Neural basis for stereopsis from second-order contrast cues

Journal of Neuroscience

Volumn 26, Issue 16, 2006, Pages 4370-4382

  Tanaka, Hiroki ^a   Ohzawa, Izumi ^a  

^a OSAKA UNIVERSITY   (Japan)

Author keywords

Binocular processing; Cat area 18; Contrast cues; Cue invariance; Early visual cortex; Second order stimuli; Stereopsis

Indexed keywords

ANIMAL EXPERIMENT; ARTICLE; BINOCULAR CONVERGENCE; BINOCULAR VISION; BRAIN CELL; BRAIN REGION; CAT; CONTROLLED STUDY; LUMINANCE; MONOCULAR VISION; NONHUMAN; PRIORITY JOURNAL; STEREOSCOPIC VISION; VISUAL STIMULATION; ANIMAL; ASSOCIATION; COMPARATIVE STUDY; CONTRAST SENSITIVITY; CYTOLOGY; DEPTH PERCEPTION; METHODOLOGY; PHOTOSTIMULATION; PHYSIOLOGY; VISUAL SYSTEM;

ANIMALS; CATS; CONTRAST SENSITIVITY; CUES; DEPTH PERCEPTION; PHOTIC STIMULATION; VISION, BINOCULAR; VISUAL PATHWAYS;

EID: 33646458110     PISSN: 02706474     EISSN: 02706474     Source Type: Journal    
DOI: 10.1523/JNEUROSCI.4379-05.2006     Document Type: Article

References (53)

1. Adelson EH, Bergen JR (1985) Spatiotemporal energy models for the perception of motion. J Opt Soc Am A 2:284-299.
2. Albright TD (1992) Form-cue invariant motion processing in primate visual cortex. Science 255:1141-1143.
3. Anzai A, Ohzawa I, Freeman RD (1999) Neural mechanisms for encoding binocular disparity: receptive field position versus phase. J Neurophysiol 82:874-890.
4. Bakin JS, Nakayama K, Gilbert CD (2000) Visual responses in monkey areas V1 and V2 to three-dimensional surface configurations. J Neurosci 20:8188-8198.
5. Cavanagh P, Mather G (1989) Motion: the long and short of it. Spat Vis 4:103-129.
6. Chubb C, Sperling G (1988) Drift-balanced random stimuli: a general basis for studying non-Fourier motion perception. J Opt Soc Am A 5:1986-2007.
7. Cumming BG, Parker AJ (2000) Local disparity not perceived depth is signaled by binocular neurons in cortical area V1 of the macaque. J Neurosci 20:4758-4767.
8. Demb JB, Zaghloul K, Sterling P (2001) Cellular basis for the response to second-order motion cues in Y retinal ganglion cells. Neuron 32:711-721.
9. Derrington AM, Fuchs AF (1979) Spatial and temporal properties of X and Y cells in the cat lateral geniculate nucleus. J Physiol (Lond) 293:347-364.
10. Draper NR, Smith H (1998) Appried regression analysis, Ed 3. New York: Wiley.
11. Edwards M, Pope DR, Schor CM (1999) Orientation tuning of the transient-stereopsis system. Vision Res 39:2717-2727.
12. Edwards M, Pope DR, Schor CM (2000) First- and second-order processing in transient stereopsis. Vision Res 40:2645-2651.
13. Ferster D (1981) A comparison of binocular depth mechanisms in areas 17 and 18 of the cat visual cortex. J Physiol (Lond) 311:623-655.
14. Ferster D (1990) X- and Y-mediated current sources in areas 17 and 18 of cat visual cortex. Vis Neurosci 4:135-145.
15. Fleet DJ, Wagner H, Heeger DJ (1996) Neural encoding of binocular disparity: energy models, position shifts and phase shifts. Vision Res 36:1839-1857.
16. Freeman RD, Ohzawa I (1988) Monocularly deprived cats: binocular tests of cortical cells reveal functional connections from the deprived eye. J Neurosci 8:2491-2506.
17. Halpern DL, Blake RR (1988) How contrast affects stereoacuity. Perception 17:483-495.
18. Hess RF, Wilcox LM (1994) Linear and non-linear filtering in stereopsis. Vision Res 34:2431-2438.
19. Hubel DH, Wiesel TN (1970) Stereoscopic vision in macaque monkey. Cells sensitive to binocular depth in area 18 of the macaque monkey cortex. Nature 225:41-42.
20. Julesz B (1971) Foundations of cyclopean perception. Chicago: The University of Chicago.
21. Langley K, Fleet DJ, Hibbard PB (1996) Linear filtering precedes nonlinear processing in early vision. Curr Biol 6:891-896.
22. Langley K, Fleet DJ, Hibbard PB (1999) Stereopsis from contrast envelopes. Vision Res 39:2313-2324.
23. Legge GE, Gu YC (1989) Stereopsis and contrast. Vision Res 29:989-1004.
24. Mareschal I, Baker Jr CL (1998a) A cortical locus for the processing of contrast-defined contours. Nat Neurosci 1:150-154.
25. Mareschal I, Baker Jr CL (1998b) Temporal and spatial response to second-order stimuli in cat area 18. J Neurophysiol 80:2811-2823.
26. Mareschal I, Baker Jr CL (1999) Cortical processing of second-order motion. Vis Neurosci 16:527-540.
27. Marr D, Poggio T (1979) A computational theory of human stereo vision. Proc R Soc Lond B Biol Sci 204:301-328.
28. McKee SP, Mitchison GJ (1988) The role of retinal correspondence in stereoscopic matching. Vision Res 28:1001-1012.
29. McKee SP, Verghese P, Farell B (2004) What is the depth of a sinusoidal grating? J Vis 4:524-538.
30. Movshon JA, Thompson ID, Tolhurst DJ (1978) Spatial summation in the receptive fields of simple cells in the cat's striate cortex. J Physiol (Lond) 283:53-77.
31. Nishimoto S, Arai M, Ohzawa I (2005) Accuracy of subspace mapping of spatiotemporal frequency domain visual receptive fields. J Neurophysiol 93:3524-3536.
32. Ohzawa I, Freeman RD (1986a) The binocular organization of simple cells in the cat's visual cortex. J Neurophysiol 56:221-242.
33. Ohzawa I, Freeman RD (1986b) The binocular organization of complex cells in the cat's visual cortex. J Neurophysiol 56:243-259.
34. Ohzawa I, DeAngelis GC, Freeman RD (1990) Stereoscopic depth discrimination in the visual cortex: neurons ideally suited as disparity detectors. Science 249:1037-1041.
35. Ohzawa I, DeAngelis GC, Freeman RD (1996) Encoding of binocular disparity by simple cells in the cat's visual cortex. J Neurophysiol 75:1779-1805.
36. Ohzawa I, DeAngelis GC, Freeman RD (1997) Encoding of binocular disparity by complex cells in the cat's visual cortex. J Neurophysiol 77:2879-2909.
37. O'Keefe LP, Movshon JA (1998) Processing of first- and second-order motion signals by neurons in area MT of the macaque monkey. Vis Neurosci 15:305-317.
38. Prince SJ, Cumming BG, Parker AJ (2002) Range and mechanism of encoding of horizontal disparity in macaque V1. J Neurophysiol 87:209-221.
39. Qian N, Zhu Y (1997) Physiological computation of binocular disparity. Vision Res 37:1811-1827.
40. Read JC, Parker AJ, Cumming BG (2002) A simple model accounts for the response of disparity-tuned V1 neurons to anticorrelated images. Vis Neurosci 19:735-753.
41. Sary G, Vogels R, Orban GA (1993) Cue-invariant shape selectivity of macaque inferior temporal neurons. Science 260:995-997.
42. Schor CM, Edwards M, Pope DR (1998) Spatial-frequency and contrast tuning of the transient-stereopsis system. Vision Res 38:3057-3068.
43. Skottun BC, De Valois RL, Grosof DH, Movshon JA, Albrecht DG, Bonds AB (1991) Classifying simple and complex cells on the basis of response modulation. Vision Res 31:1079-1086.
44. Smith AT (1994) The detection of second-order motion. In: Visual detection of motion (Smith AT, Snowden RJ, eds), pp 145-176. London: Academic.
45. Smith III EL, Chino YM, Ni J, Ridder III WH, Crawford ML (1997a) Binocular spatial phase tuning characteristics of neurons in the macaque striate cortex. J Neurophysiol 78:351-365.
46. Smith III EL, Chino Y, Ni J, Cheng H (1997b) Binocular combination of contrast signals by striate cortical neurons in the monkey. J Neurophysiol 78:366-382.
47. Tanaka H, Uka T, Yoshiyama K, Kato M, Fujita I (2001) Processing of shape defined by disparity in monkey inferior temporal cortex. J Neurophysiol 85:735-744.
48. Thomas OM, Cumming BG, Parker AJ (2002) A specialization for relative disparity in V2. Nat Neurosci 5:472-478.
49. Truchard AM, Ohzawa I, Freeman RD (2000) Contrast gain control in the visual cortex: monocular versus binocular mechanisms. J Neurosci 20:3017-3032.
50. Wilcox LM, Hess RF (1995) Dmax for stereopsis depends on size, not spatial frequency content. Vision Res 35:1061-1069.
51. Wilcox LM, Hess RF (1996) Is the site of non-linear filtering in stereopsis before or after binocular combination? Vision Res 36:391-399.
52. Wilcox LM, Hess RF (1997) Scale selection for second-order (non-linear) stereopsis. Vision Res 37:2981-2992.
53. Zhou YX, Baker Jr CL (1993) A processing stream in mammalian visual cortex neurons for non-Fourier responses. Science 261:98-101.