NeuroBiography: A database of cognitive neuroscientists' lives & work
User: Guest
Quicksearch:
Holmes NP (2009b) The principle of inverse effectiveness in multisensory integration: Some statistical considerations. Brain Topography, 21(3-4):168-176        
Actions:
49 Papers found...

View these results as a formatted reference list in journal styles: APA - ExpBrainRes - JNeuroPhys - NB

1. Antunes LR (2012) The vestibular in film: orientation and balance in gus van sant’s cinema of walking. Essays in Philosophy, 13(2):10
    [NBArticle #45643] [Cites 1]
2. Bergmann D (2010) Neuronale Mechanismen zeitabhängiger Prozesse bei audiovisueller Verarbeitung. PhD Thesis, Otto-von-Guericke Universität, Magdeburg, 258pp.
  [NBArticle #31175] [Cites 2]
3. Cappe C, Murray MM, Barone P, Rouiller EM (2010) Multisensory facilitation of behavior in monkeys: Effects of stimulus intensity. Journal of Cognitive Neuroscience, 22(12):2850-2863
    [NBArticle #31263] [Cites 1]
4. Cappe C, Thut G, Romei V, Murray MM (2010) Auditory–visual multisensory interactions in humans: Timing, topography, directionality, and sources. Journal of Neuroscience, 30(38):12572-12580
    [NBArticle #31477] [Cites 1]
5. Chandrasekaran CF (2017) Computational principles and models of multisensory integration. Current Opinion in Neurobiology, 43:25-34
    [NBArticle #46485] [Cites 1]
6. Charbonneau G, Veronneau M, Boudrias-Fournier C (2013) The ventriloquist in periphery: impact of eccentricity-related reliability on audio-visual localization. Journal of Vision, 13(12):20
  [NBArticle #36672] [Cites 2]
7. Chen L (2009) Crossmodal temporal capture in visual and tactile apparent motion: Influences of temporal structure and crossmodal grouping. PhD Thesis, Ludwig-Maximilians-Universität, München, 86pp.
  [NBArticle #31174] [Cites 1]
8. Couth S, Gowen E, Poliakoff E (2016) Investigating the spatial and temporal modulation of visuotactile interactions in older adults. Experimental Brain Research, 234(5):1233-1248
    [NBArticle #43375] [Cites 3]
9. Folegatti A, de Vignemont F, Pavani F, Rossetti YRC, Farnè A (2009) Losing one's hand: Visual-proprioceptive conflict affects touch perception. Public Library of Science ONE, 4:e6920
      [NBArticle #27829] [Cites 39] [CitedBy 4]
10. Hagmann CE, Russo NN (2016) Multisensory integration of redundant trisensory stimulation. Attention, Perception, & Psychophysics, 78(8):2558-2568
    [NBArticle #45649] [Cites 2]
11. Hertz U, Amedi A (2010) Disentangling unisensory and multisensory components in audiovisual integration using a novel multifrequency fMRI spectral analysis. NeuroImage, 52(2):617-632
    [NBArticle #30276] [Cites 1]
12. Holle H, Obleser J, Rueschemeyer S, Gunter TC (2010) Integration of iconic gestures and speech in left superior temporal areas boosts speech comprehension under adverse listening conditions. NeuroImage, 49(1):875-884
      [NBArticle #30677] [Cites 1]
13. Holmes NP (unpublished) Multisensory integration: inverse effectiveness and noisy signals. Current Biology, 0:0
  [NBArticle #45652] [Cites 1]
14. Holmes NP (2016) The Old Statistics, the New Statistics (then back to the Old Statistics again): Bootstrapping data in Matlab for descriptive and inferential statistics. , A16, Pope, 7th December
  [NBArticle #46383] [Cites 17]
15. Jaekl PM, Soto-Faraco S (2010) Audiovisual contrast enhancement is articulated primarily via the M-pathway. Brain Research, 1366:85-92
    [NBArticle #31868] [Cites 1]
16. Jao RJ (2015) The neural development of visuohaptic object processing. PhD Thesis, Indiana University, 225pp.
  [NBArticle #45653] [Cites 2]
17. Kim S, James TW (2010) Enhanced effectiveness in visuo-haptic object-selective brain regions with increasing stimulus salience. Hearing Research, 31(5):678-693
      [NBArticle #30678] [Cites 2]
18. Kim S, Stevenson RA, James TW (2012) Visuo-haptic neuronal convergence demonstrated with an inversely effective pattern of bold activation. Journal of Cognitive Neuroscience, 24(4):830-842
    [NBArticle #34348] [Cites 2]
19. Knoeferle KM, Knoeferle P, Velasco C, Spence C (2016) Multisensory brand search: how the meaning of sounds guides consumers’ visual attention. Journal of Experimental Psychology: Applied, 22(2):196-210
    [NBArticle #47349] [Cites 1]
20. Lanz F, Moret V, Rouiller EM (2013) Multisensory integration in non-human primates during a sensory-motor task. Frontiers in Human Neuroscience, 7:UNSP799
  [NBArticle #36671] [Cites 1]
21. Laurienti PJ, Hugenschmidt CE (2012) Multisensory processes in old age. In: Bremner AJ, Lewkowicz DJ, Spence C (eds) Multisensory Development. Oxford University Press, Oxford, pp 251–270
  [NBArticle #34543] [Cites 2]
22. Leone LM, McCourt ME (2013) The roles of physical and physiological simultaneity in audiovisual multisensory facilitation. i-Perception, 4(4):213-228
    [NBArticle #45642] [Cites 3]
23. Macaluso E (2011) Spatial constraints in multisensory attention. In: Murray MM, Wallace MT (eds) The neural bases of multisensory processes. CRC Press, Taylor & Francis, London, pp 485–507
  [NBArticle #33127] [Cites 1]
24. Makovac E, Gerbino W (2014) Color selectivity of the spatial congruency effect: evidence from the focused attention paradigm. Journal of General Psychology, 141(1):18-34
  [NBArticle #36670] [Cites 2]
25. McKenzie KJ, Lloyd DM, Brown RJ (2012) Investigating the mechanisms of visually-evoked tactile sensations. Acta Psychologica, 139(1):46-53
    [NBArticle #34347] [Cites 2]
26. Murray MM, Sperdin HF (2010) Single-trial multisensory learning and memory retrieval. In: Kaiser J, Naumer MJ (eds) Multisensory Object Perception in the Primate Brain. Springer, pp 191–208
    [NBArticle #31172] [Cites 1]
27. Navarra J, Yeung HH, Werker JF, Soto-Faraco S () Multisensory interactions in speech perception. In: Stein BE (eds) The new handbook of multisensory processes.
  [NBArticle #45646] [Cites 2]
28. Noesselt T, Tyll S, Boehler CN, Budinger E, Heinze H, Driver J (2010) Sound-induced enhancement of low-intensity vision: Multisensory influences on human sensory-specific cortices and thalamic bodies relate to perceptual enhancement of visual detection sensitivity. Journal of Neuroscience, 30(41):13609-13623
    [NBArticle #31679] [Cites 1]
29. Occelli V, Spence C, Zampini M (2011b) Audiotactile interactions in temporal perception. Psychonomic Bulletin and Review, 18(3):429-454
    [NBArticle #32931] [Cites 3]
30. Rach S, Diederich A, Colonius H (2011) On quantifying multisensory interaction effects in reaction time and detection rate. Psychological Research, 75(2):77-94
      [NBArticle #30874] [Cites 61]
31. Rodríguez Sarmiento B (2014) Procesamiento multisensorial y atención: efectos de la proporción de congruencia. PhD Thesis, Universidad de Granada, 173pp.
  [NBArticle #45654] [Cites 1]
32. Russell D, Keegan J, Ramiccio J, Henderson M, Still D, Temme L, Ranes B, Crowley J, Estrada A (2016) Usaarl report no. 2016-10: pilot cueing synergies for degraded visual environments. , pp 1–93
  [NBArticle #47213] [Cites 1]
33. Schouten B (2010) Visual in-depth perception and audiovisual perception of biological motion. PhD Thesis, KATHOLIEKE UNIVERSITEIT LEUVEN, 189pp.
  [NBArticle #45363] [Cites 3]
34. Senkowski D, Saint-Amour D, Höfle M, Foxe JJ (2011) Multisensory interactions in early evoked brain activity follow the principle of inverse effectiveness. NeuroImage, 56(4):2200-2208
    [NBArticle #34443] [Cites 1]
35. Spence C (2013) Just how important is spatial coincidence to multisensory integration? evaluating the spatial rule. Annals of the New York Academy of Sciences, 1296:31-49
    [NBArticle #36142] [Cites 6]
36. Spence C, Senkowski D, Röder B (2009) Crossmodal processing. Experimental Brain Research, 198(2-3):107-111
    [NBArticle #28139] [Cites 2]
37. Su Y (2014) Visual enhancement of auditory beat perception across auditory interference levels. Brain and Cognition, 90:19-31
    [NBArticle #37252] [Cites 2]
38. Su Y (2016) Visual enhancement of illusory phenomenal accents in non-isochronous auditory rhythms. Public Library of Science ONE, 11(11):e166880
    [NBArticle #46388] [Cites 2]
39. Talsma D (2015) Predictive coding and multisensory integration: an attentional account of the multisensory mind. Frontiers in Integrative Neuroscience, 9:19
    [NBArticle #45641] [Cites 1]
40. Targher S, Occelli V, Zampini M (2012) Audiovisual integration in low vision individuals. Neuropsychologia, 50(5):576-582
    [NBArticle #36031] [Cites 2]
41. Thomas JP (2013) Multisensory action perception: sounds influence on visual sensitivity to viewed actions. PhD Thesis, Rutgers University-Graduate School-Newark, 213pp.
  [NBArticle #45370] [Cites 3]
42. Tye-Murray N, Sommers MS, Spehar B, Myerson‌ J, Hale‌ S (2010) Aging, audiovisual integration, and the principle of inverse effectiveness. Ear and Hearing, 31(5):636-644
    [NBArticle #31173] [Cites 1]
43. Tyll S (2010) Neuronale prozesse auditorisch induzierter visueller wahrnehmungssteigerung. PhD Thesis, Otto-von-Guericke Universität Magdeburg, 179pp.
  [NBArticle #45369] [Cites 3]
44. van der Stoep N, Van der Stigchel S, Nijboer TCW (2015b) Exogenous spatial attention decreases audiovisual integration. Attention, Perception, & Psychophysics, 77(2):464-482
    [NBArticle #45644] [Cites 2]
45. van der Stoep N (2015) Into the depths of spatial attention and multisensory integration. PhD Thesis, Universiteit Utrecht, 250pp.
  [NBArticle #45648] [Cites 8]
46. van der Stoep N, Van der Stigchel S, Nijboer TCW, Van der Smagt MJ (2016) Audiovisual integration in near and far space: effects of changes in distance and stimulus effectiveness. Experimental Brain Research, 234(5):1175-1188
    [NBArticle #43373] [Cites 3]
47. Van Engen KJ, Xie Z, Chandrasekaran B (2017) Audiovisual sentence recognition not predicted by susceptibility to the mcgurk effect. Attention, Perception, & Psychophysics, 79(2):396-403
    [NBArticle #47212] [Cites 1]
48. Werner S, Noppeney U (2010) Superadditive responses in superior temporal sulcus predict audiovisual benefits in object categorization. Cerebral Cortex, 20(8):1829-1842
    [NBArticle #30684] [Cites 2]
49. Wiggins IM, Hartley DEH (2015) A synchrony-dependent influence of sounds on activity in visual cortex measured using functional near-infrared spectroscopy (fnirs). Public Library of Science ONE, 10(3):e122862
    [NBArticle #45651] [Cites 1]