Sage Journals: Discover world-class research

Abstract

The generic-view principle (GVP) states that given a 2-D image the visual system interprets it as a generic view of a 3-D scene when possible. The GVP was applied to 3-D-motion perception to show how the visual system decomposes retinal image motion into three components of 3-D motion: stretch/shrinkage, rotation, and translation. First, the optical process of retinal image motion was analyzed, and predictions were made based on the GVP in the inverse-optical process. Then experiments were conducted in which the subject judged perception of stretch/shrinkage, rotation in depth, and translation in depth for a moving bar stimulus. Retinal-image parameters—2-D stretch/shrinkage, 2-D rotation, and 2-D translation—were manipulated categorically and exhaustively. The results were highly consistent with the predictions. The GVP seems to offer a broad and general framework for understanding the ambiguity-solving process in motion perception. Its relationship to other constraints such as that of rigidity is discussed.

Get full access to this article

View all access options for this article.

References

Albert

M K

Hoffman

D D

, (in press) “Genericity in spatial vision” Scientific American

Attneave

Frost

, 1969

“The determination of perceived tridimensional orientation by minimum criteria”

Perception & Psychophysics 6 391–396

Beverley

K I

Regan

, 1979

“Separable aftereffects of changing-size and motion-in-depth: Different neural mechanisms?”

Vision Research 19 727–732

Biederman

, 1985

“Human image understanding: Recent research and a theory”

Computer Vision, Graphics, and Image Processing 32 29–73

Binford

T O

, 1981

“Inferring surfaces from images”

Artificial Intelligence 17 205–244

Brainard

D H

Freeman

W T

, 1994

“Bayesian method for recovering surface and illuminant properties from photosensor responses”

Human Vision, Visual Processing, and Digital Display V, SPIE 2179 364–376

Braunstein

M L

Andersen

G J

, 1984

“A counterexample to the rigidity assumption in the visual perception of structure from motion”

Perception 13 213–217

Braunstein

M L

Andersen

G J

, 1986

“Testing the rigidity assumption: A reply to Ullman”

Perception 15 641–646

Freeman

W T

, 1992 “Exploiting the generic view assumption to estimate scene parameters” MIT Media Laboratory vision and modeling technical report 196 pp 1–29

10.

Freeman

W T

, 1994

“The generic viewpoint assumption in a framework for visual perception”

Nature (London) 368 542–545

11.

Gigus

Malik

, 1990

“Computing the aspect graph for line drawings of polyhedral objects”

IEEE Transactions on Pattern Analysis and Machine Intelligence 12 113–122

12.

Hochberg

Brooks

, 1960

“The psychophysics of form: Reversible perspective drawings of spatial objects”

American Journal of Psychology 73 337–354

13.

Hochberg

McAlister

, 1953

“A quantitative approach to figural ‘goodness’”

Journal of Experimental Psychology 46 361–364

14.

Johansson

, 1964

“Perception of motion and changing form”

Scandinavian Journal of Psychology 5 181–208

15.

Johansson

Jansson

, 1968

“Perceived rotary motion from change in a straight line”

Perception & Psychophysics 4 165–170

16.

Koenderink

J J

van Doorn

A J

, 1976

“The singularities of the visual mapping”

Biological Cybernetics 24 51–59

17.

Koenderink

J J

van Doorn

A J

, 1979

“The internal representation of solid shape with respect to vision”

Biological Cybernetics 32 211–216

18.

Kriegman

D J

Ponce

, 1990

“Computing exact aspect graphs of curved objects: Solids of revolution”

International Journal of Computer Vision 5 119–135

19.

Lowe

D G

, 1985 Perceptual Organization and Visual Recognition (Boston, MA: Kluwer–Nijhoff)

20.

Malik

, 1987

“Interpreting line drawings of curved objects”

International Journal of Computer Vision 1 73–103

21.

Nakayama

Shimojo

, 1992

“Experiencing and perceiving visual surfaces”

Science 257 1357–1363

22.

Ponce

Kriegman

D J

, 1992 “Toward 3-D curved object recognition from image contours”, in Geometric Invariance in Computer Vision Eds Mundy

Zisserman

, (Cambridge, MA: MIT Press) pp 408–439

23.

Regan

Beverley

K I

, 1978

“Illusory motion in depth: Aftereffect of adaptation to changing size”

Vision Research 18 209–212

24.

Richards

W A

Koenderink

J J

Hoffman

D D

, 1987

“Inferring three-dimensional shapes from two-dimensional silhouettes”

Journal of the Optical Society of America A 4 1168–1175

25.

Ullman

, 1979

“The interpretation of structure from motion”

Proceedings of the Royal Society of London, Series B 203 405–426

26.

Ullman

, 1984a

“Rigidity and misperceived motion”

Perception 13 219–220

27.

Ullman

, 1984b

“Maximizing rigidity: The incremental recovery of 3-D structure from rigid and nonrigid motion”

Perception 13 255–274

28.

Ullman

, 1986

“Competence, performance, and the rigidity assumption”

Perception 15 644–646

29.

Wallach

O'Connell

D N

, 1953

“The kinetic depth effect”

Journal of Experimental Psychology 45 205–217

30.

Witkin

A P

Tannenbaum

J M

, 1983 “On the role of structure in vision”, in Human and Machine Vision Eds Beck

Hope

Rosenfeld

, (New York: Academic Press) pp 481–543

‘Generic-View Principle’ for Three-Dimensional-Motion Perception: Optics and Inverse Optics of a Moving Straight Bar

Abstract

Get full access to this article

References