```
library(nlme)
mydat <-
structure(list(class = c(91L, 91L, 91L, 91L, 91L, 91L, 92L, 92L,
92L, 92L, 92L, 92L, 92L, 92L, 92L, 92L, 92L, 92L, 92L, 92L, 92L,
92L, 93L, 93L, 93L, 94L, 94L, 94L, 94L, 94L, 94L, 94L, 94L, 94L,
94L, 94L, 94L, 94L, 95L, 95L, 95L, 95L, 95L, 95L, 95L, 95L, 95L,
95L, 95L, 95L), days = c(5.7, 11.1, 13.9, 15.3, 18.3, 18.9, 1.9,
2.1, 2.9, 3.4, 4.4, 5, 6.9, 10.4, 11.6, 13, 13.4, 15.7, 15.9,
17.3, 17.7, 19.4, 2.3, 12.6, 15.4, 2, 2.4, 4.9, 5.4, 5.7, 7,
7.1, 7.7, 9.1, 9.6, 12.6, 16.6, 17.1, 1, 2, 4.4, 5.6, 5.7, 10.4,
12.1, 12.9, 13, 15.6, 16.1, 18.6), outcome = c(3.31586988521325,
3.26226473964254, 3.26098046236747, 3.26086828734987, 3.26081582971007,
3.2608136610639, 1.54175217273846, 1.74336277564818, 2.48010804039677,
2.73455940271066, 2.86602619542132, 2.85753365781511, 2.81667209739959,
2.80430238913247, 2.80395479988755, 2.80383291979961, 2.8038189189449,
2.80379174103878, 2.80379113213262, 2.80378896928776, 2.80378871890839,
2.80378827755366, 1.96537220180574, 3.00124636046136, 3.00096700482166,
2.05608815148142, 2.44248026102198, 4.03918455971327, 4.08570704450138,
4.09781416453829, 4.09869791687544, 4.09759058744364, 4.09084045815843,
4.07921200433542, 4.07668896637335, 4.07081047825795, 4.06993724272757,
4.06991925387706, 1.07225026715462, 3.72090308875724, 4.93988448353623,
4.7209971449984, 4.70681751285687, 4.49435510591282, 4.48824648431355,
4.4870870783591, 4.48698191392076, 4.48574152736339, 4.48566703246688,
4.48551396890595), s = c(0.0693, 0.0693, 0.0693, 0.0693, 0.0693,
0.0693, 0.0693, 0.0693, 0.0693, 0.0693, 0.0693, 0.0693, 0.0693,
0.0693, 0.0693, 0.0693, 0.0693, 0.0693, 0.0693, 0.0693, 0.0693,
0.0693, 0.0693, 0.0693, 0.0693, 0.0693, 0.0693, 0.0693, 0.0693,
0.0693, 0.0693, 0.0693, 0.0693, 0.0693, 0.0693, 0.0693, 0.0693,
0.0693, 0.0693, 0.0693, 0.0693, 0.0693, 0.0693, 0.0693, 0.0693,
0.0693, 0.0693, 0.0693, 0.0693, 0.0693)), .Names = c("class",
"days", "outcome", "s"), row.names = 1001:1050, class = "data.frame")
library(nlme)
obj_NM <- function(arg){
model = nlme(outcome ~ exp(beta1) * s * days / (s * days + exp(1 - beta3 * s * days)) +
exp(beta2) * exp(1 - beta4 * s * days) / (s * days + exp(1 - beta4 * s * days)),
data = mydat,
fixed = list(beta1 ~ 1, beta2 ~ 1, beta3 ~ 1, beta4 ~ 1),
random = list(class = pdDiag(list(beta1 ~ 1, beta2 ~ 1, beta4 ~ 1))),
start = list(fixed = c(beta1 = arg[1], beta2 = arg[2], beta3 = arg[3], beta4 = arg[4])), verbose = FALSE)
return(model$logLik)
}
control = list(fnscale = -1)
optim(par = c(1.310239, -4.668217, 17.01345, 2.402943), fn = obj_NM, hessian = TRUE, control = control)
```

Running the above code gives me the error and warning:

```
Error in chol.default((value + t(value))/2) :
the leading minor of order 2 is not positive definite In addition: Warning messages:
1: In nlme.formula(outcome ~ exp(beta1) * s * days/(s * days + exp(1 - :
Singular precision matrix in level -1, block 1
2: In nlme.formula(outcome ~ exp(beta1) * s * days/(s * days + exp(1 - :
Singular precision matrix in level -1, block 1
```

My goal here is to obtain the hessian matrix and investigate why my `nlme`

model may not be fitting. I am trying to maximize my objective function, therefore I set `fnscale = -1`

(documentation says that it should be negative in order for `optim`

to perform maximization). However, I am not sure what to make of the error message. Is there a way for `optim`

to output the hessian matrix? It seems that an error from `nlme`

has stopped it from doing so.

actuallytrying to achieve is to find the value of the Hessian at the point arrived at by nlme, then wrapping inside optim is completely the wrong approach. Instead you should either 1) just use a numerical Hessian method such as e.g.`pracma::hessian`

(with parameter values from nlmeObject providing the input values to the hessian calculation. Or 2) since your formula looks pretty simple, just solve the hessian matrix analytically by symbolic differentiation. – dww Aug 18 '17 at 15:27