Calculating the Bit error rate (BER) for a Visible Light Communication (VLC)

27 views (last 30 days)
I am trying to calculate the bit error rate (BER) for a visible light communication LED source.
Based on the code of this link Number of bit errors and bit error rate (BER) I calculate the BER. Unfortunately, the results that I got were unreasonable as shown below:
their results like below:
Why is my estimated BER so far off from the theoretical one?
Is there anyone who calculated the BER for a VLC before? May I get an assistance, please?
close all;
clear variables;
clc;
%% Simulation Parameters
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%% Main Simulation Parameters %%%%
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%-------------------------%
% NUMBER OF LIGHT SOURCES %
%-------------------------%
N_t = 1; % Number of light sources
% Set the simulation parameters.
M = 64; % Modulation order
k = log2(M); % Bits per symbol
EbNoVec = (5:15)'; % Eb/No values (dB)
numSymPerFrame = 100; % Number of QAM symbols per frame
n = 34560; % Number of transmitted bits
N_iter = 1;
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%% AP Parameters %%%%
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%------------------------%
% LIGHT SOURCES GEOMETRY %
%------------------------%
L = 20; W = 20; H = 3; % Length, width and height of the room (m)
theta_half = 30;
m = -log(2)./log(cosd(theta_half)); % Lambertian order of emission
coord_t = [0 0 0]; % Positions of the light sources
n_t_LED = [0, 0, -1]; n_t_LED = n_t_LED/norm(n_t_LED); % Normalized normal vector of each light source
n_t = repmat(n_t_LED, N_t, 1); % Normalized normal vectors of the light sources
%-------------------------------------%
% LIGHT SOURCES ELECTRICAL PARAMETERS %
%-------------------------------------%
P_LED = 2.84; % Average electrical power consummed by each light source (W)
param_t = {coord_t, n_t, P_LED, m};
%%
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%%%% Rx Parameters %%%%
%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%%
%--------------------------%
% PHOTODETECTOR PARAMETERS %
%--------------------------%
A_det = 1e-4; % Photoreceiver sensitive area (m²)
FOV = 60*pi/180; % Fielf-of-view of the photoreceiver
T_s = 1; % Gain of the optical filter (ignore if not used)
index = 1.5; % Refractive index of the Rx concentrator/lens (ignore if not used)
G_Con = (index^2)/sin(FOV); % Gain of an optical concentrator; ignore if no lens is used
n_r = [0, 0, 1]; % Normal vector of the photoreceiver
n_r = n_r/norm(n_r); % Normal vector of the photoreceiver (normalized)
%---------------------------%
% RECEIVER PLANE PARAMETERS %
%---------------------------%
step = 0.5; % Distance between each receiving point (m)
X_r = -L/2:step:L/2; % Range of Rx points along x axis
Y_r = -W/2:step:W/2; % Range of Rx points along y axis
N_rx = length(X_r); N_ry = length(Y_r); % Number of reception points simulated along the x and y axis
z_ref = 0.85; % Height of the receiver plane from the ground (m)
z = z_ref-H; % z = -1.65; % Height of the Rx points ("-" because coordinates system origin at the center of the ceiling)
if( abs(z) > H )
fprintf('ERROR: The receiver plane is out of the room.\n');
return
end
param_r = {A_det, n_r, FOV}; % Vector of the Rx parameters used for channel simulation
berEst = zeros(size(EbNoVec));
for n = 1:length(EbNoVec)
snrdB = EbNoVec(n) + 10*log10(k);
numErrs = 0;
numBits = 0;
while numErrs < 200 && numBits < 1e7
data = randi([0 1],numSymPerFrame,k);
dataSym = bi2de(data);
txSignal = qammod(dataSym,M);
% LOS received optical power calculation
H0_LOS = zeros(N_rx,N_ry,N_t);
P_rec_dbm = zeros(N_rx,N_ry,N_t);
%rxSignal = zeros(N_t,length(txSignal));
T = param_t{1}(1,:);
P_t = param_t{3};
for r_x = 1:N_rx
for r_y = 1:N_ry
for i_t = 1:N_t
x = X_r(r_x); y = Y_r(r_y);
R = [x,y,z];
v_tr = (R-T)./norm(R-T);
d_tr = sqrt(dot(R-T,R-T));
phi = 0;
psi = 0;
H0_LOS(r_x,r_y,i_t)= (m+1)*A_det/(2*pi*d_tr^2)*cosd(phi)^m*cosd(psi);
end
end
end
rx = (txSignal).*(H0_LOS(r_x,r_y,i_t)*G_Con*T_s); % Photocurrent produced by the PD without noise (A)
rxSignal = awgn(rx,snrdB,'measured');
rxSym = qamdemod(rxSignal,M);
dataOut = de2bi(rxSym,k);
nErrors = biterr(data,dataOut);
numErrs = numErrs + nErrors;
numBits = numBits + numSymPerFrame*k;
end
% Estimate the BER
berEst(n) = numErrs/numBits;
end
%Determine the theoretical BER curve by using the berawgn function.
berTheory = berawgn(EbNoVec,'qam',M);
P_r_LOS = P_t.*H0_LOS.*T_s.*G_Con;
P_rec_dBm = 10*log10(P_r_LOS*1000);
% Plot the estimated and theoretical BER data. The estimated BER data
% points are well aligned with the theoretical curve.
figure
semilogy(EbNoVec,berEst,'*')
hold on
semilogy(EbNoVec,berTheory)
grid
legend('Estimated BER','Theoretical BER')
xlabel('Eb/No (dB)')
ylabel('Bit Error Rate')
  6 Comments
kim zheng cho
kim zheng cho on 20 Dec 2022
that's very kind of you.Likewise if i have done i will send you as well. Wish you good luck......

Sign in to comment.

Answers (0)

Community Treasure Hunt

Find the treasures in MATLAB Central and discover how the community can help you!

Start Hunting!