Learning Motor Control of Redundant Systems

RESEARCH THESIS

Amir Karniel

References

The numbers in the square brackets after each source refers to the sections of this thesis were the source is mentioned.

Abend W, Bizzi E, Morasso P (1982) Human Arm Trajectory Formation Brain,105:331-348. [4.2.1]
Akazawa K, and Kato K (1990) Neural network model for control of muscle force based on the size principle of motor unit. Proceedings of the IEEE 78:1531-1535 [4.1.1]
Albus JS (1975) A new approach to manipulator control: The cerebellar model articulation controller(CMAC). Transactions of the ASME journal of dynamic systems, measurement and control 97:220-227 [2.2.3]
Allin J, and Inbar GF (1986) FNS parameter selection and upper limb characterization. IEEE transactions on biomedical engineering, 33:809-817 [2.3]
Anthony M, and Bartlett PL (1999) Neural network learning: Theoretical foundations. Cambridge University Press, in press. [5.4.4, 6.1.1, 6.1.3]
Arbib M.A. and Hoff B (1994) Trends in neural modeling for reach to grasp. In: from Insights into reach to grasp movement K.M.B. Bennett and U. Castiello Ed. Elsevier Science B.V. [4.2.1]
Arbib MA, Editor (1995) The handbook of brain theory and neural networks. A Bradford book, MIT press. [2.1]
Arshavsky YI, Deliagina TG, and Orlovsky GN (1997) Pattern generation. Current opinion in neurobiology. 7:781-789 [4.1.2]
Asada H, Slotin JE (1986) Robot Analysis and Control. John Wiley & Sons. [2.1.1]
Astrom KJ (1995a) Adaptive control. 2nd edition Addison-Wesley publication company. [2.2.2, 7.1.3]
Astrom KJ (1995b) Adaptive control: General methodology. In The Handbook of Brain Theory and Neural Networks. M. A. Arbib, Ed. M.I.T press, pp. 66-69. [2.2.2]
Bahill AT, Clark MR, and Stark L (1975) The main Sequence, A tool for Studying Human Eye Movements. Mathematical Biosciences 24:191-204. [4.3.1]
Baker DR, Wampler CWII (1988) On the inverse kinematics of redundant manipulators. The international journal of robotics research 7:3-21 [7.1.3]
Baker DR. (1990), Some Topological Problems in Robotics. The mathematical intelligencer Vol. 12, No. 1 [7.1.3]
Barto AG, Buckingham JT, Houk JC (1995) A predictive switching model of cerebellar movement control. NIPS 8, MIT press, pp. 138-144. [4.3.3]
Barto AG, Fagg AH, Sitkoff N, and Houk JC (1999) A cerebellar model of timing and prediction in the control of reaching. Neural Computation. 11:565-594. [2.1.5, 4.1.2, 4.3.3, 7.1.1, 7.1.4, 7.2.1]
Beer RD, Chiel HJ, Quinn RD, and Ritzmann RE (1998) Biorobotic approaches to the study of motor systems. Current opinion in neurobiology 8:777-782 [7.2.7]
Behera L, Gopal M, and Chaudhury S (1996) On Adaptive Trajectory Tracking of a Robot Manipulator Using Inversion of Its Neural Emulator. IEEE Trans. On Neural Networks 7:1401-1414. [2.2.5]
Beiser DG, Hua SE, and Houk JC (1997) Network models of the basal ganglia. Current opinion in neurobiology 7:185-190. [2.1.5]
Bekey GA (1996) Biologically inspired control of autonomous robots. Robotics and Autonomous Systems 18:21-31 [7.2.7]
Bellman R (1961) Adaptive control processes: A guided tour. Princeton university press, Princeton, New Jersey. [3.3]
Bernstein, N. (1967) The Coordination and Regulation of Movements. Pergamon Press, Oxford. [1.1, 3.3, 7.1]
Bertenthal, B. I., & von Hofsten, C. (1998). Eye, head and trunk control: The foundation for manual development. Neuroscience & Biobehavioral Reviews 22:515-520 [7.1.4]
Berthier NE (1996) Learning to Reach: A Mathematical Model. Developmental Psychology 32:811-823. [7.1.2, 7.1.4]
Berthier NE, Clifton RK, McCall DD, and Robin DJ (1999) Proximosidtal structure of early reaching in human infants. Exp. Brain Res. 127:259-269 [7.1.4]
Bertsimas D, and Tsitsiklis JN (1997) Introduction to linear optimization. Athena Scientific, Belmont, Massachusetts. [5.4.4]
Bhushan N and Shadmehr R (1999) Computational nature of human adaptive control during learning of reaching movements in force fields. Biol. Cybern. 81:39-60. [2.2.5, 7.1.2]
Bizzi E, Hogan N, Mussa-Ivaldi FA, and Giszter S (1992) Does the nervous system use equilibrium-point control to guide single and multiple joint movements? Behavioral and brain sciences 15:603-613. [4.1.3]
Bizzi E, Mussa-Ivaldi FA, and Giszter S (1991) Computations underlying the execution of movement: a biological perspective. Science, 253:287-291 [2.1.4, 7.2.1]
Bloedel JR (1992) Functional heterogeneity with structural homogeneity: How does the cerebellum operate? Behavioral and Brain Sciences 15:666-678 [2.1.5]
Brashers-Krug T, Shadmehr R, and Todorov E (1995) Catastrophic Interference in Human Motor Learning. Adv Neural Inform Proc Syst, vol 7 .pp19-26 [7.2.3]
Breiman L (1993) Hinging Hyperplanes for Regression, Classification, and Function Approximation. IEEE Transactions on Information Theory, Vol. 39, No.3. [1.4, 3.4, 5.2, 5.2.1, 5.2.2, 5.7.1, 6.3.2, 7.1.4]
Breiman L, Friedman JH (1997) Predicting multivariate responses in multiple linear regression. Journal of the Royal Statistical Society B, Vol. 59, No. 1, pp. 3-54 [7.2.3]
Brown AC, and Brengelmann GL (1970) The interaction of peripheral and central inputs in the temperature regulation system. In Physiological and Behavioral Temperature Regulation J. D. Hardy, A. P. Gagge, and J. A. J. Stolwijk, Eds. Chapter 47, pp. 684-702. [2.4.1]
Bullock D, and Grossberg S (1991) Adaptive neural networks for control of movement trajectories invariant under speed and force rescaling. Human Movement Science 10:3-53. [2.2.5]
Bullock D, Grossberg S, and Guenther FH (1993) A self-organizing neural model of motor equivalent reaching and tool use by a multijoint arm. Journal of cognitive neuroscience Vol. 4 No. 5 pp408-435 [2.2.5]
Chaudhuri P, Huang M-C, Loh W-Y and Yao R (1994) Piecewise-polynomial regession trees. Statistica Sinica 4:143-167 [7.1.3]
Chow S-C, and Shao J (1990) On the difference between the classical and inverse methods of calibration. Applied Statistics 39:219-228 [6.2.5, 7.1.4]
Cybenko G.(1989) Approximation by Superpositions of a Sigmoidal Function. Math. Control, Signals, and Systems, Vol. 2,pp. 303-314 [2.2.5]
Dean P, and Porrill J. (1998) Pseudo-inverse control in biological systems: a learning mechanism for fixation stability. Neural Networks 11:1205-1218. [7.1.3]
DeLuca CJ. and Erim Z (1994) Common drive of motor units in regulation of muscle force. TINS 17:299-305 [2.1.4, 4.1.1]
DeMers D and Kreutz-Delgado K, (1994) Canonically Parameterized Families of Inverse Kinematic Functions for Redundant Manipulators. Proc. IEEE int’l conf. robotics and automation (San Diego, May 1994). [7.1.3]
DeMers D, Kreutz-Delgado K (1998) Learning Global Properties of Nonredundant Kinematic Mappings. The international Journal of robotics research 17:547-560. [3.3.1, 7.1.3]
DeMers, DE (1993) Learning to Invert Many-To-One Mappings. Ph.D. dissertation, University of California, San Diego. [7.1.3]
Desmedt J. E. (1983) Size Principle of Motoneuron Recruitment and the Calibration of Muscle Force and Speed in Man. In: J.E.Desmedt (Ed.) Motor Control Mechanisms in Health and Disease. Raven Press. [4.1.1]
Devroye L, Gyorfi L, Lugosi G. (1996) A probabilistic theory of pattern recognition. Springer-Verlag New York Inc. [6.1.1, 6.1.3]
Draper NR, and Smith H (1998) Applied regression analysis 3rd edition. Wiley. [6.2.5]
Edelman GM (1987) Neural Darwinism. Basic Books, Inc. [2.4]
Eisenhart C (1939) The interpretation of certain regression methods and their use in biological and industrial research. Annals of Mathematical Statistics 10:162-186 [7.1.4]
Fagg AH, Barto AG, and Houk JC (1998) Learning to Reach Via Corrective Movements, Proceedings of the Tenth Yale Workshop on Adaptive and Learning Systems, New Haven, CT, June 10-12, pp. 179-185 [7.1.4]
Feldman AG, Ostry DJ, Levin MF, Gribble PL, and Mitnitski AB (1998) Recent tests of the equilibrium-point hypothesis (l model). Motor Control 2:189-205. [4.1.3]
Feldman GA, Levin MF (1995) The origin and use of positional frames of reference in motor control. Behavioral and brain sciences 18:723-806 [4.1.3]
Flash T (1995) Arm trajectory learning and control: from human to robotic arms. Proc. of IFAC Man Machine System Symposium, Cambridge, MA, 1995. [7.2.7]
Flash T, Hogan N (1985) The coordination of arm movements: an experimentally confirmed mathematical model. J. Neurosci Vol 5 No. 7: pp.1688-1703. [3.5, 4.2.1, 7.1]
Franklin GF, Powell JD, and Emami-Naeini A (1986) Feedback control of dynamic systems. Adison-Wesley. [2.2.1]
Friedman JH (1979) A tree-structured approach to nonparametric multiple regression. Smoothing techniques for curve estimation (Gasser T and Rosenbltt M Eds.) Lecture Notes in Math 757:5-22, Springer-Verlag, New York. [7.1.4]
Frolov A. and Rizek S (1995) Model of neurocontrol of redundant systems. Journal of computational and applied mathematics 63:465-473 [7.1.3]
Full JR (1994) The Importance of Mechanical Systems in Understanding Arthropod Neural Control of Locomotion. Proceedings of the Eighth Yale Workshop on Adaptive and Learning Systems:21-26 [7.1.1]
Funahashi K.(1989) On the Approximate Realization of Continuous Mappings by Neural Networks. Neural Networks, Vol 2, pp. 183-192, 1989. [2.2.5]
Gardner H (1993) Frames of mind: the theory of multiple intelligences. Basic Books New-York. [7.2.3]
Gat-Falik T, and Flash T (1999) The superposition strategy for arm trajectory modification in robotic manipulators. IEEE transactions on SMC-B 29:83-95. [7.1.2]
Georgopoulos AP, Taira M, Lukashin A (1993), Cognitive Neurophysiology of the motor cortex. Science 260:47-52. [2.1.5]
Ghahramani Z (1994) Solving inverse problems using an EM approach to density estimation. In Mozer MC, Smolensky P, Touretzky DS, Elman JL, and Weigend AS (eds) Proceedings of the 1993 connectionist models summer school pp.316-323. Erlbaum Associates. [7.1.3]
Ghahramani Z, and Wolpert DM (1997) Modular decomposition in visuomotor learning. Nature 386:392-395 [7.1.3]
Ghez C, Gordon J, Ghilardi MF, Christakos CN, Cooper SE (1990) Roles of Proprioceptive Input in the Programming of Arm Trajectories. Cold Spring Harbor Symposia on Quantitative Biology, Vol LV:837-847 [7.1.2]
Giat Y, Mizrahi J, Levine WS, and Chen Jigien (1994) Simulation of distal tendon transfer of the biceps brachii and the brachialis muscles. J. Biomechanics, 27:1005-1014 [2.1.1]
Gielen CCAM, and Houk JC (1984) Nonlinear viscosity of human wrist. Journal of Neurophysiology. 52:553-569 [4.3.2]
Gielen CCAM, and Houk JC (1987) A model of the motor servo: Incorporation nonlinear spindle receptor and muscle mechanical properties. Biol. Cybern. 57:217-231. [4.3.2]
Gielen CCAM, Vrijenhoek EJ, Flash T, and Neggers SFW (1997) Arm position constraints during pointing and reaching in 3-D space. Journal of Neurophysiology 78: 660-673. [7.2.6]
Gomi H, and Kawato M (1996) Equilibrium-point control hypothesis examined by measured arm stiffness during multijoint movement. Science vol. 272, pp. 117-120 [4.1.3, 4.2.4]
Gomi H, and Kawato M (1997) Human arm stiffness and equilibrium-point trajectory during multi-joint movement. Biol. Cybern. vol. 76, pp. 163-171. [4.2.4]
Goodman SR, and Gottlieb GL (1995) Analysis of kinematic invariances of multijoint reaching movement. Biological Cybernetics 73:311-322 [7.1.1]
Goodwin GC, and Sin KS, (1984) Adaptive Filtering Prediction and Control, Prentice-Hall. [2.2.2, 2.3.2]
Gorinevsky D and Connolly TH (1994) Comparison of some neural network and scattered data approximations: the inverse manipulator kinematics example. Neural Computation 6:521-542 [7.1.3]
Gottlieb GL (1993), A computational Model of the Simplest Motor Program. J motor behav 25:153-161 [4.2.3]
Gottlieb GL (1998) Rejecting the equilibrium-point hypothesis. Motor Control, 2:10-12. Human Kinetics Publishers, Inc. [4.1.3]
Gottlieb GL, Corcos DM, Agarwal GC (1989) Strategies for the control of voluntary movements with one mechanical degree of freedom. Behavioral and brain sciences12:189-250 [4.3.4, 7.1.1]
Gribble PL, Ostry DJ, Sanguineti V, and Laboissiere R (1998) Are Complex Signals Required for Human Arm Movement? J. Neurophysiol 79:1409-1424. [4.2.4, 7.1.1]
Grossberg S (1995) Are there universal principles of brain computation? In Mira and Sndoval (Eds) From natural to artificial neural computation, International workshop on artificial neural networks (IWANN95) proceedings, Lecture notes in computer science 930, Springer, pp. 1-6 [2.2.5]
Grossberg S (1999) The link between brain learning, attention, and consciousness. Consciousness and cognition 8:1-44 [2.2.5, 7.2.7]
Guenther FH, Barreca DM (1997) Neural models for flexible control of redundant systems. In: Morasso P and Sanguineti V (Eds) Self-organization, computational maps, and motor control. Elsevier. [7.2.4]
Gutfreund Y, Flash T, Yarom Y, Fiorito G, Segev I, and Hochner B (1996) Organization of octopus arm movements: A model system for studying the control of flexible arms. The Journal of Neuroscience. 16:7297-7307 [3.5]
Hahn GJ (1974) Regression for prediction versus regression for control. Chemtech September, pp. 574-576. [7.1.4]
Halperin M (1970) On inverse estimation in linear regression. Technometrics 12:727-736. [7.1.4]
Hannaford B, Winters JM, Chou C-P, and Marbot P-H (1995) The anthroform biorobotic arm: A system for the study of spinal circuits. Annals of Biomedical Engineering, 23:399-408. [7.2.1]
Hanneman E, Somjen G, and Carpenter DO (1965) Functional significant of cell size in spinal motoneurons. Journal of Neurophysiology 28:560-580 [4.1.1]
Hanneton S. Berthoz A, Droulez J, Slotine JJE (1997) Does the brain use sliding variables for the control of movements? Biol. Cybern. 77,381-393 [4.3.1, 7.1.2]
Harris CM, and Wolpert DM (1998) Single-dependent noise determines motor planning. Nature 394:780-784. [7.2.1]
Haykin S (1999) Neural Networks: A comprehensive Foundation. 2nd edition. Prentice Hall. [2.2.5]
Henis EA, and Flash R (1995) Mechanisms underlying the generation of averaged modified trajectories. Biol. Cybern. 72:407-419. [7.1.2]
Hill AV (1938) The heat of shortening and dynamic constants of muscle. Proc. Royal Society of London Vol. B126:136-195 [2.1.2, 4.2.2, 4.2.4, 4.3.2]
Hirayama M, Kawato M, and Jordan MI (1993) The Cascade Neural Network Model and a Speed-Accuracy Trade-Off of Arm Movement J Motor Behav 25:162-174 [7.1.2]
Hoeffding W (1963) Probability Inequalities for sums of bounded random variables. American statistical association journal. 58:13-30 [6.1.3]
Holland JH (1995) Hidden Order How Adaptation Builds Complexity. Addison-Wesley. [1.1, 3.2]
Hollerbach JM (1982) Computers, brains and the control of movement. TINS 5:189-192 [7.2.7]
Hore J, Watts S, and Vilis T (1992) Constraints on arm position when pointing in three dimensions: Donders' law and Fick gimbal strategy. Journal of neurophysiology 68:374-383 [7.2.6]
Hornik K, Stinchcombe M and White H (1989) Multilayer Feedforward Networks are Universal Approximators. Neural Networks, Vol. 2, pp. 183-192 [2.2.5]
Houk JC (1961) A mathematical model of the stretch reflex in human muscle systems. MSc Thesis. Massachusetts Institute of Technology. [2.2.1]
Houk JC, Buckingham, and Barto AG (1996) Models of the cerebellum and motor learning. Behavioral and brain sciences 19:368-383. [2.1.5]
Houk JC, Singh SP, Fisher C, and Barto AG (1990) An adaptive sensorimotor network inspired by the anatomy and physiology of the cerebellum. Chapter 13 in: Miller WT, Sutton RS, and Werbos PJ, Eds. Neural networks for control, A Bradford Book, MIT press. [4.1.2]
Houk JC, Wise SP (1992) Outline for a Theory of Motor Behavior: Involving Cooperative Actions of Cerebellum, Basal Ganglia and Cerebral Cortex. NPB Technical report 5. Aslo In Rudomin P, Arbib MA, Cervantes-Perez F, and Romo R (1993) Neuroscience: From neural networks to artificial intelligence. Springer-Verlag, pp. 452-470 [2.1.5, 4.2.3]
Hunt KJ, Sbarbaro D, Zbikowski R, and Gawthrop PJ (1992) Neural networks for control systems - A Survey. Automatica Vol 28 No 6 pp1083-1112 [2.2.5]
Hunter IW, and Kearney RE (1982) Dynamics of human ankle stiffness: variation with mean ankle torque. J. Biomechanics, vol. 15, pp. 747-752 [4.2.4]
Hush DR, and Horne B (1998) Efficient Algorithms for Function approximation with piecewise linear sigmoidal networks. IEEE transactions on neural networks 9:1129-1141. [7.1.4]
Inbar GF (1972a) Muscles spindles in muscle control II. Analysis of Muscle Servo Model. Kybernetik 11:123-129. [2.2.1]
Inbar GF (1972b) Muscle spindles in muscle control III. analysis of adaptive system model. Kybernetik, 11:130-141. [2.2.2]
Inbar GF (1996) Estimation of human elbow joint mechanical transfer function during steady state and during cyclical movements. In:Gath I & Inbar GF (eds.) Advances in Processing and Pattern Analysis of Biological Signals. Plenum Press. [4.2.4]
Inbar GF, Hsia TC, and Baskin RJ, (1970) Parameter identification analysis of muscle dynamics. Mathematical Biosciences, vol. 7, pp. 61-79 [2.3.2]
Inbar GF, Yafe A (1976) Parameter and Signal Adaptation in the Stretch Reflex Loop. In: Homma S. (Ed), Progress in brain research. Vol 44:317-337. Elsevier. [2.2.3]
Jacobs RA, and Jordan MI (1993) Learning Piecewise Control Strategies in a Modular Neural Network Architecture. IEEE transactions on systems man and cybernetics, Vol 23, No 1, pp337-345 [7.1.3]
Jacobs RA, Jordan MI, Nowlan SJ, and Hinton GE (1991) Adaptive mixture of local experts. Neural Computation. 3 79-87. [3.4, 5.3.1]
Jordan MI (1990) Motor learning and the degrees of freedom problem. In Attention and performance XIII, Jeannerod, Ed, pp. 796-836 [3.1, 7.1]
Jordan MI (1996) Computational Aspects of Motor Control and Motor Learning. In Heuer H, Keele SW (eds.) Handbook of Perception and Action Vol 2:Motor skills. [2.2.5, 6.2, 6.2.3]
Jordan MI and Jacobs RA (1995) Modular and Hierarchical Learning Systems. The Handbook of Brain Theory and Neural Networks, M.A.Arbib (Editor) .I.T press 1995 p. 579 [7.1.3]
Jordan MI, and Rumelhart DE (1992) Forward Models: Supervised Learning with Distal Teacher. Cognitive Science 16, 307-354 [2.2.5, 6.2, 6.2.4]
Jordan MI, Flash T, Arnon Y (1994) A model of the learning of arm trajectories from spatial targets. The journal of cognitive neuroscience 6:359-376. [4.2.1, 4.2.2]
Kandel ER, Schwartz JH, and Jessell TM Editors (1991) Principles of neural science 3rd edition, Elsevier, New York. [2.1, 2.1.5, 4.1.2]
Kandel ER, Schwartz JH, and Jessell TM Editors (1995) Essentials of neural science and behavior. Appleton & Lange, Norwalk, Connecticut. [2.1]
Karniel A (1996) Model of Human Motor Control Using Artificial Neural Networks. M.Sc Thesis (In Hebrew) Technion - Israel Institute of Technology. [1.4, 4.2.3]
Karniel A, and Inbar GF (1997) A Model for Learning Human Reaching-Movements. Biological Cybernetics 77:173-183 [1.4, 4.2.2, 4.2.3, 4.2.4, 7.1.4, 7.2.1]
Karniel A, and Inbar GF (1999a) The use of a nonlinear muscle model in explaining the relationship between duration, amplitude and peak velocity of human rapid movements. Journal of Motor Behavior Vol.31 No.3 pp. 203-206. [1.4]
Karniel A, and Inbar GF (1999b) Linear systems description. Chapter 21 In: Windhorst U, and Johansson H (Eds.) Modern techniques in neuroscience research. Springer-Verlag, pp. 589-625. [4.2.2, 7.1.1]
Karniel A, and Inbar GF (2000) Human Motor Control: Learning to Control a Time-Varying Non-linear Many-to-One System, to appear in IEEE transactions on Systems, Man, and Cybernetics. [1.4]
Karniel A, Meir R, and Inbar GF (1998) Polyhedral mixture of linear experts for many-to-one mapping inversion. ESANN"98 European Symposium on Artificial Neural Networks, Proceedings, Michel Verleysen Editor, D-Facto publications, Brussels. Pp 155-160. [1.4]
Karniel A, Meir R, and Inbar GF (1999) Exploiting the virtue of redundancy. IJCNN'99 International Joint Conference on Neural Networks. The proceedings in press. [1.4]
Katayama M, and Kawato M (1991) Learning trajectory and force control of an artificial muscle arm by parallel-hierarchical neural network model. Advances in neural information processing systems 3, Lippmann RP, Moody JE, and Touretzky DS (eds), MIT press pp. 436-442 [7.1.3]
Katayama M, Asada K, Zheng XZ, Yamakita M, and Ito K (1996) Self-organization of a task-oriented visuo-motor map for a redundant arm. IEEE symposium on emerging technologies and factory automation ETFA Vol. 1:302-308. [7.1.3]
Kavli T (1990) Nonuniformly Partitioned Piecewise Linear Representation of Continuous Learned Mappings. IEEE International workshop on intelligent motion control, Kaynak O. Editor IEEE Cat No:90TH0272-5 [7.1.4]
Kawato M, and Gomi H (1992) A computational model of four regions of the cerebellum based on feedback-error learning. Biol. Cybern. 68:95-103 [2.2.5, 4.2.1, 6.2, 6.2.4]
Kawato M, Furukawa K, and Suzuki R (1987) A hierarchical neural network model for control and learning voluntary movement. Biological Cybernetics 57:169-185. [2.2.5]
Kawato M, Gomi H, Katayama M, Koike Y (1992) Supervised learning for Coordinative Motor Control. Proceeding of the third NEC research symposium pp.126-161 [2.2.5]
Keifer J, Houk JC (1994) Motor Function of the Cerebellorubrospinal System. Physiological Reviews Vol. 74, No. 3. [2.1]
Kettner RE, Mahamud S, Leung H-C, Sitkoff N, Houk JC, Peterson BW, and Barto AG (1997) Prediction of complex two-dimensional trajectories by a cerebellar model of smooth pursuit eye movement. J. Neurophysiol. 77:2115-2130 [2.1.5]
Krutchkoff RG (1967) Classical and inverse regression methods of calibration. Technometrics 9:425-439 [7.1.4]
Krutchkoff RG (1969) Classical and inverse regression methods of calibration in extrapolation. Technometrics 11:605-608 [7.1.4]
Krylow AM, Rymer WZ (1997) Role of Intrinsic Muscle Properties in Producing Smooth Movements. IEEE Trans. Biomed. Eng. 44:165-176. [7.1.1]
Kwakernaak H, and Sivan R (1972) Linear Optimal Control Systems, Wiley & Sons, INC. [2.2.1]
Kwakernaak H, and Sivan R (1991) Modern signals and systems, Prentice-Hall International, Inc. [7.1.1]
Latash ML (1996) The Bernstein problem: How does the central nervous system make its choices? In Latash and Turvey (1996). Pp. 277-303. [3.5]
Latash ML and Anson JG (1996) What are "normal movements" in atypical populations? Behavioral and brain sciences 19:55-106 [3.5, 7.1]
Latash ML, and Turvey MT Eds (1996) Dexterity and its development, Erlbaum, New Jersey [1.1, 2.4, 3.1, 3.3, 3.5, 7.1, 7.1.4]
Latash ML, and Zatsiorsky VM (1993) Joint stiffness: Myth or reality? Human movement science 12:653-692. [7.2.2]
Lavrentev MM and Savelev LYA (1995) Linear Operators and Ill-Posed Problems. consultants bureau, New York. [2.2.4]
Lee JW, and Oh JH (1997) Inversion control of nonlinear systems with neural network modeling. IEEE Proc. control theory applications 144:481-487 [2.2.5, 7.1.3]
Lee S, Lee JM. (1995) Nonlinear system control based on multi-resolution radial-basis competitive and cooperative networks. Neurocomputing 9:187-206. [5.7.3, 7.1.3]
Levin AU and Narendra KS (1996) Control of nonlinear dynamic systems using neural networks - part II: observability, identification and control. IEEE transactions on neural networks, vol. 7, No. 1. [2.2.5]
Levin E, Gewirtzman R, and Inbar GF (1991) Neural network architecture for adaptive system modeling and control. Neural Networks, vol. 4, pp. 185-191. [2.2.5]
Levine WS, Ed. (1996) The control handbook, CRC press. [2.2.1, 7.1.2]
Linder T, Lugosi G, and Zeger K (1994) Rates of Convergence in the source coding theorms, in empirical quantizer design, and in universal lossy source coding. IEEE transactions on information theory 40:1728-1740 [6.1.3]
Ljung L (1994) System identification toolbox: the manual. The Mathworks Inc. 4th ed [2.3.3, 2.3.4]
Ljung L (1996) System identification. In The control handbook, W. S. Levine, Ed., CRC press Inc. 1996, pp:1033-1054. [2.3.4]
Lu B-L and Ito K (1995) Regularization of Inverse Kinematics for Redundant Manipulators Using Neural Network Inversions. IEEE International conference on neural networks proceedings, pp 2726-2731. [7.1.3]
Lu B-L, Kita H, and Nishikawa Y (1997) Inverting Feedforward Neural Networks Using Linear and Nonlinear Programming. BMC Technical Report BMC TR-97-12. Bio-Mimetic Control Research Center The Institute of Physical and Chemical Research (RIKEN), Japan. [2.2.5]
Luenberger DG (1984) Linear and Nonlinear Programming Addisom-Wesley. [5.4.2]
Marr D. (1969) A theory of cerebellar cortex. J. Physiol. 202:437-470 [2.1.5]
Massone LLE (1995) Sensorimotor Learning. In The Handbook of Brain Theory and Neural Networks, M.A.Arbib (Editor) .I.T press 1995 p. 860 [6.2]
Massone LLE, Myers JD (1996) The Role of Plant Properties in Arm Trajectory Formation: A Neural Network Study. IEEE Trans. Sys. Man. Cybern. B:26:719-732 [4.2.2]
Matthews PBC (1988) Proprioceptors and their contribution to somatosensory mapping: complex messages require complex processing. Can. J. physiol. pharmacol. Vol 66 Pp. 430-438 [2.1.3]
McDonald PV, REA van Emmerik, and KM Newell (1989) The Effects of Practice on Limb Kinematics in a Throwing Task. Journal of Motor Behavior 21:245-264 [7.1.4]
McFarland D, and Bosser T (1993) Intelligent behavior in animals and robots. MIT press. [7.2.7]
McRuer DT, Magdaleno RE, and Moore GP (1968) A neuromuscular actuation system model. IEEE trans. Man-Machine Systems, vol. 9, pp. 61-71 [2.1.2, 2.1.3, 2.2.1, 2.3, 2.3.3]
Miao Y and Hua Y (1995) Generalized inverse computations using two-layer feedforward neural networks with pruning. Proceedings of the IEEE international conference on neural networks. 3154-3158 [2.2.5]
Milgram P, and Inbar GF (1976) Distortion suppression in neuromuscular information transmission due to interchannel dispersion in muscle spindle firing thresholds. IEEE transactions on biomedical engineering, vol. 23, pp. 1-15, 1976. [2.1.3, 2.4.2]
Miller WT, Sutton RS, and Werbos PJ, Eds. (1990) Neural networks for control, A Bradford Book, MIT press. [2.2.5, 6.2]
Miyamoto H, Schaal S, Gandolfo F, Gomi H, Koike Y, Osu R, Nakano E, Wada Y, and Kawato M (1996) A Kendama learning robot based on bi-directional theory. Neural Networks, 9:1281-1302 [7.2.7]
Murray JM, and Weber A (1974) The Cooperative Action of Muscle Proteins. Scientific American 230:59-69 [2.1.1]
Murray-Smith R, and Johansen TA (Eds) (1997) Multiple Model Approaches to Modelling and Control. Taylor&Francis Ltd, London. [7.1.3]
Mussa-Ivaldi FA, and Bizzi E (1995) The modular organization of motor control: What frogs can teach us about adaptive learning. IFAC Man-Machine Systems, Cambridge, Massachusetts, USA 1995. [7.2.1]
Mussa-Ivaldi FA, Giszter SF, and Bizzi E (1994) Linear combinations of primitives in vertebrate motor control. Proc. Natl. Acad. Sci. USA 91:7534-7538 [2.1.4]
Narendra KS (1995) Adaptive Control: Neural Network Applications. The Handbook of Brain Theory and Neural Networks, M.A.Arbib (Editor) .I.T press 1995 p.69 [2.2.5]
Narendra KS, and Balakrishnan J (1997) Adaptive Control Using Multiple Models. IEEE trans. On automatic control 42:171-187 [2.4, 7.1.3]
Narendra KS, and Parthasarathy K (1990) Identification and control of dynamical systems using neural networks. IEEE transuction on neural networks. Vol. 1. No. 1. [6.2]
Neilson PD (1993) The problem of redundancy in movement control: The adaptive model theory approach, Psychological Research 55:99-106 [3.3.1]
Noble B, and Daniel JW (1988) Applied linear algebra, third edition, Prentice-hall international INC. [5.6]
Paiss O, and Inbar GF, (1987) Autoregressive modeling of surface EMG and its spectrum with application to fatigue. IEEE transactions on biomedical engineering, vol. 34, pp. 761-770 [2.3.4]
Penrose R (1994) Shadows of the mind. Oxford university press. [7.2.7]
Plamondon R (1995) A kinematc theory of rapid human movements Part I. Movement representation and generation. Biological Cybernetics 72:295-307 [4.3.1, 7.1.1]
Porat B (1994) Digital processing of random signals: theory and methods, Prentice-Hall, Inc, New Jersey [2.3.3, 2.3.4, 7.1.1]
Potkonjak V, Popovic M, Lazarevic M, and Sinanovic J (1998) Redundancy problem in writing: from human to antropomorphic robot arm. IEEE transactions on system man and cybernetics B28:790-805 [7.1]
Psaltis D, Sideris A, and Yamamura AA (1988) A multilayered neural network controller. IEEE control systems magazine April 1988 pp. 17-21 [6.2]
Pucar P, and Sjoberg J (1998) On the Hinge-Finding Algorithm for Hinging Hyperplanes. IEEE Transactions on Information Theory. 44:1310-1319 [5.2, 5.2.1, 5.2.2, 7.1.4]
Ritter H, Martinetz T, and Schulten K (1992) Neural Computation and Self-Organizing Maps. Addison-Wesley [2.1.5, 2.2.5]
Robertson EM and Miall RC (1997) Multi-joint limbs permit a flexible response to unpredictable events. Exp. Brain. Res. 117:148-152. [7.2.4]
Robinson DA (1964) The Mechanics of Human Saccadic Eye Movement. J. Physiol 174:245-264. [3.5, 4.3.1]
Rosenbaum DA. (1991) Human Motor Control. Academic Press, Inc. [2.1]
Rumelhart DE, Hinton GE, and Williams RJ(1986) Learning internal representations by error propagation. In Parallel distributed processing: VOl 1, 318-363. Cambridge, MA: MIT Press. [2.2.5]
Ryan TP (1997) Modern Regression Methods. Wiley. [6.2.5]
Santina SM, Stubberud AR, and Hostetter GH (1996) Discrete-time equivalents to continuous-time systems. In Levine (1996) pp. 265-279. [2.3.3]
Schaal S (1999) Is imitation learning the way to humanoid robots?. Trends in cognitive sciences 3:233-242 [7.2.7]
Schapire RE, Singer Y (In press) Improved boosting algorithm using confidence-rated predictions. Machine Learning, to appear. [7.1.4]
Schweighofer N, Arbib MA, and Kawato M (1998a) Role of the cerebellum in reaching quickly and accurately. I. Inverse dynamics control. European Journal of Neuroscience 10:86-94. [2.1.5]
Schweighofer N, Spoelstra J, Arbib MA, and Kawato M (1998b) Role of the cerebellum in reaching quickly and accurately. II. A detailed model of the intermediate cerebellum. European Journal of Neuroscience 10:95-105. [2.1.5]
Searle JR (1998) How to study consciousness scientifically. Brain research review 26:379-387 [7.2.7]
Shadmehr R (1995) Equilibrium point hypothesis. The Handbook of Brain Theory and Neural Networks, M.A.Arbib (Editor) .I.T press 1995 p. 370 [4.1.3]
Shadmehr R, Brashers-Krug T, and Mussa-Ivaldi F. (1995) Interference in Learning Internal Models of Inverse Dynamics in Humans. Adv Neural Inform Proc Syst, vol 7 1995.pp1117-1124 [7.2.3]
Shamma JS, and Athans M (1990) Analysis of gain scheduled control for nonlinear plants. IEEE transactions on automatic control. 35:898-907 [7.1.3]
Shimkin N, and Feuer A (1987) Persistency of excitation in continuous-time systems. Systems & Control Letters 9:225-233 [2.2.2]
Siegelmann HT (1999) Neural networks and analog computation: Beyond the Turing limit. Birkhauser, Boston. [7.2.7]
Sjoberg J, Zhang Q, Ljung L, Benveniste A, Delyon B, Glorennec PY, Hjalmarsson H, and Juditsky A (1995) Nonlinear black-box modeling in system identification: a unified overview, Automatica, vol.31, no.12, p. 1691-724 [2.3.1, 2.3.4]
Soechting JF and Flanders M (1995) Psychophysical approaches to motor control. Current Opinion in Neurobiology, 5:742-748 [7.2.6]
Soechting JF, CA Buneo, U Herrmann, M Flannders (1995) Moving Effortlessly in three dimensions: Does Donders’ law apply to arm movements? , The journal of neuroscience, 15(9):6271-6280 [7.2.6]
Sontag ED (1981) Nonlinear Regulation: The piecewise Linear Approach. IEEE Transactions on automatic control Vol AC-26,No. 2,pp. 346-357 [7.1.3]
Sontag ED (1992) Feedback Stabilization Using Two-Hidden-Layer Nets. IEEE Transactions on neural networks, Vol. 3, No. 6, November. [2.2.5, 5.3.3]
Stroeve S (1998) Neuromuscular control of arm movements: A modelling approach. PhD thesis. Department of Mechanical Engineering and Marine technology of Delft University of Technology, Delft, The Netherlands. [2.2.5]
Sutton RS, Barto AG (1998) Reinforcement Learning : An Introduction. MIT press [7.1.4]
Taylor JG (1999) Neural networks for consciousness. International joint conference on neural networks, IJCNN'99, Washington DC July 10-16. [7.2.7]
Tononi G, Sporns O, and Edelman GM (1999) Measures of degeneracy and redundancy in biological networks. Proc. Natl. Acad. Sci. USA 96:3257-3262 [2.4, 3.3.1, 7.2.4]
Tresch MC, Saltiel P, and Bizzi E (1999) The construction of movement by the spinal cord. Nature neuroscience Vol. 2, No. 2, pp. 162-167. [7.2.1]
Turing AM (1950) Computing Machinery and Intelligence. In Mind, A Quarterly Review of Psychology and Philosophy. Vol. LIX. No. 236. [7.2.7]
Vidyasagar M (1997) A theory of learning and generalization. Springer-Verlag, London [6.1.1, 6.1.3]
Walter J (1997) Rapid Learning in Robotics, PhD thesis. [7.1.3]
Walter J and Ritter H (1996) Rapid learning with parameterized self-organizing maps. Neurocomputing 12:131-153. [7.1.3]
Werbos PJ (1989) Backpropagation and neurocontrol: A review and prospectus. Proceedings of the International Joint Conference on Neural Networks (IJCNN'89) Vol.1. pp. 209-216. [2.2.5]
Widrow B, McCool JM, Medoff BP (1979) Adaptive Control by inverse modeling. In Twelfth Asilomar Conference on Circuits, Systems, and Computers. [2.2.3]
Wilkie D.R. (1956) The Mechanical Properties of Muscle. Brit.Med.Bull. 12:177-182 [2.1.2]
Wilson F. R. (1998) The Hand. Random House. [7.2.4]
Winters JM, Stark L (1987) Muscle Models: What is Gained and What is Lost by Varying Model Complexity. Byol. Cybern. 55:403-420 [2.1.2, 4.3.2]
Wolpert DM (1997) Computational approaches to motor control. Trends in cognitive sciences 1:209-216 [7.1.3]
Wolpert DM, Kawato M (1998) Multiple paired forward and inverse models for motor control. Neural Networks 11:1317-1329 [2.3, 2.4, 7.1.3]
Wolpert DM., Ghahramani Z, and Jordan MI (1995) An Internal Model for Sensorimotor Integration. Science Vol 269, 29 September 1995 pp 1880-1882 [7.1.2, 7.1.3]
Wu C, Houk JC, Young KY and Miller LE (1990) Nonlinear Damping of Limb Motion. In Winters JM and Woo SL-Y (Eds) Multiple Muscle Systems. Springer-Verlag: 214-235 [4.2.4, 4.3.2]
Yoshikawa T (1984) Analysis and control of robot manipulators with redundancy. In: Brady et al. Eds. Robotics research MIT press. [7.1.3]
Zangemeister WH, Lehman S, Stark L (1981) Simulation of head movement trajectories: Model and fit to main sequence. Biol. Cybern. 41:19-32 [4.2.2]
Zatsiorsky VM (1997) On muscle and joint viscosity. Motor Control 1:299-308 [7.2.2]
Zatsiorsky VM, Li Z, Latash ML (1998) Coordinated force production in multi-finger tasks: finger interaction and neural network modeling. Biol. Cybern. 79:139-150 [2.4]
Zeevi A, Meir R, and Maiorov V (1998) Error bounds for functional approximation and estimation using mixture of experts. IEEE transactions on information theory 44:1010-1025. [6.1.1]