The Effect of Hearing Loss on Localization of Amplitude-Panned and Physical Sources

 

 Lizenzen und Reprints

Abstract

Background Clinics are increasingly turning toward using virtual environments to demonstrate and validate hearing aid fittings in “realistic” listening situations before the patient leaves the clinic. One of the most cost-effective and straightforward ways to create such an environment is through the use of a small speaker array and amplitude panning. Amplitude panning is a signal playback method used to change the perceived location of a source by changing the level of two or more loudspeakers. The perceptual consequences (i.e., perceived source width and location) of amplitude panning have been well-documented for listeners with normal hearing but not for listeners with hearing impairment.

Purpose The purpose of this study was to examine the perceptual consequences of amplitude panning for listeners with hearing statuses from normal hearing through moderate sensorineural hearing losses.

Research Design Listeners performed a localization task. Sound sources were broadband 4 Hz amplitude-modulated white noise bursts. Thirty-nine sources (14 physical) were produced by either physical loudspeakers or via amplitude panning. Listeners completed a training block of 39 trials (one for each source) before completing three test blocks of 39 trials each. Source production method was randomized within block.

Study Sample Twenty-seven adult listeners (mean age 52.79, standard deviation 27.36, 10 males, 17 females) with hearing ranging from within normal limits to moderate bilateral sensorineural hearing loss participated in the study. Listeners were recruited from a laboratory database of listeners that consented to being informed about available studies.

Data Collection and Analysis Listeners indicated the perceived source location via touch screen. Outcome variables were azimuth error, elevation error, and total angular error (Euclidean distance in degrees between perceived and correct location). Listeners' pure-tone averages (PTAs) were calculated and used in mixed-effects models along with source type and the interaction between source type and PTA as predictors. Subject was included as a random variable.

Results Significant interactions between PTA and source production method were observed for total and elevation errors. Listeners with higher PTAs (i.e., worse hearing) did not localize physical and panned sources differently whereas listeners with lower PTAs (i.e., better hearing) did. No interaction was observed for azimuth errors; however, there was a significant main effect of PTA.

Conclusion As hearing impairment becomes more severe, listeners localize physical and panned sources with similar errors. Because physical and panned sources are not localized differently by adults with hearing loss, amplitude panning could be an appropriate method for constructing virtual environments for these listeners.

Previous Presentations

Portions of this work were presented at the 177th Meeting of the Acoustical Society of America in Louisville, Kentucky. The meeting was in May, 2019.

Publikationsverlauf

Eingereicht: 31. Oktober 2019

Angenommen: 27. März 2020

Artikel online veröffentlicht:
08. Oktober 2020

© 2020. American Academy of Audiology. This article is published by Thieme.

Thieme Medical Publishers, Inc.
333 Seventh Avenue, 18th Floor, New York, NY 10001, USA

• References

• 1 Benítez-Barrera CR, Thompson EC, Angley GP, Woynaroski T, Tharpe AM. Remote microphone system use at home: impact on child-directed speech. J Speech Lang Hear Res 2019; 62 (06) 2002-2008
  CrossrefPubMedGoogle Scholar
• 2 Gatehouse S, Naylor G, Elberling C. Linear and nonlinear hearing aid fittings--2. Patterns of candidature. Int J Audiol 2006; 45 (03) 153-171
  CrossrefPubMedGoogle Scholar
• 3 Klein KE, Wu Y-H, Stangl E, Bentler RA. Using a digital language processor to quantify the auditory environment and the effect of hearing aids for adults with hearing loss. J Am Acad Audiol 2018; 29 (04) 279-291
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 4 Wu Y-H, Stangl E, Chipara O, Hasan SS, Welhaven A, Oleson J. Characteristics of real-world signal to noise ratios and speech listening situations of older adults with mild to moderate hearing loss. Ear Hear 2018; 39 (02) 293-304
  CrossrefPubMedGoogle Scholar
• 5 Timmer BHB, Hickson L, Launer S. Do hearing aids address real-world hearing difficulties for adults with mild hearing impairment? Results from a pilot study using ecological momentary assessment. Trends Hear 2018; 22: 2331216518783608
  Google Scholar
• 6 Wu Y-H, Stangl E, Zhang X, Bentler RA. Construct validity of the ecological momentary assessment in audiology research. J Am Acad Audiol 2015; 26 (10) 872-884
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 7 Compton-Conley CL, Neuman AC, Killion MC, Levitt H. Performance of directional microphones for hearing aids: real-world versus simulation. J Am Acad Audiol 2004; 15 (06) 440-455
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 8 Miller CW, Stewart EK, Wu Y-H, Bishop C, Bentler RA, Tremblay K. Working memory and speech recognition in noise under ecologically relevant listening conditions: effects of visual cues and noise type among adults with hearing loss. J Speech Lang Hear Res 2017; 60 (08) 2310-2320
  CrossrefPubMedGoogle Scholar
• 9 Valente M, Mispagel KM, Tchorz J, Fabry D. Effect of type of noise and loudspeaker array on the performance of omnidirectional and directional microphones. J Am Acad Audiol 2006; 17 (06) 398-412
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 10 Frank M, Zotter F, Sontacchi A. Producing 3D audio in Ambisonics. Paper presented at the 57th International Conference: The future of audio entertainment technology; March 6–8, 2015; Hollywood, CA
  Google Scholar
• 11 Pulkki V. Virtual sound source position using vector base amplitude panning. J Audio Eng Soc 1997; 45 (06) 456-466
  Google Scholar
• 12 Seldess Z. MIAP: manifold-interface amplitude panning in Max/MSP and pure data. Paper presented at the Audio Engineering Society Convention 137; 2014
  Google Scholar
• 13 Baumgartner R, Majdak P. Modeling localization of amplitude-panned virtual sources in sagittal planes. J Audio Eng Soc 2015; 63 (7-8): 562-569
  CrossrefPubMedGoogle Scholar
• 14 Pulkki V. Localization of amplitude-panned virtual sources II: two-and three-dimensional panning. J Audio Eng Soc 2001; 49 (09) 753-767
  Google Scholar
• 15 Pulkki V, Karjalainen M. Localization of amplitude-panned virtual sources - I: stereophonic panning. J Audio Eng Soc 2001; 49 (09) 739-752
  Google Scholar
• 16 Wendt K. Das Richtungshören bei der Überlageruun zqeier Schallfelder bei Intensitäts - un Laufzeitstereophonie [Directional hearing with two superimposed sound fields in intensity- and delay-different stereophony]. Aachen: Technische Hochschule; 1963
  Google Scholar
• 17 Blauert J. Spatial Hearing: the Psychophysics of Human Sound Localization. Cambridge, MA: MIT Press; 1983
  Google Scholar
• 18 Brungart DS, Durlach NI, Rabinowitz WM. Auditory localization of nearby sources. II. Localization of a broadband source. J Acoust Soc Am 1999; 106 (4 Pt 1): 1956-1968
  CrossrefPubMedGoogle Scholar
• 19 Giguère C, Abel SM. Sound localization: effects of reverberation time, speaker array, stimulus frequency, and stimulus rise/decay. J Acoust Soc Am 1993; 94 (2 Pt 1): 769-776
  CrossrefPubMedGoogle Scholar
• 20 Hartmann WM. Localization of sound in rooms. J Acoust Soc Am 1983; 74 (05) 1380-1391
  CrossrefPubMedGoogle Scholar
• 21 Hartmann WM, Rakerd B. Localization of sound in rooms. IV: the Franssen effect. J Acoust Soc Am 1989; 86 (04) 1366-1373
  CrossrefPubMedGoogle Scholar
• 22 Middlebrooks JC. Narrow-band sound localization related to external ear acoustics. J Acoust Soc Am 1992; 92 (05) 2607-2624
  CrossrefPubMedGoogle Scholar
• 23 Mills AW. On the minimum audible angle. J Acoust Soc Am 1958; 30 (04) 237-246
  CrossrefGoogle Scholar
• 24 Wightman FL, Kistler DJ, Perkins ME. A new approach to the study of human sound localization. In: Yost WA, Gourevitch G. eds. Directional Hearing. New York, NY: Springer; 1987: 26-48
  CrossrefGoogle Scholar
• 25 Johnson JA, Xu J, Cox RM. Impact of hearing aid technology on outcomes in daily life III: localization. Ear Hear 2017; 38 (06) 746-759
  CrossrefPubMedGoogle Scholar
• 26 Oreinos C, Buchholz JM. Evaluation of loudspeaker-based virtual sound environments for testing directional hearing aids. J Am Acad Audiol 2016; 27 (07) 541-556
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 27 Ricketts TA, Picou EM, Shehorn J, Dittberner AB. Degree of hearing loss affects bilateral hearing aid benefits in ecologically relevant laboratory conditions. J Speech Lang Hear Res 2019; 62 (10) 3834-3850
  CrossrefPubMedGoogle Scholar
• 28 Weller T, Best V, Buchholz JM, Young T. A method for assessing auditory spatial analysis in reverberant multitalker environments. J Am Acad Audiol 2016; 27 (07) 601-611
  Artikel in Thieme ConnectPubMedGoogle Scholar
• 29 Hair JFJ, Anderson RE, Tatham RL, Black WC. Multivariate Data Analysis. 3rd ed.. New York: Macmillan; 1995
  Google Scholar
• 30 Ringle CM, Wende S, Becker JM. SmartPLS 3. Boenningstedt: SmartPLS GmbH; 2015
  Google Scholar
• 31 Dorman MF, Loiselle LH, Cook SJ, Yost WA, Gifford RH. Sound source localization by normal-hearing listeners, hearing-impaired listeners and cochlear implant listeners. Audiol Neurotol 2016; 21 (03) 127-131
  CrossrefPubMedGoogle Scholar
• 32 Häusler R, Colburn S, Marr E. Sound localization in subjects with impaired hearing: Spatial-discrimination and interaural-discrimination tests. Acta Otolaryngol Suppl 1983; 400: 1-62
  CrossrefPubMedGoogle Scholar
• 33 Moore BCJ. An Introduction to the Psychology of Hearing. 6th ed.. Leiden: Brill; 2013
  Google Scholar