Independent Mixed-gamma Variables for Modelling Rainfall

Understanding the rainfall process and characteristics are crucial to the efficient design of flood mitigation and construction of crop growth models. Modelling rainfall is not limited to fit the historical data to a suitable distribution but the model should be able to generate synthetic rainfall...

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Main Authors:	Roslinazairimah, Zakaria, Nor Hafizah, Moslim
Format:	Conference or Workshop Item
Language:	English English
Published:	2015
Subjects:	GB Physical geography
Online Access:	http://umpir.ump.edu.my/id/eprint/8293/ http://umpir.ump.edu.my/id/eprint/8293/ http://umpir.ump.edu.my/id/eprint/8293/1/Independent_Mixed-gamma_Variables_for_Modelling_Rainfall.pdf http://umpir.ump.edu.my/id/eprint/8293/4/MATH-34.pdf

id	ump-8293
recordtype	eprints
spelling	ump-82932018-06-28T08:25:39Z http://umpir.ump.edu.my/id/eprint/8293/ Independent Mixed-gamma Variables for Modelling Rainfall Roslinazairimah, Zakaria Nor Hafizah, Moslim GB Physical geography Understanding the rainfall process and characteristics are crucial to the efficient design of flood mitigation and construction of crop growth models. Modelling rainfall is not limited to fit the historical data to a suitable distribution but the model should be able to generate synthetic rainfall data. In this study, we derive sets of formulae of mean and variance for the sum of two and three independent mixed-gamma variables, respectively. Firstly, the positive data is fitted to gamma model marginally and the shape and scale parameters are estimated using the maximum likelihood estimation method. Then, the mixed-gamma model is defined to include zero and positive data. The formulae of mean and variance for the sum of two and three independent mixed-gamma variables are derived and tested using the daily rainfall totals from Pooraka station in South Australia for the period of 1901-1990. The results demonstrate that the values of generated mean and using formula are close to the observed mean. However, the values of the variance are sometimes over-estimated or under-estimated of the observed values. The observed variance is lower possibly due to correlation between the experimental data, that have not been included in the mixed-gamma models. The Kolmogorov–Smirnov and Anderson–Darling goodness of fit tests are used to assess the fit between the observed sum and the generated sum of independent mixed-gamma variables. In both cases, the observed sum is not significantly different from the generated sum of independent mixed-gamma model at 5% significance level. This methodology and formulae derived can be applied to find the sum of more than three independent mixed-gamma variables and the general form of the formulae can be derived. 2015 Conference or Workshop Item PeerReviewed application/pdf en http://umpir.ump.edu.my/id/eprint/8293/1/Independent_Mixed-gamma_Variables_for_Modelling_Rainfall.pdf application/pdf en cc_by http://umpir.ump.edu.my/id/eprint/8293/4/MATH-34.pdf Roslinazairimah, Zakaria and Nor Hafizah, Moslim (2015) Independent Mixed-gamma Variables for Modelling Rainfall. In: 6th NAUN European Conference on Applied Mathematics and Informatics (AMATHI 2015), 10-12 January 2015 , Spain. pp. 239-244.. http://www.wseas.us/e-library/conferences/2015/Tenerife/MATH/MATH-34.pdf
repository_type	Digital Repository
institution_category	Local University
institution	Universiti Malaysia Pahang
building	UMP Institutional Repository
collection	Online Access
language	English English
topic	GB Physical geography
spellingShingle	GB Physical geography Roslinazairimah, Zakaria Nor Hafizah, Moslim Independent Mixed-gamma Variables for Modelling Rainfall
description	Understanding the rainfall process and characteristics are crucial to the efficient design of flood mitigation and construction of crop growth models. Modelling rainfall is not limited to fit the historical data to a suitable distribution but the model should be able to generate synthetic rainfall data. In this study, we derive sets of formulae of mean and variance for the sum of two and three independent mixed-gamma variables, respectively. Firstly, the positive data is fitted to gamma model marginally and the shape and scale parameters are estimated using the maximum likelihood estimation method. Then, the mixed-gamma model is defined to include zero and positive data. The formulae of mean and variance for the sum of two and three independent mixed-gamma variables are derived and tested using the daily rainfall totals from Pooraka station in South Australia for the period of 1901-1990. The results demonstrate that the values of generated mean and using formula are close to the observed mean. However, the values of the variance are sometimes over-estimated or under-estimated of the observed values. The observed variance is lower possibly due to correlation between the experimental data, that have not been included in the mixed-gamma models. The Kolmogorov–Smirnov and Anderson–Darling goodness of fit tests are used to assess the fit between the observed sum and the generated sum of independent mixed-gamma variables. In both cases, the observed sum is not significantly different from the generated sum of independent mixed-gamma model at 5% significance level. This methodology and formulae derived can be applied to find the sum of more than three independent mixed-gamma variables and the general form of the formulae can be derived.
format	Conference or Workshop Item
author	Roslinazairimah, Zakaria Nor Hafizah, Moslim
author_facet	Roslinazairimah, Zakaria Nor Hafizah, Moslim
author_sort	Roslinazairimah, Zakaria
title	Independent Mixed-gamma Variables for Modelling Rainfall
title_short	Independent Mixed-gamma Variables for Modelling Rainfall
title_full	Independent Mixed-gamma Variables for Modelling Rainfall
title_fullStr	Independent Mixed-gamma Variables for Modelling Rainfall
title_full_unstemmed	Independent Mixed-gamma Variables for Modelling Rainfall
title_sort	independent mixed-gamma variables for modelling rainfall
publishDate	2015
url	http://umpir.ump.edu.my/id/eprint/8293/ http://umpir.ump.edu.my/id/eprint/8293/ http://umpir.ump.edu.my/id/eprint/8293/1/Independent_Mixed-gamma_Variables_for_Modelling_Rainfall.pdf http://umpir.ump.edu.my/id/eprint/8293/4/MATH-34.pdf
first_indexed	2023-09-18T22:05:42Z
last_indexed	2023-09-18T22:05:42Z
_version_	1777414693087870976

Independent Mixed-gamma Variables for Modelling Rainfall

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