I am trying to convert some code from Matlab to Python, but I am unfamiliar with a considerable amount of the Matlab syntax and functionality. I have managed to do a some of the conversion using the PIL and Numpy python package, but I was hoping someone would be able to explain what is going on with some elements of this code.
clear all;close all;clc; % Set gray scale to 0 for color images. Will need more memory GRAY_SCALE = 1 % The physical mask placed close to the sensor has 4 harmonics, therefore % we will have 9 angular samples in the light field nAngles = 9; cAngles = (nAngles+1)/2; % The fundamental frequency of the cosine in the mask in pixels F1Y = 238; F1X = 191; %Cosine Frequency in Pixels from Calibration Image F12X = floor(F1X/2); F12Y = floor(F1Y/2); %PhaseShift due to Mask In-Plane Translation wrt Sensor phi1 = 300; phi2 = 150; %read 2D image disp('Reading Input Image...'); I = double(imread('InputCones.png')); if(GRAY_SCALE) %take green channel only I = I(:,:,2); end %make image odd size I = I(1:end,1:end-1,:); %find size of image [m,n,CH] = size(I); %Compute Spectral Tile Centers, Peak Strengths and Phase for i = 1:nAngles for j = 1:nAngles CentY(i,j) = (m+1)/2 + (i-cAngles)*F1Y; CentX(i,j) = (n+1)/2 + (j-cAngles)*F1X; %Mat(i,j) = exp(-sqrt(-1)*((phi1*pi/180)*(i-cAngles) + (phi2*pi/180)*(j-cAngles))); end end Mat = ones(nAngles,nAngles); % 20 is because we cannot have negative values in the mask. So strenght of % DC component is 20 times that of harmonics Mat(cAngles,cAngles) = Mat(cAngles,cAngles) * 20; % Beginning of 4D light field computation % do for all color channel for ch = 1:CH disp('================================='); disp(sprintf('Processing channel %d',ch)); % Find FFT of image disp('Computing FFT of 2D image'); f = fftshift(fft2(I(:,:,ch))); %If you want to visaulize the FFT of input 2D image (Figure 8 of %paper), uncomment the next 2 lines % figure;imshow(log10(abs(f)),);colormap gray; % title('2D FFT of captured image (Figure 8 of paper). Note the spectral replicas'); %Rearrange Tiles of 2D FFT into 4D Planes to obtain FFT of 4D Light-Field disp('Rearranging 2D FFT into 4D'); for i = 1: nAngles for j = 1: nAngles FFT_LF(:,:,i,j) = f( CentY(i,j)-F12Y:CentY(i,j)+F12Y, CentX(i,j)-F12X:CentX(i,j)+F12X)/Mat(i,j); end end clear f k = sqrt(-1); for i = 1:nAngles for j = 1:nAngles shift = (phi1*pi/180)*(i-cAngles) + (phi2*pi/180)*(j-cAngles); FFT_LF(:,:,i,j) = FFT_LF(:,:,i,j)*exp(k*shift); end end disp('Computing inverse 4D FFT'); LF = ifftn(ifftshift(FFT_LF)); %Compute Light-Field by 4D Inverse FFT clear FFT_LF if(ch==1) LF_R = LF; elseif(ch==2) LF_G = LF; elseif(ch==3) LF_B = LF; end clear LF end clear I %Now we have 4D light fiel disp('Light Field Computed. Done...'); disp('=========================================='); % Digital Refocusing Code % Take a 2D slice of 4D light field % For refocusing, we only need the FFT of light field, not the light field disp('Synthesizing Refocused Images by taking 2D slice of 4D Light Field'); if(GRAY_SCALE) FFT_LF_R = fftshift(fftn(LF_R)); clear LF_R else FFT_LF_R = fftshift(fftn(LF_R)); clear LF_R FFT_LF_G = fftshift(fftn(LF_G)); clear LF_G FFT_LF_B = fftshift(fftn(LF_B)); clear LF_B end % height and width of refocused image H = size(FFT_LF_R,1); W = size(FFT_LF_R,2); count = 0; for theta = -14:14 count = count + 1; disp('==============================================='); disp(sprintf('Calculating New ReFocused Image: theta = %d',theta)); if(GRAY_SCALE) RefocusedImage = Refocus2D(FFT_LF_R,[theta,theta]); else RefocusedImage = zeros(H,W,3); RefocusedImage(:,:,1) = Refocus2D(FFT_LF_R,[theta,theta]); RefocusedImage(:,:,2) = Refocus2D(FFT_LF_G,[theta,theta]); RefocusedImage(:,:,3) = Refocus2D(FFT_LF_B,[theta,theta]); end str = sprintf('RefocusedImage%03d.png',count); %Scale RefocusedImage in [0,255] RefocusedImage = RefocusedImage - min(RefocusedImage(:)); RefocusedImage = 255*RefocusedImage/max(RefocusedImage(:)); %write as png image clear tt for ii = 1:CH tt(:,:,ii) = fliplr(RefocusedImage(:,:,ii)'); end imwrite(uint8(tt),str); disp(sprintf('Refocused image written as %s',str)); end
Here is the Refocus2d function:
function IOut = Refocus2D(FFTLF,theta) [m,n,p,q] = size(FFTLF); Theta1 = theta(1); Theta2 = theta(2); cTem = floor(size(FFTLF)/2) + 1; % find the coordinates of 2D slice [XX,YY] = meshgrid(1:n,1:m); cc = (XX - cTem(2))/size(FFTLF,2); cc = Theta2*cc + cTem(4); dd = (YY - cTem(1))/size(FFTLF,1); dd = Theta1*dd + cTem(3); % Resample 4D light field along the 2D slice v = interpn(FFTLF,YY,XX,dd,cc,'cubic'); %set nan values to zero idx = find(isnan(v)==1); disp(sprintf('Number of Nans in sampling = %d',size(idx,1))) v(isnan(v)) = 0; % take inverse 2D FFT to get the image IOut = real(ifft2(ifftshift(v)));
If anyone could help it would be greatly appreciated.
Thanks in advance
Apologies: Here is a brief description of what the code does:
The code reads in an image of a light field, and with prior knowledge of the plenoptic mask it we store the relevant nAngles and the fundamental frequencies of the mask and the phase shift, these are used to find multiple spectral replicas of the image.
Once the image is read in and the green channel is extracted we perform a Fast Fourier Transform on the image, and start taking slices from the image matrix that represent one of the spectral replicas.
We then take the Inverse Fourier Transform of all the spectral replicas to produce a the light field.
The Refocus2d function, then takes a 2 dimensional slice of the 4d data to recreate a refocused image.
The things I am struggling with specifically are:
FFT_LF(:,:,i,j) = f( CentY(i,j)-F12Y:CentY(i,j)+F12Y, CentX(i,j)-F12X:CentX(i,j)+F12X)/Mat(i,j);
We are taking a slice from the Matrix f, but where is that data in FFT_LF? What does (:,:,i,j) mean? Is it a multidimensional array?
and what does the size function return:
[m,n,p,q] = size(FFTLF);
Just a brief explanation of how this translates to python would be a great help.
Thanks everyone so far :)