# Generate a random point within a rectangle (uniformly)

Generate a random point within a rectangle (uniformly)

This suppose to be a simple problem.

However, in RANDOM_DATA homepage I found the following note:

However, we will not achieve uniform distribution in the simple case of a rectangle of nonequal sides [0,A] x [0,B], if we naively scale the random values (u1,u2) to (A*u1,B*u2). In that case, the expected point density of a wide, short region will differ from that of a narrow tall region. The absence of uniformity is most obvious if the points are plotted.

I found it quite of strange... I can't figure out why such scaling will affect the uniformity.

What am I missing?

Edit:

Thank you Patrick87 and missingno. I was searching for a theoretical reason for the statement. I now understand that the reason is not theoretical, but practical - the granularity of floating-point values.

If I'll generate two uniform floating-points between 0 and 1 (which is an issue by itself due to the nature of floating-point value representation. Look here for an algorithm) - the granularity will be limited.

Suppose that there are X different values between 0 and 1. By scaling (u1,u2) to (u1,2*u2) we'll have X different values in the range [0,u1] and X different values in the range [0,2*u2]. For area uniformity we should have twice as many different values in [0,2*u2] than in [0,u1].

Given that, Allow me to change my question:

How should I generate a random point within a rectangle (with uniform distribution by area)?

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This is a non-issue if you define a lattice (even a very fine one) and choose random integer coordinates for points. It's a question of granularity. – Patrick87 Jul 30 '11 at 15:17
There's no problem with floating-point granularity or something. – unkulunkulu Jul 30 '11 at 15:41
If there was no word "random" in the quote, I could presume that they're talking about generating of a uniform grid and not about random variables' distributions, but as this word is there, I cannot. – unkulunkulu Jul 30 '11 at 15:44
Correct. The lattice solution addresses this directly by ensuring that the number of possibilities in each dimension is roughly in proportion to the length of the interval over which it is uniformly ranging... so there really are twice as many distinct values in the X-dimension, if the rectangle is twice as wide as it is tall. – Patrick87 Jul 30 '11 at 15:56

## 4 Answers

How should I generate a random point within a rectangle (with uniform distribution by area)?

This should work:

``````  // given A, B, dimensions of rectangle
// given g, granularity of shorter side

if A > B then
bm := g
am := floor(g * A / B)
else then
am := g
bm := floor(g * B / A)

for i := 1 to n do
av := A * RandomInt(0..am) / am
bv := B * RandomInt(0..bm) / bm
print (av, bb)
``````

EDIT: A simpler alternative would be to simply scale random floating point values by the same factor, choose points at random, and throw away points that fall outside your rectangle. However, you don't know how many trials you'd need before you got N points in the rectangle...

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interesting. Can you define granularity precisely? – unkulunkulu Jul 30 '11 at 15:46
oh, never mind, I think I got it. But this is insignificant for floats, I guess. `g` for `float`s should be so little I would be afraid to multiply numbers by it :) – unkulunkulu Jul 30 '11 at 15:50
The idea is to define an integer lattice of dimensions am x bm, where am/bm ~ A/B. Granularity is then defined to be the number of distinct lattice coordinates in the smaller dimension, so that you are guaranteed to have at least g^2 distinct lattice points to choose from. – Patrick87 Jul 30 '11 at 15:51
Ok, now I see that this is just complete nonsense. This is not what was discussed on RANDOM_DATA and this is something really bad. Can you give the value of `g` for `float` and A = 3, B = 7, for example? This is not going to be any better than scaling, I bet on worse. – unkulunkulu Jul 30 '11 at 17:55
This has nothing to do with floating-point numbers... there is no g that makes this scheme the same as floating-point. Floating point numbers work completely differently. For A = 7, B = 3, a g of 3,000,000 would result in am=7,000,000 bm=3,000,000 and 21x10^12 unique grid points (when converted to floats, there can be rounding, but that's unavoidable) which are equally likely... – Patrick87 Jul 30 '11 at 18:05

That statement is incorrect, direct product of two independent uniform measures is a uniform measure. This can be shown as follows:

A probability for a random point to hit a rectangle with sides `a` and `b` is equal to probability for the first coordinate to hit the segment with the length `a` and the second coordinate to hit the segment with the length `b`. (We are talking about projections of a rectangle to axes).

First probability is `a / A`, the second one is `b / B`. As these variables are independent, the probabilities multiply, so the resulting probability is `ab / AB`, so we have a uniform 2D distribution as the probability is proportional to the area of the rectangle. This formula is symmetric with respect to `a` and `b`, so the observation in the quote is wrong about narrow and wide rectangles.

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+1. A simple argument based on their own example shows you are right. 1/(nm) of points will fall in a rectangle of dimensions (A/n)x(B/m). Clearly, the same is true of rectangles (A/m)x(B/n). These rectangles have the same area and same number of points, so same density by area. – Patrick87 Jul 30 '11 at 15:32
@Patrick, although it is obvious, I drew two rectangles on the paper before answering :D – unkulunkulu Jul 30 '11 at 15:34

Ascii art:

Take a 3x3 rectangle:

``````***
***
***
``````

And spread one of the sides by 3x:

``````*..*..*..*
*..*..*..*
*..*..*..*
``````

You can kind of see here that the points are more densely packed vertically than they are horizontaly. What you actually want instead is uniform distribution by area

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The most straightforward way to handle this is through rejection sampling:

http://en.wikipedia.org/wiki/Rejection_sampling

``````// Given dimensions of the rectangle A, B where A <= B
boolean flag = true
while (flag) do:
double a = NextRandomDouble(0,B)
double b = NextRandomDouble(0,B)
if (a <= A)
return(a, b)
else
next
``````

You essentially generate uniform numbers from a square that fits the original rectangle (of length B, in this example). If the number falls in the rectangle, keep the pair. If it does not, throw it away and try again!

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