Biomedical Engineering Reference
In-Depth Information
Schöner, G., Jiang, W.Y., & Kelso, J.A.S. (1990).
A synergetic theory of quadrupedal gaits and
gait transitions.
Journal of Theoretical Biology,
142, 359-391.
Wilson, H.R. (1999).
Spikes, decisions, and ac-
tions: dynamical foundations of neuroscience
.
New York: Oxford University Press.
Winter, D.A., Prince, F., & Patla, A.E. (1998).
Stiffness control of balance during quiet standing.
Journal of Neurophysiology,
80, 1211-1221.
Stein, P.S.G. (1978). Motor systems with specific
reference to the control of locomotion.
Annual
Review of Neuroscience,
1, 61-81.
Yang, Z., & França, F.M.G. (2003). A generalized
locomotion CPG architecture based on oscilla-
tor building blocks.
Biological Cybernetics,
89,
34-42.
Taga, G., Yamaguchi, Y., & Shimizu, H. (1991).
Self-organized control of bipedal locomotion by
neural oscillators in unpredictable environment.
Biological Cybernetics,
65, 147-159.
Taga, G. (1995). A model of the neuro-mus-
culo-skeletal system for human locomotion - I.
Emergence of basic gait.
Biological Cybernetics,
73, 97-111.
ADDITIONAL READING
Alexander, R.M. (1989) Optimization and gaits
in the locomotion of vertebrates.
Physiological
Reviews,
69, 1199-1227.
Taft, R. (1955). An introduction: Eadweard Muy-
bridge and his work. In E. Muybridge (Ed.),
The
human figure in motion
(pp.7-14). New York:
Dover Publications.
Arena, P. (2000). The central pattern generator: A
paradigm for artificial locomotion.
Soft Comput-
ing - A Fusion of Foundations, Methodologies
and Applications,
4(4), 251-266.
Tsutsumi, K., & Matsumoto, H. (1984). A synaptic
modification algorithm in consideration of the
generation of rhythmic oscillation in a ring neural
network.
Biological Cybernetics,
50, 419-430.
Bucher, D., Prinz, A.A., & Marder, E. (2005).
Animal-to-animal variability in motor pattern
production in adults and during growth.
Journal
of Neuroscience,
25, 1611-1619.
Turing, A.M. (1952). The chemical basis of mor-
phogenesis.
Philosophical Transactions of the
Royal Society B,
237, 37-72.
Butt, S.J., & Kiehn, O. (2003).
Functional identi-
fication of interneurons responsible for left-right
coordination of hindlimbs in mammals.
Neuron,
38, 953-963.
Wang, X.J., & Rinzel, J. (1992). Alternating and
synchronous rhythms in reciprocally inhibitory
model neurons.
Neural Computation,
4, 84-97.
Buono, P.L. (2001). Models of central pattern
generators for quadruped locomotion.
Journal of
Mathematical Biology,
42(4), 327-346.
Webb, B. (2002). Robots in Invertebrate Neurosci-
ence.
Nature,
417, 359-363.
Cangiano, L., & Grillner, S. (2005).
Mechanisms
of rhythm generation in a spinal locomotor
network deprived of crossed connections: the
lamprey hemicord.
Journal of Neuroscience,
25, 923-935.
Webb, B. (2001). Can robots make good models
of biological behaviour?
Behavioural and Brain
Sciences,
24, 1033-1050.
Webb, B. (2004). Neural mechanisms for predic-
tion: Do insects have forward models?
Trends in
Neurosciences,
27, 278-282.
Cohen, A.H. (1992). The role of heterarchical con-
trol in the evolution of central pattern generators.
Brain, Behavior and Evolution,
40, 112-124.
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