The Average of the Matrix G with the dimension (M,n) that I'm repeating 3 times in a loop so I'll have 3 matrices of G (M,n) and I want to take the Average of these 3 matrices so I can get only one matrix of G(M,n) represent the Average of them)

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Matthew Worker
Matthew Worker on 17 May 2021
Edited: Rena Berman on 16 Dec 2021
clc; clear;
M=5; n=3; freq = 28e9; lambda = physconst('LightSpeed')/freq; d_BS=lambda/2; %Inter-antenna separation atthe BS. d_IRS=lambda/2; %Inter-element separation at the IRS.
G = zeros(M,n);
for l=1:3
theta_2=-pi+(2*pi*rand); %AoA [-pi,pi]
phi_2=(-pi+(2*pi*rand))/2; %AoA [-pi/2,pi/2]
theta_1=-pi+(2*pi*rand); %AoD [-pi,pi]
phi_1=(-pi+(2*pi*rand))/2; %AoD [-pi/2,pi/2]
for mi=1:M
for ni=1:n
e = exp(1i*2*pi/lambda*((mi-1)*d_BS*sin(theta_1)*sin(phi_1)+(ni-1)*d_IRS*sin(theta_2)*sin(phi_2)));
Beta = 1; % path loss factor
G(mi,ni) = 1/sqrt(2).*sqrt(Beta).*e
end
end
end

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Accepted Answer

DGM
DGM on 17 May 2021
Edited: DGM on 17 May 2021
Something like this
M=5;
n=3;
freq = 28e9;
lambda = physconst('LightSpeed')/freq;
d_BS=lambda/2; %Inter-antenna separation atthe BS.
d_IRS=lambda/2; %Inter-element separation at the IRS.
G = zeros(M,n,3); % allocate big enough for all copies
for l=1:3
theta_2=-pi+(2*pi*rand); %AoA [-pi,pi]
phi_2=(-pi+(2*pi*rand))/2; %AoA [-pi/2,pi/2]
theta_1=-pi+(2*pi*rand); %AoD [-pi,pi]
phi_1=(-pi+(2*pi*rand))/2; %AoD [-pi/2,pi/2]
for mi=1:M
for ni=1:n
e = exp(1i*2*pi/lambda*((mi-1)*d_BS*sin(theta_1)*sin(phi_1)+(ni-1)*d_IRS*sin(theta_2)*sin(phi_2)));
Beta = 1; % path loss factor
G(mi,ni,l) = 1/sqrt(2).*sqrt(Beta).*e; % write just this page
end
end
end
G = mean(G,3) % average along dim3

More Answers (1)

Sulaymon Eshkabilov
Sulaymon Eshkabilov on 17 May 2021
in your exercise, the loop is not a good one. You can use vectorization instead. E.g.:
theta_2=-pi+(2*pi*rand(3,1)); %AoA [-pi,pi]
phi_2=(-pi+(2*pi*rand(3,1)))/2; %AoA [-pi/2,pi/2]
theta_1=-pi+(2*pi*rand(3,1)); %AoD [-pi,pi]
phi_1=(-pi+(2*pi*rand(3,1)))/2; %AoD [-pi/2,pi/2]
M_theta2=mean(theta_2);
M_phi2=mean(phi_2);
M_theta1=mean(theta_1);
M_phi1=mean(phi_1);

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