# Scheme Monte-Carlo-Sampling

I am trying to determine the number of marbles that fall within a given circle (radius 1) given that they have random x and y coordinates.

My overall goal is to find an approximate value for pi by using monte carlo sampling by multiplying by 4 the (number of marbles within the circle)/(total number of marbles).

I intended for my function to count the number of marbles within the circle, but I am having trouble following why it does not work. Any help on following the function here would be appreciated.

Please comment if my above request for help is unclear.

``````(define(monte-carlo-sampling n)
(let ((x (- (* 2 (random)) 1))
(y (- (* 2 (random)) 1)))
(cond((= 0 n)
* 4 (/ monte-carlo-sampling(+ n 1) n)
((> 1 n)
(cond((< 1 (sqrt(+ (square x) (square y))) (+ 1 (monte-carlo-sampling(- n 1)))))
((> 1 (sqrt(+ (square x) (square y))) (monte-carlo-sampling(- n 1))))
)))))
``````
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So what do you mean by "it does not work" –  Blorgbeard Sep 10 at 2:09

I wrote a solution to this problem at my blog; the inner function is called `sand` because I was throwing grains of sand instead of marbles:

``````(define (pi n)
(define (sand?) (< (+ (square (rand)) (square (rand))) 1))
(do ((i 0 (+ i 1)) (p 0 (+ p (if (sand?) 1 0))))
((= i n) (exact->inexact (* 4 p (/ n))))))
``````

This converges very slowly; after a hundred thousand iterations I had 3.14188. The blog entry also discusses a method for estimating pi developed by Archimedes over two hundred years before Christ that converges very quickly, with 27 iterations taking us to the bound of double-precision arithmetic.

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Your parentheses are all messed up, and your argument order for `<` is wrong. Here's how the code should look like after it's corrected:

``````(define (monte-carlo-sampling n)
(let ((x (- (* 2 (random)) 1))
(y (- (* 2 (random)) 1)))
(cond ((= n 0)
0)
(else
(cond ((< (sqrt (+ (square x) (square y))) 1)
(+ 1 (monte-carlo-sampling (- n 1))))
(else
(monte-carlo-sampling (- n 1))))))))
``````

This returns the number of hits. You'd have to convert the number of hits into a pi estimate using an outer function, such as:

``````(define (estimate-pi n)
(* 4 (/ (monte-carlo-sampling n) n)))
``````

Here's how I'd write the whole thing, if it were up to me:

``````(define (estimate-pi n)
(let loop ((i 0)
(hits 0))
(cond ((>= i n)
(* 4 (/ hits n)))
((<= (hypot (sub1 (* 2 (random)))
(sub1 (* 2 (random)))) 1)
(else
``````

(Tested on Racket, using the definition of `hypot` I gave in my last answer. If you're not using Racket, you have to change `add1` and `sub1` to something appropriate.)

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Here's a general method of doing monte-carlo it accepts as arguments the number of iterations, and a thunk (procedure with no arguments) that should return #t or #f which is the experiment to be run each iteration

``````(define (monte-carlo trials experiment)
(define (iter trials-remaining trials-passed)
(cond ((= trials-remaining 0)
(/ trials-passed trials))
((experiment)
(iter (- trials-remaining 1) (+ trials-passed 1)))
(else
(iter (- trials-remaining 1) trials-passed))))
(iter trials 0))
``````

Now it's just a mater of writing the specific experiment

You could write in your experiment where experiment is invoked in monte-carlo, but abstracting here gives you a much more flexible and comprehensible function. If you make a function do too many things at once it becomes hard to reason about and debug.

``````(define (marble-experiment)
(let ((x ...)  ;;assuming you can come up with
(y ...)) ;;a way to get a random x between 0 and 1
;;with sufficient granularity for your estimate)
(< (sqrt (+ (* x x) (* y y))) 1)))

(define pi-estimate
(* 4 (monte-carlo 1000 marble-experiment)))
``````
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