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I'm supposed to be writing a for loop which does the following: Using the singular vectors (columns of Ur etc. and rows of VrT etc.) corresponding to the largest n singular values create new R, G and B matrices of the same size as the original image (500 x 375)

here is what I have so far

from PIL import Image
from Image import new
from numpy import *
import numpy as np
from scipy.linalg import svd

r, g, b = im.split()
R = np.array(r.getdata())
R = np.asmatrix(R)
R = np.reshape(R, (375, 500), order = 'F')
G = np.array(g.getdata())
G = np.asmatrix(G)
G = np.reshape(G, (375, 500), order = 'F')
B = np.array(b.getdata())
B = np.asmatrix(B)
B = np.reshape(B, (375, 500), order = 'F')
Ur, Sr, VrT = svd(R.T, full_matrices=False)
Ug, Sg, VgT = svd(G.T, full_matrices=False)
Ub, Sb, VbT = svd(R.T, full_matrices=False)
R1 = np.dot(Ur, diag(Sr))
R1 = np.dot(R1, VrT)
G1 = np.dot(Ug, diag(Sg))
G1 = np.dot(G1, VgT)
B1 = np.dot(Ub, diag(Sb))
B1 = np.dot(B1, VbT)
R1 = np.around([R1])
G1 = np.around([G1])
B1 = np.around([B1])
R1 = np.uint8(R1)
G1 = np.uint8(G1)
B1 = np.uint8(B1)
R1 = R1.T
G1 = G1.T
B1 = B1.T
R1 = R1.flatten('F')
G1 = G1.flatten('F')
B1 = B1.flatten('F')
R1 = tuple(R1)
G1 = tuple(G1)
B1 = tuple(B1)
zipped = zip(R1,G1,B1)
newim = im.putdata(zipped,1,0)
im.show(newim)

for i in xrange(5):
N = array([200,100,50,10,1])
newUr = Ur[0:N[i], : ]
newSr = newSr[0:N[i]]
newVrT = VrT[ 0:N[i], :]
newUg = Ug[0:N[i], : ]
newSg = Sg[0:N[i]]
newVgT = VgT[ 0:N[i], :]
newUb = Ub[0:N[i], : ]
newSb = Sb[0:N[i]]
newVbT = VbT[ 0:N[i],:]
newR = dot(dot(newUr, diag(newSr), newVrT))
newG = dot(dot(newUg, diag(newSg), newVgT))
newB = dot(dot(newUb, diag(newSb), newVbT))
zipped = zip(newR,newG,newB)
newim = im.putdata(zipped,1,0)
im.show()
i = i+1
share|improve this question
    
the shapes of U, S, and VT are (500,375) (375,) and (375,375) –  Chris C Nov 13 '12 at 2:21
    
we are asked to make S a diagonal matrix where the n*n terms have values and every other entry is 0 –  Chris C Nov 13 '12 at 2:22
    
in the end newU.shape is supposed to be (500,N) newS.shape is (N,N) and newVT.shape is (N,375) –  Chris C Nov 13 '12 at 2:33
    
Make yourself a favor and change your np.array/np.asmatrix/np.reshape routine as a single command np.reshape(x.getdata(), (375,500), order='F').view(np.matrix) –  Pierre GM Nov 13 '12 at 11:24

1 Answer 1

You could find the n greatest values in S using np.argsort. For example,

In [31]: S = np.array([1,3,5,2,4,7])

In [32]: np.argsort(S)[-3:]
Out[32]: array([4, 2, 5])

In [33]: idx = np.argsort(S)[-3:]

In [34]: S[idx]
Out[34]: array([4, 5, 7])

import Image
import numpy as np
linalg = np.linalg
N = 10

def ngreatest(arr, n):
    idx = np.argsort(arr)[-n:]
    return idx

img = Image.open(filename).convert('RGB')
arr = np.asarray(img)
r, g, b = np.rollaxis(arr, axis = -1)

Ur, Sr, VrT = linalg.svd(r, full_matrices=False)
idx = ngreatest(Sr, N)
Sr = np.diag(Sr[idx])
VrT = VrT[idx]
Ur = Ur[:,idx]

print(Ur.shape, Sr.shape, VrT.shape)
share|improve this answer
    
do i start with just for or is anything supposed to follow? –  Chris C Nov 13 '12 at 6:22
    
how do i find the smallest then if this gives me the n greatest values? –  Chris C Nov 13 '12 at 7:42

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