The role of different submovement types during pointing to a target (original) (raw)
Abrams RA, Pratt J (1993) Rapid aimed limb movements: differential effects of practice on component submovements. J Mot Behav 25:288–298 ArticlePubMedCAS Google Scholar
Adam JJ, Paas F (1996) Dwell time in reciprocal aiming tasks. Hum Mov Sci 15:1–24 Article Google Scholar
Adam JJ, Vanderbruggen DPW, Bekkering H (1993) The control of discrete and reciprocal target-aiming responses—evidence for the exploitation of mechanics. Hum Mov Sci 12:353–364 Article Google Scholar
Adamovich SV, Levin MF, Feldman AG (1994) Merging different motor patterns—coordination between rhythmical and discrete single-joint movements. Exp Brain Res 99:325–337 ArticlePubMedCAS Google Scholar
Almeida GL, Hong DA, Corcos D, Gottlieb GL (1995) Organizing principles for voluntary movement—extending single-joint rules. J Neurophys 74:1374–1381 CAS Google Scholar
Bedard P, Proteau L (2004) On-line vs. off-line utilization of peripheral visual afferent information to ensure spatial accuracy of goal-directed movements. Exp Brain Res 158:75–85 ArticlePubMed Google Scholar
Berardelli A, Hallett M, Rothwell JC, Agostino R, Manfredi M, Thompson PD, Marsden CD (1996) Single-joint rapid arm movements in normal subjects and in patients with motor disorders. Brain 119:661–674 PubMed Google Scholar
Buchanan JJ, Park JH, Ryu YU, Shea CH (2003) Discrete and cyclical units of action in a mixed target pair aiming task. Exp Brain Res 150:473–489 PubMed Google Scholar
Buchanan JJ, Park JH, Shea CH (2004) Systematic scaling of target width: dynamics, planning, and feedback. Neurosci Lett 367:317–322 ArticlePubMedCAS Google Scholar
Carlton LG (1992) Visual processing time and the control of movement. In: Proteau L, Elliott D (eds) Vision and motor control. Elsevier, New York, Amsterdam, pp 3–31
Christou EA, Carlton LG (2002) Motor output is more variable during eccentric compared with concentric contractions. Med Sci Sports Exerc 34:1773–1778 ArticlePubMed Google Scholar
Chua R, Elliott D (1993) Visual regulation of manual aiming. Hum Mov Sci 12:365–401 Article Google Scholar
Crossman E, Goodeve PJ (1983) Feedback-control of hand-movement and fitts law. Q J Exp Psych A Hum Exp Psych 35:251–278 CAS Google Scholar
Desmurget M, Grafton S (2000) Forward modeling allows feedback control for fast reaching movements. Trends Cogn Sci 4:423–431 ArticlePubMed Google Scholar
Dounskaia N, Ketcham CJ, Stelmach GE (2002a) Commonalities and differences in control of various drawing movements. Exp Brain Res 146:11–25 ArticleCAS Google Scholar
Dounskaia NV, Ketcham CJ, Stelmach GE (2002b) Influence of biomechanical constraints on horizontal arm movements. Motor Control 6:366–387 Google Scholar
Dounskaia N, Wisleder D, Johnson T (2005) Influence of biomechanical factors on substructure of pointing movements. Exp Brain Res 164:505–516 ArticlePubMed Google Scholar
Elliott D, Helsen WF, Chua R (2001) A century later: Woodworth’s (1899) two-component model of goal-directed aiming. Psychol Bull 127:342–357 ArticlePubMedCAS Google Scholar
Enoka RM (1994) Neuromechanical basis of kinesiology. Human Kinetics, Champaign, IL Google Scholar
Fitts PM (1954) The information capacity of the human motor system in controlling the amplitude of movement. J Exp Psychol 47:381–391 ArticlePubMedCAS Google Scholar
Ghez C, Gordon J, Ghilardi MF, Sainburg RL (1994) Contributions of vision and proprioception to accuracy in limb movements. In: Gazzaniga MS (ed) The cognitive neurosciences. MIT Press, Cambridge, MA, pp 549–564 Google Scholar
Gordon J, Ghilardi MF, Cooper SE, Ghez C (1994) Accuracy of planar reaching movements. II. Systematic extent errors resulting from inertial anisotropy. Exp Brain Res 99:112–130 PubMedCAS Google Scholar
Gottlieb GL (1998) Muscle activation patterns during two types of voluntary single-joint movement. J Neurophys 80:1860–1867 CAS Google Scholar
Gribble PL, Ostry DJ (1999) Compensation for interaction torques during single- and multijoint limb movement. J Neurophys 82:2310–2326 CAS Google Scholar
Guiard Y (1993) On Fitts’s and Hooke’s laws: simple harmonic movement in upper-limb cyclical aiming. Acta Psychol (Amst) 82:139–159 ArticleCAS Google Scholar
Guiard Y (1997) Fitts’ law in the discrete vs cyclical paradigm. Hum Mov Sci 16:97–131 Article Google Scholar
Hallett M, Shahani BT, Young RR (1975) EMG analysis of stereotyped voluntary movements in man. J Neurol Neurosurg Psychiatry 38:1154–1162 ArticlePubMedCAS Google Scholar
Hannaford B, Stark L (1985) Roles of the elements of the triphasic control signal. Exp Neurol 90:619–634 ArticlePubMedCAS Google Scholar
Hogan N (1985) The mechanics of multi-joint posture and movement control. Biol Cybern 52:315–331 ArticlePubMedCAS Google Scholar
Hollerbach JM, Flash T (1982) Dynamic interactions between limb segments during planar arm movement. Biol Cybern 44:67–77 ArticlePubMedCAS Google Scholar
Kelso JAS (1992) Theoretical concepts and strategies for understanding perceptual-motor skill—from information capacity in closed systems to self-organization in open, nonequilibrium systems. J Exp Psych Gen 121:260–261 ArticleCAS Google Scholar
Ketcham CJ, Seidler RD, Van Gemmert AW, Stelmach GE (2002) Age-related kinematic differences as influenced by task difficulty, target size, and movement amplitude. J Gerontol B Psychol Sci Soc Sci 57:P54–P64 PubMed Google Scholar
Khan MA, Franks IM (2003) Online versus offline processing of visual feedback in the production of component submovements. J Mot Behav 35:285–295 ArticlePubMed Google Scholar
Khan MA, Lawrence G, Fourkas A, Franks IM, Elliott D, Pembroke S (2003) Online versus offline processing of visual feedback in the control of movement amplitude. Acta Psychol (Amst) 113:83–97 Article Google Scholar
Meulenbroek RGJ, Thomassen A (1993) Exploitation of elasticity as a biomechanical property in the production of graphic stroke sequences. Acta Psychologica 82:313–327 ArticlePubMedCAS Google Scholar
Meulenbroek RGJ, Vinter A, Desbiez D (1998) Exploitation of elasticity in copying geometrical patterns: the role of age, movement amplitude, and limb-segment involvement. Acta Psychol (Amst) 99:329–345 ArticleCAS Google Scholar
Meulenbroek RGJ, Van Galen GP, Hulstijn M, Hulstijn W, Bloemsaat G (2005) Muscular co-contraction covaries with task load to control the flow of motion in fine motor tasks. Biol Psychol 68:331–352 ArticlePubMed Google Scholar
Meyer DE, Abrams RA, Kornblum S, Wright CE, Smith JE (1988) Optimality in human motor performance: ideal control of rapid aimed movements. Psychol Rev 95:340–370 ArticlePubMedCAS Google Scholar
Novak KE, Miller LE, Houk JC (2000) Kinematic properties of rapid hand movements in a knob turning task. Exp Brain Res 132:419–433 ArticlePubMedCAS Google Scholar
Pratt J, Chasteen AL, Abrams RA (1994) Rapid aimed limb movements: age differences and practice effects in component submovements. Psychol Aging 9:325–334 ArticlePubMedCAS Google Scholar
Rand MK, Stelmach GE, Bloedel JR (2000) Movement accuracy constraints in parkinson’s disease patients. Neuropsychologia 38:203–212 ArticlePubMedCAS Google Scholar
Sainburg RL, Poizner H, Ghez C (1993) Loss of proprioception produces deficits in interjoint coordination. J Neurophysiol 70:2136–2147 PubMedCAS Google Scholar
Sainburg RL, Ghilardi MF, Poizner H, Ghez C (1995) Control of limb dynamics in normal subjects and patients without proprioception. J Neurophysiol 73:820–835 PubMedCAS Google Scholar
Sainburg RL, Ghez C, Kalakanis D (1999) Intersegmental dynamics are controlled by sequential anticipatory, error correction, and postural mechanisms. J Neurophysiol 81:1045–1056 PubMedCAS Google Scholar
Saunders JA, Knill DC (2003) Humans use continuous visual feedback from the hand to control fast reaching movements. Exp Brain Res 152:341–352 ArticlePubMed Google Scholar
Schmidt RA, Zelaznik HN, Frank JS (1978) Sources of inaccuracy in rapid movements. In: Stelmach GE (ed) Information processing in motor control and learning. Academic, New York, pp 183–203 Google Scholar
Schmidt RA, Zelaznik H, Hawkins B, Frank JS, Quinn JT (1979) Motor-output variability: a theory for the accuracy of rapid motor acts. Psychol Rev 47:415–451 ArticlePubMedCAS Google Scholar
Schoner G (1990) A dynamic theory of coordination of discrete movement. Biol Cybern 63:257–270 ArticlePubMedCAS Google Scholar
Seidler Dobrin RD, Stelmach GE (1998) Persistence in visual feedback control by the elderly. Exp Brain Res 119:467–474 ArticlePubMedCAS Google Scholar
Smits-Engelsman BCM, Van Galen GP, Duysens J (2002) The breakdown of Fitts’ law in rapid, reciprocal aiming movements. Exp Brain Res 145:222–230 ArticlePubMedCAS Google Scholar
Sternad D, Dean WJ, Schaal S (2000) Interaction of rhythmic and discrete pattern generators in single-joint movements. Hum Mov Sci 19:627–664 Article Google Scholar
Tunik E, Poizner H, Levin MF, Adamovich SV, Messier J, Lamarre Y, Feldman AG (2003) Arm-trunk coordination in the absence of proprioception. Exp Brain Res 153:343–355 ArticlePubMedCAS Google Scholar
Van Galen GP, Dejong WP (1995) Fitts law as the outcome of a dynamic noise filtering model of motor control. Hum Mov Sci 14:539–571 Article Google Scholar
Van Galen GP, Schomaker LRB (1992) Fitts law as a low-pass filter effect of muscle-stiffness. Hum Mov Sci 11:11–21 Article Google Scholar
Van Galen GP, Van Huygevoort M (2000) Error, stress and the role of neuromotor noise in space oriented behaviour. Biol Psych 51:151–171 Article Google Scholar
Walker N, Philbin DA, Fisk AD (1997) Age-related differences in movement control: adjusting submovement structure to optimize performance. J Gerontol B Psychol Sci Soc Sci 52:P40–P52 PubMedCAS Google Scholar
Woodworth R (1899) The accuracy of voluntary movement. Psychol Rev Suppl 3:1–119 Google Scholar
Zelaznik HN, Hawkins B, Kisselburgh L (1983) Rapid visual feedback processing in single-aiming movements. J Motor Behavior 15:217–236 CAS Google Scholar