Perceptual Coherence : Hearing and Seeing

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References 445 Troost, J. M. (1998). Empirical studies in color constancy. In V. Walsh & J. Kulikowski (Eds.), Perceptual constancies (pp. 262–282). Cambridge, UK: Cambridge University Press. Tse, P., Cavanagh, K., & Nakayama, K. (1998). The role of parsing in high-level motion processing. In T. Watanabe (Ed.), Computational neurobiological, and psychophysical perspectives (pp. 249–266). Cambridge, MA: MIT Press. Turgeon, M. (2000). Cross-spectral auditory grouping using the paradigm of rhythmic masking release. Unpublished doctoral dissertation, McGill University, Montreal. Tyler, C. W. (2004). Theory of texture discrimination based on higher-order perturbations in individual texture samples. Vision Research, 44, 2179–2186. Uttal, W. R. (1975). An autocorrelation theory of form perception. Hillsdale, NJ: Erlbaum. van der Helm, P. A. (2000). Simplicity versus likelihood in visual perception: From surprisals to precisals. Psychological Bulletin, 126, 770–800. Van de Smagt, M. J., Verstraten, F. A., & van de Grind, W. A. (1999). A new transparent motion aftereffect. Nature Neuroscience, 2, 595–596. Van Essen, D. C., Anderson, C. H., & Felleman, D. J. (1992). Information processing in the primate visual system: An integrated systems perspective. Science, 255, 419–422. van Noorden, L. P. A. S. (1975). Temporal coherence in the perception of tone sequences. Unpublished doctoral dissertation, Eindhoven University of Technology, Eindhoven. Vanderveer, N. J. (1979). Ecological acoustics: Human perception of environmental sounds. Unpublished doctoral dissertation, Cornell University, Ithaca, NY. Victor, J. D. (1994). Images, statistics, and textures: Implications of triple correlation uniqueness for texture statistics and the Julesz conjecture: Comment. Journal of the Optical Society of America, A, 11, 1680–1684. Victor, J. D. (2000). How the brain uses time to represent and process visual information. Brain Research, 886, 33–46. Victor, J. D., & Conte, M. M. (2004). Visual working memory for image statistics. Vision Research, 44, 541–556. Vidnyanszky, Z., Blaser, E., & Papathomas, T. V. (2002). Motion integration during motion aftereffects. Trends in Cognitive Science, 6, 157–161. Vinje, W. E., & Gallant, J. L. (2000). Sparse coding and decorrelation in primary visual cortex during natural vision. Science, 287, 1273–1276. Vinje, W. E., & Gallant, J. L. (2002). Natural stimulation of the nonclassical receptive field increases information transmission efficiency in V1. Journal of Neuroscience, 22, 2904–2915. von Bekesy, G. (1963). Three experiments concerned with speech perception. Journal of the Acoustical Society of America, 35, 602–606. von Bekesy, G. (1967). Sensory inhibition. Princeton, NJ: Princeton University Press. von Kreis, J. (1970). Chromatic adaptation. In D. L. MacAdam (Ed.), Sources of color science (pp. 109–119). Cambridge, MA: MIT Press. Voss, R. F., & Clarke, J. (1978). 1/f Noise in music: Music from 1/f noise. Journal of the Acoustical Society of America, 63, 258–263. Vrhel, M. J., Gershon, R., & Iwan, L. S. (1994). Measurement and analysis of object reflectance spectra. Color Research and Application, 19, 4–9. Wachler, T., Lee, T.-W., & Sejnowski, T. J. (2001). Chromatic structure of natural scenes. Journal of the Optical Society of America, A, 18, 65–77.
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PERCEPTUAL COHERENCE
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Perceptual Coherence Hearing and Se
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To My Family, My Parents, and the B
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Preface The purpose of this book is
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Preface ix intertwined with my own
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Contents 1. Basic Concepts 3 2. Tra
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PERCEPTUAL COHERENCE
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1 Basic Concepts In the beginning G
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Basic Concepts 5 sources moving in
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even though its appearance changes.
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sources. A single sound source is t
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straight line parallel to the actua
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continuous sound. The correspondenc
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Basic Concepts 15 overall uncertain
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problem. The “snapshots” in spa
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segments at different orientations.
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in amplitude across time (analogous
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Basic Concepts 23 visual experience
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we would expect the correlation to
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Transformation of Sensory Informati
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Table 2.1 Derivation of the Recepti
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Figure 2.7. Continued
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3 Characteristics of Auditory and V
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Information =−Σ. Pr(x i ) log 2
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Characteristics of Auditory and Vis
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valleys” that support the high-fr
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Phase Relationships and Power Laws
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systems to be. One possibility woul
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are most active, relatively large c
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(see figure 2.2 based on the Differ
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epresenting these naturally occurri
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found in V1. Even though the filter
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Figure 3.14. The independent compon
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specific persons or objects (e.g.,
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amplitudes of each picture and foun
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4 The Transition Between Noise (Dis
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more cortical levels. For example,
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The Transition Between Noise and St
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about poorer performance by creatin
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Figure 4.8. Continued The Transitio
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Surface Textures Visual Glass Patte
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Figure 4.11. Continued The Transiti
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(A) (B) (C) The Transition Between
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(A) (B) Warbleness The Transition B
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2000 Hz with a single action potent
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The same problem of the multiplicit
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order to create the appearance of s
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Perception of Motion 199 Figure 5.2
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Perception of Motion 203 together.
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Perception of Motion 205 (The two f
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again, two perceptions can result a
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Perception of Motion 211 notes of t
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Perception of Motion 213 Braddick (
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larger arrays and Baddeley and Tirp
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Perception of Motion 217 the judgme
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Perception of Motion 219 one color
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To review, neurons sensitive to mot
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Transparency aftereffects do occur
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Perception of Motion 225 stimuli, t
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Perception of Motion 231 perception
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Perception of Motion 237 same direc
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Time 1, Tone 1 is turned off, at Ti
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6 Gain Control and External and Int
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a signal-to-noise ratio), and Barlo
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Gain Control and External and Inter
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Suppose we have a background that h
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R Gain Control and External and Int
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Makous (1997) pointed out how diffi
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contrast that defines the boundarie
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per Second Figure 6.10. Continued G
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ane was linear, the higher sound pr
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(C. D. Geisler, 1998; C. D. Geisler
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noise visual field. 4 The S + N inp
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B. Murray, Bennett, and Sekular (20
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The authors proposed that the four
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Efficiency and Noise in Auditory Pr
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etween samples). Spiegel and Green
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In sum, the masking release is grea
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The Perception of Quality: Visual C
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Visual Worlds Modeling the Light Re
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Indirect Illumination Causing Specu
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of an object but also require the c
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assumed, so that the surface irradi
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Relative Power of Basis Functions S
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that the reflectance of the test co
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amount of light transmitted through
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light reflected by all surfaces in
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magenta to white). Then Bloj et al.
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Why is there opponent processing? O
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8 The Perception of Quality: Audito
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exists at several levels: (a) descr
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The Perception of Quality: Auditory
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mode is proportional to the relativ
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The overall result is that the rela
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obvious. The tension on the vocal c
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(termed the amplitude envelopes) ar
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obviously misplaced). The majority
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Pastore (1991) investigated whether
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experience. Erickson (2003) found t
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Rhythmic patterning usually gives i
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Let me summarize at this point. The
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the oddball note to be the one most
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9 Auditory and Visual Segmentation
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Auditory and Visual Segmentation 37
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processes (e.g., basilar membrane v
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same time, the difficulty of detect
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elease (discussed in chapter 6) dem
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(A) Target Rhythm Target + Masking
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to grouping by perceived position d
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4. Convexity: Convex figures usuall
Page 408 and 409: Auditory and Visual Segmentation 39
Page 416 and 417: filter inferred from the background
Page 420 and 421: Jackson (1953) found that the sound
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Page 430 and 431: was high, then the resolution of th
Page 432 and 433: Listeners were more likely to repor
Page 434 and 435: 10 Summing Up Perceiving is the con
Page 436 and 437: Summing Up 423 course of the stimul
Page 438 and 439: References Adelson, E. H. (1982). S
Page 440 and 441: References 427 Bermant, R. I., & We
Page 442 and 443: References 429 Crawford, B. H. (194
Page 444 and 445: References 431 Feldman, J., & Singh
Page 446 and 447: References 433 and male voices in t
Page 448 and 449: References 435 Isabelle, S. K., & C
Page 450 and 451: References 437 Laughlin, S. B. (200
Page 452 and 453: References 439 McAdams, S., Winsber
Page 454 and 455: References 441 Pittinger, J. B., Sh
Page 456 and 457: References 443 Shamma, S. (2001). O
Page 460 and 461: References 447 Welch, R. B. (1999).
Page 462 and 463: Index Boldfaced entries refer to ci
Page 464 and 465: Barbour, D. L., 83, 367, 426 Barlow
Page 466 and 467: Color reflectance 1/f c amplitude f
Page 468 and 469: Figure-ground auditory, 373, 421 in
Page 470 and 471: Hallikainen, J., 304, 440 Handel, S
Page 472 and 473: K-order statistics. See Visual text
Page 474 and 475: separation of things, 5 See also Pe
Page 476 and 477: Recanzone, G. H., 409-412, 441, 443
Page 478 and 479: Stream segregation default assumpti
Page 480 and 481: vibration frequencies of air masses
Page 482: Wavelet analysis. See Sparse coding
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