I am using matlab to try and investigate farfield radiation patterns of antennas. Basically, I am trying to plot 3 different functions of x, and their fourier transform. I have worked out how to write a script that calculates the far field of three different distributions and plots them.

However, in the script I use a variable 'a'. I would like to be able to update the variable in real time using a slider. When the slider is moved, a is changed, and all the calculations that use a are recalculated, and the plots refreshed.

I believe I have to change my script into a function, and use a callback. I have been trying various things, I have managed to get a slider which updates the value of a, but it doesn't recalculate and replot.

My script is as follows. This is my first time using matlab so it might be a bit crazy.

```
% ------- APERTURE FUNCTIONS -------
x = -5 : 0.001 : 5; % Define the x axis
a = 1; % Define aperture size
f1 = zeros(size(x)); % Initialise an aperture function
f2 = zeros(size(x)); % Initialise an aperture function
f3 = zeros(size(x)); % Initialise an aperture function
% Declaration of functions
for i = 1 : length(x)
if abs(x(i)) <= a/2
f1(i) = 1; % Rectangular Function
f2(i) = cos(pi*x(i)/a); % Cosine Function
f3(i) = 1-2*abs(x(i))/a; % Triangular Function
else
f1(i) = 0;
f2(i) = 0;
f3(i) = 0;
end
end
figure;
subplot(2,3,1); plot(x,f1,'LineWidth',2);
ylim([0 1.5])
xlabel('x (m)');
ylabel('f1(x)');
title('Rectangular Aperture Function');
subplot(2,3,2); plot(x,f2,'LineWidth',2);
ylim([0 1.5])
xlabel('x (m)');
ylabel('f3(x)');
title('Cosine Aperture Function');
subplot(2,3,3); plot(x,f3,'LineWidth',2);
ylim([0 1.5])
xlabel('x (m)');
ylabel('f2(x)');
title('Triangular Aperture Function');
%------------- FARFIELD CALCULATION ------------
u = [-4 : 0.01 : 4]; % Define the u axis
G1 = zeros(size(u)); % Initialise a Farfield function
G2 = zeros(size(u)); % Initialise a Farfield function
G3 = zeros(size(u)); % Initialise a Farfield function
for i = 1 : length(u)
G1(i) = trapz(x,f1.*exp(-j*2*pi*u(i)*x)); % Fourier Transform
G2(i) = trapz(x,f2.*exp(-j*2*pi*u(i)*x)); % Fourier Transform
G3(i) = trapz(x,f3.*exp(-j*2*pi*u(i)*x)); % Fourier Transform
end
subplot(2,3,4);
plot(u,20*log(abs(G1)),'LineWidth',2);
axis([-4 4 -200 0]);
xlabel('u');
ylabel('|G(u)|');
title('Far-Field Magnitude of a Rectangular Function');
subplot(2,3,5);
plot(u,20*log(abs(G2)),'LineWidth',2);
axis([-4 4 -200 0]);
xlabel('u');
ylabel('|G(u)|');
title('Far-Field Magnitude of a Cosine Function');
subplot(2,3,6);
plot(u,20*log(abs(G3)),'LineWidth',2);
axis([-4 4 -200 0]);
xlabel('u');
ylabel('|G(u)|');
title('Far-Field Magnitude of a Triangular Function');
```