Your search keyword '"Chen, ZhangLi"' showing total 2 results

1. A new method of calculating auditory excitation patterns and loudness for steady sounds

Author

Chen, Zhangli, Hu, Guangshu, Glasberg, Brian R., and Moore, Brian C.J.

Subjects

*LOUDNESS, *SOUNDS, *EXCITATION (Physiology), *BANDWIDTHS, *NOISE, *BASILAR membrane

Abstract

Abstract: A new method for calculating auditory excitation patterns and loudness for steady sounds is described. The method is based on a nonlinear filterbank in which each filter is the sum of a broad passive filter and a sharp active filter. All filters have a rounded-exponential shape. For each center frequency (CF), the gain of the active filter is controlled by the output of the passive filter. The parameters of the model were derived from large sets of previously published notched-noise masking data obtained from human subjects. Excitation patterns derived using the new filterbank include the effects of basilar membrane compression. Loudness can be calculated as the area under the excitation pattern when plotted in intensity-like units on an ERBN-number (Cam) scale; no transformation from excitation to specific loudness is required. The method predicts the standard equal-loudness contours and loudness as a function of bandwidth with good accuracy. With some additional assumptions, the method also gives reasonably accurate predictions of partial loudness. [Copyright &y& Elsevier]

Published

2011

2. A new model for calculating auditory excitation patterns and loudness for cases of cochlear hearing loss

Author

Chen, Zhangli, Hu, Guangshu, Glasberg, Brian R., and Moore, Brian C.J.

Subjects

*COCHLEA, *HAIR cells, *HEARING disorders, *LOUDNESS, *ATTENUATION (Physics)

Abstract

Abstract: A model for calculating auditory excitation patterns and loudness for steady sounds for normal hearing is extended to deal with cochlear hearing loss. The filters used in the model have a double ROEX-shape, the gain of the narrow active filter being controlled by the output of the broad passive filter. It is assumed that the hearing loss at each audiometric frequency can be partitioned into a loss due to dysfunction of outer hair cells (OHCs) and a loss due to dysfunction of inner hair cells (IHCs). OHC loss is modeled by decreasing the maximum gain of the active filter, which results in increased absolute threshold, reduced compressive nonlinearity and reduced frequency selectivity. IHC loss is modeled by a level-dependent attenuation of excitation level, which results in elevated absolute threshold. The magnitude of OHC loss and IHC loss can be derived from measures of loudness recruitment and the measured absolute threshold, using an iterative procedure. The model accurately fits loudness recruitment data obtained using subjects with unilateral or highly asymmetric cochlear hearing loss who were required to make loudness matches between tones presented alternately to the two ears. With the same parameters, the model predicted loudness matches between narrowband and broadband sound reasonably well, reflecting loudness summation. The model can also predict when a dead region is present. [Copyright &y& Elsevier]

Published

2011