TY - GEN
T1 - The Development of Modular Evolutionary Networks for Quadrupedal Locomotion
AU - Muthuraman, Sethuraman
AU - MacLeod, Christopher
AU - Maxwell, Grant
PY - 2003
Y1 - 2003
N2 - Artificial Neural Networks have so far failed to produce a convincing route to Robotic Intelligence. Training and Organizational Algorithms (such as Evolutionary Algorithms) are presently not flexible or sophisticated enough to configure large networks which fuse data from different sensory domains in a complex and changing environment. The approach outlined here is different in that it allows the neural network to grow, building itself up, piece by piece, from a simple to a complex form. This is accomplished by allowing the robot's body plan and environment to develop while simultaneously adding to the structure of the controlling network. Network structures from previous iterations are retained but are not retrained. Each time the robot attains a satisfactory performance with its current body plan in its current environment, complexity is increased and new networks are configured on top of the old until this more challenging system is also mastered. The biological justification for this approach is outlined. Results are presented which demonstrate the operation of the approach in the development of a quadrupedal gait for a simulated robot.
AB - Artificial Neural Networks have so far failed to produce a convincing route to Robotic Intelligence. Training and Organizational Algorithms (such as Evolutionary Algorithms) are presently not flexible or sophisticated enough to configure large networks which fuse data from different sensory domains in a complex and changing environment. The approach outlined here is different in that it allows the neural network to grow, building itself up, piece by piece, from a simple to a complex form. This is accomplished by allowing the robot's body plan and environment to develop while simultaneously adding to the structure of the controlling network. Network structures from previous iterations are retained but are not retrained. Each time the robot attains a satisfactory performance with its current body plan in its current environment, complexity is increased and new networks are configured on top of the old until this more challenging system is also mastered. The biological justification for this approach is outlined. Results are presented which demonstrate the operation of the approach in the development of a quadrupedal gait for a simulated robot.
KW - Artificial Neural Networks
KW - Evolutionary Algorithms
KW - Locomotion
KW - Modular Networks
KW - Robots
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M3 - Conference contribution
AN - SCOPUS:1542316891
SN - 0889863679
T3 - Proceedings of the IASTED International Conference on Artificial Intelligence and Soft Computing
SP - 268
EP - 273
BT - Proceedings of the IASTED International Conference on Artificial Intelligence and Soft Computing
A2 - Leung, H.
A2 - Leung, H.
T2 - Proceedings of the Seventh IASTED International Conference on Artificial Intelligence and Soft Computing
Y2 - 14 July 2003 through 16 July 2003
ER -