TY - JOUR
T1 - Preliminary experiments with ensembles of neurally diverse artificial neural networks for pattern recognition
AU - Adamu, Abdullahi
AU - Maul, Tomas
AU - Bargiela, Andrzej
AU - Roadknight, Christopher
N1 - Publisher Copyright:
© Springer International Publishing Switzerland 2015
PY - 2015
Y1 - 2015
N2 - Although there have been a few approaches to achieve the goal of fault tolerance by diversifying redundancy of the individual networks that make up a neural network ensemble, some of which include ensembles of neural networks of different sizes, and ensembles of different models of neural networks such as Radial Basis Function Networks and Multilayer Perceptron, there is yet to be an empirical study on hybrid neural networks that makes use of a diverse set of transfer functions, which we would expect to be able to exhibit diverse network architectures, and thus possibly more diverse error patterns. In this paper, we present an approach that uses transfer function diversity to achieve significant results on ensembles. The results show that even with relatively small networks having 5 hidden nodes, and a relatively small ensemble size of just 10 members, the ensemble is able to get competitive results on the Iris data set. It also capable of obtaining competitive results with 20 ensemble members of relatively small networks on other popular data sets such as the Diabetes, Sonar, Hepatitis, and Australian Credit Card problems. In addition to that, it is shown that these results can be achieved with a simple sorting and selection of the Top N solutions of the population, in contrast to other methods of selecting ensemble members that can be computationally expensive, such as selection of the Pareto-front, or hill climbing methods of selection.
AB - Although there have been a few approaches to achieve the goal of fault tolerance by diversifying redundancy of the individual networks that make up a neural network ensemble, some of which include ensembles of neural networks of different sizes, and ensembles of different models of neural networks such as Radial Basis Function Networks and Multilayer Perceptron, there is yet to be an empirical study on hybrid neural networks that makes use of a diverse set of transfer functions, which we would expect to be able to exhibit diverse network architectures, and thus possibly more diverse error patterns. In this paper, we present an approach that uses transfer function diversity to achieve significant results on ensembles. The results show that even with relatively small networks having 5 hidden nodes, and a relatively small ensemble size of just 10 members, the ensemble is able to get competitive results on the Iris data set. It also capable of obtaining competitive results with 20 ensemble members of relatively small networks on other popular data sets such as the Diabetes, Sonar, Hepatitis, and Australian Credit Card problems. In addition to that, it is shown that these results can be achieved with a simple sorting and selection of the Top N solutions of the population, in contrast to other methods of selecting ensemble members that can be computationally expensive, such as selection of the Pareto-front, or hill climbing methods of selection.
KW - Artificial neural networks
KW - Hybrid neural networks
KW - Pattern recognition
KW - Transfer function optimization
UR - http://www.scopus.com/inward/record.url?scp=84931269335&partnerID=8YFLogxK
U2 - 10.1007/978-3-319-19024-2_9
DO - 10.1007/978-3-319-19024-2_9
M3 - Article
AN - SCOPUS:84931269335
SN - 2194-5357
VL - 361
SP - 85
EP - 96
JO - Advances in Intelligent Systems and Computing
JF - Advances in Intelligent Systems and Computing
ER -