OALib Journal期刊
ISSN: 2333-9721
费用：99美元

投递稿件

查看量	下载量

相关文章
更多...

PLOS ONE 2013

Stereoscopic Depth Perception Using a Model Based on the Primary Visual Cortex

DOI: 10.1371/journal.pone.0080745

Fernanda da C. e C. Faria, Jorge Batista, Helder Araújo

Full-Text Cite this paper Add to My Lib

Abstract:

This work describes an approach inspired by the primary visual cortex using the stimulus response of the receptive field profiles of binocular cells for disparity computation. Using the energy model based on the mechanism of log-Gabor filters for disparity encodings, we propose a suitable model to consistently represent the complex cells by computing the wide bandwidths of the cortical cells. This way, the model ensures the general neurophysiological findings in the visual cortex (V1), emphasizing the physical disparities and providing a simple selection method for the complex cell response. The results suggest that our proposed approach can achieve better results than a hybrid model with phase-shift and position-shift using position disparity alone.

References

[1]	Cumming BG, DeAngelis GC (2001) The physiology of stereopsis. Annual Review of Neuroscience 24: 203–238.
[2]	Qian N, Li Y (2011) Physiologically based models of binocular depth perception. In: Harris, LR, Jenkin, MRM, editors. Vision in 3D Environments. Cambridge University Press, 11–45 pp.
[3]	Ohzawa I, DeAngelis GC, Freeman RD (1990) Stereoscopic depth discrimination in the visual cortex: neurons ideally suited as disparity detectors. Science 249: 1037–1041.
[4]	Qian N (1997) Binocular disparity and the perception of depth. Neuron 18: 359–368.
[5]	Qian N (1994) Computing stereo disparity and motion with known binocular cell properties. Neural Computation 6: 390–404.
[6]	Scharstein D, Szeliski R (2002) A taxonomy and evaluation of dense two-frame stereo correspondence algorithms. International Journal of Computer Vision 47: 7–42.
[7]	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.
[8]	Parker AJ (2007) Binocular depth perception and the cerebral cortex. Nature Reviews, Neuroscience 8: 379–391.
[9]	Hubel DH, Wiesel TN (1962) Receptive fields, binocular interaction and functional architecture in the cat's visual cortex. The Journal of Physiology 160: 106–154.
[10]	Daugman JG (1985) Uncertainty relation for resolution in space, spatial frequency, and orientation optimized by two-dimensional visual cortical filters. Journal of the Optical Society of America A: Optics, Image Science, and Vision 2: 1160–1169.
[11]	Anzai A, Ohzawa I, Freeman RD (1999) Neural mechanisms for processing binocular information. i. simple cells. Journal of Neurophysiology 82: 891–908.
[12]	Haefner RM, Cumming BG (2008) Adaptation to natural binocular disparities in primate v1 explained by a generalized energy model. Neuron 57: 147–158.
[13]	Poggio GF, Fischer B (1977) Binocular interaction and depth sensitivity in striate and prestriate cortex of behaving rhesus monkey. J Neurophysiol 40: 1392–1405.
[14]	Adelson EH, Bergen JR (1985) Spatiotemporal energy models for the perception of motion. Journal of the Optical Society of America A 2: 284–299.
[15]	Ohzawa I, DeAngelis GC, Freeman RD (1997) Encoding of binocular disparity by complex cells in the cat's visual cortex. Journal of Neurophysiology 77: 2879–2909.
[16]	Qian N, Zhu Y (1997) Physiological computation of binocular disparity. Vision Research 37: 1811–1827.
[17]	Read JCA, Parke AJ, Cumming BG (2002) A simple model accounts for the response of disparity-tuned v1 neurons to anticorrelated images. Visual Neuroscience 19: 735–753.
[18]	Ohzawa I (1998) Mechanisms of stereoscopic vision: the disparity energy model. Current Opinion in Neurobiology 8: 509–515.
[19]	Anzai A, Ohzawa I, Freeman RD (1999) Neural mechanisms for processing binocular information. ii. complex cells. J Neurophysiol 82: 909–924.
[20]	Anderson JS, Carandini M, Ferster D (2000) Orientation tuning of input conductance, excitation, and inhibition in cat primary visual cortex. J Neurophysiol 84: 909–926.
[21]	Chen Y, Qian N (2004) A coarse-to-fine disparity energy model with both phase-shift and position -shift receptive field mechanisms. Neural Comput 16: 1545–1577.
[22]	Read JCA, Cumming BG (2007) Sensors for impossible stimuli may solve the stereo correspondence problem. Nature Neuroscience 10: 1322–1328.
[23]	Tsang EKC, Shi BE (2007) Estimating disparity with confidence from energy neurons. In: Advances in Neural Information Processing Systems 20: 1537–1544.
[24]	Faria FCC, Batista J, Araújo H (2010) Bio-inspired binocular disparity with position-shift receptive field. In: Proc. First Doctoral Conference on Computing, Electrical and Industrial Systems – DoCEIS'10, Costa de Caparica, Portugal. 351–358.
[25]	Field DJ (1987) Relations between the statistics of natural images and the response properties of cortical cells. Journal of the Optical Society of America A 4: 2379–2394.
[26]	Kovesi P (1999) Image features from phase congruency. Journal of Computer Vision Research 1: 1–26.
[27]	Gabor D (1946) Theory of communication. J Inst Elect Eng 93: 429–457.
[28]	DeValois RL, Albrecht DG, Thorell LG (1982) Spatial frequency selectivity of cells in macaque visual cortex. Vision Res 22: 545–559.
[29]	Fischer S, Sroubek F, Perrinet L, Redondo R, Cristóbal G (2007) Self-invertible 2d log-gabor wavelets. International Journal of Computer Vision 75: 231–246.
[30]	Morrone MC, Burr DC (1988) Feature detection in human vision: a phase-dependent energy model. Proceedings of the Royal Society of London Series B Biological Sciences 235: 221–245.
[31]	Scharstein D, Pal C (2007) Learning conditional random fields for stereo. In: IEEE Computer Society Conference on Computer Vision and Pattern Recognition.
[32]	Hirschmüller H, Scharstein D (2007) Evaluation of cost functions for stereo matching. In: IEEE Computer Society Conference on Computer Vision and Pattern Recognition.

Full-Text

Contact Us

service@oalib.com

QQ:3279437679

WhatsApp +8615387084133