Tech Topic | November 2015 Hearing Review
The authors take issue with recent reports about the performance of Musicians Earplugs, and show that the ways in which data were graphically displayed explain the differences in interpretation.
Repeated claims in recent years that ER-15 Musicians Earplugs®1 and ER-20® HiFi earplugs do not perform as advertised have been based on experiments published by Chesky et al2 and Chesky and Amlani.3 They suggest that real ear attenuation at threshold (REAT) measurements made in accordance with ANSI standard S12.6-19844 are invalid because they are made at threshold, and also that typical manikin measurements are invalid unless musical tokens are used.
The purpose of this paper is to report that their manikin data—using their own recorded musical tokens—show a nearly flat response for the ER-15 within a few dB from 100 Hz to 16 kHz when plotted correctly on a standard logarithmic (musical) frequency scale. In the correct format, their data agree with 25 years of measurements by independent laboratories in the United States and abroad using REAT and manikin measurements.
ER-15 Measurements Re-plotted
Chesky and Amlani3 show a series of careful KEMAR® manikin measurements, using several different musical tokens as the sound source. Eight loudspeakers were located one meter from the manikin, and spaced every 45° around a circle. The attenuation for the ER-15 earplug in a custom earmold made for the KEMAR manikin was obtained by comparing the plugged- and open-ear response on KEMAR.
The published ER-15 graph of Chesky and Amlani3 shown in Figure 1a was recreated after a careful extraction of the data from their Figure 6. (Appendix 1, in the online version of this article, describes the extraction method.) Their graph used a linear frequency scale starting with a frequency of 47.07 Hz. The next frequency on their graph is at 1765.72 Hz, slightly more than five octaves higher, and so on until, at the opposite end of the spectrum, the last two labeled frequencies, 17269.61 and 18992.27 Hz, are about 1.5 musical half tones apart. The strong dip that visually appears to be at the middle of the piano is at 8.5 kHz, an octave above the top of the piano keyboard.
Figure 1b shows the same ER-15 data re-plotted on the logarithmic frequency scale normally used for reporting earplug attenuation data. Chesky and Amlani’s ER-15 data show a nearly flat response within a few dB from 100 HZ to 16 kHz, with the exception of an anomaly (dip) around 8 kHz. Such a dip does not appear in a true diffuse-field measurement, suggesting that each of the eight loudspeakers played identical (in-phase) musical tokens. Chesky and Amlani3 state that:
“…the claims used to market [Musicians Earplugs] to musicians and music schools are misleading and that the discrepancies for claiming attenuation characteristics in response to musical stimuli are related, in part, to the use of the REAT testing procedure.”
The explanation appears instead to be related to the visual appearance of graphs plotted on a linear frequency scale. In fact, their KEMAR measurements generally agree within a few dB of the ER-15 REAT measurements reported 26 years ago by Berger (1989),5 as shown in Figure 4 of this article.
Previous Comparison between KEMAR and REAT Measurements
Figure 2a shows open-ear and plugged-ear data for a nominal ER-15 Musicians Earplug in a correctly-made custom earmold. Figure 2a shows the good match in spectrum shape between open ear and plugged ear obtained with an ER-15 earplug.
Figure 2b shows the attenuation derived from the responses in Figure 2a, as well as the attenuation based on REAT “Real People” measurements reported by Berger5 in 1989 on 16 subjects tested 3 times. Both of the attenuations shown in Figure 2b resulted from diffuse-field measurements; objective in the case of KEMAR data and subjective (threshold-difference) in the case of Berger’s E-A-RCAL data. Both used noise instead of music for the measurements.
The close agreement between the two curves in Figure 2b suggests that either one of those curves could reasonably represent the performance of the earplug under test. The use of pink or third-octave noise is irrelevant: Any sound source that has sufficient bandwidth and enough energy in each measurement band (to stay above system noise) will give identical attenuation results. The first author has performed many fidelity-rating tests6,7 using pink noise, orchestral passages, jazz trio segments, and a string quartet from the Chicago Symphony Orchestra. All of these, including pink noise, gave the same frequency response, as has been well known since the development of Fourier signal analysis back in the 1800s.
Any measurement involving subjects will show variability, of course. Figure 3 shows the typical across-subject differences in REAT attenuation. Two sources of statistical variability influence each subject’s curve in Figure 3 about equally: Across-Subject variance and Test-Retest variance.
In the present case, the KEMAR measurements of Chesky and Amlani agree with both the Etymotic Research KEMAR measurements and the E-A-RCAL real-ear REAT measurements, as shown in Figure 4. The exception is the 8-kHz anomaly discussed previously.
Criticism of the Fidelity of ER-20 Earplugs
ER-20 HiFi earplugs, which are approximately one-tenth the cost of Musicians Earplugs and widely used by high school bands and drumlines, have also come under criticism from Chesky et al,2 who concluded that “This study disputes often cited claims that flat-attenuating earplugs are widely accepted by musicians (Chasin, 20018; Niquette, 20079).”
Yet, in that same Chesky et al study of the more than 300 students given ER-20 earplugs (of the 600 ER-20 earplugs supplied by Etymotic Research at no cost for the experiment), 85% of students report using the earplugs since receiving them, and the use rate was 91% for music majors compared to 78% for non-music majors. The report states that “The music majors also reported being significantly more likely to use the earplugs in the future compared to non-music majors.” Most significantly, “Students reported that…the university should provide earplugs to all music students (93.4%).”
To be fair, brass players reported some difficulty playing with earplugs, perhaps because the average playing time before that survey was taken was only slightly more than 5 hours, insufficient time to adapt to their new listening conditions.
Measurement of ER-20 HiFi Earplugs
ER-20 HiFi earplugs have been measured more often than Musicians Earplugs by independent testing laboratories in the United States and abroad. The two curves labeled REAT in Figure 5 were obtained by two separate laboratories: E-A-RCAL Laboratory (solid black curve) and Michael and Associates Inc (solid blue curve). The Etymotic KEMAR measurements in Figure 5 basically agree with those two REAT data sets.
The Chesky and Amlani3 data do not agree with the other three data sets even though they were obtained on KEMAR. In contrast to the ER-15 Musicians Earplugs, which depend on the earmold laboratory to make an earmold that seals, the ER-20 triple-flange eartip depends on a trained experimenter to obtain a good seal on KEMAR. One problem that is not obvious is the risk of “folding” of the three flanges, which can produce a large leak in the solid-steel “ear canal” on the KEMAR manikin. The attenuation shown in the Chesky and Amlani data is remiscent of that problem. Colleagues at other testing laboratories have reported that extreme care is required to obtain valid KEMAR data that are comparable to the normal real-ear performance of that earplug.
A comparison among the attenuation measurements of ER-15 Musicians Earplugs at several labs shows excellent agreement between objective measurements on the KEMAR® manikin and subjective REAT measurements on human subjects, both of which show a nearly flat attenuation response from 100 Hz to 16 kHz. The discrepancies in Chesky and Amlani’s data3 appear unrelated to REAT measures, but instead to the scale used to plot the data. When re-plotted to standard scales, Chesky and Amlani’s data show a flat-attenuation response, in agreement with all other published data within a few dB from 100 Hz to 16 kHz, except for an anomaly around 8 kHz.
Patty Johnson provided a careful analysis of Chesky et al.
This appendix consists of two supporting graphs and commentary. One graph shows the data extraction method underlying Figure 1 in this article; the other provides information on the electrical analog of Musicians Earplugs as detailed by their inventor, Elmer Carlson.
The data extraction method underlying the graphs in Figure 1 is illustrated in Figure A1. Interpolation of data between the lines was confirmed or corrected as required by overlaying the resulting Excel spreadsheet (linear) graph over the original graph until the two graphs agreed within one dB at all frequencies.
Since the 1940s, Elmer Carlson taught how to use the electrical analog of a microphone, receiver, coupling tube, or earplug.10 Carlson, the inventor of the Musicians Earplug,1 designed it—of course—with the aid of an analog. That analog, reproduced from Killion’s 1992 tribute to Carlson,11 is shown in Figure A2.
A properly constructed analog will agree within 1-2 dB of the actual device in each case. Having analogs for all products helps prevent errors in design, production, and measurement. The analog-derived attenuation of ER-15 and ER-20 earplugs agree with the data in the solid and dotted curves in Figure 5.
Carlson EV. Passive Ear Protector. US Patent #4,807,612.
Chesky K, Pair M, Yoshimura E, Landford S. An evaluation of musician earplugs with college music students. Intl J Audiol. 2009;48:661-670
Chesky K, Amlani AM. An acoustical analysis of the frequency-attenuation response of musician earplugs, Communication Disorders Deaf Students Hearing Aids. 2014;3:127.
American National Standards Institute (ANSI). Method for the Measurement of the Real-Ear Attenuation of Hearing Protectors. ANSI S12.6-1984 (R2008). New York, NY:ANSI;1984.
Berger EH. Real-ear attenuation of musicians earplugs measured on 16 subjects tested three times each. Indianapolis: E-A-RCAL Laboratories;1989.
Killion MC. Design and Evaluation of High-fidelity Hearing Aids [dissertation]. Northwestern University, University Microfilms;1979.
Killion MC. Myths that discourage improvements in hearing aid design. Hearing Review. 2004;11(1):32-40,70. Available at: https://hearingreview.com/2004/01/myths-that-discourage-improvements-in-hearing-aid-design
Chasin M. Hearing Loss in Musicians: Prevention and Management. San Diego: Plural Publishing;2009.
Johnson PA. The high notes of musicians earplugs. Hearing Review. 2014;21(8):22-24. Available at: https://hearingreview.com/2014/07/high-notes-musicians-earplugs
Zuercher JC, Carlson EV, Killion MC. Small acoustic tubes: New approximations including isothermal and viscous effects. J Acoust Soc Am. 1988;83:1653-1660.
Killion MC. Elmer Carlson: A Lifetime of Achievement. Bulletin of the Am Auditory Soc. 1992;17:(1):10-13,20-21.
Berger EH. Using KEMAR to measure hearing protector attenuation: When it works, and when it doesn’t. In: Daigle, GA, Stinson MR, eds. Proceedings of Inter-Noise 92. Poughkeepsie, NY: Noise Control Foundation;1992:273-278.
Berger EH. Preferred Methods for Measuring Hearing Protector Attenuation. Presented at; RIO2005 Inter-noise Congress and Exposition, Rio de Janeiro, Brazil;2005.
Killion MC. Factors influencing use of hearing protection by trumpet players. Trends in Amplification. 2012;16(3):173-178.
Mead C. Killion, PhD, is Chief Technology Officer and Founder of Etymotic Research, Inc, Elk Grove Village, Ill, and Adjunct Professor of Audiology at Northwestern University.
Andy Haapapuro is a senior engineer at Etymotic Research, and has primary responsibility for high-fidelity passive earplug developments.
Original citation for this article: Killion MC, Haapapuro AJ. High-Fidelity Earplug Attenuation Measurements Agree After All. Hearing Review. 2015;22(11):28.?