The Role of the Bandwidth-Duration Product WT in the Detectability of Diotic Signals

The bandwidth-duration product, WT , is a fundamental parameter in most theories of aural amplitude discrimination of Gaussian noise. These theories predict that detectability is dependent on WT , but not on the individual values of bandwidth and duration. Due to the acoustical uncertainty principle...

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Bibliographic Details
Main Author: Lapsley Miller, Judi
Format: Thesis
Language:unknown
Published: 1999
Subjects:
Psychology and Cognitive Sciences not elsewhere classified
Acoustical uncertainty principle
Auditory filter
Diotic
Critical band
Duration reciprocity
Asymptotic performance
Gaussian noise
Measures of detectability
Bandwidth
Duration Product
Envelope detector
Ideal observers
Group Operating Characteristic (GOC) analysis
Non parametic
Information theory
Auditory time constant
Temporal integrator
Function of Replications Added (FORA)
Combinations analysis
Energy detector
Linear detector
Function of Replications Combined Estimation (FORCE) analysis
School: Antarctic Research Centre
179999 Psychology and Cognitive Sciences not elsewhere classified
Marsden: 380109 Psychological Methodology
Design and Analysis
Degree Discipline: Psychology
Degree Level: Doctoral
Degree Name: Doctor of Philosophy
Antarctic
Marsden
Antarc*
Online Access:https://doi.org/10.26686/wgtn.16934959.v1
https://figshare.com/articles/thesis/The_Role_of_the_Bandwidth-Duration_Product_WT_in_the_Detectability_of_Diotic_Signals/16934959
Description
Summary:The bandwidth-duration product, WT , is a fundamental parameter in most theories of aural amplitude discrimination of Gaussian noise. These theories predict that detectability is dependent on WT , but not on the individual values of bandwidth and duration. Due to the acoustical uncertainty principle, it is impossible to completely specify an acoustic waveform with both finite duration and finite bandwidth. An observer must decide how best to trade-off information in the time domain with information in the frequency domain. As Licklider (1963) states, "The nature of [the ear's] solution to the time-frequency problem is, in fact, one of the central problems in the psychology of hearing."This problem is still unresolved, primarily due to observer inconsistency in experiments, which degrades performance making it difficult to compare models. The aim was to compare human observers' ability to trade bandwidth and duration, with simulated and theoretical observers. Human observers participated in a parametric study where the bandwidth and duration of 500 Hz noise waveforms was systematically varied for the same bandwidth-duration products (WT = 1, 2, and 4, where W varied over 2.5-160 Hz, and T varied over 400-6.25 ms, in octave steps). If observers can trade bandwidth and duration, detectability should be constant for the same WT . The observers replicated the experiments six times so that group operating characteristic (GOC) analysis could be used to reduce the effects of their inconsistent decision making. Asymptotic errorless performance was estimated by extrapolating results from the GOC analysis, as a function of replications added. Three simulated ideal observers: the energy, envelope, and full-linear (band-pass filter, full-wave rectifier, and true integrator) detectors were compared with each other, with mathematical theory and with human observers. Asymptotic detectability relative to the full-linear detector indicates that human observers best detect signals with a bandwidth of 40-80 Hz and a duration of ...

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