The physical elevation corresponding to visually perceived eye level (VPEL) changes linearly with the pitch of a visual field. Deviations from true eye level average more than 0.5 times the angle of pitch over a 65 degrees pitch range. A visual field consisting of 2 dim, isolated vertical lines in darkness is more than 4/5 as effective as that of a complexly structured visual field; 2 horizontal lines have a small and inconsistent effect. Differences in influence on VPEL between pitched-from-vertical and horizontal lines were predicted from an analysis that extracted differences in retinal perspective resulting from changes in pitch. The Great Circle Model (GCM), based on a spherical approximation to the erect, stationary eye, predicts the present results and results of 8 other sets of experiments. The model treats the influence of a single line on VPEL as systematically related to the elevation of the intersection between the great circle containing the image of the line and the central vertical retinal meridian; generalized GCM combines visual inputs with inputs from the body-referenced mechanism and maps onto the central nervous system.
[1]
David Marr,et al.
VISION A Computational Investigation into the Human Representation and Processing of Visual Information
,
2009
.
[2]
I. Howard,et al.
Human Spatial Orientation
,
1966
.
[3]
D. Jameson,et al.
Mach bands : quantitative studies on neural networks in the retina
,
1966
.
[4]
D. Hubel.
Eye, brain, and vision
,
1988
.
[5]
D. Hilbert,et al.
Geometry and the Imagination
,
1953
.
[6]
H. Coxeter,et al.
Introduction to Geometry.
,
1961
.
[7]
Ian P. Howard,et al.
Human visual orientation
,
1982
.
[8]
H. Pick,et al.
Intersensory Perception and Sensory Integration
,
1981
.
[9]
M. Sanders.
Handbook of Sensory Physiology
,
1975
.
[10]
Alexander H. Wertheim,et al.
Tutorials on motion perception
,
1982
.
[11]
V. Mountcastle,et al.
Higher functions of the brain
,
1987
.
[12]
L. Kaufman,et al.
Handbook of perception and human performance
,
1986
.