Title :
Epistasis in Multi-Objective Evolutionary Recurrent Neuro-Controllers
Author :
Ventresca, Mario ; Ombuki-Berman, Beatrice
Author_Institution :
Syst. Design Eng., Waterloo Univ., Ont.
Abstract :
This paper presents an information-theoretic analysis of the epistatic effects present in evolving recurrent neural networks. That is, how do the gene-gene interactions change as the evolutionary process progresses from an initially random state to the final generation and does this reveal anything about the problem difficulty. Also, to what extent does the environment influence epistasis. Our investigation concentrates on multi-objective evolution, where the major task to be performed is broken into sub-tasks which are then used as our objectives. Our results show that the behavior of epistasis during the evolutionary process is strongly dependant on the environment. The experimental results are presented for the path following robot application using continuous-time and spiking neuro-controllers.
Keywords :
evolutionary computation; genetics; information theory; neurocontrollers; recurrent neural nets; continuous-time neurocontrollers; epistatic effects; evolving recurrent neural networks; gene-gene interactions; information-theoretic analysis; multiobjective evolutionary recurrent neurocontrollers; path following robot application; spiking neurocontrollers; Biological cells; Cognitive robotics; Councils; Design engineering; Evolutionary computation; Information analysis; Neural networks; Recurrent neural networks; Robot control; Systems engineering and theory; Epistasis; continuous-time; evolutionary algorithm; multi-objective; recurrent neural network; spiking;
Conference_Titel :
Artificial Life, 2007. ALIFE '07. IEEE Symposium on
Conference_Location :
Honolulu, HI
Print_ISBN :
1-4244-0701-X
DOI :
10.1109/ALIFE.2007.367781
