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Let a circle of known radius be plotted in MATLAB.

Assume a pair of random points whose location has to be determined in terms of coordinates (x1,y1) (x2,y2)..(xn,yn). Pairs should be close to each other. For example T1 and R1 should be near.

As shown in figure, there are four random pairs (T1,R1)..(T4,R4). There coordinates need to be determined wrt to center (0,0).

figure

How can I generate this in MATLAB?

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I am able to generate 4 random pts but finding difficulty in placing other points to form a pair which should be close to the points T1,...T4. –  Ash Jan 31 '13 at 6:47
    
Why can't you just simulate uniform random variables with a lower and upper bound specified around whatever point you're interested in, and then discard any that fall outside your circle? Yes it isn't very elegant, but it'll work, and you shouldn't have to throw out too many simulated observations... –  Colin T Bowers Jan 31 '13 at 6:49
1  
what are the T's and R's ? what makes two random points a "pair", what do you mean by "close" to each other? you need to know how to specify these things accurately. –  bla Jan 31 '13 at 6:51
3  
@HebeleHododo: A perfect edit; thank you! –  Lightness Races in Orbit Jan 31 '13 at 6:58
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Can i do something in this way, like generate 8 points randomly in circle . and then choose pairs by those points which are close to each other. But how to do it using Matlab. –  Ash Jan 31 '13 at 6:58

5 Answers 5

up vote 0 down vote accepted

(Complete edit after the question was edited).

To complete this task, I think that you need to combine the different approaches that have been mentioned before your edit:

  • To generate the centers T1,T2,T3,... in the green torus, use the polar coordinates. (Edit: this turned out to be wrong, rejection sampling must also be used here, otherwise, the distribution is not uniform!)
  • To generate the points R1,R2,R3,... in the circle around T1,T2,T3,... but still in the torus, use the rejection sampling.

With these ingredients, you should be able to do everything you need. Here is the code I wrote:

d=859.23;
D=1432.05;
R=100;
N=400;

% Generate the angle
theta = 2*pi*rand(N,1);

% Generate the radius
r = d + (D-d)*rand(N,1);

% Get the centers of the circles
Tx = r.*cos(theta);
Ty = r.*sin(theta);

% Generate the R points
Rx=zeros(N,1);
Ry=zeros(N,1);
for i=1:N
    while true
        % Try
        alpha = 2*pi*rand();
        rr = R*rand();

        Rx(i) = Tx(i) + rr*cos(alpha);
        Ry(i) = Ty(i) + rr*sin(alpha);

        % Check if in the correct zone
        if ( (Rx(i)*Rx(i) + Ry(i)*Ry(i) > d*d) && (Rx(i)*Rx(i) + Ry(i)*Ry(i) < D*D) )
           break
        end
    end
end

% Display
figure(1);
clf;
angle=linspace(0,2*pi,1000);
plot( d*cos(angle), d*sin(angle),'-b');
hold on;
plot( D*cos(angle), D*sin(angle),'-b');
for i=1:N
    plot(Tx(i),Ty(i),'gs');
    plot(Rx(i),Ry(i),'rx');
    plot([Tx(i) Rx(i)],[Ty(i) Ry(i)],'-k');
end
hold off;
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thank u so much for your help ! :) –  Ash Feb 4 '13 at 6:12
    
This solution cannot provide an uniform distribution. It is only uniform for angle. –  iampat Aug 20 '13 at 0:17
    
@iampat Correct, the density is probably higher close to the center (sorry for the mistake). So, rejection sampling should probably be used here. However, I don't know if I should edit the answer, since the question has been edited and does not correspond to the answer any more. –  Dr_Sam Aug 20 '13 at 6:46
    
You simply can use Gibbs sampling and generate Ti. Then used Ti as the centre and generate another point Ri –  iampat Aug 20 '13 at 18:32

The simplest approach to pick a point from a uniform distribution over a circle with reduce R is using Gibbs sampling. Here is the code:

function [x y] = circular uniform (R)
while true
   x = 2*R*rand() - R
   y = 2*R*rand() - R
   if (x*x + y*y) > R*R
       return
   end
end

The loop runs 4/π times on average.

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let R be radious of (0;0) centered circle.
(x,y) : x^2+y^2<=R^2 (LE) to be inside the circle

x = rand()*2*R - R;  

y should be in interval (-sqrt(R^2 - x^2);+sqrt(R^2 - x^2))
so, let it be

y = rand()*sqrt(R^2 - x^2)*2-sqrt(R^2 - x^2);  

Hope, that's right, i have no matlab to test.
Hope, you'll manage to find close pairs your self.
Ok, i'll spend a bit more time for a hint. To find a random number k in interval [a,b] use

k = rand()*(b-a)+a  

Now it should really help if i still remember the matlab syntaxis. Good luck.

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X can range from -R to +R (assuming it is zero centered) so I think it should be x = rand()*2*R - R ? –  Dan Jan 31 '13 at 7:32
    
of course! :) Remade. –  Pheu Verg Jan 31 '13 at 7:58
2  
Your approach is correct, however it cannot generate random samples from a uniform distribution! –  iampat Jan 31 '13 at 8:20

Here is a low quality solution that is very easy to use with uniformly distributed points. Assuming the number of points is small efficiency should not be a concern, if you want better quality you can use something more powerfull than nearest neighbor:

  1. While you have less than n points: Generate a random point
  2. If it is in the circle, store it else go to step 1
  3. While there are unpaired points: check which point is nearest to the first unpaired point, make them a pair

As a result most pairs should be good, but some can be really really bad. I would recommend you to try it and perhaps add a step 4 with k-opt or some other local search if required. And if you really have little points (e.g. less than 20) you can of course just calculate all distances and find the optimum matching.


If you don't really care about the uniform distribution, here is an even easier solution:

  1. While you have less than n points: Generate a random point
  2. If it is in the circle, store it else go to step 1
  3. For each of these points, generate a point near it
  4. If it is in the circle, store it else go to step 3
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Generate the random points as @PheuVerg suggested (with a slight vectorized tweak)

n = 8; %must be even!
x = rand(n, 1)*2*R - R; 
y = rand(n, 1).*sqrt(R^2 - x.^2).*2-sqrt(R^2 - x.^2);

Then use kmeans clustering to get n/2 centers

[~ c] = kmeans([x y], n/2);

now you have to loop through each center and find it's distance to each point

dists = zeros(n, n/2);
for cc = 1:n/2
    for pp = 1:n
        dists(pp, cc) = sqrt((c(cc,1) - x(pp))^2 + (c(cc,2) - y(pp))^2);
    end
end

now you must find the smallest 2 values for each columns of dists

[sorted, idx] = sort(dists);

so now the top two rows of each column are the two nearest points. But there could be clashes! i.e. points that are nearest to two different centers. So for repeated values you have to loop through and choose swap for the point that will give you the smallest extra distance.

Example data:

x =

    0.7894
   -0.7176
   -0.5814
    0.0708
    0.5198
   -0.2299
    0.2245
   -0.8941

y =

   -0.0800
   -0.3339
    0.0012
    0.9765
   -0.4135
    0.5733
   -0.1867
    0.2094

sorted =

    0.1870         0         0    0.1555
    0.2895    0.5030    0.5030    0.2931
    0.3145    1.1733    0.6715    0.2989
    1.0905    1.1733    0.7574    0.7929
    1.1161    1.2326    0.8854    0.9666
    1.2335    1.2778    1.0300    1.2955
    1.2814    1.4608    1.2106    1.3051
    1.4715    1.5293    1.2393    1.5209

idx =

     5     4     6     3
     7     6     4     2
     1     3     3     8
     6     7     8     6
     3     8     7     7
     2     1     2     4
     4     5     1     5
     8     2     5     1

So now it's clear that 5 and 7 are pairs, and that 3 and 2 are pairs. But 4 and 6 are both repeated. (in this case it is clear that they are pairs too I guess!) but what I would suggest is to leave point 4 with center 2 and point 6 with center 3. Then we start at column 2 and see the next available point is 8 with a distance of 1.2326. This would leave point 1 paired with point 6 but then it's distance from the center is 1.2106. Had we paired point 6 with 8 and point 4 with 1 we would have got distances of 0.7574 and 1.2778 respectively which is actually less total distance. So finding 'close' pairs is easy but finding the set of pairs with the globally smallest minimum is hard! This solutions gets you something decent quite easily but fi you need the global best then I'm afraid you have quite a bit of work to do still :(

Finally let me add some visualisation. First lets (manually) create a vector that shows which points are paired:

   I = [1 2 2 1 3 4 3 4];

Remember that that will depend on your data! Now you can plot is nicely like this:

gscatter(x, y, I)

Hope this gets you close and that you can eliminate the manual pairing of mine at the end by yourself. It shouldn't be too hard to get a crude solution.

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