丽),Tan G(谈戈).2003.Eoo-hydrology-Concept, framework and system. J Irrigation Drai-nage(灌溉排水学报),22(1):4～10(in Chinese)
[64] Xia J(夏军).1993.Scale Issues in hydrology.J Hydraul(水利学报),(5):32～37(in Chinese)
[65] Xia J(夏军).2002.Theory and Methods of Hydrological Nonlinear System. Wuhan: Wuhan University Academic Library. 1～25(in Chinese)
[66] XieY-Q(谢应齐),Cao J(曹杰).2001.10.NonlinearDynamics Mathematics Methods. Beijing: Meteorological Press. (in Chinese)
[67] Yu P-T(于澎涛). 2000. Application of physically-based distributed modelsinforest hydrology.For Res(林业科学研究),13(4):431～438(in Chinese)
[68] Zhou D-L(周大良).1997.Remote sensing information models of HSU and plant canopy interception water. Master Dissertation. Beijing: Beijing University. 28～30 (in Chinese)
[69] Zuo Q-T(左其亭),Wang Z-G(王中根).2002.Morden Hydrology. Zhengzhou: Yellow River Hydraulic Press. 65(in Chinese)