Skip to main content
Article thumbnail
Location of Repository

Coding of visual object features and feature conjunctions in the human brain

By Jasna Martinovic, Thomas Gruber and Matthias M Mueller


Peer reviewedPublisher PD

Topics: gamma-band-responses, repetition priming task, human EEG, time-course, neurophysiological evidence, bioelectric events, evoked-potentials, recognition, color, identification, RC0321 Neuroscience. Biological psychiatry. Neuropsychiatry, RC0321
Year: 2008
DOI identifier: 10.1371/journal.pone.0003781
OAI identifier:

Suggested articles


  1. (2006). A cross-lab study of event-related gamma activity in a standard object-recognition paradigm. doi
  2. (1980). A standardized Set of 260 pictures: Norms for name agreement, image agreement, familiarity and visual complexity. doi
  3. (2000). Activation timecourse of ventral visual stream object-recognition areas: High density electrical mapping of perceptual closure processes. doi
  4. (2006). Age of acquisition for naming and knowing: A new hypothesis. doi
  5. (2003). An event-related potential investigation of the relationship between semantic and perceptual levels of representation. doi
  6. (2006). Color makes a difference: Two-dimensional object naming in literate and illiterate subjects. doi
  7. (2002). Contribution of color to face recognition. doi
  8. (2006). Dynamic shape synthesis in posterior inferotemporal cortex. doi
  9. (1998). Early gamma response is sensory in origin: a conclusion based on cross-comparison of results from multiple experimental paradigms. doi
  10. (2007). EEG oscillations in the gamma and alpha range respond differently to spatial frequency. doi
  11. (2004). EEGLAB: an open source toolbox for analysis of single-trial EEG dynamics including independent component analysis. doi
  12. (2002). Effects of picture repetition on induced gamma band responses, evoked potentials, and phase synchrony in the human EEG. doi
  13. (1990). Feature linking via synchronization among distributed assemblies: simulations of results from cat visual cortex. doi
  14. (1999). Gamma responses and ERPs in a visual classification task. doi
  15. (1990). High quality recording of bioelectric events: I: interference reduction, theory and practice. doi
  16. (1991). High quality recording of bioelectric events. II: a low noise low-power multichannel amplifier design. doi
  17. (1989). Human brain electrophysiology.
  18. (2008). Induced gamma-band activity is related to the time point of object identification. doi
  19. (2007). Induced gamma-band responses predict recognition delays during object identification. doi
  20. (2003). Is color an intrinsic property of object representation? doi
  21. (2004). Keil A
  22. (2007). Limits of eventrelated potential differences in tracking object processing speed. doi
  23. (2004). Memory-matches evoke human gamma-responses.
  24. (2006). Microsaccades: A microcosm for research on oculomotor control, attention and visual perception. doi
  25. (2005). Modelling event-related responses in the brain. doi
  26. (2004). Modulation of oscillatory brain activity and evoked potentials in a repetition priming task in the human EEG. doi
  27. (2007). Neuronal correlates of repetition priming of frequently presented objects: Insights from induced gamma band responses. doi
  28. (2005). Neuronal mechanisms of repetition priming in occipitotemporal cortex: spatiotemporal evidence from functional magnetic resonance imaging and electroencephalography. doi
  29. (2007). Neurophysiological evidence for the time course of activation of global shape, part, and local contour representations during visual object categorization and memory. doi
  30. (2002). Neuropsychological evidence for two processing times for visual object identification. doi
  31. (2007). Object recognition and segmentation by a fragment-based hierarchy. doi
  32. (2005). Oscillatory brain activity dissociates between associative stimulus content in a repetition priming task in the human EEG. doi
  33. (1999). Oscillatory gamma activity in humans and its role in object representation. doi
  34. (1997). Oscillatory gammaband (30–70 Hz) activity induced by a visual search task in human.
  35. (2005). Rapid categorization of foveal and extrafoveal natural images: Associated ERPs and effects of lateralization. doi
  36. (1998). Real age-of-acquisition effects in lexical retrieval. doi
  37. (1987). Recognition-by-components: A theory of human image understanding. doi
  38. (1978). Representation and recognition of the spatial organization of three-dimensional shapes. doi
  39. (2004). Revisiting Snodgrass and Vanderwart’s object pictorial set: The role of surface detail in basic-level object recognition. doi
  40. (1999). Selective visual-spatial attention alters induced gamma band responses in the human EEG. doi
  41. (2000). Sensory and cognitive contributions of color to the recognition of natural scenes. doi
  42. (2004). Size matters: effects of stimulus size, duration and eccentricity on the visual gammaband response. doi
  43. (1996). Speed of processing in the human visual system. doi
  44. (1988). Spherical splines for scalp potential and current source density mapping. doi
  45. (2000). Statistical control of artifacts in dense array EEG/MEG studies. doi
  46. (1994). Stimulus frequency dependence of the transient oscillatory auditory evoked response (40 Hz) studied by electric and magnetic recordings doi
  47. (1958). The 10–20 electrode system of the International Federation.
  48. (2001). The role of color in high level vision. Trends doi
  49. (2001). The time course of visual processing: from early perception to decision-making. doi
  50. (2003). Time course of processes and representations supporting visual object identification and memory. doi
  51. (2008). Time pressure modulates electrophysiological correlates of early visual processing. doi
  52. (2003). Timecourse of neural signatures of object recognition. doi
  53. (2003). Timed picture naming in seven languages. doi
  54. (2006). Topdown facilitation of visual recognition. doi
  55. (2008). Transient induced gamma-band response in EEG as a manifestation of miniature saccades. doi

To submit an update or takedown request for this paper, please submit an Update/Correction/Removal Request.