Vision and sports performance

In collaboration with partners at Liverpool Hope University, we are examining visual perception and visual-motor performance under habitual and simulated impaired vision.

We use physical (e.g., Bangerter filters) and computer-generated (e.g., sine-wave filter) manipulations of spatial frequency while participants perform aiming and pointing tasks.

Unlike defocusing lenses these do not influence image size (i.e., refractive error following the magnification of image size), or potentially introduce spurious resolution.

Importantly, our use of aiming tasks enables precise measurement of movement planning and subsequent online control, as well the manipulation of visual information that is available during these phases.

Findings from this work are contributing toward understanding the performance of daily tasks in individuals with ocular disorders, and possible functional adaptations.

Extending upon our earlier VR work in boxing, we are studying the impact of spatial frequency manipulations on anticipation, decision making and pattern recall in dynamic sporting tasks.

Central to this project is the controlled, digital manipulation of low and high spatial frequencies within pre-recorded clips of penalty kicks (from a goalkeeper perspective) and netball free-throw.

As well as determining if these sporting tasks can be maintained and/or subsequently improved by training in adapted visual conditions, the findings could have implications for the categorisation of visual impairment in sport.

For example, there is a growing discussion about whether the use of clinical diagnostic tools adequately recognise the dynamic contexts in which athletes use vision.

In collaboration with partners at University of Rennes (France), we used VR to study the impact of computer-generated (e.g., Gaussian filter) manipulations of spatial frequency on the ability to dodge and counter-attack in boxing.

As per previous studies on tasks such as cricket batting, we found across a series of studies that there was a general resilience to the presence of blur, irrespective of level and location in the visual field, as well as participant skill level.

The effects were mirrored in the eye gaze data (i.e., 3D ellipse Volume, fixation rate). We concluded that gaze-contingent manipulations of spatial frequency may facilitate learning by orienting attention to specific locations (e.g. head, trunk and the upper limb extremities).

Importantly, we also found that the VR boxing task used in the latter studies was received positively by the boxers and coaches. The boxers reported feeling immersed in the task and commented that it represented a real boxing situation.

Therefore, the realistic and representative VR boxing tool could offer an alternative, safe practice environment, which could also be used with injured boxers as they prepare to return to fight.

Findings showed a more prolonged time to initiate movements for blurred compared to clear targets, but no influence for movement time, or end-point accuracy and precision.

The adaptation in movement preparation may reflect an initial uncertainty surrounding the visual target characteristics, whereas the absence of any influence within movement reflects the independent processing of the coarse and dynamic visual characteristics of the limb.

Read more about the impact of simulated target blur

In two experiments, we studied participants ability to anticipate the direction of pre-recorded penalty kicks that were occluded at the point of ball contact.

The penalty kicks were presented with low (LSF; ‘blurred’), high (HSF; ‘edge detection’) or unfiltered (i.e., original footage) spatial frequencies. Experiment 1 involved a lab-controlled setting using a life-sized display of the non-deceptive penalty kicks with outfield participants, which indicated no effect of visual condition.

Experiment 2 involved a remote online protocol that displayed deceptive and non-deceptive penalty kicks with goalkeeper participants. While there was a decline in the anticipation of deceptive compared to non-deceptive kicks for the unfiltered condition, there was no such decline for the LSF and HSF conditions.

We suggest that the LSF and HSF conditions were able to overcome deception because of the isolating global kinematic and local detailed cues, respectively.

Read more about the influence of low and high spatial frequency

We developed a novel experimental protocol to examine the effect of different levels of Gaussian blur on interception performance and eye gaze data using an immersive VR task.

This provided a realistic simulation of a real-world boxing scenario in which expert combat athletes (n = 18) experienced a first-person, adaptive viewpoint of the visual environment, which could be blurred according to their gaze location (central blur, peripheral blur, no blur).

Findings indicated that participants exhibited similar interception performance in the presence of central blur or peripheral blur compared to a control condition with no blur.

Eye gaze data indicated that although participants fixated at similar areas of interest irrespective of the presence of blur, fixation duration was significantly longer with a strong level of blur in the peripheral viewing condition than all levels of central blur and the control condition.

These findings can be explained by relocating attention to different areas of the environment, which thereby influenced the perception of salient information. These are the first evidence for the use of VR as a means to examine gaze-contingent manipulations of the environment, and hence highlight the potential for facilitating learning and transfer to a real sporting situations.

Read more in Virtual reality boxing

We examined whether elite athletes demonstrate faster visually mediated reaction times (VRT) and whether gaze stability contributes to any advantage.

International‑level cricketers, professional rugby‑league players, and non‑sporting controls completed a simple reaction‑time task while we recorded saccades and blinks around stimulus onset.

Cricketers responded faster than controls, but saccades and blinks slowed reaction time in all groups. Elite female cricketers showed steadier gaze than female controls, yet adjusting for gaze stability did not alter group differences in VRT.

These results indicate that although gaze disruptions impair reaction time, superior gaze stability does not explain the faster VRT observed in elite athletes.

Read more about Faster visual reaction times