Coding gain

Last updated March 20, 2019

In coding theory and related engineering problems, coding gain is the measure in the difference between the signal-to-noise ratio (SNR) levels between the uncoded system and coded system required to reach the same bit error rate (BER) levels when used with the error correcting code (ECC).

Coding theory study of the properties of codes and their fitness for a specific application

Coding theory is the study of the properties of codes and their respective fitness for specific applications. Codes are used for data compression, cryptography, error detection and correction, data transmission and data storage. Codes are studied by various scientific disciplines—such as information theory, electrical engineering, mathematics, linguistics, and computer science—for the purpose of designing efficient and reliable data transmission methods. This typically involves the removal of redundancy and the correction or detection of errors in the transmitted data.

Signal-to-noise ratio is a measure used in science and engineering that compares the level of a desired signal to the level of background noise. SNR is defined as the ratio of signal power to the noise power, often expressed in decibels. A ratio higher than 1:1 indicates more signal than noise.

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Example

If the uncoded BPSK system in AWGN environment has a bit error rate (BER) of 10⁻² at the SNR level 4 dB, and the corresponding coded (e.g., BCH) system has the same BER at an SNR of 2.5 dB, then we say the coding gain = 4 dB − 2.5 dB = 1.5 dB, due to the code used (in this case BCH).

The decibel is a unit of measurement used to express the ratio of one value of a power or field quantity to another on a logarithmic scale, the logarithmic quantity being called the power level or field level, respectively. It can be used to express a change in value or an absolute value. In the latter case, it expresses the ratio of a value to a fixed reference value; when used in this way, a suffix that indicates the reference value is often appended to the decibel symbol. For example, if the reference value is 1 volt, then the suffix is "V", and if the reference value is one milliwatt, then the suffix is "m".

In coding theory, the BCH codes or Bose–Chaudhuri–Hocquenghem codes form a class of cyclic error-correcting codes that are constructed using polynomials over a finite field. BCH codes were invented in 1959 by French mathematician Alexis Hocquenghem, and independently in 1960 by Raj Bose and D. K. Ray-Chaudhuri. The name Bose–Chaudhuri–Hocquenghem arises from the initials of the inventors' surnames.

Power-limited regime

In the power-limited regime (where the nominal spectral efficiency $\rho \leq 2$ [b/2D or b/s/Hz], i.e. the domain of binary signaling), the effective coding gain $\gamma _{\mathrm {eff} }(A)$ of a signal set $A$ at a given target error probability per bit $P_{b}(E)$ is defined as the difference in dB between the $E_{b}/N_{0}$ required to achieve the target $P_{b}(E)$ with $A$ and the $E_{b}/N_{0}$ required to achieve the target $P_{b}(E)$ with 2-PAM or (2×2)-QAM (i.e. no coding). The nominal coding gain $\gamma _{c}(A)$ is defined as

Spectral efficiency, spectrum efficiency or bandwidth efficiency refers to the information rate that can be transmitted over a given bandwidth in a specific communication system. It is a measure of how efficiently a limited frequency spectrum is utilized by the physical layer protocol, and sometimes by the media access control.

Pulse-amplitude modulation (PAM), is a form of signal modulation where the message information is encoded in the amplitude of a series of signal pulses. It is an analog pulse modulation scheme in which the amplitudes of a train of carrier pulses are varied according to the sample value of the message signal. Demodulation is performed by detecting the amplitude level of the carrier at every single period.

Quadrature amplitude modulation (QAM) is the name of a family of digital modulation methods and a related family of analog modulation methods widely used in modern telecommunications to transmit information. It conveys two analog message signals, or two digital bit streams, by changing (modulating) the amplitudes of two carrier waves, using the amplitude-shift keying (ASK) digital modulation scheme or amplitude modulation (AM) analog modulation scheme. The two carrier waves of the same frequency are out of phase with each other by 90°, a condition known as orthogonality and as quadrature. Being the same frequency, the modulated carriers add together, but can be coherently separated (demodulated) because of their orthogonality property. Another key property is that the modulations are low-frequency/low-bandwidth waveforms compared to the carrier frequency, which is known as the narrowband assumption.

\gamma _{c}(A)={\frac {d_{\min }^{2}(A)}{4E_{b}}}.

This definition is normalized so that $\gamma _{c}(A)=1$ for 2-PAM or (2×2)-QAM. If the average number of nearest neighbors per transmitted bit $K_{b}(A)$ is equal to one, the effective coding gain $\gamma _{\mathrm {eff} }(A)$ is approximately equal to the nominal coding gain $\gamma _{c}(A)$ . However, if $K_{b}(A)>1$ , the effective coding gain $\gamma _{\mathrm {eff} }(A)$ is less than the nominal coding gain $\gamma _{c}(A)$ by an amount which depends on the steepness of the $P_{b}(E)$ vs. $E_{b}/N_{0}$ curve at the target $P_{b}(E)$ . This curve can be plotted using the union bound estimate (UBE)

P_{b}(E)\approx K_{b}(A)Q{\sqrt {\frac {2\gamma _{c}(A)E_{b}}{N_{0}}}},

where Q is the Gaussian probability-of-error function.

In mathematics, the error function is a special function (non-elementary) of sigmoid shape that occurs in probability, statistics, and partial differential equations describing diffusion. It is defined as:

For the special case of a binary linear block code $C$ with parameters $(n,k,d)$ , the nominal spectral efficiency is $\rho =2k/n$ and the nominal coding gain is kd/n.

Example

The table below lists the nominal spectral efficiency, nominal coding gain and effective coding gain at $P_{b}(E)\approx 10^{-5}$ for Reed–Muller codes of length $n\leq 64$ :

Code	$\rho$	$\gamma _{c}$	$\gamma _{c}$ (dB)	$K_{b}$	$\gamma _{\mathrm {eff} }$ (dB)
[8,7,2]	1.75	7/4	2.43	4	2.0
[8,4,4]	1.0	2	3.01	4	2.6
[16,15,2]	1.88	15/8	2.73	8	2.1
[16,11,4]	1.38	11/4	4.39	13	3.7
[16,5,8]	0.63	5/2	3.98	6	3.5
[32,31,2]	1.94	31/16	2.87	16	2.1
[32,26,4]	1.63	13/4	5.12	48	4.0
[32,16,8]	1.00	4	6.02	39	4.9
[32,6,16]	0.37	3	4.77	10	4.2
[64,63,2]	1.97	63/32	2.94	32	1.9
[64,57,4]	1.78	57/16	5.52	183	4.0
[64,42,8]	1.31	21/4	7.20	266	5.6
[64,22,16]	0.69	11/2	7.40	118	6.0
[64,7,32]	0.22	7/2	5.44	18	4.6

Bandwidth-limited regime

In the bandwidth-limited regime ( $\rho >2b/2D$ , i.e. the domain of non-binary signaling), the effective coding gain $\gamma _{\mathrm {eff} }(A)$ of a signal set $A$ at a given target error rate $P_{s}(E)$ is defined as the difference in dB between the $SNR_{\mathrm {norm} }$ required to achieve the target $P_{s}(E)$ with $A$ and the $SNR_{\mathrm {norm} }$ required to achieve the target $P_{s}(E)$ with M-PAM or (M×M)-QAM (i.e. no coding). The nominal coding gain $\gamma _{c}(A)$ is defined as

\gamma _{c}(A)={(2^{\rho }-1)d_{\min }^{2}(A) \over 6E_{s}}.

This definition is normalized so that $\gamma _{c}(A)=1$ for M-PAM or (M×M)-QAM. The UBE becomes

P_{s}(E)\approx K_{s}(A)Q{\sqrt {3\gamma _{c}(A)SNR_{\mathrm {norm} }}},

where $K_{s}(A)$ is the average number of nearest neighbors per two dimensions.

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References

MIT OpenCourseWare, 6.451 Principles of Digital Communication II, Lecture Notes sections 5.3, 5.5, 6.3, 6.4

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Coding gain

Contents

Example

Power-limited regime

Example

Bandwidth-limited regime

See also

Related Research Articles

References