fun.auto.bimodal.pml: Fitting mixture of generalied lambda distribtions to data...
In GLDEX: Fitting Single and Mixture of Generalised Lambda Distributions
fun.auto.bimodal.pml R Documentation
Fitting mixture of generalied lambda distribtions to data using
parition maximum likelihood estimation
Description
This function will fit mixture of generalised lambda distributions to dataset.
It is restricted to two generalised lambda distributions. The method of fitting
is parition maximum likelihood. It is a two step optimization procedure, each
unimodal part of the bimodal distribution is modelled using the maximum
likelihood method or the starship method (FMKL GLD only). These initial values
the used to "maximise" the complete log likelihood for the entire bimodal
distribution. It fits mixture of the form p*(f1)+(1-p)*(f2) where f1 and f2 are
pdfs of the generalised lambda distributions.
Usage
fun.auto.bimodal.pml(data, clustering.m = clara, init1.sel = "rprs",
init2.sel = "rprs", init1=c(-1.5, 1.5), init2=c(-1.5, 1.5), leap1=3, leap2=3,
fun1="runif.sobol", fun2="runif.sobol",no=10000,max.it=5000, optim.further="Y")
Arguments
data
A numerical vector representing the dataset.
clustering.m
Clustering method used in classifying the dataset into
two parts. Valid arguments include clara, fanny and pam from the cluster
library. Default is clara. Or a logical vector specifying how data should
be split.
init1.sel
This can be "rprs", "rmfmkl" or "star",
the initial method used to fit the first distribution.
init2.sel
This can be "rprs", "rmfmkl" or "star",
the initial method used to fit the second distribution.
init1
Inititial values lambda3 and lambda4 for the first generalised
lambda distribution.
init2
Inititial values lambda3 and lambda4 for the second generalised
lambda distribution.
leap1
See scrambling argument in fun.gen.qrn.
fun1
A character string of either "runif.sobol" (default), "runif.sobol.owen",
"runif.halton" or "QUnif".
leap2
See scrambling argument in fun.gen.qrn.
fun2
A character string of either "runif.sobol" (default), "runif.sobol.owen",
"runif.halton" or "QUnif".
no
Number of initial random values to find the best initial values for
optimisation.
max.it
Maximum number of iterations for numerical optimisation.
optim.further
Whether to optimise the function further using full
maximum likelihood method, recommended setting is "Y"
Details
The initial values that work well for RPRS are c(-1.5,1.5) and for RMFMKL
are c(-0.25,1.5). For scrambling, if 1, 2 or 3 the
sequence is scrambled otherwise not. If 1, Owen type type of scrambling
is applied, if 2, Faure-Tezuka type of scrambling, is applied, and if
3, both Owen+Faure-Tezuka type of scrambling is applied. The star
method uses the same initial values as rmfmkl since it uses the FMKL
generalised lambda distribution. Nelder-Simplex algorithm is used in the
numerical optimization. rprs stands for revised percentile method for RS
generalised lambda distribution and "rmfmkl" stands for revised method of moment
for FMKL generalised lambda distribution. These acronyms represents the initial
optimization algorithm used to get a reasonable set of initial values for the
subsequent optimization procedues. This function is an improvement from Su
(2007) in Journal of Statistical Software.
Value
par
The best set of parameters found, the first four corresponds to the
first distribution fit, the second four corresponds to the second distribution
fit, the last value correspond to p for the first distribution fit.
value
The value of -PML for the paramters obtained.
counts
A two-element integer vector giving the number of calls to "fn"
and "gr" respectively. This excludes those calls needed to compute the Hessian,
if requested, and any calls to 'fn' to compute a finite-difference approximation
to the gradient.
convergence
0 indicates successful convergence, 1
indicates the iteration limit maxit had been reached, 10 indicates
degeneracy of the Nelder-Mead simplex.
message
A character string giving any additional information returned by
the optimizer, or NULL.
Note
If the number of observations is small, rprs can sometimes fail as
the percentiles may not exist for this data. Also, if the initial values do not
result in a valid generalised lambda distribution, try another set of initial
values.
References
Bratley P. and Fox B.L. (1988) Algorithm 659: Implementing Sobol's quasi random
sequence generator, ACM Transactions on Mathematical Software 14, 88-100.
Joe S. and Kuo F.Y. (1998) Remark on Algorithm 659: Implementing Sobol's quasi
random Sequence Generator.
Nelder, J. A. and Mead, R. (1965) A simplex algorithm for function minimization.
Computer Journal *7*, 308-313.
Su (2007). Fitting Single and Mixture of Generalized Lambda Distributions to
Data via Discretized and Maximum Likelihood Methods: GLDEX in R. Journal of
Statistical Software: *21* 9.
See Also
fun.auto.bimodal.ml,fun.plot.fit.bm,
fun.diag.ks.g.bimodal
Examples
# Fitting faithful data from the dataset library, with the clara clustering
# regime. The first distribution is RS and the second distribution is fmkl.
fun.auto.bimodal.pml(faithful[,1],clustering.m=clara,init1.sel="rprs",
init2.sel="rmfmkl",init1=c(-1.5,1,5),init2=c(-0.25,1.5),leap1=3,leap2=3)
GLDEX documentation built on Aug. 21, 2023, 9:08 a.m.
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| fun.auto.bimodal.pml | R Documentation |
Fitting mixture of generalied lambda distribtions to data using parition maximum likelihood estimation
Description
This function will fit mixture of generalised lambda distributions to dataset. It is restricted to two generalised lambda distributions. The method of fitting is parition maximum likelihood. It is a two step optimization procedure, each unimodal part of the bimodal distribution is modelled using the maximum likelihood method or the starship method (FMKL GLD only). These initial values the used to "maximise" the complete log likelihood for the entire bimodal distribution. It fits mixture of the form p*(f1)+(1-p)*(f2) where f1 and f2 are pdfs of the generalised lambda distributions.
Usage
fun.auto.bimodal.pml(data, clustering.m = clara, init1.sel = "rprs",
init2.sel = "rprs", init1=c(-1.5, 1.5), init2=c(-1.5, 1.5), leap1=3, leap2=3,
fun1="runif.sobol", fun2="runif.sobol",no=10000,max.it=5000, optim.further="Y")
Arguments
data |
A numerical vector representing the dataset. |
clustering.m |
Clustering method used in classifying the dataset into two parts. Valid arguments include clara, fanny and pam from the cluster library. Default is clara. Or a logical vector specifying how data should be split. |
init1.sel |
This can be |
init2.sel |
This can be |
init1 |
Inititial values lambda3 and lambda4 for the first generalised lambda distribution. |
init2 |
Inititial values lambda3 and lambda4 for the second generalised lambda distribution. |
leap1 |
See scrambling argument in |
fun1 |
A character string of either |
leap2 |
See scrambling argument in |
fun2 |
A character string of either |
no |
Number of initial random values to find the best initial values for optimisation. |
max.it |
Maximum number of iterations for numerical optimisation. |
optim.further |
Whether to optimise the function further using full maximum likelihood method, recommended setting is "Y" |
Details
The initial values that work well for RPRS are c(-1.5,1.5) and for RMFMKL
are c(-0.25,1.5). For scrambling, if 1, 2 or 3 the
sequence is scrambled otherwise not. If 1, Owen type type of scrambling
is applied, if 2, Faure-Tezuka type of scrambling, is applied, and if
3, both Owen+Faure-Tezuka type of scrambling is applied. The star
method uses the same initial values as rmfmkl since it uses the FMKL
generalised lambda distribution. Nelder-Simplex algorithm is used in the
numerical optimization. rprs stands for revised percentile method for RS
generalised lambda distribution and "rmfmkl" stands for revised method of moment
for FMKL generalised lambda distribution. These acronyms represents the initial
optimization algorithm used to get a reasonable set of initial values for the
subsequent optimization procedues. This function is an improvement from Su
(2007) in Journal of Statistical Software.
Value
par |
The best set of parameters found, the first four corresponds to the first distribution fit, the second four corresponds to the second distribution fit, the last value correspond to p for the first distribution fit. |
value |
The value of -PML for the paramters obtained. |
counts |
A two-element integer vector giving the number of calls to "fn" and "gr" respectively. This excludes those calls needed to compute the Hessian, if requested, and any calls to 'fn' to compute a finite-difference approximation to the gradient. |
convergence |
|
message |
A character string giving any additional information returned by
the optimizer, or |
Note
If the number of observations is small, rprs can sometimes fail as
the percentiles may not exist for this data. Also, if the initial values do not
result in a valid generalised lambda distribution, try another set of initial
values.
References
Bratley P. and Fox B.L. (1988) Algorithm 659: Implementing Sobol's quasi random sequence generator, ACM Transactions on Mathematical Software 14, 88-100.
Joe S. and Kuo F.Y. (1998) Remark on Algorithm 659: Implementing Sobol's quasi random Sequence Generator.
Nelder, J. A. and Mead, R. (1965) A simplex algorithm for function minimization. Computer Journal *7*, 308-313.
Su (2007). Fitting Single and Mixture of Generalized Lambda Distributions to Data via Discretized and Maximum Likelihood Methods: GLDEX in R. Journal of Statistical Software: *21* 9.
See Also
fun.auto.bimodal.ml,fun.plot.fit.bm,
fun.diag.ks.g.bimodal
Examples
# Fitting faithful data from the dataset library, with the clara clustering
# regime. The first distribution is RS and the second distribution is fmkl.
fun.auto.bimodal.pml(faithful[,1],clustering.m=clara,init1.sel="rprs",
init2.sel="rmfmkl",init1=c(-1.5,1,5),init2=c(-0.25,1.5),leap1=3,leap2=3)
R Package Documentation
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