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I find myself overwhelmed with information, and I still haven't been able to find exactly what I'm looking for, at least not in a format I can convert for my uses.

What I need is an algorithm that can give me positions around a sphere for N points (less than 20, probably) that vaguely spreads them out. There's no need for "perfection", but I just need it so none of them are bunched together.

  • This question provided good code, but I couldn't find a way to make this uniform, as this seemed 100% randomized.
  • This blog post recommended had two ways allowing input of number of points on the sphere, but the Saff and Kuijlaars algorithm is exactly in psuedocode I could transcribe, and the code example I found contained "node[k]", which I couldn't see explained and ruined that possibility. The second blog example was the Golden Section Spiral, which gave me strange, bunched up results, with no clear way to define a constant radius.
  • This algorithm from this question seems like it could possibly work, but I can't piece together what's on that page into psuedocode or anything.

A few other question threads I came across spoke of randomized uniform distribution, which adds a level of complexity I'm not concerned about. I apologize that this is such a silly question, but I wanted to show that I've truly looked hard and still come up short.

So, what I'm looking for is simple psuedocode to evenly distribute N points around a unit sphere, that either returns in spherical or Cartesian coordinates. Even better if it can even distribute with a bit of randomization (think planets around a star, decently spread out, but with room for leeway).

Thanks so much to anyone who can help, and sorry for the wall of text.

share|improve this question
    
What do you mean "with a bit of randomization"? Do you mean perturbations in some sense? –  ninjagecko Mar 7 '12 at 13:58
8  
OP is confused. What he's looking for is to put n-points on a sphere, so that the minimum distance between any two points is as large as possible. This will give the points the appearance of being "evenly distributed" over the entire sphere. This is completely unrelated to creating a uniform random distribution on a sphere, which is what many of those links are about, and what many of the answers below are talking about. –  BlueRaja - Danny Pflughoeft Mar 7 '12 at 17:12

10 Answers 10

up vote 6 down vote accepted

in this example code node[k] is just the kth node. you are generating an array N points and node[k] is the kth (from 0 to N-1). if that is all that is confusing you, hopefully you can use that now.

(in other words, k is an array of size N that is defined before the code fragment starts, and which contains a list of the points).

alternatively, building on the other answer here (and using Python):

> cat ll.py
from math import asin
nx = 4; ny = 5
for x in range(nx):
    lon = 360 * ((x+0.5) / nx)
    for y in range(ny):                                                         
        midpt = (y+0.5) / ny                                                    
        lat = 180 * asin(2*((y+0.5)/ny-0.5))                                    
        print lon,lat                                                           
> python2.7 ll.py                                                      
45.0 -166.91313924                                                              
45.0 -74.0730322921                                                             
45.0 0.0                                                                        
45.0 74.0730322921                                                              
45.0 166.91313924                                                               
135.0 -166.91313924                                                             
135.0 -74.0730322921                                                            
135.0 0.0                                                                       
135.0 74.0730322921                                                             
135.0 166.91313924                                                              
225.0 -166.91313924                                                             
225.0 -74.0730322921                                                            
225.0 0.0                                                                       
225.0 74.0730322921                                                             
225.0 166.91313924
315.0 -166.91313924
315.0 -74.0730322921
315.0 0.0
315.0 74.0730322921
315.0 166.91313924

if you plot that, you'll see that the vertical spacing is larger near the poles so that each point is situated in about the same total area of space (near the poles there's less space "horizontally", so it gives more "vertically").

this isn't the same as all points having about the same distance to their neighbours (which is what i think your links are talking about), but it may be sufficient for what you want and improves on simply making a uniform lat/lon grid.

share|improve this answer
    
nice, it's good to see a mathematical solution. I was thinking of using a helix and arc length separation. I'm still not certain on how to get the optimal solution which is an interesting problem. –  robert king Mar 7 '12 at 12:23
    
did you see that i edited my answer to include an explanation of node[k] at the top? i think that may be all you need... –  andrew cooke Mar 7 '12 at 12:51
    
Wonderful, thanks for the explanation. I'll try it out later, as I haven't time currently, but thank you so much for helping me out. I'll let you know how it ends up working for my purposes. ^^ –  Befall Mar 7 '12 at 21:06
    
Using the Spiral method fits my needs perfectly, thanks so much for the help and clarification. :) –  Befall Mar 8 '12 at 1:22

This is known as packing points on a sphere, and there is no (known) general, perfect solution. However, there are plenty of imperfect solutions. The three most popular seem to be:

  1. Create a simulation. Treat each point as an electron constrained to a sphere, then run a simulation for a certain number of steps. The electrons' repulsion will naturally tend the system to a more stable state, where the points are about as far away from each other as they can get.
  2. Hypercube rejection. This fancy-sounding method is actually really simple: you uniformly choose points (much more than n of them) inside of the cube surrounding the sphere, then reject the points outside of the sphere. Treat the remaining points as vectors, and normalize them. These are your "samples" - choose n of them using some method (randomly, greedy, etc).
  3. Spiral approximations. You trace a spiral around a sphere, and evenly-distribute the points around the spiral. Because of the mathematics involved, these are more complicated to understand than the simulation, but much faster (and probably involving less code). The most popular seems to be by Saff, et al.

A lot more information about this problem can be found here

share|improve this answer
1  
nice answer..... –  Neil G Mar 7 '12 at 18:06
    
I will be looking into the spiral tactic that andrew cooke posted below, however, could you please clarify the difference between what I want and what "uniform random distribution" is? Is that just 100% randomized placement of points on a sphere so that they are uniformly placed? Thanks for the help. :) –  Befall Mar 7 '12 at 21:08
1  
@Befall: "uniform random distribution" refers to the probability-distribution being uniform - it means, when choosing a random point on the sphere, every point has an equal likelihood of being chosen. It has nothing to do with the final spatial-distribution of the points, and thus has nothing to do with your question. –  BlueRaja - Danny Pflughoeft Mar 7 '12 at 21:57
    
Ahhh, okay, thanks very much. Searching for my question lead to a ton of answers for both, and I couldn't really grasp which was pointless to me. –  Befall Mar 7 '12 at 21:59

Take the two largest factors of your N, if N==20 then the two largest factors are {5,4}, or, more generally {a,b}. Calculate

dlat  = 180/(a+1)
dlong = 360/(b+1})

Put your first point at {90-dlat/2,(dlong/2)-180}, your second at {90-dlat/2,(3*dlong/2)-180}, your 3rd at {90-dlat/2,(5*dlong/2)-180}, until you've tripped round the world once, by which time you've got to about {75,150} when you go next to {90-3*dlat/2,(dlong/2)-180}.

Obviously I'm working this in degrees on the surface of the spherical earth, with the usual conventions for translating +/- to N/S or E/W. And obviously this gives you a completely non-random distribution, but it is uniform and the points are not bunched together.

To add some degree of randomness, you could generate 2 normally-distributed (with mean 0 and std dev of {dlat/3, dlong/3} as appropriate) and add them to your uniformly distributed points.

share|improve this answer
3  
that would look a lot better if you worked in sin(lat) rather than lat. as it is, you will get a lot of bunching near the poles. –  andrew cooke Mar 7 '12 at 12:06

This works and it's deadly simple. As many points as you want:

    private function moveTweets():void {


        var newScale:Number=Scale(meshes.length,50,500,6,2);
        trace("new scale:"+newScale);


        var l:Number=this.meshes.length;
        var tweetMeshInstance:TweetMesh;
        var destx:Number;
        var desty:Number;
        var destz:Number;
        for (var i:Number=0;i<this.meshes.length;i++){

            tweetMeshInstance=meshes[i];

            var phi:Number = Math.acos( -1 + ( 2 * i ) / l );
            var theta:Number = Math.sqrt( l * Math.PI ) * phi;

            tweetMeshInstance.origX = (sphereRadius+5) * Math.cos( theta ) * Math.sin( phi );
            tweetMeshInstance.origY= (sphereRadius+5) * Math.sin( theta ) * Math.sin( phi );
            tweetMeshInstance.origZ = (sphereRadius+5) * Math.cos( phi );

            destx=sphereRadius * Math.cos( theta ) * Math.sin( phi );
            desty=sphereRadius * Math.sin( theta ) * Math.sin( phi );
            destz=sphereRadius * Math.cos( phi );

            tweetMeshInstance.lookAt(new Vector3D());


            TweenMax.to(tweetMeshInstance, 1, {scaleX:newScale,scaleY:newScale,x:destx,y:desty,z:destz,onUpdate:onLookAtTween, onUpdateParams:[tweetMeshInstance]});

        }

    }
    private function onLookAtTween(theMesh:TweetMesh):void {
        theMesh.lookAt(new Vector3D());
    }
share|improve this answer

This answer is based on the same 'theory' that is outlined well by this answer

I'm adding this answer as:
-- None of the other options fit the 'uniformity' need 'spot-on' (or not obviously-clearly so). (Noting to get the planet like distribution looking behavior particurally wanted in the original ask, you just reject from the finite list of the k uniformly created points at random (random wrt the index count in the k items back).)
--The closest other impl forced you to decide the 'N' by 'angular axis', vs. just 'one value of N' across both angular axis values ( which at low counts of N is very tricky to know what may, or may not matter (e.g. you want '5' points -- have fun ) )
--Furthermore, it's very hard to 'grok' how to differentiate between the other options without any imagery, so here's what this option looks like (below), and the ready-to-run implementation that goes with it.

with N at 20:

enter image description here
and then N at 80: enter image description here


here's the ready-to-run python3 code, where the emulation is that same source: " http://web.archive.org/web/20120421191837/http://www.cgafaq.info/wiki/Evenly_distributed_points_on_sphere " found by others. ( The plotting I've included, that fires when run as 'main,' is taken from: http://www.scipy.org/Cookbook/Matplotlib/mplot3D )

from math import cos, sin, pi, sqrt

def GetPointsEquiAngularlyDistancedOnSphere(numberOfPoints=45):
    """ each point you get will be of form 'x, y, z'; in cartesian coordinates
        eg. the 'l2 distance' from the origion [0., 0., 0.] for each point will be 1.0 
        ------------
        converted from:  http://web.archive.org/web/20120421191837/http://www.cgafaq.info/wiki/Evenly_distributed_points_on_sphere ) 
    """
    dlong = pi*(3.0-sqrt(5.0))  # ~2.39996323 
    dz   =  2.0/numberOfPoints
    long =  0.0
    z    =  1.0 - dz/2.0
    ptsOnSphere =[]
    for k in range( 0, numberOfPoints): 
        r    = sqrt(1.0-z*z)
        ptNew = (cos(long)*r, sin(long)*r, z)
        ptsOnSphere.append( ptNew )
        z    = z - dz
        long = long + dlong
    return ptsOnSphere

if __name__ == '__main__':                
    ptsOnSphere = GetPointsEquiAngularlyDistancedOnSphere( 80)    

    #toggle True/False to print them
    if( True ):    
        for pt in ptsOnSphere:  print( pt)

    #toggle True/False to plot them
    if(True):
        from numpy import *
        import pylab as p
        import mpl_toolkits.mplot3d.axes3d as p3

        fig=p.figure()
        ax = p3.Axes3D(fig)

        x_s=[];y_s=[]; z_s=[]

        for pt in ptsOnSphere:
            x_s.append( pt[0]); y_s.append( pt[1]); z_s.append( pt[2])

        ax.scatter3D( array( x_s), array( y_s), array( z_s) )                
        ax.set_xlabel('X'); ax.set_ylabel('Y'); ax.set_zlabel('Z')
        p.show()
        #end

tested at low counts (N in 2, 5, 7, 13, etc) and seems to work 'nice'

share|improve this answer

Hi this one is pretty amazingly good, it's similar to the other code on here:

 function sphere ( N:float,k:int):Vector3{

   var inc =  Mathf.PI  * (3 - Mathf.Sqrt(5));
   var off = 2 / N;
var y = k * off - 1 + (off / 2);
var r = Mathf.Sqrt(1 - y*y);
var phi = k * inc;
return Vector3((Mathf.Cos(phi)*r), y, Mathf.Sin(phi)*r); 

}; above function should run in loop with N loop total and k loop currrent iteration.

its based on a sunflower seeds pattern, except the sunflower seeds are curved around into a half dome, and again into a sphere.

here is a pic, except i put the camera half way inside teh sphere so it looks 2d instead of 3d because the camera is same distance from all points. http://3.bp.blogspot.com/-9lbPHLccQHA/USXf88_bvVI/AAAAAAAAADY/j7qhQsSZsA8/s640/sphere.jpg

share|improve this answer

with small numbers of points you could run a simulation:

from random import random,randint
r = 10
n = 20
best_closest_d = 0
best_points = []
points = [(r,0,0) for i in range(n)]
for simulation in range(10000):
    x = random()*r
    y = random()*r
    z = r-(x**2+y**2)**0.5
    if randint(0,1):
        x = -x
    if randint(0,1):
        y = -y
    if randint(0,1):
        z = -z
    closest_dist = (2*r)**2
    closest_index = None
    for i in range(n):
        for j in range(n):
            if i==j:
                continue
            p1,p2 = points[i],points[j]
            x1,y1,z1 = p1
            x2,y2,z2 = p2
            d = (x1-x2)**2+(y1-y2)**2+(z1-z2)**2
            if d < closest_dist:
                closest_dist = d
                closest_index = i
    if simulation % 100 == 0:
        print simulation,closest_dist
    if closest_dist > best_closest_d:
        best_closest_d = closest_dist
        best_points = points[:]
    points[closest_index]=(x,y,z)


print best_points
>>> best_points
[(9.921692138442777, -9.930808529773849, 4.037839326088124),
 (5.141893371460546, 1.7274947332807744, -4.575674650522637),
 (-4.917695758662436, -1.090127967097737, -4.9629263893193745),
 (3.6164803265540666, 7.004158551438312, -2.1172868271109184),
 (-9.550655088997003, -9.580386054762917, 3.5277052594769422),
 (-0.062238110294250415, 6.803105171979587, 3.1966101417463655),
 (-9.600996012203195, 9.488067284474834, -3.498242301168819),
 (-8.601522086624803, 4.519484132245867, -0.2834204048792728),
 (-1.1198210500791472, -2.2916581379035694, 7.44937337008726),
 (7.981831370440529, 8.539378431788634, 1.6889099589074377),
 (0.513546008372332, -2.974333486904779, -6.981657873262494),
 (-4.13615438946178, -6.707488383678717, 2.1197605651446807),
 (2.2859494919024326, -8.14336582650039, 1.5418694699275672),
 (-7.241410895247996, 9.907335206038226, 2.271647103735541),
 (-9.433349952523232, -7.999106443463781, -2.3682575660694347),
 (3.704772125650199, 1.0526567864085812, 6.148581714099761),
 (-3.5710511242327048, 5.512552040316693, -3.4318468250897647),
 (-7.483466337225052, -1.506434920354559, 2.36641535124918),
 (7.73363824231576, -8.460241422163824, -1.4623228616326003),
 (10, 0, 0)]
share|improve this answer
    
to improve my answer you should change closest_index = i to closest_index = randchoice(i,j) –  robert king Mar 7 '12 at 12:26
    
note: I assumed you wanted the points on the surface .. –  robert king Mar 7 '12 at 12:30

edit: This does not answer the question the OP meant to ask, leaving it here in case people find it useful somehow.

We use the multiplication rule of probability, combined with infinitessimals. This results in 2 lines of code to achieve your desired result:

longitude: φ = uniform([0,2pi))
azimuth:   θ = -arcsin(1 - 2*uniform([0,1]))

(defined in the following coordinate system:)

enter image description here

Your language typically has a uniform random number primitive. For example in python you can use random.random() to return a number in the range [0,1). You can multiply this number by k to get a random number in the range [0,k). Thus in python, uniform([0,2pi)) would mean random.random()*2*math.pi.


Proof

Now we can't assign θ uniformly, otherwise we'd get clumping at the poles. We wish to assign probabilities proportional to the surface area of the spherical wedge (the θ in this diagram is actually φ):

enter image description here

An angular displacement dφ at the equator will result in a displacement of dφ*r. What will that displacement be at an arbitrary azimuth θ? Well, the radius from the z-axis is r*sin(θ), so the arclength of that "latitude" intersecting the wedge is dφ * r*sin(θ). Thus we calculate the cumulative distribution of the area to sample from it, by integrating the area of the slice from the south pole to the north pole.

enter image description here (where stuff=dφ*r)

We will now attempt to get the inverse of the CDF to sample from it: http://en.wikipedia.org/wiki/Inverse_transform_sampling

First we normalize by dividing our almost-CDF by its maximum value. This has the side-effect of cancelling out the dφ and r.

azimuthalCDF: cumProb = (sin(θ)+1)/2 from -pi/2 to pi/2

inverseCDF: θ = -sin^(-1)(1 - 2*cumProb)

Thus:

let x by a random float in range [0,1]
θ = -arcsin(1-2*x)
share|improve this answer
    
isn't this equivalent to the option he discarded as being "100% randomized"? my understanding is that he wants them to be more evenly spaced than a uniform random distribution. –  andrew cooke Mar 7 '12 at 15:22
    
-1 See my comment to the original post –  BlueRaja - Danny Pflughoeft Mar 7 '12 at 17:13
    
@BlueRaja-DannyPflughoeft: Hmm, fair enough. I guess I didn't read the question as carefully as I should have. I leave this here anyway in case others find it useful. Thanks for pointing this out. –  ninjagecko Mar 7 '12 at 23:05
# create uniform spiral grid
numOfPoints = varargin[0]
vxyz = zeros((numOfPoints,3),dtype=float)
sq0 = 0.00033333333**2
sq2 = 0.9999998**2
sumsq = 2*sq0 + sq2
vxyz[numOfPoints -1] = array([(sqrt(sq0/sumsq)), 
                              (sqrt(sq0/sumsq)), 
                              (-sqrt(sq2/sumsq))])
vxyz[0] = -vxyz[numOfPoints -1] 
phi2 = sqrt(5)*0.5 + 2.5
rootCnt = sqrt(numOfPoints)
prevLongitude = 0
for index in arange(1, (numOfPoints -1), 1, dtype=float):
  zInc = (2*index)/(numOfPoints) -1
  radius = sqrt(1-zInc**2)

  longitude = phi2/(rootCnt*radius)
  longitude = longitude + prevLongitude
  while (longitude > 2*pi): 
    longitude = longitude - 2*pi

  prevLongitude = longitude
  if (longitude > pi):
    longitude = longitude - 2*pi

  latitude = arccos(zInc) - pi/2
  vxyz[index] = array([ (cos(latitude) * cos(longitude)) ,
                        (cos(latitude) * sin(longitude)), 
                        sin(latitude)])
share|improve this answer
2  
It'd be helpful if you wrote some text explaining what this is meant to do, so the OP doesn't have to take it on faith that it will just work. –  Hbcdev Sep 26 '12 at 6:53

OR... to place 20 points, compute the centers of the icosahedronal faces. For 12 points, find the vertices of the icosahedron. For 30 points, the mid point of the edges of the icosahedron. you can do the same thing with the tetrahedron, cube, dodecahedron and octahedrons: one set of points is on the vertices, another on the center of the face and another on the center of the edges. They cannot be mixed, however.

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