Description Usage Arguments Details Value Note Author(s) References See Also
This ia an auxiliary function used to control the iterations for nlgamlss
fitting. Typically
only used when calling nlgamlss
function with the option control
.
Since the nlgamlss
uses nlm
for fitting all of the NL.control
argument are passed to
nlm
.
1 2 3 4 | NL.control(fscale = 1, typsize = NULL, stepmax = NULL, iterlim = 100,
ndigit = 10, steptol = 1e-05,
gradtol = 1e-05, print.level = 0, check.analyticals = TRUE,
hessian = TRUE)
|
fscale |
an estimate of the size of log-likelihood at the minimum with default equal 1. |
typsize |
this argument is passed to |
stepmax |
this argument is passed to |
iterlim |
a positive integer specifying the maximum number of iterations to be performed before the program is terminated. The default is 100 |
ndigit |
the number of significant digits in the log-likelihood function. The default is 10 |
steptol |
A positive scalar providing the minimum allowable relative step length. The defaults is 1e-05 |
gradtol |
a positive scalar giving the tolerance at which the scaled gradient is considered close enough to zero to terminate the algorithm. The scaled gradient is a measure of the relative change in log-likelihood in each direction 'p[i]' divided by the relative change in 'p[i]'. The default is 1e-05 |
print.level |
this argument determines the level of printing which is done during the minimization process. The default value of '0' means that no printing occurs, a value of '1' means that initial and final details are printed and a value of 2 means that full tracing information is printed. |
check.analyticals |
a logical scalar specifying whether the analytic gradients and Hessians, if they are supplied, should be checked against numerical derivatives at the initial parameter values. This can help detect incorrectly formulated gradients or Hessians. |
hessian |
if |
See the R function nlm
and the fist two refernces below for details of the algotithm.
A list with the arguments as components.
This functions supports the function nlgamlss
Mikis Stasinopoulos d.stasinopoulos@londonmet.ac.uk, Bob Rigby r.rigby@londonmet.ac.uk
Dennis, J. E. and Schnabel, R. B. (1983) Numerical Methods for Unconstrained Optimization and Nonlinear Equations. Prentice-Hall, Englewood Cliffs, NJ.
Schnabel, R. B., Koontz, J. E. and Weiss, B. E. (1985) A modular system of algorithms for unconstrained minimization. ACM Trans. Math. Software, 11, 419-440.
Rigby, R. A. and Stasinopoulos D. M. (2005). Generalized additive models for location, scale and shape,(with discussion), Appl. Statist., 54, part 3, pp 507-554.
Stasinopoulos D. M., Rigby R.A. and Akantziliotou C. (2003) Instructions on how to use the GAMLSS package in R. Accompanying documentation in the current GAMLSS help files, (see also http://www.gamlss.com/).
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