The `prob`

package numerically evaluates characteristic functions for base R distributions. For almost all distributions there are existing formulas. For a few cases, though, no closed-form solution is known. Case in point: the Weibull distribution (but see below).

For the Weibull characteristic function I essentially compute two integrals and put them together:

```
fr <- function(x) cos(t * x) * dweibull(x, shape, scale)
fi <- function(x) sin(t * x) * dweibull(x, shape, scale)
Rp <- integrate(fr, lower = 0, upper = Inf)$value
Ip <- integrate(fi, lower = 0, upper = Inf)$value
Rp + (0+1i) * Ip
```

Yes, it's clumsy, but it works surprisingly well! ...*ahem*, most of the time. A user reported recently that the following breaks:

```
cfweibull(56, shape = 0.5, scale = 1)
Error in integrate(fr, lower = 0, upper = Inf) :
the integral is probably divergent
```

Now, we know that the integral isn't divergent, so it must be a numerical problem. With some fiddling I could get the following to work:

```
fr <- function(x) cos(56 * x) * dweibull(x, 0.5, 1)
integrate(fr, lower = 0.00001, upper = Inf, subdivisions=1e7)$value
[1] 0.08024055
```

That's OK, but it isn't quite right, plus it takes a fair bit of fiddling which doesn't scale well. I've been investigating this for a better solution. I found a recently published "closed-form" for the characteristic function with `scale > 1`

(see here), but it involves Wright's generalized confluent hypergeometric function which isn't implemented in R (yet). I looked into the archives for `integrate`

alternatives, and there's a ton of stuff out there which doesn't seem very well organized.

As part of that searching it occurred to me to translate the region of integration to a finite interval via the inverse tangent, and *voila*! Check it out:

```
cfweibull3 <- function (t, shape, scale = 1){
if (shape <= 0 || scale <= 0)
stop("shape and scale must be positive")
fr <- function(x) cos(t * tan(x)) * dweibull(tan(x), shape, scale)/(cos(x))^2
fi <- function(x) sin(t * tan(x)) * dweibull(tan(x), shape, scale)/(cos(x))^2
Rp <- integrate(fr, lower = 0, upper = pi/2, stop.on.error = FALSE)$value
Ip <- integrate(fi, lower = 0, upper = pi/2, stop.on.error = FALSE)$value
Rp + (0+1i) * Ip
}
> cfweibull3(56, shape=0.5, scale = 1)
[1] 0.08297194+0.07528834i
```

## Questions:

- Can you do better than this?
- Is there something about numerical integration routines that people who are expert about such things could shed some light on what's happening here? I have a sneaking suspicion that for large
`t`

the cosine fluctuates rapidly which causes problems...? - Are there existing R routines/packages which are better suited for this type of problem, and could somebody point me to a well-placed position (on the mountain) to start the climb?

## Comments:

- Yes, it is bad practice to use
`t`

as a function argument. - I calculated the exact answer for
`shape > 1`

using the published result with Maple, and the`brute-force-integrate-by-the-definition-with-R`

kicked Maple's ass. That is, I get the same answer (up to numerical precision) in a small fraction of a second and an even smaller fraction of the price.

## Edit:

I was going to write down the exact integrals I'm looking for but it seems this particular site doesn't support MathJAX so I'll give links instead. I'm looking to numerically evaluate the characteristic function of the Weibull distribution for reasonable inputs `t`

(whatever that means). The value is a complex number but we can split it into its real and imaginary parts and that's what I was calling `Rp`

and `Ip`

above.

One final comment: Wikipedia has a formula listed (an infinite series) for the Weibull c.f. and that formula matches the one proved in the paper I referenced above, **however**, that series has only been proved to hold for `shape > 1`

. The case `0 < shape < 1`

is still an open problem; see the paper for details.

`?integrate... integrate(f, lower, upper, ..., subdivisions=100, rel.tol = .Machine$double.eps^0.25, abs.tol = rel.tol, stop.on.error = TRUE, keep.xy = FALSE, aux = NULL)`

. So what happens if you increase to`subdivisions = 1e4`

, for example? – Carl Witthoft Sep 15 '12 at 19:43`subdivisions = 1e7`

). I'd like to avoid the fiddling if possible, but maybe it's not possible. If it's not possible because`dweibull`

is tricky, that's OK, but I don't want it to be because of ignorance on my part w.r.t. numerical integration methods (in R). – G. Jay Kerns Sep 15 '12 at 21:32