Motor Control & Learning - EXSS3062 PDF

Summary

This document is a set of lecture notes on motor control and learning, focusing on the constraints-led framework for skill acquisition. It covers key definitions and examples of individual, task, and environmental constraints, and discusses implications for instructors and coaches.

Full Transcript

EXSS3062
Motor Control & Learning

Motor Learning (ML 1)
Introduction:
The Constraints-led Framework
for Skill-Acquisition

Prof. Stephen Cobley
Faculty of Medicine & Health Sciences
The University of Sydney Page 1
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Motor Learning (ML 1)
Unit Learning Outcome
LO 3 Explain and evaluate core theoretical models & hypothetical explanations
as they apply to motor control & skill learning situations.

LO 4 Identify & explain how individual constraints & preexisting functioning
influence the implementation of pedagogical motor skill learning strategies.

ML 1 Lecture Learning Outcomes
1) Identify components of the Constraints-led Approach to Skill Acquisition.

2) Identify constraints impacting coordinated movement & how changes in
movement behaviour occur.

3) Identify implications of the constraints-led approach for instruction/coaching
in skill learning.
 ML 1 - Supportive Reading

Introduction: The Constraints-led
Framework for Skill-Acquisition

Davids, K., et al., (2008). Dynamics of Skill Acquisition - Chapter 2.

Renshaw, I. et al., (2010). Motor Learning in Practice. Routledge - Chapter 1.
 Key definitions
Introduction: What is motor control & skill acquisition?
Motor Control v Motor Learning

Motor Control Motor Learning (Skill Acquisition)

Study of underlying mechanisms Study of how we (optimally) learn perceptual,
permitting posture or movement cognitive, & movement skills across the life-
coordination & control. span, & in a range of contexts.
All movements reflect neuro- Conditions of acquisition, retention, transfer &
physiological functioning. performance.
Interaction of CNS with muscles &
joints to generate observable Interaction between:
movement. Individual, Task & Learning Environment
Perspectives in Movement Control & Learning
Centralised Motor Programs v Dynamical Systems

Interactions between neural, hormonal,
biomechanical, physiological, psychological
& environmental conditions

V

- Randomness to self-organisation
- Synergies create variability/changeable
- Brain pre-planned (open loop) + specific
movement
sensor feedback (closed loop) control.
- Variation exploration for optimal function
- Conscious, deliberative control
- Movements develop stability & become
- Fixed, rigid movement patterns
unstable in exploration.
- Movement error & variations is
- Abstract movement options in brain control,
bad/unwanted
but response to condition/constraints.
1) Constraints-led Framework for Skill Acquisition
(Newell, 1986)

Performer (Individual)
Emergent Behaviour
Individual coordination of movement

Task Environment

Constraints

- Coordinated movements emerge/arise from neuro-muscular self-organisation
given the existence or presence of task, individual & environmental constraints.

- Not necessarily pre-determined (planned) but responsive to conditions. 8
 1) Constraints-led Framework for Skill Acquisition

Constraints:
= A factor that eliminates, reduces, or influences options for ways of movement.
= Boundaries or features shaping/influencing emergent behaviour.

Performer/Individual:
- Anthropometric, physiological, cognitive, psychological, pre-existing control & skill capabilities.

Task:
- Task goal, time/speed demands, (co-)independence, implement/control components,
task/game biomechanical & physiological demands.

Environment
- Instructional knowledge/experience & interaction capability
- Social conditions (social support, social attitudes, norms, culture)
- Environmental conditions (presence of objects/others, surfaces, ambient temperature etc.)

Individual searches/identifies a movement solution for given tasks within
movement constraints (conditions).

Constraints lead to repeatable or new/alternative ways of moving in set tasks.
 1) Constraints-led Framework for Skill Acquisition
Examples of individual, task, & environment constraints!

Performer Anthrop. (Height, Weight, Body comp, Lean mass)
(Newell, 1986) (Individual)
Starting positions
Physiology (Muscle development [strength,
power]; Cardio-respiratory fitness, Core-Strength,
ROM - Flexibility; Biological maturity etc)
Psychology (Motivation, Efficacy, Resilience,
Self-Regulation, Social communication)
Posture; Gait; Existing movement patterns.
Pass type, distance, speed Perceptual/Cognitive Skills
Pass height, trajectory Handedness/Footedness
Need for object control Training/Playing & Injury History
Game/movement rules Training/Comp load; Fatigue state
Physical game & skill demands
Court position & tactic demands

Environment
Task
Access to sensory information.
Skill level of opponents / fellow players.
Constraints Playing surfaces
Weather conditions/climate.
Game context (prac. v comp.)
Social/psychological climate.
Coaching climate & interactions
Emergent Behaviour Opponent movements/tactics
Individual coordination of movement
10
2) Identify constraints impacting coordinated movement
Examples: what constraints may affect emergent behaviour in particular
movement situations?

Forward lunge movement Child (top picture) trying to Performance control in
complete a basketball free throw springboard diving
(e.g., inward somersault dive)

Identify constraints which could affect coordinated movement behaviour in one of these
situations - Enter constraint list on next slide!
11
 2) Identify constraints impacting coordinated movement

Performer
(Individual) 1) _________________
2) _________________
3) _________________
4) _________________
5) _________________
1) _________________
2) _________________
Image from
3) _________________
prior slide
4) _________________
5) _________________

Task Environment
1) _________________
Constraints
2) _________________
3) _________________
4) _________________
Emergent Behaviour 5) _________________
Individual coordination of movement
12
1 & 2) Key Points
Constraints-led Framework for Skill Acquisition

Constraints don’t cause movements, nor identify a prescribed ‘perfect’ movement for a
specific task. (rather influence/guide self-coordination)

Optimal movement is based on ‘it depends …’ (presence/absence) on what specific task,
individual & enviro factors are involved.

Similarity & unique movement behaviour (& variability) can occur. Movement solutions work
toward maximizing either accuracy, efficiency, &/or initial protection.

Potentially no one ‘idealized’ movement pattern is apparent for a given skill.
(= Less need to coach for a perfect model)

Understanding coordinated behaviour = Understanding constraints present
Changing coordinated behaviour = Careful altering manipulation of constraints.
(Gray, 2017)
3) Constraints-led Framework for Skill Acquisition
Implications for Instructors/Coaches

Perception - Action Cycles

(i) Help skill learners identify relevant perceptual cues in task/environment to inform movement.

(ii) Stimulate movement variations by changing task & environmental conditions.

(iii) Stimulate movement exploration/variation to develop adaptable coordination capabilities.
(the effect is to change psychological perception)
 3) Implications:
Exploration & experience of
Perception – Movement Action Coupling in tasks

Perception Cognitive Decision-Making Movement Action

Movement
Perception Action

Perception-Action Coupling

15
 3) Implications:
Movement exploration/variation informs self-
perception of movement capabilities

Benefits of Fundamental
Parkour - Effects on perceived Benefits of small-sided games
Movement Skill (FMS)
& actual movement capabilities With changing conditions in soccer
Development in children

16
3) Constraints-led Framework for Skill Acquisition

Implications: how different to normal instructing/coaching

Instructor/coach role:

1) Identify constraints limiting skill development/movement performance.
Constraint(s) identifier

2) Behavioural Practice = Changer task/enviro constraints to challenge
CNS/muscular systems to overcome or solve movement problems.
Movement problem creator

3) Understand sensory perception, cognitive & motor features of
performance/ skill.
Perception-Action coupler, Simulator of real contexts

4) Guide & shape emergent behaviour rather than explicit prescriptive
instruction.
Scaffolded guidance - Support movement solution finding
(Less prescription & intrusive instructional approach)