I'd like to generate random points being located on the surface of an n-dimensional torus. I have found formulas for how to generate the points on the surface of a 3-dimensional torus:
x = (c + a * cos(v)) * cos(u)
y = (c + a * cos(v)) * sin(u)
z = a * sin(v)
u, v ∈ [0, 2 * pi); c, a > 0.
My question is now: how to extend this formulas to n dimensions. Any help on the matter would be much appreciated.
I guess that you can do this recursively. Start with a full orthonormal basis of your vector space, and let the current location be the origin. At each step, choose a point in the plane spanned by the first two coordinate vectors, i.e. take w1 = cos(t)*v1 + sin(t)*v2. Shift the other basis vectors, i.e. w2 = v3, w3 = v4, …. Also take a step from your current position in the direction w1, with the radius r1 chosen up front. When you only have a single basis vector remaining, then the current point is a point on the n-dimensional torus of the outermost recursive call.
Note that while the above may be used to choose points randomly, it won't choose them uniformly. That would likely be a much harder question, and you definitely should ask about the math of that on Math SE or perhaps on Cross Validated (Statistics SE) to get the math right before you worry about implementation.
An n-torus (n being the dimensionality of the surface of the torus; a bagel or doughnut is therefore a 2-torus, not a 3-torus) is a smooth mapping of an n-rectangle. One way to approach this is to generate points on the rectangle and then map them onto the torus. Aside from the problem of figuring out how to map a rectangle onto a torus (I don't know it off-hand), there is the problem that the resulting distribution of points on the torus is not uniform even if the distribution of points is uniform on the rectangle. But there must be a way to adjust the distribution on the rectangle to make it uniform on the torus.
Merely generating u and v uniformly will not necessarily sample uniformly from a torus surface. An additional step is needed.
J.F. Williamson, "Random selection of points distributed on curved surfaces", Physics in Medicine & Biology 32(10), 1987, describes a general method of choosing a uniformly random point on a parametric surface. It is an acceptance/rejection method that accepts or rejects each candidate point depending on its stretch factor (norm-of-gradient). To use this method for a parametric surface, several things have to be known about the surface, namely—
x(u, v), y(u, v) and z(u, v), which are functions that generate 3-dimensional coordinates from two dimensional coordinates u and v,
The ranges of u and v,
g(point), the norm of the gradient ("stretch factor") at each point on the surface, and
gmax, the maximum value of g for the entire surface.
For the 3-dimensional torus with the parameterization you give in your question, g and gmax are the following:
g(u, v) = a * (c + cos(v) * a).
gmax = a * (a + c).
The algorithm to generate a uniform random point on the surface of a 3-dimensional torus with torus radius c and tube radius a is then as follows (where RNDEXCRANGE(x,y) returns a number in [x,y) uniformly at random, and RNDRANGE(x,y) returns a number in [x,y] uniformly at random):
// Maximum stretch factor for torus
gmax = a * (a + c)
while true
u = RNDEXCRANGE(0, pi * 2)
v = RNDEXCRANGE(0, pi * 2)
x = cos(u)*(c+cos(v)*a)
y = sin(u)*(c+cos(v)*a)
z = sin(v)*a
// Norm of gradient (stretch factor)
g = a*abs(c+cos(v)*a)
if g >= RNDRANGE(0, gmax)
// Accept the point
return [x, y, z]
end
end
If you have n-dimensional torus generating formulas, a similar approach can be used to generate uniform random points on that torus (accept a candidate point if norm-of-gradient equals or exceeds a random number in [0, gmax), where gmax is the maximum norm-of-gradient).
The magnitude of the cross product describes the signed area of the parallelogram described by the two vectors (u, v) used to build the cross product, it has its uses. This same magnitude can be calculated as the magnitude of u times the magnitude of v times the sine of the angle between u and v:
||u||||v||sin(theta).
Now the dot product of u (normalized) and v (normalized) gives the cosine of the angle between u and v:
cos(theta)==dot(normalize(u), normalize(v))
I want to be able to get the signed sine value that is related to the cosine value. It is related because the sine and cosine waves are PI/2 out of sync. I know that the square root of 1 less the cosine value squared gives the unsigned sine value:
sin(theta)==sqrt(1 - (cos(theta) * cos(theta))
Where by cos(theta) I mean the dot product not the angle.
But the attendant sign calculation (+/-) requires theta as an angle:
(cos(theta + PI / 2)) > or == or < 0
If I have to perform an acos function I might as well just do the cross product and find the magnitude.
Is there a known ratio or step that can be added to a cosine value to get its related sine value?
For each possible cosine, both signs are possible for the sine if the corresponding angle is unrestricted.
If you know the angle is between [0,pi], then the sine must be positive or zero.
If you want to know the area of a parallelogram, always take the positive branch sin(x) = sqrt(1 - cos(x)^2). Negative area rarely makes sense (only to define orientation w.r.t. to a plane such as for backface culling)
If you have the two vectors, use a cross product or dot product directly, not the other one and convert.
Seems to me like a complicated way to get to atan2 identities:
d = 𝐚·𝐛 = |𝐚||𝐛|cosθ
c = |𝐚×𝐛| = |𝐚||𝐛|sinθ (with 0° < θ < 180°)
tanθ = 𝐚·𝐛 / |𝐚×𝐛|
θ = atan2(c·sgn(c|z), d) (= four quadrant)
where sgn(c|z) is the sign of the z-component in c (unless 𝐚 and 𝐛 both run exactly parallel with the xz or yz plane, then its the sign of the y-component and x-component, respectively).
Now, from basic trig identities,
r = √(x²+y²)
cos(atan2(y,x)) = x/r
sin(atan2(y,x)) = y/r
Therefore,
sinθ = c·sgn(c|z)/√(c²+d²)
cosθ = d/√(c²+d²)
I think I have found a solution.
cos(b) == sin(a)
v_parallel = dot(normalize(u), v) // the projection of v on u
v_perp = normalize(v) - v_parallel
cos(b) = dot(normalize(v), v_perp) // v_perp is already normalized
Therefore, the magnitude of
u cross v = magnitude(u) * magnitude(v) * cos(b)
I need to generate a uniformly random point within a circle of radius R.
I realize that by just picking a uniformly random angle in the interval [0 ... 2π), and uniformly random radius in the interval (0 ... R) I would end up with more points towards the center, since for two given radii, the points in the smaller radius will be closer to each other than for the points in the larger radius.
I found a blog entry on this over here but I don't understand his reasoning. I suppose it is correct, but I would really like to understand from where he gets (2/R2)×r and how he derives the final solution.
Update: 7 years after posting this question I still hadn't received a satisfactory answer on the actual question regarding the math behind the square root algorithm. So I spent a day writing an answer myself. Link to my answer.
How to generate a random point within a circle of radius R:
r = R * sqrt(random())
theta = random() * 2 * PI
(Assuming random() gives a value between 0 and 1 uniformly)
If you want to convert this to Cartesian coordinates, you can do
x = centerX + r * cos(theta)
y = centerY + r * sin(theta)
Why sqrt(random())?
Let's look at the math that leads up to sqrt(random()). Assume for simplicity that we're working with the unit circle, i.e. R = 1.
The average distance between points should be the same regardless of how far from the center we look. This means for example, that looking on the perimeter of a circle with circumference 2 we should find twice as many points as the number of points on the perimeter of a circle with circumference 1.
Since the circumference of a circle (2πr) grows linearly with r, it follows that the number of random points should grow linearly with r. In other words, the desired probability density function (PDF) grows linearly. Since a PDF should have an area equal to 1 and the maximum radius is 1, we have
So we know how the desired density of our random values should look like.
Now: How do we generate such a random value when all we have is a uniform random value between 0 and 1?
We use a trick called inverse transform sampling
From the PDF, create the cumulative distribution function (CDF)
Mirror this along y = x
Apply the resulting function to a uniform value between 0 and 1.
Sounds complicated? Let me insert a blockquote with a little side track that conveys the intuition:
Suppose we want to generate a random point with the following distribution:
That is
1/5 of the points uniformly between 1 and 2, and
4/5 of the points uniformly between 2 and 3.
The CDF is, as the name suggests, the cumulative version of the PDF. Intuitively: While PDF(x) describes the number of random values at x, CDF(x) describes the number of random values less than x.
In this case the CDF would look like:
To see how this is useful, imagine that we shoot bullets from left to right at uniformly distributed heights. As the bullets hit the line, they drop down to the ground:
See how the density of the bullets on the ground correspond to our desired distribution! We're almost there!
The problem is that for this function, the y axis is the output and the x axis is the input. We can only "shoot bullets from the ground straight up"! We need the inverse function!
This is why we mirror the whole thing; x becomes y and y becomes x:
We call this CDF-1. To get values according to the desired distribution, we use CDF-1(random()).
…so, back to generating random radius values where our PDF equals 2x.
Step 1: Create the CDF:
Since we're working with reals, the CDF is expressed as the integral of the PDF.
CDF(x) = ∫ 2x = x2
Step 2: Mirror the CDF along y = x:
Mathematically this boils down to swapping x and y and solving for y:
CDF: y = x2
Swap: x = y2
Solve: y = √x
CDF-1: y = √x
Step 3: Apply the resulting function to a uniform value between 0 and 1
CDF-1(random()) = √random()
Which is what we set out to derive :-)
Let's approach this like Archimedes would have.
How can we generate a point uniformly in a triangle ABC, where |AB|=|BC|? Let's make this easier by extending to a parallelogram ABCD. It's easy to generate points uniformly in ABCD. We uniformly pick a random point X on AB and Y on BC and choose Z such that XBYZ is a parallelogram. To get a uniformly chosen point in the original triangle we just fold any points that appear in ADC back down to ABC along AC.
Now consider a circle. In the limit we can think of it as infinitely many isoceles triangles ABC with B at the origin and A and C on the circumference vanishingly close to each other. We can pick one of these triangles simply by picking an angle theta. So we now need to generate a distance from the center by picking a point in the sliver ABC. Again, extend to ABCD, where D is now twice the radius from the circle center.
Picking a random point in ABCD is easy using the above method. Pick a random point on AB. Uniformly pick a random point on BC. Ie. pick a pair of random numbers x and y uniformly on [0,R] giving distances from the center. Our triangle is a thin sliver so AB and BC are essentially parallel. So the point Z is simply a distance x+y from the origin. If x+y>R we fold back down.
Here's the complete algorithm for R=1. I hope you agree it's pretty simple. It uses trig, but you can give a guarantee on how long it'll take, and how many random() calls it needs, unlike rejection sampling.
t = 2*pi*random()
u = random()+random()
r = if u>1 then 2-u else u
[r*cos(t), r*sin(t)]
Here it is in Mathematica.
f[] := Block[{u, t, r},
u = Random[] + Random[];
t = Random[] 2 Pi;
r = If[u > 1, 2 - u, u];
{r Cos[t], r Sin[t]}
]
ListPlot[Table[f[], {10000}], AspectRatio -> Automatic]
Here is a fast and simple solution.
Pick two random numbers in the range (0, 1), namely a and b. If b < a, swap them. Your point is (b*R*cos(2*pi*a/b), b*R*sin(2*pi*a/b)).
You can think about this solution as follows. If you took the circle, cut it, then straightened it out, you'd get a right-angled triangle. Scale that triangle down, and you'd have a triangle from (0, 0) to (1, 0) to (1, 1) and back again to (0, 0). All of these transformations change the density uniformly. What you've done is uniformly picked a random point in the triangle and reversed the process to get a point in the circle.
Note the point density in proportional to inverse square of the radius, hence instead of picking r from [0, r_max], pick from [0, r_max^2], then compute your coordinates as:
x = sqrt(r) * cos(angle)
y = sqrt(r) * sin(angle)
This will give you uniform point distribution on a disk.
http://mathworld.wolfram.com/DiskPointPicking.html
Think about it this way. If you have a rectangle where one axis is radius and one is angle, and you take the points inside this rectangle that are near radius 0. These will all fall very close to the origin (that is close together on the circle.) However, the points near radius R, these will all fall near the edge of the circle (that is, far apart from each other.)
This might give you some idea of why you are getting this behavior.
The factor that's derived on that link tells you how much corresponding area in the rectangle needs to be adjusted to not depend on the radius once it's mapped to the circle.
Edit: So what he writes in the link you share is, "That’s easy enough to do by calculating the inverse of the cumulative distribution, and we get for r:".
The basic premise is here that you can create a variable with a desired distribution from a uniform by mapping the uniform by the inverse function of the cumulative distribution function of the desired probability density function. Why? Just take it for granted for now, but this is a fact.
Here's my somehwat intuitive explanation of the math. The density function f(r) with respect to r has to be proportional to r itself. Understanding this fact is part of any basic calculus books. See sections on polar area elements. Some other posters have mentioned this.
So we'll call it f(r) = C*r;
This turns out to be most of the work. Now, since f(r) should be a probability density, you can easily see that by integrating f(r) over the interval (0,R) you get that C = 2/R^2 (this is an exercise for the reader.)
Thus, f(r) = 2*r/R^2
OK, so that's how you get the formula in the link.
Then, the final part is going from the uniform random variable u in (0,1) you must map by the inverse function of the cumulative distribution function from this desired density f(r). To understand why this is the case you need to find an advanced probability text like Papoulis probably (or derive it yourself.)
Integrating f(r) you get F(r) = r^2/R^2
To find the inverse function of this you set u = r^2/R^2 and then solve for r, which gives you r = R * sqrt(u)
This totally makes sense intuitively too, u = 0 should map to r = 0. Also, u = 1 shoudl map to r = R. Also, it goes by the square root function, which makes sense and matches the link.
Let ρ (radius) and φ (azimuth) be two random variables corresponding to polar coordinates of an arbitrary point inside the circle. If the points are uniformly distributed then what is the disribution function of ρ and φ?
For any r: 0 < r < R the probability of radius coordinate ρ to be less then r is
P[ρ < r] = P[point is within a circle of radius r] = S1 / S0 =(r/R)2
Where S1 and S0 are the areas of circle of radius r and R respectively.
So the CDF can be given as:
0 if r<=0
CDF = (r/R)**2 if 0 < r <= R
1 if r > R
And PDF:
PDF = d/dr(CDF) = 2 * (r/R**2) (0 < r <= R).
Note that for R=1 random variable sqrt(X) where X is uniform on [0, 1) has this exact CDF (because P[sqrt(X) < y] = P[x < y**2] = y**2 for 0 < y <= 1).
The distribution of φ is obviously uniform from 0 to 2*π. Now you can create random polar coordinates and convert them to Cartesian using trigonometric equations:
x = ρ * cos(φ)
y = ρ * sin(φ)
Can't resist to post python code for R=1.
from matplotlib import pyplot as plt
import numpy as np
rho = np.sqrt(np.random.uniform(0, 1, 5000))
phi = np.random.uniform(0, 2*np.pi, 5000)
x = rho * np.cos(phi)
y = rho * np.sin(phi)
plt.scatter(x, y, s = 4)
You will get
The reason why the naive solution doesn't work is that it gives a higher probability density to the points closer to the circle center. In other words the circle that has radius r/2 has probability r/2 of getting a point selected in it, but it has area (number of points) pi*r^2/4.
Therefore we want a radius probability density to have the following property:
The probability of choosing a radius smaller or equal to a given r has to be proportional to the area of the circle with radius r. (because we want to have a uniform distribution on the points and larger areas mean more points)
In other words we want the probability of choosing a radius between [0,r] to be equal to its share of the overall area of the circle. The total circle area is pi*R^2, and the area of the circle with radius r is pi*r^2. Thus we would like the probability of choosing a radius between [0,r] to be (pi*r^2)/(pi*R^2) = r^2/R^2.
Now comes the math:
The probability of choosing a radius between [0,r] is the integral of p(r) dr from 0 to r (that's just because we add all the probabilities of the smaller radii). Thus we want integral(p(r)dr) = r^2/R^2. We can clearly see that R^2 is a constant, so all we need to do is figure out which p(r), when integrated would give us something like r^2. The answer is clearly r * constant. integral(r * constant dr) = r^2/2 * constant. This has to be equal to r^2/R^2, therefore constant = 2/R^2. Thus you have the probability distribution p(r) = r * 2/R^2
Note: Another more intuitive way to think about the problem is to imagine that you are trying to give each circle of radius r a probability density equal to the proportion of the number of points it has on its circumference. Thus a circle which has radius r will have 2 * pi * r "points" on its circumference. The total number of points is pi * R^2. Thus you should give the circle r a probability equal to (2 * pi * r) / (pi * R^2) = 2 * r/R^2. This is much easier to understand and more intuitive, but it's not quite as mathematically sound.
It really depends on what you mean by 'uniformly random'. This is a subtle point and you can read more about it on the wiki page here: http://en.wikipedia.org/wiki/Bertrand_paradox_%28probability%29, where the same problem, giving different interpretations to 'uniformly random' gives different answers!
Depending on how you choose the points, the distribution could vary, even though they are uniformly random in some sense.
It seems like the blog entry is trying to make it uniformly random in the following sense: If you take a sub-circle of the circle, with the same center, then the probability that the point falls in that region is proportional to the area of the region. That, I believe, is attempting to follow the now standard interpretation of 'uniformly random' for 2D regions with areas defined on them: probability of a point falling in any region (with area well defined) is proportional to the area of that region.
Here is my Python code to generate num random points from a circle of radius rad:
import matplotlib.pyplot as plt
import numpy as np
rad = 10
num = 1000
t = np.random.uniform(0.0, 2.0*np.pi, num)
r = rad * np.sqrt(np.random.uniform(0.0, 1.0, num))
x = r * np.cos(t)
y = r * np.sin(t)
plt.plot(x, y, "ro", ms=1)
plt.axis([-15, 15, -15, 15])
plt.show()
I think that in this case using polar coordinates is a way of complicate the problem, it would be much easier if you pick random points into a square with sides of length 2R and then select the points (x,y) such that x^2+y^2<=R^2.
Solution in Java and the distribution example (2000 points)
public void getRandomPointInCircle() {
double t = 2 * Math.PI * Math.random();
double r = Math.sqrt(Math.random());
double x = r * Math.cos(t);
double y = r * Math.sin(t);
System.out.println(x);
System.out.println(y);
}
based on previus solution https://stackoverflow.com/a/5838055/5224246 from #sigfpe
I used once this method:
This may be totally unoptimized (ie it uses an array of point so its unusable for big circles) but gives random distribution enough. You could skip the creation of the matrix and draw directly if you wish to. The method is to randomize all points in a rectangle that fall inside the circle.
bool[,] getMatrix(System.Drawing.Rectangle r) {
bool[,] matrix = new bool[r.Width, r.Height];
return matrix;
}
void fillMatrix(ref bool[,] matrix, Vector center) {
double radius = center.X;
Random r = new Random();
for (int y = 0; y < matrix.GetLength(0); y++) {
for (int x = 0; x < matrix.GetLength(1); x++)
{
double distance = (center - new Vector(x, y)).Length;
if (distance < radius) {
matrix[x, y] = r.NextDouble() > 0.5;
}
}
}
}
private void drawMatrix(Vector centerPoint, double radius, bool[,] matrix) {
var g = this.CreateGraphics();
Bitmap pixel = new Bitmap(1,1);
pixel.SetPixel(0, 0, Color.Black);
for (int y = 0; y < matrix.GetLength(0); y++)
{
for (int x = 0; x < matrix.GetLength(1); x++)
{
if (matrix[x, y]) {
g.DrawImage(pixel, new PointF((float)(centerPoint.X - radius + x), (float)(centerPoint.Y - radius + y)));
}
}
}
g.Dispose();
}
private void button1_Click(object sender, EventArgs e)
{
System.Drawing.Rectangle r = new System.Drawing.Rectangle(100,100,200,200);
double radius = r.Width / 2;
Vector center = new Vector(r.Left + radius, r.Top + radius);
Vector normalizedCenter = new Vector(radius, radius);
bool[,] matrix = getMatrix(r);
fillMatrix(ref matrix, normalizedCenter);
drawMatrix(center, radius, matrix);
}
First we generate a cdf[x] which is
The probability that a point is less than distance x from the centre of the circle. Assume the circle has a radius of R.
obviously if x is zero then cdf[0] = 0
obviously if x is R then the cdf[R] = 1
obviously if x = r then the cdf[r] = (Pi r^2)/(Pi R^2)
This is because each "small area" on the circle has the same probability of being picked, So the probability is proportionally to the area in question. And the area given a distance x from the centre of the circle is Pi r^2
so cdf[x] = x^2/R^2 because the Pi cancel each other out
we have cdf[x]=x^2/R^2 where x goes from 0 to R
So we solve for x
R^2 cdf[x] = x^2
x = R Sqrt[ cdf[x] ]
We can now replace cdf with a random number from 0 to 1
x = R Sqrt[ RandomReal[{0,1}] ]
Finally
r = R Sqrt[ RandomReal[{0,1}] ];
theta = 360 deg * RandomReal[{0,1}];
{r,theta}
we get the polar coordinates
{0.601168 R, 311.915 deg}
This might help people interested in choosing an algorithm for speed; the fastest method is (probably?) rejection sampling.
Just generate a point within the unit square and reject it until it is inside a circle. E.g (pseudo-code),
def sample(r=1):
while True:
x = random(-1, 1)
y = random(-1, 1)
if x*x + y*y <= 1:
return (x, y) * r
Although it may run more than once or twice sometimes (and it is not constant time or suited for parallel execution), it is much faster because it doesn't use complex formulas like sin or cos.
The area element in a circle is dA=rdr*dphi. That extra factor r destroyed your idea to randomly choose a r and phi. While phi is distributed flat, r is not, but flat in 1/r (i.e. you are more likely to hit the boundary than "the bull's eye").
So to generate points evenly distributed over the circle pick phi from a flat distribution and r from a 1/r distribution.
Alternatively use the Monte Carlo method proposed by Mehrdad.
EDIT
To pick a random r flat in 1/r you could pick a random x from the interval [1/R, infinity] and calculate r=1/x. r is then distributed flat in 1/r.
To calculate a random phi pick a random x from the interval [0, 1] and calculate phi=2*pi*x.
You can also use your intuition.
The area of a circle is pi*r^2
For r=1
This give us an area of pi. Let us assume that we have some kind of function fthat would uniformly distrubute N=10 points inside a circle. The ratio here is 10 / pi
Now we double the area and the number of points
For r=2 and N=20
This gives an area of 4pi and the ratio is now 20/4pi or 10/2pi. The ratio will get smaller and smaller the bigger the radius is, because its growth is quadratic and the N scales linearly.
To fix this we can just say
x = r^2
sqrt(x) = r
If you would generate a vector in polar coordinates like this
length = random_0_1();
angle = random_0_2pi();
More points would land around the center.
length = sqrt(random_0_1());
angle = random_0_2pi();
length is not uniformly distributed anymore, but the vector will now be uniformly distributed.
There is a linear relationship between the radius and the number of points "near" that radius, so he needs to use a radius distribution that is also makes the number of data points near a radius r proportional to r.
I don't know if this question is still open for a new solution with all the answer already given, but I happened to have faced exactly the same question myself. I tried to "reason" with myself for a solution, and I found one. It might be the same thing as some have already suggested here, but anyway here it is:
in order for two elements of the circle's surface to be equal, assuming equal dr's, we must have dtheta1/dtheta2 = r2/r1. Writing expression of the probability for that element as P(r, theta) = P{ r1< r< r1 + dr, theta1< theta< theta + dtheta1} = f(r,theta)*dr*dtheta1, and setting the two probabilities (for r1 and r2) equal, we arrive to (assuming r and theta are independent) f(r1)/r1 = f(r2)/r2 = constant, which gives f(r) = c*r. And the rest, determining the constant c follows from the condition on f(r) being a PDF.
I am still not sure about the exact '(2/R2)×r' but what is apparent is the number of points required to be distributed in given unit 'dr' i.e. increase in r will be proportional to r2 and not r.
check this way...number of points at some angle theta and between r (0.1r to 0.2r) i.e. fraction of the r and number of points between r (0.6r to 0.7r) would be equal if you use standard generation, since the difference is only 0.1r between two intervals. but since area covered between points (0.6r to 0.7r) will be much larger than area covered between 0.1r to 0.2r, the equal number of points will be sparsely spaced in larger area, this I assume you already know, So the function to generate the random points must not be linear but quadratic, (since number of points required to be distributed in given unit 'dr' i.e. increase in r will be proportional to r2 and not r), so in this case it will be inverse of quadratic, since the delta we have (0.1r) in both intervals must be square of some function so it can act as seed value for linear generation of points (since afterwords, this seed is used linearly in sin and cos function), so we know, dr must be quadratic value and to make this seed quadratic, we need to originate this values from square root of r not r itself, I hope this makes it little more clear.
Such a fun problem.
The rationale of the probability of a point being chosen lowering as distance from the axis origin increases is explained multiple times above. We account for that by taking the root of U[0,1].
Here's a general solution for a positive r in Python 3.
import numpy
import math
import matplotlib.pyplot as plt
def sq_point_in_circle(r):
"""
Generate a random point in an r radius circle
centered around the start of the axis
"""
t = 2*math.pi*numpy.random.uniform()
R = (numpy.random.uniform(0,1) ** 0.5) * r
return(R*math.cos(t), R*math.sin(t))
R = 200 # Radius
N = 1000 # Samples
points = numpy.array([sq_point_in_circle(R) for i in range(N)])
plt.scatter(points[:, 0], points[:,1])
A programmer solution:
Create a bit map (a matrix of boolean values). It can be as large as you want.
Draw a circle in that bit map.
Create a lookup table of the circle's points.
Choose a random index in this lookup table.
const int RADIUS = 64;
const int MATRIX_SIZE = RADIUS * 2;
bool matrix[MATRIX_SIZE][MATRIX_SIZE] = {0};
struct Point { int x; int y; };
Point lookupTable[MATRIX_SIZE * MATRIX_SIZE];
void init()
{
int numberOfOnBits = 0;
for (int x = 0 ; x < MATRIX_SIZE ; ++x)
{
for (int y = 0 ; y < MATRIX_SIZE ; ++y)
{
if (x * x + y * y < RADIUS * RADIUS)
{
matrix[x][y] = true;
loopUpTable[numberOfOnBits].x = x;
loopUpTable[numberOfOnBits].y = y;
++numberOfOnBits;
} // if
} // for
} // for
} // ()
Point choose()
{
int randomIndex = randomInt(numberOfBits);
return loopUpTable[randomIndex];
} // ()
The bitmap is only necessary for the explanation of the logic. This is the code without the bitmap:
const int RADIUS = 64;
const int MATRIX_SIZE = RADIUS * 2;
struct Point { int x; int y; };
Point lookupTable[MATRIX_SIZE * MATRIX_SIZE];
void init()
{
int numberOfOnBits = 0;
for (int x = 0 ; x < MATRIX_SIZE ; ++x)
{
for (int y = 0 ; y < MATRIX_SIZE ; ++y)
{
if (x * x + y * y < RADIUS * RADIUS)
{
loopUpTable[numberOfOnBits].x = x;
loopUpTable[numberOfOnBits].y = y;
++numberOfOnBits;
} // if
} // for
} // for
} // ()
Point choose()
{
int randomIndex = randomInt(numberOfBits);
return loopUpTable[randomIndex];
} // ()
1) Choose a random X between -1 and 1.
var X:Number = Math.random() * 2 - 1;
2) Using the circle formula, calculate the maximum and minimum values of Y given that X and a radius of 1:
var YMin:Number = -Math.sqrt(1 - X * X);
var YMax:Number = Math.sqrt(1 - X * X);
3) Choose a random Y between those extremes:
var Y:Number = Math.random() * (YMax - YMin) + YMin;
4) Incorporate your location and radius values in the final value:
var finalX:Number = X * radius + pos.x;
var finalY:Number = Y * radois + pos.y;
I have a unit vector in 3D space whose direction I wish to perturb by some angle within the range 0 to theta, with the position of the vector remaining the same. What is a way I can accomplish this?
Thanks.
EDIT: After thinking about the way I posed the question, it seems to be a bit too general. I'll attempt to make it more specific: Assume that the vector originates from the surface of an object (i.e. sphere, circle, box, line, cylinder, cone). If there are different methods to finding the new direction for each of those objects, then providing help for the sphere one is fine.
EDIT 2: I was going to type this in a comment but it was too much.
So I have orig_vector, which I wish to perturb in some direction between 0 and theta. The theta can be thought of as forming a cone around my vector (with theta being the angle between the center and one side of the cone) and I wish to generate a new vector within that cone. I can generate a point lying on the plane that is tangent to my vector and thus creating a unit vector in the direction of the point, call it rand_vector. At this time, I orig_vector and trand_vector are two unit vectors perpendicular to each other.
I generate my first angle, angle1 between 0 and 2pi and I rotate rand_vector around orig_vector by angle1, forming rand_vector2. I looked up a resource online and it said that the second angle, angle2 should be between 0 and sin(theta) (where theta is the original "cone" angle). Then I rotate rand_vector2 by acos(angle2) around the vector defined by the cross product between rand_vector2 and orig_vector.
When I do this, I don't obtain the desired results. That is, when theta=0, I still get perturbed vectors, and I expect to get orig_vector. If anyone can explain the reason for the angles and why they are the way they are, I would greatly appreciate it.
EDIT 3: This is the final edit, I promise =). So I fixed my bug and everything that I described above works (it was an implementation bug, not a theory bug). However, my question about the angles (i.e. why is angle2 = sin(theta)*rand() and why is perturbed_vector = rand_vector2.Rotate(rand_vector2.Cross(orig_vector), acos(angle2)). Thanks so much!
Here's the algorithm that I've used for this kind of problem before. It was described in Ray Tracing News.
1) Make a third vector perpendicular to the other two to build an orthogonal basis:
cross_vector = unit( cross( orig_vector, rand_vector ) )
2) Pick two uniform random numbers in [0,1]:
s = rand( 0, 1 )
r = rand( 0, 1 )
3) Let h be the cosine of the cone's angle:
h = cos( theta )
4) Modify uniform sampling on a sphere to pick a random vector in the cone around +Z:
phi = 2 * pi * s
z = h + ( 1 - h ) * r
sinT = sqrt( 1 - z * z )
x = cos( phi ) * sinT
y = sin( phi ) * sinT
5) Change of basis to reorient it around the original angle:
perturbed = rand_vector * x + cross_vector * y + orig_vector * z
If you have another vector to represent an axis of rotation, there are libraries that will take the axis and the angle and give you a rotation matrix, which can then be multiplied by your starting vector to get the result you want.
However, the axis of rotation should be at right angles to your starting vector, to get the amount of rotation you expect. If the axis of rotation does not lie in the plane perpendicular to your vector, the result will be somewhat different than theta.
That being said, if you already have a vector at right angles to the one you want to perturb, and you're not picky about the direction of the perturbation, you can just as easily take a linear combination of your starting vector with the perpendicular one, adjust for magnitude as needed.
I.e., if P and Q are vectors having identical magnitude, and are perpendicular, and you want to rotate P in the direction of Q, then the vector R given by R = [Pcos(theta)+Qsin(theta)] will satisfy the constraints you've given. If P and Q have differing magnitude, then there will be some scaling involved.
You may be interested in 3D-coordinate transformations to change your vector angle.
I don't know how many directions you want to change your angle in, but transforming your Cartesian coordinates to spherical coordinates should allow you to make your angle change as you like.
Actually, it is very easy to do that. All you have to do is multiply your vector by the correct rotation matrix. The resulting vector will be your rotated vector. Now, how do you obtain such rotation matrix? That depends on the 3d framework/engine you are using. Any 3d framework must provide functions for obtaining rotation matrices, normally as static methods of the Matrix class.
Good luck.
Like said in other comments you can rotate your vector using a rotation matrix.
The rotation matrix has two angles you rotate your vector around. You can pick them with a random number generator, but just picking two from a flat generator is not correct. To ensure that your rotation vector is generated flat, you have to pick one random angle φ from a flat generator and the other one from a generator flat in cosθ ;this ensures that your solid angle element dcos(θ)dφ is defined correctly (φ and θ defined as usual for spherical coordinates).
Example: picking a random direction with no restriction on range, random() generates flat in [0,1]
angle1 = acos(random())
angle2 = 2*pi*random()
My code in unity - tested and working:
/*
* this is used to perturb given vector 'direction' by changing it by angle not more than 'angle' vector from
* base direction. Used to provide errors for player playing algorithms
*
*/
Vector3 perturbDirection( Vector3 direction, float angle ) {
// division by zero protection
if( Mathf.Approximately( direction.z, 0f )) {
direction.z = 0.0001f;
}
// 1 get some orthogonal vector to direction ( solve direction and orthogonal dot product = 0, assume x = 1, y = 1, then z = as below ))
Vector3 orthogonal = new Vector3( 1f, 1f, - ( direction.x + direction.y ) / direction.z );
// 2 get random vector from circle on flat orthogonal to direction vector. get full range to assume all cone space randomization (-180, 180 )
float orthoAngle = UnityEngine.Random.Range( -180f, 180f );
Quaternion rotateTowardsDirection = Quaternion.AngleAxis( orthoAngle, direction );
Vector3 randomOrtho = rotateTowardsDirection * orthogonal;
// 3 rotate direction towards random orthogonal vector by vector from our available range
float perturbAngle = UnityEngine.Random.Range( 0f, angle ); // range from (0, angle), full cone cover guarantees previous (-180,180) range
Quaternion rotateDirection = Quaternion.AngleAxis( perturbAngle, randomOrtho );
Vector3 perturbedDirection = rotateDirection * direction;
return perturbedDirection;
}