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Network: Computation in Neural Systems Volume 20, 2009 - Issue 4
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Original

Discrimination of complex form by simple oscillator networks

Yoshinori Nagai Center for Information Science, Kokushikan University, Tokyo, Japan
,
Ryan RL Taylor ARC Centre of Excellence in Vision Science and Centre for Visual Sciences, Research School of Biology, Australian National University, Canberra, ACT 0200, Australia
,
Yik-Wen Loh ARC Centre of Excellence in Vision Science and Centre for Visual Sciences, Research School of Biology, Australian National University, Canberra, ACT 0200, Australia
&
Ted Maddess ARC Centre of Excellence in Vision Science and Centre for Visual Sciences, Research School of Biology, Australian National University, Canberra, ACT 0200, AustraliaCorrespondence[email protected]
Pages 233-252 | Received 29 Apr 2009, Accepted 28 Sep 2009, Published online: 17 Nov 2009

References

  • Allan DW. Statistics of atomic frequency standard. Proc IEEE 1966; 54: 221–231
  • Beason-Held LL, Purpura KP, et al. Cortical regions involved in visual texture perception: A fMRI study. Brain Res Cogn Brain Res 1998a; 7: 111–118
  • Beason-Held LL, Purpura KP, et al. PET reveals occipitotemporal pathway activation during elementary form perception in humans. Vis Neurosci 1998b; 15: 503–510
  • Beason-Held LL, Purpura KP, Krasuski JS, Desmond RE, Mangot DJ, Daly EM, Optican LM, Rapoport SI, VanMeter JW. Striate cortex in humans demonstrates the relationship between activation and variations in visual form. Exp Brain Res 2000; 130: 221–226
  • Beck J, Sutter A, Ivry R. Spatial frequency channels and perceptual grouping in texture segregation. Comput Vision Graphics Image Process 1987; 37: 299–325
  • Bhatt R, Carpenter GA, Grossberg S. Texture segregation by visual cortex: Perceptual grouping, attention, and learning. Vision Res 2007; 47: 3173–3211
  • Cesmeli E, Wang D. Texture segmentation using Gaussian-Markov random fields and neural oscillator networks. IEEE Trans Neural Netw 2001; 12: 394–404
  • Chandler DM, Field DJ. Estimates of the information content and dimensionality of natural scenes from proximity distributions. J Opt Soc Am A Opt Image Sci Vis 2007; 24: 922–941
  • Chellappa R, Kashyap R, Manjunath B. Model-based texture segmentation and classification. ‘Handbook of Pattern Recognition and Computer Vision’. World Scientific, Singapore 1993; 277–310
  • Chubb C, Sperling G. Texture quilts: Basic tools for studying motion-from-texture. J Math Psychol 1991; 35: 411–442
  • Franz MO, Schölkopf B. Implicit Volterra and Wiener series for higher-order image analysis. ‘Advances in neural information processing systems’, LK Saul, Y Weiss, L Bottou. MIT Press, Cambridge, MA 2005; 465–472
  • Friston K. A theory of cortical responses. Philos Trans R Soc Lond B Biol Sci 2005; 360: 815–836
  • Gilbert EN. Random colorings of a lattice on squares in the plane. SIAM J Algebra Dis Meth 1980; 1: 152–159
  • Graham N, Sutter A. Effect of spatial scale and background luminance on the intensive and spatial nonlinearities in texture segregation. Vision Res 1996; 36: 1371–1390
  • Graham N, Sutter A. Spatial summation in simple (Fourier) and complex (non-Fourier) texture channels. Vision Res 1998; 38: 231–257
  • Graham N, Sutter A. Normalization: Contrast-gain control in simple (Fourier) and complex (non-Fourier) pathways of pattern vision. Vision Res 2000; 40: 2737–2762
  • Graham N, Sutter A, Venkatesan C, Humaran M. Non-linear processes in perceived region segregation: Orientation selectivity of complex channels. Ophthalmic Physiol Opt 1992; 12: 142–146
  • Grossberg S, Mingolla E, Ross WD. Visual brain and visual perception: How does the cortex do perceptual grouping?. Trends Neurosci 1997; 20: 106–111
  • Grossberg S, Pessoa L. Texture segregation, surface representation and figure-ground separation. Vision Res 1998; 38: 2657–2684
  • Hindmarsh JL, Rose RM. A model of the nerve impulse using two first-order differential equations. Nature 1982; 296: 162–164
  • Hindmarsh JL, Rose RM. A model of neuronal bursting using three coupled first order differential equations. Proc R Soc Lond B Biol Sci 1984; 221: 87–102
  • Hirsch J, DeLaPaz RL, Relkin NR, Victor J, Kim K, Li T, Borden P, Rubin N, Shapley R. Illusory contours activate specific regions in human visual cortex: Evidence from functional magnetic resonance imaging. Proc Natl Acad Sci U S A 1995; 92: 6469–6473
  • Julesz B, Gilbert EN, Victor JD. Visual discrimination of textures with identical third-order statistics. Biol Cybern 1978; 31: 137–140
  • Krieger G, Rentschler I, Hauske G, Schill K, Zetzsche C. Object and scene analysis by saccadic eye-movements: An investigation with higher-order statistics. Spatial Vision 2000; 13: 201–214
  • Kuzmina M, Manykin E, Surina I. Oscillatory network with self-organized dynamical connections for synchronization-based image segmentation. Biosystems 2004; 76: 43–53
  • Landy MS, Bergen JR. Texture segregation and orientation gradient. Vision Res 1991; 31: 679–691
  • Maddess T, Davey M, Yang E. Discrimination of complex textures by bees. J Comp Physiol A 1999; 184: 107–117
  • Maddess T, Nagai Y. Discriminating isotrigon textures. Vision Res 2001; 41: 3837–3860
  • Maddess T, Nagai Y, James AC, Ankiewicz A. Binary and ternary textures containing higher-order spatial correlations. Vision Res 2004; 44: 1093–1113
  • Maddess T, Nagai Y, Victor JD, Taylor RRL. Multilevel isotrigon textures. JOSA A 2007; 24: 278–293
  • May RM. Simple mathematical models with very complicated dynamics. Nature 1976; 261: 459–467
  • Mumford D. On the computational architecture of the neocortex. II. The role of cortico-cortical loops. Biol Cybern 1992; 66: 241–251
  • Nagai Y, Maddess T. Nearest neighbour coupled systems of four 1-D oscillators. ‘Brain-inspired Information Technology Series’, H Nakagawa, K Ishii, H Miyamoto. Elsevier, Amsterdam 2004; 129–132
  • Nagai Y, Maddess T. Adaptive network structure for texture discrimination by a 1-D oscillator system. ‘Brain-inspired Information Technology Series’, Y Touitou, J Arendt, P Pévet. Elsevier, Amsterdam 2007; 282–285
  • Nagai Y, Maddess T, Hyde S. The oscillatory features of triangular and square prism oscillator networks. Mem Kokushikan U Cent Inform Sci 2005; 26: 1–16
  • Purpura KP, Victor JD, Katz E. Striate cortex extracts higher-order spatial correlations from visual textures. Proc Natl Acad Sci U S A 1994; 91: 8482–8486
  • Simoncelli EP, Olshausen BA. Natural Image statistics and neural representation. Annual Review of Neuroscience 2001; 24: 1193–1216
  • Strzelecki M. Texture boundary detection using network of synchronised oscillators. Electron Lett 2004; 40: 466–467
  • Taylor RRL, Maddess T, Nagai Y. Spatial biases and computational constraints on the encoding of complex local image structure. J Vision 2008; 8: 1–13
  • Victor JD. Complex visual textures as a tool for studying the VEP. Vision Res 1985; 25: 1811–1827
  • Victor JD. Images, statistics and textures: Implications of triple correlation uniqueness for texture statistics and the Julesz conjecture: Comment. J Opt Soc Am A 1994; 11: 1680–1684
  • Victor JD, Conte MM. Cortical interactions in texture processing: Scale and dynamics. Vis Neurosci 1989; 2: 297–313
  • Victor JD, Conte MM. Spatial organization of nonlinear interactions in form perception. Vision Res 1991; 31: 1457–1488
  • Victor JD, Conte MM. The role of high-order phase correlations in texture processing. Vision Research 1996; 36: 1615–1631
  • Victor JD, Purpura KP. Nature and precision of temporal coding in visual cortex: A metric-space analysis. J Neurophysiol 1996; 76: 1310–1326
  • Victor JD, Zemon V. The human visual evoked potential: analysis of components due to elementary and complex aspects of form. Vision Res. 1985; 25: 1829–1842
  • von der Heydt R, Peterhans E. Mechanisms of contour perception in monkey visual cortex. I. Lines of pattern discontinuity. J Neurosci 1989; 9: 1731–1748
  • von der Heydt R, Peterhans E, Baumgartner G. Illusory contours and cortical neuron responses. Science 1984; 224: 1260–1262
  • Yang EC, Maddess T. Orientation-sensitive neurons in the brain of the honeybee (Apis mellifera). J Insect Physiol 1997; 43: 329–336
  • Zetzsche C, Rohrbein F. Nonlinear and extra-classical receptive field properties and the statistics of natural scenes. Network: Computation in Neural Systems 2001; 12: 331–350

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