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Literature DB >> 20329836

Interaural coherence for noise bands: waveforms and envelopes.

Abstract

This paper reports the results of experiments performed in an effort to find a formulaic relationship between the interaural waveform coherence of a band of noise gamma(W) and the interaural envelope coherence of the noise band gamma(E). An interdependence described by gamma(E)=pi/4+(1-pi/4)(gamma(W))(2.1) is found. This relationship holds true both in a computer experiment and for binaural measurements made in two rooms using a KEMAR manikin. Room measurements are used to derive a measure of reliability for the formula. Ultimately, a user who knows the waveform coherence can predict the envelope coherence with a small degree of uncertainty.

Mesh：

Year: 2010 PMID： 20329836 PMCID： PMC2906201 DOI： 10.1121/1.3290991

Source DB: PubMed Journal: J Acoust Soc Am ISSN： 0001-4966 Impact factor: 1.840

14 in total

7. Time-Varying Distortions of Binaural Information by Bilateral Hearing Aids: Effects of Nonlinear Frequency Compression.

Authors: Andrew D Brown; Francisco A Rodriguez; Cory D F Portnuff; Matthew J Goupell; Daniel J Tollin
Journal: Trends Hear Date: 2016-10-03 Impact factor: 3.293

7 in total

Interaural coherence for noise bands: waveforms and envelopes.

1. A consideration of the normalization that is typically included in correlation-based models of binaural detection.

2. The coherence of reverberant sound fields.

3. Interaural correlation sensitivity.

4. Derivation of auditory filter shapes from notched-noise data.

5. Discrimination of interaural envelope correlation and its relation to binaural unmasking at high frequencies.

6. Interaural correlation and the binaural summation of loudness.

7. Spatial mapping of intracranial auditory events for various degrees of interaural coherence.

8. Temporal coding of resonances by low-frequency auditory nerve fibers: single-fiber responses and a population model.

9. Binaural detection at high frequencies with time-delayed waveforms.

10. Detectability of a pulsed tone in the presence of a masker with time-varying interaural correlation.

1. Localization of sound in rooms. V. Binaural coherence and human sensitivity to interaural time differences in noise.

2. Envelope contributions to the representation of interaural time difference in the forebrain of barn owls.

3. Effects of interaural decoherence on sensitivity to interaural level differences across frequency.

4. On the localization of high-frequency, sinusoidally amplitude-modulated tones in free field.

5. Human cortical processing of interaural coherence.

6. Sensitivity to a Break in Interaural Correlation in Frequency-Gliding Noises.

7. Time-Varying Distortions of Binaural Information by Bilateral Hearing Aids: Effects of Nonlinear Frequency Compression.