The effect of changing size on vergence is mediated by changing disparity

Journal of Vision

Volumn 9, Issue 13, 2009, Pages 1-10

  Wismeijer, Dagmar A ^a   Erkelens, Casper J ^a  

^a UTRECHT UNIVERSITY   (Netherlands)

Author keywords

Changing size; Disparity; Motion in depth; Vergence

Indexed keywords

ARTICLE; BINOCULAR CONVERGENCE; COMPARATIVE STUDY; DEPTH PERCEPTION; HUMAN; PERCEPTION; PHOTOSTIMULATION; PHYSIOLOGY;

CONVERGENCE, OCULAR; DEPTH PERCEPTION; HUMANS; PHOTIC STIMULATION; SIZE PERCEPTION; VISION DISPARITY;

EID: 77950343239     PISSN: None     EISSN: 15347362     Source Type: Journal    
DOI: 10.1167/9.13.1     Document Type: Article

References (19)

1. Brenner, E., Van Den Berg, A.V., & Van Damme, W.J. (1996). Perceived motion in depth. Vision Research, 36, 699-706.
2. Erkelens, C.J., & Collewijn, H. (1985a). Eye movements and stereopsis during dichoptic viewing of moving randomdot stereograms. Vision Research, 25, 1689-1700.
3. Erkelens, C.J., & Collewijn, H. (1985b). Eye movements in relation to loss and regaining of fusion of disjunctively moving random-dot stereograms. Human Neurobiology, 4, 181-188.
4. Erkelens, C.J., & Collewijn, H. (1985c). Motion perception during dichoptic viewing of moving random-dot stereograms. Vision Research, 25, 583-588.
5. Erkelens, C.J., & Collewijn, H. (1991). Control of vergence: Gating among disparity inputs by voluntary target selection. Experimental Brain Research, 87, 671-678.
6. Erkelens, C.J., & Regan, D. (1986). Human ocular vergence movements induced by changing size and disparity. The Journal of Physiology, 379, 145-169.
7. Harris, J.M. (2006). The interaction of eye movements and retinal signals during the perception of 3-D motion direction. Journal of Vision, 6(8):2, 777-790, http://journalofvision.org/6/8/2/, doi:10.1167/6.8.2.
8. Harris, J.M., & Drga, V. (2005). Using visual direction in three-dimensional motion perception. Nature Neuroscience, 8, 229-233.
9. Harris, J.M., McKee, S.P., & Watamaniuk, S.N. (1998). Visual search for motion-in-depth: Stereomotion does not 'pop out' from disparity noise. Nature Neuroscience, 1, 165-168.
10. Howard, I.P. (2008). Vergence modulation as a cue to movement in depth. Spatial Vision, 21, 581-592.
11. Howard, I.P., Fang, X., Allison, R.S., & Zacher, J.E. (2000). Effects of stimulus size and eccentricity on horizontal and vertical vergence. Experimental Brain Research, 130, 124-132.
12. Howard, I.P., & Rogers, B.J. (2002). Seeing in depth: Vol. 1. Basic mechanisms. I. Porteous. Toronto, Canada.
13. Nefs, H.T., & Harris, J.M. (2007). Vergence effects on the perception of motion-in-depth. Experimental Brain Research, 183, 313-322.
14. Nefs, H.T., & Harris, J.M. (2008). Induced motion in depth and the effects of vergence eye movements. Journal of Vision, 8(3):8, 1-16, http://journalofvision.org/8/3/8/, doi:10.1167/8.3.8.
15. Rashbass, C., & Westheimer, G. (1961). Disjunctive eye movements. The Journal of Physiology, 159, 339-360.
16. Regan, D., & Beverley, K.I. (1979). Binocular and monocular stimuli for motion in depth: Changingdisparity and changing-size feed the same motion-indepth stage. Vision Research, 19, 1331-1342.
17. Regan, D., Erkelens, C.J., & Collewijn, H. (1986). Necessary conditions for the perception of motion in depth. Investigative Ophthalmology & Visual Science, 27, 584-597.
18. Stevenson, S.B., Reed, P.E., & Yang, J. (1999). The effect of target size and eccentricity on reflex disparity vergence. Vision Research, 39, 823-832.
19. Welchman, A.E., Harris, J.M., & Brenner, E. (2009). Extra-retinal signals support the estimation of 3d motion. Vision Research, 49, 782-789.