Showing total 5 results

1. QFC: A Parallel Software Tool for Feature Construction, Based on Grammatical Evolution.

Author

Tsoulos, Ioannis G.

Subjects

*SOFTWARE development tools, *ARTIFICIAL neural networks, *PARALLEL programming, *COMPUTATIONAL intelligence

Abstract

This paper presents and analyzes a programming tool that implements a method for classification and function regression problems. This method builds new features from existing ones with the assistance of a hybrid algorithm that makes use of artificial neural networks and grammatical evolution. The implemented software exploits modern multi-core computing units for faster execution. The method has been applied to a variety of classification and function regression problems, and an extensive comparison with other methods of computational intelligence is made. [ABSTRACT FROM AUTHOR]

Published

2022

2. A Comparison of Energy Consumption Prediction Models Based on Neural Networks of a Bioclimatic Building.

Author

Khosravani, Hamid R., Del Mar Castilla, María, Berenguel, Manuel, Ruano, Antonio E., and Ferreira, Pedro M.

Subjects

*ENERGY consumption of buildings, *ARTIFICIAL neural networks, *ELECTRIC power consumption forecasting, *GENETIC algorithms, *AUTOREGRESSIVE models

Abstract

Energy consumption has been increasing steadily due to globalization and industrialization. Studies have shown that buildings are responsible for the biggest proportion of energy consumption; for example in European Union countries, energy consumption in buildings represents around 40% of the total energy consumption. In order to control energy consumption in buildings, different policies have been proposed, from utilizing bioclimatic architectures to the use of predictive models within control approaches. There are mainly three groups of predictive models including engineering, statistical and artificial intelligence models. Nowadays, artificial intelligence models such as neural networks and support vector machines have also been proposed because of their high potential capabilities of performing accurate nonlinear mappings between inputs and outputs in real environments which are not free of noise. The main objective of this paper is to compare a neural network model which was designed utilizing statistical and analytical methods, with a group of neural network models designed benefiting from a multi objective genetic algorithm. Moreover, the neural network models were compared to a naïve autoregressive baseline model. The models are intended to predict electric power demand at the Solar Energy Research Center (Centro de Investigación en Energía SOLar or CIESOL in Spanish) bioclimatic building located at the University of Almeria, Spain. Experimental results show that the models obtained from the multi objective genetic algorithm (MOGA) perform comparably to the model obtained through a statistical and analytical approach, but they use only 0.8% of data samples and have lower model complexity. [ABSTRACT FROM AUTHOR]

Published

2016

3. Output Effect Evaluation Based on Input Features in Neural Incremental Attribute Learning for Better Classification Performance.

Author

Ting Wang, Sheng-Uei Guan, Ka Lok Man, Park, Jong Hyuk, and Hui-Huang Hsu

Subjects

*ARTIFICIAL neural networks, *MACHINE learning, *PARTICLE swarm optimization, *GENETIC algorithms, *LEARNING, *MATHEMATICAL models

Abstract

Machine learning is a very important approach to pattern classification. This paper provides a better insight into Incremental Attribute Learning (IAL) with further analysis as to why it can exhibit better performance than conventional batch training. IAL is a novel supervised machine learning strategy, which gradually trains features in one or more chunks. Previous research showed that IAL can obtain lower classification error rates than a conventional batch training approach. Yet the reason for that is still not very clear. In this study, the feasibility of IAL is verified by mathematical approaches. Moreover, experimental results derived by IAL neural networks on benchmarks also confirm the mathematical validation. [ABSTRACT FROM AUTHOR]

Published

2015

4. A General Approach in Optimization of Heat Exchangers by Bio-Inspired Artificial Intelligence Methods.

Author

Krzywanski, Jaroslaw

Subjects

*HEAT exchangers, *BIOLOGICALLY inspired computing, *ARTIFICIAL intelligence, *HEAT, *ARTIFICIAL neural networks, *FALLING films

Abstract

The paper introduces the artificial intelligence (AI) approach as a general method for the design and optimization study of heat exchangers. Genetic Algorithms (GA) and Artificial Neural Networks (ANN) are applied in the paper. An AGENN model, combining Genetic Algorithms with Artificial Neural Networks, was developed and validated against the desired data on a large falling film evaporator. A broad range of operating conditions and geometric configurations are considered in the study. Four kinds of tubes are deliberated, including plain and enhanced tubes. Different tube pass arrangements, i.e., top-to-bottom, bottom-to-top, and side-by-side, are discussed. Finally, the effects of liquid refrigerant mass flow rate, as well as the number of flooded tubes on the performance of the evaporator, are analyzed. The total heat transfer rate of the evaporator, predicted by the model, is in good agreement with the desired data; the maximum error is lower than ±3%. The highest heat transfer rate of the evaporator is 1140.01 kW and corresponds to Turbo EHP tubes, and bottom-to-top tubes pass arrangements, which guarantee the best thermal energy conversion. The presented approach can be referred to as a complementary technique in heat exchanger design procedures, besides the common rating and sizing tasks. It is an effective and alternative method for the existing approaches, considering the complexity of analytical and numerical techniques as well as the high costs of experiments. [ABSTRACT FROM AUTHOR]

Published

2019

5. GA-BP Neural Network-Based Strain Prediction in Full-Scale Static Testing of Wind Turbine Blades.

Author

Liu, Zheng, Liu, Xin, Wang, Kan, Liang, Zhongwei, Correia, José A.F.O., and De Jesus, Abílio M.P.

Subjects

*TURBINE blades, *GENETIC algorithms, *ARTIFICIAL neural networks, *WIND turbines, *CALIBRATION

Abstract

This paper proposes a strain prediction method for wind turbine blades using genetic algorithm back propagation neural networks (GA-BPNNs) with applied loads, loading positions, and displacement as inputs, and the study can be used to provide more data for the wind turbine blades' health assessment and life prediction. Among all parameters to be tested in full-scale static testing of wind turbine blades, strain is very important. The correlation between the blade strain and the applied loads, loading position, displacement, etc., is non-linear, and the number of input variables is too much, thus the calculation and prediction of the blade strain are very complex and difficult. Moreover, the number of measuring points on the blade is limited, so the full-scale blade static test cannot usually provide enough data and information for the improvement of the blade design. As a result of these concerns, this paper studies strain prediction methods for full-scale blade static testing by introducing GA-BPNN. The accuracy and usability of the GA-BPNN prediction model was verified by the comparison with BPNN model and the FEA results. The results show that BPNN can be effectively used to predict the strain of unmeasured points of wind turbine blades. [ABSTRACT FROM AUTHOR]

Published

2019