Ph.D position: Modeling of the acoustic response of hearing protectors excited by impulsive industrial noise (Ecole de Technologie Superieure, Montreal, Canada)

Application deadline: Sat 15 Oct 2022

Context : The selection of a hearing protector, the last bastion to protect against exposure to noise, is mainly
based on the acoustic attenuation it can provide. While knowledge on the attenuation of hearing protectors for
continuous noise has progressed in recent years, that on attenuation for industrial impulse noise is less advanced
both in terms of metrology and in terms of modeling. A model relaxing the limits of existing models and allowing
for a better understanding of the transmission of waves in the ear/protector system with a view in particular to
improving the design of protectors and the methods for measuring their performance against impulse noise is
lacking. Recent progress made on the numerical modeling of hearing protection for continuous noises and the
increasing use in other applications of the Bayesian formalism integrating all the uncertainties of the problem,
make it possible to consider the development of such a model. It is in this perspective of designing a probabilistic
model by finite elements (FE) of the acoustic response of the auditory canals of a human head, equipped or not
with a protector, excited by impulse industrial noises and including all the transmission paths through tissues, that
a research program is proposed. This research program is divided into four specific objectives: OS1) Model the
acoustic response of the unprotected ear; OS2) Model the acoustic response of hearing protectors; OS3) Model
the acoustic response of the ear coupled to a protector; OS4) Exploit FE models to understand the mechanisms of
sound transmission in the earcanal open or occluded by a protector, taking into account uncertainties.


Subject of the Ph.D. project: This topic tackles the specific objectives OS2 and OS4 and consists in developing a
probabilistic model by FE of the sound transmission of industrial impulse noise through different types of
protectors. The corresponding FE models will be calibrated/validated in a Bayesian framework from experimental
data provided by simplified test benches and will be used to study the underlying mechanisms of sound
transmission.


Main tasks: In addition to carrying out his·her doctoral project in compliance with the rules of research ethics, the student will contribute to the writing of deliverables (e.g., articles, presentations, reports) and will be encouraged to present his·her work at international scientific conferences.

More information in this document.

Contact: Send resume + cover letter to Franck Sgard (Franck.Sgard@irsst.qc.ca)