G.711

G.711 is a narrowband audio codec originally designed for use in telephony that provides toll-quality audio at 64 kbit/s. G.711 passes audio signals in the range of 300–3400 Hz and samples them at the rate of 8,000 samples per second, with the tolerance on that rate of 50 parts per million (ppm). Non-uniform (logarithmic) quantization with 8 bits is used to represent each sample, resulting in a 64 kbit/s bit rate. There are two slightly different versions: μ-law, which is used primarily in North America and Japan, and A-law, which is in use in most other countries outside North America.

G.711
Pulse code modulation (PCM) of voice frequencies
StatusIn force
Year started1972
Latest version(02/00)
February 2000
OrganizationITU-T
Related standardsG.711.0, G.711.1
Domainaudio compression
Websitehttps://www.itu.int/rec/T-REC-G.711

G.711 is an ITU-T standard (Recommendation) for audio companding, titled Pulse code modulation (PCM) of voice frequencies released for use in 1972. It is a required standard in many technologies, such as in the H.320 and H.323 standards.[1] It can also be used for fax communication over IP networks (as defined in T.38 specification).

Two enhancements to G.711 have been published: G.711.0 utilizes lossless data compression to reduce the bandwidth usage and G.711.1 increases audio quality by increasing bandwidth.

Features

  • 8 kHz sampling frequency
  • 64 kbit/s bitrate (8 kHz sampling frequency × 8 bits per sample)
  • Typical algorithmic delay is 0.125 ms, with no look-ahead delay
  • G.711 is a waveform speech coder
  • G.711 Appendix I defines a packet loss concealment (PLC) algorithm to help hide transmission losses in a packetized network
  • G.711 Appendix II defines a discontinuous transmission (DTX) algorithm which uses voice activity detection (VAD) and comfort noise generation (CNG) to reduce bandwidth usage during silence periods
  • PSQM testing under ideal conditions yields mean opinion scores of 4.45 for G.711 μ-law, 4.45 for G.711 A-law
  • PSQM testing under network stress yields mean opinion scores of 4.13 for G.711 μ-law, 4.11 for G.711 A-law

Types

G.711 defines two main companding algorithms, the μ-law algorithm and A-law algorithm. Both are logarithmic, but A-law was specifically designed to be simpler for a computer to process. The standard also defines a sequence of repeating code values which defines the power level of 0 dB.

The μ-law and A-law algorithms encode 14-bit and 13-bit signed linear PCM samples (respectively) to logarithmic 8-bit samples. Thus, the G.711 encoder will create a 64 kbit/s bitstream for a signal sampled at 8 kHz.[1]

G.711 μ-law tends to give more resolution to higher range signals while G.711 A-law provides more quantization levels at lower signal levels.

The terms PCMU, G711u or G711MU for G711 μ-law, and PCMA or G711A for G711 A-law, are used.[2]

A-law

A-law encoding thus takes a 13-bit signed linear audio sample as input and converts it to an 8 bit value as follows:

Linear input code
[note 1]
Compressed code
XOR 01010101
Linear output code
[note 2]
s0000000abcdxs000abcds0000000abcd1
s0000001abcdxs001abcds0000001abcd1
s000001abcdxxs010abcds000001abcd10
s00001abcdxxxs011abcds00001abcd100
s0001abcdxxxxs100abcds0001abcd1000
s001abcdxxxxxs101abcds001abcd10000
s01abcdxxxxxxs110abcds01abcd100000
s1abcdxxxxxxxs111abcds1abcd1000000
  1. This value is produced by taking the two's complement representation of the input value, and inverting all bits after the sign bit if the value is negative.
  2. Signed magnitude representation

Where s is the sign bit, s is its inverse (i.e. positive values are encoded with MSB = s = 1), and bits marked x are discarded. Note that the first column of the table uses different representation of negative values than the third column. So for example, input decimal value −21 is represented in binary after bit inversion as 1000000010100, which maps to 00001010 (according to the first row of the table). When decoding, this maps back to 1000000010101, which is interpreted as output value −21 in decimal. Input value +52 (0000000110100 in binary) maps to 10011010 (according to the second row), which maps back to 0000000110101 (+53 in decimal).

This can be seen as a floating-point number with 4 bits of mantissa m (equivalent to a 5-bit precision), 3 bits of exponent e and 1 sign bit s, formatted as seeemmmm with the decoded linear value y given by formula

which is a 13-bit signed integer in the range ±1 to ±(212  26). Note that no compressed code decodes to zero due to the addition of 0.5 (half of a quantization step).

In addition, the standard specifies that all resulting even bits (LSB is even) are inverted before the octet is transmitted. This is to provide plenty of 0/1 transitions to facilitate the clock recovery process in the PCM receivers. Thus, a silent A-law encoded PCM channel has the 8 bit samples coded 0xD5 instead of 0x80 in the octets.

When data is sent over E0 (G.703), MSB (sign) is sent first and LSB is sent last.

ITU-T STL[3] defines the algorithm for decoding as follows (it puts the decoded values in the 13 most significant bits of the 16-bit output data type).

void            alaw_expand(lseg, logbuf, linbuf)
  long            lseg;
  short          *linbuf;
  short          *logbuf;
{
  short           ix, mant, iexp;
  long            n;

  for (n = 0; n < lseg; n++)
  {
    ix = logbuf[n] ^ (0x0055);	/* re-toggle toggled bits */

    ix &= (0x007F);		/* remove sign bit */
    iexp = ix >> 4;		/* extract exponent */
    mant = ix & (0x000F);	/* now get mantissa */
    if (iexp > 0)
      mant = mant + 16;		/* add leading '1', if exponent > 0 */

    mant = (mant << 4) + (0x0008);	/* now mantissa left justified and */
    /* 1/2 quantization step added */
    if (iexp > 1)		/* now left shift according exponent */
      mant = mant << (iexp - 1);

    linbuf[n] = logbuf[n] > 127	/* invert, if negative sample */
      ? mant
      : -mant;
  }
}

See also "ITU-T Software Tool Library 2009 User's manual" that can be found at.[4]

μ-law

The μ-law (sometimes referred to as ulaw, G.711Mu, or G.711μ) encoding takes a 14-bit signed linear audio sample in two's complement representation as input, inverts all bits after the sign bit if the value is negative, adds 33 (binary 100001) and converts it to an 8 bit value as follows:

Linear input value
[note 1]
Compressed code
XOR 11111111
Linear output value
[note 2]
s00000001abcdxs000abcds00000001abcd1
s0000001abcdxxs001abcds0000001abcd10
s000001abcdxxxs010abcds000001abcd100
s00001abcdxxxxs011abcds00001abcd1000
s0001abcdxxxxxs100abcds0001abcd10000
s001abcdxxxxxxs101abcds001abcd100000
s01abcdxxxxxxxs110abcds01abcd1000000
s1abcdxxxxxxxxs111abcds1abcd10000000
  1. This value is produced by taking the two's complement representation of the input value, inverting all bits after the sign bit if the value is negative, and adding 33.
  2. Signed magnitude representation. Final result is produced by decreasing the magnitude of this value by 33.

Where s is the sign bit, and bits marked x are discarded.

In addition, the standard specifies that all result bits are inverted before the octet is transmitted. Thus, a silent μ-law encoded PCM channel has the 8 bit samples coded 0xFF instead of 0x00 in the octets.

Adding 33 is necessary so that all values fall into a compression group and it is subtracted back when decoding.

Breaking the encoded value formatted as seeemmmm into 4 bits of mantissa m, 3 bits of exponent e and 1 sign bit s, the decoded linear value y is given by formula

which is a 14-bit signed integer in the range ±0 to ±8031.

Note that 0 is encoded as 0xFF, and −1 is encoded as 0x7F, but when decoded back the result is 0 in both cases.

G.711.0

G.711.0, also known as G.711 LLC, utilizes lossless data compression to reduce the bandwidth usage by as much as 50 percent.[5] The Lossless compression of G.711 pulse code modulation standard was approved by ITU-T in September 2009.[6][7]

G.711.1

G.711.1 is an extension to G.711, published as ITU-T Recommendation G.711.1 in March 2008. Its formal name is Wideband embedded extension for G.711 pulse code modulation.[7][8][9]

G.711.1, allows the addition of narrowband and/or wideband (16000 samples/s) enhancements, each at 25% of the bitrate of the (included) base G.711 bitstream, leading to data rates of 64, 80 or 96 kbit/s.

G.711.1 is compatible with G.711 at 64 kbit/s,[10] hence an efficient deployment in existing G.711-based voice over IP (VoIP) infrastructures is foreseen. The G.711.1 coder can encode signals at 16 kHz with a bandwidth of 50–7000 Hz at 80 and 96 kbit/s, and for 8-kHz sampling the output may produce signals with a bandwidth ranging from 50 up to 4000 Hz, operating at 64 and 80 kbit/s.[8]

The G.711.1 encoder creates an embedded bitstream structured in three layers corresponding to three available bit rates: 64, 80 and 96 kbit/s. The bitstream does not contain any information on which layers are contained, an implementation would require outband signalling on which layers are available. The three G.711.1 layers are: log companded pulse code modulation (PCM) of the lower band including noise feedback, embedded PCM extension with adaptive bit allocation for enhancing the quality of the base layer in the lower band, and weighted vector quantization coding of the higher band based on modified discrete cosine transformation (MDCT).[8]

Two extensions for G.711.1 are planned in 2010: superwideband extension (bandwidth to 14000 Hz) and lossless bitstream compression.[11]

Licensing

The patents for G.711, released in 1972, have expired, so it may be used without the need for a licence.[1]

gollark: !pw free LyricLy#5695 Bees dispatched.
gollark: ????????/
gollark: !pw on Heavpoot#5118 !pw on 461970193728667648 the potatOS privacy policy is self-writing, esolangs are hard, pastebin is case sensitive now, are you alive?, apiolasers are now unlegal, potatOS cannot be destroyed, so do I, the heavdrone is controlled by SPUDNET
gollark: !pw on 461970193728667648 the potatOS privacy policy is self-writing, esolangs are hard, pastebin is case sensitive now, are you alive?, apiolasers are now unlegal, potatOS cannot be destroyed, so do I, the heavdrone is controlled by SPUDNET
gollark: It's in memory and appears to run an extra task for each ping.

See also

References

  1. "G.711 : Pulse code modulation (PCM) of voice frequencies". www.itu.int. Archived from the original on 2019-06-17. Retrieved 2019-11-11.
  2. "Video/Voice/Speech Codecs". Grandstream=. Retrieved 19 July 2020.
  3. G.191 : Software tools for speech and audio coding standardization. Function alaw_expand in file Software/stl2009/g711/g711.c. Itu.int. Retrieved on 2013-09-18.
  4. G.191 : ITU-T Software Tool Library 2009 User's manual. Itu.int (2010-07-23). Retrieved on 2013-09-18.
  5. ITU-T (2009-07-17). "ITU-T Newslog - Voice codec gets new lossless compression". Archived from the original on 2016-03-03. Retrieved 2010-02-28.
  6. ITU-T. "G.711.0 : Lossless compression of G.711 pulse code modulation". Retrieved 2010-02-28.
  7. Recent Audio/Speech Coding Developments in ITU-T and future trends (PDF), August 2008, retrieved 2010-02-28
  8. ITU-T (2008) G.711.1 : Wideband embedded extension for G.711 pulse code modulation Retrieved on 2009-06-19
  9. Hiwasaki; et al. (2008-08-25), G.711.1: a wideband extension to ITU-T G.711 (PDF), retrieved 2015-06-13
  10. Lapierre; et al. (2008-08-25), Noise shaping in an ITU-T G.711-Interoperable embedded codec (PDF), retrieved 2015-06-13
  11. Nokia Research Center (2009-04-06), Coding standards (PDF), retrieved 2010-03-01
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