A-law algorithm

Graph of μ-law & A-law algorithms

An A-law algorithm is a standard companding algorithm, used in European digital communications systems to optimize, i.e., modify, the dynamic range of an analog signal for digitizing.

It is similar to the μ-law algorithm used in North America and Japan.

For a given input x, the equation for A-law encoding is as follows,

$F(x) = \sgn(x) \begin{cases} {A |x| \over 1 + \ln(A)}, & |x| < {1 \over A} \\frac{1+ \ln(A |x|)}{1 + \ln(A)}, & {1 \over A} \leq |x| \leq 1, \end{cases}$

where A is the compression parameter. In Europe, $A = 87.7$ ; the value 87.6 is also used.

A-law expansion is given by the inverse function,

$F^{-1}(y) = \sgn(y) \begin{cases} {|y| (1 + \ln(A)) \over A}, & |y| < {1 \over 1 + \ln(A)} \{\exp(|y| (1 + \ln(A)) - 1) \over A}, & {1 \over 1 + \ln(A)} \leq |y| < 1. \end{cases}$

The reason for this encoding is that the wide dynamic range of speech does not lend itself well to efficient linear digital encoding. A-law encoding effectively reduces the dynamic range of the signal, thereby increasing the coding efficiency and resulting in a signal-to-distortion ratio that is superior to that obtained by linear encoding for a given number of bits.

Comparison to μ-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.

External links

Waveform Coding Techniques - Has details of implementation (but note that the A-law equation is incorrect)
A-Law and μ-law Companding Implementations Using the TMS320C54x (PDF)
A-law and μ-law realisation (in C)

Data compression methods

Information theory

Entropy
Complexity
Redundancy
Lossy
Timeline of information theory
Quantization
Rate distortion theory

Lossless

Entropy encoding	Arithmetic Golomb Huffman Adaptive Canonical Modified Range Shannon–Fano Shannon–Fano–Elias Tunstall Universal Gamma Exp-Golomb Fibonacci Levenstein

Dictionary	Byte pair encoding DEFLATE Lempel–Ziv LZ77 and LZ78 LZSS LZW LZWL LZO LZMA LZX LZRW LZJB LZS LZT ROLZ Statistical Lempel Ziv RLE

Others	CTW BWT PPM DMC Delta

Audio

Theory	Companding Convolution Dynamic range Latency Sampling Nyquist–Shannon theorem Sound quality

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

Others	Bit rate CBR ABR VBR Speech compression Sub-band coding

Image

Terms	Color space Pixel Chroma subsampling Compression artifact Image resolution

Methods	RLE Fractal Wavelet EZW SPIHT LP DCT Chain code KLT

Others	Test images PSNR quality measure Quantization

Video

Terms	Video characteristics Frame Frame rate Interlace Frame types Video quality Video resolution

Video codec parts	Motion compensation DCT Deblocking filter

Others	Video codecs Lossless compressed Uncompressed Bit rate CBR ABR VBR

See Compression formats for formats and Compression software for codecs

Comparison to μ-law

See also

External links