Commenced in January 2007
Frequency: Monthly
Edition: International
Paper Count: 33123
Reactive Neural Control for Phototaxis and Obstacle Avoidance Behavior of Walking Machines
Authors: Poramate Manoonpong, Frank Pasemann, Florentin Wörgötter
Abstract:
This paper describes reactive neural control used to generate phototaxis and obstacle avoidance behavior of walking machines. It utilizes discrete-time neurodynamics and consists of two main neural modules: neural preprocessing and modular neural control. The neural preprocessing network acts as a sensory fusion unit. It filters sensory noise and shapes sensory data to drive the corresponding reactive behavior. On the other hand, modular neural control based on a central pattern generator is applied for locomotion of walking machines. It coordinates leg movements and can generate omnidirectional walking. As a result, through a sensorimotor loop this reactive neural controller enables the machines to explore a dynamic environment by avoiding obstacles, turn toward a light source, and then stop near to it.Keywords: Recurrent neural networks, Walking robots, Modular neural control, Phototaxis, Obstacle avoidance behavior.
Digital Object Identifier (DOI): doi.org/10.5281/zenodo.1076922
Procedia APA BibTeX Chicago EndNote Harvard JSON MLA RIS XML ISO 690 PDF Downloads 1734References:
[1] S. Fujii and T. Nakamura, "Development of an amphibious hexapod robot based on a water strider," in Proc. 10th International Conference on Climbing and Walking Robots, pp. 135-143, 2007.
[2] A. J. Ijspeert, A. Crespi, D. Ryczko, and J. M. Cabelguen, "From swimming to walking with a salamander robot driven by a spinal cord model," Science, vol. 315, pp. 1416-1420, 2007.
[3] R. A. Brooks, "A robot that walks: emergent behaviors from a carefully evolved network," Neural Computation, vol. 12, pp. 253-262, 1989.
[4] H. Cruse, T. Kindermann, M. Schumm, J. Dean, and J. Schmitz, "Walknet-A biologically inspired network to control six-legged walking," Neural Networks, vol. 11, pp. 1435-1447, 1998.
[5] H. Kimura, Y. Fukuoka, and A. H. Cohen, "Adaptive dynamic walking of a quadruped robot on natural ground based on biological concepts," International Journal of Robotics Research, vol. 26, pp. 475-490, 2007.
[6] R. C. Arkin, K. Ali, A. Weitzenfeld, and F. Cervantes-Perez, "Behavior models of the praying matis as a basis for robotic behavior," Robotics and Autonomous Systems, vol. 32, pp. 39-60, 2000.
[7] W. G. Walter, The Living Brain, New York: Norton, 1953.
[8] P. Manoonpong, Neural Preprocessing and Control of Reactive Walking Machines: Towards Versatile Artificial Perception-Action Systems, Cognitive Technologies, Springer, 2007.
[9] P. Manoonpong, F. Pasemann, and F. Woergoetter, "Sensor-driven neural control for omnidirectional locomotion and versatile reactive behaviors of walking machines," Robotics and Autonomous Systems, doi:10.1016/j.robot.2007.07.004, 2007, in press.
[10] F. Pasemann, M. Huelse, and K. Zahedi, "Evolved neurodynamics for robot control," in Proc. European Symposium on Artificial Neural Networks, vol. 2, pp. 439-444, 2003.
[11] F. Pasemann, "Discrete dynamics of two neuron networks," Open Systems and Information Dynamics, vol. 2, pp. 49-66, 1993.
[12] M. Huelse, S. Wischmann, and F. Pasemann, "The role of non-linearity for evolved multifunctional robot behavior," in Proc. 6th International Conference on Evolvable Systems-ICES 2005, LNCS vol. 3637, pp. 108- 118, 2005.
[13] S. L. Hooper, "Central pattern generators," Current Biology, vol. 10, pp. R176-R177, 2000.
[14] P. Manoonpong, F. Pasemann, J. Fischer, and H. Roth, "Neural processing of auditory signals and modular neural control for sound tropism of walking machines," International Journal of Advanced Robotic Systems (ARS), vol. 2, no. 3, pp. 223-234.