Authors: Lily Ingsrisawang, Supawadee Ingsriswang, Saisuda Somchit, Prasert Aungsuratana, Warawut Khantiyanan

Abstract:

This paper presents the methodology from machine learning approaches for short-term rain forecasting system. Decision Tree, Artificial Neural Network (ANN), and Support Vector Machine (SVM) were applied to develop classification and prediction models for rainfall forecasts. The goals of this presentation are to demonstrate (1) how feature selection can be used to identify the relationships between rainfall occurrences and other weather conditions and (2) what models can be developed and deployed for predicting the accurate rainfall estimates to support the decisions to launch the cloud seeding operations in the northeastern part of Thailand. Datasets collected during 2004-2006 from the Chalermprakiat Royal Rain Making Research Center at Hua Hin, Prachuap Khiri khan, the Chalermprakiat Royal Rain Making Research Center at Pimai, Nakhon Ratchasima and Thai Meteorological Department (TMD). A total of 179 records with 57 features was merged and matched by unique date. There are three main parts in this work. Firstly, a decision tree induction algorithm (C4.5) was used to classify the rain status into either rain or no-rain. The overall accuracy of classification tree achieves 94.41% with the five-fold cross validation. The C4.5 algorithm was also used to classify the rain amount into three classes as no-rain (0-0.1 mm.), few-rain (0.1- 10 mm.), and moderate-rain (>10 mm.) and the overall accuracy of classification tree achieves 62.57%. Secondly, an ANN was applied to predict the rainfall amount and the root mean square error (RMSE) were used to measure the training and testing errors of the ANN. It is found that the ANN yields a lower RMSE at 0.171 for daily rainfall estimates, when compared to next-day and next-2-day estimation. Thirdly, the ANN and SVM techniques were also used to classify the rain amount into three classes as no-rain, few-rain, and moderate-rain as above. The results achieved in 68.15% and 69.10% of overall accuracy of same-day prediction for the ANN and SVM models, respectively. The obtained results illustrated the comparison of the predictive power of different methods for rainfall estimation.

Keywords: Machine learning, decision tree, artificial neural network, support vector machine, root mean square error.

Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1060906

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References:

[1] M.J.A. Berry, and G.S. Linoff, Mastering Data Mining. New York: John Wiley & Sons, Inc, 2000.
[2] D.C. Blanchard, "Raindrop Size Distribution in Hawaiian Rains," Journal of Meteorology, vol. 10, pp. 457-473, 2000.
[3] A.J. Gasiewski, G.A. Showman, and G.M. Skofronick, "Application of Neural Nets to Rain Rate Retrieval from Simulated Multichannel Passive Microwave Imagery," In Geoscience and Remote Sensing Symposium. Remote Sensing for a Sustainable Future. IGARSS -96. International, vol. 3, pp. 1688 - 1691, 1996.
[4] M. A. Hall, and L. A. Smith, "Feature subset selection: a correlation based filter approach," International Conference on Neural Information Processing and Intelligent Information Systems. Springer, 1997, pp. 855- 858
[5] M. A. Hall, and L. A. Smith, "Feature selection for machine learning: comparing a correlation-based filter approach to the wrapper," Florida Artificial Intelligence Symposium. AAAI Press, 1999, pp. 235-239.
[6] J. Joss, K. Schran, J.C. Thoms, and A. Waldvogel, "On the Quantitative Determination of Precipitation by Radar" Wissenschaftclich Mitfeilung, No.63, Eidgennossischen Komnission Sum Studiumder Hagelgilbung and der Hergelshe, 1970.
[7] W. Khantiyanan, Analysis of GPCM forecasting model results. Bureau of Royal Rainmaking and Agricultural Aviation. Thailand, 1996.
[8] G.R. Kohavi, and John, "Wrappers for feature subset selection," Artificial Intelligence, vol. 97, pp. 273-324, 1997.
[9] J.S. Marshall, and W. Mc. Palmer, "The Distribution of Raindrops with Size," Journal of Meteorology, vol 5, pp. 165-166, 1948.