Pressure enhances online control when 'I' don't know I need to correct, but reduces it when 'I' do: Motor control strategies and state anxiety

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Pressure enhances online control when 'I' don't know I need to correct, but reduces it when 'I' do: Motor control strategies and state anxiety. / Owen, Robin; Gottwald, Victoria; Lawrence, Gavin.
Journal of Exercise, Movement, and Sport: SCAPPS refereed abstracts repository. Vol. 50 1. ed. 2018. p. 54.

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

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Owen R, Gottwald V, Lawrence G. 2018. Pressure enhances online control when 'I' don't know I need to correct, but reduces it when 'I' do: Motor control strategies and state anxiety. In Journal of Exercise, Movement, and Sport: SCAPPS refereed abstracts repository. 1 ed. pp. 54.

MLA

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Owen R, Gottwald V, Lawrence G. Pressure enhances online control when 'I' don't know I need to correct, but reduces it when 'I' do: Motor control strategies and state anxiety. In Journal of Exercise, Movement, and Sport: SCAPPS refereed abstracts repository. 1 ed. Vol. 50. 2018. p. 54

Author

Owen, Robin ; Gottwald, Victoria ; Lawrence, Gavin. / Pressure enhances online control when 'I' don't know I need to correct, but reduces it when 'I' do: Motor control strategies and state anxiety. Journal of Exercise, Movement, and Sport: SCAPPS refereed abstracts repository. Vol. 50 1. ed. 2018. pp. 54

RIS

TY - GEN

T1 - Pressure enhances online control when 'I' don't know I need to correct, but reduces it when 'I' do: Motor control strategies and state anxiety

AU - Owen, Robin

AU - Gottwald, Victoria

AU - Lawrence, Gavin

PY - 2018/10/21

Y1 - 2018/10/21

N2 - This series of studies directly investigated the effects of pressure and available cognitive resources on online and offline control. We tested pressured target-directed accuracy in situations where the distribution of online and offline control is a 'voluntary' strategy and when successful accuracy depends on the 'forced' use of online motor control i.e., unpredictable cursor jump trials. We investigated these processes under normal and ego depleted conditions and examined how reinvestment propensity may lead to different motor control strategies under pressure. In study 1 (n = 14), online motor control, as described by significant decreases in within-subject SDs at the later stages of limb trajectory, was impaired in pressured compared to non-pressured conditions. However, individuals used compensatory resources to shift from an online to an offline-dependent control strategy to maintain outcome performance under pressure. When the cursor representing limb trajectory unexpectedly jumped, online motor control (correction magnitudes) improved in pressured compared to non-pressured conditions. These results were replicated in study 2 (n=60) with reinvestment propensity correlating with greater online to offline control strategy shifts during pressured (no-jump) conditions. Study 3 (n=62), again revealed that pressured online motor control was impaired in no-jump trials but enhanced in jump trials. Furthermore, ego depleted participants saw a reduction in the efficiency of shifting from an online to offline control strategy to maintain performance under the no-jump pressured trials. Thus, pressure enhances forced online control and reduces voluntary online control. With the latter, only compensated for via shifts in control strategy when sufficient cognitive resources are available.

AB - This series of studies directly investigated the effects of pressure and available cognitive resources on online and offline control. We tested pressured target-directed accuracy in situations where the distribution of online and offline control is a 'voluntary' strategy and when successful accuracy depends on the 'forced' use of online motor control i.e., unpredictable cursor jump trials. We investigated these processes under normal and ego depleted conditions and examined how reinvestment propensity may lead to different motor control strategies under pressure. In study 1 (n = 14), online motor control, as described by significant decreases in within-subject SDs at the later stages of limb trajectory, was impaired in pressured compared to non-pressured conditions. However, individuals used compensatory resources to shift from an online to an offline-dependent control strategy to maintain outcome performance under pressure. When the cursor representing limb trajectory unexpectedly jumped, online motor control (correction magnitudes) improved in pressured compared to non-pressured conditions. These results were replicated in study 2 (n=60) with reinvestment propensity correlating with greater online to offline control strategy shifts during pressured (no-jump) conditions. Study 3 (n=62), again revealed that pressured online motor control was impaired in no-jump trials but enhanced in jump trials. Furthermore, ego depleted participants saw a reduction in the efficiency of shifting from an online to offline control strategy to maintain performance under the no-jump pressured trials. Thus, pressure enhances forced online control and reduces voluntary online control. With the latter, only compensated for via shifts in control strategy when sufficient cognitive resources are available.

M3 - Conference contribution

VL - 50

SP - 54

BT - Journal of Exercise, Movement, and Sport

ER -