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In case you need any kind of assistant then You can use the Comment form for asking any kind of Question.
NIOSH has released a free smartphone sound measurement app for iOS devices. For more info and to download the app, see the. Please share your comments on the related. The SoundMeter app on the iPhone 5 (L) and iPhone 4S (R) compared to ½” Larson-Davis 2559 random incidence type 1 microphone (C). As of June 2013, 60% of all mobile subscribers use smartphones—that’s more than 140 million devices. Apple iOS and Google Android platforms account for 93% of those devices Nielsen, 2013. Smartphone developers now offer many sound measurement applications (apps) using the devices’ built-in microphone (or through an external microphone for more sophisticated applications).
The use of smartphone sound measurement apps can have a tremendous and far-reaching impact in the areas of noise research and noise control in the workplace as every smartphone can be potentially turned into a dosimeter or a sound level meter Maisonneuve et al., 2010; Williams and Sukara, 2013. However, in order for smartphone apps to gain acceptance in the occupational environment, the apps must meet certain minimal criteria for functionality, accuracy, and relevancy to the users in general and the worker in particular. Video: CAPT Kardous testing mobile sound-meter apps in the lab NIOSH noise researchers received numerous requests from stakeholders, safety professionals, and the public to address the accuracy of the many sound measurement applications available for smartphones and whether they can be relied upon to provide an accurate assessment of the ambient environment. As a result, we conducted a pilot study to select and characterize the functionality and accuracy of these apps as an initial step in a broader effort to determine whether these apps can be relied on to conduct participatory noise monitoring studies in the workplace Kardous and Shaw, 2014. The resulting paper, was published in the Journal of the Acoustical Society of America. We selected and acquired a representative sample of the popular smartphones and tablets on the market as of June 2013.
Smartphone apps were selected based on their ability to measure occupationally relevant sound level values. A total of 130 iOS apps were examined and downloaded from the iTunes store., of those, 10 apps met our selection criteria.
A total of 62 Android apps were examined and downloaded, however, only 4 apps partially met our criteria and were selected for additional testing. As a result, a comprehensive experimental design and analysis similar to the iOS devices and apps study above was not possible.
The measurements were conducted in a diffuse sound field at a reverberant noise chamber at the NIOSH acoustics testing laboratory. For our experimental setup, we generated pink noise with a 20Hz ‒ 20kHz frequency range, at levels from 65 dB to 95 dB in 5-dB increments (7 different noise levels. Reference sound level measurements were obtained using a ½-inch Larson-Davis (DePew, NY) model 2559 random incidence microphone. Additionally, a Larson-Davis Model 831 type 1 sound level meter was used to verify sound pressure levels. Smartphones were set up on a stand in the middle of the chamber at a height of 4 feet and approximately 6 inches from the reference microphone as shown in Figure 1.
Figure 2: Differences in A-weighted and Unweighted sound levels between reference system and app measurements by app. Overall, the results in Figure 2 show that for A-weighted sound level measurements three apps had mean differences within ± 2dBA of the reference measurements. For un-weighted sound level measurements three apps had mean differences within the ± 2 dB of the reference measurement. Since national standards and occupational guidelines specify that type 2 sound measurement instruments have an accuracy of ± 2dBA, some of the above-mentioned apps could potentially be used in the occupational setting, especially if they’re used in conjunction with a type 2 external microphone such as the MicW i436. Android-based apps lacked the features and functionalities found in iOS apps.
This is likely due to the iOS advanced audio capabilities compared to other platforms, the open ecosystem of the Android platform, and having so many different Android device manufacturers using different suppliers and components. Challenges remain with using smartphones to collect and document noise exposure data. Some of the main issues encountered in recent studies relate to privacy and collection of personal data, sustained motivation to participate in such studies, bad or corrupted data, and mechanisms for storing and accessing such data. Most of these issues are being carefully studied and addressed Drosatos et al., 2012; Huang et al. In conclusion, smartphone sound apps can serve to empower workers and help them make educated decisions about their work environments. They may be useful for industrial hygienists and OS&H managers to make quick spot measurements to determine if noise levels exist in a workplace that can harm workers’ hearing. The ubiquity of smartphones and the availability of these sound measurement apps may also present new research opportunities for occupational hearing scientists and researchers.
November 2016 Update:NIOSH researchers have just published a follow-up study: to examine the performance of sound measurement apps using external microphones. The study showed sound level measurements to be within ±1 dB of the reference system using the same test setup and apps from the initial study. This follow-up study suggests that using external, calibrated, microphones greatly improves the overall accuracy and precision of smartphone sound measurements, and removes much of the variability and limitations associated with the built-in smartphone microphones. June 2018 Update: EA LAB and NIOSH researchers have evaluated the app’s performance as part of a system (iPhone + external microphone) for compliance with type 2 requirements of IEC 61672/ANSI S1.4 standard: Sound Level Meters – Part 3: Periodic Tests.
The results were published in the Applied Acoustics Journal Celestina et al. Celestina, M., Hrovat, J., & Kardous, C.
Smartphone-based sound level measurement apps: Evaluation of compliance with international sound level meter standards. Applied Acoustics, 139, 119-128. Kardous, MS, PE and Peter B. CAPT Kardous is a research engineer in the NIOSH Division of Applied Research and Technology. Shaw is a statistician in the NIOSH Division of Applied Research and Technology.References to products, services, or apps do not constitute an endorsement by NIOSH or the U.S. References Drosatos, G., Efraimidis, P. S., Athanasiadis, I. N., D’Hondt, E., & Stevens, M.
A privacy-preserving cloud computing system for creating participatory noise maps. In Computer Software and Applications Conference (COMPSAC), 2012 IEEE 36th Annual (pp.
L., Kanhere, S. Are you contributing trustworthy data?
The case for a reputation system in participatory sensing. In Proceedings of the 13th ACM international conference on Modeling, analysis, and simulation of wireless and mobile systems (pp. A., & Shaw, P. Evaluation of smartphone sound measurement applications. The Journal of the Acoustical Society of America, 135(4), EL186-EL192; Kardous, C. A., & Shaw, P. Evaluation of smartphone sound measurement applications using external microphones – A follow-up study.
140, EL327 (2016); Maisonneuve N., Matthias N. Participatory noise pollution monitoring using mobile phones. Information Polity, 51-71. Nielsen 2013.
Mobile Majority: U.S. Smartphone ownership tops 60%. Retrieved June 23, 2013, from Williams W.
And Sukara Z. Simplified noise labelling for plant or equipment used in workplaces. Journal of Health and Safety, Research and Practice, Vol.
5 (2), 18-22. Posted on April 9, 2014 by Chucri A. Kardous, MS, PE and Peter B. NIOSH does not recommend nor endorse a particular commercial product. The data from our study “Evaluation of smartphone sound measurement applications” is available in the journal article referenced at. The discussion section (page 189) highlights two apps — SoundMeter and SPLnFFT — that had the best accuracy over our testing range. There were two other apps — Noise Hunter and NoiSee — that were within ± 2dB of the reference sound source.
Once again, note that the data results in the study do not constitute as NIOSH endorsement of any of these products. The question of any technology designed to collect data is to ask “now what” or “what do we do with this data?” If these apps, whether for noise or other occupational exposure purposes, will continue to pervade our society, a guidance document to inform public and workers on what to do with the data is appropriate. For compliance purposes, this bears serious examination since compliance may entail expensive fines or other regulatory actions. For general information to prompt workers and the public to employ safe practices and/or hearing protection until detailed analysis with actual noise survey equipment is prudent. NIOSH should seriously consider producing this guidance. Thank you for your comment.
You are correct that compliance officer measurements will still need to be made with calibrated survey meters, not smartphone apps. Additionally, if an employer is considering large investments in noise control equipment they may wish to employ professionals who have more complex analytical instruments to assure the control designs are efficient and effective.
Nevertheless, smartphone apps can serve a useful function as range-finding devices and may help workers make educated decisions such as knowing when to seek help or use hearing protection; and they may be useful for industrial hygienists and OS&H managers to make quick spot measurements when a professional survey meter is not available. Many years ago NIOSH did publish an “Occupational Exposure Sampling Strategy Manual” which is still available on the Internet at:. It describes the use of range-finding instruments and also strategies for monitoring compliance and enforcement. While the 1977 manual didn’t envision using smartphones, the strategies in that old document still apply for sampling and may guide the use of survey data. NIOSH is in the process of updating the Occupational Sampling Strategies Manual. We will consider your suggestion for updating our guidance on data analysis.
NIOSH is also in the process of standing up a virtual center that will focus on guidance documents with respect to direct reading monitors and sensor technology. Thanks for your interesting article. In July 2013 I have tested several free apps myself mainly to see how my app SafeNoise was doing compared to other free apps. You can find an article about my test on (only in Dutch).
In my test I have used 5 samples: – pink noise with a sound level of 80 and 100 dB(A) – pure tones of 80 Hz (81 dB(A) and 4 kHz (93 dB(A) – rockmusic 93 dB(A) The setup was straight forward using a stage floor monitor (35 Hz to 16 kHz), a PA amplifier and a laptop with the sound samples. The smartphone and the reference microphone were located close to each other about 1.5 mtr distance from the speaker and pointed directly to the speaker.
Due to the short distance between speaker and microphones, there was no influence of the room acoustics (about 65 m3, RTs between 0,5 and 0,2). I also checked the influence of the position of the smartphone and the reference microphone (figures 3 and 4 in my article). The iOs apps turned out to be better than the Windows or Android apps. Some iOs apps performed within 2 dB(A) of the reference soundlevel meter (MusicSafeCheck and SafeNoise).
Did you test those apps as well? If so, how did they do? I was surprised to find that the microphones used in the Apple phones have a fairly flat frequency response, as I thought that all cell phone mics were intended to capture speech and therefore had poor responses at both the low and high end of the frequency spectrum. That means that mics used in Android devices, even when the apps have been properly calibrated, can give a fairly accurate sound level for sounds in the speech frequency range (500 Hz to 2000 Hz range), but can give very inaccurate results when recording other sounds with low and high frequency content, such as from music and diesel engines.
The microphones themselves exhibit a good flat frequency response up to around 10-12 kHz depending on the type of MEMS microphone used in each device, the smartphone manufacturers introduce speech and noise cancelling filters into the system for normal communication needs. However, starting with iOS 6, Apple allowed developers to bypass such filters. Android developers must still work around such filters during the development of their apps. As far as microphones used in Android devices, they’re usually similar to those found in Apple devices, almost all smartphone manufacturers rely on few suppliers of MEMS microphones. The difference in performance and accuracy across devices and platforms are not necessarily related to the microphones but rather the set of software and drivers that handle and process the audio signal. Apple offers its developers access to their digital audio infrastructure, called Core Audio, which is tightly integrated with the iOS.
No such infrastructure exists for other platforms such as Android and Windows as they continue to rely on third-party drivers and that can introduce latency and affect the performance of the apps. Thanks for this investigation. Steady broadband noise test signal: the test should be extended with offering bursts (in free field!) and signals with high (but realistic) crest factors. The test should also be extend with performance at different temperatures for example. Some other factor maybe added, for example if it has a fair high frequency response (think about compressed air noise). Then, if you clearly inform the user about all limitations, selected apps could be very well useful. Of course no one should expect the “full performace” of such apps.
But it will be used by a large audience with little knowledge about the subject; then its important that they know were it goes wrong. OK, So I’m far from an intellectual and honestly just barley graduated High School. Most of what’s said here is Greek To Me. I work in a night club doing as best as I can for My Family with what I have. I’ve noticed several of the older people there who have admitted to being in clubs for a long time have difficulties in hearing.
What I’m trying to do is find a device / app that I can turn or / activate that can give me a”DECENT” reading and tell me if I could be wearing hearing protection or not? I understand that some people or business’s are not allowed to say choose this one over this one, but as a person who DOES NOT want to lose his hearing and can not quit right now, could someone PLEASE put in PLAIN ENGLISH the good, the bad or the indifferent. I have an older iphone 4 and really want to know. We appreciate your comment and sincere request. Please note that NIOSH does not recommend nor endorse a particular commercial product and also note that this was a pilot study so there may be other apps out there that may be as accurate as the ones we tested. The results of our study showed that the SPLnFFT app from Fabien Lefebvre and SoundMeter app from Faber Acoustical had the best accuracy, followed by Noise Hunter and NoiSee.
All of these apps are available through the iTunes app store. Take a look at the description and screen layout of each and choose an app that you feel most comfortable using. Any of these apps should be adequate to do the job (The apps pricing range from $0.99 for NoiSee to $19.99/$99.99 for SoundMeter). The most important thing is to get 3-5 readouts over different periods of times so you can get a better understanding of the noise environment at your club and find out what the overall average noise levels.
To make sense of the noise level readouts you get from a particular app, note that the NIOSH recommended exposure over an 8-hour workday is 85 decibels, A-weighted (dBA), and for every 3-dB increase in that level, you cut exposure time in half, so if your reading is 88 dBA, you should only be exposed to that level of noise for up to 4 hours (per day), at 91 dBA, exposure time is cut to 2 hours, and so on. See Table 1-1 in this document and try to match the noise level readout to the recommended exposure duration. Remember, these apps are only meant to give you a rough idea about your environment, they do not replace the need for a professional noise assessment. But if your readouts exceed our recommended limit of 85 dBA on a consistent basis, then it might be worthwhile to share that information with the club management and see if they can address it. There are a variety of solutions available to an employer, from reducing and controlling the noise levels, to administrative controls such as limiting time spent in the area with the excessive noise and taking breaks, or if those are not possible, offering hearing protection. There are many different kinds of hearing protectors available these days, such as the “musicians’ earplugs” that attenuate noise uniformly across all frequencies without distorting speech and music.
Based on your description of your job, the musicians’ type of protectors would seem to be ideal for your situation. Good questions, Pierre.
We do discuss the variability in our journal article and also in our more detailed report here:. Please note that such variability is expected since we were testing the same apps with several different iOS devices (iPhone 3GS, iPhone 4S, iPhone 5, and iPads). We would likely see similar variability if we would test several dosimeters, for instance, from several manufacturers over that same test range. And that’s why we decided to use the means of the differences between each of the apps (and each of the devices we tested) against the reference sound levels as a measure of accuracy. As for your second question, each app behaved a little differently, but we saw a little more variability at the low test level of 65 dB compared to the higher test levels of 90-95dB.
We chose 95 dB as the upper limit for our study because of our interest in typical occupational exposures. Our system is capable of generating 110-115 dB but we haven’t tried to push its limits.
We are currently exploring the accuracy of apps with external mics, we have used them with acoustic calibrators generating 114 dB at 1000 Hz and 124 dB at 250 Hz and the main apps from our previous study all performed well were able to measure those levels without any issues. We will be posting updates on our twitter account @NIOSHNoise soon. As a person with hearing loss, I agree with Dr. Grossan that everyone should have a way to know when the noise level around them is dangerous. We live in a very noisy world. I think there are OSHA regulations for noise in the workplace, but it is a shame that individuals have to have personal DB meters to know if the noise level around them is safe. Smoking has been banned in most public places because second hand smoke is dangerous.
Why do we allow noise levels in restaurants, bars, theaters, airplanes, and other public places that can damage hearing? I found this web site, because after being at a party last night and a restaurant this morning that were both painfully noisy, I decided that I did need a personal DB meter so I don’t lose what little hearing I have left. I also want one so I can walk up to a movie theater manager and say “Here is the DB level in your I-Max. It’s too loud. Turn down the volume or give me my money back.”. Thank you for your comment, Birger. We did not calibrate the apps as we could not establish a viable and repeatable protocol for accurately calibrating the internal mics.
You simply cannot place a calibrator on the opening of the internal mic, and that’s the reason we decided to expand our study to examine the accuracy of sound measurement apps using external mics which allowed us to use acoustic calibrators as they’re intended to be used. See photos here:. We will be publishing results soon, stay tuned. While the paper was very interesting, it does not do enough to caution the potential user that the resulting measurements do not come near to meeting International IEC or even local US ANSI measurement standards, nor to accurately measuring many “real world” noises sources, however close to the “truth” it seems on simple sinusoidal noise sources. Even the most reputable manufacturers of professional meters, such as B &K, Cirrus Research, Rion, Pulsar or 3M-Quest have not found it easy to have their sound level meters accepted and approved by a standards body such as the PTB in Germany; in other words to meet the legally required measurement standards of accuracy is hard to do – indeed, some mid-range sound level meter manufacturers have never managed to get their meters approved.
Low frequency has been mentioned as a problem as has calibration and non steady noises sources. If calibration is out and a meter app reads just 3dB too low, the exposure to noise damage risk will potentially be DOUBLED. Similarly if the noise is impulsive with a high LZpeak content, the app may well read 6dB low, so the worker is potentially exposed to FOUR times the safe level. Now add in the potential error for the microphone’s imperfect omnidirectional response as well as temperature, humidity and vibration issues, using the app would seem more like a “goodish guess”. It seems to follow that these apps should NEVER be used as hearing damage risk tools, but just as a very crude indicator, for which task they seem adequate. Thank you Dudley, you bring up some great points in your comment. One of the main reason we embarked on such a study, we had stakeholders and industrial hygienists ask us whether such apps can be used to make assessment of noise exposures in the workplace.
We continue to investigate the viability of using such apps when adding a type 2 external microphones, that are supposed to have flat frequency responses from 20 Hz – 20 kHz. Our preliminary results showed even greater accuracy of such apps when used with external mics.
Impulse noise assessment is a tricky issue by itself because even type 1 sound level meters are often not capable of measuring impulses that exceed the dynamic range of the meter. NIOSH has published extensively on the issues with impulse noise measurements. For example, see. Clearly, whatever the range of an instrument there will ALWAYS be some peak that may exceed the meter’s linear range – that is why these matters are specified in IEC 61672 so it is not relevant is it?
As a matter of fact, most B & K and Cirrus microphones – two types fitted to many commercial units – have a linear range from about 16dB(A) up to 153 dB. One important point is that IEC 61672 mandates a Class 2 microphone ONLY up to 8kHz (see IEC 61672 table 2). Even a Class 1 is only fully specified up to 16kHz. At 20kHz the tolerances are +6dB and – infinity (+4dB and -infinity for Class 1). I am aware that ANSI standards have different limits, even though very few commercial units in truth meet the ANSI requirements. In Europe, meters have to be fully tested, but in the USA as far as I am aware, such specification claims do not have to be substantiated by pattern approval and so may not be trustworthy. The only apps we have tested did not even meet the rms test and in truth are little better than $30 ‘toys’ – wonderful for setting up hi-fi and great for giving a scale order of the noise levels, but absolutely not suitable for noise measurement.
I feel you would be doing people at hearing damage risk a great dis-service by supporting the use of phone apps. Lots of deserved “attaboy” comments obscure a few especially useful comments and responses. Perhaps the authors could add an addendum that references a few of these or even extends the blog post.
For example, I could not expand the images enough to read many of the app names so the additional information buried in responses that identified the four best performing apps was very useful. (Some recommended apps were quite inexpensive at $1, $4, or $6). I also found links such as these quite useful: (where I can read the box graph but was overwhelmed by the detail spread across 37 pages) (shorter published version) —– (April 22, 2013 – “30 iPad Sound Measurement Apps Reviewed” – be sure to read the updates like the note on higher db levels) (May 19k 2014) In conclusion, “attaboy” and a positive “my tax dollars at work”! Android and Apple smartphones have won a kind of sweepstakes leaving other platforms such as Windows Mobile and Palm OS in the dust. Functional used smartphones based on the less favored platforms are cheap enough — often under $10 U.S.
— to beg the question whether lemonade can be made from these lemons? What about longer term noise measurement? As good as iOS and Android noise measurement apps have become, you still wouldn’t want to deploy such a device in a public or semi-public place unattended. It very likely would get stolen. If long-term (24 hours to one week) noise monitoring could be done with less desirable and cheaply replaceable devices the picture changes. Can an appropriate hardware/operating system platform — cheap, favorable tradeoff of processing capability and battery life, ability to bypass or compensate for speech-oriented frequency shaping, a mic that can handle 100+ dB, accommodating flash memory cards — be identified and then software development be supported?
This probably could be launched for something like $10,000 and seems enormously cost-beneficial in terms of making longer-term noise monitoring much more widely doable. The software/hardware only needs to capture.WAV files, for post-processing into a number of noise statistics over time, and for extracting clips of incidents of interest. 22,000 16-bit samples per second scales up to just under 28GB per week, comfortably within limits of removable flash memory cards that most smartphones can use.
For shorter time periods, higher sampling rates are perfectly feasible, if only to validate the expectation that noise at the highest audible frequencies is seldom very high energy. Thank you David, you raise some very interesting and exciting ideas. I believe some citizen science projects have done just that (albeit on a small scale) – used cheaper smartphones and developed a basic sound measurement app, specific for those devices. Some other projects have developed their own cheaper “noise measurement” boxes for environmental noise monitoring. But I agree, there’s great potential to acquire a large number of these “cheaper” devices and pass them along to university students or citizen scientists to conduct a large surveillance effort.
The idea of smartphone sound measurement apps is more about personal awareness and empowerment since most people carry one everywhere they go. As for NIOSH, our mission is focused on occupational noise exposure and we hope that this effort would serve to empower workers to use their smartphones to become better aware of their noise environment and take actions to reduce their personal exposure to noise. There are a number of design choices that can help or hinder repurposing. For example: – Equalization may de-emphasize frequencies outside normal voice range. For noise measurement purposes it should be possible to turn this off.
– Gain should be adjustable so a phone’s dynamic range can shifted to suit an expected range of environmental noise levels, however AGC needs to be turned off so relationships between noise dB and digitized quantities are known. – Being able to save uncompressed.WAV files, 16 or 24 bits per sample, sample rates variable up to 22,050 or 44,100 per second. Compressed representations such as ADPCM or MP3 throw away too much information. – Operating systems should not block repurposing. – Batteries and flash storage media should be easily replaceable and upgradeable in capacity. – USB ports should be reprogrammable into host mode. – There may be further requirements to support repurposing beyond noise measurement, e.g.
Measuring vibration, radiation, light intensity, temperature, pollution. Why not make these accomodations mandatory through the FCC, just as radiation, interference, telemarketing and privacy are already regulated? Making phones more friendly to repurposing can promote a number of societal benefits. Great and useful information. As a science teacher I was surfing the net for apps to use in the classroom and share amongst the pupils. Both iOS and Android (I use Android myself). As a Dane, I found and shared the Swedish “Buller” app.
– published by the occupational health ministry I think -, but was curious as to how well it performed. You haven’t tested it apparently, but your survey is gold anyway! Now I know that relatively low but constant levels of both infra- and ultra-sounds – mostly from machinery – can permanently damage hearing, but are there any apps available that can measure infra- and ultra-sound levels at all? We actually tested the Buller app from the Swedish Work Environment Authority and though it was well-designed and easy to operate, it did not meet our accuracy criterion. See page 30 of our more detailed report:.
As for ultra sounds and infra sounds, the issue is not the apps but the built-in microphones used on most smartphones which have a limited frequency response and introduce distortions at very low and high frequencies. There are external microphones that can be used with smartphones but even those have are limited especially below 20 Hz. For such measurements, you will need a high-end sound level meter and a special attention needs to be made for the selection of the appropriate microphone. Enevoldsen – Electret microphones have good response down into the infrasound range and iOS 7 or higher can turn off the equalization that favors voice frequencies for phone purposes, so it’s likely an app could be written if one doesn’t already exist. Whether this is also feasible for Androids is harder to judge. Apparently there is a lot of variation in the hardware, brand to brand and perhaps model to model. Ultrasound measurement would normally be limited by maximum sample rates, 44,100 or 48,000 Hz.
Even at 48,000 there would need to be a steep filter blocking frequencies above 21 or 22 kHz to avoid aliasing. Nevertheless, if noise is random you could look at the highest frequencies that can be measured. If there is a substantial amount of energy there, chances are very good that there is also sound energy at higher frequencies out the device’s range. As a DIY experiment, perhaps you could build an oscillator with selectable output about 10 kHz apart, through the entire band of interest. If you got a microphone capable of responding in that range, you could amplify that signal with a filter to cut out the audio band, then mix it with oscillator output. Input that into a MIC jack and run an app with spectrum analysis (e.g.
Then there should be peaks at difference frequencies. For example if there is ultrasound at 31 kHz and you mixed it with 30 kHz, you should see a spike at 1 kHz. Perhaps you could build an ultrasound mic and the mixer circuitry into an Altoids tin. That’s better than I would have thought, and in some cases on par with very low cost (sub-$50) dedicated SPL meters. I have a side business that does audiovisual services, and I’ve been meaning to get the other folks in the crew to test their phone with one of these apps against my SPL meter (which is a $80 unit that I believe is pretty accurate in most circumstances), so they’d have a ballpark idea of how loud they’re running the gear (there are noise ordinances that we sometimes have to take responsibility for following). I’d be curious how well a phone could act as an RTA, as well.
I used to use my Amiga to do analysis (non-realtime, but reasonably useful in a time when having a high resolution spectrum analyzer was amazing), and standard PCs have been able to act as RTAs for at least 15 years, so I’m absolutely certain the processing power needed is there in modern phones and tablets, but the mic and audio interface would be a limiting factor. This is an excellent idea, Eva – to allow other crew members to use your SPL meter to calibrate their apps (since calibration is one of the most important things to achieve better accuracy). As for RTA, you’re correct, the processing power in these devices allow for some very complex analysis. Two of the apps we tested above offer RTA as “in-app” purchases or as part of larger suite of apps.
For such analysis, the use of a “professional grade” external microphone (that can be calibrated using acoustical calibrators) would be crucial to obtain quality results. Thank you for your interesting question, Richard. I have not thought of such an application, though I do not think these apps and smartphones are suitable for these types of measurements.
There are specific standards to measure the hearing protection attenuation (Such as ANSI S12.6). At NIOSH, we typically use an artificial head fixture such as GRAS 45CB when we need to evaluate the attenuation of hearing protector devices. You may find this article helpful:. If you have a specific earmuff in mind, I would recommend that you consult our hearing protector compendium at and use the methods outlined to obtain the true attenuation of protectors. However, you may be able to get a very rough approximation of the noise reduction of an earmuff by using a MicW or some other mic (see the Etyomtic Research in-ear mics) with an extension cable running under the foam cup of the earmuff. I would recommend using two calibrated mics and devices unless you can generate the exact ambient sound field when you conduct your measurement under the earmuff. You will also need to secure the mic at the entrance of the ear canal with some form of tape without compromising the seal of the hearing protector too much.
I would be interested, as I’m sure some of our readers, to find out more about the specifics of your measurements and your eventual findings. Indeed, even the most respectable producers of expert meters, for example, B &K, Cirrus Research, Rion, Pulsar or 3M-Quest have not thought that it was anything but difficult to have their sound level meters acknowledged and endorsed by a benchmarks body, for example, the PTB in Germany; at the end of the day to meet the lawfully required estimation principles of exactness is difficult to do – in fact, some mid-reach sound level meter makers have never figured out how to get their meters affirmed. Low recurrence has been specified as an issue as has adjustment and non consistent clamors sources. On the off chance that alignment is out and a meter application peruses only 3dB too low, the presentation to clamor harm danger will conceivably be DOUBLED. Essentially if the commotion is indiscreet with a high LZpeak content, the application may well read 6dB low, so the specialist is conceivably presented to FOUR times the sheltered level. Presently include the potential mistake for the amplifier’s defective omnidirectional reaction and also temperature, stickiness and vibration issues, utilizing the application would appear to be more like a “goodish theory”.
Follow can’t help thinking that these applications ought to NEVER be utilized as listening to harm danger instruments, yet pretty much as an exceptionally unrefined marker, for which assignment they appear to be sufficient. The product/equipment just needs to catch.WAV documents, for post-handling into various commotion insights after some time, and for extricating clasps of episodes of hobby. 22,000 16-bit tests every second scales up to just shy of 28GB every week, serenely inside of cutoff points of removable glimmer memory cards that most cell phones can utilize.
For shorter time periods, higher inspecting rates are flawlessly plausible, if just to accept the desire that clamor at the most noteworthy capable of being heard frequencies is rarely high vitality. Of all the apps that we tested, 4 apps met our test criteria, and of those, NoiSee from EA LAB provides a Dose calculation as an included feature of their app. SoundMeter from Faber Acoustical provides an upgrade option for Dose (called%Dose). There may have been other apps that have been introduced recently that offer such features though. We do agree that there’s a slew of apps that provide sound level measurements but no averaging or integrating noise exposure features such as TWA or Dose. This is one of several reasons that NIOSH decided to release its own app, developed in collaboration with EA LAB, and it will include all of the typical dosimetry measures such as LeqA, TWA, and Dose, etc.
Look for its release soon. No, we are not “afraid of the implication on a vendor using your work as a “NIOSH APPROVED” SLM, because we are flawed.” We do not want any vendor implying endorsement by the U.S. Government (i.e., NIOSH, CDC, or HHS) because that would be a potential violation of the Lanham Act, 15 U.S.C. § 1125, or Section 5 of the Federal Trade Commission Act, 15 U.S.C.
§ 45(a), as well as other federal laws. Our research revealed that certain apps performed better than others on specific measures. Identifying this does not imply an endorsement of one product over another. This may be a good time to reiterate what we noted in the blog and in our published paper: “References to products, services, or apps do not constitute an endorsement by NIOSH or the U.S. Hello Felipe, there have been very few newer sound meter apps on Android but we have not evaluated them. As mentioned in our article, we continue to see the same issues with the Android-based apps – fragmented marketplace for hardware devices, lack of uniformity in audio integration between the different manufacturers, and most importantly, lack of support from the developers community.
For purposes such as teaching a course, I would focus on precision of measurements instead of accuracy. One of the major issues with Android devices is that a very small percentage run the latest version of the OS. I suggest you have the students download a certain app (see table 9 in our expanded report ), ensure that they all have the same version (latest) of the Android OS, and see if you can use a single sound source to calibrate those phones, collectively, to a known sound level. You bring up a good point regarding access, so I invite our readers to contribute to this conversation if they know of specific newer Android apps or ideas that could advance noise measurements on Android devices. Thank you for the feedback. My experiment found its origin when I began to notice that when I would turn my car on the radio would be blasting. The road noise was so loud that I didn’t realize how loud the stereo was playing from the day’s commute.
I began to wonder what the long term effects of all this road noise would be on my hearing. I downloaded Decibel 10th Professional Noise Meter, free from the app store. I drove down the interstate at 70 MPH and had my wife sit in the passenger seat and operate the app.
I have a 2014 Suburu Impreza hatchback and it measured 83 decibels. My first vehicle to test drive was a Hyundai Sonata. Quite a step up from the Impreza in terms of price, but I thought it would be worth it for a much quieter ride. Unfortunately the Sonata came in between 75 and 80 decibels which was quite surprising. The final car that I tested was a Nissan Rouge measuring 60 decibels. It was noticeably a quieter cab, but the app provided that reassurance. This is absolutely disgraceful.
Reading through the comments it is clear that you are misleading people into thinking that +/-2dB of a reference signal is what matters. Surely you demand a sound level meter that meets the ANSI or other national standards. Meeting a reference level to +/-2dB is the most basic part of those standards and so easy to meet. Did you test frequency response, linearity, any of the other very many parts of the standard that ensure a sound level meter is reading accurately?
Sound level meters are very difficult to design and build because of the need for extreme accuracy when measuring such small changes in pressure. Inaccuracies away from that reference signal could easily make a difference of 3dB or more, which, as NIOSH surely agrees, makes a difference that halves the safe exposure time. That’s a huge difference and really we all know that the error when measuring with a phone is going to be much greater than 3dB just because of the location of the microphone. Why do none of the sound level meter manufacturers not offer such an application? You can be sure they have tried, I know this because as a software developer I have been involved in such attempts. The reason is simple.
Nobody has so far got close to meeting the standards. Yes, with a good quality external microphone you can get close, but still not there. And of course the cost is high. I really can’t believe you have published this “research” under the NIOSH name, leaving readers thinking that a current smartphone can possibly make these measurements accurately. Thank you for your comment, Michael.
We put the apps through a battery of tests in our laboratory (and currently conducting studies in the field) to verify their performance and accuracy, please see our open-access publications in the reference section to learn more about our studies. In our recent publication using external, calibrated, microphones we note that professional sound level meters must comply with a host of acoustical and electrical tests to meet national and international standards and that no smartphone or smartphone-based app has met the requirement of IEC or ANSI standards.
We also state very clearly that such apps are not meant to replace professional sound level meters. We do take our research very seriously and stand firmly behind our science. Hello Chuck, thank you for your reply. Some of my words were not well chosen as I agree that this research is very valuable and needed to be done by an independent body. My greatest concern is that the research shows that a smartphone doesn’t come close to being adequate, but that people are reading the research, seeing +/-2dB and thinking they are fine, when they are far from it. I know from work I have done that even with an external microphone (other than some USB mics) it is also not possible to meet the standards. You just cannot technically get the dynamic range required by the standards due to the limitations of the A/D converters in the phone.
You can get something that measures accurately within a limited span, but that still does not meet the standards. There are other limitations too, but this is a big one with no solution. The standards are there for a very good reason. People are reading this research and taking from it that the smartphone apps are up to the job, when in reality they are a long way from it. Much further away than 2dB!
Thanks again. Research is good and essential, not letting people develop the wrong conclusion is too. I’m mainly interested in measuring peak, very fast events (like industrial power hammers, fire arms). Do you find that there is a meter app better suited for unweighted, impulse noises like that? Also, have you continued to test new apps as they are released – anything new that meets or exceeds the Faber or SPLnFFT for that sort of measuring? Generally, the rise time of the system is the problem – I need to figure out how to get a 20 microsecond or less mic and system to truly capture impulse noise like that.
I don’t think apps are generally suited for making impulse noise measurements. Even some professional instruments are not often suited for making such measurements, see our study on limitations of dosimeters. However, you can try one of the apps mentioned, or our own newly release NIOSH SLM app with an external, calibrated, microphone such as the MicW i436 or equivalent. We did a follow-up study using external microphones that we refer to in the “update” section of this blog.
We were able to capture peaks, fairly accurately, up to 120-125 dB SPL. Lastly, we have not done any additional studies on new apps, nor do we have any immediate plans to do so. Hi Julian and thanks for reaching out. I’m familiar with your app, and it’s wonderful to see some Android developers such as yourself put greater efforts in including appropriate metrics and advanced features into their applications. This was not the case few years ago when we did our first study. Please feel free to share your experience and help us close the gap between iOS and Android sound measurement apps.
As you mentioned, one of the main issues we ran into when we did our initial study was the inconsistencies of getting accurate measurements, even from the same app, across multiple Android devices. Another issue was the variety of audio tools, chips, and microphones used by the different manufacturers, it would be great to understand if Samsung for example uses the same audio architecture across all its devices? Also, how were you able to tackle the challenge of various Android OS’s out there, i.e. 86% of iOS devices run the most recent version of iOS compared to only 11% of Android devices running the most recent version of Android OS?
As Android worldwide market share continues to rise, it will be great if we can work with the Android developer community to develop some standardized methods for testing and evaluation. Great question. We recommend using acoustical calibrators to calibrate external microphones similar to how an industrial hygienist or an occupational safety and health specialist calibrates their sound measurement instruments before they get started.
Very few manufacturers provide sensitivity information for external microphones, and even when sensitivity is provided, we found that those values do not always match the real sensitivity when we conducted our measurements in our laboratory. Sensitivity of external microphones can also change over time and with environmental conditions and that is why we do not recommend relying on entering a single “sensitivity” value and rather on conducting a true calibration with an acoustical calibrator. What is the noise level and noise dose for jachammers? I have been exposed to 4 jackhammers continuous for hours on end at my work inside a interior metal roofed building. The risk manager says it is okay with earplugs that were given in a plastic cup with no instructions or rating.
I was stationed within 15 feet of these jackhammers many nights in a row and there was a thin wallboard to keep the dust out. It was only 15 feet up and the ceiling was over 30 feet high. The noise reverberated downward. It is a casino. I have bad tinnitus from this and am seeking relief through workers comp. I asked to leave the area and go to another part of the casino.
I was not allowed to. I had to leave on FMLA after filing for comp, which was denied. I have seen several ENT’s and they recommend expensive treatment. I contacted OSHA and the risk manager said to that agency that everything was okay.
Hello Stu, we have done some research on 4 different types of jackhammers in the context of developing noise controls (not to characterize the risk to hearing), you can find a copy here: ). If you look at Figures 10 or 11, you can see sound power levels (which can closely approximate sound pressure levels at the ear) from jackhammers averaged anywhere from 110-120 decibels, A-weighted (dBA) for one jackhammer. If you add two equivalent sources the resulting level is 3 dB higher than one alone.
If you add 4 equivalent sources the resulting level is 6 dB higher than one alone. At 115 dBA, a person should not be exposed more than half a minute per day according to our Recommended Exposure Limit (table 1-1). You mentioned that you were offered hearing protection, but you received no instructions on ratings or proper fitting. Without the instructions and fitting, the overall benefit of using hearing protection was likely diminished. In summary, it will be very hard to estimate a daily noise dose in such a complex environment without making actual measurements, on-site. NIOSH is a research agency.
We provide recommendations for prevention of injury and illness. However, we do not have regulatory authorities, nor do we intervene in worker compensation claims or disputes.