Analysis of Relations Between Spatiotemporal Movement Regulation and Performance of Discrete Actions Reveals Functionality in Skilled Climbing

Overview

Journal Front Psychol

Date 2017 Oct 24

PMID 29056919

Citations 15

Authors

Dominic Orth

Graham Kerr

Keith Davids

Ludovic Seifert

Affiliations

Soon will be listed here.

Abstract

In this review of research on climbing expertise, we focus on different measures of climbing performance, including spatiotemporal measures related to fluency and activity states (i.e., discrete actions), adopted by climbers for achieving overall performance goals of getting to the end of a route efficiently and safely. Currently, a broad range of variables have been reported, however, many of these fail to capture how climbers adapt to a route whilst climbing. We argue that spatiotemporal measures should be considered concurrently with evaluation of activity states (such as reaching or exploring) in order gain a more comprehensive picture of how climbers successfully adapt to a route. Spatial and temporal movement measures taken at the hip are a traditional means of assessing efficiency of climbing behaviors. More recently, performatory and exploratory actions of the limbs have been used in combination with spatiotemporal indicators, highlighting the influence of limb states on climbing efficiency and skill transfer. However, only a few studies have attempted to combine spatiotemporal and activity state measures taken during route climbing. This review brings together existing approaches for observing climbing skill at performance outcome (i.e., spatiotemporal assessments) and process (i.e., limb activity states) levels of analysis. Skill level is associated with a spatially efficient route progression and lower levels of immobility. However, more difficult hold architecture designs require significantly greater mobility and more complex movement patterning to maintain performance. Different forms of functional, or goal-supportive, movement variability, including active recovery and hold exploration, have been implicated as important adaptations to physiological and environmental dynamics that emerge during the act of climbing. Indeed, recently it has also been shown that, when climbing on new routes, efficient exploration can improve the transfer of skill. This review provides new insights into how climbing performance and related actions can be quantified to better capture the functional role of movement variability.

Citing Articles

Climbing Technique Evaluation by Means of Skeleton Video Stream Analysis.

Beltran Beltran R, Richter J, Kostermeyer G, Heinkel U Sensors (Basel). 2023; 23(19).

PMID: 37837046 PMC: 10574944. DOI: 10.3390/s23198216.

Wearable and Non-Invasive Sensors for Rock Climbing Applications: Science-Based Training and Performance Optimization.

Breen M, Reed T, Nishitani Y, Jones M, Breen H, Breen M Sensors (Basel). 2023; 23(11).

PMID: 37299807 PMC: 10255440. DOI: 10.3390/s23115080.

Exploring in a climbing task during a learning protocol: a complex sense-making process.

Ganachaud C, Ganiere C, Hacques G, Rochat N, Seifert L, Ade D Psychol Res. 2023; 87(8):2365-2379.

PMID: 37027038 DOI: 10.1007/s00426-023-01817-9.

Evaluating transfer prediction using machine learning for skill acquisition study under various practice conditions.

Aniszewska-Stpien A, Herault R, Hacques G, Seifert L, Gasso G Front Psychol. 2023; 13:961435.

PMID: 36817389 PMC: 9937057. DOI: 10.3389/fpsyg.2022.961435.

Visual Perception in Expert Athletes: The Case of Rock Climbers.

Marcen-Cinca N, Sanchez X, Otin S, Cimarras-Otal C, Bataller-Cervero A Front Psychol. 2022; 13:903518.

PMID: 35911052 PMC: 9330107. DOI: 10.3389/fpsyg.2022.903518.

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