EBU R 128
EBU R 128 is a recommendation for loudness normalisation and maximum level of audio signals. It is primarily followed during audio mixing of television and radio programmes and adopted by broadcasters to measure and control programme loudness.[1] It was first issued by the European Broadcasting Union in August 2010 and most recently revised in June 2014.[2]
Loudness normalization and permitted maximum level of audio signals | |
Status | Published |
---|---|
Year started | 2012 |
First published | 2010 |
Latest version | 3.0 3 June 2014 |
Organization | European Broadcasting Union |
Related standards | ITU-R BS.1770 |
Website | https://tech.ebu.ch/publications/r128/ |
R 128 employs an international standard for measuring audio loudness, stated in the ITU-R BS.1770 recommendation and using the loudness measures LU (loudness units) and LUFS (loudness units referenced to full scale), specifically created with this purpose.[3] The EBU Tech 3341 document further clarified loudness metering implementation and practices in 2016.[4]
Premise
Before the adoption of R 128, normalisation was based on the peak level of audio signals, which led to considerable loudness discrepancies between programmes and between broadcast channels.[1] The same peak level does not necessarily produce the same loudness, because the use of dynamic range compression and limiting can increase the average level of the programme without increasing its peak level. Starting from the early 1990s through the early 2010s, both the music and the advertising industries urged continuation of this practice to ensure that music and advertising spots became louder without exceeding the maximum permitted peak level. This phenomenon is known as the loudness war.
The resulting inconsistencies and changes in loudness, especially between programmes and commercials, became a frequent cause of complaints from viewers and listeners. To help address these problems, the International Telecommunication Union (ITU) developed new algorithms to measure audio programme loudness in a manner similar to how the human ear perceives sounds and studied new methods to measure loudness over a long-term timeframe. This would allow normalising the loudness of different programs and programme contents appropriately.[1]
Development
To find practical solutions for the switch from peak normalization to loudness normalization, the EBU Production Management Committee formed an international working group comprising sound engineers from various radio stations and broadcasting institutes. Its name, PLoud, derived from a combination of the words "production" and "loudness".[5]
The group first developed evaluation and measurement methods to guide the development of appropriate measurement instruments in the industry.[4] It drafted a technical document to enable broadcasters and programme producers to change their sound processing to the new recommendation,[6] while another technical document dealt with the procedures to follow in the signal distribution.[7]
Specification
Definitions
To characterize the level and the dynamic range of an audio signal, R 128 introduced new units of measurement:
Unit | Definition | Description | Examples and implementation |
---|---|---|---|
LK | K-weighted loudness level | Loudness level measured with K frequency weighting. | R 128 target level is: LK = −23 LUFS |
LUFS | Loudness Units referenced to full scale | Loudness measurement unit on an absolute scale, K-weighted,[3] relative to a digital scale (which upper limit is 0 dBFS). Equivalent with LKFS, used in ITU-R BS.1770. | |
LU | Loudness Unit | Relative loudness measurement. 1 LU corresponds to the relative measurement of 1 dB on a digital scale. LU can also express the difference in level from the target level.[5] | In a loudness meter implementing EBU Mode: Reference level = −23 LUFS = 0 LU A programme with an integrated loudness of a −26 LUFS measures −3 LU in EBU Mode (i.e. is 3 LU quieter than the target level). |
LRA | Loudness Range[8] | A statistically determined value that describes the loudness variation (dynamics) of a programme. | R 128 does not prescribe a maximum loudness range. LRA could be limited arbitrarily during production for aesthetic purposes (depending on style or genre) or practical purposes (depending on the environment where the programme is intended to be played back: for example, a home theatre, a mobile device or a cinema). |
TP | True Peak | Reconstruction of the inter-sample peak level of the signal (the peak level generated between two samples), calculated by oversampling.[9] | The maximum true peak level permitted by R 128 in production is −1 dBTP. |
dBTP | True Peak level referenced to full scale | Level in of the audio signal that takes inter-sample peaks into account, measured in decibels relative to full scale. |
Recommendation
R 128 recommends normalizing audio at the target level of −23 LUFS. This measurement is calculated over the whole duration of the programme (called "integrated loudness") and in the entirety of its contents (i.e. without emphasizing specific foreground elements, such as voice).[1] A deviation of ±0.5 LU is permitted; when practical limitations prevent to achieve this result (specifically, less predictable materials such as live mixed programmes), a wider tolerance of ±1 LU is permitted. Furthermore, the whole programme must not exceed the peak level of −1 dBTP.[1]
To make sure that loudness meters developed by different manufacturers provide the same reading, EBU Tech 3341 defines how to perform the measurement: this standardized method is called EBU Mode and adopts the algorithms introduced with the ITU-R BS.1770 recommendation.[4]
EBU Mode metering
EBU Mode specifies three distinct methods which analyse loudness over three different timeframes:
- Momentary (M), using a sliding time window of 400 ms, best describes the instantaneous loudness;
- Short-term (S), using a sliding time window of 3 s, describes a more averaged, less event-dependant loudness of the past three seconds;
- Integrated (I), averaging the programme from start to finish, describes the loudness of the whole programme.
To prevent that silent passages of a programme misrepresent the overall loudness measurement, integrated loudness is measured through a gating function (with an absolute threshold and a relative threshold). The detection gate, specified in ITU-R BS.1770-4, considers "silence" the portions of audio in which the signal falls below the absolute threshold of −60 LUFS; similarly, the relative gate also drops incoming loudness data if the average level falls 10 LU below the current integrated loudness value.[9] Measurement is not gated in momentary and short-term loudness.[4]
Meter ballistics of real-time meters must provide an update rate of at least 10 Hz for short-term meters and of at least 1 Hz for integrated loudness meters.
Implementation
EBU R 128 and EBU Mode have been implemented by several software developers, audio technology companies and content distributors, including Adobe, Apple, Dolby, iZotope, Magix, PreSonus, Sony, Steinberg, TC Electronic, Toyo and Waves.[10]
Real-time metering plug-ins aid engineers in their mixing decisions and in delivering R 128-compliant programmes, while broadcasters and content distributors can check and normalize whole programmes by performing a faster-than-real-time analysis; programmes produced before the recommendation are likely to be lowered in volume to match the target level.
Adoption and aftermath
The recommendation encourages the use of a wider dynamic range in production, despite not deprecating employing heavy dynamic compression a priori. In essence, it ties the use of using dynamic compression to artistic and aesthetic decisions, rather than the necessity of obtaining a louder mix.[5] Broadcasters and streaming platforms have been adopting loudness normalization since the introduction of EBU R 128, therefore reducing dynamic range doesn't repay anymore in terms of increased loudness.[11] Widespread adoption of ITU-R BS.1770 and EBU R 128, combined with the prevailing of streaming over physical media distribution in the 2010s, put an end to the loudness war.[9]
Starting from 2012, European countries integrated EBU R 128 to their audiovisual legislations, and television stations in Europe adopted it on all distribution channels.[12] Sky UK adopted R 128 in 2013.[13]
R 128 is applicable also to radio programmes and is gradually being introduced in European radio broadcasts: for example, German public broadcaster BR changed its radio programmes at the end of 2015.[14]
Since R 128 implementation is not binding, some television stations imposed additional conditions on programme production. For example, Austrian public broadcaster ORF has a limit of −3 dBTP for data-reduced formats; Franco-German TV network ARTE has published guidelines for LRA; various broadcasters impose maximum momentary and short-term loudness values for short reports, such as commercials.
Through the 2010s, Internet streaming services have implemented loudness-based normalization, even though each platform uses different methods and target levels: for example, YouTube and Tidal use downward normalization only (turn down louder content to match the target level, but do not turn up quieter content).[15] Spotify uses ReplayGain to measure loudness, although it is planning to use ITU-R BS.1770, and it has adjusted the algorithm calibration to approximately match the −14 LUFS target level.[16] Apple Music activates loudness normalization when the iTunes Sound Check option is enabled.
Target level | Platform |
---|---|
−14 LUFS | Tidal, Amazon Music, YouTube, Spotify |
−16 LUFS | Apple Music |
−18 LUFS |
References
- "R 128 – Loudness normalisation and permitted maximum level of audio signals" (PDF). tech.ebu.ch. Geneva: European Broadcasting Union. June 2014. Retrieved 31 March 2020.
- "Change log R 128 v3.0". tech.ebu.ch. 31 May 2016. Retrieved 5 April 2020.
- "Recommendation ITU-R BS.1770-2 – Algorithms to measure audio programme loudness and true-peak audio level" (PDF). International Telecommunication Union. March 2011. Retrieved 31 March 2020.
- "Tech 3341 – Loudness Metering: 'EBU Mode' metering to supplement Loudness normalisation" (PDF). tech.ebu.ch. Geneva: European Broadcasting Union. January 2016. Retrieved 4 April 2020.
- "Ploud (Loudness) – FAQ". tech.ebu.ch. 18 December 2019. Retrieved 8 April 2020.
- "Tech 3343 – Guidelines for production of programmes in accordance with EBU R 128" (PDF). tech.ebu.ch. Geneva: European Broadcasting Union. January 2016. Retrieved 4 April 2020.
- "Tech 3344 – Guidelines for distribution and reproduction in accordance with EBU R 128" (PDF). tech.ebu.ch. Geneva: European Broadcasting Union. July 2016. Retrieved 4 April 2020.
- "Tech 3342 – Loudness Range: measure to supplement loudness normalisation" (PDF). tech.ebu.ch. Geneva: European Broadcasting Union. January 2016. Retrieved 4 April 2020.
- Robjohns, Hugh (February 2014). "The end of the loudness war?". Sound on Sound. Retrieved 8 April 2020.
- "Ploud (Loudness) – Implementations". tech.ebu.ch. 18 December 2019. Retrieved 8 April 2020.
- Schorah, Jon; Inglis, Sam (June 2017). "Mastering for streaming services". Sound on Sound. Retrieved 8 April 2020.
- "Loudness: France chooses EBU R128 to bolster audio laws". European Broadcasting Union. 25 October 2011. Retrieved 8 April 2020.
- Davies, David (9 December 2013). "Sky confirms formal adoption of R128 loudness specification". SVG Europe. Retrieved 8 April 2020.
- Rundfunk, Bayerischer (10 July 2015). "Angenehmer hören: BR optimiert Klang durch Aussteuerung nach Lautheit". BR.de (in German).
- Shepherd, Ian (18 September 2019). "YouTube changes loudness reference to –14 LUFS". meterplugs.com. Retrieved 8 April 2020.
- "Mastering & loudness – FAQ – Spotify for Artists". artists.spotify.com. Retrieved 8 April 2020.
External links
- ffmpeg-normalize – Open source utility to normalize audio files in batch processing using Python and the FFmpeg framework
- EBU R 128 Normalizer – Component for the freeware player foobar2000 to analyse and normalize audio files during playback