Coding gain

In coding theory, telecommunications engineering and other 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).

Example[edit]

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).

Power-limited regime[edit]

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

\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\left({\sqrt {\frac {2\gamma _{c}(A)E_{b}}{N_{0}}}}\right),

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

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[edit]

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[edit]

In the bandwidth-limited regime ( $\rho >2~b/2D$ , 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