Line 67: Line 67:
 
<math>P(im2|R) = \frac{(\frac{1}{3})(.8)}{.5} = \frac{.8}{1.5}</math>
 
<math>P(im2|R) = \frac{(\frac{1}{3})(.8)}{.5} = \frac{.8}{1.5}</math>
  
<math>\therefore P(im_1|\{R,G,B\}) = \frac{P(im_1|R)P(\{G,B\}|im_1)}{P(\{R,G,B\})} = \frac{(\frac{.3}{1.5})(.1)(.6)}{(\frac{1}{1.5})((.3)(.1)(.6) + (.8)(.1)(.1) + (.4)(.2)(.4))} = \frac{(.3)(.1)(.6)}{((.3)(.1)(.6) + (.8)(.1)(.1) + (.4)(.2)(.4))}</math>
+
<math>\therefore P(im_1|\{R,G,B\}) = \frac{P(im_1|R)P(\{G,B\}|im_1)}{P(\{R,G,B\})} = \frac{(\frac{.3}{1.5})(.1)(.6)}{(\frac{1}{1.5})((.3)(.1)(.6) + (.8)(.1)(.1) + (.4)(.2)(.4))} = \frac{(.3)(.1)(.6)}{((.3)(.1)(.6) + (.8)(.1)(.1) + (.4)(.2)(.4))} \approx .31</math>
  
 
'''(c)'''
 
'''(c)'''
  
Here we're looking for:<math></math>
+
Here we're looking for:
  
<math>P(R|\{R,G,B\}) = P(R|im_1)P(im_1|\{R,G,B\}) + P(R|im_2)P(im_2|\{R,G,B\}) + P(R|im_3)P(im_3|\{R,G,B\})</math>
+
<math>P(im2|R) = \frac{(\frac{1}{3})(.8)}{.5} = \frac{.8}{1.5}</math>
  
  
Since we calculated the normalized probability that the sequence {R,G,B} was derived from image 1 (and it's easy enough to see how we would find this for the other two images), now we just need to need calculate the following equation for
+
<math>= \frac{(.3)(.3)(.1)(.6)}{((.3)(.1)(.6) + (.8)(.1)(.1) + (.4)(.2)(.4))} + \frac{(.8)(.8)(.1)(.1)}{((.3)(.1)(.6) + (.8)(.1)(.1) + (.4)(.2)(.4))} + \frac{(.4)(.4)(.2)(.4)}{((.3)(.1)(.6) + (.8)(.1)(.1) + (.4)(.2)(.4))}</math>
 
+
All we need to find is <math style='inline>P</math>. It should be clear that we did the bulk of this problem in '''(b)'''.
+
  
 +
<math>\approx (.3)(.31) + (.8)(.14) + (.4)(.55) = .425</math>
  
 
  Although I'm confident in these answers, I don't understand why order does not matter for the calculation of '''(b)'''.
 
  Although I'm confident in these answers, I don't understand why order does not matter for the calculation of '''(b)'''.

Revision as of 18:26, 27 January 2013


Pixel = 'Pic'ture 'El'ement

Smiley 3 1 6.PNG

Above is an RGB image with a pixel color distribution of roughly the following:

red = 30%
green = 10%
blue = 60%

Therefore, if we were to randomly sample a pixel color from the image ('im1'), we would have the following probabilities of sampling each color:

$ P(R|im_1) = .3 $
$ P(G|im_1) = .1 $
$ P(B|im_1) = .6 $

Given the following probabilities of two more RGB images with the same number of pixels as im1, solve (a), (b), and (c). (Note: we assume for this problem that pixels are sampled with replacement.)

$ P(R|im_1) = .3 $     $ P(R|im_2) = .8 $     $ P(R|im_3) = .4 $
$ P(G|im_1) = .1 $     $ P(G|im_2) = .1 $     $ P(G|im_3) = .2 $    } where R = red pixel sampled, etc, and im1 = pixel sampled is in image 1, etc.
$ P(B|im_1) = .6 $     $ P(B|im_2) = .1 $     $ P(B|im_3) = .4 $
(a) Assuming that we have an equal probability of sampling a pixel from each image (ie $ P(im_1) = P(im_2) = P(im_3) = 1/3 $,
    what is the probability that a sampled red pixel came from image 3? 
(b) Now, assume that after the first pixel is sampled, our remaining pixel samples must come from the same image as the first
    pixel.  Given that we first sampled a red pixel, then a green and blue, what is the probability that we have been sampling
    from image 1?
(c) Given the same {R,G,B} scenario as (b), and where pixels after the first must come from the same image, what is the
    probability that our next (fourth) pixel sampled is red?

Solution

(a)

We have been asked to find P(im3|R):

$ P(im_3|R) = \frac{P(im_3 \cap R)}{P(R)} $ from conditional probability $ = \frac{P(im_3)P(R|im_3)}{P(R)} $ from Bayes' rule

Because the numerators of the previous equation are both given, we are only left to find P(R). Since the sample space is partitioned into disjoint subsets im1, im2, and im3 (see graphic below), we can use the law of total probability:

$ P(R) = \sum_{i=1}^{3} P(im_i)P(R|im_i) = \frac{1}{3}(.3 + .8 + .4) = .5 $

$ \therefore P(im_3|R) = \frac{(\frac{1}{3})(.4)}{.5} = \frac{.4}{1.5} $

Visualization of Our Sample Space

(b)

We know that once an image has been sampled from, future color order does not matter since pixels are sampled with replacement. However, one might think that does matter for the first pixel (when the image number is not yet known). However, after performing the following calculations, it surprisingly turns out that order does not matter for this. (I don't know why.)

$ P(im_1|\{R,G,B\}) = \frac{P(im_1|R)P(\{G,B\}|im_1)}{P(\{R,G,B\})} $

The calculation of $ P(\{R,G,B\}) $ is defined similarly to the numerator. That is:

$ P(\{R,G,B\}) = \sum_{i=1}^{3} P(im_i|R)P(\{G,B\}|im_i) $

Since $ P(\{G,B\}|im_i) $ decomposes into $ P(G|im_i)P(B|im_i) $ due to independence, the only terms we are missing are P(im1|R) and P(im2|R). However, we calculated this for image 3 in (a). Using the same method:

$ P(im1|R) = \frac{(\frac{1}{3})(.3)}{.5} = \frac{.3}{1.5} $

$ P(im2|R) = \frac{(\frac{1}{3})(.8)}{.5} = \frac{.8}{1.5} $

$ \therefore P(im_1|\{R,G,B\}) = \frac{P(im_1|R)P(\{G,B\}|im_1)}{P(\{R,G,B\})} = \frac{(\frac{.3}{1.5})(.1)(.6)}{(\frac{1}{1.5})((.3)(.1)(.6) + (.8)(.1)(.1) + (.4)(.2)(.4))} = \frac{(.3)(.1)(.6)}{((.3)(.1)(.6) + (.8)(.1)(.1) + (.4)(.2)(.4))} \approx .31 $

(c)

Here we're looking for:

$ P(im2|R) = \frac{(\frac{1}{3})(.8)}{.5} = \frac{.8}{1.5} $


$ = \frac{(.3)(.3)(.1)(.6)}{((.3)(.1)(.6) + (.8)(.1)(.1) + (.4)(.2)(.4))} + \frac{(.8)(.8)(.1)(.1)}{((.3)(.1)(.6) + (.8)(.1)(.1) + (.4)(.2)(.4))} + \frac{(.4)(.4)(.2)(.4)}{((.3)(.1)(.6) + (.8)(.1)(.1) + (.4)(.2)(.4))} $

$ \approx (.3)(.31) + (.8)(.14) + (.4)(.55) = .425 $

Although I'm confident in these answers, I don't understand why order does not matter for the calculation of (b).
Perhaps my notation of the conditional probabilities is inaccurate (e.g. I'm not comfortable with events like {R,G,B}).

Back to first bonus point opportunity, ECE302 Spring 2013

Alumni Liaison

Ph.D. 2007, working on developing cool imaging technologies for digital cameras, camera phones, and video surveillance cameras.

Buyue Zhang