Discrimination contours for moving sounds reveal duration and distance cues dominate auditory speed perception

PLoS ONE

Volumn 9, Issue 7, 2014, Pages

  Freeman, Tom C A ^a   Leung, Johahn ^b   Wufong, Ella ^b   Orchard Mills, Emily ^b   Carlile, Simon ^b   Alais, David ^b  

^a CARDIFF UNIVERSITY   (United Kingdom)

^b UNIVERSITY OF SYDNEY   (Australia)

Author keywords

[No Author keywords available]

Indexed keywords

ARTICLE; ASSOCIATION; AUDITORY DISCRIMINATION; AUDITORY STIMULATION; CONTROLLED STUDY; DECISION MAKING; HEARING ACUITY; HUMAN; HUMAN EXPERIMENT; NOISE; NORMAL HUMAN; STIMULUS RESPONSE; VELOCITY; ADULT; FEMALE; MALE; PERCEPTIVE DISCRIMINATION; SOUND DETECTION; SPEECH PERCEPTION; TIME;

ADULT; CUES; DISCRIMINATION (PSYCHOLOGY); FEMALE; HUMANS; MALE; SOUND LOCALIZATION; SPEECH PERCEPTION; TIME FACTORS;

EID: 84905014872     PISSN: None     EISSN: 19326203     Source Type: Journal    
DOI: 10.1371/journal.pone.0102864     Document Type: Article

References (51)

1. Bremmer F, Schlack a, Shah NJ, Zafiris O, Kubischik M, et al. (2001) Polymodal motion processing in posterior parietal and premotor cortex: a human fMRI study strongly implies equivalencies between humans and monkeys. Neuron 29: 287-296.
2. Warren JD, Zielinski BA, Green GGR, Rauschecker JP, Griffiths TD (2002) Perception of sound-source motion by the human brain. Neuron 34: 139-148. (Pubitemid 34270705)
3. Pavani F, Macaluso E, Warren JD, Driver J, Griffiths TD (2002) Activated by Horizontal and Vertical Sound Movement in the Human Brain. 12: 1584-1590.
4. Torunchuk JM, Stumpf E, Cynader MS (1992) Auditory cortex neurons sensitive to correlates of auditory motion: underlying mechanisms. Experimental Brain Research 88: 169-180.
5. Getzmann S (2011) Auditory motion perception: onset position and motion direction are encoded in discrete processing stages. The European journal of neuroscience 33: 1339-1350.
6. Griffiths TD, Rees G, Rees A, Green GG, Witton C, et al. (1998) Right parietal cortex is involved in the perception of sound movement in humans. Nature neuroscience 1: 74-79. (Pubitemid 128652646)
7. Baumgart F (1999) A movement-sensitive area in auditory cortex. Nature 400: 724-726.
8. Magezi Da, Buetler Ka, Chouiter L, Annoni J-M, Spierer L (2013) Electrical neuroimaging during auditory motion aftereffects reveals that auditory motion processing is motion sensitive but not direction selective. Journal of neurophysiology 109: 321-331.
9. Zakarauskas P, Cynader M (1991) Aural intensity for a moving source. Hearing research 52: 233-244.
10. Wagner H, Kautz D, Poganiatz I (1997) Principles of acoustic motion detection in animals and man. Trends in neurosciences 20: 583-588. (Pubitemid 27508972)
11. Perrott DR, Costantino B, Ball J (1993) Discrimination of moving events which accelerate or decelerate over the listening interval. The Journal of the Acoustical Society of America 93: 1053-1057. (Pubitemid 23059832)
12. Ahissar M, Ahissar E, Bergman H, Vaadia E (1992) Encoding of sound-source location and movement: activity of single neurons and interactions between adjacent neurons in the monkey auditory cortex. Journal of Neurophysiology 67: 203-215.
13. Altman JA (1968) Arev there neurons detecting direction of sounds source motion? Experimental Neurology 22: 13-25.
14. Jenison RL, Schnupp JWH, Reale RA, Brugge JF (2001) Auditory space-time receptive field dynamics revealed by spherical white-noise analysis. Journal of Neuroscience 21: 4408-4415. (Pubitemid 32538567)
15. Sovijarvi ARA, Hyvarinen J (1974) Auditory cortical neurons in the cat sensitive to the direction of sound source movement. Brain Research 73: 455-471.
16. Spitzer MW, Semple MN (1993) Responses of inferior colliculus neurons to time-varying interaural phase disparity: Effects of shifting the locus of virtual motion. Journal of Neurophysiology 69: 1245-1263. (Pubitemid 23118824)
17. Jiang H, Lepore F, Poirier P, Guillemot JP (2000) Responses of cells to stationary and moving sound stimuli in the anterior ectosylvian cortex of cats. Hearing research 139: 69-85.
18. Grzeschik R, Böckmann-Barthel M, Mühler R, Hoffmann MB (2010) Motion-onset auditory-evoked potentials critically depend on history. Experimental brain research 203: 159-168.
19. Grantham DW (1986) Detection and discrimination of simulated motion targets in the horizontal plane. 79: 1939-1949.
20. Grantham DW (1997) Auditory motion perception: Snapshots revsiited. In: Gilkey RH, Anderseon TR, editors. Binaural and spatial hearing in real and virtual environments. New Jersey: Lawrence Erlbaum.
21. Getzmann S, Lewald J (2011) The effect of spatial adaptation on auditory motion processing. Hearing research 272: 21-29.
22. Mollon JD (1974) After-effects and the brain. New Scientist 61: 479-482.
23. Grantham DW (1989) Motion aftereffects with horizontally moving sound sources in the free field. Perception & psychophysics 45: 129-136.
24. Dong CJ, Swindale NV, Zakarauskas P, Hayward V, Cynader MS (2000) The auditory motion aftereffect: its tuning and specificity in the spatial and frequency domains. Perception & psychophysics 62: 1099-1111.
25. Neelon MF, Jenison RL (2003) The effect of trajectory on the auditory motion aftereffect. Hearing Research 180: 57-66. (Pubitemid 36627603)
26. Anstis S, Verstraten FAJ, Mather G (1998) The motion aftereffect. Trends in Cognitive Sciences 2: 111-117. (Pubitemid 28396474)
27. Chandler DW, Grantham DW (1992) Minimum audible movement angle in the horizontal plane as a funciton of stimulus frequency and bandwidth, source azimuth, and velocity. Journal of the Acoustical Society of America 91.
28. Perrott DR, Tucker J (1988) Minimum audible movement angle as a function of signal frequency and the velocity of the source for publication. 1522-1527.
29. Xiao X, Grantham D (1997) The effect of a free-field auditory target's motion on its detectability in the horizontal plane. The Journal of the Acoustical Society of America 102: 1907-1910. (Pubitemid 27391375)
30. Perrott DR, Marlborough K (1989) Minimum audible movement angle: marking the end points of the path traveled by a moving sound source. The Journal of the Acoustical Society of America 85: 1773-1775.
31. Nakayama K (1985) Biological image motion processing: a review. Vision Research 25: 625-660.
32. Carlile S, Best V (2002) Discrimination of sound source velocity in human listeners. The Journal of the Acoustical Society of America 111: 1026-1035. (Pubitemid 34127483)
33. Freeman TCA, Sumnall JH (2002) Motion versus position in the perception of head-centred movement. Perception 31: 603-615.
34. Gegenfurtner KR, Hawken MJ (1995) Temporal and chromatic properties of motion mechanisms. Vision Research 35: 1547-1563.
35. Noorlander C, Heuts MJG, Koenderink JJ (1980) Influence of the target size on the detection threshold for luminance and chromaticity contrast. Journal of the Optical Society of America 70: 1116-1121.
36. Poirson AB, Wandell BA, Varner DC, Brainard DH (1990) Surface characterizations of color thresholds. Journal of the Optical Society of America A 7: 783-789.
37. Wandell BA (1985) Colour measurement and discrimination. Journal of Optical Society of America A 2: 62-71.
38. Champion RA, Freeman TCA (2010) Discrimination contours for the perception of head-centred velocity. Journal of Vision 10(6):14: 1-9.
39. Reisbeck TE, Gegenfurtner KR (1999) Velocity tuned mechanisms in human motion processing. Vision Research 39: 3267-3285.
40. Wardle SG, Alais D (2013) Evidence for speed sensitivity to motion in depth from binocular cues. 13: 1-16.
41. Middlebrooks JC, Green DM (1991) Sound localisation by human listeners. Annual review of psychology 42: 135-159.
42. Pralong D, Carlile S (1996) Generation and validation of virtual auditory space. In: Carlile S, editor. Virtual auditory space: Generation and applications. Austin: Landes.
43. Farina A (2007) Advancements in impulse response measurements by sine sweeps. Ausio Engineering Society Convention 122.
44. Ernst MO (2007) Learning to integrate arbitrary signals from vision and touch. Journal of Vision 7(5):7: 1-14.
45. Wichmann FA, Hill NJ (2001) The psychometric function: I. Fitting, sampling, and goodness of fit. Perception & Psychophysics 63: 1293.
46. Bompas A, Sumner P (2013) Systematic biases in adult color perception persist despite lifelong information sufficient to calibrate them. 13: 1-19.
47. Lappin JS, Bell HH, Harm OJ, Kottas B (1975) On the relation between time and space in the visual discrimination of velocity. Journal of Experimental Psychology: Human Perception and Performance 1: 383-394.
48. Kaczmarek T (2005) Auditory perception of sound source velocity. Journal of the Acoustical Society of America 117: 3149-3156.
49. Lutfi RA, Wang W (1999) Correlational analysis of acoustic cues for the discrimination of auditory motion. Journal of the Acoustical Society of America 106: 919-928. (Pubitemid 29379519)
50. Kaczmarek T (2005) Auditory perception of sounds source velocity. Journal of the Acoustical Society of America 117: 3149-3156.
51. Wuerger SM, Meyer GF, Hofbauer M, Zetzsche C, Schill K (2010) Motion extrapolation of auditory-visual targets. Information fusion 11: 45-50.