Sequence aiming movement between nervous systems

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Sequence aiming movement between nervous systems. / Roberts, James; Lawrence, Gavin.
Journal of Exercise, Movement, and Sport: SCAPPS refereed abstracts repository. Vol. 50 1. ed. 2018. p. 64.

Research output: Chapter in Book/Report/Conference proceedingConference contributionpeer-review

HarvardHarvard

Roberts, J & Lawrence, G 2018, Sequence aiming movement between nervous systems. in Journal of Exercise, Movement, and Sport: SCAPPS refereed abstracts repository. 1 edn, vol. 50, pp. 64. <http://www.scapps.org/jems/index.php/1/issue/view/10>

APA

Roberts, J., & Lawrence, G. (2018). Sequence aiming movement between nervous systems. In Journal of Exercise, Movement, and Sport: SCAPPS refereed abstracts repository (1 ed., Vol. 50, pp. 64) http://www.scapps.org/jems/index.php/1/issue/view/10

CBE

Roberts J, Lawrence G. 2018. Sequence aiming movement between nervous systems. In Journal of Exercise, Movement, and Sport: SCAPPS refereed abstracts repository. 1 ed. pp. 64.

MLA

Roberts, James and Gavin Lawrence "Sequence aiming movement between nervous systems". Journal of Exercise, Movement, and Sport: SCAPPS refereed abstracts repository. 1 udg., 2018, 64.

VancouverVancouver

Roberts J, Lawrence G. Sequence aiming movement between nervous systems. In Journal of Exercise, Movement, and Sport: SCAPPS refereed abstracts repository. 1 ed. Vol. 50. 2018. p. 64

Author

Roberts, James ; Lawrence, Gavin. / Sequence aiming movement between nervous systems. Journal of Exercise, Movement, and Sport: SCAPPS refereed abstracts repository. Vol. 50 1. ed. 2018. pp. 64

RIS

TY - GEN

T1 - Sequence aiming movement between nervous systems

AU - Roberts, James

AU - Lawrence, Gavin

PY - 2018/10/21

Y1 - 2018/10/21

N2 - In two target aiming sequences, movement times to the first target are typically longer compared to single target responses – something referred to as the one-target advantage (OTA). Recent evidence has shown this advantage unfolds both within and between limbs, suggesting it emanates from a central representation. In a separate line of evidence, the involuntary movement interference or facilitation invoked by the concurrent observation of another moving agent has supported the view of a correspondence between perception and action. The following study explores the potential of the OTA unfolding between, as well as within, nervous systems. Thus, we had participants execute a fast-and-accurate aim to a single target (1T), two targets with one limb (2T1L), two targets with two limbs (2T2L), and two targets between two persons (2T2P). Movement time within the first segment revealed a significant effect of target sequence, which surprisingly indicated a significantly shorter time for the 2T2P condition compared to all other one- and two-target movements (Tukey HSD; ps <.05). On the contrary, it seems sequential movements between nervous systems does not reflect a correspondence with the information processes found during a single person context. Instead, there is complementary arrangement where the first person allocates more time for the second person to complete the movement. These findings present a novel joint action paradigm that potentially extends our understanding of perception-action frameworks.

AB - In two target aiming sequences, movement times to the first target are typically longer compared to single target responses – something referred to as the one-target advantage (OTA). Recent evidence has shown this advantage unfolds both within and between limbs, suggesting it emanates from a central representation. In a separate line of evidence, the involuntary movement interference or facilitation invoked by the concurrent observation of another moving agent has supported the view of a correspondence between perception and action. The following study explores the potential of the OTA unfolding between, as well as within, nervous systems. Thus, we had participants execute a fast-and-accurate aim to a single target (1T), two targets with one limb (2T1L), two targets with two limbs (2T2L), and two targets between two persons (2T2P). Movement time within the first segment revealed a significant effect of target sequence, which surprisingly indicated a significantly shorter time for the 2T2P condition compared to all other one- and two-target movements (Tukey HSD; ps <.05). On the contrary, it seems sequential movements between nervous systems does not reflect a correspondence with the information processes found during a single person context. Instead, there is complementary arrangement where the first person allocates more time for the second person to complete the movement. These findings present a novel joint action paradigm that potentially extends our understanding of perception-action frameworks.

M3 - Conference contribution

VL - 50

SP - 64

BT - Journal of Exercise, Movement, and Sport

ER -