single-jc.php

JACIII Vol.17 No.5 pp. 699-706
doi: 10.20965/jaciii.2013.p0699
(2013)

Paper:

Generating Cooperative Collective Behavior in Swarm Robotic Systems

Kazuhiro Ohkura*, Toshiyuki Yasuda*, and Yoshiyuki Matsumura**

*Graduate School of Engineering, Hiroshima University, 1-4-1 Kagamiyama, Higashi-Hiroshima 739-8527, Japan

**Faculty of Textile Science and Technology, Shinshu University, 3-15-1 Tokida, Ueda, Nagano 386-8567, Japan

Received:
April 13, 2013
Accepted:
May 21, 2013
Published:
September 20, 2013
Keywords:
swarm robotics, evolutionary robotics, topology and weight evolving artificial neural network (TWEANN), MBEANN
Abstract
Swarm robotics research involves multirobot systems that consist of many homogeneous autonomous robots but no global controller. In this paper, an evolutionary robotics approach using an artificial neural network is applied to a swarm robotic system. Conventionally, the neural network evolved using only synaptic weights under the condition of a fixed topology. Our research group has been developing a novel approach to a topology and weight evolving artificial neural network named Mutation-Based Evolving Artificial Neural Network (MBEANN). A series of computer simulations shows that MBEANN yields better results in terms of flexibility than conventional solutions to the cooperative package-pushing problem.
Cite this article as:
K. Ohkura, T. Yasuda, and Y. Matsumura, “Generating Cooperative Collective Behavior in Swarm Robotic Systems,” J. Adv. Comput. Intell. Intell. Inform., Vol.17 No.5, pp. 699-706, 2013.
Data files:
References
  1. [1] E. Şahin, “Swarm Robotics: From Sources of Inspiration to Domain of Applications,” Swarm Robotics, SAB2004 Int. Workshop, Santa Monica, CA, USA, July 2004, Revised Selected Papers, LNCS, Vol.3342, pp. 10-20, 2005.
  2. [2] T. Fukuda, and S. Nakagawa, “Approach to the Dynamically Reconfigurable Robotic System,” J. of Intelligent and Robotic Systems, Vol.1, No.1, pp. 55-72, 1998.
  3. [3] C. R. Kube and H. Zhang, “Task Modeling in Collective Robotics,” Autonomous Robots, Vol.4, No.1, pp. 53-72, Kluwer Academic, 1997.
  4. [4] H. Asama et al. (Ed.), “Distributed Autonomous Robotic Systems,” Springer-Verlag, 1995.
  5. [5] G. Beni, “From Swarm Intelligence to Swarm Robotics,” Swarm Robotics, SAB2004 Int.Workshop, LNCS, Vol.3342, pp. 1-9, 2005.
  6. [6] E. Şahin et al., “Swarm Robotics, in Swarm Intelligence – Introduction and Applications,” C. Blum and D.Merkle (Eds.), Springer, pp. 87-100, 2008.
  7. [7] M. J. Matarić, “Learning Social Behavior,” Robotics and Autonomous Systems, Vol.20, pp. 191-204, 1997.
  8. [8] I. Harvey et al., “Issues in Evolutionary Robotics,” From Animals to Animats 2: Proc. of the Second Int. Conf. on Simulation of Adaptive Behavior (SAB92), pp. 364-373, 1993.
  9. [9] I. Harvey et al., “Evolutionary Robotics: the Sussex Approach,” Robotics and Autonomous Systems, Vol.20, pp. 205-224, 1997.
  10. [10] S. Nolfi and D. Floreano, “Evolutionary Robotics,” MIT Press, 2000.
  11. [11] X. Yao, “Evolving Artificial Neural Networks,” Proc. of the IEEE, Vol.89, No.9, pp. 1423-1447, 1999.
  12. [12] D. Floreano et al., “Neuroevolution: from Architectures to Learning,” Evolutionary Intelligence, Vol.1, No.1, pp. 47-62, 2008.
  13. [13] A. E. Eiben et al., “Collective Specialization for Evolutionary Design of a Multi-Robot System,” Swarm Robotics, SAB2006 Second Int. Workshop, Revised Selected Papers, LNCS, Vol.4433, pp. 189-205, 2007.
  14. [14] M. Quinn et al., “Evolving Controllers for a Homogeneous System of Physical Robots: Structured Cooperation with Minimal Sensors,” Philosophical Trans. of The Royal Society A, Vol.361, pp. 2321-2343, 2003.
  15. [15] G. Baldassarre et al., “Evolving Mobile Robots Able to Display Collective Behaviour,” Artificial Life, Vol.9, pp. 255-267, 2003.
  16. [16] V. Trianni, “Evolutionary Swarm Robotics. Evolving Self-Organising Behaviours in Groups of Autonomous Robot,” Studies in Computational Intelligence, Vol.108, Springer Verlag, Berlin, Germany, 2008.
  17. [17] R. Gross and M. Dorigo, “Towards Group Transport by Swarms of Robot,” Int. J. of Bio-Inspired Computation, Vol.1, No.1-2, pp. 1-13, 2009.
  18. [18] E. Tuci et al., “Evolving Homogeneous Neuro-Controllers for a Group of Heterogeneous Robots: Coordinated Motion, Cooperation, and Acoustic Communication,” Artificial Life, Vol.14, No.2, pp. 157-178, 2008.
  19. [19] K. Stanley and R. Miikkulainen, “Evolving Neural Networks through Augmenting Topologies,” Evolutionary Computation, Vol.10, No.2, pp. 99-127, 2002.
  20. [20] P. J. Angeline et al., “An Evolutionary Algorithm That Constructs Recurrent Neural Networks,” IEEE Trans. on Neural Networks, Vol.5, pp. 54-65, 1994.
  21. [21] X. Yao and Y. Liu, “A New Evolutionary System for Evolving Artificial Neural Networks,” IEEE Trans. on Neural Networks, Vol.8, No.3, pp. 694-713, 1997.
  22. [22] F. Gomez and R. Miikkulainen, “Solving Non-Markovian Control Tasks with Neuroevolution,” Proc. of the Sixteenth Int. Joint Conf. on Artificial Intelligence, pp. 1356-1361, 1999.
  23. [23] N. Siebel and G. Sommer, “Reinforcement Learning of Artificial Neural Networks,” Int. J. of Hybrid Intelligent Systems, No.4, No.3, pp. 171-183, 2007.
  24. [24] K. Ohkura et al., “MBEANN: Mutation-Based Evolving Artificial Neural Networks,” Advances in Artificial Life, Proc. of the 9th European Conf. on Artificial Life, LNAI, Vol.4648, pp. 936-945, 2007.
  25. [25] K. Ohkura, Y. Matsumura, T. Yasuda, and T. Matsuda, “Evolutionary Robotics Approach to Autonomous Task Allocation for a Multi-Robot System,” Proc. of Artificial Neural Networks in Engineering 2008, Intelligent Engineering Systems Through Artificial Neural Networks, Vol.18, pp. 121-128, ASME Press, 2008.

*This site is desgined based on HTML5 and CSS3 for modern browsers, e.g. Chrome, Firefox, Safari, Edge, Opera.

Last updated on Dec. 13, 2024