μ-law algorithm

Companding of μ-law and A-law algorithms

The µ-law algorithm (sometimes written "mu-law", often approximated as "u-law") is a companding algorithm, primarily used in 8-bit PCM digital telecommunication systems in North America and Japan. It is one of two versions of the G.711 standard from ITU-T, the other version being the similar A-law, used in regions where digital telecommunication signals are carried on E-1 circuits, e.g. Europe.

Companding algorithms reduce the dynamic range of an audio signal. In analog systems, this can increase the signal-to-noise ratio (SNR) achieved during transmission; in the digital domain, it can reduce the quantization error (hence increasing signal to quantization noise ratio). These SNR increases can be traded instead for reduced bandwidth for equivalent SNR.

Algorithm types

There are two forms of this algorithm—an analog version, and a quantized digital version.

Continuous

For a given input $x$ , the equation for μ-law encoding is^[1]

F(x) = \sgn(x) \frac{\ln(1+ \mu |x|)}{\ln(1+\mu)}~~~~-1 \leq x \leq 1

where $μ = 255$ (8 bits) in the North American and Japanese standards. It is important to note that the range of this function is −1 to 1.

μ-law expansion is then given by the inverse equation:

F^{-1}(y) = \sgn(y) (1 / \mu ) ((1 + \mu)^{|y|}- 1)~~~~-1 \leq y \leq 1

The equations are culled from Cisco's Waveform Coding Techniques.

Discrete

This is defined in ITU-T Recommendation G.711.^[2]

G.711 is unclear about how to code the values at the limit of a range (e.g. whether +31 codes to 0xEF or 0xF0). However, G.191 provides example C code for a μ-law encoder which gives the following encoding. Note the difference between the positive and negative ranges, e.g. the negative range corresponding to +30 to +1 is −31 to −2. This is accounted for by the use of 1's complement (simple bit inversion) rather than 2's complement to convert a negative value to a positive value during encoding.

Quantized μ-law algorithm
14 bit Binary Linear input code	8 bit Compressed code
+8158 to +4063 in 16 intervals of 256	0x80 + interval number
+4062 to +2015 in 16 intervals of 128	0x90 + interval number
+2014 to +991 in 16 intervals of 64	0xA0 + interval number
+990 to +479 in 16 intervals of 32	0xB0 + interval number
+478 to +223 in 16 intervals of 16	0xC0 + interval number
+222 to +95 in 16 intervals of 8	0xD0 + interval number
+94 to +31 in 16 intervals of 4	0xE0 + interval number
+30 to +1 in 15 intervals of 2	0xF0 + interval number
0	0xFF
−1	0x7F
−31 to −2 in 15 intervals of 2	0x70 + interval number
−95 to −32 in 16 intervals of 4	0x60 + interval number
−223 to −96 in 16 intervals of 8	0x50 + interval number
−479 to −224 in 16 intervals of 16	0x40 + interval number
−991 to −480 in 16 intervals of 32	0x30 + interval number
−2015 to −992 in 16 intervals of 64	0x20 + interval number
−4063 to −2016 in 16 intervals of 128	0x10 + interval number
−8159 to −4064 in 16 intervals of 256	0x00 + interval number

Implementation

There are three ways of implementing a μ-law algorithm:

Analog: Use an amplifier with non-linear gain to achieve companding entirely in the analog domain.
Non-linear ADC: Use an analog-to-digital converter with quantization levels which are unequally spaced to match the μ-law algorithm.
Digital: Use the quantized digital version of the μ-law algorithm to convert data once it is in the digital domain.

Usage justification

This encoding is used because speech has a wide dynamic range. In the analog world, when mixed with a relatively constant background noise source, the finer detail is lost. Given that the precision of the detail is compromised anyway, and assuming that the signal is to be perceived as audio by a human, one can take advantage of the fact that the perceived acoustic intensity level or loudness is logarithmic by compressing the signal using a logarithmic-response operational amplifier (Weber-Fechner law). In telecommunications circuits, most of the noise is injected on the lines, thus after the compressor, the intended signal is perceived as significantly louder than the static, compared to an un-compressed source. This became a common solution, and thus, prior to common digital usage, the μ-law specification was developed to define an inter-compatible standard.

In digital systems this pre-existing algorithm had the effect of significantly reducing the number of bits needed to encode recognizable human voice. Using μ-law, a sample could be effectively encoded in as few as 8 bits, a sample size that conveniently matched the symbol size of most standard computers.

μ-law encoding effectively reduced the dynamic range of the signal, thereby increasing the coding efficiency while biasing the signal in a way that results in a signal-to-distortion ratio that is greater than that obtained by linear encoding for a given number of bits. This is an early form of perceptual audio encoding.

μ-law encoding as generated with the Sun Microsystems C-language routine g711.c commonly available on the Internet.

The μ-law algorithm is also used in the .au format, which dates back at least to the SPARCstation 1 by Sun Microsystems as the native method used by the /dev/audio interface, widely used as a de facto standard for sound on Unix systems. The au format is also used in various common audio APIs such as the classes in the sun.audio Java package in Java 1.1 and in some C# methods.

This plot illustrates how μ-law concentrates sampling in the smaller (softer) values. The abscissa represents the byte values 0-255 and the vertical axis is the 16-bit linear decoded value of μ-law encoding.

Comparison with A-law

The µ-law algorithm provides a slightly larger dynamic range than the A-law at the cost of worse proportional distortion for small signals. By convention, A-law is used for an international connection if at least one country uses it.

References

This article incorporates public domain material from the General Services Administration document "Federal Standard 1037C".

↑ "Cisco - Waveform Coding Techniques". Retrieved 2008-07-29.
↑ "ITU-T Recommendation G.711".

External links

Waveform Coding Techniques – details of implementation
A-Law and mu-Law Companding Implementations Using the TMS320C54x (PDF)
TMS320C6000 μ-Law and A-Law Companding with Software or the McBSP (PDF)
A-law and μ-law realisation (in C) (ctrl-a "highlight all" to see linked black-on-black text).

Data compression methods

Lossless

Entropy type	Unary Arithmetic Golomb Huffman Adaptive Canonical Modified Range Shannon Shannon–Fano Shannon–Fano–Elias Tunstall Universal Exp-Golomb Fibonacci Gamma Levenshtein

Dictionary type	Byte pair encoding DEFLATE Lempel–Ziv LZ77 / LZ78 (LZ1 / LZ2) LZJB LZMA LZO LZRW LZS LZSS LZW LZWL LZX LZ4 Statistical

Other types	BWT CTW Delta DMC MTF PAQ PPM RLE

Audio

Concepts	Bit rate average (ABR) constant (CBR) variable (VBR) Companding Convolution Dynamic range Latency Nyquist–Shannon theorem Sampling Sound quality Speech coding Sub-band coding

Codec parts	A-law μ-law ACELP ADPCM CELP DPCM Fourier transform LPC LAR LSP MDCT Psychoacoustic model WLPC

Image

Concepts	Chroma subsampling Coding tree unit Color space Compression artifact Image resolution Macroblock Pixel PSNR Quantization Standard test image

Methods	Chain code DCT EZW Fractal KLT LP RLE SPIHT Wavelet

Video

Concepts	Bit rate average (ABR) constant (CBR) variable (VBR) Display resolution Frame Frame rate Frame types Interlace Video characteristics Video quality

Codec parts	Lapped transform DCT Deblocking filter Motion compensation

Theory

Compression formats
Compression software (codecs)

Multimedia compression and container formats

Video
compression

ISO/IEC	MJPEG Motion JPEG 2000 MPEG-1 MPEG-2 Part 2 MPEG-4 Part 2/ASP Part 10/AVC MPEG-H Part 2/HEVC

ITU-T	H.120 H.261 H.262 H.263 H.264 H.265

SMPTE	VC-1 VC-2 VC-3 VC-5

Others	Apple Video AVS Bink Cinepak Daala Dirac DV DVI FFV1 Huffyuv Indeo Microsoft Video 1 MSU Lossless Lagarith OMS Video Pixlet ProRes 422 ProRes 4444 QuickTime Animation Graphics RealVideo RTVideo SheerVideo Smacker Sorenson Video, Spark Theora Thor VP3 VP6 VP7 VP8 VP9 WMV XEB YULS

Audio
compression

ISO/IEC	MPEG-1 Layer III (MP3) MPEG-1 Layer II Multichannel MPEG-1 Layer I AAC HE-AAC AAC-LD MPEG Surround MPEG-4 ALS MPEG-4 SLS MPEG-4 DST MPEG-4 HVXC MPEG-4 CELP MPEG-D USAC MPEG-H 3D Audio

ITU-T	G.711 (A-law, µ-law) G.718 G.719 G.722 G.722.1 G.722.2 G.723 G.723.1 G.726 G.728 G.729 G.729.1

IETF	Opus iLBC

3GPP	AMR AMR-WB AMR-WB+ EVRC EVRC-B GSM-HR GSM-FR GSM-EFR

Others	ACELP AC-3 ALAC Asao ATRAC CELT Codec2 DRA DTS FLAC iSAC Monkey's Audio TTA True Audio MT9 Musepack OptimFROG OSQ QCELP RCELP RealAudio RTAudio SD2 SHN SILK Siren SMV Speex SVOPC TwinVQ VMR-WB Vorbis VSELP WavPack WMA MQA aptX

Image
compression

IEC, ISO, ITU-T,W3C,IETF	CCITT Group 4 JPEG JPEG 2000 JPEG XR Lossless JPEG JBIG JBIG2 PNG TIFF/EP TIFF/IT HEVC GIF TIFF

Others	APNG BPG DjVu EXR FLIF ICER MNG PGF QTVR WBMP WebP

Containers

ISO/IEC	MPEG-PS MPEG-TS ISO base media file format MPEG-4 Part 14 (MP4) Motion JPEG 2000 MPEG-21 Part 9 MPEG media transport

ITU-T	H.222.0 T.802

Others	3GP and 3G2 AMV ASF AIFF AVI AU BPG Bink Smacker BMP DivX Media Format EVO Flash Video GXF IFF M2TS Matroska WebM MXF Ogg QuickTime File Format RatDVD RealMedia RIFF WAV MOD and TOD VOB, IFO and BUP

Collaborations

See Compression methods for methods and Compression software for codecs

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