Participants in two experiments moved a mouse-like device to the right to move a cursor on a computer screen to a target position. The cursor was invisible during motion but reappeared at the end of each movement. The relationship between the amplitudes of the cursor movement and the mouse movement was exponential in Experiment 1 and logarithmic in Experiment 2 for two groups of participants, while it was linear for the control groups in both experiments. The results of both experiments indicate that participants adjusted well to the external transformation by developing an internal model that approximated the inverse of the external transformation. We introduce a method to determine the locus of the internal model. It indicates that the internal model works at a processing level that either preceded specification of movement amplitude, or had become part of movement amplitude specification. Limited awareness of the nonlinear mouse–cursor relationship and the fact that a working-memory task had little effect on performance suggest that the internal model is modular and not dependent on high-level cognitive processes.
Get full access to this article
View all access options for this article.
References
1.
AbramsR. A.van DillenL.StemmonsV. (1994). Multiple sources of spatial information for aimed limb movements.Attention and performance: XV. Conscious and nonconscious processing. UmiltàC.MoscovitchM.Cambridge, MA: MIT Press267–290.
2.
BedfordF. L. (1989). Constraints on learning new mappings between perceptual dimensions.Journal of Experimental Psychology: Human Perception and Performance15, 232–248.
3.
BedfordF. L. (1994). Of computer mice and men.Cahier de Psychologie Cognitive13, 405–426.
4.
BockO.AbeeleS.EversheimU. (2003). Human adaptation to rotated vision: Interplay of a continuous and a discrete process.Experimental Brain Research152, 528–532.
5.
BockO.BurghoffM. (1997). Visuo-motor adaptation: Evidence for a distributed amplitude control system.Behavioral Brain Research89, 267–273.
6.
ClowerD. M.BoussaoudD. (2000). Selective use of perceptual recalibration versus visuomotor skill acquisition.Journal of Neurophysiology84, 2703–2708.
7.
CruseH.BrüwerM. (1987). The human arm as a redundant manipulator: The control of path and joint angles.Biological Cybernetics57, 137–144.
8.
CunninghamH. A. (1989). Aiming error under transformed spatial mappings suggests a structure for visual-motor maps.Journal of Experimental Psychology: Human Perception and Performance15, 493–506.
9.
CunninghamH. A.WelchR. B. (1994). Multiple concurrent visual-motor mappings: Implications for models of adaptation.Journal of Experimental Psychology: Human Perception and Performance20, 987–999.
10.
FlanaganJ. R.RaoA. (1995). Trajectory adaptation to a nonlinear visuomotor transformation: Evidence of motion planning in visually perceived space.Journal of Neurophysiology74, 2174–2178.
11.
FlashT.HoganN. (1985). The coordination of arm movements: An experimentally confirmed mathematical model.Journal of Neuroscience5, 1688–1703.
12.
FodorJ. A. (1983). Modularity of mindCambridge, MA: MIT Press.
13.
GhahramaniZ.WolpertD. M. (1997). Modular decomposition in visuomotor learning.Nature386, 392–395.
14.
GhezC.FavillaM.GhilardiM. F.GordonJ.BermejoR.PullmanS. (1997). Discrete and continuous planning of hand movements and isometric force trajectories.Experimental Brain Research115, 217–233.
15.
GoodaleM. A.PelissonD.PrablancC. (1986). Large adjustments in visually guided reaching do not depend on vision of the hand or perception of target displacement.Nature320, 748–750.
16.
GottsdankerR. M. (1952). The accuracy of prediction motion.Journal of Experimental Psychology43, 26–36.
17.
GottsdankerR. M. (1955). A further study of prediction-motion.American Journal of Psychology68, 432–437.
18.
HarrisC. M.WolpertD. M. (1998). Signal-dependent noise determines motor planning.Nature394, 780–784.
19.
HayJ. C. (1974). Motor transformation learning.Perception3, 487–496.
20.
HelsenW. F.ElliottD.StarkesJ. L.RickerK. L. (1998). Temporal and spatial coupling of point of gaze and hand movements in aiming.Journal of Motor Behavior30, 249–259.
21.
HeningW.FavillaM.GhezC. (1988). Trajectory control in targeted force impulses. V. Gradual specification of response amplitude.Experimental Brain Research71, 116–128.
22.
HeuerH. (2003). Motor control.Handbook of psychology: Vol. 4. Experimental psychology. HealeyA. F.ProctorR. W.New York: Wiley317–354.
23.
HeuerH.SangalsJ. (1998). Task-dependent mixtures of coordinate systems in visuomotor transformations.Experimental Brain Research119, 224–236.
24.
InoueK.KawashimaR.SatohK.KinomuraS.SugiuraM.GotoR. (2000). A PET study of visuomotor learning and optical rotation.NeuroImage11, 505–516.
25.
JeannerodM. (1999). To act or not to act: Perspectives on the representation of actions.Quarterly Journal of Experimental Psychology52A, 1–29.
26.
JordanM. I. (1996). Computational aspects of motor control and motor learning.Handbook of perception and action: Vol. 2. Motor skills. HeuerH.KeeleS. W.London: Academic Press71–120.
27.
KawatoM. (1996). Bidirectional theory approach to integration.Attention and performance: XVI. Information integration in perception and communication. InuiT.McClellandJ. L.Cambridge, MA: MIT Press335–367.
28.
KhanM. A.LawrenceG.FourkasA.FranksI. M.ElliottD.PembrokeS. (2003). Online versus offline processing of visual feedback in the control of movement amplitude.Acta Psychologica113, 83–97.
29.
KnoblichG.KircherT. T. J. (2004). Deceiving oneself about being in control: Conscious detection of changes in visuomotor coupling.Journal of Experimental Psychology: Human Perception and Performance30, 657–666.
30.
KohK.MeyerD. E. (1991). Function learning: Induction of continuous stimulus–response relations.Journal of Experimental Psychology: Learning, Memory and Cognition17, 811–836.
31.
KrakauerJ. W.PineZ. M.GhilardiM. F.GhezC. (2000). Learning of visuomotor transformations for vectorial planning of reaching trajectories.Journal of Neuroscience20, 8916–8924.
32.
KundeW.KochI.HoffmannJ. (2004). Anticipated action effects affect the selection, initiation and execution of actions.Quarterly Journal of Experimental Psychology57A, 87–106.
33.
KurataK.HoshiE. (1999). Reacquisition deficits in prism adaptation after muscimol microinjection into the ventral remotor cortex of monkeys.Journal of Neurophysiology81, 1927–1938.
34.
PoultonE. C. (1980). Range effects and asymmetric transfer in studies of motor skill.Psychology of motor behavior and sport–1979. NadeauC. H.HalliwellW. R.NewellK. M.RobertsG. C.Champaign, IL: Human Kinetics Publishers339–359.
35.
PoultonE. C. (1989). Bias in quantifying judgmentsHove, UK: Lawrence Erlbaum Associates, Inc.
36.
PragerA. D.Contreras-VidalJ. L. (2003). Adaptation to display rotation and display gain distortions during drawing.Human Movement Science22, 173–187.
37.
PrattJ.AbramsR. A. (1996). Practice and component submovements: The roles of programming and feedback in rapid aimed limb movements.Journal of Motor Behavior28, 149–156.
38.
ReddingG. M.WallaceB. (1992). Adaptive eye–hand coordination: Implications of prism adaptation for perceptual-motor organization.Vision and motor control. ProteauL.ElliottD.Amsterdam: North Holland105–127.
39.
RiegerM.KnoblichG.PrinzW. (2005). Compensation for and adaptation to changes in the environment.Experimental Brain Research163, 487–502.
40.
SchmidtR. A.ZelaznikH. N.HawkinsB.FrankJ. S.QuinnJ. T. (1979). Motor-output variability: A theory for the accuracy of rapid motor acts.Psychological Review86, 415–451.
41.
SeidlerR. D.BloombergJ. J.StelmachG. E. (2001). Patterns of transfer of adaptation among body segments.Behavioural Brain Research122, 145–157.
42.
TodorovE.JordanM. I. (2002). Optimal feedback control as a theory of motor coordination.Nature Neuroscience5, 1226–1235.
43.
van BeersR. J.HaggardP.WolpertD. M. (2004). The role of execution noise in movement variability.Journal of Neurophysiology91, 1050–1063.
44.
van GalenG. P.SchomakerL. R. B. (1992). Fitts’ law as a low-pass filter effect of muscle stiffness.Human Movement Science11, 11–21.
45.
VoigtE. (1933). über den Aufbau von Bewegungsgestalten.Neue psychologische Studien9, 1–32.
46.
WagenaarW. A.SagariaS. D. (1975). Misperception of exponential growth.Perception & Psychophysics18, 416–422.
47.
WelchR. B.BridgemanB.AnandS.BrownmanK. (1993). Alternating prism exposure causes dual adaptation and generalization to a novel displacement.Perception & Psychophysics54, 195–204.
48.
WolpertD. M.GhahramaniZ.JordanM. I. (1995). Are arm trajectories planned in kinematic or dynamic coordinates? An adaptation study.Experimental Brain Research103, 460–470.
49.
WulfG.PrinzW. (2001). Directing attention to movement effects enhances learning: A review.Psychonomic Bulletin & Review8, 648–660.
