Your search keyword '"adaptive neuro fuzzy interface system"' showing total 9 results

1. Multi-objective Optimization Approaches for Design, Planning, and Management of Water Resource Systems

Author

Ferdowsi, Ahmad, Singh, Vijay P., Ehteram, Mohammad, Mirjalili, Seyedali, Kostianoy, Andrey, Series Editor, and Bozorg-Haddad, Omid, editor

Published

2021

2. EANFIS-based Maximum Power Point Tracking for Standalone PV System.

Author

Manikandan, P. Veera and Selvaperumal, S.

Subjects

*PHOTOVOLTAIC power generation, *MAXIMUM power point trackers, *PHOTOVOLTAIC power systems, *RENEWABLE energy sources, *SOLAR panels, *FUZZY logic, *FUZZY systems

Abstract

The design and development of eco-friendly renewable energy sources is a critical process in the power generation system. Power generation of photovoltaic system depend on temperature and irradiation. Variation of atmospheric conditions need to find points for every instant on V-I characteristics of PV in which maximum power transfer from source to load is achieved. This work deals with Maximum Power Point Tracking (MPPT) method based on Adaptive Neuro Fuzzy Interference System (EANFIS) in standalone operation. The novelty is introduced in the design of inverter, motor selection, and maximum power point tracking. Quasi-Z-source inverter (qZSI) is designed with Z-shaped impedance network to continuously draw constant current from solar panel. MPPT enhance the efficiency of PV panel via load matching; however, it may be affected by environmental changes. Hence, an EANFIS-based MPPT technique is used in the proposed work to confirm maximum power delivery to current motor. The proposed method is the combination of ParticleSwarmOptimization (PSO) and Adaptive Neuro Fuzzy Inference System (ANFIS). Training stage of ANFIS is optimized by PSO to handle switching angle of Multi-Level Inverter (MLI) and generate harmonic-less control voltage, hence named Enhanced ANFIS (EANFIS). Voltage and current control of solar panel decide maximum power generation which is verified using Simulink and practical environment. Thus, EANFIS-based MPPT technique achieved the maximum tracking efficiency of 94% which is better than other comparison methods, namely P&O, RBFNN, ANN, and IDISMC. [ABSTRACT FROM AUTHOR]

Published

2022

3. Predicting the scouring depth around a rectangular pier with a round nose by artificial intelligence methods.

Author

Hosseini, Seyyed Hossein, Movahednejad, Mohamad Hadi, and Rohani, Abbas

Subjects

*ARTIFICIAL neural networks, *ARTIFICIAL intelligence, *PIERS, *ELECTRONIC noses, *MACHINE learning, *RADIAL basis functions

Abstract

Local scour around bridge piers constitutes a significant phenomenon in river engineering. The development of artificial intelligence models and their capabilities has resulted in the widespread adoption of these models. In the experiments, various factors were considered, encompassing three different pier angles (0, 5, and 10°), six submerged vanes with two angles (20 and 30°) aligned with the flow direction, three vane heights (0, 1.25, and 2.5 cm) on the bed, and a collar. The study evaluated the performance of distinct machine learning models, namely, the multi-linear regression (MLR) model, radial basis function neural network (RBF), multilayer perceptron neural network (MLP), support vector machine (SVM), and adaptive neuro-fuzzy inference system (ANFIS) in predicting the scouring depth. Application of these models (RBF, MLP, ANFIS, SVM, and MLR) yielded positive outcomes, with corresponding R2 values of 0.99, 0.98, 0.97, 0.96, and 0.90 for scour depth assessment. The results demonstrated that the RBF artificial neural network model exhibited excellent generalizability in comparison to the other models. It consistently provided accurate predictions with minimal errors across varying training set sizes. Conversely, the ANFIS model exhibited limited generalizability compared to the other models, as reducing the training set size resulted in a significant increase in prediction errors during testing. Furthermore, although the MLR model demonstrated good generalizability, its prediction error was relatively high compared to the alternative models. [ABSTRACT FROM AUTHOR]

Published

2024

4. A review on modeling of solar photovoltaic systems using artificial neural networks, fuzzy logic, genetic algorithm and hybrid models.

Author

Garud, Kunal Sandip, Jayaraj, Simon, and Lee, Moo‐Yeon

Subjects

*MAXIMUM power point trackers, *ARTIFICIAL neural networks, *FUZZY logic, *GENETIC algorithms, *SOLAR radiation, *ARTIFICIAL intelligence

Abstract

Summary: The uncertainty associated with modeling and performance prediction of solar photovoltaic systems could be easily and efficiently solved by artificial intelligence techniques. During the past decade of 2009 to 2019, artificial neural network (ANN), fuzzy logic (FL), genetic algorithm (GA) and their hybrid models are found potential artificial intelligence tools for performance prediction and modeling of solar photovoltaic systems. In addition, during this decade there is no extensive review on applicability of ANN, FL, GA and their hybrid models for performance prediction and modeling of solar photovoltaic systems. Therefore, this article focuses on extensive review on design, modeling, maximum power point tracking, fault detection and output power/efficiency prediction of solar photovoltaic systems using artificial intelligence techniques of the ANN, FL, GA and their hybrid models. In addition, the selected articles on the solar radiation prediction using ANN, FL, GA and their hybrid models are also summarized. Total of 122 articles are reviewed and summarized in the present review for the period of 2009 to 2019 with 90 articles in the field of {ANN, FL, GA and their hybrid models} + solar photovoltaic systems and 32 articles in the field of {ANN, FL, GA and their hybrid models} + solar radiation. The review shows the suitability and reliability of ANN, FL, GA and hybrid models for accurate prediction of the solar radiation and the performance characteristics of solar photovoltaic systems. In addition, this review presents the guidance for the researchers and engineers in the field of solar photovoltaic systems to select the suitable prediction tool for enhancement of the performance characteristics of the solar photovoltaic systems and the utilization of the available solar radiation. [ABSTRACT FROM AUTHOR]

Published

2021

5. Modeling Compressive Strength of Eco-Friendly Volcanic Ash Mortar Using Artificial Neural Networking

Author

Muhammad Nasir Amin, Muhammad Faisal Javed, Kaffayatullah Khan, Faisal I. Shalabi, and Muhammad Ghulam Qadir

Subjects

compressive strength, volcanic ash, mortar, artificial neural network, adaptive neuro fuzzy interface system, Mathematics, QA1-939

Abstract

Forecasting the compressive strength of concrete is a complex task owing to the interactions among concrete ingredients. In addition, an important characteristic of the concrete failure surface is its six-fold symmetry. In this study, an artificial neural network (ANN) and adaptive neuro fuzzy interface system (ANFIS) were employed to model the compressive strength of natural volcanic ash mortar (VAM) by using the six-fold symmetry of concrete failure. The modeling was correlated with four parameters. To train and test the projected models, data for more than 150 samples were collected from the literature. Furthermore, mortar samples with varying proportions of volcanic ash were prepared in the laboratory and tested, and the results were used to validate the models. The performance of the developed models was assessed using numerous statistical measures. The results show that both the ANN and ANFIS models accurately predict the compressive strength of VAM with R-square above 0.9 and lower error statistics. The permutation feature analysis confirmed that the age of specimens affects the strength of VAM the most, followed by the water-to-cement ratio, curing temperature, and percentage of volcanic ash.

Published

2021

6. ANN and ANFIS for Short Term Load Forecasting.

Author

Shah, S., Nagraja, H. N., and Chakravorty, Jaydeep

Subjects

ARTIFICIAL neural networks, LOAD forecasting (Electric power systems), ELECTRICAL engineering, ARTIFICIAL intelligence, FUZZY logic

Abstract

Load forecasting has become one of the major areas of research in electrical engineering. Short term load forecasting (STLF) is essential for power system planning and economic load dispatch. A variety of mathematical methods has been developed for load forecasting. This paper discusses the influencing factors of STLF and an artificial intelligence (AI) based STLF model for MGVCL load. It also includes comparison of various AI models. Our main objective is to develop the best suited model for MGVCL, by critically evaluating the ways in which the AI techniques proposed are designed and tested. [ABSTRACT FROM AUTHOR]

Published

2018

7. Modeling Compressive Strength of Eco-Friendly Volcanic Ash Mortar Using Artificial Neural Networking

Author

Kaffayatullah Khan, Muhammad Ghulam Qadir, Muhammad Nasir Amin, Faisal I. Shalabi, and Muhammad Faisal Javed

Subjects

Adaptive neuro fuzzy inference system, Curing (food preservation), Physics and Astronomy (miscellaneous), Artificial neural network, Neuro-fuzzy, General Mathematics, compressive strength, adaptive neuro fuzzy interface system, Environmentally friendly, volcanic ash, mortar, artificial neural network, Compressive strength, Chemistry (miscellaneous), QA1-939, Computer Science (miscellaneous), Environmental science, Geotechnical engineering, Mortar, Mathematics, Volcanic ash

Abstract

Forecasting the compressive strength of concrete is a complex task owing to the interactions among concrete ingredients. In addition, an important characteristic of the concrete failure surface is its six-fold symmetry. In this study, an artificial neural network (ANN) and adaptive neuro fuzzy interface system (ANFIS) were employed to model the compressive strength of natural volcanic ash mortar (VAM) by using the six-fold symmetry of concrete failure. The modeling was correlated with four parameters. To train and test the projected models, data for more than 150 samples were collected from the literature. Furthermore, mortar samples with varying proportions of volcanic ash were prepared in the laboratory and tested, and the results were used to validate the models. The performance of the developed models was assessed using numerous statistical measures. The results show that both the ANN and ANFIS models accurately predict the compressive strength of VAM with R-square above 0.9 and lower error statistics. The permutation feature analysis confirmed that the age of specimens affects the strength of VAM the most, followed by the water-to-cement ratio, curing temperature, and percentage of volcanic ash.

Published

2021

8. Modeling Compressive Strength of Eco-Friendly Volcanic Ash Mortar Using Artificial Neural Networking.

Author

Amin, Muhammad Nasir, Javed, Muhammad Faisal, Khan, Kaffayatullah, Shalabi, Faisal I., and Qadir, Muhammad Ghulam

Subjects

*VOLCANIC ash, tuff, etc., *ARTIFICIAL neural networks, *COMPRESSIVE strength, *MORTAR, *CONCRETE fatigue, *FUZZY systems

Abstract

Forecasting the compressive strength of concrete is a complex task owing to the interactions among concrete ingredients. In addition, an important characteristic of the concrete failure surface is its six-fold symmetry. In this study, an artificial neural network (ANN) and adaptive neuro fuzzy interface system (ANFIS) were employed to model the compressive strength of natural volcanic ash mortar (VAM) by using the six-fold symmetry of concrete failure. The modeling was correlated with four parameters. To train and test the projected models, data for more than 150 samples were collected from the literature. Furthermore, mortar samples with varying proportions of volcanic ash were prepared in the laboratory and tested, and the results were used to validate the models. The performance of the developed models was assessed using numerous statistical measures. The results show that both the ANN and ANFIS models accurately predict the compressive strength of VAM with R-square above 0.9 and lower error statistics. The permutation feature analysis confirmed that the age of specimens affects the strength of VAM the most, followed by the water-to-cement ratio, curing temperature, and percentage of volcanic ash. [ABSTRACT FROM AUTHOR]

Published

2021

9. ANN and ANFIS for Short Term Load Forecasting

Author

H. N. Nagraja, S. Shah, and J. Chakravorty

Subjects

Adaptive neuro fuzzy inference system, Artificial neural network, lcsh:T58.5-58.64, Computer science, neural network, lcsh:Information technology, Load forecasting, load forecasting, adaptive neuro fuzzy interface system, Term (time), Variety (cybernetics), Reliability engineering, Electric power system, lcsh:TA1-2040, Economic load dispatch, lcsh:Technology (General), lcsh:T1-995, lcsh:Engineering (General). Civil engineering (General)

Abstract

Load forecasting has become one of the major areas of research in electrical engineering. Short term load forecasting (STLF) is essential for power system planning and economic load dispatch. A variety of mathematical methods has been developed for load forecasting. This paper discusses the influencing factors of STLF and an artificial intelligence (AI) based STLF model for MGVCL load. It also includes comparison of various AI models. Our main objective is to develop the best suited model for MGVCL, by critically evaluating the ways in which the AI techniques proposed are designed and tested.

Published

2018