Hi Abdulrahman Alsalmi,
To calculate the Modulation Transfer Function (MTF) from an image of a thermal imager with a half-moon target, you need to follow a series of steps that involve image processing techniques. Below is a high-level outline of the MATLAB code for the same:
% Assuming 'thermalImage' is your loaded thermal image with a half-moon target
% Step 1: Find the size (resolution) of the image
[rows, columns, ~] = size(thermalImage);
% Step 2: Find the edge response function (ESF)
% This usually involves finding the edge of the half-moon target and then
% extracting the pixel values across that edge.
% Convert the image to grayscale if it is not already
grayImage = rgb2gray(thermalImage);
% Find edges using an edge detection algorithm like 'Sobel'
edges = edge(grayImage, 'sobel');
% You may need to process 'edges' to find the actual edge of the half-moon
% For simplicity, let's assume 'edgeRow' is the row index of the half-moon edge
edgeRow = findEdgeRow(edges); % You need to implement this function
% Extract the edge response function (ESF)
ESF = double(grayImage(edgeRow, :));
% Step 3: Find the line spread function (LSF) from the ESF
% The LSF is the derivative of the ESF
LSF = diff(ESF);
% Step 4: Graph the MTF from the LSF
% The MTF is the magnitude of the Fourier Transform of the LSF
MTF = abs(fft(LSF));
% Normalize the MTF by its maximum value
MTF = MTF / max(MTF);
% Create a frequency axis for plotting
frequencyAxis = linspace(0, columns/2, numel(MTF)/2);
% Plot the MTF
figure;
plot(frequencyAxis, MTF(1:numel(MTF)/2));
xlabel('Spatial Frequency (cycles per pixel)');
ylabel('MTF');
title('Modulation Transfer Function');
You can refer to the following documentation to know more about the functions used:
- rgb2gray: https://in.mathworks.com/help/matlab/ref/rgb2gray.html
- edge: https://in.mathworks.com/help/images/ref/edge.html
Best Regards,
Abhishek Chakram
