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References
Abdusamatov, R. M., Feldman, A. G., Berkinblit, M. B. & Chernavsky, A. V. (1985) One-joint movement control: A mathematical model and Computer simulation exhibiting electromyographic patterns. In: Motor Control “85,” 5th International Symposium, Varna, Bulgaria, 06 10–15. [rMBB]Google Scholar
Abend, W., Bizzi, E. & Morasso, P. (1982) Human arm trajectory formation. Brain105:331–48. [taMBB]CrossRefGoogle ScholarPubMed
Abraham, R. H. & Shaw, C. D. (1982) Dynamics – The geometry of behavior. Aerial. [KGM]Google Scholar
Abrahams, V. C., Richmond, F. & Rose, P. K. (1975) Absence of monosynaptic reflex in dorsal neck muscles of the cat. Brain Research92:130–31. [GEL]CrossRefGoogle ScholarPubMed
Adamovich, S. V., Boiko, M. I., Burlachkova, N. I. & Feldman, A. G. (1985) Central formation of fast movements in man. In: Motor Control “85,” 5th International Symposium, Varna, Bulgaria, 06 10–15. p. 24. [rMBB]Google Scholar
Adamovich, S. V., Burlachkova, N. I. & Feldman, A. G. (1984) Wave nature of the central process of formation of the trajectories of change in the joint angle in man. Biophysics29:130–34 (Biofizika 29:122–25). [GCA, tarMBB, RAS]Google Scholar
Adamovich, S. V. & Feldman, A. G. (1984) Model of the central regulation of the parameters of motor trajectories. Biophysics29:338–42. (Biofizika:306–9). [GCA, taMBB, RAS]Google Scholar
Akazawa, K., Aldridge, J. W., Sleeves, J. D. & Stein, R. B. (1982) Modulation of stretch reflexes during locomotion in the mesencephalic catJournal of Physiology329:553–67. [ WDC]Google Scholar
Akazawa, K., Milner, T. E. & Stein, R. B. (1983) Modulation of reflex emg and stiffness in response to stretch of human finger muscle. Journal of Neurophysiology49:16–27. [CC]CrossRefGoogle ScholarPubMed
Alexander, R. McN. (1981) Mechanics of skeleton and tendons. In: Handbook of phsiology – The nervous system, ed. Brooks, V. B.. American Physiology Society. [LDP]Google Scholar
Allan, D. G. C. & Schofield, R. E. (1980) Stephen Hales: Scientist and philanthropist. Oxford University Press. [ESR]Google Scholar
Anderson, O. & Grillner, S. (1981) Peripheral control of the cat's step cycle: I. Phase dependent effects of ramp-movements of the hip during “fictive locomotion.”Acta Physiologica Scandinavica113:89–101. [taMBB, ZH]Google Scholar
Anderson, O. & Grillner, S. (1983) Peripheral control of the cat's step cycle: II. Entrainment of the central pattern generators for locomotion by sinusoidal hip movements during “fictive locomotion.”Acta Physiologica Scandinavica118:229–39. [ZH]CrossRefGoogle Scholar
Anokhin, P. K. (1975) Essays on the physiology of functional systems. Moscow: Medicina (in Russian). [ESR]Google Scholar
Arshavsky, Yu. I., Beloozerova, I. N., Orlovsky, G. N., Pavlova, G. A. & Panchin, Yu. V. (1984) Activity of motoneurons during generation of locomotor rhythm in Clione limaciner. Neirofiziologia16:117–22. [taMBB]Google Scholar
Asatryan, D. G. & Feldman, A. G. (1965) Functional tuning of the nervous system with control of movement or maintenance of a steady posture. I. Mechanographic analysis of the work of the lint on execution of a postural task. Biophysics10:925–35 (Biofizika 10:837–46). [taMBB, RME, CLG]Google Scholar
Bakker, J. G. M. & Crowe, A. (1982) Multicyclic scratch reflex movements in the terrapin Pseudemys scripta elegans. Journal of Comparative Physiology145:477–84. [taMBB]Google Scholar
Baldissera, F., Hultborn, H. & Illert, M. (1981) Integration in spinal neuronal systems. In: Handbook of physiology. Sect. 1: The nervous system, vol. 2, part 1. American Physiological Society. [PDN]Google Scholar
Baranov, V. V., Berlov, S. P., Matuhin, V. I., Pozin, N. V., Sverdlov, S. S., Sveshnikov, V. A. & Filimonov, P. M. (1973) The structure of instinctive building behavior in stream larvae Oligostomis reticulata. Herald of Moscow University6:3–13. [taMBB]Google Scholar
Barlow, G. W. (1968) Ethiological units of behavior. In: The central nervous system and fish behavior, ed. Ingle, D.. University of Chicago Press. [WHE]Google Scholar
Barlow, G. W. (1977) Modal action patterns. In: How animals communicate, ed. Sebeok, T. A.. Indiana University Press. [WHE]Google Scholar
Bässler, U. (1976) Reversal of a reflex to a single motoneuron in the stick insect Carausius morosus. Biological Cybernetics24:47–79. [ZH]Google Scholar
Bellman, K. L. & Goldberg, L. S. (1984) Common origin of linguistic and movement abilities. American Journal of Physiology15:R915–R921. [MLL]Google Scholar
Bentley, D. R. (1969) Intracellular activity in cricket neurons during the generation of behavior patterns. Journal of Insect Physiology15:667–99. [taMBB]Google Scholar
Berkinblit, M. B., Gelfand, I. M. & Feldman, A. G. (1986) A model for the control of multi-joint movements. Biofizika31:728–38. [rMBB]Google Scholar
Berkinblit, M. B., Zharkova, I. S., Feldman, A. G. & Fukson, O. I. (1984) Biomechanical singularities of wiping reflex cycle. Biofizika29:483–88. [taMBB]Google Scholar
Bernstein, N. A. (1947) On the construction of movements. Moscow. In Russian. [taMBB]Google Scholar
Bernstein, N. A. (1967) The co-ordination and regulation of movements. Pergamon. [taMBB, MTT]Google Scholar
Bernstein, N. A. (1975) Bewegungsphysiologie, ed. Pickenhain, L. & Schnabel, G.. Barth. [ESR]Google Scholar
Bernstein, N. A. (1984) Human motor actions: Bernstein re-assessed, ed. Whiting, H. T. A.. North-Holland. [ESR]Google Scholar
Berridge, K. C. & Fentress, J. C. (in press) Contextual control of trigeminal sensorimotor function. Journal of Neuroscience. [JCF]Google Scholar
Bethe, A. (1930) Studien über die Plastizität des Nervensystems. I. Arachnoideen und Crustaceen. Archiv für die gesamte Physiologie224:793–20. [RJ]Google Scholar
Bethe, A. (1933) Die Plastizität (Anpassungsfähigkeit) des Nervensystems. Naturwissenschaften21:214–21. [RJ]Google Scholar
Bilo, D. & Bilo, A. (1983) Neck flexion related activity of flight control muscles in the flow-stimulated pigeon. Journal of Comparative PhysiologyA153:111–22. [taMBB]Google Scholar
Bizzi, E. (1980) Central and peripheral mechanisms in motor control. In: Tutorials in motor behavior, ed. Stelmach, G. E. & Requin, J.. North-Holland. [taMBB, PDN]Google Scholar
Bizzi, E. & Abend, W. (1983) Posture control and trajectory formation in single- or multi-joint arm movements. In: Motor control mechanisms in health and disease, vol. 39 of Advances in neurology, ed. Desmedt, J. E.. Raven. [PDN]Google Scholar
Bizzi, E., Accornero, N., Chapple, W. & Hogan, N. (1981) Processes underlying arm trajectory formation. In: Brain mechanisms and perceptual awareness, ed. Pompeiano, O. and Marsan, C. Ajmone. Raven. [PDN]Google Scholar
Bizzi, E., Accornero, N., Chapple, W. & Hogan, N. (1982) Arm trajectory formation in monkeys. Experimental Brain Research46:139–43. [taMBB, ZH, GEL, RAS]Google Scholar
Bizzi, E., Accornero, N., Chapple, W. & Hogan, N. (1984) Posture control and trajectory formation during arm movement. Journal of Neuroscience4:2738–44. [ZH, GEL]CrossRefGoogle ScholarPubMed
Bizzi, E., Chapple, W. & Hogan, N. (1982) Mechanical properties of muscles: Implication for motor control. Trends in Neurosciences5:395–98. [taMBB]Google Scholar
Bizzi, E., Polit, A. & Morasso, P. (1976) Mechanisms underlying achievement of final head position. Journal of Neurophysiology39:435–44. [CCA]CrossRefGoogle ScholarPubMed
Boring, E. G. (1942) Sensation and Perception in the history of experimental psychology. Appleton-Century-Crofts. [MTT]Google Scholar
Bouisset, S., Lestienne, F. & Maton, B. (1977) The stability of synergy in agonists during the execution of a simple voluntary movement. Electroencephalography and Clinical Neurophysiology42:543–51. [RME]Google Scholar
Box, G. E. P. & Jenkins, G. M. (1976) Time series analysis: Forecasting and control. Holden-Day. [PDN]Google Scholar
Brooks, V. B., Cooke, J. D. & Thomas, J. S. (1973) The continuity of movements. In: Control of Posture and locomotion, ed. Stein, R. B., Pearson, K. G., Smith, R. S. & Bedford, J. B.. Plenum Press. [taMBB]Google Scholar
Brown, S. H. & Cooke, J. D. (1981) Responses to force perturbations preceding voluntary human arm movements. Brain Research220:350–55. [WAM]CrossRefGoogle ScholarPubMed
Brown, T. G. (1912) The factor in rhythmic activity of the nervous system. Proceedings of the Royal Society of London, Series B 85:278–89. [WHE]Google Scholar
Burrows, M. (1979) Graded synaptic interactions between local premotor interneurons of the locust. Journal of Neurophysiology42:1108–23. [WHE]CrossRefGoogle ScholarPubMed
Burrows, M. (1984) The search for principles of neuronal organization. Journal of Experimental Biology112:1–4. [WDC]Google Scholar
Camhi, J. M. (1974) Neuroal mechanisms of response modification in insects. In: Experimental analysts of insect behavior, ed. Barton-Browne, L.. Springer. [taMBB]Google Scholar
Camhi, J. M. & Hinkle, M. (1974) Response modification by the central flight oscillator of locusts. Journal of Experimental Biology60:477–92. [taMBB]CrossRefGoogle ScholarPubMed
Campbell, B. (1985) Human evolution. Aldine. [ESR]Google Scholar
Capaday, C. & Stein, R. B. (1985) Amplitude modulation of the soleus H-reflex in the human during walking and standing. Society for Neuroscience Abstracts. [CC]CrossRefGoogle Scholar
Careri, G. (1984) Order and disorder in matter. Benjamin Cummings. [MTT]Google Scholar
Carlson, J. R. (1977) The imaginal ecdysis of the cricket (Teleogryllus oceanicus) I. Organization of motor programs and roles of central and sensory control. Journal of Comparative Physiology115:319–36. [taMBB]Google Scholar
Chalfie, M., Horvitz, H. R. & Sulston, J. E. (1981) Mutation that leads to reiterations in the cell lineages of C. elegans. Cell24:59–69. [taMBB]Google Scholar
Chestnut, H. & Mayer, R. W. (1959) Servomechanisms and regulating system design. John Wiley. [PDN]Google Scholar
Cohen, A. H., Holmes, P. J. & Rand, R. H. (1982) The nature of the coupling between segmentai oscillators of the lamprey spinal generators for locomotion: A mathematical model. Journal of Mathematical Biology13:345–69. [WHE]Google Scholar
Cooke, J. D. (1980a) The organization of simple skilled movements. In: Tutorials in motor behavior, ed. Stelmach, G. E. & Requin, J.. North-Holland. [taMBB, KGM, WAM]Google Scholar
Cooke, J. D. (1980b) The role of stretch reflexes during active movements. Brain Research181:493–97. [PME]Google Scholar
Coreos, D. M., Gottlieb, G. L. & Agarwal, G. C. (submitted) Kinematic and myoelectric correlates of accurate, rapid movements of the human elbow. Journal of Neurophysiology. [GCA]Google Scholar
Crago, P. E., Houk, J. C. & Hasan, Z. (1976) Regulatory actions of human stretch reflex. Journal of Neurophysiology39:925–35. [taMBB, TRN]CrossRefGoogle ScholarPubMed
Creed, R. S., Denny-Brown, D., Eccles, J. C., Liddell, E. G. T. & Sherrington, C. S. (1932) Reflex activity of the spinal cord. Oxford University Press. [LDP]Google Scholar
Darwin, C. (1872) The expression of the emotions in man and animals. John Murray. [taMBB]Google Scholar
Davis, W. J. & Kennedy, D. (1972) Command intemeurons controlling swimmeret movements in the lobster. III: Temporal relationships among bursts in different motoneurons. Journal of Neurophysiology35:20–29. [taMBB]CrossRefGoogle Scholar
Davis, W. J., Mpitsas, G. J. & Pinnes, M. (1974) The behavioral hierarchy of the mollusk Pleurobranchca. II: Hormonal suppression of feeding associated with egg-laying. Journal of Comparative Physiology90:225–43. [taMBB]CrossRefGoogle Scholar
Davis, W. R. & Kelso, J. A. S. (1982) Analysis of “invariant characteristics” in the motor control of Down's syndrome and normal subjects. Journal of Motor Behavior14:194–212. [tarMBB]Google Scholar
Delatizky, J. (1982) Final position control in simulated planar horizontal arm movements. Ph.D. diss., MIT Department of Electrical Engineering and Computer Science. [KGM]Google Scholar
Deliagina, T. G., Feldman, A. G., Gelfand, I. M. & Orlovsky, G. N. (1975) On the role of central program and afferent inflow in the control of scratching movements in the cat. Brain Research100:297–313. [taMBB]CrossRefGoogle Scholar
Desmedt, J. E. (1978) Cerebral motor control in man: Long loop mechanisms, vol. 4 of Progress in clinical neurophysiology. ed. Desmedt, J. E.. Karger. [PDN]Google Scholar
DiCaprio, R. A. & Clarac, F. (1981) Reversal of a walking leg reflex elicited by a muscle receptor. Journal of Experimental Biology90:197–203. [ZH]Google Scholar
Dimery, N. J. & Alexander, R. McN. (1985) Elastic properties of the hind foot of the Donkey Equus asinus. Journal of Zoology A, 207:9–20. [RMcNa]CrossRefGoogle Scholar
Dum, R. P., Burke, R. E., O'Donovan, M. J., Toop, J. & Hodgson, J. A. (1982) Motor-unit organization in flexor digitorum longus muscle of the cat. Journal of Neurophysiology47:1108–25. [RME]Google Scholar
Eccles, J. C., Eccles, R. M. & Lundberg, A. (1957) The convergence of monosynaptic excitatory afferents on to many different species of alphamotoneurons. Journal of Physiology-London137:22–50. [GCA]Google Scholar
Edgerton, V. R., Grillner, S., Sjöström, A. & Zangger, P. (1976) Central generation of locomotion in vertebrates. n: Neural control of locomotion, ed. Herman, R., Grillner, S., Stein, P. & Stuart, D., vol. 18. Plenum Press. [taMBB]CrossRefGoogle Scholar
Elftman, H. (1939) The function of muscles in locomotion. American Journal of Physiology125:357–66. [LDP]CrossRefGoogle Scholar
Engberg, I. & Lundberg, A. (1969) An electromyographic analysis of muscular activity in the hindlimb of the cat during unrestrained locomotion. Acta Physiologica Scandinavica75:614–30. [taMBB]Google Scholar
Enoka, R. M. (1983) Muscular control of a learned movement: The speed control system hypothesis. Experimental Brain Research51:135–45. [taMBB]CrossRefGoogle ScholarPubMed
Eshkol, N. & Wachman, A. (1958) Movement notation. Weidenfeld and Nicholson. [IG]Google Scholar
Evarts, E. (1981) Sherrington's concept of proprioception. Trends in Neurosciences4:44–46. [UW]Google Scholar
Evoy, W. H. & Ayers, J. (1982) Locomotion and control of limb movements. In: Biology of Crustacea, vol. 4, ed. Bliss, D. E.. Academic Press. [ZH]Google Scholar
Evoy, W. H., Roberts, A., Soffe, S. R. & Dale, N. (1984) Synaptic components of the central pattern generator for swimming in an amphibian embryo spinal cord. Neuroscience Abstracts10:658. [WHE]Google Scholar
Eykhoff, P. (1974) System identification. John Wiley. [GFI]Google Scholar
Fabre, J. N. (1879–1907) Souvenirs entomologiques. Librairie Delagrave. [taMBB]Google Scholar
Fearing, F. (1930/1970) Reflex action: A study in the history of physiological psychology. MIT Press. [MTT]CrossRefGoogle Scholar
Feldman, A. G. (1966a) Functional tuning of the nervous system with control of movement or maintenance of a steady posture. II. Controllable parameters of the muscle. Biophysics11:565–78 (Biofizika 11:498–508). [taMBB, RAS]Google Scholar
Feldman, A. G. (1966b) Functional tuning of the nervous system with control of movement or maintanance of a steady posture. III. Mechanographic analysis of execution by man of the simplest motor tasks. Biophyscs 11:766 (Biofizika11:667–75). [taMBB]Google Scholar
Feldman, A. G. (1974a) Change of muscle length as a consequence of a shift in an equilibrium of muscle-load system. Biophyscs 19:544–48 (Biofizika19:534–38). [tar MBB, CC, RME].Google Scholar
Feldman, A. G. (1974b) Control of the length of a muscle. Biophysics 19:776–71 (Biofizika19:749–53). [tarMBB, CC, RAS]Google Scholar
Feldman, A. G. (1976) Control of postural length and strength of a muscle: Advantages of central co-activation of alpha and gamma motoneurons. Biophysics 21:188–90 (Biofizika21:187–89). [taMBB]Google Scholar
Feldman, A. G. (1979) Central and reflex mechanisms in motor control. Nauka. In Russian. [tarMBB]Google Scholar
Feldman, A. G. (1980a) Superposition of motor programs. I. Rhythmic forearm movements in man. Neuroscience5:81–90. [taMBB, RME, TRN]Google Scholar
Feldman, A. G. (1980b) Superposition of motor programs. II. Rapid flexion of forearm in man. Neuroscience5:91–95. [taMBB, CG]CrossRefGoogle ScholarPubMed
Feldman, A. G. (1981) The composition of central programs subserving horizontal eye movements in man. Biological Cybernetics42:107–16. [rMBB]Google Scholar
Feldman, A. G. & Orlovsky, G. N. (1972) The influence of different descending systems on the tonic stretch reflex in the cat. Experimental Neurology37:481–94. [taMBB]Google Scholar
Fentress, J. C. (1983) Ethological models of hierarchy and patterning of species-specific behavior. In: Handbook of behavioral neurobiology: Motivation, ed. Satinoff, E. & Teitelbaum, P.. Plenum. [JCF]Google Scholar
Fentress, J. C. (1984) The development of motor coordination. Journal of Motor Behavior16:99–134. [JCF]Google Scholar
Ferrier, D. (1886) The functions of the brain. Smith, Elder. [ESR]Google Scholar
Fitts, P. M. (1954) The information capacity of the human motor system in controlling the amplitude of movement. Journal of Experimental Psychology. 47:381–91. [GCA]Google Scholar
Fitts, P. M. & Peterson, J. R. (1964) Information capacity of discrete motor responses. Journal of Experimental Psychology67:103–12. [GCA]CrossRefGoogle ScholarPubMed
Fodor, J. A. (1985) Précis of The modularity of mind. Behavioral and Brain Sciences8:1–42. [JCF]Google Scholar
Ford, L. E., Huxley, A. F. & Simmons, R. M. (1981) The relation between stiffness and filament overlap in stimulated frog muscle fibres. Journal of Physiology311:219–249. [WAM]Google Scholar
Forssberg, H. (1979) Stumbling corrective reaction: A phase dependent compensatory reaction during locomotion. Journal of Neurophysiology42:936–53. [taMBB, WHE]Google Scholar
Forssberg, H. (1982) Spinal locomotion function and descending control. In: Brainstcm control of spinal mechanisms, ed. Sjolund, B. & Bjorkland, A.. Ferstrom Foundation Series. [DJO]Google Scholar
Fowler, C. A. & Turvey, M. T. (1978) Skill acquisition: An event approach with special reference to searching for the optimum of a function of several variables. In: Information processing in motor control and learning, ed. Stelmach, G. E.. Academic. [KGM, MTT]Google Scholar
French, R. (1969) Robert Whytt, the soul, and medicine. Wellcome Institute for the History of Medicine. [ESR]Google Scholar
Frieshen, W. O., Poon, M. & Stent, G. S. (1978) Neuronal control of swimming in the medical leech. IV. Identification of a network of oscillatory intemeurons. Journal of Experimental Biology75:25–43. [taMBB]CrossRefGoogle Scholar
Frisch, K. von (1950) Bees, their vision, chemical senses and language. Cornell University Press. [taMBB]Google Scholar
Fukson, O. I., Berkinblit, M. B. & Feldman, A. G. (1980) The spinal frog takes into account the scheme of its body during the wiping reflex. Science209:1261–63. [taMBB]Google Scholar
Gallistel, C. R. (1981) Précis of Gallistel's The organization of action: A new synthesis. Behavioral and Brain Sciences4:609–50. [taMBB]CrossRefGoogle Scholar
Gasser, H. S. & Hill, A. V. (1924) The dynamics of muscular contraction. Proceedings of Royal Society of LondonB96:398–437. [rMBB]Google Scholar
Gelfand, I. M., Gurfinkel, V. S., Tsetlin, M. L. & Shik, M. L. (1971) Some problems in the analysis of movements. In: Models of the structural–functional organization of certain biological systems, ed. Gelfand, I. M., Gurfinkel, V. S., Fomin, S. V. & Tsetlin, M. L.. MIT Press. [taMBB]Google Scholar
Gelfand, I. M. & Tsetlin, M. L. (1967) Mathematical modeling of mechanisms of the central nervous system. In: Models of the structural-functional organization of certain biological systems, ed. Gelfand, I. M., Gurfinkel, V. S., Fomin, S. V. & Tsetlin, M. L.. MIT Press. [taMBB]Google Scholar
Chiselin, M. T. (1984) The triumph of the Darwinian method, 2d ed.University of Chicago Press. [ESR]Google Scholar
Gibson, E. J. (1952) The role of shock in reinforcement. Journal of Comparative and Physiological Psychology45:18–30. [ESR]Google Scholar
Gibson, J. & Hudson, L. (1935) Bilateral transfer of the conditioned knee jerk. Journal of Experimental Psychology18:774–83. [ESR]Google Scholar
Gibson, J., Jack, E. & Raffel, G. (1932) Bilateral transfer of the conditioned response in the human subject. Journal of Experimental Psychology15:416–21. [ESR]CrossRefGoogle Scholar
Gibson, J. J. (1966) The senses considered as perceptual systems. Houghton-Mifflin. [ESR, MTT]Google Scholar
Gibson, J. J. (1979) The ecological approach to visual perception. Houghton-Mifflin. [MTT]Google Scholar
Gielen, C. C. A. M. & Houk, J. C. (1984) Nonlinear viscosity of the human wrist. Journal of Neurophysiohgy52:553–69. [rMBB, CG]Google Scholar
Gielen, C. C. A. M., Houk, J. C., Marcus, S. L. & Miller, L. E. (1984) Viscoelastic properties of the wrist motor servo in man. Annals of Biomedical Engineering12:599–620. [GCA, CG]Google Scholar
Golani, I. & Fentress, J. C. (in press) Early ontogeny of face grooming in mice. Developmental Psychobiology. [JCF]Google Scholar
Gordon, J. & Ghez, C. (1984) EMG patterns in antagonist muscles during isometric contraction in man: Relations to response dynamicsExperimental Brain Research55: 167–71. [MBB, ZH]Google Scholar
Gottlieb, G. L. & Agarwal, G. C. (1978) Stretch and Hoffmann reflexes during phasic voluntary contractions of the human soleus muscle. Electroen-cephalography and Clinical Neurophysiology44:533–61. [RME]Google Scholar
Gottlieb, G. L. & Agarwal, G. C. (1979) Response to sudden torques about ankle in man: Myotatic reflex. Journal of Neurophysiology42:91–106. [rMBB, RME]Google Scholar
Gottlieb, G. L. & Agarwal, G. C. (1980a) Response to sudden torques about ankle in man. II. Postmyototic reaction. Journal of Neurophysiology43:86–101. [UW]Google Scholar
Gottlieb, G. L. & Agarwal, G. C. (1980b) Response to sudden torques about ankle in man. III. Suppression of stretch-evoked responses during phasic contraction. Journal of Neurophysiology44:233–46. [RME]Google Scholar
Gottlieb, G. L. & Agarwal, G. C. (1983) Muscle-reflex compliance: Elasticity and plasticity at the human elbow. Society for Neuroscience Abstracts9:632. [GLG]Google Scholar
Gottlieb, G. L. & Agarwal, G. C. (1984) Muscle-reflex compliance: A comparison of elbow and ankle. Society Neuroscience Abstracts10:335. [GCA, CLG]Google Scholar
Gracco, V. L. & Abbs, J. H. (in press) Dynamic control of the perioral system during speech: Kinematic analyses of autogenic and nonautogenic sensorimotor processes. Journal of Neurophysiology. [KGM]Google Scholar
Granit, R. (1970) The basis of motor control. Academic Press. [MI]Google Scholar
Granit, R. (1975) The purposive brain. MIT Press. [ESR]Google Scholar
Greene, P. H. (1972) Problems of organization of motor systems. Progress in Theoretical Biology2:303–38. [WAM]Google Scholar
Greene, P. H. (1982) Why is it easy to control your arms?Journal of Motor Behavior4:260–86. [taMBB]Google Scholar
Grillner, S. (1974) On the generation of locomotion in the spinal dogfish. Experimental Brain Research20:459–70. [LDP]Google Scholar
Grillner, S. (1975) Locomotion in vertebrates: Central mechanisms and reflex interaction. Physiological Review55:277–304. [taMBB]CrossRefGoogle ScholarPubMed
Grillner, S. (1981) Control of locomotion in bipeds, tetrapods and fish. In: Handbook of physiology, motor control, ed. V. Brooks, vol. 3. [taMBB]CrossRefGoogle Scholar
Grillner, S. (1982) Possible analogies of the control of innate motor acts and the production of sound in speech. In: Wennergren Center Internacional Simposium series, vol. 36, Speech motor control, ed. Grillner, S., Lindblom, B., Lubker, J. & Persson, A.. Pergamon Press. [taMBB]Google Scholar
Grillner, S. & Rossignol, S. (1978) On the initiation of the swing phase of locomotion in chronic spinal cats. Brain Research146:269–77. [taMBB]Google Scholar
Grillner, S. and Wallen, P. (1985) Central pattern generators for locomotion, with special reference to vertebrates. Annual Review of Neuroscience8:233–61. [WHE]CrossRefGoogle ScholarPubMed
Haken, H. (1978) Synergetics: An introduction. Spring-Verlag. [MTT]Google Scholar
Halbertsma, J. (1983) The stride cycle of the cat: The modelling of locomotion by computerized analysis of automatic recordings. Acta Physiologica Scandinavica. Suppl. 521:1–75. [taMBB, RMcN, LDP]Google Scholar
Haller, A. von (1752) De partibus corporis humani sensibilus et irritabilus. Acta Gottingensis2:1–114. [ESR]Google Scholar
Harrison, P. J. (1985) An interneuronal system contributing to the coordination of the cat hind limb. In: Coordination of motor behavior, ed. Bush, B. M. H. and Clarac, F.. Society for Experimental Biology Seminar Series, no. 24. Cambridge University Press. [WHE]Google Scholar
Harrison, P. J. & Jankowska, E. (1985a) Organization of input to the interneurones mediating group I non-reciprocal inhibition of motoneurones in the cat. Journal of Physiology-London361:403–418. [UW]Google Scholar
Harrison, P. J. & Jankowska, E. (1985b) Sources of input to interneurones mediating group I non-reciprocal inhibition of motoneurons in the cat. Journal of Physiology-London361:379–401. [UW]Google Scholar
Hasan, Z. & Enoka, R. M. (1985) Isometric torque–angle relationship and movement-related activity of human elbow flexors: Implications for the equilibrium-point hypothesis. Experimental Brain Research59:441–50. [ZH]Google Scholar
Hasan, Z., Enoka, R. M. & Stuart, D. G. (1985) The interface between biomechanics and neurophysiology in the study of movement: Some recent approaches. In: Exercise and Sport Sciences Reviews, ed. Terjung, R. L.. Macmillan. [RME]Google Scholar
Hebb, D. (1949) The organization of behavior. Wiley. [taMBB, KGM]Google Scholar
Helmholtz, H. (1848) Über die Wämeentwicklung bei der Muskelaction. Archiv für Anatomie, Physiologie und Wissenschaftliche Medizin, Leipzig 144–64. [taMBB]Google Scholar
Henneman, E., Solmjen, G. & Carpenter, D. O. (1965) Excitability and inhibitibility of motoneurons of different sizes. Journal of Neurophysiology28:599–620. [LDP]Google Scholar
Hoffer, J. A. (1982) Central control and reflex regulation of mechanical impedance: The basis for a unified motor-control scheme. Behavioral and Brain Sciences5:548–49. [GFI]Google Scholar
Hoffer, J. A. & Andreassen, S. (1981) Regulation of soleus muscle stiffness in premammillary cats: Intrinstic and reflex components. Journal of Neurophysiology45:267–85. [taMBB, WDC]CrossRefGoogle Scholar
Hoffer, J. A., Leonard, T. A., Spence, N. L. & Cleland, C. L. (1984) Reflex gain, muscle stiffness and viscosity in normal cats. Society for Neuroscience Abstracts10:330. [rMBB, TRN]Google Scholar
Hogan, N. (1982) Moving with control: Using control theory to understand motor behaviour. Behavioral and Brain Sciences5:550. [UW]Google Scholar
Holmes, G. (1922) The Cooonian Lectures on the clinical symptoms of the cerebellar disease and their interpretation. Lancet 100, 1:1177–82, 1231–37; 2:59–65, 111–15. [LDP]Google Scholar
Hoist, E. von & Mittelstaedt, H. (1950) Das Reafferenzprìnzip. Wechselwirkung zwischen Zentralnervensystem und Peripherie. Die Naturwissenschaften37:464–76. [taMBB]Google Scholar
Houk, J. C. (1976) An assessment of Stretch reflex function. Progress in Brain Research44:303–14. [tarMBB]Google Scholar
Houk, J. C. (1979) Regulation of stiffness by skeletomotor reflexes. Annual Review of Physiology41:99–114. [taMBB]Google Scholar
Houk, J. C., Crago, P. E. & Rymer, W. Z. (1981) Function of the spindle dynamic response in stiffness regulation – a predictive mechanism provided by non-linear feedback. In: Muscle receptors and movement, ed. Taylor, A. & Prochazka, A.. Macmillan. [TRN]Google Scholar
Houk, J. C. & Henneman, E. (1974) Feedback control of muscle: Introductory concepts. In: Medical physiology, ed. Mountcastle, V. B.. C. V. Mosby. [TRN]Google Scholar
Houk, J. C., Marcus, S. L. & Miller, L. E. (1983) Neural mechanisms for motor control and load adaptation. Annals of Biomedical Engineering11:39–40. [rMBB]Google Scholar
Houk, J. C., Rymer, W. Z. & Crago, P. E. (1981) Nature of the dynamic response and its relation to the high sensitivity of muscle spindles to small changes in length. In: Muscle receptors and movement, ed. Taylor, A. & Prochazka, A.. Macmillan. [GEL]Google Scholar
Howard, J. D., Hoit, J. D., Enoka, R. M. & Hassan, Z. (1986) Relative activation of two human elbow flexors under isometric conditions: A cautionary note concerning flexor equivalence. Experimental Brain Research62: 199–202. [RME]Google Scholar
Hoyle, C. (1984) The scope of neuroethology. Behavioral and Brain Sciences7:367–412. [taMBB, JCF]Google Scholar
Hughes, G. M. & Wiersma, C. A. (1960) The coordination of swimmeret movements in the crayfish, Procambarus clarkii (Girard). Journal of Experimental Biology37:657–70. [taMBB]Google Scholar
Hunt, K. H. (1978) Kinematic geometry of mechanisms. Oxford University Press. [RMcNA]Google Scholar
Huxley, A. F. & Niedergerke, R. (1954) Structural changes in muscle during contraction. Interference microscopy of living muscle fibres. Nature173:971–73. [taMBB]Google Scholar
Inbar, G. F. (1972) Muscle spindles in muscle control. III. Analysis of adaptive system model. Kybernetik11:130–41. [GFI, PDN, UW]Google Scholar
Inbar, G. F. (1985) Adaptation in the neuromuscular system. In: Proceedings of the Tri-National Conference on Sensorimotor Plasticity: Theoretical. Experimental and Clinical Aspects, ed. Ron, S.. North-Holland. [GFI]Google Scholar
Inbar, G. F. & Yafe, A. (1976) Parameter and signal adaptation in the stretch reflex loop. Progress in Brain Research44:317–37. [GFI, PDN]Google Scholar
Jacob, M. (1981) The radical enlightenment: Pantheists, Freemasons and republicans. Allen & Unwin. [ESR]Google Scholar
Jander, R. (1957) Die optische Richtungsorientierung der Roten Waldameise (Formico rufa L). Zeitschrift für Vergleichende Physiologie40:162–38. [taMBB]Google Scholar
Jankowska, E. & Lundberg, A. (1981) Intenieuroncs in the spinal cord. Trends in Neuroscience4:230–33. [GEL]Google Scholar
Jenkins, F. A. (1971) Posture and locomotion in the Virginia opossum (Didelphis marsupialis) and in other non-cursorial mammals. Journal of Zoology165:303–15. [RMcNA]Google Scholar
Jordan, L. M. (1983) Factors determining motoneuron rhythmicity during fictive locomotion. In: Neural origin in rhythmic movements, ed. Roberts, A. & Roberts, B. L.. Symposia of the Society for Experimental Biology, no. 37. Cambridge University Press. [WHE]Google Scholar
Joseph, V. & Inbar, G. F. (1985) Estimation of the mechanical impedance parameters of human subjects in response to white noise mechanical perturbations. Submitted for publication. [GFI]Google Scholar
Kahn, J. A. & Roberts, A. (1982) Experiments of the central pattern generator for swimming in amphibian embryons. Philosophical Transactions of the Royal Society of London Series B 296:229–43. [taMBB]Google Scholar
Kandel, E. R. (1976) Cellular basis of behavior. An introduction to behavioral neurobiology. W. H. Freeman. [taMBB]Google Scholar
Keele, S. W. (1968) Movement control in skilled motor performances. Psychological Bulletin70:387–403. [KGM]Google Scholar
Kelso, J. A. S. (1977) Motor control mechanisms underlying human movement reproduction. Journal of Experimental Psychology: Human Perception and Performance3:529–43. [taMBB]Google Scholar
Kelso, J. A. S. (1978) Changing views of feedforward and feedback in voluntary movement. Behavioral and Brain Sciences1:153–54. [taMBB]CrossRefGoogle Scholar
Kelso, J. A. S. (1984) Phase transitions and critical behavior in human bimanual coordination. American Journal of Physiology246:R1000–04. [taMBB]Google Scholar
Kelso, J. A. S. & Holt, K. G. (1980) Exploring a vibratory system analysis of human movement production. Journal of Neurophysiology43:1183–96. [taMBB, KGM, RAS]Google Scholar
Kelso, J. A. S., Holt, K. G., Kugler, P. N. & Turvey, M. T. (1980) On the concept of coordinative structures as dissipative structures; II. Empirical lines of convergency. In Tutorials in motor behavior, ed. Stelmach, C. E. & Requin, J.. North-Holland. [RAS]Google Scholar
Kelso, J. A. S., Holt, K. G., Rubin, P., Kugler, P. N. (1981) Patterns of human interlimb coordination emerge from the properties of non-linear, limit cycle oscillatory processes: Theory and data. Journal of Motor Behavior13:226–61. [RAS]Google Scholar
Kelso, J. A. S. & Saltzman, E. L. (1982) Motor control: Which themes do we orchestrate?Behavioral and Brain Sciences5:554–57. [taMBB]Google Scholar
Kelso, J. A. S., Southard, D. L. & Goodman, D. (1979) On the nature of human interlimb coordination. Science203:1029–31. [taMBB]CrossRefGoogle ScholarPubMed
Kelso, J. A. S. & Tuller, B. (1983) “Compensatory articulation” under conditions of reduced afferent information: A dynamic formulation. Journal of Speech and Hearing Research26:217–24. [taMBB]Google Scholar
Kelso, J. A. S. & Tuller, B. (1984) Converging evidence in support of common dynamic principles for speech and movement coordination. American Journal of Physiology15:R928–R935. [MLL]Google Scholar
Kelso, J. A. S. & Tuller, B. (in press) Intrinsic time in speech production: Theory, methodology, and preliminary observations. In: Motor and sensory processes of language, ed. Keller, E. & Gopnik, M.. Erlbaum. [KGM]Google Scholar
Kelso, J. A. S., Tuller, B., V.-Bateson, E. & Fowler, C. A. (1984) Functionally specific articulatory cooperation adaptation to jaw perturbations during speech: Evidence for coordinative structures. Journal of Experimental Psychology: Human Perception and Performance10:812–32. [KGM, DGO]Google Scholar
Kelso, J. A. S., V.-Bateson, E., Saltzman, E. L. & Kay, B. A. (1985) A qualitative dynamic analysis of reiterant speech production: Phase portraits, kinematics and dynamic modeling. Journal of the Acoustical Society of America77:266–80. [KGM]Google Scholar
Kennedy, W. & Davis, W. J. (1977) Organization of invertebrate motor systems. In: Handbook of physiology, ed. S. P. Geiger, E. R. Kandel, I. M. Brookhart & V. B. Mountcastle. [taMBB]Google Scholar
Kuffler, D. P. & Muller, K. I. (1974) The properties and connections of supernumerary sensory and motor nerve cells in the central nervous system of an abnormal leech. Journal of Neurobiology5:331–48. [taMBB]Google Scholar
Kugler, P. N., Kelso, J. A. S. & Turvey, M. T. (1980) On the concept of coordinative structures as dissipative structures: I. Theoretical lines of convergence. In: Tutorials in motor behavior, ed. Stelmach, C. E. & Requin, J.. North-Holland. [taMBB]Google Scholar
Kugler, P. N. & Turvey, M. T. (in press) Information, natural law and the self-assembly of rhythmic movement. Erlbaum. [KGM, MTT]Google Scholar
Kupfermann, I. & Weiss, K. R. (1978) The command neuron concept. Behavioral and Brain Sciences1:3–39. [taMBB, WHE]Google Scholar
Lacquaniti, F. & Soechting, J. F. (1983) Changes in mechanical impedance and gain of the myotatic response during transitions between two motor tasks. In: Neural coding of motor performance, ed. Massion, J., Paillard, J., Schultz, W. & Wiesendanger, M.. Springer-Verlag. [PDN]Google Scholar
Lange, F. A. (1880) The history of materialism, vol. 2. Trubner. [ESR]Google Scholar
Lashley, K. S. (1942) The problem of cerebral organization in vision. In: Visual mechanisms, ed. Kluver, H., Biological Symposium 7. [KGM]Google Scholar
Lee, W. A. (1984) Neuromotor synergies as a basis for coordinated intentional action. Journal of Motor Behavior16:135–70. [WAL]Google Scholar
Lestienne, F. (1979) Effects of inertial load and velocity on the braking process of voluntary limb movements. Experimental Brain Research35:407–18. [WAM]Google Scholar
Llinás, R. & Precht, W., eds. (1976) Frog neurobiology. A handbook. Springer-Verlag. [UW]Google Scholar
Lloyd, D. P. C. (1946) Integrative patterns of excitation and inhibition in two-neuron reflex arcs. Journal of Neurophysiology9:439–44. [TRN]Google Scholar
Loeb, G. E. (1984) The control and responses of mammalian muscle spindles during normally executed motor tasks. Exercise and Sport Sciences Reviews12:157–204. [GEL, UW]CrossRefGoogle ScholarPubMed
Lombard, W. P. & Abbott, F. M. (1907) The mechanical effects produced by the contraction of individual muscles of the thigh of the frog. American Journal of Physiology. 20:1–60. [LDP]Google Scholar
Lorenz, K. Z. (1950) The comparative method in studying innate behavior patterns. Symposia of the Society for Experimental Biology4:221–68. [taMBB]Google Scholar
Lorenz, K. Z. (1966) Evolution and modification of behaviors. Methuen. [taMBB]Google Scholar
Lorenz, K. Z. (1981) The foundations of ethology. Springer-Verlag. [LDP]Google Scholar
Lorenz, K. & Tinbergen, N. (1938) Taxis und Instinkthandlung in der Eirollbewegung der Graugans I. Zeitschrift für Tierpsychologie2:1–29. [WDC]Google Scholar
Lubbock, J. (1888) On the senses, instincts and intelligence of animals. London. [taMBB]Google Scholar
Lundberg, A. (1975) Control of spinal mechanisms from the brain. In: The nervous system ed. Tower, D. B., vol. 2. Raven Press. [taMBB]Google Scholar
Lundberg, A. & Voorhoeve, P. (1962) Effects from pyramidal tract on the spinal reflex arcs. Acta Physiologica Scandinavica56:201–19. [rMBB]Google Scholar
Luria, A. R. (1973) The working brain. Penguin. [ESR]Google Scholar
MacKay, W. A., Kwan, H. C., Murphy, J. T. & Wong, Y. C. (1983) Stretch reflex modulation during a cyclic elbow movement. Electroencephalo graphy and Clinical Neurophysiology55:687–98. [WAM]Google Scholar
Magnus, R. (1924) Körperstellung. Springer. [taMBB]Google Scholar
Marsden, C. D., Merton, P. A. & Morton, H. B. (1983) Rapid postural reactions to mechanical displacements of the hand in man. In: Motor control mechanisms in health and disease, ed. Desmedt, J.. Raven. [KGM]Google Scholar
Marsden, C. D., Obeso, J. A. & Rothwell, J. C. (1983) The function of the antagonist muscle during fast limb movements in man. Journal of Physiology (London)335:1–13. [CG]Google Scholar
Matthews, P. B. C. (1959) The dependence of tension upon extension in the stretch reflex of the soleus of the decerebrate cat. Journal of Physiology (London)47:521–46. [taMBB]Google Scholar
Matthews, P. B. C. (1972) Mammalian muscle receptors and their central actions. Physiology Society Monographs, Arnold. [GEL]Google Scholar
Matthews, P. B. C. (1981) Muscle spindles: Their messages and their fusimotor supply. In: Handbook of physiology, Sect. 1: The nervous system, vol. 2, part 1. American Physiological Society. [PDN]Google Scholar
Matthews, P. B. C. & Watson, J. D. G. (1981) Effect of vibrating agonist or antagonist muscle on the reflex response to sinusoidal displacement of the human forearm. Journal of Physiology-London321:297–316. [TRN]Google Scholar
Mayr, E. (1982) The growth of biological thought. Harvard University Press. [ESR]Google Scholar
McCulloch, W. S. (1947) Modes of functional organization of the cerebral cortex. Federation of American Societies for Experimental Biology, Proceedings6:448–52. [WAM]Google Scholar
McMahon, T. A. (1975) Using body size to understand the structural design of animals: Quadrapedal locomotion. Journal of Applied Physiology39:619–27. [GEL]Google Scholar
Mecacci, L. (1979) Brain and history. M. E. Sharpe. [ESR]Google Scholar
Merton, P. A. (1953) Speculations on the servo-control of movement. In: CIBA Foundation Symposium, The spinal cord, ed. Wolstenholme, G. E. W.. Churchill. [taMBB, GCA, GLG]Google Scholar
Meyer, D. E., Smith, J. E. K. & Wright, C. E. (1982) Models for the speed and accuracy of aimed movements. Psychological Reviews89:449–82. [WAM]Google Scholar
Miller, J. P. & Selverston, A. I. (1982) Mechanisms underlying pattern generation in lobster stomatogastric ganglion as determined by selective inactivation of identified neurons. 4. Network properties of the pyloric system. Journal of Neurophysiology48:1416–32. [WDC]Google Scholar
Minsky, M. & Papert, S. (1969) Perceptron. MIT Press. [rMBB]Google Scholar
Morasso, P., Bizzi, E. & Dichgans, J. (1973) Adjustment of saccade characteristics during head movements. Experimental Brain Research16:492–500. [LDP]Google Scholar
Morasso, P. & Mussa Ivaldi, F. A. (1982) Trajectory formation and handwriting: A computational model. Biological Cybernetics45:131–42. [taMBB]Google Scholar
Mortin, L. I., Keifer, J. & Stein, P. S. G. (1982) Three forms of the turtle scratch reflex. Society for Neuroscience Abstracts8:159. [taMBB]Google Scholar
Munhall, K. G. & Kelso, J. A. S. (1985) Phase dependent sensitivity to perturbation reveals the nature of speech cooperative structures. Journal of the Acoustical Society of America78:538. [KGM]Google Scholar
Munhall, K. G., Ostry, D. O. & Parush, A. (1985) Characteristics of velocity profiles of speech movements. Journal of Experimental Psychology: Human Perception and Performance11:457–74. [KGM]Google Scholar
Nashner, L. M. (1976) Adapting reflexes controlling the human posture. Experimental Brain Research26:59–72. [RME]Google Scholar
Nashner, L. M. (1981) Analysis of stance posture in human. In: Handbook of behavioral neurobiology, ed. Towe, A. L. & Luschei, E. S.. Vol. 5. Plenum. [taMBB]Google Scholar
Nashner, L. M. & McCollum, G. (1985) The organization of human postural movements. Behavioral and Brain Sciences8:135–72. [taMBB]Google Scholar
Neilson, P. D. & Lance, J. W. (1978) Reflex transmission characteristics during voluntary activity in normal man and in patients with movement disorders. In: Cerebral motor control in man: Long loop mechanisms, vol. 4 of Progress in clinical neurophyisology ed. Desmedt, J. E.. Karger. [PDN]Google Scholar
Neilson, P. D. & McCaughey, J. (1981) Effect of contraction level and magnitude of stretch on tonic stretch reflex transmission characteristics. Journal of Neurology, Neurosurgery and Psychiatry44:320–30. [PDN]Google Scholar
Neilson, P. D. & McCaughey, J. (1982) Self-regulation of spasm and spasticity in cerebral palsy. Journal of Neurology, Neurosurgery and Psychiatry45:320–30. [PDN]Google ScholarPubMed
Neilson, P. D. & O'Dwyer, N. J. (1984) Adaptive control of tonic stretch reflexes in man. Spastic Centre Research Unit Progress Report, The Prince Henry Hospital, Sydney, Australia. [PDN]Google Scholar
Nichols, T. R. (1974) Soleus muscle stiffness and its reflex control. Ph.D. thesis, Harvard University. [TRN]Google Scholar
Nichols, T. R. (1981) Evidence for authentic changes in the gain of an autogenetic reflex in the soleus muscle in the decerebrate cat. Society for Neuroscience Abstracts7:688. [TRN]Google Scholar
Nichols, T. R. (1982) Reflex action in the context of motor control. Behavioral and Brain Sciences5:559–60. [taMBB]Google Scholar
Nichols, T. R. (1983) Reflex action in an agonist–antagonist muscle system in the decerebrate cat. Society for Neuroscience Abstracts9:527. [rMBB, TRN]Google Scholar
Nichols, T. R. & Houk, J. C. (1976) The improvement in linearity and the regulation of stiffness that results from the actions of the stretch reflex. Journal of Neurophysiology39:119–42. [taMBB]Google Scholar
Nuberg, N. D., Bongard, M. M. & Nikolaev, P. P. (1971) On the constancy of colour perception. Biofizika16:1052–63. [taMBB]Google Scholar
O'Donovan, M. J., Pinter, M. J., Dum, R. P. & Burke, R. E. (1982) Actions of FDL and FHL muscles in intact cats: Functional dissociation between anatomical synergists. Journal of Neurophysiology47:1126–43. [RME]Google Scholar
Ostry, D. J. & Munhall, K. G. (1985) Control of rate and duration of speech movements. Journal of the Acoustical Society of America77:640–48. [KGM, DJO]Google Scholar
Ostry, J., Keller, E. & Parush, A. (1983) Similarities in the control of the speech articalators and the limbs: Kinematics of tongue dorsum movements in speech. Journal of Experimental Psychology9:622–36. [taMBB]Google Scholar
Partridge, L. D. (1972) Interrelationships studied in semibiological “reflex.”American Journal of Physiology223:144–58. [taM BB]Google Scholar
Partridge, L. D. (1981) Neural control drives a muscle spring: A presisting yet limited theory. Experimental Brain Research Supplement7:280–90. [LDP]Google Scholar
Partridge, L. D. (1982) The good enough calculi of evolving control systems: Evolution is not engineering. American Journal of Physiology242:R173–R177. [LDP]Google Scholar
Partridge, L. D. (1983) Neural control drives a muscle spring: A persisting yet limited motor theory. In: Neural coding of motor performace, ed. Massion, J., Paillard, J., Schultz, W. & Wiesendanger, M.. Experimental Brain Research, Sappl 7. Springer. [taMBB]Google Scholar
Partridge, L. D. & Benton, L. A. (1981) Muscle the motor. In: Handbook of physiology – The nervous system ed. Brooks, V. B.. American Physiology Society. [LDP]Google Scholar
Paton, G. (1846) On the perceptive power of the spinal cord, as manifested by cold-blooded animals. Edinburgh Medical and Surgical Journal65:251–69. [taMBB]Google Scholar
Pattee, H. H. (1972) Laws and constraints, symbols and language. In Towards a theoretical biology, ed. Waddington, C. H.. Atherton-Aldine. [MTT]Google Scholar
Pearson, K. G. (1972) Central programming and reflex control of walking in the cockroach. Journal of Experimental Biology56:173–93. [taMBB]Google Scholar
Pearson, K. G. (1981) Function of sensory input in insect motor systems. Canadian Journal of Physiology and Pharmacology59:660–66. [taMBB]Google Scholar
Pearson, K. G. & Duysens, J. (1976) Function of segmental reflexes in the control of stepping in cockroaches and cats. In: Neural control of locomotion, ed. Herman, R. M., Grillner, S., Stein, P. & Stuart, D.. Plenum. [taMBB]Google Scholar
Pellionisz, A. & Llinas, R. (1979) Brain modelling by tensor network theory and computer simulation. The cerebellum: Distributed processor for predictive coordination. Neuroscience4:323–48. [taMBB]Google Scholar
Pfluger, E. (1853) Die Sensoriscen Functionen des Rückenmarks bei Wirbelttieren. Berlin. [taMBB]Google Scholar
Polit, A. & Bizzi, E. (1978) Processes controlling arm movements in monkeys. Science201:1235–37. [RAS]Google Scholar
Popper, K. & Eccles, J. (1977) The self and its brain. Springer. [ESR]Google Scholar
Prigogine, I. (1980) From being to becoming: Time and complexity in the physical sciences. W. H. Freeman. [MTT]Google Scholar
Rack, P. M. H. & Westbury, D. R. (1969) The effects of length and stimulus rate on tension in the isometric cat soleus muscle. Journal of Physiology (London)204:443–60. [taMBB]Google Scholar
Ralston, H. J., Inman, V. T., Strait, L. A. & Shaffrath, M. D. (1947) Mechanics of human isolated voluntary muscle. American Journal of Physiology151:612–20. [taMBB]Google Scholar
Reaumur, R. A. (1732–1742) Memoires pour servir à l'hystoire des insektes. Paris. [taMBB]Google Scholar
Reed, E. S. (1979) Evolution, classification and symmetry in Ghiselin's “radical solution” to the species problem. Systematic Zoology. [ESR]Google Scholar
Reed, E. S. (1980) The corporeal ideas hypothesis and the origin of scientific psychology. Ph.D. Diss., Boston University. [ESR]Google Scholar
Reed, E. S. (1982a) The corporal idea hypothesis and the origin of experimental psychology. Review of Metaphysics35:731–52. [MTT]Google Scholar
Reed, E. S. (1982b) An outline of a theory of action systems. Journal of Motor Behavior14:98–134. [ESR, MTT]Google Scholar
Reed, E. S. (1984) From action Cestalts to direct action. In: Human motor actions: Bernstein reasessed, ed. Whiting, H. T. A.. North-Holland. [ESR]Google Scholar
Reed, E. S. (1985) The ecological approach to the evolution of behavior. In: Issues in the ecological study of learning, ed. Johnston, T. & Pietrewicz, A.. Erlbaum. [ESR]Google Scholar
Ritzmann, R. E. & Tobias, M. L. (1980) Flight activity initiated via giant interneurons of the cockroach: Evidence for bifunctional trigger interneurons. Science210:443–45. [taMBB]Google Scholar
Roberts, A., Dale, N., Evoy, W. H. & Soffe, S. R. (1985) Synaptic potentials in motoneurons during fictive swimming in spinal Xenopus embryos. Journal of Neurophysiology54:1–10. [WHE]Google Scholar
Roberts, A., Dale, N. & Soffe, S. R. (1984) Sustained responses to brief stimuli: Swimming in Xenopus embryos. Journal of Experimental Biology112:321–35. [WHE]Google Scholar
Roberts, T. D. M. (1963) Rhythmic excitation of a stretch reflex, revealing (a) hysteresis and (b) a difference between the responses to pulling and to stretching. Quarterly Journal of Experimental Physiology48:328–45. [TDMR]CrossRefGoogle Scholar
Rothwell, J. C., Traub, M. M., Day, B. L., Obeso, J. A., Thomas, P. K. & Marsden, C. D. (1982) Manual motor performance in a deafferented man. Brain105:515–42. [PDN]Google Scholar
Rudomin, P. & Dutton, H. (1969) Effects of conditioning afferent volleys on variability of monosynaptic responses of extensor motoneurons. Journal of Neurophysiology32:130–57. [GEL]Google Scholar
Saltzman, E. (1979) Levels of sensomotor representation. Journal of Mathematical Psychology20:91–163. [taMBB]Google Scholar
Saltzman, E. L. & Kelso, J. A. S. (1983) Skilled actions: A task dynamic approach. Haskins Laboratories Status Reports on Speech Research SR-76, 3–50. [KGM]Google Scholar
Sanes, J. N. & Jennings, V. A. (1984) Centrally programmed patterns of muscle activity in voluntary motor behavior of humans. Experimental Brain Research54:23–32. [rMBB, CG]Google Scholar
Sanes, J. N., Mauritz, K.-H., Dalakas, M. C. & Evarts, E. V. (1985) Motor control in humans with large-fiber sensory neuropathy. Human Neurobiology4:101–14. [rMBB]Google Scholar
Schleidt, W. M. (1974) How “fixed” is the fixed action pattern?Sonderdruck aus Zeitschrift für Tierpsychologie36:184–211. [taMRR, RJ]Google Scholar
Schmidt, R. A. (1975) A schema theory of discrete motor skill learning. Psychological Review82:225–60. [RAS]Google Scholar
Schmidt, R. A. (1982) Motor control and learning: A behavioral emphasis. Human Kinetics Press. [RAS]Google Scholar
Schmidt, R. A. (1980a) On the theoretical status of time in motor-program representations. In: Tutorials in motor behavior, ed. Stelmach, G. E. & Requin, J.. North-Holland. [RAS]Google Scholar
Schmidt, R. A. (1980b) Past and future issues in motor programming. Research Quarterly for Exercise and Sport51:122–40. [taMBB]Google Scholar
Schmidt, R. A. (1982) Motor control and learning: A behavioral emphasis. Human Kinetics Publishers. [taMBB]Google Scholar
Schmidt, R. A. & McGown, C. (1980) Terminal accuracy of unexpectly loaded rapid movements: Evidence for a mass-spring mechanisms in programming. Journal of Motor Behavior12:149–61. [RAS]Google Scholar
Schmidt, R. A. & McCown, C. (1980) Terminal accuracy of unexpectedly loaded rapid movements: Evidence for a mass-spring mechanisms programming. Journal of Motor Behavior12:149–61. [RAS]Google Scholar
Schmidt, R. A., McCown, C., Quinn, J. T. & Hawkins, B. (in press) Unexpected inertial loading in rapid reversal movements: Violations of equifinality. Human Movement Science. [RAS]Google Scholar
Seller, W. (1864) Memoir of the life and writings of Robert Whytt. Transactions of the Royal Society of Edinburgh23:99–131. [ESR]Google Scholar
Selverston, A. I. (1980) Are central pattern generators understandable?Behavioral and Brain Sciences3:535–71. [taMBB]Google Scholar
Shapiro, D. C. & Walter, C. B. (1982) Control of rapid bimanual aiming movements: The effect of a mechanical block. Society for Neuroscience Abstracts, 8:733 (Abstract). [RAS]Google Scholar
Sherrington, C. S. (1906) The integrative action of the nervous system. Yale University Press. [taMBB, PBCM, TRN]Google Scholar
Sherrington, C. S. (1947) Man on his nature. Doubleday. [ESR]Google Scholar
Shik, M. L. (1976) Control of terrestrial locomotion in mammals. In: Physiology of movement, ed. Alekseev, M. A., Gurfinkel, V. S., Kostyuk, P. G., Person, R. S., Shapovalov, A. I. & Shik, M. L.. Nauka. [taMBB]Google Scholar
Shik, M. L. & Orlovsky, C. N. (1976) Neurophysiology of locomotor automatism. Physiological Reviews56:465–501. [taMBB]Google Scholar
Siegler, M. V. S. (1982) Electrical coupling between superhumerary motor neurons in the locust. Journal of Experimental Biology. 101:105–19. [taMBB]Google Scholar
Siegler, M. V. S. (1984) Local interneurons and local interactions in arthropods. Journal of Experimental Biology112:253–81. [WHE]Google Scholar
Sillar, K. T. (1985) Comparative overview and perspectives. In: Coordination of motor behavior, ed. Bush, B. M. H. & Clarac, F.. Society for Experimental Biology Seminar Series, no. 24. Cambridge University Press. [WHE]Google Scholar
Simon, H. A. (1962) The architecture of complexity. Proceedings of the American Philosophical Society106:467–82. [GCA]Google Scholar
Smith, A. P. (1978) An investigation of the mechanisms underlying nest construction in the mud wasp Paralastor sp. (Hymenoptera Eumenidae). Animal Behavior26:332–40. [taMBB]Google Scholar
Smith, J. L., Betts, B., Edgerton, V. R. & Zernicke, R. F. (1980) Rapid ankle extension during paw shakes: Selective recruitment of fast ankle extensors. Journal of Neurophysiology43:612–20. [LDP]Google Scholar
Soechting, J. F., Dufresne, J. R. & Lacquaniti, F. (1981) Time-varying properties of myotatic response in man during some simple motor tasks. Journal of Neurophysiology46:1226–43. [RME, PDN]Google Scholar
Soffe, S. R. (1985) Central coordination of swimming in lower vertebrates. In: Coordination of motor behavior, ed. Bush, B. M. H. & Clarac, F.. Society for Experimental Biology Seminar Series, no. 24. Cambridge University of Press. [WHE]Google Scholar
Sperry, R. (1952) Neurobiology of the mind-brain problem. American Scientist40:291–312. [ESR]Google Scholar
Stanley, W. D. (1975) Digital spinal processing. Reston. [PDN]Google Scholar
Stark, L. (1968) Neurological control systems: Studies in bioengineering. Plenum Press. [WAM]Google Scholar
Steeves, J. D. & Pearson, K. G. (1983) Variability in the structure of an identified interneuron in isogenetic clones of locusts. Journal of Experimental Biology103:47–54. [taMBB]Google Scholar
Stein, P. S. G. (1978) Motor systems, with specific reference to the control of locomotion. Annual Review of Neurosciences1:61–81. [taMBB]Google Scholar
Stein, P. S. G. (1983) The vertebrate scratch reflex. In: Society for Experimental Biology sympoisum XXXVII. Neural origin of rhythmic movements, ed. A. Roberts & B. Roberts. [taMBB]Google Scholar
Stein, P. S. G. & Grossman, M. L. (1980) Central program of stretch reflex in turtle. Journal of Comparative Physiology140:287–94. [taMBB]Google Scholar
Stein, R. B. (1982) What muscle variable(s) does the nervous system control in limb movements?Behavioral and Brain Sciences5:535–77. [taMBB, WDC]Google Scholar
Stevens, P. S. (1974) Patterns in nature. Atlantic Monthly Press. [MTT]Google Scholar
Taub, E. & Berman, A. J. (1968) Movement and learning in the absence of sensory feedback. In: The neurophysiology of spatially oriented behavior, ed. Freedman, S. J.. Dorsey. [PDN]Google Scholar
Terzuolo, C. A., Soechting, J. F. & Dufresne, J. R. (1981) Operational characteristic of reflex response to change in muscle length during different motor tasks and their functional utility. In: Brain mechanisms and perceptual awareness, ed. Pompeiano, O. & Marsan, C. Ajmone. Raven. [PDN]Google Scholar
Thelen, E., Bradshaw, G., Ward, J. A. (1981) Spontaneous kicking in month-old infants: Manifestation of a human central locomotor program. Behavioral and Neural Biology32:45–53. [DJO]Google Scholar
Thom, R. (1985) Less cybernetics, more geometry …Brain and Behavioral Sciences8:166–67. [KGM]Google Scholar
Thrope, W. H. (1979) The origins and rise of ethology. Praeger. [taMBB]Google Scholar
Tinbergen, N. (1950) The hierarchical organization of nervous mechanisms underlying instinctive behaviour. Symposia of the Society for Experimental Biology4:305–12. [taMBB]Google Scholar
Tinbergen, N. (1951) The study of instinct. Oxford University Press. [taMBB]Google Scholar
Tomovic, R. & Bellman, R. (1970) A system approach to muscle control. Mathematical Biosciences8:265–77. [LDP]Google Scholar
Treistman, S. W. & Schwartz, J. H. (1976) Functional constancy in Aplysia nervous system with anomalously duplicated identified neurons. Brain Research109:607–14. [taMBB]Google Scholar
Tuller, B., Kelso, J. A. S. & Harris, K. S. (1982) Interarticulator phasing as an index of temporal regularity in speech. Journal of Experimental Psychology: Human Perception and PerformanceG:460–72. [DJO]Google Scholar
Turvey, M. T. (1977) Preliminaries to a theory of action with reference to vision. In: Perceiving, acting, and knowing, Shaw, R. & Bransford, J.. Erlbaum. [RAS]Google Scholar
Valk-Fai, T. & Crowe, A. (1978) Analyses of the reflex movements in the hind limbs of the terrapin Pseudemys seripta elegans. Journal of Comparative Physiology125:351–57. [taMBB]Google Scholar
Valk-Fai, T. & Crowe, A. (1979) Further analyses of reflex movements in the hind limbs of the terrapin Pseudemys scripta elegans. Journal of Comparative Physiology130:241–49. [taMBB]Google Scholar
Vedel, J.-P. (1982) Reflex reversal resulting from active movements in the antenna of the rock lobster. Journal of Experimental Biology101:121–33. [ZH]Google Scholar
Vincken, M. H., Gielen, C. C. A. M. & Denier van der Gon, I. J. (1983) Intrinsic and afferent components in apparent muscle stiffness in man. Neuroscience9:529–34. [taMBB]Google Scholar
Vincken, M. H., Gielen, C. C. A. M. & Denier van der Gon, I. J. (1984) Stiffness control after fast goal-directed arm movements. Human Movement Sciences3:269–80. [CG]Google Scholar
Viviani, P. & Terzuolo, C. (1982) Trajectory determines movement dynamics. Neuroscience7:431–37. [taMBB]Google Scholar
Waddington, C. H. (1957) The strategy of the genes. Allen & Unwin. [taMBB]Google Scholar
Wadman, W. J., Denier van der Gon, J. J., Geuze, R. H. & Mol, C. R. (1979) Control of fast goal-directed arm movements. Journal of Human Movement Studies5:3–17. [rMBB, CG, RAS]Google Scholar
Wagner, V. (1910) Biological fundamentals for comparative psychology. Vol. 1. [taMBB]Google Scholar
Wallace, S. A. (1981) An impulse-timing theory for reciprocal control of muscular activity in rapid, discrete movements. Journal of Motor Behavior13:144–60. [taMBB, RAS]Google Scholar
Walmsley, B. & Proske, U. (1981) Comparison of stiffness of soleus and medial gastrocnemius muscles in cats. Journal of Neurophysiology46:250–59. [WAM]Google Scholar
Weeks, J. C. (1982) Synaptic basis of swim-initiation in the leech. II. A pattern-generating neuron (cell 208) which mediates motor effects on swim-initiating neurons. Journal of Comparative Physiology148:265–79. [taMBB]Google Scholar
Weiss, P. (1967) 1 + 1 ≠ 2 (when one plus one does not equal two). In: The neurosciences: A study program, ed. Quarton, G. C., Melnechuk, T., Schmitt, F. O.. Rockefeller University Press. [MTT]Google Scholar
Wetzel, M. C. & Stuart, D. G. (1976) Ensemble characteristics of cat locomotion and its neural control. Progress in Neurobiology7:1–98. [taMBB]Google Scholar
Whytt, Robert (1751) An essay on the vital and other involuntary motions of animals. Balfour. [ESR]Google Scholar
Whytt, Robert (1755) Observations on the sensibility and irritability of the parts of men and other animals, occasioned by M. de Haller's late treatise on these subjects. Balfour. [ESR]Google Scholar
Whytt, Robert (1768) Works. Balfour. [ESR]Google Scholar
Wickens, D. D. (1938) The transference of conditioned excitation and conditioned inhibition from one muscle group to the antagonistic muscle group. Journal of Experimental Psychology22:101–23. [ESR]Google Scholar
Wickens, D. D. (1939) The simultaneous transfer of conditioned excitation and inhibition. Journal of Experimental Psychology24:332–38. [ESR]CrossRefGoogle Scholar
Wilkie, D. R. (1954) Facts and theories about muscle. Progress in Biophysics4:288–324. [RME]Google Scholar
Wilson, D. M. (1966) Insect walking. Annual Review of Entomology11:103–22. [taMBB]Google Scholar
Windhorst, U. (1979) A possible partitioning of segmental muscle stretch reflex into incompletely de-coupled parallel loops. Biological Cybernetics34:205–13. [UW]Google Scholar
Wine, J. J. (1984) The structural basis of an innate behavioral pattern. Journal of Experimental Biology112:283–319. [WDC]CrossRefGoogle Scholar
Winter, D. (1984) Kinematic and kinetic patterns in human gait: Variability and compensating effects. Human Movement Science3:51–76. [WAM]Google Scholar
Wolpaw, J. R., O'Keefe, J. A. & Dowman, R. (1984) Adaptive plasticity in primate spinal stretch reflex (SSR): A two-phase process. Society for Neuroscience Abstracts10:129. [rMBB, TRN]Google Scholar
Young, R. M. (1971) Mind, brain, and adaptation in the nineteenth century. Cambridge University Press. [ESR]Google Scholar
Ziegler, H. E. (1911) Der Begriff des Instinktes einst und jetzt. Berlin. [taMBB]Google Scholar