Information Technology Reference
In-Depth Information
95. I.K. Kominis, Quantum Zeno effect explains magnetic-sensitive radical-ion-pair reactions.
Phys.Rev.E
80
, 056115 (2009)
96. B. Kosko,
Neural Networks and Fuzzy Systems: A Dynamical Systems Approach to Machine
Intelligence
(Prentice Hall, Englewood Cliffs, 1992)
97. T. Kurikawa, K. Kaneko, Learning to memorize input-output mapping as bifurcation in neural
dynamics: relevance of multiple time-scales for synaptic changes. Neural Comput. Appl.
31
,
725-734 (2012)
98. K. Kushima, Y. Kawamura, J. Imura, Oscillation analysis of coupled piecewise affine systems:
Application to spatio-temporal neuron dynamics. Automatica
47
, 1249-1254 (2011)
99. M. Lankarany, W.P. Zhu, M.N.S. Swamy, Parameter estimation of Hodgkin-Huxley neuronal
model using the dual Extended Kalman Filter, in
IEEE ISCAS 2013 International Symposium
on Circuits and Systems
, Beijing, 2013
100. N. Lambert, Y.N. Chen, Y.C. Cheng, C.M. Li, G.Y. Chen, Franco Nori Nat. Phys.
9
, 10-18
(2013)
101. B. Laroche, P. Martin, N. Petit,
Commande par platitude: Equations différentielles ordinaires
et aux derivées partielles
(Ecole Nationale Supérieure des Techniques Avancées, Paris, 2007)
102. B. Laroche, D. Claude, Flatness-based control of PER protein oscillations in a Drosophila
model. IEEE Trans. Automat. Contr.
49
(2), 175-183 (2004)
103. B. Lautrup, R. Appali, A.D. Jackson, T. Heimburg, The stability of solitons in biomembranes
and nerves. Eur. Phys. J. E
34
(57), 1-9 (2011)
104. J.C. Leloup, D. Gonze, A. Goldbeter, Computational models for circadian rythms: determin-
istic versus stochastic approaches, in
Computational Systems Biology
ed. by A. Kriete, R. Eils
(Elsevier, San Diego, 2006)
105. F.A. Lévi, The Circadian timing system: a coordinator of life processes. IEEE Eng. Med. Biol.
Mag. (2008)
106. J.H. Lee, A. Sancar, Circadian clock disruption improves the efficacy of chemotherapy
through p73-mediated apoptosis, in
Proceedings of the National Academy of Sciences
, 2011
107. V.S. Letokhov,
Laser Control of Atoms and Molecules
(Oxford University Press, Oxford,
2007)
108. H. Levine, W.J. Rappel, Self-organization in systems of self-propelled particles. Phys. Rev. E
63
, 2000
109. J. Lévine, On necessary and sufficient conditions for differential flatness. Appl. Algebra Eng.
Commun. Comput.
22
(1), 47-90 (2011)
110. J. Lévine, D.V. Nguyen, Flat output characterization for linear systems using polynomial
matrices. Syst. Control Lett.
48
, 69-75 (2003)
111. Z. Li, L. Liu, Uncertainty principles for Sturm-Liouville operators. Constr. Approx.
21
, 195-
205 (2005)
112. H.Y. Li, Y.K. Wang, W.L. Chan, The asymptotic structure of the Morris-Lecar models.
Neurocomputing
74
, 2108-2113 (2011)
113. X. Liao, K.W. Wong, Z. Wu, Bifurcation analysis of a two-neuron system with distributed
delays. Physica D
149
, 123-141 (2001)
114. M.
Loh,
E.T.
Rolls,
G.
Deco,
Statistical
fluctuation
in
attractor
networks
related
to
Schizophrenia. Pharmacopsychiatry
40
, 78-84 (2007)
115. M. Loh, E.T. Rolls, G. Deco, A dynamical systems hypothesis of Schizophrenia. PLoS
Comput. Biol.
3
(11), 1-11 (2007)
116. M. Lysetskiy, J.M. Zurada, Bifurcating neuron: computation and learning. Neural Netw.
17
,
225-232 (2004)
117. L. Ma, K. Khorasani, Application of adaptive constructive neural networks to image
compression. IEEE Trans. Neural Netw.
13
(5), 1112-1125 (2002)
118. L. Ma, K. Khorasani, Constructive feedforward neural networks using hermite polynomial
activation functions. IEEE Trans. Neural Netw.
16
(4), 821-833 (2005)
119. S. Mallat,
A Wavelet Tour of Signal Processing
(Academic, San Diego, 1998)
120. G. Mahler, V.A. Weberuss,
Quantum Networks: Dynamics of Open Nanostructures
(Springer,
New York , 1998)
