Genetic interference reduces the evolvability of modular and non-modular visual neural networks

The aim of this paper is to propose an interdisciplinary evolutionary connectionism approach for the study of the evolution of modularity. It is argued that neural networks as a model of the nervous system and genetic algorithms as simulative models of biological evolution would allow us to formulat...

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Bibliographic Details
Published in:Philosophical transactions of the Royal Society of London. Series B. Biological sciences 2007-03, Vol.362 (1479), p.403-410
Main Author: Calabretta, Raffaele
Format: Article
Language:English
Subjects:
'what And Where' Tasks
Animals
Architecture
Biological Evolution
Biological neural networks
Brain - physiology
Cognitive models
Connectionism
Evolution
Evolution Of Modularity
Evolutionary Connectionism
Evolutionary genetics
Genetic Algorithms
Genetic Linkage
Genetic mutation
Humans
Mind
Models, Biological
Modularity
Nature-Nurture Debate
Nerve Net - physiology
Neural Networks, Computer
Primates
Primates - genetics
Primates - physiology
Visual Perception - genetics
Visual Perception - physiology
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Summary:The aim of this paper is to propose an interdisciplinary evolutionary connectionism approach for the study of the evolution of modularity. It is argued that neural networks as a model of the nervous system and genetic algorithms as simulative models of biological evolution would allow us to formulate a clear and operative definition of module and to simulate the different evolutionary scenarios proposed for the origin of modularity. I will present a recent model in which the evolution of primate cortical visual streams is possible starting from non-modular neural networks. Simulation results not only confirm the existence of the phenomenon of neural interference in non-modular network architectures but also, for the first time, reveal the existence of another kind of interference at the genetic level, i.e. genetic interference, a new population genetic mechanism that is independent from the network architecture. Our simulations clearly show that genetic interference reduces the evolvability of visual neural networks and sexual reproduction can at least partially solve the problem of genetic interference. Finally, it is shown that entrusting the task of finding the neural network architecture to evolution and that of finding the network connection weights to learning is a way to completely avoid the problem of genetic interference. On the basis of this evidence, it is possible to formulate a new hypothesis on the origin of structural modularity, and thus to overcome the traditional dichotomy between innatist and empiricist theories of mind.
ISSN:0962-8436
1471-2970
DOI:10.1098/rstb.2006.1967