Relative errors can cue absolute visuomotor mappings

van Dam, Loes; Ernst, Marc O.

Relative errors can cue absolute visuomotor mappings

van Dam L, Ernst MO (2015)
Experimental Brain Research 233(12): 3367-3377.

Zeitschriftenaufsatz | Veröffentlicht | Englisch

Download

Es wurden keine Dateien hochgeladen. Nur Publikationsnachweis!

DOI

https://doi.org/10.1007/s00221-015-4403-9

Autor*in

van Dam, Loes^UniBi ; Ernst, Marc O.^UniBi

Einrichtung

Fakultät für Biologie > Kognitive Neurowissenschaften
Center of Excellence - Cognitive Interaction Technology CITEC

Erscheinungsjahr

2015

Zeitschriftentitel

Experimental Brain Research

Band

233

Ausgabe

12

Seite(n)

3367-3377

ISSN

0014-4819

eISSN

1432-1106

Page URI

https://pub.uni-bielefeld.de/record/2752996

Zitieren

van Dam L, Ernst MO. Relative errors can cue absolute visuomotor mappings. Experimental Brain Research. 2015;233(12):3367-3377.

van Dam, L., & Ernst, M. O. (2015). Relative errors can cue absolute visuomotor mappings. Experimental Brain Research, 233(12), 3367-3377. doi:10.1007/s00221-015-4403-9

van Dam, Loes, and Ernst, Marc O. 2015. “Relative errors can cue absolute visuomotor mappings”. Experimental Brain Research 233 (12): 3367-3377.

van Dam, L., and Ernst, M. O. (2015). Relative errors can cue absolute visuomotor mappings. Experimental Brain Research 233, 3367-3377.

van Dam, L., & Ernst, M.O., 2015. Relative errors can cue absolute visuomotor mappings. Experimental Brain Research, 233(12), p 3367-3377.

L. van Dam and M.O. Ernst, “Relative errors can cue absolute visuomotor mappings”, Experimental Brain Research, vol. 233, 2015, pp. 3367-3377.

van Dam, L., Ernst, M.O.: Relative errors can cue absolute visuomotor mappings. Experimental Brain Research. 233, 3367-3377 (2015).

van Dam, Loes, and Ernst, Marc O. “Relative errors can cue absolute visuomotor mappings”. Experimental Brain Research 233.12 (2015): 3367-3377.

Daten bereitgestellt von European Bioinformatics Institute (EBI)

1 Zitation in Europe PMC

Daten bereitgestellt von Europe PubMed Central.

Optimal visual-haptic integration with articulated tools.
Takahashi C, Watt SJ., Exp Brain Res 235(5), 2017
PMID: 28214998

27 References

Daten bereitgestellt von Europe PubMed Central.

GP, J Exp Psychol Hum Percept Perform 25(5), 1999

A color-contingent prism displacement aftereffect.
Donderi DC, Jolicoeur P, Berg I, Grimes R., Perception 14(6), 1985
PMID: 3837871

MO, 2001

Learning motor synergies makes use of information on muscular load.
Fernandez-Ruiz J, Hall-Haro C, Diaz R, Mischner J, Vergara P, Lopez-Garcia JC., Learn. Mem. 7(4), 2000
PMID: 10940319

Rapid topographical plasticity of the visuomotor spatial transformation.
Fernandez-Ruiz J, Diaz R, Moreno-Briseno P, Campos-Romo A, Ojeda R., J. Neurosci. 26(7), 2006
PMID: 16481431

Serial adaptation to conflicting prismatic rearrangement effects in monkey and man.
Flook JP, McGonigle BO., Perception 6(1), 1977
PMID: 402637

Gaze-contingent prism adaptation: optical and motor factors.
Hay JC, Pick HL Jr., J Exp Psychol 72(5), 1966
PMID: 5972002

Implicit and explicit components of dual adaptation to visuomotor rotations.
Hegele M, Heuer H., Conscious Cogn 19(4), 2010
PMID: 20537562

The efficacy of colour cues in facilitating adaptation to opposing visuomotor rotations.
Hinder MR, Woolley DG, Tresilian JR, Riek S, Carson RG., Exp Brain Res 191(2), 2008
PMID: 18679663

Does the motor control system use multiple models and context switching to cope with a variable environment?
Karniel A, Mussa-Ivaldi FA., Exp Brain Res 143(4), 2002
PMID: 11914799

Bayesian integration in sensorimotor learning.
Kording KP, Wolpert DM., Nature 427(6971), 2004
PMID: 14724638

JH, Percept Psychophys 11(1A), 1972

JH, Percept Psychophys 12(3), 1972

Conditioned adaptation to prismatic displacement: training trials and decay.
Kravitz JH, Yaffe FL., J Exp Psychol 102(2), 1974
PMID: 4811940

Throwing while looking through prisms. II. Specificity and storage of multiple gaze-throw calibrations.
Martin TA, Keating JG, Goodkin HP, Bastian AJ, Thach WT., Brain 119 ( Pt 4)(), 1996
PMID: 8813283

Long-term retention of single and multistate prismatic adaptation by humans.
McGonigle BO, Flook J., Nature 272(5651), 1978
PMID: 634364

Adaptation to split-field wedge prism spectacles.
Pick HL Jr, Hay JC, Martin R., J Exp Psychol 80(1), 1969
PMID: 5787407

Dual prism adaptation: calibration or alignment?
Redding GM, Wallace B., J Mot Behav 35(4), 2003
PMID: 14607776

Are people adapted to their own glasses?
Schot WD, Brenner E, Sousa R, Smeets JB., Perception 41(8), 2012
PMID: 23362676

Context-dependent arm pointing adaptation.
Seidler RD, Bloomberg JJ, Stelmach GE, Bloomberg JJ., Behav. Brain Res. 119(2), 2001
PMID: 11165331

Sensory integration does not lead to sensory calibration.
Smeets JB, van den Dobbelsteen JJ, de Grave DD, van Beers RJ, Brenner E., Proc. Natl. Acad. Sci. U.S.A. 103(49), 2006
PMID: 17130453

Interacting adaptive processes with different timescales underlie short-term motor learning.
Smith MA, Ghazizadeh A, Shadmehr R., PLoS Biol. 4(6), 2006
PMID: 16700627

LCJ, PLoS Comput Biol (), 2015

LCJ, J Vis (), 2013

RB, Percept Psychophys 10(2), 1971

Alternating prism exposure causes dual adaptation and generalization to a novel displacement.
Welch RB, Bridgeman B, Anand S, Browman KE, Welch RB., Percept Psychophys 54(2), 1993
PMID: 8361835

Dual adaptation to two opposing visuomotor rotations when each is associated with different regions of workspace.
Woolley DG, Tresilian JR, Carson RG, Riek S., Exp Brain Res 179(2), 2006
PMID: 17119942

Export

Markieren/ Markierung löschen
Markierte Publikationen

Open Data PUB