Predicting the nonlinear dynamics of biological neurons using support vector machines with different kernels

Author

Frontzek, Thomas ; Lal, Thomas Navin ; Eckmiller, Rolf

Author_Institution

Dept. of Comput. Sci. VI, Bonn Univ., Germany

Volume

2

fYear

2001

fDate

2001

Firstpage

1492

Abstract

Based on biological data we examine the ability of support vector machines (SVMs) with Gaussian, polynomial and tanh-kernels to learn and predict the nonlinear dynamics of single biological neurons. We show that SVMs for regression learn the dynamics of the pyloric dilator neuron of the Australian crayfish, and we determine the optimal SVMs parameters with regard to the test error. Compared to conventional RBF networks and MLPs, SVMs with Gaussian kernels learned faster and performed a better iterated one-step-ahead prediction with regard to training and test error. From a biological point of view SVMs are especially better in predicting the most important part of the dynamics, where the membrane potential is driven by superimposed synaptic inputs to the threshold for the oscillatory peak

Keywords

bioelectric potentials; biomembranes; dynamics; learning (artificial intelligence); learning automata; neurophysiology; physiological models; Australian crayfish; Gaussian kernel; biological neurons; iterated one-step-ahead prediction; membrane potential; nonlinear dynamics; oscillatory peak; polynomial kernel; pyloric dilator neuron; regression; superimposed synaptic inputs; support vector machines; tanh-kernel; Biological system modeling; Biology; Filters; Kernel; Neural networks; Neurons; Radial basis function networks; Support vector machines; Testing; Time measurement;

fLanguage

English

Publisher

ieee

Conference_Titel

Neural Networks, 2001. Proceedings. IJCNN '01. International Joint Conference on

Conference_Location

Washington, DC

ISSN

1098-7576

Print_ISBN

0-7803-7044-9

Type

conf

DOI

10.1109/IJCNN.2001.939585

Filename

939585