WOEXT: 18 - Vision (visual perception)
 
Bib -> Asymmetry | Author | ICA | NMF | Novelty | Statistics | SVD | Title | WOBIB ]
 
 
Exp -> Alphabetic | Asymmetry | ICA | NMF | Novelty | SVD | WOEXP | WOEXT ]
 
 
Ext -> Alphabetic index | Map | Roots ]          [ Brede ]          Loc -> Statistics ]
 


WOEXT: 18. Vision (visual perception).
All forms of vision and visual perception.

MeSH UID: D014796.
Wikipedia: Visual perception

ParentsSiblingsChildren
Perception
Saccadic eye movements
Visual motion
Visual object recognition
Visual artefact object categorization
Action observation
Visual orientation
Visual shape
Color perception
Visuoproprioception
Visual human body perception
Visual object processing
Visual memory
Visuospatial processing
Visual change

Experiments:

  1. Dynamic complex visual scene. Passive viewing and hearing of a movie (James Bond, Tomorrow never dies) with changes from color to black and white every 30 seconds and interrupted every 2.5 or 3 minutes with a blank period. Areas with high loadings in an independent component analysis.. WOEXP: 174.
    Semir Zeki; R. J. Perry; A. Bartels. The processing of kinetic contours in the brain. Cerebral Cortex 13(2):189-202, 2003. PMID: 12507950. WOBIB: 52.
  2. Visuospatial 0-back, pooled data. Viewing of dots in one of four displayed boxes with button pressing for indicating where the dot versus rest. WOEXP: 350.
    B. J. Casey; Jonathan D. Cohen; K. O'Craven; Richard J. Davidson; W. Irwin; C. A. Nelson; D. C. Noll; X. Hu; M. J. Lowe; B. R. Rosen; C. L. Truwitt; P. A. Turski. Reproducibility of fMRI results across four institutions using a spatial working memory task. NeuroImage 8(3):249-261, 1998. PMID: 9758739. FMRIDCID: . WOBIB: 116.
  3. Visuospatial stimulus, pooled data. Viewing of dots in one of four displayed boxes versus rest. WOEXP: 351.
    B. J. Casey; Jonathan D. Cohen; K. O'Craven; Richard J. Davidson; W. Irwin; C. A. Nelson; D. C. Noll; X. Hu; M. J. Lowe; B. R. Rosen; C. L. Truwitt; P. A. Turski. Reproducibility of fMRI results across four institutions using a spatial working memory task. NeuroImage 8(3):249-261, 1998. PMID: 9758739. FMRIDCID: . WOBIB: 116.
  4. Visuospatial stimulus, Boston site. Viewing of dots in one of four displayed boxes versus resting. WOEXP: 360.
    B. J. Casey; Jonathan D. Cohen; K. O'Craven; Richard J. Davidson; W. Irwin; C. A. Nelson; D. C. Noll; X. Hu; M. J. Lowe; B. R. Rosen; C. L. Truwitt; P. A. Turski. Reproducibility of fMRI results across four institutions using a spatial working memory task. NeuroImage 8(3):249-261, 1998. PMID: 9758739. FMRIDCID: . WOBIB: 116.
  5. Visuospatial stimulus, Pittsburgh site. Viewing of dots in one of four displayed boxes versus resting. WOEXP: 361.
    B. J. Casey; Jonathan D. Cohen; K. O'Craven; Richard J. Davidson; W. Irwin; C. A. Nelson; D. C. Noll; X. Hu; M. J. Lowe; B. R. Rosen; C. L. Truwitt; P. A. Turski. Reproducibility of fMRI results across four institutions using a spatial working memory task. NeuroImage 8(3):249-261, 1998. PMID: 9758739. FMRIDCID: . WOBIB: 116.
  6. Vision. Vision by viewing a Mondrian-like images with a collage of colored or gray squares and rectangles of different shapes versus eyes closed. WOEXP: 428.
    Semir Zeki; J. D. Watson; C. J. Lueck; Karl J. Friston; C. Kennard; Richard S. J. Frackowiak. A direct demonstration of functional specialization in human visual cortex. Journal of Neuroscience 11(3):641-649, 1991. PMID: 2002358. FMRIDCID: . WOBIB: 140.
corner cube

VRML97 file (131 Kb)


Child experiments:

  1. Self-generated saccades. Voluntary self-generated large-amplitude horizontal saccades with eyes open versus resting state with eyes closed. WOEXP: 1.
    Ian Law; Claus Svarer; Egill Rostrup; Olaf B. Paulson. Parieto-occipital cortex activation during self-generated eye movements in the dark. Brain 121 ( Pt 11):2189-200, 1998. PMID: 9827777. WOBIB: 1.
  2. Saccade versus central contrast. Saccadic eye movement versus central contrast. WOEXP: 7.
    Darren R. Gitelman; Todd B. Parrish; Karl J. Friston; M-Marsel Mesulam. Functional anatomy of visual search: regional segregations within the frontal eye fields and effective connectivity of the superior colliculus. NeuroImage 15(4):970-82, 2002. PMID: 11906237. DOI: 10.1006/nimg.2001.1006. WOBIB: 3.
  3. Face visual object. Visual objects: Faces versus building. WOEXP: 11.
    I Levy; U Hasson; G Avidan; T Hendler; R Malach. Center-periphery organization of human object areas. Nature Neuroscience 4(5):533-9, 2001. PMID: 11319563. DOI: 10.1038/87490. WOBIB: 5.
  4. Buildings visual objects. Visual object stimuli: Building versus faces. WOEXP: 12.
    I Levy; U Hasson; G Avidan; T Hendler; R Malach. Center-periphery organization of human object areas. Nature Neuroscience 4(5):533-9, 2001. PMID: 11319563. DOI: 10.1038/87490. WOBIB: 5.
  5. Recognizable visual objects. Recognizable visual objects versus unrecognizable. WOEXP: 15.
    Christian Gerlach; C. T. Aaside; G. W. Humphreys; Anders Gade; O. B. Paulson; I. Law. Brain activity related to integrative processes in visual object recognition: bottom-up integration and the modulatory influence of stored knowledge. Neuropsychologia 40(8):1254-67, 2002. PMID: 11931928. WOBIB: 7.
  6. Moving dots versus stationary dots. 250 white dots moved radially from the fixation point in the middle of the screen in random directions towards the border of the screen. WOEXP: 76.
    Christian Büchel; Oliver Josephs; Geraint Rees; R. Turner; C. D. Frith; Karl J. Friston. The functional anatomy of attention to visual motion. A functional MRI study. Brain 121 ( Pt 7):1281-94, 1998. PMID: 9679780. WOBIB: 24.
  7. Attention to moving dots by detecting changes versus no attention to moving dots. 250 white dots moved radially from the fixation point in the middle of the screen in random directions towards the border of the screen. WOEXP: 77.
    Christian Büchel; Oliver Josephs; Geraint Rees; R. Turner; C. D. Frith; Karl J. Friston. The functional anatomy of attention to visual motion. A functional MRI study. Brain 121 ( Pt 7):1281-94, 1998. PMID: 9679780. WOBIB: 24.
  8. Photographs of faces versus houses and chairs. Conjunction between passive viewing and delayed match-to sample of gray-scale photographs versus scrambled pictures and faces versus houses and chairs, with matching choice indicated by pressing a button with the right of left thumb. WOEXP: 91.
    A. Ishai; L. G. Ungerleider; A. Martin; J. V. Haxby. The representation of objects in the human occipital and temporal cortex. Journal of Cognitive Neuroscience 12 Suppl 2:35-51, 2000. PMID: 11506646. DOI: 10.1162/089892900564055. FMRIDCID: 2-2000-1113D. WOBIB: 28.
  9. Biological visual motion. Biological motion of dots versus scrambled motion of dots. WOEXP: 111.
    E. Grossman; M. Donnelly; R. Price; D. Pickens; V. Morgan; G. Neighbor; R. Blake. Brain areas involved in perception of biological motion. Journal of Cognitive Neuroscience 12(5):711-20, 2000. PMID: 11054914. WOBIB: 33.
  10. Coherent visual motion. Coherent visual motion of dots versus static display of dots. WOEXP: 112.
    E. Grossman; M. Donnelly; R. Price; D. Pickens; V. Morgan; G. Neighbor; R. Blake. Brain areas involved in perception of biological motion. Journal of Cognitive Neuroscience 12(5):711-20, 2000. PMID: 11054914. WOBIB: 33.
  11. Kinetic boundaries. Visual motion of dots with boundaries versus coherent visual motion of dots. WOEXP: 113.
    E. Grossman; M. Donnelly; R. Price; D. Pickens; V. Morgan; G. Neighbor; R. Blake. Brain areas involved in perception of biological motion. Journal of Cognitive Neuroscience 12(5):711-20, 2000. PMID: 11054914. WOBIB: 33.
  12. Categorization of artefacts. Categorization of visually presented artefacts versus categorization of natural objects, naming of artefacts and pattern discrimination. WOEXP: 114.
    Christian Gerlach; I. Law; Anders Gade; O. B. Paulson. The role of action knowledge in the comprehension of artefacts--a PET study. NeuroImage 15(1):143-52, 2002. PMID: 11771982. DOI: 10.1006/nimg.2002.0969. WOBIB: 34.
  13. Degraded versus undegraded words. Read visually degraded words versus reading undegraded words. WOEXP: 122.
    Terry L. Jernigan; A. L. Ostergaard; Ian Law; Claus Svarer; Christian Gerlach; O. B. Paulson. Brain activation during word identification and word recognition. NeuroImage 8(1):93-105, 1998. PMID: 9698579. WOBIB: 35.
  14. Front-face. Line drawings of front face versus line drawings of tumblers. WOEXP: 123.
    U. Hasson; T. Hendler; D. Ben Bashat; R. Malach. Vase or face? A neural correlate of shape-selective grouping processes in the human brain. Journal of Cognitive Neuroscience 13(6):744-53, 2001. PMID: 11564319. DOI: 10.1162/08989290152541412. FMRIDCID: 2-2001-111P8. WOBIB: 36.
  15. Visually guided saccades. Visually guided saccadic eye movements by following an white spot on a screen unpredictably right and left jumping along the horizontal meridian versus central fixation. WOEXP: 150.
    R. A. Berman; C. L. Colby; C. R. Genovese; J. T. Voyvodic; B. Luna; K. R. Thulborn; J. A. Sweeney. Cortical networks subserving pursuit and saccadic eye movements in humans: an FMRI study. Human Brain Mapping 8(4):209-25, 1999. PMID: 10619415. WOBIB: 46.
  16. Observation of action for imitation versus observation of action for recognition. Observation of hand and arm action showed on a video for the purpose of later imitation. WOEXP: 160.
    Jean Decety; J. Grezes; N. Costes; Daniela Perani; Marc Jeannerod; E. Procyk; F. Grassi; F. Fazio. Brain activity during observation of actions. Influence of action content and subject's strategy. Brain 120 ( Pt 10):1763-77, 1997. PMID: 9365369. WOBIB: 49.
  17. Observation of action for recognition versus observation of action for imitation. Observation of hand and arm action showed on a video for the purpose of later recognition. WOEXP: 161.
    Jean Decety; J. Grezes; N. Costes; Daniela Perani; Marc Jeannerod; E. Procyk; F. Grassi; F. Fazio. Brain activity during observation of actions. Influence of action content and subject's strategy. Brain 120 ( Pt 10):1763-77, 1997. PMID: 9365369. WOBIB: 49.
  18. Observation of meaningful action versus observation of meaningless action. Observation of hand and arm meaningful action such as "opening a bottle", "drawing a line", "sewing a button" showed on a video. WOEXP: 162.
    Jean Decety; J. Grezes; N. Costes; Daniela Perani; Marc Jeannerod; E. Procyk; F. Grassi; F. Fazio. Brain activity during observation of actions. Influence of action content and subject's strategy. Brain 120 ( Pt 10):1763-77, 1997. PMID: 9365369. WOBIB: 49.
  19. Observation of meaningless action versus observation of meaningful action. Observation of hand and arm meaningless action showed on a video. WOEXP: 163.
    Jean Decety; J. Grezes; N. Costes; Daniela Perani; Marc Jeannerod; E. Procyk; F. Grassi; F. Fazio. Brain activity during observation of actions. Influence of action content and subject's strategy. Brain 120 ( Pt 10):1763-77, 1997. PMID: 9365369. WOBIB: 49.
  20. Observation of meaningful action in order to recognize versus observation of meaningless action. Observation of hand and arm meaningful action such as "opening a bottle", "drawing a line", "sewing a button" showed on a video for later recognition. WOEXP: 164.
    Jean Decety; J. Grezes; N. Costes; Daniela Perani; Marc Jeannerod; E. Procyk; F. Grassi; F. Fazio. Brain activity during observation of actions. Influence of action content and subject's strategy. Brain 120 ( Pt 10):1763-77, 1997. PMID: 9365369. WOBIB: 49.
Corner cube


Bib -> Asymmetry | Author | ICA | NMF | Novelty | Statistics | SVD | Title | WOBIB ]
Exp -> Alphabetic | Asymmetry | ICA | NMF | Novelty | SVD | WOEXP | WOEXT ]
Ext -> Alphabetic index | Map | Roots ]          [ Brede ]          Loc -> Statistics ]
Automatically constructed by Brede Toolbox through brede_ext_ext2html, 2006-08-15T21:47:38