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Reseach Article

Study of Time Series Data Mining for the Real Time Hydrological Forecasting: A Review

by Satanand Mishra, C. Saravanan, V. K. Dwivedi
International Journal of Computer Applications
Foundation of Computer Science (FCS), NY, USA
Volume 117 - Number 23
Year of Publication: 2015
Authors: Satanand Mishra, C. Saravanan, V. K. Dwivedi
10.5120/20692-3581

Satanand Mishra, C. Saravanan, V. K. Dwivedi . Study of Time Series Data Mining for the Real Time Hydrological Forecasting: A Review. International Journal of Computer Applications. 117, 23 ( May 2015), 6-17. DOI=10.5120/20692-3581

@article{ 10.5120/20692-3581,
author = { Satanand Mishra, C. Saravanan, V. K. Dwivedi },
title = { Study of Time Series Data Mining for the Real Time Hydrological Forecasting: A Review },
journal = { International Journal of Computer Applications },
issue_date = { May 2015 },
volume = { 117 },
number = { 23 },
month = { May },
year = { 2015 },
issn = { 0975-8887 },
pages = { 6-17 },
numpages = {9},
url = { https://ijcaonline.org/archives/volume117/number23/20692-3581/ },
doi = { 10.5120/20692-3581 },
publisher = {Foundation of Computer Science (FCS), NY, USA},
address = {New York, USA}
}
%0 Journal Article
%1 2024-02-06T23:00:10.498724+05:30
%A Satanand Mishra
%A C. Saravanan
%A V. K. Dwivedi
%T Study of Time Series Data Mining for the Real Time Hydrological Forecasting: A Review
%J International Journal of Computer Applications
%@ 0975-8887
%V 117
%N 23
%P 6-17
%D 2015
%I Foundation of Computer Science (FCS), NY, USA
Abstract

This paper presents a review of runoff forecasting method based on hydrological time series data mining. Researchers are developed models for runoff forecasting using the data mining tools and techniques like regression analysis, clustering, artificial neural network (ANN), and support vector machine (SVM), Genetic Algorithms (GA), fuzzy logic and rough set theories. The scientific community has been trying to find out a better approach to solve the issues of flood problems. Time Series Data mining is paying crucial role for the achieving a real time hydrological forecast. Hydrological Time series is an important class of temporal data objects and it can be find out from water resource management and metrological department. A hydrological time series is a collection of observations of hydro and hydrometeorological parameters chronologically. The wide use of hydrological time series data has initiated a great deal of research and development attempts in the field of data mining. Trend, pattern, simulation, similarity measures indexing, segmentation, visualization and prediction carried out by the researchers with the implicit mining from the historical observed data. The critical reviews of the existing hydrological parameter prediction research are briefly explored to identify the present circumstances in hydrological fields and its concerned issues.

References
  1. Chaubey V. , Mishra S. and Pandey,S. K. (2014), Time series data mining in real time surface runoff forecasting through support vector machine, IJCA(0975-8887), ISBN : 973-93-80882-93-2, 98(3), PP 23-28. Doi> 10. 5120/17163-7223. ISBN: 973-93-80882-93-2.
  2. Gupta, P. , Mishra, S. , and Pandey, S. K. (2014), Time series data mining in rainfall forecasting using artificial neural network, IJSET (ISSN: 2277-1581), 3(8), pp 1060-1065.
  3. Mishra,S. , Tiwari,H. L. , Shukla J. P. and Purvia,R. (2014), Estimation of runoff and flood risk in the Narmada River Basin using hydrological time series data mining, in 19th International conference on "Hydraulics, Water Resources, Coastal & Environmental Engineering (HYDRO 2014 INTERNATIONAL)", MANIT, Bhopal.
  4. Mishra, S. Gupta, P. , Pandey, S. K. , Shukla, J. P. (2014), An Efficient Approach of Artificial Neural Network in Runoff Forecasting, IJCA, 92(5), PP 9-15. Doi> 10. 5120/16003-4991.
  5. Mishra,S. , Chaubey,V. , Pandey,S. K . and Shukla,J. P. (2014), "An efficient approach of Support vector machine in runoff forecasting", IJSER (0975-8887), ISSN 2229-5518 , 5(3) PP. 158-167.
  6. Mishra, S. , Dwivedi, V. K. , Sarvanan, C. and Pathak, K. K. (2013), "Pattern Discovery in Hydrological Time Series Data Mining during the Monsoon Period of the High Flood Years in Brahmaputra River Basin", IJCA(0975-8887), doi-10. 5120/11397-6698, 67(6), pp 7-14.
  7. Mishra,S. , Saravanan,C. and Dwivedi,V. K. (2014), Estimation of flood magnitude and flood risk in the Brahmaputra river basin using hydrological time series data mining in the Brahmaputra river basin using hydrological time series data mining, International conference on decision support systems for early warning and mitigation of disaster (DSS-EWMD), NIT Durgapur.
  8. Mishra,S. , Sarvanan,C. , Dwivedi,V. K. and Shukla,J. P. (2014), Rainfall prediction using hydrological time series data mining, published in national workshop on "Technologies for Sustainable Rural Development- Having Potential for Socio-economic Upliftment" during July, 04-05, 2014 at CSIR-AMPRI, Bhopal, pp. 403-408.
  9. Mishra,S. , Shukla,J. P. , Saravanan,C. , Dwivedi V. K. and Pathak,K. K. (2013), "An Innovative Approach of Data Mining Techniques in Stream Flow Forecasting" ISCA-ISC-2013-5CITS-05, Souvenir of 3rd International Science Congress, Coimbatore, India, 8th – 9th .
  10. Mishra,S. , Majumder S. and Dwivedi V. K. (2011), "PATTERN DISCOVERY IN HYDROLOGICAL TIMESERIES DATA MINING " in a Sustainable Water resources Management And Climate Change Adaptation, II, pp. 107-115, NIT Durgapur.
  11. Mishra, S. , Sarvanan, C. ,Dwivedi, V. K. , and Pathak, K. K. (2014), "Discovering Flood Recession Pattern in Hydrological Time Series Data Mining during the Post Monsoon Period", IJCA(0975-8887), ISBN : 973-93-80880-78-3, 90(08), PP 35-44 doi-10. 5120/15597-4375.
  12. Mishra, S. , Sarvanan,C. , Dwivedi, V. K. and Pathak,K. K. (2015), "Discovering Flood Rising Pattern in Hydrological Time Series Data Mining during the Pre Monsoon Period", Indian. J. of Zeo-Marine Science, 44(3).
  13. Purviya,R. , Tiwari,H. L. Mishra,S. (2014), "Application of Clustering Data Mining Techniques in Temporal Data Sets of Hydrology: A Review" , IJSET(ISSN:2277-1581) , 3(4), pp 360-365.
  14. Mohammadi, K. , Eslami, R. H. and Kahawita, R. (2006), Parameter estimation of an ARMA model for river flow forecasting using Goal programming, ELSEVIER Sciences, Journal of Hydrology 331, pp 293-299.
  15. Abhishek, K. , Kumar, A. , Ranjan, R. , and Kumar, S. (2012), A Rainfall Prediction Model using Artificial Neural Network, IEEE.
  16. Abrahart, R. J. , See, L. & Kneale, P. E. (1999), Using pruning algorithms and genetic algorithms to optimise network architectures and forecasting inputs in a neural network rainfall-runoff model, journal of hydroinformatics.
  17. Adamowski, J. and Karapataki, C. (2010), Comparison of Multivariate Regression and Artificial Neural Networks for Peak Urban Water-Demand Forecasting: Evaluation of Different ANN Learning Algorithms, ASCE
  18. Adamowski, J. F. (2008), Peak Daily Water Demand Forecast Modeling Using Artificial Neural Networks, ASCE.
  19. Mittal, P. , Chowdhury, S. , Roy, S. , Bhatia, N. , and Srivastav, R. (2012), Dual Artificial Neural Network for Rainfall-Runoff Forecasting, Journal of Water Resource and Protection, 4, pp 1024-1028.
  20. Abbasi,M. Abduli, M. A. , Omidvar, B. and Baghvand, A. (2013), Forecasting Municipal Solid waste Generation by Hybrid Support Vector Machine and Partial Least Square Model, Int. J. Environ. Res. , 7(1), pp 27-38, ISSN: 1735-6865.
  21. Ramoni, M. ,Sebastiani, P. and Cohen, P. (2000), Multivariate clustering by dynamics, Proceedings of the 2000 National Conference on Artificial Intelligence (AAAI-2000), San Francisco, CA, pp 633–638.
  22. Wijk, J. J. van and Selow, E. R. Van (1999), Cluster and calendar based visualization of time series data, Proceedings of IEEE Symposium on Information Visualization, San Francisco, CA, pp25–26.
  23. Vlachos, M. ,Lin, J. and Keogh, E. (2003), A wavelet based anytime algorithm for k-means clustering of time series, Proceedings of the Third SIAM International Conference on Data Mining, San Francisco, CA, May 1–3.
  24. Li, C. And Biswas, G. (1999), Temporal pattern generation using hidden Markov model based unsupervised classification, in: D. J. Hand, J. N. Kok, M. R. Berthold (Eds. ), Lecture Notes in Computer Science, vol. 164, IDA '99, Springer, Berlin, pp 245–256.
  25. Liao, T. W. (2005), Clustering of time series data—a survey, Pattern Recognition Society.
  26. Agarwal, P. , Alam Afshar, M. And Biswas, R. (2010), Analysing the agglomerative hierarchical Clustering Algorithm for Caegorical Attributes, IJJMT, 1(2), pp 186-190.
  27. Hall, M. J. , Minns, A. W. and Ashrafuzzaman, A. K. M. , (2002), The application of data mining techniques for the regionalization of hydrological variables, Hydrology and Earth System Sciences, 6(4), 685–694.
  28. Mujumdar, P. P. and Kumar, D. N. , 1990 "Stochastic models of streamflow: some case studies", Hydrological Sciences Journal, vol. 35,4.
  29. Wang, C. W. , Chau, W. K. , Cheng, T. C. and Qiu, Lin (2009), A comparison of performance of several artificial intelligent methods for forecasting monthly discharge time series, Journal of Hydro, 374(3-4), pp 294-306.
  30. Makridakis, S. and Hison, M. , 1995 "ARMA MODELS and The Box Jenkins methodology" by revised version of 95/33/TM.
  31. Agarwal, A. and Singh, R. D. (2004), Runoff Modelling Through Back Propagation Artificial Neural Network With Variable Rainfall-Runoff Data, Water Resources Management, 18, pp 285–300.
  32. Boudaghpour, S. , Bagheri, M. , and Bagheri, Z. ,2014, "Using Stochastic Modeling Techniques to Predict the Changes of Total Suspended Solids and Sediments in Lighvan Chai Catchment Area in Iran", Journal of River Engineering, Vol. 2 , Issue 1.
  33. Tesfaye, Y. G. , Meerschaert, M. M. and Andersonet, P. L. , 2006 "Identification of periodic autoregressive moving average models and their application to the modelling of river flows", Water Resources Research, Vol. 42, p. p. no 1-11.
  34. Musa, J. J, 2013 "Stochastic Modelling of Shiroro River Stream flow Process", AJER, Vol-02, Issue-06, pp-49-54.
  35. E. Toth, Brath, A. , and Montanari, A. , 2000 "Comparison of short-term rainfall prediction models for real-time flood forecasting", Journal of Hydrology, Vol -239, p. p. no. 132–147.
  36. Chakraborty, S. , Denis, D. M. , and Sherring, A. "Development of Time Series Autoregressive Model for prediction of rainfall and runoff in Kelo Watershed Chhattisgarh", International Journal of Advances in Engineering Science and Technology, Vol- 2, p. p. no. 153-163.
  37. Devi, C. J. , Reddy, B. S. P. , Kumar, K. V. , Reddy, B. M. , and Nayak, N. R. (2012), ANN Approach for Weather Prediction using Back Propagation, IJETT.
  38. Dreiseitl, S. , and Ohno-Machado, L. (2002), Logistic regression and artificial neural network classification models: a methodology review, SCIENCE DIRECT.
  39. Edossa, D. C. , Mukand, S. , Babel, Forecasting Hydrological Droughts Using Artificial Neural Network Modeling Technique.
  40. Hsieh, B. B. , Bartos, C. C. L. , and Zhang, B. , USE OF ARTIFICIAL NEURAL NETWORKS IN A STREAMFLOW PREDICTION SYSTEM.
  41. Kumar, R. , and Yadav, G. S. (2013), Forecasting of Rain Fall in Varanasi District, Uttar Pradesh Using Artificial Neural Network, JECET.
  42. Kumarasiri, A. D. , and Sonnadara, U. J. (2008), Performance of an artificial neural network on forecasting the daily occurrence and annual depth of rainfall at a tropical site, Hydrological process, 22, pp 3535–3542
  43. Luc, K. C. , Ball, J. E. , and Sharma, A. (2001), An Application of Artificial Neural Networks for Rainfall Forecasting, ELSEVIER, 33(6–7), pp 683–693.
  44. Machado, F. , Mine, M. , Kaviski, E. , and Fill, H. (2011), Monthly rainfall–runoff modelling using artificial neural networks, Hydrological Sciences Journal, 56(3).
  45. Maier, H. R. , Jain, A. ,Dandy, G. C. and Sudheer, K. P. (2010), Methods used for the development of neural networks for the prediction of water resource variables in river systems: Current status and future directions, environmental modeling & software, 25, pp 891-909.
  46. Minns, A. W. , and Hall, M. J. (1996), artificial neural networks as rainfall runoff models, Hydrological Sciences Journal.
  47. Mutlu, E. , Chaubey, I. , Hexmoor, H. , and Bajwa, S. G. (2008), Comparison of artificial neural network models for hydrologic predictions at multiple gauging stations in an agricultural watershed, Hydological Process.
  48. Raman, H. and Sunilkumar, N. (1995), Multivariate modelling of water resources time series using artificial neural networks, Hydrological Sciences Journal, 40(2).
  49. Riad, S. Mania, J. , Bouchaou, L. , and Najjar, Y. (2004), Rainfall-Runoff Model Using an Artificial Neural Network Approach, Mathematical and Computer Modelling 40 pp 839-846.
  50. Sarkar, A. And Kumar, R. (2012), Artificial Neural Network for Event Based Rainfall-Runoff modelling, Journal of Water Resource and Prediction, 4, pp 891-897.
  51. Shamseldin, A. Y. , Nasr, A. E. and O'Connor, K. M. (2002), Comparison of different forms of the Multi-layer Feed-ForwardNeural Network method used for river flow forecasting, Hydrology and Earth System Sciences, 6(4), pp 671–684.
  52. Sharda, V. N. , Patel, R. M. , Prasher, S. O. , Ojasvi, P. R. , and Prakash, C. (2006), Modeling runoff from middle Himalayan watersheds employing artificial intelligence techniques, agricultural water management 83, pp 233 – 242.
  53. Srinivasulu, S. and Jain, A. (2006), A comparative analysis of training methods for artificial neural network rainfall-runoff models, applied soft computing, 6, pp 295-306.
  54. Wu, J. S. , P. E. , Asce, M. , Han, J. , Annambhotla, S. and Bryant, S. (2005), Artificial neural network for forecasting watershed runoff and stream flows, Journal of Hydrologic Engineering, pp 216-222.
  55. Cigizoglu, H. K. (2005), Generalized regression neural network in monthly flow forecasting, Civil Engineering and Environmental Systems, 22 (2).
  56. Cigizoglu, H. K. , and Alp, M. (2006), Generalized regression neural network in modelling river sediment yield, ELSEVIER
  57. Koutsoyiannis, D. (2007), Discussion of "Generalized regression neural networks for evapotranspiration modelling, IAHS.
  58. Kisi, O. (2006), Generalized regression neural networks for evapotranspiration modelling, IAHS.
  59. Wang, Z. L. , and Sheng, H. H. (2010), Rainfall Prediction Using Generalized Regression Neural Network: Case study Zhengzhou, IEEE.
  60. Cannas, B. , Fanni, A. , Sias, G. , Tronci, S. , and Zedda, M. K. (2005), River flow foreasting using neural networks and wavelet analysis, European Geosciences Union.
  61. Adamowski, J. and Sun, K. (2010), Development of a coupled wavelet transform and neural network method ofr flow forecasting of non-perennial rivers in semi-arid watershed, ELSEVIER
  62. Adamowski, J. , Chan, H. F. , Prasher, S. O. , and Sharda, V. N. (2012), Comparison of multivariate adaptive regression splines with coupled wavelet transform artificial neural networks for runoff forecasting in Himalayan micro-watersheds with limited data, IWA.
  63. Adamouski, J. , and Chan, H. F. (2011), A wavelet neural network conjunction model for groundwater level forecasting, ELSEVIER
  64. Belayneh, A. , and Adamowski, J. (2012), Standard precipitation index drought forecasting using Neural Networks, Wavelet Neural Networks, and Support Vector Regression, Applied Computational Intelligence and Soft Computing Volume 2012 Article ID 794061, 13 pages.
  65. Campisi-Pinto, S. , Adamouski, J. , and Oron, G. (2012), Forecasting UrbanWater Demand ViaWavelet-Denoising and Neural Network Models. Case Study: City of Syracuse, Italy, Springer, 26(12) pp 3539-3558.
  66. Partal, T. , and Cigizoglu, H. K. (2009), Prediction of daily precipitation using wavelet–neural networks, IAHS.
  67. Ramana, R. V. , Krishna, B. , Kumar, S. R. , and Pandey, N. G. (2013), Monthly Rainfall prediction using wavelet neural network analysis, Springer.
  68. Santos, C. A. G. and da Silva, G. B. L. (2014), Daily streamflow forecasting using a wavelet transform and artificial neural network hybrid models,HydrologicalSciences. JournalJournaldesSciencesHydrologiques,59(2),PP. 312324,http://dx. doi. org/10. 1080/02626667. 2013. 800944
  69. Wei, S. , Yang, H. , Song, J. , Abbaspour, K. , and Xu, Z. (2013), A wavelet-neural network hybrid modeling approach for estimating and predicting river monthly flows, IAHS.
  70. Aggarwal, N. & Aggarwal, K. (2012), A Mid-Point based K-mean Clustering Algorithm for Data mining, IJCSE, 4(06) .
  71. Botsis, D. , Latinopulos, P. and Diamantaras, K. (2011), Rainfall-Runoff Modeling Using Support Vector Regression and Artificial Neural Networks, CEST2011- Rhodes, Ref No. XXX, Greece.
  72. Bhagwat, P. and Maity, R. (2013), Hydroclimatic stream flow prediction using Least Square Support Vector Regression, ISH Journal of Hydraulic Engineering, 19(3) , pp 320-328.
  73. Cimen, M. (2008), Estimation of daily suspended sediments using support vector machines, Journal of Hydrological Sciences, l. 53 (3).
  74. Espinoza, M. , Johan, A. K. Suykens and Bart De Moor. (2006), Load Forecasting using Fixed-Size Least Squares Support Vector Machines.
  75. Flint, E. L. and Flint, L. A. (2012), Downscaling future climate scenarios to fine scales for hydrologic and ecological modeling and analysis, Ecological Processes, A Springer Open Journal. http://www. ecologicalprocesses. com/content/1/1/2.
  76. Lai, H. C. and Tseng, H. M. (2010), Comparison of regression models, grey models, and supervised learning models for forecasting flood stage caused by typhoon events, Journal of the Chinese Institute of Engineers, 33(4), pp 629-634.
  77. Li, H. P. , Kwon, H. H. , Sun, L. , Lall, Upmanu and Kao, J. J. (2010), A modified support vector machine based prediction model on streamflow at the Shihmen Reservoir, Taiwan, International Journal Of Climatology 30, pp 1256-1268.
  78. Liong, Y. S. and Chandrasekaran, S. (2002), Flood Stage Forecasting With Support Vector Machines, Journal of the American Water Resources Association, 38(1).
  79. Lin, Y. J. , Cheng, T. C. and Chau, W. K. (2006), Using support vector machines for long term discharge prediction, Hydrological Science Journal, 51(4), pp599-612.
  80. Ma, Xixia, Ping, J. , Yang, L. , Yan, M. and Mu, H. (2011), Combined model of chaos theory, wavelet and support vector machine for forecasting runoff series and its application, IEEE 978-1-61284-340-7/11.
  81. Maity, R. and Khasid, S. S. (2009), Hydroclimatological approach for monthly streamflow prediction using genetic programming, ISH Journal of Hydraulic Engineering, 15(2).
  82. Lingras, P. and Butz, C. (2004), Interval set Classifiers using Support Vector Machines, IEEE, 0-7803-8376-1/04.
  83. Mamat, M. and Samad, A. S. , Performance of Radial Basis Function and Support Vector Machine in Time Series Forecasting.
  84. Misra, D. , Oommen, T. , Agarwal, A. , Mishra, S. K. and Thompson, M. A. (2009), Application and analysis of support vector machine based simulation for runoff and sediment yield, ELSEVIER Science: 103(2009), pp 527-535.
  85. Mountrakis, G. , Im, J. and Ogole, C. (2010), Support vector machines in remote sensing: A review, ISPRS Journal of Photogrammetry and Remote Sensing, doi:10. 1016/j. isprsjprs. 2010. 11. 001.
  86. Solomatine, P. D. (2002), Computational intelligence techniques in modeling water systems: some applications, IEEE, 0-7803-7278-6/02.
  87. Shahbazi, N. A. and Pilpayeh, A. R. (2012), River flow forecasting using support vector machines, 14th ISCCBE, Moscow, Russia.
  88. Torabi, M. and Hashemi, S. (2012), A Data Mining paradigm to Forecast Weather Sensitive Short-Term Energy Consumption, IEEE 978-1-4673-1479-4/12.
  89. Wu, H. C. , Ho, M. J. and Lee, T. D. (2004), Travel-Time Prediction with Support Vector Regression, IEEE Transactions on Intelligent Transportation Systems, 5(4), 1524-9050/04.
  90. Yang, H. , Huang, K. , King, I. and Lyu, R. M. (2009), Localized support vector regression for time series prediction, ELSEVIER Sciences Neurocomputing 72, pp 2659-2669.
  91. Yi, D. , Wei, C. and Shengfeng, L. (2011), A new Regression Method Based on SVM classification, Eighth International Conference on Fuzzy Systems and Knowledge Discovery, 978-1-61284-181-6/11.
  92. Xian, M. G. and Zeng, Q. B. , (2008), A novel evaluation method basing on support vector machines, IEEE 978-0-7695-3134-2/08.
  93. Yoon, H. , Jun, C. S. , Hyun, Y. , Bae, O. G. and Lee, K. K. (2011), A comparative study of artificial neural network and support vector achiness for predicting groundwater levels in a costal aquifer, ELSEVIER Sciences, Journal of Hydrology No. 396, pp 128-138.
  94. Hwang, H. S, Ham, H. D. and Kim, H. J. (2012), A new measure for assessing the efficiency of hydrological data-driven forecasting models, Hydrological Sciences Journal, 57(7), pp 1257-1274.
  95. Samsudin, R. , Ismail, S. and Shabri, A. (2011), "A Hybrid Model of Self-Organizing Maps (SOM) and Least Square Support Vector Machine (LSSVM) for Time-Series Forecasting," Expert Systems with Applications, 38(8), pp. 10574-10578.
  96. Shabri, A. and Suhartono, (2012), Streamflow forecasting using least-square support vector machines, Hydrological Sciences Journal, 57 (7), pp 1275-1293.
  97. Shah Shiloh, R. (2005), Least Squares Support Vector Machines
  98. Suykens, K. A. J, Brabanter, D. J. , Lukas, L. and Vandewalle, J. (2001), Weighted least support vector machines: robustness and sparse approximation, ELSEVIER Science Neurocomputing: 48, 0925-2312/02, pp85-105. Doi: 10. 1023/A: 1018628609742.
  99. Ismail, S. , Shabri, A. and Samsudin, R. (2012), A hybrid model of self organizing maps and least square support vector machine for river flow forecasting, Hydrology and Earth System Sciences, 16, pp 4417-4433.
  100. Lin, F. , Yeh, C. C. and Lee, Y. M. (2013), A Hybrid Business Failure Prediction Model Using Locally Linear Embedding and Support Vector Machines, Romanian Journal of Economic Forecasting.
  101. Pandhiani, M. S. and Shabri, B. A. (2013), Time Series Forecasting Using Wavelet-Least Squares Support Vector Machines and Wavelet Regression models for Monthly Stream Flow Data, Open Journal of Statistics,3, pp183-194. doi: 10. 4236/ojs. 2013. 33021.
  102. Sivakumar, B. , Berndtsson, R. , Olsson, J. , Jinno, K. and kawamura, A. (2000), Dynamics of monthly rainfall-runoff process at the Gota basin: A search of chaos, Hydrology and Earth System Sciences, 4(3), pp 407-417.
  103. Mutao, H. (2007), An Intelligent Hybrid Genetic Annealing Neural Network Algorithms for Runoff Forecasting, ASCE.
  104. Wang, W. , Xu, D. and Qiu, L. (2010), Support Vector Machine with Chaotic Genetic Algorithms for Annual Runoff Forecasting, ICNC IEEE, 978-1-4244-5961-2/10.
  105. Wang, W. C. , Xu, D. M. , Chau, K. W. and Chen, S. (2013), Improved annual rainfall-runoff forecasting using PSO–SVM model based on EEMD, Journal of Hydroinformatics, doi:10. 2166/hydro. 2013. 134.
  106. Wei, L. H. and Billings, A. S. (2006), Long term prediction of non-linear time series using multiresolution wavelet models, International Journal of Control, 79(6), pp 569-580.
  107. Yu, X. , Liong, Y. S. and Babovic, V. (2004), EC-SVM approach for real time hydrological forecasting, Journal of Hydroinformatics, 06. 3.
  108. Li, S. , Qi, R. & Jia, W. (2009), Calibration Of The Conceptual Rainfall-Run Off Model's Parameters, Advances in Water Resources and Hydraulic Engineering, pp 55-59.
  109. Patil, S. , Patil, S. & Valunjkar, S. (2012), Study of Different Rainfall-Runoff Forecasting Algorithms for Better Water Consumption, ICCTAI.
  110. Banik, S. , Anwer, M. , Khan, A. F. M. K. , Rouf, R. A. & Chanchary, F. A. (2009), Forecasting Bangladeshi monsoon rainfall using neural network and genetic algorithm approaches, ITMR.
  111. Dong, S. , Zhou, H. , and Xu, H. (2004), A Forecast Model of Hydrologic Single Element Medium and Long-Period Based on Rough Set Theory, Water Resources Management, 18, pp 483-495.
  112. Mahabir, C. , Hicks, F. And Fayek, A. (2003), Application of fuzzy logic to forecast seasonal runoff, Hydrological Processes, 17, pp 3749-3762.
  113. Alvisi, S. , Mascellani, G. , Franchini, M. and Bardossy, A. (2006), Water level forecasting through fuzzy logic and artificial neural network approaches, Hydrology and Earth System Sciences, 10, pp 1-17.
  114. Shirke, Y. , Kawitkar, R. And Balan, S. (2012), Artificial Neural Network based Runoff Prediction Model for a Reservoir, IJERT, 1(3), pp 1-4.
Index Terms

Computer Science
Information Sciences

Keywords

Clustering data mining runoff hydrological time series pattern discovery regression analysis ANN SVM. rough set and fuzzy logic genetic algorithms.