# quantiles of sums using copula distributions too slow

Trying to create a table for quantiles of the sum of two dependent random variables using built-in copula distributions (Clayton, Frank, Gumbel) with Beta marginals. Tried `NProbability` and `FindRoot` with various methods -- not fast enough. An example of the copula-marginal combinations I need to explore is the following:

``````nProbClayton[t_?NumericQ, c_?NumericQ] :=
NProbability[  x + y <= t, {x, y}  \[Distributed]
``````

For a single evaluation of the numeric probability using

``````nProbClayton[1.9, 1/10] // Timing // Quiet
``````

I get

``````{4.914, 0.939718}
``````

on a Vista 64bit Core2 Duo T9600 2.80GHz machine (MMA 8.0.4)

To get a quantile of the sum, using

``````FindRoot[nProbClayton[q, 1/10] == 1/100, {q, 1, 0, 2}// Timing // Quiet
``````

with various methods

``````( `Method -> Automatic`, `Method -> "Brent"`, `Method -> "Secant"` )
``````

takes about a minute to find a single quantile: Timings are

``````{48.781, {q -> 0.918646}}
{50.045, {q -> 0.918646}}
{65.396, {q -> 0.918646}}
``````

For other copula-marginal combinations timings are marginally better.

Need: any tricks/methods to improve timings.

-

The CDF of a Clayton-Pareto copula with parameter `c` can be calculated according to

``````cdf[c_] := Module[{c1 = CDF[BetaDistribution[8, 2]]},
(c1[#1]^(-1/c) + c1[#2]^(-1/c) - 1)^(-c) &]
``````

Then, `cdf[c][t1,t2]` is the probability that `x<=t1` and `y<=t2`. This means that you can calculate the probability that `x+y<=t` according to

``````prob[t_?NumericQ, c_?NumericQ] :=
NIntegrate[Derivative[1, 0][cdf[c]][x, t - x], {x, 0, t}]
``````

The timings I get on my machine are

``````prob[1.9, .1] // Timing

(* ==> {0.087518, 0.939825} *)
``````

Note that I get a different value for the probability from the one in the original post. However, running `nProbClayton[1.9,0.1]` produces a warning about slow convergence which could mean that the result in the original post is off. Also, if I change `x+y<=t` to `x+y>t` in the original definition of `nProbClayton` and calculate `1-nProbClayton[1.9,0.1]` I get `0.939825` (without warnings) which is the same result as above.

For the quantile of the sum I get

``````FindRoot[prob[q, .1] == .01, {q, 1, 0, 2}] // Timing

(* ==> {1.19123, {q -> 0.912486}} *)
``````

Again, I get a different result from the one in the original post but similar to before, changing `x+y<=t` to `x+y>t` and calculating `FindRoot[nProbClayton[q, 1/10] == 1-1/100, {q, 1, 0, 2}]` returns the same value for `q` as above.

-
Thank you so much! This is the kind of method I was hoping for. I get similar timings and the same final result for `q`, but `prob[.1, 1.9] // Timing` gives `(* ==> {0.1089999,1.6476002080383803`*^-10}*)` on my machine. – kglr Nov 12 '11 at 17:34
@kguler that should have been `prob[1.9, 0.1]`. I had `c` and `t` reversed in a previous version but I'd forgotten to change it in my answer. I've fixed it now. – Heike Nov 12 '11 at 17:43
A minor modification of `cdf` to `cdf[c_] := Module[{c1 = CDF[BetaDistribution[8, 2]],c2 = CDF[BetaDistribution[8, 2]]}, (c1[#1]^(-1/c) + c2[#2]^(-1/c) - 1)^(-c) &]` works as a template for arbitrary bivariate distributions. Regarding `<=` in original post, yes, your suggested change or simplychanging `<=` to `<` in `nProbClayton` gives `0.939825` and no `slwcon` warnings. – kglr Nov 12 '11 at 17:53