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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). | |||
==Example== | |||
If the uncoded [[BPSK]] system in [[AWGN]] environment has a [[Bit error rate]] (BER) of <math>10^{-2}</math> at the SNR level 4[[decibel|dB]], and the corresponding coded (''e.g.'', [[BCH code|BCH]]) system has the same BER at an SNR level of 2.5dB, then we say the ''coding gain'' = 4dB-2.5dB = 1.5dB, due to the code used (in this case BCH). | |||
==Power-limited regime== | |||
In the ''power-limited regime'' (where the nominal [[spectral efficiency]] <math>\rho \le 2</math> [b/2D or b/s/Hz], ''i.e.'' the domain of binary signaling), the effective coding gain <math>\gamma_{eff}(A)</math> of a signal set <math>A</math> at a given target error probability per bit <math>P_b(E)</math> is defined as the difference in dB between the <math>E_b/N_0</math> required to achieve the target <math>P_b(E)</math> with <math>A</math> and the <math>E_b/N_0</math> required to achieve the target <math>P_b(E)</math> with 2-[[Pulse-amplitude modulation|PAM]] or (2×2)-[[Quadrature amplitude modulation|QAM]] (''i.e.'' no coding). The nominal coding gain <math>\gamma_c(A)</math> is defined as | |||
: <math>\gamma_c(A) = {d^2_{min}(A) \over 4E_b}.</math> | |||
This definition is normalized so that <math>\gamma_c(A) = 1</math> for 2-PAM or (2×2)-QAM. If the average number of nearest neighbors per transmitted bit <math>K_b(A)</math> is equal to one, the effective coding gain <math>\gamma_{eff}(A)</math> is approximately equal to the nominal coding gain <math>\gamma_c(A)</math>. However, if <math>K_b(A)>1</math>, the effective coding gain <math>\gamma_{eff}(A)</math> is less than the nominal coding gain <math>\gamma_c(A)</math> by an amount which depends on the steepness of the <math>P_b(E)</math> ''vs.'' <math>E_b/N_0</math> curve at the target <math>P_b(E)</math>. This curve can be plotted using the [[union bound]] estimate (UBE) | |||
: <math>P_b(E) \approx K_b(A)Q\sqrt(2\gamma_c(A)E_b/N_0),</math> | |||
where <math>Q(\cdot)</math> denotes the [[error function|Gaussian probability of error function]]. | |||
For the special case of a binary [[linear block code]] <math>C</math> with parameters <math>(n,k,d)</math>, the nominal spectral efficiency is <math>\rho = 2k/n </math> 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 <math>P_b(E) \approx 10^{-5}</math> for [[Reed-Muller code]]s of length <math>n \le 64</math>: | |||
{| class="wikitable" | |||
! Code !! <math>\rho</math> !! <math>\gamma_c</math> !! <math>\gamma_c</math> (dB) !! <math>K_b</math> !! <math>\gamma_{eff}</math> (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'' (<math>\rho > 2b/2D</math>, ''i.e.'' the domain of non-binary signaling), the effective coding gain <math>\gamma_{eff}(A)</math> of a signal set <math>A</math> at a given target error rate <math>P_s(E)</math> is defined as the difference in dB between the <math>SNR_{norm}</math> required to achieve the target <math>P_s(E)</math> with <math>A</math> and the <math>SNR_{norm}</math> required to achieve the target <math>P_s(E)</math> with M-[[Pulse-amplitude modulation|PAM]] or (M×M)-[[Quadrature amplitude modulation|QAM]] (''i.e.'' no coding). The nominal coding gain <math>\gamma_c(A)</math> is defined as | |||
: <math>\gamma_c(A) = {(2^\rho - 1)d^2_\min (A) \over 6E_s}.</math> | |||
This definition is normalized so that <math>\gamma_c(A) = 1</math> for M-PAM or (M×M)-QAM. The UBE becomes | |||
: <math>P_s(E) \approx K_s(A)Q\sqrt(3\gamma_c(A)SNR_{norm}),</math> | |||
where <math>K_s(A)</math> is the average number of nearest neighbors per two dimensions. | |||
==See also== | |||
*[[Channel capacity]] | |||
*[[Eb/N0]] | |||
==References== | |||
[http://ocw.mit.edu MIT OpenCourseWare], 6.451 Principles of Digital Communication II, Lecture Notes sections 5.3, 5.5, 6.3, 6.4 | |||
[[Category:Coding theory]] | |||
[[Category:Error detection and correction]] |
Revision as of 16:41, 4 January 2013
Template:No footnotes 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).
Example
If the uncoded BPSK system in AWGN environment has a Bit error rate (BER) of at the SNR level 4dB, and the corresponding coded (e.g., BCH) system has the same BER at an SNR level of 2.5dB, then we say the coding gain = 4dB-2.5dB = 1.5dB, due to the code used (in this case BCH).
Power-limited regime
In the power-limited regime (where the nominal spectral efficiency [b/2D or b/s/Hz], i.e. the domain of binary signaling), the effective coding gain of a signal set at a given target error probability per bit is defined as the difference in dB between the required to achieve the target with and the required to achieve the target with 2-PAM or (2×2)-QAM (i.e. no coding). The nominal coding gain is defined as
This definition is normalized so that for 2-PAM or (2×2)-QAM. If the average number of nearest neighbors per transmitted bit is equal to one, the effective coding gain is approximately equal to the nominal coding gain . However, if , the effective coding gain is less than the nominal coding gain by an amount which depends on the steepness of the vs. curve at the target . This curve can be plotted using the union bound estimate (UBE)
where denotes the Gaussian probability of error function.
For the special case of a binary linear block code with parameters , the nominal spectral efficiency is 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 for Reed-Muller codes of length :
Bandwidth-limited regime
In the bandwidth-limited regime (, i.e. the domain of non-binary signaling), the effective coding gain of a signal set at a given target error rate is defined as the difference in dB between the required to achieve the target with and the required to achieve the target with M-PAM or (M×M)-QAM (i.e. no coding). The nominal coding gain is defined as
This definition is normalized so that for M-PAM or (M×M)-QAM. The UBE becomes
where is the average number of nearest neighbors per two dimensions.
See also
References
MIT OpenCourseWare, 6.451 Principles of Digital Communication II, Lecture Notes sections 5.3, 5.5, 6.3, 6.4