Abstract
A model of a pre-planned single joint movements performed without feedback is considered. Modifications of this movement result from transformation of a trajectory pattern f(t) in space and time. The control system adjusts the movement to concrete external conditions specifying values of the transform parameters before the movement performance. The preplanned movement is considered to be simple one, if the transform can be approximated by an affine transform of the movement space and time. In this case, the trajectory of the movement is x(t) = Af(t/τ + s) +p, were A and 1/τ are space and time scales, s and p are translations. The variability of movements is described by time profiles of variances and covariances of the trajectory x(t), velocity v(t), and acceleration a(t). It is assumed that the variability is defined only by parameters variations. From this assumption follows the main finding of this work: the variability time profiles can be expanded on a special system of basic functions corresponding to established movement parameters. Particularly, basic functions of variance time profiles, reflecting spatial and temporal scaling, are x 2(t) and t 2 v 2(t) for trajectory, v 2(t) and (v(t) + t · a(t))2 for velocity, and a 2(t) and (2a(t) +t · j(t))2, where j(t) = d3 x(t)/dt 3, for acceleration. The variability of a model of a reaching movement was studied analytically. The model predicts certain peculiarities of the form of time profiles (e.g., the variance time profile of velocity is bi-modal, the one of acceleration is tri-modal, etc.). Experimental measurements confirmed predictions. Their consistence allows them to be considered invariant properties of reaching movement. A conclusion can be made, that reaching movement belongs to the type of simple preplanned movements. For a more complex movement, time profiles of variability are also measured and explained by the model of movements of this type. Thus, a movement can be attributed to the type of simple pre-planned ones by testing its variability.
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References
Abend W, Bizzi E, Morasso P (1982) Human arm trajectory formation. Brain 105:331–348
Atkeson CG, Hollerbach JM (1985) Kinematic features of unrestrained vertical arm movements. J Neurosci 5:2318–2320
Berkenblit MB, Feldman AG, Fukson OI (1986) Adaptability of innate motor patterns and motor control mechanisms. Behav Brain Sci 9:585–638
Bernstein NA (1935) The problem of interrelation between coordination and localization. Arch Biol Sci 38:1–35 (in Russian)
Bernstein NA (1967) The co-ordination and regulation of movements. Pergamon Press, Oxford
Bullock D, Grossberg S (1988) Neural dynamics of planned arm movements: Emergent invariants and speed-accuracy properties during trajectory formation. Psychol Rev 95:49–90
Carter MC, Shapiro DC (1984) Control of sequential movements: Evidence for generalized motor Programs. J Neurophysiol 52:787–796
Corcos DM, Gottlieb GL, Agarwal GC (1988) Accuracy constraints upon rapid elbow movements. J Motor Behav 20:255–272
Corcos DM, Gutman SR, Agarwal GC, Gottlieb GL (1991) Movement strategies and the necessity for task differentiation. Behav Brain Sci 14:359–364
Darling WG, Cole KJ, Abbs JH (1988) Kinematic variability of grasp movements as a function of practice and movement speed. Exp Brain Res 73:225–235
Darling WG, Cooke JD (1987) Changes in the variability of movement trajectories with practice. J Motor Behav 19:291–309
Fitts PM (1954) The information capacity of the human motor system in controlling the amplitude of movement. J Exp Psychol 47:381–391
Flash T, Hogan N (1985) The coordination of arm movements: An experimentally confirmed mathematical model. J Neurosci 5:1688–1703
Gottlieb GL, Corcos DM, Agarwal GC (1989) Strategies for the control of voluntary movements with one mechanical degree of freedom. Behav Brain Sci 12:189–250
Gutman SR, Gottlieb GL (1990) Nonlinear “inner time” in reaching movement trajectory formation. Abstr 1-st World Congress Biomechanics, San Diego, CA.
Gutman SR, Gottlieb GL, Latash ML (1991) Temporal patterns of variability in trajectory, velocity, and acceleration of movement. 21-st Annual Meeting of the Society for Neuroscience. Abstracts 1:938, New Orleans
Gutman SR, Gottlieb GL, Corcos DM (1992) Exponential model of a reaching movement trajectory with non-linear time. Comm Theor Biol 5:357–384
Hogan N (1984) An organizational principle for a class of voluntary movements. J Neurosci 4:2745–2754
Hughes BG, Stelmach GE (1986) On Bernstein as a contributor to cognitivist theory of motor behavior. J Hum Movement Sci 5:35–45
Latash ML, Gottlieb GL (1990) Equilibrium-point hypothesis and variability of the amplitude, speed and time of single-joint movements. Biofizika 35:870–874
Latash ML, Gottlieb GL (1991) An equilibrium-point model of dynamic regulation for fast single-joint movements: II. Similarity of isometric and isotonic programs. J Motor Behav 23:179–191
Latash ML, Gutman SR (in press) Variability of fast single-joint movements and the equilibrium-point hypothesis. In: Newell K, Corcos DM (eds) Variability and motor control. Human Kinetics, Urbana
Meyer DE, Smith JEK, Wright CE (1982) Model for the speed and accuracy of aimed movements. Psychol Rev 89:445–482
Meyer DE, Abrams RA, Kornblum S, Wright CE, Smith J (1988) Optimality in human motor performance. Ideal control of rapid aimed movements. Psychol Rev 95:340–370
Morasso P (1981) Spatial control of arm movements. Exp Brain Res 42:223–227
Plamondon R, YuLD, Stelmach GE, Clement B (1991) On the automatic extraction of biomechanical information from handwriting signal. IEEE Trans Syst Man Cybern 21:90–101
Schmidt RA (1975) A schema theory of discrete motor skill learning. Psychol Rev 82:225–260
Schmidt RA (1976) control processes in motor skills. Exercise Sport Sci Rev 4:229–261
Schmidt RA, Zelaznik H, Hawkins B, Franks JS, Quinn JT (1979) Motor output variability: A theory for the accuracy of rapid motor acts. Psychol Rev 86:415–451
Soechting JF, Lacquaniti F (1981) Invariant characteristics of a pointing movement in man. J Neurosci 1:710–720
Turvey MT (1977) Preliminaries to a theory of action with reference to vision. In: Show N, Bransford J (eds) Perceiving, acting, and knowing: toward an ecological psychology. Erlbaum, Hillsdale
Van der Meulen JHP, Gooskens RHJM, Denier van der Gon JJ, Gielen CCAM, Wilhelm K (1990) Mechanisms underlying accuracy in fast goal-directed arm movements in man. J Motor Behav 22:67–84
Viviani P, Terzuolo C (1980) Space-time invariance in learned motor skills. In: Stelmach GE, Requin J (eds) Tutorial in motor behavior. North-Holland, Amsterdam, pp 525–533
Woodsworth RS (1889) The accuracy of the voluntary movement. Psychol Rev (suppl) 13:1–114
Wright CE, Meyer DE (1983) Conditions for a linear speed-accuracy trade-off in aimed movements. Q J Exp Psychol 35A:279–296
Zelaznik HN, Mone S, McCabe GP, Thaman C (1988) Role of temporal and spatial precision in determining the nature of the speed-accuracy trade-off in aimed-hand movement. J Exp Psychol Hum Percept Perform 14:221–230
Zelaznik HN, Schmidt RA, Gielen SCAM (1986) Kinematic properties of rapid aimed hand movements. J Motor Behav 18:353–372
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Gutman, S.R., Gottlieb, G.L. Basic functions of variability of simple pre-planned movements. Biol. Cybern. 68, 63–73 (1992). https://doi.org/10.1007/BF00203138
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DOI: https://doi.org/10.1007/BF00203138