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I want to visualize the the Algorithm of the Polar method from two perspectives (bird's-eye and frog's eye view).

To draw the first step of the method I need random number of the uniform distribution in a square and a circle.

I've already been able to plot the circle in a square, but how to plot random numbers (z1) inside of this construct?

require (plotrix)
require (grid)
z1 = runif (100)

plot (c(-1,1), c(-1,1), type="n", asp=1)
rect(-1,-1,1,1)
draw.circle (0,0,1)

And how to change the perspective?

share|improve this question
    
what do you mean by "change the perspective"? Can you point us to an existing example of what you're trying to achieve in R? – Ben Bolker Apr 12 '12 at 20:40
    
i want to see the distribution of the random numbers in the birds eye perspective like it is now, but also in the frog's eye view....how can I realise that? – jeffrey Apr 12 '12 at 20:47
    
Please be more precise about the definition of "frog's eye view". It's hard to guess, and we shouldn't have to ... – Ben Bolker Apr 12 '12 at 21:30
    
I want to create random numbers of the normal distribution, beginning with random numbers of the uniform distribution by the polar method, a variation of the box muller algorithm. step by step you can see more from the well known density function of the normal distribution. So I want to see those steps from above like its now and from the front like a normal density function. hope you understand my problem :-) – jeffrey Apr 12 '12 at 21:40
up vote 4 down vote accepted

You can do without 'rejecting' any points. The following R function needs 3*n random numbers and will generate n randomly chosen points in a circle of radius r:

randp <- function(n = 1, r = 1) {
    if (n < 1 || r < 0) return(c())
    x <- rnorm(n)
    y <- rnorm(n)
    r <- r * sqrt(runif(n)/(x^2 + y^2))
    if (n == 1) U <- c(x, y)
    else        U <- cbind(r*x, r*y)
    return(U)
}
share|improve this answer
1  
Can you elaborate, or provide a reference? I rewrote your formula, for a single element, as xj = sqrt(unifj)* cos(thetaj) . It's not clear to me that the square root of a uniform r.v. multiplied by the cosine of a sort-of normally distributed angle yields a uniform r.v. . – Carl Witthoft Apr 13 '12 at 14:09
    
Interesting. But I think throwing away the points outside the circle is faster: A (circle) = πr² = π; A (square) = a² = 4 Throwing away => needs to generate 4 / π pairs of uniform random numbers = 8 / π = ca. 2.55 random numbers per point < 3 random numbers per point. And normal random numbers take longer to generate than uniform ones (for me about 3 times as long). – cbeleites Apr 13 '12 at 15:01
2  
@Carl This is mentioned somewhere in D. Knuth (1981). The Art of Computer Programming, Vol. 2: Seminumerical Algorithms, Chapt. 3: Random Numbers. I don't have it at hand right now. You may have a look at "Three Different Algorithms for Generating Uniformly Distributed Random Points on the N-Sphere" <www-alg.ist.hokudai.ac.jp/~jan/randsphere.pdf> for a reason why the normal distribution comes in. – Hans Werner Apr 13 '12 at 15:03
    
@Hans-Werner: So it gets faster when the dimensionality grows. Good to know! Thx. – cbeleites Apr 13 '12 at 15:33
    
@Hans Thanks for the references. Always fun to learn new things. – Carl Witthoft Apr 13 '12 at 15:38

To plot points, you need both x and y coordinates. ...But since your square is from -1 to 1, you also need to scale the points (or change the square):

x = runif(100, min=-1, max=1)
y = runif(100, min=-1, max=1)
points(x,y)

UPDATE

Here's a function that generates random numbers on a circle. It uses rejection to discard points outside the circle. It uses an (in my opinion) interesting way to do so: It generates a batch of numbers, rejects some and then generates some more until enough values are available. This is typically much more efficient than generating one number at a time...

UPDATE AGAIN I improved the speed by not appending the new batch until the end. Also added speed comparisons.

rndCircle <- function(n = 100, r=1) {
    scale <- 1.15 # Generate 15% more values than requested
    m <- matrix(0, 0, 2, dimnames=list(NULL, c('x','y')))
    lst <- list(m)
    nMore <- n
    while (nMore > 0) {
      #cat("nMore=", nMore, "\n") # uncomment to see how many iterations are needed

      m <- matrix(runif(floor(nMore*scale)*2, min=-1, max=1), ncol=2)
      m <- m[rowSums(m*m) <= 1, , drop=FALSE]
      nMore <- nMore - nrow(m)
      lst[[length(lst)+1L]] <- m
    }

    # Combine and truncate to desired length
    do.call(rbind, lst)[seq_len(n),]*r
}
# Measure performance
set.seed(42); system.time( rndCircle(1e6) ) # 0.19

# Compare to @Hans Werner's solution
set.seed(42); system.time( randp(1e6) )     # 0.26
share|improve this answer
    
ok, that works :-) – jeffrey Apr 12 '12 at 20:42
    
how can I make the restriction that q=x^2+y^2 mustn't be 0 or >1, if that condition is false, new random numbers should be created like you posted? – jeffrey Apr 12 '12 at 20:45
    
@jeffrey - I updated the answer. – Tommy Apr 12 '12 at 21:14
    
@Tommy: you've just (sort of) reinvented one of the popular "rejection method" of generating random numbers from an arbitrary distribution function. If you're interested, read things like "Numerical Recipes in C" chapter 7.3 – Carl Witthoft Apr 12 '12 at 21:15
    
@CarlWitthoft - Well, I didn't reinvent it - I just reimplemented it ;-) Haven't read that particular chapter though. – Tommy Apr 12 '12 at 21:22

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