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I have a problem which I try to solve with mathematica. I am having a list with x and y coordinates from a position measurement (and also with z values of the quantity which was measured at each point). So, my list starts with list={{-762.369,109.998,0.915951},{-772.412,109.993,0.923894},{-777.39, 109.998, 0.918108},...} (x,y,z). Out of some reasons, I have to fill all these x,y, and z-values into a matrix. That would be easy if I have for each y-coordinate the same amount of x-coordinates (lets say 80), then I could use Partition[list,80] which produces a matrix with 80 columns (and some rows whose number is given by the number of y-coordinates with the same value).
Unfortunately, it is not so easy, the number of x-coordinates for each y is not strictly constant, as can be seen from the attached ListPlot. xy coordinates with ListPlot Can anybody give me some suggestions, how I could fill each point of this plot / each x-y-(and z-) coordinate of my list into a matrix?

To explain better what I want to have, I indicated in the attached picture a matrix. There one can see that almost every point of my plot would fall into a cell of a matrix, only some cells would stay empty. I used in the plot the color red for the points whose x coordinates are ascending in my list and blue for the points whose x coordinate are descending in my list (the positions are measured along a meander line). Perhaps this kind of order can be useful to solve to problem... Here a link to my coordinates, perhaps this helps.

Well, I hope I explained my question well enough. I would appreciate every help much!

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It'd be nice if you could provide the dataset. If I got it, you need the matrix elements to be z values, and the matrix indices should approximately correspond to x and y, right? (Also, it's better not to use variable names starting with capital letter to avoid conflict with builtins/packages. List is a builtin!) –  Szabolcs Jul 26 '11 at 15:56
    
Thanks for the quick reply. Sorry for the capital letter in list, I used it to make it better readable but did not think at the conflict problem (I edited). Well, I would love to provide the dataset here but I do not know how to upload a file... Sorry! Therefore, I hope it is ok, when I am sending a file to your email address. Yes, the matrix indices should approximately correspond to x and y. But my aim is to have (x,y,z) in each matrix element, I do not want to use interpolation of my values. –  partial81 Jul 26 '11 at 16:43
1  
What do you want to do with your matrix? –  belisarius Jul 26 '11 at 16:47
    
@partial81 You can upload the datafile e.g. to ge.tt and include a link –  Szabolcs Jul 26 '11 at 18:48
    
@Szabolcs Thanks a lot for the email reply and your answer here! Your suggestion is great! After some hours of sleep I will try to understand it better ;-) Thanks also for the hint with the upload. I did not know this page. I edited my question again and provide the link to a file with my x- and y-coordinates now. So other user can use them in the case they want to try applying yours or others suggestion. –  partial81 Jul 26 '11 at 21:25

1 Answer 1

up vote 6 down vote accepted

The basic idea behind this solution is:

  • all points seem to lie on a lattice, but it's not precisely a square lattice (it's slanted)
  • so let's find the basis vectors of the lattice, then all (most?) points will be approximate integer linear combinations of the basis vectors
  • the integer "coordinates" of the points along the basis vectors will be the matrix indices for the OP's matrix

(The OP emailed me the datafile. It consists of {x,y} point coordinates.)

Read in the data:

data = Import["xy.txt", "Table"];

Find the nearest 4 points to each point, and notice that they lie about distance 5 away both horizontally and vertically:

nf = Nearest[data];

In:= # - data[[100]] & /@ nf[data[[100]], 5]

Out= {{0., 0.}, {-4.995, 0.}, {5.003, 0.001}, {-0.021, 5.003}, {0.204, -4.999}}

ListPlot[nf[data[[100]], 5], PlotStyle -> Red, 
  PlotMarkers -> Automatic, AspectRatio -> Automatic]

enter image description here

Generate the difference vectors between close points and keep only those that are about length 5:

vv = Select[
      Join @@ Table[(# - data[[k]] & /@ nf[data[[k]], 5]), {k, 1, Length[data]}], 
      4.9 < Norm[#] < 5.1 &
     ];

Average the vectors out by directions they can point to, and keep two "good" ones (pointing "up" or to the "right").

In:= Mean /@ GatherBy[vv, Round[ArcTan @@ #, 0.25] &]

Out= {{0.0701994, -4.99814}, {-5.00094, 0.000923234}, {5.00061, -4.51807*10^-6},  
      {-4.99907, -0.004153}, {-0.0667469, 4.9983}, {-0.29147, 4.98216}}

In:= {u1, u2} = %[[{3, 5}]]

Out= {{5.00061, -4.51807*10^-6}, {-0.0667469, 4.9983}}

Use one random point as the point of origin, so the coordinates along the basis vectors u1 and u2 will be integers:

translatedData = data[[100]] - # & /@ data;

Let's find the integer coordinates and see how good they are (how far they are from actual integers):

In:= integerIndices = LinearSolve[Transpose[{u1, u2}], #] & /@ translatedData ;

In:= Max[Abs[integerIndices - Round[integerIndices]]]

Out= 0.104237

In:= ListPlot[{integerIndices, Round[integerIndices]}, PlotStyle -> {Black, Red}]

enter image description here

All points lie close to the integer approximations.

Offset the integer coordinates so they're all positive and can be used as matrix indices, then gather the elements into a matrix. I put the coordinates in a point object in order not to confuse SparseArray:

offset = Min /@ Transpose[Round[integerIndices]]
offset = {1, 1} - offset

result = 
 SparseArray[
  Thread[(# + offset & /@ Round[integerIndices]) -> point @@@ data]]

result = Normal[result] /. {point -> List, 0 -> Null}

And we finally have a matrix result where each element is a coordinate-pair! (I was sloppy doing 0 -> Null here to mark missing elements: it's important that data contained no exact 0s.)

MatrixForm[result[[1 ;; 10, 1 ;; 5]]]

enter image description here

EDIT

Just for fun, let's look at the deviations of points from the precise integer lattice sites:

lattice = #1 u1 + #2 u2 & @@@ Round[integerIndices];

delta = translatedData - lattice;
delta = # - Mean[delta] & /@ delta;

ListVectorPlot[Transpose[{lattice, delta}, {2, 1, 3}], VectorPoints -> 30]

enter image description here

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Nice idea with finding the basis vectors. What breaks if you do not use point with data in the sparse array? (writing from iPad, so no mathematica to try) –  acl Jul 26 '11 at 19:43
    
@acl, I didn't spend time to figure out how it works exactly ... what I knew before is that one can create a (sparse) array with SparseArray[{ {row, column} -> element }]. If element is a List, SparseArray gives me a 1D array. I guess it's because SparseArray[{index, index, ...} -> {element, element, ...}] is also a valid syntax. –  Szabolcs Jul 26 '11 at 19:46
    
@Sza Curious! I did almost the same thing here stackoverflow.com/questions/4917896/… –  belisarius Jul 26 '11 at 22:21
    
@Szabolcs Thank you for your solution and the explanations. They are really fine! It is just a bit difficult for me to understand all details because your code is far above my programming skills. But anyway, I got the idea and understand much of the solution! And it seems that I can adapt your solution well to my real data. Thank you again! –  partial81 Jul 27 '11 at 12:39

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