TY - JOUR
T1 - Motion dazzle
T2 - A locust's eye view
AU - Santer, Roger Douglas
N1 - Media coverage: http://www.livescience.com/41659-razzle-dazzle-camouflage-fools-eye.html
Syndicated to others, e.g. Yahoo News
PY - 2013/12/23
Y1 - 2013/12/23
N2 - Motion dazzle describes high-contrast patterns (e.g. zigzags on snakes and dazzle paint on World War I ships) that do not conceal an object, but inhibit an observer's perception of its motion. However, there is limited evidence for this phenomenon. Locusts have a pair of descending contralateral movement detector (DCMD) neurons which respond to predator-like looming objects and trigger escape responses. Within the network providing input to a DCMD, separate channels are excited when moving edges cause areas of the visual field to brighten or darken, respectively, and these stimuli interact antagonistically. When a looming square has an upper half and lower half that are both darker than background, it elicits a stronger DCMD response than the upper half does alone. However, when a looming square has a darker-than-background upper half and a brighter-than-background lower half, it elicits a weaker DCMD response than its upper half does alone. This effect allows high-contrast patterns to weaken and delay DCMD response parameters implicated in escape decisions, and is analogous to motion dazzle. However, the motion dazzle effect does not provide the best means of motion camouflage, because uniform bright squares, or low-contrast squares, elicit weaker DCMD responses than high-contrast, half dark, half bright squares.
AB - Motion dazzle describes high-contrast patterns (e.g. zigzags on snakes and dazzle paint on World War I ships) that do not conceal an object, but inhibit an observer's perception of its motion. However, there is limited evidence for this phenomenon. Locusts have a pair of descending contralateral movement detector (DCMD) neurons which respond to predator-like looming objects and trigger escape responses. Within the network providing input to a DCMD, separate channels are excited when moving edges cause areas of the visual field to brighten or darken, respectively, and these stimuli interact antagonistically. When a looming square has an upper half and lower half that are both darker than background, it elicits a stronger DCMD response than the upper half does alone. However, when a looming square has a darker-than-background upper half and a brighter-than-background lower half, it elicits a weaker DCMD response than its upper half does alone. This effect allows high-contrast patterns to weaken and delay DCMD response parameters implicated in escape decisions, and is analogous to motion dazzle. However, the motion dazzle effect does not provide the best means of motion camouflage, because uniform bright squares, or low-contrast squares, elicit weaker DCMD responses than high-contrast, half dark, half bright squares.
KW - escape
KW - motion camouflage
KW - adaptive colaration
KW - descending contralateral movement detector
KW - lobula giant movement detector
KW - looming motion
KW - Escape
KW - Adaptive coloration
KW - Lobula giant movement detector
KW - Motion camouflage
KW - Looming motion
KW - Descending contralateral movement detector
KW - Motion
KW - Visual Pathways/physiology
KW - Animals
KW - Photic Stimulation/methods
KW - Vision, Ocular
KW - Grasshoppers/physiology
KW - Perception
KW - Software
KW - Electrophysiology/methods
KW - Motion Perception/physiology
UR - http://hdl.handle.net/2160/12978
UR - http://www.scopus.com/inward/record.url?scp=84891927402&partnerID=8YFLogxK
U2 - 10.1098/rsbl.2013.0811
DO - 10.1098/rsbl.2013.0811
M3 - Review Article
C2 - 24307529
SN - 1744-9561
VL - 9
JO - Biology Letters
JF - Biology Letters
IS - 6
M1 - 20130811
ER -