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A-weighting

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(Redirected from G-weighted) Frequency response curves used in sound pressure level measurement

A graph of the A-, B-, C- and D-weightings across the frequency range 10 Hz – 20 kHz
Video illustrating A-weighting by analyzing a sine sweep (contains audio)

A-weighting is a form of frequency weighting and the most commonly used of a family of curves defined in the International standard IEC 61672:2003 and various national standards relating to the measurement of sound pressure level. A-weighting is applied to instrument-measured sound levels in an effort to account for the relative loudness perceived by the human ear, as the ear is less sensitive to low audio frequencies. It is employed by arithmetically adding a table of values, listed by octave or third-octave bands, to the measured sound pressure levels in dB. The resulting octave band measurements are usually added (logarithmic method) to provide a single A-weighted value describing the sound; the units are written as dB(A). Other weighting sets of values – B, C, D and now Z – are discussed below.

The curves were originally defined for use at different average sound levels, but A-weighting, though originally intended only for the measurement of low-level sounds (around 40 phon), is now commonly used for the measurement of environmental noise and industrial noise, as well as when assessing potential hearing damage and other noise health effects at all sound levels; indeed, the use of A-frequency-weighting is now mandated for all these measurements, because decades of field experience have shown a very good correlation with occupational deafness in the frequency range of human speech. It is also used when measuring low-level noise in audio equipment, especially in the United States. In Britain, Europe and many other parts of the world, broadcasters and audio engineers more often use the ITU-R 468 noise weighting, which was developed in the 1960s based on research by the BBC and other organizations. This research showed that our ears respond differently to random noise, and the equal-loudness curves on which the A, B and C weightings were based are really only valid for pure single tones.

History

A-weighting began with work by Fletcher and Munson which resulted in their publication, in 1933, of a set of equal-loudness contours. Three years later these curves were used in the first American standard for sound level meters. This ANSI standard, later revised as ANSI S1.4-1981, incorporated B-weighting as well as the A-weighting curve, recognising the unsuitability of the latter for anything other than low-level measurements. But B-weighting has since fallen into disuse. Later work, first by Zwicker and then by Schomer, attempted to overcome the difficulty posed by different levels, and work by the BBC resulted in the CCIR-468 weighting, currently maintained as ITU-R 468 noise weighting, which gives more representative readings on noise as opposed to pure tones.

Deficiencies

A-weighting is valid to represent the sensitivity of the human ear as a function of the frequency of pure tones. The A-weighting was based on the 40-phon Fletcher–Munson curves, which represented an early determination of the equal-loudness contour for human hearing. However, because decades of field experience have shown a very good correlation between the A scale and occupational deafness in the frequency range of human speech, this scale is employed in many jurisdictions to evaluate the risks of occupational deafness and other auditory problems related to signals or speech intelligibility in noisy environments.

Because of perceived discrepancies between early and more recent determinations, the International Organization for Standardization (ISO) revised its standard curves as defined in ISO 226, in response to the recommendations of a study coordinated by the Research Institute of Electrical Communication, Tohoku University, Japan. The study produced new curves by combining the results of several studies, by researchers in Japan, Germany, Denmark, UK, and USA. (Japan was the greatest contributor with about 40% of the data.) This resulted in the acceptance of a new set of curves standardized as ISO 226:2003 (subsequently revised again in 2023 with changes to the ISO 226 equal loudness contours of less than 0.5 dB over the 20-90 phon range). The report comments on the large differences between the combined study results and the original Fletcher–Munson equal loudness contours, as well as the later Robinson-Dadson contours that formed the basis for the first version of ISO 226, published in 1987. Subsequent research has demonstrated that A-weighting is in closer agreement with the updated 60-phon contour incorporated into ISO 226:2003 than with the 40-phon Fletcher-Munson contour, which challenges the common misapprehension that A-weighting represents loudness only for quiet sounds.

Nevertheless, A-weighting would be a closer match to the equal loudness curves if it fell more steeply above 10 kHz, and it is conceivable that this compromise may have arisen because steep filters were more difficult to construct in the early days of electronics. Nowadays, no such limitation need exist, as demonstrated by the ITU-R 468 curve. If A-weighting is used without further band-limiting it is possible to obtain different readings on different instruments when ultrasonic, or near ultrasonic noise is present. Accurate measurements therefore require a 20 kHz low-pass filter to be combined with the A-weighting curve in modern instruments. This is defined in IEC 61012 as AU weighting and while very desirable, is rarely fitted to commercial sound level meters.

B-, C-, D-, G- and Z-weightings

A-frequency-weighting is mandated by the international standard IEC 61672 to be fitted to all sound level meters and are approximations to the equal loudness contours given in ISO 226. The old B- and D-frequency-weightings have fallen into disuse, but many sound level meters provide for C frequency-weighting and its fitting is mandated — at least for testing purposes — to precision (Class one) sound level meters. D-frequency-weighting was specifically designed for use when measuring high-level aircraft noise in accordance with the IEC 537 measurement standard. The large peak in the D-weighting curve is not a feature of the equal-loudness contours, but reflects the fact that humans hear random noise differently from pure tones, an effect that is particularly pronounced around 6 kHz. This is because individual neurons from different regions of the cochlea in the inner ear respond to narrow bands of frequencies, but the higher frequency neurons integrate a wider band and hence signal a louder sound when presented with noise containing many frequencies than for a single pure tone of the same pressure level.

Following changes to the ISO standard, D-frequency-weighting by itself should now only be used for non-bypass-type jet engines, which are found only on military aircraft and not on commercial aircraft. For this reason, today A-frequency-weighting is now mandated for light civilian aircraft measurements, while a more accurate loudness-corrected weighting EPNdB is required for certification of large transport aircraft. D-weighting is the basis for the measurement underlying EPNdB.

Z- or ZERO frequency-weighting was introduced in the International Standard IEC 61672 in 2003 and was intended to replace the "Flat" or "Linear" frequency weighting often fitted by manufacturers. This change was needed as each sound level meter manufacturer could choose their own low and high frequency cut-offs (–3 dB) points, resulting in different readings, especially when peak sound level was being measured. It is a flat frequency response between 10 Hz and 20 kHz ±1.5 dB. As well, the C-frequency-weighting, with –3 dB points at 31.5 Hz and 8 kHz did not have a sufficient bandpass to allow the sensibly correct measurement of true peak noise (Lpk).

G-weighting is used for measurements in the infrasound range from 8 Hz to about 40 Hz.

B- and D-frequency-weightings are no longer described in the body of the standard IEC 61672:2003, but their frequency responses can be found in the older IEC 60651, although that has been formally withdrawn by the International Electrotechnical Commission in favour of IEC 61672:2003. The frequency weighting tolerances in IEC 61672 have been tightened over those in the earlier standards IEC 179 and IEC 60651 and thus instruments complying with the earlier specifications should no longer be used for legally required measurements.

Environmental and other noise measurements

Label related to a portable air compressor

A-weighted decibels are abbreviated dB(A) or dBA. When acoustic (calibrated microphone) measurements are being referred to, then the units used will be dB SPL referenced to 20 micropascals = 0 dB SPL.

The A-weighting curve has been widely adopted for environmental noise measurement, and is standard in many sound level meters. The A-weighting system is used in any measurement of environmental noise (examples of which include roadway noise, rail noise, aircraft noise). A-weighting is also in common use for assessing potential hearing damage caused by loud noise, including noise dose measurements at work. A noise level of more than 85 dB(A) each day increases the risk factor for hearing damage.

A-weighted sound power levels LWA are increasingly found on sales literature for domestic appliances such as refrigerators, freezers and computer fans. The expected sound pressure level to be measured at a given distance as SPL with a sound level meter can with some simplifications be calculated from the sound power level. In Europe, the A-weighted noise level is used for instance for normalizing the noise of tires on cars.

Noise exposure for visitors of venues with loud music is usually also expressed in dB(A), although the presence of high levels of low frequency noise does not justify this.

Audio reproduction and broadcasting equipment

Although the A-weighting curve, in widespread use for noise measurement, is said to have been based on the 40-phon Fletcher-Munson curve, research in the 1960s demonstrated that determinations of equal-loudness made using pure tones are not directly relevant to our perception of noise. This is because the cochlea in our inner ear analyses sounds in terms of spectral content, each hair cell responding to a narrow band of frequencies known as a critical band. The high-frequency bands are wider in absolute terms than the low-frequency bands, and therefore 'collect' proportionately more power from a noise source. However, when more than one critical band is stimulated, the outputs of the various bands are summed by the brain to produce an impression of loudness. For these reasons equal-loudness curves derived using noise bands show an upwards tilt above 1 kHz and a downward tilt below 1 kHz when compared to the curves derived using pure tones.

This enhanced sensitivity to noise in the region of 6 kHz became particularly apparent in the late 1960s with the introduction of compact cassette recorders and Dolby-B noise reduction. A-weighted noise measurements were found to give misleading results because they did not give sufficient prominence to the 6 kHz region where the noise reduction was having greatest effect, and did not sufficiently attenuate noise around 10 kHz and above (a particular example is with the 19 kHz pilot tone on FM radio systems which, though usually inaudible, is not sufficiently attenuated by A-weighting, so that sometimes one piece of equipment would even measure worse than another and yet sound better, because of differing spectral content.

ITU-R 468 noise weighting was therefore developed to more accurately reflect the subjective loudness of all types of noise, as opposed to tones. This curve, which came out of work done by the BBC Research Department, and was standardised by the CCIR and later adopted by many other standards bodies (IEC, BSI) and, as of 2006, is maintained by the ITU. It became widely used in Europe, especially in broadcasting, and was adopted by Dolby Laboratories who realised its superior validity for their purposes when measuring noise on film soundtracks and compact cassette systems. Its advantages over A-weighting are less accepted in the US, where the use of A-weighting still predominates. It is used by broadcasters in Britain, Europe, and former countries of the British Empire such as Australia and South Africa.

Function realisation of some common weightings

The standard defines weightings ( A ( f ) , C ( f ) {\displaystyle A(f),C(f)} ) in dB units by tables with tolerance limits (to allow a variety of implementations). Additionally, the standard describes weighting functions R X ( f ) {\displaystyle R_{X}(f)} to calculate the weightings. The weighting function R X ( f ) {\displaystyle R_{X}(f)} is applied to the amplitude spectrum (not the intensity spectrum) of the unweighted sound level. The offsets ensure the normalisation to 0 dB at 1000 Hz. Appropriate weighting functions are:

A

R A ( f ) = 12194 2 f 4 ( f 2 + 20.6 2 )   ( f 2 + 107.7 2 ) ( f 2 + 737.9 2 )   ( f 2 + 12194 2 )   , A ( f ) = 20 log 10 ( R A ( f ) ) 20 log 10 ( R A ( 1000 ) ) 20 log 10 ( R A ( f ) ) + 2.00 {\displaystyle {\begin{aligned}R_{A}(f)&={12194^{2}f^{4} \over \left(f^{2}+20.6^{2}\right)\ {\sqrt {\left(f^{2}+107.7^{2}\right)\left(f^{2}+737.9^{2}\right)}}\ \left(f^{2}+12194^{2}\right)}\ ,\\A(f)&=20\log _{10}\left(R_{A}(f)\right)-20\log _{10}\left(R_{A}(1000)\right)\\&\approx 20\log _{10}\left(R_{A}(f)\right)+2.00\end{aligned}}}

B

R B ( f ) = 12194 2 f 3 ( f 2 + 20.6 2 )   ( f 2 + 158.5 2 )   ( f 2 + 12194 2 )   , B ( f ) = 20 log 10 ( R B ( f ) ) 20 log 10 ( R B ( 1000 ) ) 20 log 10 ( R B ( f ) ) + 0.17 {\displaystyle {\begin{aligned}R_{B}(f)&={12194^{2}f^{3} \over \left(f^{2}+20.6^{2}\right)\ {\sqrt {\left(f^{2}+158.5^{2}\right)}}\ \left(f^{2}+12194^{2}\right)}\ ,\\B(f)&=20\log _{10}\left(R_{B}(f)\right)-20\log _{10}\left(R_{B}(1000)\right)\\&\approx 20\log _{10}\left(R_{B}(f)\right)+0.17\end{aligned}}}

C

R C ( f ) = 12194 2 f 2 ( f 2 + 20.6 2 )   ( f 2 + 12194 2 )   , C ( f ) = 20 log 10 ( R C ( f ) ) 20 log 10 ( R C ( 1000 ) ) 20 log 10 ( R C ( f ) ) + 0.06 {\displaystyle {\begin{aligned}R_{C}(f)&={12194^{2}f^{2} \over \left(f^{2}+20.6^{2}\right)\ \left(f^{2}+12194^{2}\right)}\ ,\\C(f)&=20\log _{10}\left(R_{C}(f)\right)-20\log _{10}\left(R_{C}(1000)\right)\\&\approx 20\log _{10}\left(R_{C}(f)\right)+0.06\end{aligned}}}

D

h ( f ) = ( 1037918.48 f 2 ) 2 + 1080768.16 f 2 ( 9837328 f 2 ) 2 + 11723776 f 2 R D ( f ) = f 6.8966888496476 10 5 h ( f ) ( f 2 + 79919.29 ) ( f 2 + 1345600 ) D ( f ) = 20 log 10 ( R D ( f ) ) . {\displaystyle {\begin{aligned}h(f)&={\frac {\left(1037918.48-f^{2}\right)^{2}+1080768.16\,f^{2}}{\left(9837328-f^{2}\right)^{2}+11723776\,f^{2}}}\\R_{D}(f)&={\frac {f}{6.8966888496476\cdot 10^{-5}}}{\sqrt {\frac {h(f)}{\left(f^{2}+79919.29\right)\left(f^{2}+1345600\right)}}}\\D(f)&=20\log _{10}\left(R_{D}(f)\right).\end{aligned}}}

Transfer function equivalent

The gain curves can be realised by the following s-domain transfer functions. They are not defined in this way though, being defined by tables of values with tolerances in the standards documents, thus allowing different realisations:

A

H A ( s ) k A s 4 ( s + 129.4 ) 2 ( s + 676.7 ) ( s + 4636 ) ( s + 76617 ) 2 {\displaystyle H_{\text{A}}(s)\approx {k_{\text{A}}\cdot s^{4} \over (s+129.4)^{2}\quad (s+676.7)\quad (s+4636)\quad (s+76617)^{2}}}
kA ≈ 7.39705 × 10

B

H B ( s ) k B s 3 ( s + 129.4 ) 2 ( s + 995.9 ) ( s + 76617 ) 2 {\displaystyle H_{\text{B}}(s)\approx {k_{\text{B}}\cdot s^{3} \over (s+129.4)^{2}\quad (s+995.9)\quad (s+76617)^{2}}}
kB ≈ 5.99185 × 10

C

H C ( s ) k C s 2 ( s + 129.4 ) 2 ( s + 76617 ) 2 {\displaystyle H_{\text{C}}(s)\approx {k_{\text{C}}\cdot s^{2} \over (s+129.4)^{2}\quad (s+76617)^{2}}}
kC ≈ 5.91797 × 10

D

H D ( s ) k D s ( s 2 + 6532 s + 4.0975 × 10 7 ) ( s + 1776.3 ) ( s + 7288.5 ) ( s 2 + 21514 s + 3.8836 × 10 8 ) {\displaystyle H_{\text{D}}(s)\approx {k_{\text{D}}\cdot s\cdot \left(s^{2}+6532s+4.0975\times 10^{7}\right) \over (s+1776.3)\quad (s+7288.5)\quad \left(s^{2}+21514s+3.8836\times 10^{8}\right)}}
kD ≈ 91104.32

The k-values are constants that are used to normalize the function to a gain of 1 (0 dB). The values listed above normalize the functions to 0 dB at 1 kHz, as they are typically used. (This normalization is shown in the image.)

See also

Notes

  1. dBrn adjusted is not a synonym for dB(A), but for dBa. (In telecommunications dBa denotes "decibels adjusted", i.e. weighted absolute noise power, which has nothing to do with A-weighting.)

References

  1. Meyer-Bisch, Christian (2005). "[Measuring noise]". Médecine/Sciences. 21 (5): 546–550. doi:10.1051/medsci/2005215546. ISSN 0767-0974. PMID 15885208.
  2. Pierre, Jr., Richard L. St.; Maguire, Daniel J. (July 2004). "The Impact of A-weighting Sound Pressure Level Measurements during the Evaluation of Noise Exposure" (PDF). Retrieved 2011-09-13.
  3. "Precise and full-range determination of two-dimensional equal loudness contours" (PDF). Archived from the original (PDF) on 2007-09-27.
  4. "Loudness experiment on general environmental noises considering low-frequency components down to infrasound". Archived from the original on 2023-03-29.
  5. Rimell, Andrew; Mansfield, Neil; Paddan, Gurmail (2015). "Design of digital filters for frequency weightings (A and C) required for risk assessments of workers exposed to noise". Industrial Health. 53 (53): 21–27. doi:10.2486/indhealth.2013-0003. PMC 4331191. PMID 25224333. S2CID 13997453.
  6. "BIP_2_2_jb ZIP file" (PDF).
  7. Lauer, Amanda; El-Sharkawy, AbdEl-Monem M.; Kraitchman, Dara; Edelstein, William (2012). "MRI Acoustic Noise Can Harm Experimental and Companion Animals". Journal of Magnetic Resonance Imaging. 36 (3): 743–747. doi:10.1002/jmri.23653. PMID 22488793. S2CID 7436249.
  8. Ratzel, U.; Bayer, O.; Brachat, P.; Hoffmann, M.; Jänke, K.; Kiesel, K.-J.; Mehnert, C.; Scheck, C.; Westerhausen, C.; Krapf, K.-G.; Herrmann, L.; Blaul, J., eds. (February 2020) . "Tieffrequente Geräusche inkl. Infraschall von Windkraftanlagen und anderen Quellen - Bericht über Ergebnisse des Messprojekts 2013-2015" (in German) (3 ed.). Karlsruhe, Germany: Landesanstalt für Umwelt, Messungen und Naturschutz Baden-Württemberg (LUBW), Referat 34 – Technischer Arbeitsschutz, Lärmschutz. pp. 10–11, 13, 17, 22–24, 27–28, 32–33, 38–39, 43–44, 49, 90. Retrieved 2021-06-07. p. 90: Für den Bereich des Infraschalls gibt es eine eigene Frequenzbewertung, die so genannte G-Bewertung. Entsprechend bewertete Pegel werden als dB(G) – „Dezibel G" – angegeben. Bekannter ist die A-Bewertung von Geräuschen als dB(A) – „Dezibel A" –, die dem Hörempfinden des Menschen nachempfunden ist. Die G-Bewertung hat ihren Schwerpunkt bei 20 Hz. Zwischen 10 Hz und 25 Hz werden Pegel verstärkt, darunter und darüber fällt die Bewertungskurve rasch ab. Zweck der G-Bewertung ist es, eine Situation im Hinblick auf tiefe Frequenzen bzw. Infraschall mit einer einzigen Zahl zu charakterisieren. Ein Nachteil ist, dass Frequenzen unterhalb 8 Hz und oberhalb 40 Hz kaum mehr einen Beitrag leisten. (104 pages)
  9. Bauer, B.; Torick, E. (1966). "Researches in loudness measurement". IEEE Transactions on Audio and Electroacoustics. 14 (3): 141–151. doi:10.1109/TAU.1966.1161864.
  10. ^ IEC 61672-1:2013 Electroacoustics - Sound level meters - Part 1: Specifications. IEC. 2013.
  11. "Frequency weighting equations". Cross Spectrum. 2004. Archived from the original on 2011-06-17.
  12. Aarts, Ronald M. (1992-03-01). "A Comparison of Some Loudness Measures for Loudspeaker Listening Tests". Audio Engineering Society. 40 (3): 142–146. Archived from the original on 2022-10-27. Retrieved 2022-10-27.
  13. "Noise Measurement Briefing". Product Technology Partners Ltd. Archived from the original on 2008-06-30.

Further reading

  • Audio Engineer's Reference Book, 2nd Ed 1999, edited Michael Talbot Smith, Focal Press
  • An Introduction to the Psychology of Hearing 5th ed, Brian C. J. Moore, Elsevier Press

External links

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