Expanding my comments into a full answer;

@prototoast's answer is elegant, but since medians for the R, G and B values of each pixel are calculated separately, the output image will look very strange.

To get a well-defined median that makes visual sense, the easiest thing to do is cast the images to black-and-white before you try to take the median.

`rgb2gray()`

from the Image Processing toolbox will do this in a way that preserves the luminance of each pixel while discarding the hue and saturation.

*EDIT:*

If you want to define the "RGB median" as "the middle value in cartesian coordinates" this is easy enough to do for three images.

Consider a single pixel with three possible choices for the median colour, `C1=(r1,g1,b1)`

, `C2=(r2,g2,b2)`

, `C3=(r3,g3,b3)`

. Generally these form a triangle in 3D space.

Take the Pythagorean distance between the three colours: `D1_2=abs(C2-C1)`

, `D2_3=abs(C3-C2)`

, `D1_3=abs(C3-C1)`

.

Pick the "median" to be the colour that has lowest distance to the other two. Defining `D1=D1_2+D1_3`

, etc. and taking `min(D1,D2,D3)`

should work, courtesy of the Triangle Inequality. Note the degenerate cases: equilateral triangle (C1, C2, C3 equidistant), line (C1, C2, C3 linear with each other), or point (C1=C2=C3).

Note that this simple way of thinking about a 3D median is hard to extend to more than three images, because "the median" of a set of four or more 3D points is a bit harder to define.

**Edit 2**

For defining the "median" of N points as the centre of the smallest sphere that encloses them in 3D space, you could try:

- Find the two points N1 and N2 in {N} that are furthest apart. The distance between N1 and N2 is the diameter of the smallest sphere that encloses all the points. (Proof: Any smaller and the sphere would not be able to enclose both N1 and N2 at the same time.)
- The median is then halfway between N1 and N2:
`M = (N1+N2)/2`

.

*Edit 3*: The above only works if no three points are equidistant. Maybe you need to ask math.stackexchange.com?

*Edit 4*: Wikipedia delivers again! Smallest circle problem, Bounding sphere.

`numpy`

/`scipy`

. ;) (Not like I can talk: I did my thesis in MATLAB.) – Li-aung Yip Feb 18 '12 at 17:18