# Finding a gradient function for a fitted nonparametric model to use in an optimizer

I've got a model, y=f(x,z,a). I want to optimize that model (eventually subject to constraints). Numerical optimizers in R are a lot faster when one has a gradient function. But I have fit my model nonparametrically, so therefore I can't easily get the gradient analytically. Is there some way of getting a gradient function -- analogous I suppose to a fitted model object, with a predict method defined for it -- from a fitted model?

Here is some dummy code:

Define the variables:

``````x = runif(1000)*10-5
z = runif(1000)*10-5
a = runif(1000)*10-5
y = x^2+a^2+z^2 + (x*z)^2 (x*a)^2 +rnorm(1000)
``````

Fit the model:

``````library(mgcv)
m = gam(y~s(a)+te(a,z)+te(x,z))
summary(m)
par(mfrow=c(1,3))
plot(m,scheme=2)
``````

Minimize to get the smallest y:

``````f = function(par){
predict(m,newdata = data.frame(x=par[1],z=par[2],a=par[3]))
}

o = optim(par=c(0,0,0),fn=f)
``````

What I want is a gradient object, so that I can define

``````g = function(par){
}
``````

and then run

``````o = optim(par=c(0,0,0),fn=f,gr=g,method="BFGS")
``````

...which would be a lot faster given a lot of data and a complicated model and objective function.

Is what I want to do possible?

-
How complicated is your actual model? How many variables does it use? Are you certain that using numerical derivatives is too slow? – Hong Ooi Dec 13 '13 at 6:41
Actual model has 9 variables, 5 of which are subject to optimization. There are a lot of non-ignorable interactions, all represented nonparametrically. Representing them with straight lines or flat planes would basically be worthless. – generic_user Dec 13 '13 at 7:16
And yes, numerical derivatives are far too slow. Each optimization task takes ~4 minutes, and I need to do it for thousands of different parameter combinations. – generic_user Dec 13 '13 at 7:25