# Selection of data in a region of interest in a matrix (with Mathematica)

I am having a (mathematica 8.0.1.0-) problem which I cannot solve by myself. I have measurement data in a matrix, I want to select some of them and then add them up.

To explain my problem better, here an easy example. The data can be produced by a matrix S:

``````S = Table[ -Sin[i/2] - Sin[j/2], {i,20}, {j,20}];
``````

They can be nicely plotted with:

``````xmin = N[Min[S]];
xmax = N[Max[S]];
mycolorfun = Function[ Blend[{Blue,Cyan,Green,Yellow,Red},#] ];
``````

and

``````MatrixPlot[S, PlotRange -> {All,All,All}, AspectRatio -> 1/1,
ColorFunction -> (mycolorfun[ Rescale[ #1{xmin,xmax} ] ]&),
ColorFunctionScaling -> False, MaxPlotPoints -> Automatic,
FrameLabel -> {y,x} ]
``````

Then one should get a picture similar to this one:

Now I want to select the data which are inside of the brown drawn polygon. These data should be added up at the end.

How can I do this? Ok, I could use rectangles and build a sub-matrix by choosing/guessing good start and end indices. Then I just have to build the sum of this sub-matrix. But I would prefer polygons (more precise if we do not argue about little problems with the matrix values which are crossed by the line of the polygon). And I would love it if I could select my region of interest (ROI) directly by “painting” the polygon into the Matrix (no more time consuming choosing/guessing of matrix indices).
Could somebody here help me with my problem? If it is not solvable with mathematica, is there some other program which I could use?

I would be very happy about some help and hints!

-
A point of note, the code blocks require a blank line preceding them, so I fixed it for you. I also reformatted the code a bit and hid the link behind clickable text for readability. – rcollyer Jul 13 '11 at 12:38
Thank you for editing my question! Since I am new here, I had some problems with editing by myself. I try to make it better next time. – partial81 Jul 13 '11 at 16:12
Not a problem. Your new here, and laying out your questions/answers takes practice. – rcollyer Jul 13 '11 at 16:19
Thank you @belisarius and @rcollyer for editing my text. It is really nice to see that my picture is directly in my post now. That makes it more understandable! – partial81 Jul 14 '11 at 9:01

If selecting the area of interest graphically by hand is not a problem, then you could:

First, create an image out of your data, using a visualization which makes it easy for you to select manually afterward:

``````S = Table[-Sin[i/50.] - Sin[j/50.], {i, 400}, {j, 400}];
img = ReliefImage@S
``````

Then use the Front End Graphic Tools to draw the polygon over the region that interests you (right click mouse button):

Finally, make a binary image out of the mask and use it to recover the sum of the pixel inside the polygon:

``````Total[S*ImageData@mask, Infinity]
``````

The whole process looks like this:

EDIT: If you'd like to define your area of interest using a free-hand contour, use the Free-hand line tool instead of polygon. Make sure to increase the width of the stroke so that it is easy to close the contour when drawing. You may do so by moving the Stroke>Thickness slider to the right.

That would look like this:

Then create the mask by filling the inside of the free-hand contour using the function `FillingTransform`, and proceed as before:

-
OMG! That is exactly the solution I have been searching for! Thank you very much! I just made some smaller modifications. For example, I am using my own ColorFunction in the ReliefImage (out of a question of taste) and I am creating an additional matrix to plot my region of interest again. I am doing this with: SROI=MatrixForm[S*ImageData@mask]; Then I reduce the tensor SROI to a matrix with SROImatrix=SROI[[1,All,All]][[All,All,1]]; So I can easily work with the SROImatrix to calculate the sum (Total[SROImatrix,2]) and to plot it. That is working so fine, I almost cannot believe this! – partial81 Jul 14 '11 at 8:49
Ok, it also would be great if one can paint a freehand line and not only a polygon over the region of interest. But at the moment I am failing in filling the inside of a closed freehand line. Since I can adjust the vertices of my polygon afterwards, I do not really care about this problem. LOL, I am just happy that there is such a extremely nice solution :-) Thank you again for this helpful post! – partial81 Jul 14 '11 at 8:58
@user842603 I have edited my answer to show how to use a free-hand contour. This should answer your question. Besides, may I ask you to add the tag image-processing to your question? – Matthias Odisio Jul 14 '11 at 14:46
@user, @Matthias I've added the tag. I'd suggest that the question be slightly reworded to make it clearer that an image-processing answer is required; at the moment, it starts with "I have measurement data in a matrix, I want to select some of them and then add them up." – acl Jul 14 '11 at 15:09
@Matthias Ah, that is also easier than thought (I did not know the FillingTransform)! Thanks for solving this problem too. With the possibility to paint free-hand contours all my needs are perfectly satisfied now. @acl Thank you for adding the tag image-processing to my question. I think it fits to my question, although I had not thought at this key word when I wrote my question. – partial81 Jul 15 '11 at 6:28

Perhaps this:

``````upl = 20;
s = Table[-Sin[i/2] - Sin[j/2], {i, upl}, {j, upl}];

xmin = N[Min[s]]; xmax = N[Max[s]]; mycolorfun =
Function[Blend[{Blue, Cyan, Green, Yellow, Red}, #]];

mp = MatrixPlot[s, PlotRange -> {All, All, All}, AspectRatio -> 1/1,
ColorFunction -> (mycolorfun[Rescale[#1, {xmin, xmax}]] &),
ColorFunctionScaling -> False, MaxPlotPoints -> Automatic,
FrameLabel -> {"y", "x"}];
Manipulate[
{{x1, y1}, {x2, y2}} =
Floor /@ {{p1[[1]], upl - p1[[2]]}, {p2[[1]], upl - p2[[2]]}};
mp,
{{p1, {1, 1}}, Locator}, {{p2, {19, 19}}, Locator}]

Dynamic[{{x1, y1}, {x2, y2}}]
Dynamic[N@s[[y2 ;; y1, x1 ;; x2]] // MatrixForm]
``````

which produces things like with the part of the matrix updated live as you move the locators.

To create polygons instead, just add more locators. Selecting the part of the matrix is then more complicated and it depends on how you want things output.

-
Thank you acl (I hope you like Dresden; do you speak German too?) for his detailed answer. I tried your suggestion, and it even worked for my real, big (2048 x 2048) matrices. Adding more locators is simple (and it is great that you can readout their coordinates/indices so easily), but you are right: Selecting the part of the matrix in which I am interested in, is then really more complicated. Since I have read your answer, I am thinking and trying to find a solution for more than two locators (and with it for pentagons and hexagons and so on) but I have not had a good idea until now. – partial81 Jul 13 '11 at 16:16
I just can tell you, that I think that a hexagon should be always good enough for me to enclose the regions of interest in my matrix. As output I could imagine that I produce a new matrix (stretched by the 4 of the 6 locators (or even more) which have the minimum and maximum indices). The parts of the new matrix which are outside of the region of interest could be filled with 0. So, the sum of the events would be correctly calculated if I use this new matrix. But I really have no idea how I can implement this. – partial81 Jul 13 '11 at 16:17
@user Yes, if you select a polygonal region it is not so simple to extract the relevant elements, and using them is probably also cumbersome. Perhaps you can ask another, separate and more specific, question on this here. [Dresden is very nice by the way, thanks :)] – acl Jul 13 '11 at 21:15
Thanks again for your reply and your efforts. Have you seen Matthias Odisios suggestion? I did not expect that there is such a nice way to solve my problem. But I think I will also use some parts of your suggestion for some other problems. Nice to hear that you like Dresden, I should visit this city one day too ;-) – partial81 Jul 14 '11 at 9:07

If I got it right, you need to find a connected component of similar pixel values.

You can use image processing functions:

First Binarize the image using an appropriate threshold. Then use MorphologicalComponents that will identify all connected regions. Finally, you can extract the image data and use `Pick` to get the pixel values corresponding to the component you are interested in.

EDIT: Here's an illustration of the concept:

-
but if he wanted automated selection, wouldn't it be better to do it directly on the original matrix? using eg `Position`? – acl Jul 13 '11 at 14:54
Thank you Szabolcs for this totally different approach. Unfortunately, I cannot upload one of the matrix-plots with the real measurement data at the moment. There one could see that I would get into troubles if I try your solution. The reason is simple: there are several areas which have similar pixel values. For my analysis, I have to count the number of events in these areas separately. Sorry for not mentioning that earlier! – partial81 Jul 13 '11 at 16:14
@user, look at the second example for `MorphologicalComponents`, and you'll see that each disconnected region is treated separately. This implies, that you just have to find a threshold for `Binarize` that will create these disconnected regions in your data. Then, use `MorphologicalComponents` to number each region. – rcollyer Jul 13 '11 at 16:37
Thanks again for the reply and your efforts. I think I will follow Matthias Odisios suggestion. Somehow he made something like a very fruitful mix out of yours and acls suggestions. – partial81 Jul 14 '11 at 9:03
@user Finally got the time to add an example calculation. – Szabolcs Jul 14 '11 at 12:34