# Wrong Hessian from optim in R

I am doing some Extreme Values analysis. I don't want to use the fevd package for a variety of reasons (the first I want to be able to tweak some things that I cannot do otherwise). I wrote my own code. It is mostly very simple, and I thought I had solved everything. But for some parameter combinations, the Hessian coming out of my log-likelihood analysis (based on optim ) will not be correct.

Going over one step at the time. My code - or selected part of it - looks like this:

``````# routines for non stationary
Log_lik_GEV <- function(dataIN,scaleIN,shapeIN,locationIN){
# simply calculate the negative log likelihood value for a set of X and parameters, for the GPD
#xi, mu, sigma  - xi is the shape parameter, mu the location parameter, and sigma is the scale parameter.
# shape = xi
# location = mu
# scale = beta
library(fExtremes)
#dgev   Density of the GEV Distribution, dgev(x, xi = 1, mu = 0, sigma = 1)

LLvalues <- dgev(dataIN, xi = shapeIN, mu = locationIN, beta = scaleIN)
NLL <- -sum(log(LLvalues[is.finite(LLvalues)]))
return(NLL)
}

function_MLE <- function(par , dataIN){
scoreLL <- 0
shape_param <- par[1]
scale_param <- par[2]
location_param <- par[3]
scoreLL <- Log_lik_GEV(dataIN, scale_param, shape_param, location_param)
if (abs(shape_param) > 0.3) scoreLL <- scoreLL*10000000
if ((scale_param) <= 0) {
scale_param <- abs(scale_param)
par[2] <- abs(scale_param)
scoreLL <- scoreLL*1000000000
}
sum(scoreLL)
}

kernel_estimation <- function(dati_AM, shape_o, scale_o, location_o) {

paramOUT <- optim(par = c(shape_o, scale_o, location_o), fn = function_MLE, dataIN = dati_AM, control = list(maxit = 3000, reltol = 0.00000001), hessian = TRUE)

# calculation std errors
covmat <- solve(paramOUT\$hessian)
stde <- sqrt(diag(covmat))
print(covmat)

print('')

result <- list(shape_gev =paramOUT\$par[1], scale_gev = paramOUT\$par[2],location_gev =paramOUT\$par[3], var_covar = covmat)

return(result)
}
``````

Everything works great, in some cases. If I run my routines and the fevd routines, I get exactly the same results. In some cases (in my specific case when shape=-0.29 so strongly negative/weibull), my routine will give negative variances and funky hessians. It is not always wrong, but some parameter combinations are clearly not giving valid hessian (Note: the parameters are still estimated correctly, meaning are identical to the fevd results, but the covariance matrix is completely off).

I found this post that compared the hessian from two procedures, and indeed optim seems to be flaky. However, if I simply substitute maxLik in my routine, it just doesn't converge at all (even in those cases when the convergence was happening).

`````` paramOUT = maxLik(function_MLE, start =c(shape_o, scale_o, location_o),
dataIN=dati_AM, method ='NR' )
``````

I tried to give different initial values - even the correct ones - but it just doesn't converge.

I am not supplying data because I think that the optim routine is used correctly in my example. Simply, the numerical results are not stable for some parameter combination. My question is:

1) Am I missing something in the way I use maxLik?

2) Are there other optimization routines, besides maxLik, from which I can extract the hessian?

thanks

• You need to provide some minimal data for testing, otherwise it is impossible to provide any input. And proper indentation is also very helpful :) – tguzella Aug 20 '15 at 21:16
• The package numDeriv might help. You can take the optimal values of the estimation (par*). Then do `hessian(function_MLE,par*,dataIN)` – DJJ Aug 20 '15 at 21:22
• @DJJ Thanks, I will look into this. – claude Aug 20 '15 at 21:37
• @tguzella thanks for editing my code. I don't think data are important here. My original routine is right, just the numerical hessian is unstable. I will edit my question to make more clear what I want. thanks. – claude Aug 20 '15 at 22:25
• My two questions above remain, however I found the issue with the hessian from optim and the difference with fevd. fevd states: "uses the actual gradient of the negative log-likelihood. If this fails, or the Hessian matrix cannot be inverted, or there are any negative values along the diagonal in the inverted Hessian, then a second attempt is made using finite differences". Optim simply uses the gradient method. I found nlme::fdHess to calculate the finite difference hessian, and I get the same results as fevd. – claude Aug 20 '15 at 23:38