This paper summaries basic principles and concepts of
intelligent controls, implemented in humanoid robotics as well as
recent algorithms being devised for advanced control of humanoid
robots. Secondly, this paper presents a new approach neuro-fuzzy
system. We have included some simulating results from our
computational intelligence technique that will be applied to our
humanoid robot. Subsequently, we determine a relationship between
joint trajectories and located forces on robot-s foot through a
proposed neuro-fuzzy technique.
[1] D. J. Todd, Walking Machines : An introduction to legged robot. New
York: Chapmen and Hall, 1985.
[2] M. H. Raibert, Legged Robots That Balance. Cambridge, Massachusetts
: The MIT Press, 1986.
[3] S. Kajita and K. Tani, "Experimental Study of Biped Dynamic
Walking," in 1995 IEEE Int. Conf. on Robotics and Automation, pp. 13-
19.
[4] H. Kazuo, H. Masato, H. Yuji and T. Toru, "The Development of Honda
Humanoid Robot," in Conf. Rec. 1998 IEEE Int. Conf. on Robotics &
Automation, pp. 1321-1326.
[5] M. Vokobratovic, B. Borovac,D. Surla and, D. Stokic, Biped
Locomotion: Dynamics, Stability, Control and Application, Springer-
Verlag, 1990.
[6] N. Suwantep, "Design for Dynamics Stability of a Humanoid
Mechanism," M.S. thesis, Dept. Mechanical. Eng., King Mongut-s
University of Thonburi., Bangkok, Thailand, 2002.
[7] W. T. Miller, "Real-Time Neural Network Control of a Biped Walking
Robot," IEEE Control Systems Magazine, pp. 41-48, February. 1994.
[8] C. L. Shih, W. A. Gruver, and T.T Lee, "Inverse kinematics and inverse
dynamics for control of a biped walking machine," in 1993 Journal
Robotic System, Vol., 10, no 4, pp. 531-555.
[9] Murakami, E. Yamamoto and K. Fujimoto, "Fuzzy control of dynamic
biped walking robot," in Conf. Rec. 1995 IEEE Int. Conf. Fuzzy system,
pp. 77-82.
[10] J. H. Park and Y. K. Rhee, "ZMP trajectory generation for reduced trunk
motions of biped robots," in Conf. Rec. 1998 IEEE Int. Conf. on
Robotics and Automation, pp. 2014-2021.
[11] O. Bebek and K. Erbatur, "A fuzzy system for gait adaptation of biped
walking robots," in Conf. Rec. 2003 IEEE Int. Conf. on Control
Applications, pp. 669-674.
[12] H. Wongsuwarn and D. Laowattana, "Bipedal Gait Synthesizer Using
Adaptive Neuro-fuzzy Network", in the First Asia International
Symposium on Mechatronics (AISM 2004), Xi'an, China, September,
27-30, 2004.
[13] D. Kim, S. J. Seo and G. T. Park, "Zero moment point trajectory
modeling of a biped walking robot using an adaptive neuro-fuzzy
system," IEE Proc. Control Theory Application, vol. 152, pp. A-B, July
2005.
[14] H. Wongsuwarn and D. Laowattana, "Experimental Study for FIBO
Humanoid Robot," in Conf. Rec. 2006 IEEE Int. Conf. Robotics,
Automation and Mechatronics (accepted).
[15] T. Takagi and M. Sugeno, "Fuzzy identification of systems and its
application to modeling and control," IEEE Trans. SMC, vol. , pp. 116-
132, 1985.
[16] R. Babuska, "Neuro-fuzzy methods for modeling and identification," in
Recent Advances in intelligent Paradigms and Application, pp. 161-186,
Springer-Verlag, 2002.
[1] D. J. Todd, Walking Machines : An introduction to legged robot. New
York: Chapmen and Hall, 1985.
[2] M. H. Raibert, Legged Robots That Balance. Cambridge, Massachusetts
: The MIT Press, 1986.
[3] S. Kajita and K. Tani, "Experimental Study of Biped Dynamic
Walking," in 1995 IEEE Int. Conf. on Robotics and Automation, pp. 13-
19.
[4] H. Kazuo, H. Masato, H. Yuji and T. Toru, "The Development of Honda
Humanoid Robot," in Conf. Rec. 1998 IEEE Int. Conf. on Robotics &
Automation, pp. 1321-1326.
[5] M. Vokobratovic, B. Borovac,D. Surla and, D. Stokic, Biped
Locomotion: Dynamics, Stability, Control and Application, Springer-
Verlag, 1990.
[6] N. Suwantep, "Design for Dynamics Stability of a Humanoid
Mechanism," M.S. thesis, Dept. Mechanical. Eng., King Mongut-s
University of Thonburi., Bangkok, Thailand, 2002.
[7] W. T. Miller, "Real-Time Neural Network Control of a Biped Walking
Robot," IEEE Control Systems Magazine, pp. 41-48, February. 1994.
[8] C. L. Shih, W. A. Gruver, and T.T Lee, "Inverse kinematics and inverse
dynamics for control of a biped walking machine," in 1993 Journal
Robotic System, Vol., 10, no 4, pp. 531-555.
[9] Murakami, E. Yamamoto and K. Fujimoto, "Fuzzy control of dynamic
biped walking robot," in Conf. Rec. 1995 IEEE Int. Conf. Fuzzy system,
pp. 77-82.
[10] J. H. Park and Y. K. Rhee, "ZMP trajectory generation for reduced trunk
motions of biped robots," in Conf. Rec. 1998 IEEE Int. Conf. on
Robotics and Automation, pp. 2014-2021.
[11] O. Bebek and K. Erbatur, "A fuzzy system for gait adaptation of biped
walking robots," in Conf. Rec. 2003 IEEE Int. Conf. on Control
Applications, pp. 669-674.
[12] H. Wongsuwarn and D. Laowattana, "Bipedal Gait Synthesizer Using
Adaptive Neuro-fuzzy Network", in the First Asia International
Symposium on Mechatronics (AISM 2004), Xi'an, China, September,
27-30, 2004.
[13] D. Kim, S. J. Seo and G. T. Park, "Zero moment point trajectory
modeling of a biped walking robot using an adaptive neuro-fuzzy
system," IEE Proc. Control Theory Application, vol. 152, pp. A-B, July
2005.
[14] H. Wongsuwarn and D. Laowattana, "Experimental Study for FIBO
Humanoid Robot," in Conf. Rec. 2006 IEEE Int. Conf. Robotics,
Automation and Mechatronics (accepted).
[15] T. Takagi and M. Sugeno, "Fuzzy identification of systems and its
application to modeling and control," IEEE Trans. SMC, vol. , pp. 116-
132, 1985.
[16] R. Babuska, "Neuro-fuzzy methods for modeling and identification," in
Recent Advances in intelligent Paradigms and Application, pp. 161-186,
Springer-Verlag, 2002.
@article{"International Journal of Information, Control and Computer Sciences:63676", author = "Hataitep Wongsuwarn and Djitt Laowattana", title = "Neuro-Fuzzy Algorithm for a Biped Robotic System", abstract = "This paper summaries basic principles and concepts of
intelligent controls, implemented in humanoid robotics as well as
recent algorithms being devised for advanced control of humanoid
robots. Secondly, this paper presents a new approach neuro-fuzzy
system. We have included some simulating results from our
computational intelligence technique that will be applied to our
humanoid robot. Subsequently, we determine a relationship between
joint trajectories and located forces on robot-s foot through a
proposed neuro-fuzzy technique.", keywords = "Biped Robot, Computational Intelligence, Static and
Dynamic Walking, Gait Synthesis, Neuro-Fuzzy System.", volume = "2", number = "3", pages = "940-7", }
