Stream flow analysis and modelling using artificial intelligence techniques / Mohammed A. B. Seyam
The reliable prediction of stream flow (SF) is an important aspect in the planning, design and management of surface water and rivers systems. This prediction can be performed using either process-based or data driven-based models (DDMs). Several modelling approaches fall under DDMs, such as stat...
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my.um.stud.82652020-01-18T02:30:58Z Stream flow analysis and modelling using artificial intelligence techniques / Mohammed A. B. Seyam Mohammed , A. B. Seyam TJ Mechanical engineering and machinery The reliable prediction of stream flow (SF) is an important aspect in the planning, design and management of surface water and rivers systems. This prediction can be performed using either process-based or data driven-based models (DDMs). Several modelling approaches fall under DDMs, such as statistical and artificial intelligence (AI) techniques. AI includes artificial neural networks (ANNs), support vector machines (SVM) and other techniques. The main goal of this research is to develop and employ a group of efficient AI-based models for predicting the real-time hourly stream flow (Q) in the downstream area of the Selangor River basin, taken here as the paradigm of humid tropical rivers in Southeast Asia. The Q of this river is yet to be subjected to prediction using AI. Despite intensive applications of monthly and daily SF prediction using AI over the last two decades, the prediction of Q is rare, particularly in small rivers in humid tropical regions, such as the Selangor River. The significance of this research lies in the uniqueness of the considered process and the novelty of the applied methodology in the modelling process. The performance of AI-based models can be improved through the integration of the hydrological description of SF in the modelling process through estimation of lag time (Lt) and analysis of the long-term changes of SF regimes which verified considerable changes may potentially result in increasing the probability of floods occurring in future. The integration process is essential to the selection of input and output variables of AIbased models and the lag intervals between them. The modelling process are performed in two phases to explore the possibility of improving the performance of AI-based models through the accurate timing of the model variables based on Lt estimation by two approaches, namely, the correlation coefficient and hydrological graphical approaches. Through the two modelling phases, four AI techniques, which include three types of ANNs, namely, the multi-layer perceptron network, radial basis function network, and generalized regression neural networks, along with SVM, are employed to develop six AI-based models to predict the Q. Three scenarios were employed to achieve six combinations of input variables, the first adopts RF and the second adopts WL while the third adopts both WL and RF as input variables. A total of 8753 patterns of Q, water level, and rainfall hourly records representing a one-year period (2011) were utilized in the modelling process. The performance evaluation of the developed AI-based models shows that high correlation coefficient (R) between the observed and predicted Q is achieved by most of the developed models. For example, R in SVM-M6 model is 0.992 and 0.953 for the training and testing data sets, respectively. The developed AI-based models were efficiently employed in some hydrological applications, such as Q prediction, analysis of the influence of both water level and rainfall on Q and estimation of the missing records of Q. They also were employed in flood early warning throughout the advanced detection of hydrological conditions that could lead to formations of floods. 2016-02 Thesis NonPeerReviewed application/pdf http://studentsrepo.um.edu.my/8265/1/All.pdf application/pdf http://studentsrepo.um.edu.my/8265/5/mohammed.pdf Mohammed , A. B. Seyam (2016) Stream flow analysis and modelling using artificial intelligence techniques / Mohammed A. B. Seyam. PhD thesis, University of Malaya. http://studentsrepo.um.edu.my/8265/ |
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TJ Mechanical engineering and machinery Mohammed , A. B. Seyam Stream flow analysis and modelling using artificial intelligence techniques / Mohammed A. B. Seyam |
| description |
The reliable prediction of stream flow (SF) is an important aspect in the planning, design
and management of surface water and rivers systems. This prediction can be performed
using either process-based or data driven-based models (DDMs). Several modelling
approaches fall under DDMs, such as statistical and artificial intelligence (AI) techniques.
AI includes artificial neural networks (ANNs), support vector machines (SVM) and other
techniques. The main goal of this research is to develop and employ a group of efficient
AI-based models for predicting the real-time hourly stream flow (Q) in the downstream
area of the Selangor River basin, taken here as the paradigm of humid tropical rivers in
Southeast Asia. The Q of this river is yet to be subjected to prediction using AI. Despite
intensive applications of monthly and daily SF prediction using AI over the last two
decades, the prediction of Q is rare, particularly in small rivers in humid tropical regions,
such as the Selangor River. The significance of this research lies in the uniqueness of the
considered process and the novelty of the applied methodology in the modelling process.
The performance of AI-based models can be improved through the integration of the
hydrological description of SF in the modelling process through estimation of lag time
(Lt) and analysis of the long-term changes of SF regimes which verified considerable
changes may potentially result in increasing the probability of floods occurring in future.
The integration process is essential to the selection of input and output variables of AIbased
models and the lag intervals between them. The modelling process are performed
in two phases to explore the possibility of improving the performance of AI-based models
through the accurate timing of the model variables based on Lt estimation by two
approaches, namely, the correlation coefficient and hydrological graphical approaches.
Through the two modelling phases, four AI techniques, which include three types of
ANNs, namely, the multi-layer perceptron network, radial basis function network, and generalized regression neural networks, along with SVM, are employed to develop six
AI-based models to predict the Q. Three scenarios were employed to achieve six
combinations of input variables, the first adopts RF and the second adopts WL while the
third adopts both WL and RF as input variables. A total of 8753 patterns of Q, water level,
and rainfall hourly records representing a one-year period (2011) were utilized in the
modelling process.
The performance evaluation of the developed AI-based models shows that high
correlation coefficient (R) between the observed and predicted Q is achieved by most of
the developed models. For example, R in SVM-M6 model is 0.992 and 0.953 for the
training and testing data sets, respectively. The developed AI-based models were
efficiently employed in some hydrological applications, such as Q prediction, analysis of
the influence of both water level and rainfall on Q and estimation of the missing records
of Q. They also were employed in flood early warning throughout the advanced detection
of hydrological conditions that could lead to formations of floods. |
| format |
Thesis |
| author |
Mohammed , A. B. Seyam |
| author_facet |
Mohammed , A. B. Seyam |
| author_sort |
Mohammed , A. B. Seyam |
| title |
Stream flow analysis and modelling using artificial intelligence techniques / Mohammed A. B. Seyam |
| title_short |
Stream flow analysis and modelling using artificial intelligence techniques / Mohammed A. B. Seyam |
| title_full |
Stream flow analysis and modelling using artificial intelligence techniques / Mohammed A. B. Seyam |
| title_fullStr |
Stream flow analysis and modelling using artificial intelligence techniques / Mohammed A. B. Seyam |
| title_full_unstemmed |
Stream flow analysis and modelling using artificial intelligence techniques / Mohammed A. B. Seyam |
| title_sort |
stream flow analysis and modelling using artificial intelligence techniques / mohammed a. b. seyam |
| publishDate |
2016 |
| url |
http://studentsrepo.um.edu.my/8265/1/All.pdf http://studentsrepo.um.edu.my/8265/5/mohammed.pdf http://studentsrepo.um.edu.my/8265/ |
| _version_ |
1738506120655273984 |
| score |
13.23648 |