Dynamic perception of dynamic affordances: walking on a ship at sea

Motion of the surface of the sea (waves, and swell) causes oscillatory motion of ships at sea. Generally, ships are longer than they are wide. One consequence of this structural difference is that oscillatory ship motion typically will be greater in roll (i.e., the ship rolling from side to side) th...

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Bibliographic Details
Published in:Experimental brain research 2017-02, Vol.235 (2), p.517-524
Main Authors: Walter, Hannah, Wagman, Jeffrey B., Stergiou, Nick, Erkmen, Nurtekin, Stoffregen, Thomas A.
Format: Article
Language:English
Subjects:
Adult
Aged
Biomechanical Phenomena
Biomechanics
Biomedical and Life Sciences
Biomedicine
Brain research
Female
Gait
Humans
Judgment - physiology
Male
Middle Aged
Motion Perception - physiology
Neurology
Neurosciences
Oceans and Seas
Postural Balance - physiology
Research Article
Ships
Walking
Walking - physiology
Young Adult
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Summary:Motion of the surface of the sea (waves, and swell) causes oscillatory motion of ships at sea. Generally, ships are longer than they are wide. One consequence of this structural difference is that oscillatory ship motion typically will be greater in roll (i.e., the ship rolling from side to side) than in pitch (i.e., the bow and stern rising and falling). For persons on ships at sea, affordances for walking on the open deck should be differentially influenced by ship motion in roll and pitch. Specifically, the minimum width of a walkable path should be greater when walking along the ship’s short, or athwart axis than when walking along its long, or fore-aft axis. On a ship at sea, we evaluated the effects of walking in different directions (fore-aft vs. athwart) on actual walking performance. We did this by laying out narrow paths on the deck and asking participants (experienced maritime crewmembers) to walk as far as they could while remaining within the lateral path boundaries. As predicted, participants walked farther along the athwart path than along the fore-aft path. Before actual walking, we evaluated participants’ judgments of their walking ability in the fore-aft and athwart directions. These judgments mirrored the observed differences in walking performance, and the accuracy of judgments did not differ between the two directions. We conclude that experienced maritime crewmembers were sensitive to affordances for walking in which the relevant properties of the environment were exclusively dynamic.
ISSN:0014-4819
1432-1106
DOI:10.1007/s00221-016-4810-6