Detection and discrimination of frequency glides as a function of direction, duration, frequency span, and center frequency

Madden, John; Fire, Kevin M.

doi:10.1121/1.420346

Cited by 20 publications

(17 citation statements)

References 17 publications

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“…The matches to rising glides were, on average, at frequencies slightly lower than two thirds of the way into the glide; falling glides received matches that were closer to the midpoint of 1,000 Hz. This confirms findings by Gardner and Wilson [1979], Madden and Fire [1997], Moore and Sek [1998, exper-iment 1, transition span of 0 Hz], Nábelek [1978], Pisoni [1976], Schouten [1985], and Smoorenburg and Coninx [1980], to the effect that falling tones are perceptually closer to steady-state tones than are rising ones. In all these studies, it is easier to discriminate stationary tones from rising than from falling glides, although the difference is usually small.…”

Section: Control Condition 1 (Single Matching Tone)supporting

confidence: 78%

Searching for an Explanation for Diphthong Perception: Dynamic Tones and Dynamic Spectral Profiles

Schouten¹,

Peeters²

2000

Phonetica

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The aim was to find a psychophysical explanation for the perception, by naive listeners, of diphthongs as single vowels, even though they are essentially formant movements. Subjects were asked to match sinusoidal tone and resonance glides around 1,000 Hz with two connected steady-state tones or resonances whose frequencies could be controlled independently. The expectation was that short glides (below 120 ms) would give rise to single perceptual events without any movement in a particular direction, so that the two matching steady-state patterns would not show any frequency direction either; long resonance glides (above 120 ms), on the other hand, were expected to be perceived as rising or falling and matched accordingly. The results showed an effect of duration, although it interacted with glide width. At durations shorter than about 120 ms, subjects placed the two steady profiles with which they had to match the dynamic profile closer together than with durations over 120 ms; however, this only occurred if a glide covered more than 500 Hz, and is therefore irrelevant to diphthong perception.

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Section: Control Condition 1 (Single Matching Tone)supporting

confidence: 78%

Searching for an Explanation for Diphthong Perception: Dynamic Tones and Dynamic Spectral Profiles

Schouten¹,

Peeters²

2000

Phonetica

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“…That the auditory system, in general, is well equipped to analyze FM signals has been shown in a range of neurophysiological studies in animals (Whitfield and Evans, 1965;Suga, 1968;Heil et al, 1992;Mendelson et al, 1993;Eggermont, 1994Eggermont, , 2001Liang et al, 2002) as well as in human psychophysical (Schouten, 1985(Schouten, , 1986Dooley and Moore, 1988;Schouten and Pols, 1989;Viemeister, 1994a,b, 1997;Madden and Fire, 1997;Moore, 1997;Moore and Sek, 1992;Gordon and Poeppel, 2002) and brain imaging studies (Makela et al, 1987;Dimitrijevic et al, 2001;John et al, 2001John et al, , 2002Picton et al, 1987Picton et al, , 2003Boemio et al, 2005;Luo et al, 2006).…”

Section: Introductionmentioning

confidence: 95%

The perception of FM sweeps by Chinese and English listeners

et al. 2007

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“…Future studies need to test if these two DF thresholds match with each other in individual CI users. Madden and Fire (1997) showed that NH listeners can detect 400-ms, 12-Hz frequency glides around 500 Hz. Although obtained with different experimental setups, these NH data were slightly lower than our CI users' DF thresholds.…”

Section: Discussionmentioning

confidence: 99%

Pitch contour identification with combined place and temporal cues using cochlear implants

Luo

Padilla

Landsberger

2012

The Journal of the Acoustical Society of America

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This study investigated the integration of place-and temporal-pitch cues in pitch contour identification (PCI), in which cochlear implant (CI) users were asked to judge the overall pitch-change direction of stimuli. Falling and rising pitch contours were created either by continuously steering current between adjacent electrodes (place pitch), by continuously changing amplitude modulation (AM) frequency (temporal pitch), or both. The percentage of rising responses was recorded as a function of current steering or AM frequency change, with single or combined pitch cues. A significant correlation was found between subjects' sensitivity to current steering and AM frequency change. The integration of place-and temporal-pitch cues was most effective when the two cues were similarly discriminable in isolation. Adding the other (place or temporal) pitch cues shifted the temporal-or place-pitch psychometric functions horizontally without changing the slopes. PCI was significantly better with consistent place-and temporal-pitch cues than with inconsistent cues. PCI with single cues and integration of pitch cues were similar on different electrodes. The results suggest that CI users effectively integrate place-and temporal-pitch cues in relative pitch perception tasks. Current steering and AM frequency change should be coordinated to better transmit dynamic pitch information to CI users.

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Detection and discrimination of frequency glides as a function of direction, duration, frequency span, and center frequency

Cited by 20 publications

References 17 publications

Searching for an Explanation for Diphthong Perception: Dynamic Tones and Dynamic Spectral Profiles

Searching for an Explanation for Diphthong Perception: Dynamic Tones and Dynamic Spectral Profiles

The perception of FM sweeps by Chinese and English listeners

Pitch contour identification with combined place and temporal cues using cochlear implants

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