Restricted accessResearch articleFirst published online 2015-2
Effects of Frequency Separation and Diotic/Dichotic Presentations on the Alternation Frequency Limits in Audition Derived from a Temporal Phase Discrimination Task
Temporal phase discrimination is a useful psychophysical task to evaluate how sensory signals, synchronously detected in parallel, are perceptually bound by human observers. In this task two stimulus sequences synchronously alternate between two states (say, A-B-A-B and X-Y-X-Y) in either of two temporal phases (ie A and B are respectively paired with X and Y, or vice versa). The critical alternation frequency beyond which participants cannot discriminate the temporal phase is measured as an index characterizing the temporal property of the underlying binding process. This task has been used to reveal the mechanisms underlying visual and cross-modal bindings. To directly compare these binding mechanisms with those in another modality, this study used the temporal phase discrimination task to reveal the processes underlying auditory bindings. The two sequences were alternations between two pitches. We manipulated the distance between the two sequences by changing intersequence frequency separation, or presentation ears (diotic vs dichotic). Results showed that the alternation frequency limit ranged from 7 to 30 Hz, becoming higher as the intersequence distance decreased, as is the case with vision. However, unlike vision, auditory phase discrimination limits were higher and more variable across participants.
AghdaeeS. M.CavanaghP. (2007). Temporal limits of long-range phase discrimination across the visual field. Vision Research, 472156–2163.
2.
AmanoK.JohnstonA.NishidaS. (2007). Two mechanisms underlying the effect of angle of motion direction change on colour–motion asynchrony. Vision Research, 47687–705.
3.
ArnoldD. H. (2005). Perceptual pairing of colour and motion. Vision Research, 453015–3026.
4.
BartelsA.ZekiS. (2006). The temporal order of binding visual attributes. Vision Research, 462280–2286.
5.
BregmanA. S.CampbellJ. (1971). Primary auditory stream segregation and perception of order in rapid sequences of tones. Journal of Experimental Psychology, 89244–249.
6.
BregmanA. S.PinkerS. (1978). Auditory streaming and the building of timbre. Canadian Journal of Psychology/Revue Canadienne de Psychologie, 3219–31.
7.
CarlyonR. P. (1991). Discriminating between coherent and incoherent frequency-modulation of complex tones. The Journal of the Acoustical Society of America, 89329–340.
8.
CarlyonR. P. (1994). Further evidence against an across-frequency mechanism specific to the detection of frequency-modulation (FM) incoherence between resolved frequency components. The Journal of the Acoustical Society of America, 95949–961.
9.
ChiT.RuP.ShammaS. A. (2005). Multiresolution spectrotemporal analysis of complex sounds. The Journal of the Acoustical Society of America, 118887–906.
10.
CliffordC. W. G.HolcombeA. O.PearsonJ. (2004). Rapid global form binding with loss of associated colors. Journal of Vision, 4(12):8, 1090–1101.
11.
DannenbringG. L.BregmanA. S. (1978). Streaming vs. fusion of sinusoidal components of complex tones. Perception & Psychophysics, 24369–376.
FujisakiW.KoeneA.ArnoldD.JohnstonA.NishidaS. (2006). Visual search for a target changing in synchrony with an auditory signal. Proceedings of the Royal Society of London, Series B: Biological Sciences, 273(1588), 865–874.
14.
FujisakiW.NishidaS. (2007). Feature-based processing of audiovisual synchrony perception revealed by random pulse trains. Vision Research, 471075–1093.
15.
FujisakiW.NishidaS. (2008). Top-down feature-based selection of matching features for audiovisual synchrony discrimination. Neuroscience Letters, 433225–230.
16.
FujisakiW.NishidaS. (2010). A common perceptual temporal limit of binding synchronous inputs across different sensory attributes and modalities. Proceedings of the Royal Society of London, Series B: Biological Sciences, 277(1692), 2281–2290.
17.
FurukawaS.MooreB. C. J. (1996). Across-channel processes in frequency modulation detection. The Journal of the Acoustical Society of America, 1002299–2311.
18.
FurukawaS.MooreB. C. J. (1997). Dependence of frequency modulation detection on frequency modulation coherence across carriers: Effects of modulation rate, harmonicity, and roving of the carrier frequencies. The Journal of the Acoustical Society of America, 1011632–1643.
19.
GlasbergB. R.MooreB. C. (1990). Derivation of auditory filter shapes from notched-noise data. Hearing Research, 47103–138.
20.
HolcombeA. O. (2009). Seeing slow and seeing fast: Two limits on perception. Trends in Cognitive Sciences, 13216–221.
21.
HolcombeA. O.CavanaghP. (2001). Early binding of feature pairs for visual perception. Nature Neuroscience, 4127–128.
22.
HolcombeA. O.JudsonJ. (2007). Visual binding of English and Chinese word parts is limited to low temporal frequencies. Perception, 3649–74.
LuT.LiangL.WangX. (2001). Temporal and rate representations of time-varying signals in the auditory cortex of awake primates. Nature Neuroscience, 41131–1138.
25.
MaruyaK.HolcombeA. O.NishidaS. (2013). Rapid encoding of relationships between spatially remote motion signals. Journal of Vision, 13(2):4, 1–20.
26.
MicheylC.HunterC.OxenhamA. J. (2010). Auditory stream segregation and the perception of across-frequency synchrony. Journal of Experimental Psychology: Human Perception and Performance, 361029–1039.
27.
MooreB. C. J. (2003). An Introduction to the Psychology of Hearing (5th ed.). San Diego, CA: Academic Press.
28.
MooreB. C.GockelH. (2002). Factors influencing sequential stream segregation. Acta Acustica united with Acustica, 88320–333.
29.
MoutoussisK.ZekiS. (1997). A direct demonstration of perceptual asynchrony in vision. Proceedings of the Royal Society of London, Series B: Biological Sciences, 264393–399.
30.
NishidaS.JohnstonA. (2002). Marker correspondence, not processing latency, determines temporal binding of visual attributes. Current Biology, 12359–368.
31.
PattersonR. D. (1976). Auditory filter shapes derived with noise stimuli. The Journal of the Acoustical Society of America, 59640–654.
32.
RichardsV. M. (1987). Monaural envelope correlation perception. The Journal of the Acoustical Society of America, 821621–1630.
33.
StricklandE. A.ViemeisterN. F.FantiniD. A.GarrisonM. A. (1989). Within- versus cross-channel mechanisms in detection of envelope phase disparity. The Journal of the Acoustical Society of America, 862160–2166.
34.
TreismanA. (1996). The binding problem. Current Opinion in Neurobiology, 6171–178.
35.
van NoordenL. P. A. S. (1975). Temporal coherence in the perception of tone sequences. Unpublished doctoral dissertation, Eindhoven University of Technology, Eindhoven, The Netherlands.
36.
VictorJ. D.ConteM. M. (2002). Temporal phase discrimination depends critically on separation. Vision Research, 422063–2071.
37.
WarrenR. M.ObusekC. J.FarmerR. M. (1969). Auditory sequence: Confusion of patterns other than speech or music. Science, 164(3879), 586–587.
38.
YostW. A.SheftS. (1989). Across-critical-band processing of amplitude-modulated tones. The Journal of the Acoustical Society of America, 85848–857.
