File:SG RLS LMS chan var.png

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SG_RLS_LMS_chan_var.png(561 × 420 pixels, file size: 12 KB, MIME type: image/png)

Summary

Description
English: Developed according to TU Ilmenau teaching materials. 
clear all; close all; clc 

%% Initialization

% channel parameters
sigmaS = 1; %signal power
sigmaN = 0.01; %noise power

% CSI (channel state information):
% the channel for the transmission of the first NS1 training symbols
channel1 = [0.722 - 0.779i; -0.257 - 0.722i; -0.789 - 1.862i];
% the channel for the transmission of the next NS2 training symbols
channel2 = [-0.831 - 0.661i;-1.071 - 0.961i; -0.551 - 0.311i];

M = 5; % filter order

% step sizes
mu_LMS = [0.01,0.07];
mu_SG = [0.01,0.07];

% symbols / ensembles
NS1 = 500;
NS2 = 500;
NS = NS1+NS2;
NEnsembles = 1000; %number of ensembles

%% Compute Rxx and p

%the maximum index of channel taps (l=0,1...L):
L = length(channel1) - 1;  
H = convmtx(channel1, M-L); %channel matrix (Toeplitz structure)
Rnn = sigmaN*eye(M); %the noise covariance matrix

% Inline functions:
calc_Rxx = @(channel) ...
sigmaS*(convmtx(channel, M-L)*convmtx(channel, M-L)')+sigmaN*eye(M);

calc_p = @(channel) sigmaS*(convmtx(channel,M-L))*[1; zeros(M-L-1, 1)];

Rxx = zeros(M,M,2);
p = zeros(M,2);
A = calc_Rxx(channel1);

Rxx(:,:,1) = calc_Rxx(channel1);
Rxx(:,:,2) = calc_Rxx(channel2);
p(:,1) = calc_p(channel1);
p(:,2) = calc_p(channel2);

% An inline function to calculate MSE(w) for a weight vector w
calc_MSE = @(w, ch) real(w'*Rxx(:,:,ch)*w - w'*p(:, ch) - p(:, ch)'*w + sigmaS);

%% Adaptive Equalization
N_test = 2;
MSE_LMS = zeros(NEnsembles, NS, N_test);
MSE_SG = zeros(NEnsembles, NS, N_test);
MSE_RLS = zeros(NEnsembles, NS, N_test);

for nEnsemble = 1:NEnsembles
	%initial symbols:
	symbols1 = sigmaS*sign(randn(1,NS1));
    symbols2 = sigmaS*sign(randn(1,NS2));
	%received noisy symbols:
	X1 = convmtx(channel1, M-L)*hankel(symbols1(1:M-L),[symbols1(M-L:end),zeros(1,M-L-1)]) + ...
		sqrt(sigmaN)*(randn(M,NS1)+1j*randn(M,NS1))/sqrt(2);

	X2 = convmtx(channel2, M-L)*hankel(symbols2(1:M-L),[symbols2(M-L:end),zeros(1,M-L-1)]) + ...
		sqrt(sigmaN)*(randn(M,NS2)+1j*randn(M,NS2))/sqrt(2); 

	X = [X1, X2];
	symbols = [symbols1, symbols2];
	for n_mu = 1:N_test
		w_LMS = zeros(M,1);
		w_SG = zeros(M,1);
		p_SG = zeros(M,1);
		R_SG = zeros(M);
		for n = 1:NS
			if n <= NS1, curh = 1; else curh = 2; end 
			%% LMS - Least Mean Square
			e = symbols(n) - w_LMS'*X(:,n);
			w_LMS = w_LMS + mu_LMS(n_mu)*X(:,n)*conj(e);
			MSE_LMS(nEnsemble,n,n_mu)= calc_MSE(w_LMS, curh);
			
			%% SG - Stochastic gradient
			R_SG = 1/n*((n-1)*R_SG + X(:,n)*X(:,n)');
			p_SG = 1/n*((n-1)*p_SG + X(:,n)*conj(symbols(n)));
			w_SG = w_SG + mu_SG(n_mu)*(p_SG - R_SG*w_SG);
			MSE_SG(nEnsemble,n,n_mu)= calc_MSE(w_SG, curh);
		end
	end
	
	%RLS - Recursive Least Squares
	lambda_RLS = [0.8; 1]; %forgetting factors
	for n_lambda=1:length(lambda_RLS)
		%Initialize the weight vectors for RLS
		delta = 1; 
		w_RLS = zeros(M,1);
		P = eye(M)/delta; % (n-1)-th iteration, where n = 1,2...
		PI = zeros(M,1); % n-th iteration
		K = zeros(M,1);
		for n=1:NS
			if n <= NS1, curh = 1; else curh = 2; end
			% the recursive process of RLS
			PI = P*X(:,n);
			K = PI/(lambda_RLS(n_lambda)+X(:,n)'*PI);
			ee = symbols(n) - w_RLS'*X(:,n);
			w_RLS = w_RLS + K*conj(ee);
			MSE_RLS(nEnsemble,n,n_lambda)= calc_MSE(w_RLS, curh);
			P = P/lambda_RLS(n_lambda) - K/lambda_RLS(n_lambda)*X(:,n)'*P;
		end
	end
end

%% Wiener Solution
MSE_Wiener(1:NS1) = calc_MSE(Rxx(:,:,1)\p(:,1),1);
MSE_Wiener(NS1+1:NS) = calc_MSE(Rxx(:,:,2)\p(:,2),2);

MSE_LMS_1 = mean(MSE_LMS(:,:,1));
MSE_LMS_2 = mean(MSE_LMS(:,:,2));
MSE_SG_1 = mean(MSE_SG(:,:,1));
MSE_SG_2 = mean(MSE_SG(:,:,2));
MSE_RLS_1 = mean(MSE_RLS(:,:,1));
MSE_RLS_2 = mean(MSE_RLS(:,:,2));

figure(1)
n = 1:NS;
m= [2 4 6 10 30 60 100 300 600 1000];

semilogy(m, MSE_LMS_1(m),'+','linewidth',2, 'color','blue');
hold all;
semilogy(m, MSE_LMS_2(m),'o','linewidth',2, 'color','blue');
semilogy(m, MSE_SG_1(m),'+','linewidth',2, 'color','red');
semilogy(m, MSE_SG_2(m),'o','linewidth',2, 'color','red');
semilogy(m, MSE_RLS_1(m),'+','linewidth',2, 'color','green');
semilogy(m, MSE_RLS_2(m),'o','linewidth',2, 'color','green');

semilogy(n, MSE_Wiener(n), 'color','black','linewidth',2);
semilogy(n, MSE_LMS_1(n),'linewidth',2, 'color','blue');
semilogy(n, MSE_LMS_2(n),'linewidth',2, 'color','blue');
semilogy(n, MSE_SG_1(n),'linewidth',2, 'color','red');
semilogy(n, MSE_SG_2(n),'linewidth',2, 'color','red');
semilogy(n, MSE_RLS_1(n),'linewidth',2, 'color','green');
semilogy(n, MSE_RLS_2(n),'linewidth',2, 'color','green');
grid on
xlabel('Ns');
ylabel('MSE');
title(['LMS, SG, RLS, \sigma_N= ' num2str(sigmaN) ', \sigma_S= '...
    num2str(sigmaS) ', M= ' num2str(M) ', L= ' num2str(L) ]);
legend(['LMS, \mu=' num2str(mu_LMS(1))],['LMS, \mu=' num2str(mu_LMS(2))],...
    ['SG, \mu=' num2str(mu_SG(1))],['SG, \mu=' num2str(mu_SG(2))],...
    ['RLS, \lambda=' num2str(lambda_RLS(1))],['RLS, \lambda=' ...
    num2str(lambda_RLS(2))],'Weiner solution',2);
axis([0 NS 0.002 1])
Date
Source Own work
Author Kirlf

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Captions

The mean square error perofrmance of Least mean squares filter, Stochastic gradient descent and Recursive least squares filter in dependance of training symbols in case of changed during the training procedure channel.

Items portrayed in this file

depicts

inception

2 March 2019

media type

image/png

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Date/TimeThumbnailDimensionsUserComment
current19:05, 15 July 2019Thumbnail for version as of 19:05, 15 July 2019561 × 420 (12 KB)KirlfNoise power are fixed in the signal model.
16:24, 2 March 2019Thumbnail for version as of 16:24, 2 March 2019561 × 420 (12 KB)KirlfUser created page with UploadWizard
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