Evolution and development of neural controllers for locomotion, gradient-following, and obstacle-avoidance in artificial insects

Author

Kodjabachian, Jérôme ; Meyer, Jean-Arcady

Author_Institution

AnimatLab, Ecole Normale Superieure, Paris, France

Volume

9

Issue

5

fYear

1998

fDate

9/1/1998 12:00:00 AM

Firstpage

796

Lastpage

812

Abstract

This paper describes how the SGOCE paradigm has been used to evolve developmental programs capable of generating recurrent neural networks that control the behavior of simulated insects. This paradigm is characterized by an encoding scheme, an evolutionary algorithm, syntactic constraints, and an incremental strategy that are described in turn. The additional use of an insect model equipped with six legs and two antennae made it possible to generate control modules that allowed it to successively add gradient-following and obstacle-avoidance capacities to walking behavior. The advantages of this evolutionary approach, together with directions for future work, are discussed

Keywords

encoding; genetic algorithms; legged locomotion; neurocontrollers; path planning; recurrent neural nets; SGOCE paradigm; artificial insects; encoding; evolutionary algorithm; gradient-following; leaky integrators; legged locomotion; neurocontrol; obstacle-avoidance; recurrent neural networks; simple geometry oriented cellular encoding; syntactic constraints; Algorithm design and analysis; Animation; Artificial neural networks; Biological neural networks; Encoding; Evolutionary computation; Insects; Legged locomotion; Recurrent neural networks; Space exploration;

fLanguage

English

Journal_Title

Neural Networks, IEEE Transactions on

Publisher

ieee

ISSN

1045-9227

Type

jour

DOI

10.1109/72.712153

Filename

712153