So I have an array (it's large - 2048x2048), and I would like to do some element wise operations dependent on where they are. I'm very confused how to do this (I was told not to use for loops, and when I tried that my IDE froze and it was going really slow).
Onto the question:
h = aperatureimage h[:,:] = 0 indices = np.where(aperatureimage>1) for True in h: h[index] = np.exp(1j*k*z)*np.exp(1j*k*(x**2+y**2)/(2*z))/(1j*wave*z)
So I have an index, which is (I'm assuming here) essentially a 'cropped' version of my larger aperatureimage array. *Note: Aperature image is a grayscale image converted to an array, it has a shape or text on it, and I would like to find all the 'white' regions of the aperature and perform my operation.
How can I access the individual x/y values of index which will allow me to perform my exponential operation? When I try index[:,None], leads to the program spitting out 'ValueError: broadcast dimensions too large'. I also get array is not broadcastable to correct shape. Any help would be appreciated!
One more clarification: x and y are the only values I would like to change (essentially the points in my array where there is white, z, k, and whatever else are defined previously).
I'm not sure the code I posted above is correct, it returns two empty arrays. When I do this though index = (aperatureimage==1) print len(index)
Actually, nothing I've done so far works correctly. I have a 2048x2048 image with a 128x128 white square in the middle of it. I would like to convert this image to an array, look through all the values and determine the index values (x,y) where the array is not black (I only have white/black, bilevel image didn't work for me). I would then like to take all the values (x,y) where the array is not 0, and multiply them by the h[index] value listed above.
I can post more information if necessary. If you can't tell, I'm stuck.
EDIT2: Here's some code that might help - I think I have the problem above solved (I can now access members of the array and perform operations on them). But - for some reason the Fx values in my for loop never increase, it loops Fy forever....
import sys, os from scipy.signal import * import numpy as np import Image, ImageDraw, ImageFont, ImageOps, ImageEnhance, ImageColor def createImage(aperature, type): imsize = aperature*8 middle = imsize/2 im = Image.new("L", (imsize,imsize)) draw = ImageDraw.Draw(im) box = ((middle-aperature/2, middle-aperature/2), (middle+aperature/2, middle+aperature/2)) import sys, os from scipy.signal import * import numpy as np import Image, ImageDraw, ImageFont, ImageOps, ImageEnhance, ImageColor def createImage(aperature, type): imsize = aperature*8 #Add 0 padding to make it nice middle = imsize/2 # The middle (physical 0) of our image will be the imagesize/2 im = Image.new("L", (imsize,imsize)) #Make a grayscale image with imsize*imsize pixels draw = ImageDraw.Draw(im) #Create a new draw method box = ((middle-aperature/2, middle-aperature/2), (middle+aperature/2, middle+aperature/2)) #Bounding box for aperature if type == 'Rectangle': draw.rectangle(box, fill = 'white') #Draw rectangle in the box and color it white del draw return im, middle def Diffraction(aperaturediameter = 1, type = 'Rectangle', z = 2000000, wave = .001): # Constants deltaF = 1/8 # Image will be 8mm wide z = 1/3. wave = 0.001 k = 2*pi/wave # Now let's get to work aperature = aperaturediameter * 128 # Aperaturediameter (in mm) to some pixels im, middle = createImage(aperature, type) #Create an image depending on type of aperature aperaturearray = np.array(im) # Turn image into numpy array # Fourier Transform of Aperature Ta = np.fft.fftshift(np.fft.fft2(aperaturearray))/(len(aperaturearray)) # Transforming and calculating of Transfer Function Method H = aperaturearray.copy() # Copy image so H (transfer function) has the same dimensions as aperaturearray H[:,:] = 0 # Set H to 0 U = aperaturearray.copy() U[:,:] = 0 index = np.nonzero(aperaturearray) # Find nonzero elements of aperaturearray H[index,index] = np.exp(1j*k*z)*np.exp(-1j*k*wave*z*((index-middle)**2+(index-middle)**2)) # Free space transfer for ap array Utfm = abs(np.fft.fftshift(np.fft.ifft2(Ta*H))) # Compute intensity at distance z # Fourier Integral Method apindex = np.nonzero(aperaturearray) U[index,index] = aperaturearray[index,index] * np.exp(1j*k*((index-middle)**2+(index-middle)**2)/(2*z)) Ufim = abs(np.fft.fftshift(np.fft.fft2(U))/len(U)) # Save image fim = Image.fromarray(np.uint8(Ufim)) fim.save("PATH\Fim.jpg") ftfm = Image.fromarray(np.uint8(Utfm)) ftfm.save("PATH\FTFM.jpg") print "that may have worked..." return if __name__ == '__main__': Diffraction()
You'll need numpy, scipy, and PIL to work with this code.
When I run this, it goes through the code, but there is no data in them (everything is black). Now I have a real problem here as I don't entirely understand the math I'm doing (this is for HW), and I don't have a firm grasp on Python.
U[index,index] = aperaturearray[index,index] * np.exp(1j*k*((index-middle)**2+(index-middle)**2)/(2*z))
Should that line work for performing elementwise calculations on my array?