Magnitude only reconstruction doesn't look correct, am I interpreting this correctly?

I have implemented a method from "Phase retrieval from the magnitude of the Fourier transforms of nonperiodic objects" paper available at: https://pdfs.semanticscholar.org/4796/592751aaa5b316aaefbd5eab09ca51fad580.pdf

in which the authors reconstruct an object by oversampling and then using the magnitude following an HIO iterative process.

Reading the paper the figure section states: "Examples of image reconstruction from the magnitude of the Fourier transforms of complex-valued objects by oversampling;"

When I reconstruct only using the magnitude I get what looks like a blank image. Am I doing this correctly? Did I misinterpret the meaning of the paper?

``````import matplotlib.pyplot as plt
import numpy as np
import scipy.ndimage as nd

numIters = 500

# Pad image to simulate oversampling
initSize = img.shape

# Get initial magnitude
F_mag = np.abs(targetImg)
# Save for plotting later
startMag = np.abs(np.fft.ifft2(np.fft.ifftshift(F_mag)))
startPhase = np.angle(targetImg)

# keep track of where the image is vs the padding

# Paper uses random phase for phase, adding noise here
noise = np.random.normal(0,1.5,(initSize[0], initSize[1]))
source = F_mag * np.exp(1j * (startPhase + noise))

# Shift first then transform for inverse

# Test for proper image
# imgplot = plt.imshow(sourceImg)
# plt.show()

beta=0.8
for i in range(numIters):
print "Progress on: " + str(i) + " Of " + str(numIters)
G_k = np.fft.fftshift(np.fft.fft2(sourceImg))
G_k_phase = np.angle(G_k)
G_k_prime = F_mag * np.exp(1j*G_k_phase)
g_k_prime = np.fft.ifft2(np.fft.ifftshift(G_k_prime))

# In support i.e non negative real and imaginary
real_g_k = np.real(g_k_prime)
imag_g_k = np.imag(g_k_prime)
# x_e_S = np.where(((real_g_k > 0) & (imag_g_k > 0)))
x_e_notS = np.where(((real_g_k <= 0) & (imag_g_k <= 0) & (mask == 1)) | (mask == 0))

tmp = g_k_prime
beta_g_k_prime = beta * g_k_prime[x_e_notS]
tmp[x_e_notS] = sourceImg[x_e_notS] - beta_g_k_prime
sourceImg = tmp

G_k = np.fft.fftshift(np.fft.fft2(sourceImg))
finalMag = np.abs(G_k)
finalMagImg = np.abs(np.fft.ifft2(np.fft.ifftshift(finalMag)))

# Show magnitude plot
plt.title('Input Image'), plt.xticks([]), plt.yticks([])
plt.subplot(232),plt.imshow(np.abs(imgWithNoise))
plt.title('Image with Noise'), plt.xticks([]), plt.yticks([])
plt.subplot(233),plt.imshow(np.abs(sourceImg))
plt.title('Image after HIO'), plt.xticks([]), plt.yticks([])
plt.subplot(234),plt.imshow(startMag)
plt.title('Start Magnitude Spectrum'), plt.xticks([]), plt.yticks([])
plt.subplot(235),plt.imshow(finalMagImg)
plt.title('End Magnitude Spectrum Img'), plt.xticks([]), plt.yticks([])
plt.subplot(236),plt.imshow(finalMag)
plt.title('End Magnitude Spectrum'), plt.xticks([]), plt.yticks([])
plt.show()
``````

Your FinalMagImg is not empty, it has a peak at the top-left corner. Apply `fftshift` to move it to the center, and apply logarithmic mapping to see the rest of the data. This is what an inverse DFT looks like if the phase is all zero.