I asked this question a while ago. I am not sure whether I should post this as an answer or a new question. I do not have an answer but I "solved" the problem by applying the Levenberg-Marquardt algorithm using `nls.lm`

in R and when the solution is at the boundary, I run the trust-region-reflective algorithm (TRR, implemented in R) to step away from it. Now I have new questions.

From my experience, doing this way the program reaches the optimal and is not so sensitive to the starting values. But this is only a practical method to step aside from the issues I encounterd using `nls.lm`

and also other optimization functions in R. I would like to know why `nls.lm`

behaves this way for optimization problems with boundary constraints and how to handle the boundary constraints when using `nls.lm`

in practice.

Following I gave an example illustrating the two issues using `nls.lm`

.

- It is sensitive to starting values.
- It stops when some parameter reaches the boundary.

### A Reproducible Example: Focus Dataset D

```
library(devtools)
install_github("KineticEval","zhenglei-gao")
library(KineticEval)
data(FOCUS2006D)
km <- mkinmod.full(parent=list(type="SFO",M0 = list(ini = 0.1,fixed = 0,lower = 0.0,upper =Inf),to="m1"),m1=list(type="SFO"),data=FOCUS2006D)
system.time(Fit.TRR <- KinEval(km,evalMethod = 'NLLS',optimMethod = 'TRR'))
system.time(Fit.LM <- KinEval(km,evalMethod = 'NLLS',optimMethod = 'LM',ctr=kingui.control(runTRR=FALSE)))
compare_multi_kinmod(km,rbind(Fit.TRR$par,Fit.LM$par))
dev.print(jpeg,"LMvsTRR.jpeg",width=480)
```

The differential equations that describes the model/system is:

```
"d_parent = - k_parent * parent"
"d_m1 = - k_m1 * m1 + k_parent * f_parent_to_m1 * parent"
```

In the graph on the left is the model with initial values, and in the middle is the fitted model using "TRR"(similar to the algorithm in Matlab `lsqnonlin`

function ), on the right is the fitted model using "LM" with `nls.lm`

. Looking at the fitted parameters(`Fit.LM$par`

) you will find that one fitted parameter(`f_parent_to_m1`

) is at the boundary `1`

. If I change the starting value for one parameter `M0_parent`

from 0.1 to 100, then I got the same results using `nls.lm`

and `lsqnonlin`

.I have many cases like this one.

```
newpars <- rbind(Fit.TRR$par,Fit.LM$par)
rownames(newpars)<- c("TRR(lsqnonlin)","LM(nls.lm)")
newpars
M0_parent k_parent k_m1 f_parent_to_m1
TRR(lsqnonlin) 99.59848 0.09869773 0.005260654 0.514476
LM(nls.lm) 84.79150 0.06352110 0.014783294 1.000000
```

Except for the above problems, it often happens that the Hessian returned by `nls.lm`

is not invertable(especially when some parameters are on the boundary) so I cannot get an estimation of the covariance matrix. On the other hand, the "TRR" algorithm(in Matlab) almost always give an estimation by calculating the Jacobian at the solution point. I think this is useful but I am also sure that R optimization algorithms(the ones I have tried) did not do this for a reason. I would like to know whether I am wrong by using the Matlab way of calculating the covariance matrix to get standard error for the parameter estimates.

One last note, I claimed in my previous post that the Matlab `lsqnonlin`

outperforms R's optimization functions in almost all cases. I was wrong. The "Trust-Region-Reflective" algorithm used in Matlab is in fact slower(sometimes much slower) if also implemented in R as you can see from the above example. However, it is still more stable and reaches a better solution than the R's basic optimization algorithms.