MIRE- IL methodology applied to measuring the noise attenuation of earmuff hearing protectors

► An objective methodology for measuring earmuff hearing protector noise attenuation is presented. ► The methodology does not depend on human response and is less time consuming than the REAT method. ► A proper bone conduction correction factor allows one to predict the real protection of HPDs. ► Th...

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Bibliographic Details
Published in:Applied acoustics 2011-06, Vol.72 (7), p.451-457
Main Authors: de Almeida-Agurto, Danilo, Gerges, Samir N.Y., Arenas, Jorge P.
Format: Article
Language:English
Subjects:
Acoustics
Exact sciences and technology
Fundamental areas of phenomenology (including applications)
Hearing protectors
Insertion loss
MIRE
Noise attenuation
Noise: its effects and control
Physics
REAT
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Summary:► An objective methodology for measuring earmuff hearing protector noise attenuation is presented. ► The methodology does not depend on human response and is less time consuming than the REAT method. ► A proper bone conduction correction factor allows one to predict the real protection of HPDs. ► The proposed methodology shows lower standard deviation values than the REAT method. This article describes an objective methodology for measuring the noise attenuation of earmuff hearing protectors using as a reference the method known as microphone-in-real-ear (MIRE). The methodology implements the insertion loss ( IL) paradigm, in which IL is measured using miniature microphones, specially designed to comply with ANSI and ISO standards for the MIRE technique. The results for four different hearing protectors are compared with the subjective method known as real-ear-attenuation-at-threshold ( REAT). Correction factors are included in the methodology to account for external effects such as physiological noise and bone conduction. The objective method predicted well the real protection of the earmuffs and the proposed methodology showed lower standard deviation values than the REAT method.
ISSN:0003-682X
1872-910X
DOI:10.1016/j.apacoust.2011.01.009