# Possible infinite loop on math equation?

I have the following problem, and am having trouble understanding part of the equation:

Monte Carlo methods to estimate an integral is basically, take a lot of random samples and determined a weighted average. For example, the integral of f(x) can be estimated from N independent random samples xr by

alt text http://www.goftam.com/images/area.gif

for a uniform probability distribution of xr in the range [x1, x2]. Since each function evaluation f(xr) is independent, it is easy to distribute this work over a set of processes.

What I don't understand is what f(xr) is supposed to do? Does it feed back into the same equation? Wouldn't that be an infinite loop?

It should say f(xi)

f() is the function we are trying to integrate via the numerical monte carlo method, which estimates an integral (and its error) by evaluating randomly choosen points from the integration region.

Ref.

• I'd rather change the summation index to r, and the limits of integration to a and b. That way there is no confusion about the x_i's. Feb 26, 2009 at 3:33
• x_i is fairly standard notation. Feb 26, 2009 at 3:34
• It's bad notation either way, because x1 and x2 are the limits of your integral. You want the xi or xr, whichever you prefer, to be randomly distributed in [x1,x2]. Feb 26, 2009 at 3:35
• I disagree that it's bad notation. Like many things in Mathematics there are accepted forms that are used. To me x_i seems very natural Feb 26, 2009 at 3:36
• Re the notation: xi by itself is fine notation, and obviously accepted throughout math. The summation is over i from 1 to N, which means it also includes i=1 and i=2. That means that part of your sum is f(x1) and f(x2), which are the value of your function at the endpoints. You may not want this. Feb 26, 2009 at 3:39

Your goal is to compute the integral of `f` from `x1` to `x2`. For example, you may wish to compute the integral of `sin(x)` from `0` to `pi`.

Using Monte Carlo integration, you can approximate this by sampling random points in the interval `[x1,x2]` and evaluating `f` at those points. Perhaps you'd like to call this `MonteCarloIntegrate( f, x1, x2 )`.

So no, `MonteCarloIntegrate` does not "feed back" into itself. It calls a function `f`, the function you are trying to numerically integrate, e.g. `sin`.

• Thank, this is what I was looking for. Feb 26, 2009 at 4:23
• @Mitch Wheat: and +1 for you. =) Feb 26, 2009 at 6:07

Replace `f(x_r)` by `f(x_r_i)` (read: f evaluated at `x` sub `r` sub `i`). The `r_i` are chosen uniformly at random from the interval `[x_1, x_2]`.

The point is this: the area under `f` on `[x_1, x_2]` is equal to `(x_2 - x_1)` times the average of `f` on the interval `[x_1, x_2]`. That is

``````A = (x_2 - x_1) * [(1 / (x_2 - x_1)) * int_{x_1}^{x_2} f(x)\, dx]
``````

The portion in square brackets is the average of `f` on `[x_1, x_2]` which we will denote `avg(f)`. How can we estimate the average of `f`? By sampling it at `N` random points and taking the average value of `f` evaluated at those random points. To wit:

``````avg(f) ~ (1 / N) * sum_{i=1}^{N} f(x_r_i)
``````

where `x_r_1, x_r_2, ..., x_r_N` are points chosen uniformly at random from [x_1, x_2].

Then

``````A = (x_2 - x_1) * avg(f) ~ (x_2 - x_1) * (1 / N) * sum_{i=1}^{N} f(x_r_i).
``````

Here is another way to think about this equation: the area under `f` on the interval `[x_1, x_2]` is the same as the area of a rectangle with length `(x_2 - x_1)` and height equal to the average height of `f`. The average height of `f` is approximately

``````(1 / N) * sum_{i=1}^{N} f(x_r_i)
``````

which is value that we produced previously.

Whether it's xi or xr is irrelevant - it's the random number that we're feeding into function f().

I'm more likely to write the function (aside from formatting) as follows:

(x2-x1) * sum(f(xi))/N

That way, we can see that we're taking the average of N samples of f(x) to get an average height of the function, then multiplying by the width (x2-x1).

Because, after all, integration is just calculating area under the curve. (Nice pictures at http://hyperphysics.phy-astr.gsu.edu/Hbase/integ.html#c4.

x_r is a random value from the integral's range.

Substituting Random(x_1, x_2) for x_r would give an equivalent equation.