2d planar array use AF and Deconvolution metod

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WJDNJ 2024 年 3 月 21 日

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https://jp.mathworks.com/matlabcentral/answers/2097066-2d-planar-array-use-af-and-deconvolution-metod

回答済み: Balavignesh 2024 年 4 月 4 日

clear;
lambda = 1; 
d = lambda / 2; 
search = (-90:0.1:90) * (pi/180);
phi_search = linspace(-1, 1, length(search)); 
theta_search = linspace(-1, 1, length(search));
target_phi =  -20 * (pi / 180); %xaxis
target_theta = 10 * (pi / 180); %yaxis
array = [1, 2, 3, 4, 5, 6, 7, 8, 9, 10]; %linear array
%array = [1, 2, 4, 6, 7, 8, 10] %sparse array
[~, target_index_phi] = min(abs(phi_search - target_phi));
[~, target_index_theta] = min(abs(theta_search - target_theta)); 
targets = zeros(length(theta_search), length(phi_search));
targets(target_index_theta, target_index_phi) = 1;
Beam = zeros(length(phi_search), length(theta_search));
meas = zeros(length(phi_search), length(theta_search));
for x = 1:length(phi_search)
    for y = 1:1:length(theta_search)
        sum_AF = 0;
        resp1 = 0;
        resp2 = 0;
        resp3 = 0;
        for n = array
            for m = array 
                
                psi_x = 2*pi/lambda * d * phi_search(x);
                psi_y = 2*pi/lambda * d * theta_search(y);
                phase_shift = exp(1i * (n * psi_x + m * psi_y));
                
                sum_AF = sum_AF + sum(exp(1i * n * 2*pi/lambda * d * phi_search(x) + 1i * m *  2*pi/lambda * d * theta_search(y)));
                resp1 = resp1 + sum(exp(1i * n * 2*pi/lambda * d * ( target_theta - phi_search(x) ) + 1i * m * 2*pi/lambda * d * ( target_phi -theta_search(y))));
            end
        end  
        Beam(x, y) = abs(sum_AF);
        meas(x, y) = abs(resp1);
    end
end

I made a beam pattern and response using the target (theta,phi) I specified.

I want to show the target, beam pattern, and response through the contour function, and finally I want to restore the target using Deconvolution, but the result is not coming out well. What should I do? And I want to compare the difference between a linear array and a sphere array. When it's a linear array, the target should be restored well.

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Answer 1

Balavignesh 2024 年 4 月 4 日

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この回答への直接リンク

https://jp.mathworks.com/matlabcentral/answers/2097066-2d-planar-array-use-af-and-deconvolution-metod#answer_1436351

MATLAB Online で開く

Hi WJDNJ,

It is my understanding that you have already created arrays for the beam pattern (Beam) and the response (meas), and you have marked the target in the 'targets' array and now you would like to visualize these using contour plots in MATLAB.

However, deconvolution can be a bit tricky in the context of signal processing and beamforming. There could be several factors affecting the results including the choice of deconvolution algorithm, noise, resolution limits, etc... Since your case involves 2D deconvolution, you might need to use 'deconvlucy' or similar, which can handle 2D arrays. However, direct application might not yield perfect results due to the complexities mentioned.

For comparing the performance between a linear array and a sparse array, you can run your simulation with both configurations and observe the differences in the beam pattern, response, and the efficacy of target restoration. Comparing linear and sparse arrays will highlight trade-offs between array complexity, resolution, and directivity.

I have included the code for plotting the contours below your code for your review. Please take a moment to examine it.

clear;
lambda = 1;
d = lambda / 2;
search = (-90:0.1:90) * (pi/180);
phi_search = linspace(-1, 1, length(search));
theta_search = linspace(-1, 1, length(search));
target_phi =  -20 * (pi / 180); %xaxis
target_theta = 10 * (pi / 180); %yaxis
array = [1, 2, 3, 4, 5, 6, 7, 8, 9, 10]; %linear array
%array = [1, 2, 4, 6, 7, 8, 10] %sparse array
[~, target_index_phi] = min(abs(phi_search - target_phi));
[~, target_index_theta] = min(abs(theta_search - target_theta));
targets = zeros(length(theta_search), length(phi_search));
targets(target_index_theta, target_index_phi) = 1;
Beam = zeros(length(phi_search), length(theta_search));
meas = zeros(length(phi_search), length(theta_search));
for x = 1:length(phi_search)
    for y = 1:1:length(theta_search)
        sum_AF = 0;
        resp1 = 0;
        resp2 = 0;
        resp3 = 0;
        for n = array
            for m = array
                psi_x = 2*pi/lambda * d * phi_search(x);
                psi_y = 2*pi/lambda * d * theta_search(y);
                phase_shift = exp(1i * (n * psi_x + m * psi_y));
                sum_AF = sum_AF + sum(exp(1i * n * 2*pi/lambda * d * phi_search(x) + 1i * m *  2*pi/lambda * d * theta_search(y)));
                resp1 = resp1 + sum(exp(1i * n * 2*pi/lambda * d * ( target_theta - phi_search(x) ) + 1i * m * 2*pi/lambda * d * ( target_phi -theta_search(y))));
            end
        end
        Beam(x, y) = abs(sum_AF);
        meas(x, y) = abs(resp1);
    end
end
% Plot the beam pattern
figure;
contour(phi_search * (180/pi), theta_search * (180/pi), Beam', 50);
xlabel('Phi (degrees)');
ylabel('Theta (degrees)');
title('Beam Pattern');
colorbar;
% Plot the response
figure;
contour(phi_search * (180/pi), theta_search * (180/pi), meas', 50);
xlabel('Phi (degrees)');
ylabel('Theta (degrees)');
title('Response');
colorbar;
% Plot the target
figure;
contour(phi_search * (180/pi), theta_search * (180/pi), targets', 1);
xlabel('Phi (degrees)');
ylabel('Theta (degrees)');
title('Target');
colorbar;