https://github.com/cran/RandomFields
Tip revision: 41d603eb8a5f4bfe82c56acee957c79e7500bfd4 authored by Martin Schlather on 18 January 2022, 18:12:52 UTC
version 3.3.14
version 3.3.14
Tip revision: 41d603e
RMmodels.R
## This file has been created automatically by 'rfGenerateModels'.
RMplus <- function(C0, C1, C2, C3, C4, C5, C6, C7, C8, C9, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(C0)) submodels[['C0']] <- C0
if (hasArg(C1)) submodels[['C1']] <- C1
if (hasArg(C2)) submodels[['C2']] <- C2
if (hasArg(C3)) submodels[['C3']] <- C3
if (hasArg(C4)) submodels[['C4']] <- C4
if (hasArg(C5)) submodels[['C5']] <- C5
if (hasArg(C6)) submodels[['C6']] <- C6
if (hasArg(C7)) submodels[['C7']] <- C7
if (hasArg(C8)) submodels[['C8']] <- C8
if (hasArg(C9)) submodels[['C9']] <- C9
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMplus',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMplus <- new(CLASS_RM,
.Data = RMplus,
type = c('of manifold type'),
isotropy = c('submodel dependent'),
domain = c('submodel dependent'),
operator = TRUE,
monotone = 'submodel dependent monotonicity',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = -3
)
RMmult <- function(C0, C1, C2, C3, C4, C5, C6, C7, C8, C9, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(C0)) submodels[['C0']] <- C0
if (hasArg(C1)) submodels[['C1']] <- C1
if (hasArg(C2)) submodels[['C2']] <- C2
if (hasArg(C3)) submodels[['C3']] <- C3
if (hasArg(C4)) submodels[['C4']] <- C4
if (hasArg(C5)) submodels[['C5']] <- C5
if (hasArg(C6)) submodels[['C6']] <- C6
if (hasArg(C7)) submodels[['C7']] <- C7
if (hasArg(C8)) submodels[['C8']] <- C8
if (hasArg(C9)) submodels[['C9']] <- C9
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMmult',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMmult <- new(CLASS_RM,
.Data = RMmult,
type = c('of manifold type'),
isotropy = c('submodel dependent'),
domain = c('submodel dependent'),
operator = TRUE,
monotone = 'submodel dependent monotonicity',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = -3
)
RMS <- function(phi, var, scale, Aniso, proj, anisoT) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.model[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.model[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('anisoT') && !is.null(subst <- substitute(anisoT)))
par.model[['anisoT']] <- CheckArg(anisoT, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.model[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.model[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMS',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMS <- new(CLASS_RM,
.Data = RMS,
type = c('of manifold type', 'of manifold type'),
isotropy = c('submodel dependent', 'submodel dependent'),
domain = c('submodel dependent'),
operator = TRUE,
monotone = 'submodel dependent monotonicity',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = -3
)
RMave <- function(phi, A, z, spacetime, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('A') && !is.null(subst <- substitute(A)))
par.model[['A']] <- CheckArg(A, subst, TRUE)
if (hasArg('z') && !is.null(subst <- substitute(z)))
par.model[['z']] <- CheckArg(z, subst, TRUE)
if (hasArg('spacetime') && !is.null(subst <- substitute(spacetime)))
par.model[['spacetime']] <- CheckArg(spacetime, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMave',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMave <- new(CLASS_RM,
.Data = RMave,
type = c('positive definite'),
isotropy = c('symmetric'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 10,
vdim = 1
)
RMbcw <- function(alpha, beta, c, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('beta') && !is.null(subst <- substitute(beta)))
par.model[['beta']] <- CheckArg(beta, subst, TRUE)
if (hasArg('c') && !is.null(subst <- substitute(c)))
par.model[['c']] <- CheckArg(c, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMbcw',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMbcw <- new(CLASS_RM,
.Data = RMbcw,
type = c('variogram', 'positive definite', 'tail correlation', 'positive definite'),
isotropy = c('isotropic', 'isotropic', 'isotropic', 'spherical isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'normal mixture',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMlsfbm <- function(alpha, const, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('const') && !is.null(subst <- substitute(const)))
par.model[['const']] <- CheckArg(const, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMlsfbm',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMlsfbm <- new(CLASS_RM,
.Data = RMlsfbm,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMbessel <- function(nu, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('nu') && !is.null(subst <- substitute(nu)))
par.model[['nu']] <- CheckArg(nu, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMbessel',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMbessel <- new(CLASS_RM,
.Data = RMbessel,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMbigneiting <- function(kappa, mu, s, sred12, gamma, cdiag, rhored, c, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('kappa') && !is.null(subst <- substitute(kappa)))
par.model[['kappa']] <- CheckArg(kappa, subst, TRUE)
if (hasArg('mu') && !is.null(subst <- substitute(mu)))
par.model[['mu']] <- CheckArg(mu, subst, TRUE)
if (hasArg('s') && !is.null(subst <- substitute(s)))
par.model[['s']] <- CheckArg(s, subst, TRUE)
if (hasArg('sred12') && !is.null(subst <- substitute(sred12)))
par.model[['sred12']] <- CheckArg(sred12, subst, TRUE)
if (hasArg('gamma') && !is.null(subst <- substitute(gamma)))
par.model[['gamma']] <- CheckArg(gamma, subst, TRUE)
if (hasArg('cdiag') && !is.null(subst <- substitute(cdiag)))
par.model[['cdiag']] <- CheckArg(cdiag, subst, TRUE)
if (hasArg('rhored') && !is.null(subst <- substitute(rhored)))
par.model[['rhored']] <- CheckArg(rhored, subst, TRUE)
if (hasArg('c') && !is.null(subst <- substitute(c)))
par.model[['c']] <- CheckArg(c, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMbigneiting',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMbigneiting <- new(CLASS_RM,
.Data = RMbigneiting,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = TRUE,
simpleArguments = TRUE,
maxdim = -1,
vdim = 2
)
RMbernoulli <- function(phi, threshold, correlation, centred, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('threshold') && !is.null(subst <- substitute(threshold)))
par.model[['threshold']] <- CheckArg(threshold, subst, TRUE)
if (hasArg('correlation') && !is.null(subst <- substitute(correlation)))
par.model[['correlation']] <- CheckArg(correlation, subst, TRUE)
if (hasArg('centred') && !is.null(subst <- substitute(centred)))
par.model[['centred']] <- CheckArg(centred, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMbernoulli',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMbernoulli <- new(CLASS_RM,
.Data = RMbernoulli,
type = c('tail correlation'),
isotropy = c('submodel dependent'),
domain = c('submodel dependent'),
operator = TRUE,
monotone = 'submodel dependent monotonicity',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = 1
)
RMbiwm <- function(nudiag, nured12, nu, s, cdiag, rhored, c, notinvnu, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('nudiag') && !is.null(subst <- substitute(nudiag)))
par.model[['nudiag']] <- CheckArg(nudiag, subst, TRUE)
if (hasArg('nured12') && !is.null(subst <- substitute(nured12)))
par.model[['nured12']] <- CheckArg(nured12, subst, TRUE)
if (hasArg('nu') && !is.null(subst <- substitute(nu)))
par.model[['nu']] <- CheckArg(nu, subst, TRUE)
if (hasArg('s') && !is.null(subst <- substitute(s)))
par.model[['s']] <- CheckArg(s, subst, TRUE)
if (hasArg('cdiag') && !is.null(subst <- substitute(cdiag)))
par.model[['cdiag']] <- CheckArg(cdiag, subst, TRUE)
if (hasArg('rhored') && !is.null(subst <- substitute(rhored)))
par.model[['rhored']] <- CheckArg(rhored, subst, TRUE)
if (hasArg('c') && !is.null(subst <- substitute(c)))
par.model[['c']] <- CheckArg(c, subst, TRUE)
if (hasArg('notinvnu') && !is.null(subst <- substitute(notinvnu)))
par.model[['notinvnu']] <- CheckArg(notinvnu, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMbiwm',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMbiwm <- new(CLASS_RM,
.Data = RMbiwm,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 2
)
RMbistable <- function(alpha, s, cdiag, rho, rhored, betared, alphadiag, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('s') && !is.null(subst <- substitute(s)))
par.model[['s']] <- CheckArg(s, subst, TRUE)
if (hasArg('cdiag') && !is.null(subst <- substitute(cdiag)))
par.model[['cdiag']] <- CheckArg(cdiag, subst, TRUE)
if (hasArg('rho') && !is.null(subst <- substitute(rho)))
par.model[['rho']] <- CheckArg(rho, subst, TRUE)
if (hasArg('rhored') && !is.null(subst <- substitute(rhored)))
par.model[['rhored']] <- CheckArg(rhored, subst, TRUE)
if (hasArg('betared') && !is.null(subst <- substitute(betared)))
par.model[['betared']] <- CheckArg(betared, subst, TRUE)
if (hasArg('alphadiag') && !is.null(subst <- substitute(alphadiag)))
par.model[['alphadiag']] <- CheckArg(alphadiag, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMbistable',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMbistable <- new(CLASS_RM,
.Data = RMbistable,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 3,
vdim = 2
)
RMblend <- function(multi, blend, thresholds, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(multi)) submodels[['multi']] <- multi
if (hasArg(blend)) submodels[['blend']] <- blend
if (hasArg('thresholds') && !is.null(subst <- substitute(thresholds)))
par.model[['thresholds']] <- CheckArg(thresholds, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMblend',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMblend <- new(CLASS_RM,
.Data = RMblend,
type = c('positive definite'),
isotropy = c('symmetric'),
domain = c('kernel'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -3,
vdim = 1
)
RMbrownresnick <- function(phi, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMbrownresnick',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMbrownresnick <- new(CLASS_RM,
.Data = RMbrownresnick,
type = c('tail correlation'),
isotropy = c('submodel dependent'),
domain = c('single variable'),
operator = TRUE,
monotone = 'submodel dependent monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -3,
vdim = 1
)
RMbr2bg <- function(phi, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMbr2bg',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMbr2bg <- new(CLASS_RM,
.Data = RMbr2bg,
type = c('positive definite'),
isotropy = c('submodel dependent'),
domain = c('single variable'),
operator = TRUE,
monotone = 'submodel dependent monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -3,
vdim = 1
)
RMbr2eg <- function(phi, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMbr2eg',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMbr2eg <- new(CLASS_RM,
.Data = RMbr2eg,
type = c('positive definite'),
isotropy = c('submodel dependent'),
domain = c('single variable'),
operator = TRUE,
monotone = 'submodel dependent monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -3,
vdim = 1
)
RMbubble <- function(phi, scaling, z, weight, minscale, barycentre, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg(scaling)) submodels[['scaling']] <- scaling
if (hasArg('z') && !is.null(subst <- substitute(z)))
par.model[['z']] <- CheckArg(z, subst, TRUE)
if (hasArg('weight') && !is.null(subst <- substitute(weight)))
par.model[['weight']] <- CheckArg(weight, subst, TRUE)
if (hasArg('minscale') && !is.null(subst <- substitute(minscale)))
par.model[['minscale']] <- CheckArg(minscale, subst, TRUE)
if (hasArg('barycentre') && !is.null(subst <- substitute(barycentre)))
par.model[['barycentre']] <- CheckArg(barycentre, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMbubble',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMbubble <- new(CLASS_RM,
.Data = RMbubble,
type = c('positive definite'),
isotropy = c('non-dimension-reducing'),
domain = c('kernel'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMcauchy <- function(gamma, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('gamma') && !is.null(subst <- substitute(gamma)))
par.model[['gamma']] <- CheckArg(gamma, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMcauchy',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMcauchy <- new(CLASS_RM,
.Data = RMcauchy,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'normal mixture',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMcircular <- function(var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMcircular',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMcircular <- new(CLASS_RM,
.Data = RMcircular,
type = c('tail correlation'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'Gneiting-Schaback class',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 2,
vdim = 1
)
RMconstant <- function(M, var) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('M') && !is.null(subst <- substitute(M)))
par.model[['M']] <- CheckArg(M, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'RMconstant',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMconstant <- new(CLASS_RM,
.Data = RMconstant,
type = c('positive definite', 'negative definite'),
isotropy = c('framework dependent', 'isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'submodel dependent monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -1
)
iRMfixcov <- function(norm, M, x, raw, var, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(norm)) submodels[['norm']] <- norm
if (hasArg('M') && !is.null(subst <- substitute(M)))
par.model[['M']] <- CheckArg(M, subst, TRUE)
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckArg(x, subst, TRUE)
if (hasArg('raw') && !is.null(subst <- substitute(raw)))
par.model[['raw']] <- CheckArg(raw, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMfixcov',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
iRMfixcov <- new(CLASS_RM,
.Data = iRMfixcov,
type = c('positive definite', 'positive definite', 'positive definite'),
isotropy = c('non-dimension-reducing', 'isotropic', 'earth isotropic'),
domain = c('kernel'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = FALSE,
maxdim = Inf,
vdim = -1
)
RMcoxisham <- function(phi, mu, D, beta, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('mu') && !is.null(subst <- substitute(mu)))
par.model[['mu']] <- CheckArg(mu, subst, TRUE)
if (hasArg('D') && !is.null(subst <- substitute(D)))
par.model[['D']] <- CheckArg(D, subst, TRUE)
if (hasArg('beta') && !is.null(subst <- substitute(beta)))
par.model[['beta']] <- CheckArg(beta, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMcoxisham',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMcoxisham <- new(CLASS_RM,
.Data = RMcoxisham,
type = c('positive definite'),
isotropy = c('symmetric'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 3,
vdim = 1
)
RMcubic <- function(var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMcubic',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMcubic <- new(CLASS_RM,
.Data = RMcubic,
type = c('tail correlation'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 3,
vdim = 1
)
RMcurlfree <- function(phi, which, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('which') && !is.null(subst <- substitute(which)))
par.model[['which']] <- CheckArg(which, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMcurlfree',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMcurlfree <- new(CLASS_RM,
.Data = RMcurlfree,
type = c('positive definite'),
isotropy = c('cartesian system'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = -1
)
RMcutoff <- function(phi, diameter, a, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('diameter') && !is.null(subst <- substitute(diameter)))
par.model[['diameter']] <- CheckArg(diameter, subst, TRUE)
if (hasArg('a') && !is.null(subst <- substitute(a)))
par.model[['a']] <- CheckArg(a, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMcutoff',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMcutoff <- new(CLASS_RM,
.Data = RMcutoff,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = TRUE,
monotone = 'monotone',
finiterange = TRUE,
simpleArguments = TRUE,
maxdim = 13,
vdim = -3
)
RMdagum <- function(beta, gamma, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('beta') && !is.null(subst <- substitute(beta)))
par.model[['beta']] <- CheckArg(beta, subst, TRUE)
if (hasArg('gamma') && !is.null(subst <- substitute(gamma)))
par.model[['gamma']] <- CheckArg(gamma, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMdagum',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMdagum <- new(CLASS_RM,
.Data = RMdagum,
type = c('positive definite', 'tail correlation', 'positive definite'),
isotropy = c('isotropic', 'isotropic', 'spherical isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'parameter dependent monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMdampedcos <- function(lambda, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('lambda') && !is.null(subst <- substitute(lambda)))
par.model[['lambda']] <- CheckArg(lambda, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMdampedcos',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMdampedcos <- new(CLASS_RM,
.Data = RMdampedcos,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -1,
vdim = 1
)
RMderiv <- function(phi, which, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('which') && !is.null(subst <- substitute(which)))
par.model[['which']] <- CheckArg(which, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMderiv',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMderiv <- new(CLASS_RM,
.Data = RMderiv,
type = c('positive definite'),
isotropy = c('cartesian system'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = -1
)
RMdewijsian <- function(alpha, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMdewijsian',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMdewijsian <- new(CLASS_RM,
.Data = RMdewijsian,
type = c('variogram'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMdivfree <- function(phi, which, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('which') && !is.null(subst <- substitute(which)))
par.model[['which']] <- CheckArg(which, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMdivfree',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMdivfree <- new(CLASS_RM,
.Data = RMdivfree,
type = c('positive definite'),
isotropy = c('cartesian system'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = -1
)
RMepscauchy <- function(alpha, beta, eps, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('beta') && !is.null(subst <- substitute(beta)))
par.model[['beta']] <- CheckArg(beta, subst, TRUE)
if (hasArg('eps') && !is.null(subst <- substitute(eps)))
par.model[['eps']] <- CheckArg(eps, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMepscauchy',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMepscauchy <- new(CLASS_RM,
.Data = RMepscauchy,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'normal mixture',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMexp <- function(var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMexp',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMexp <- new(CLASS_RM,
.Data = RMexp,
type = c('tail correlation', 'positive definite'),
isotropy = c('isotropic', 'spherical isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'completely monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMexponential <- function(phi, n, standardised, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('n') && !is.null(subst <- substitute(n)))
par.model[['n']] <- CheckArg(n, subst, TRUE)
if (hasArg('standardised') && !is.null(subst <- substitute(standardised)))
par.model[['standardised']] <- CheckArg(standardised, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMexponential',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMexponential <- new(CLASS_RM,
.Data = RMexponential,
type = c('positive definite'),
isotropy = c('submodel dependent'),
domain = c('submodel dependent'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -3,
vdim = 1
)
RMschlather <- function(phi, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMschlather',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMschlather <- new(CLASS_RM,
.Data = RMschlather,
type = c('tail correlation'),
isotropy = c('submodel dependent'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = 1
)
RMfractdiff <- function(a, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('a') && !is.null(subst <- substitute(a)))
par.model[['a']] <- CheckArg(a, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMfractdiff',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMfractdiff <- new(CLASS_RM,
.Data = RMfractdiff,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 1,
vdim = 1
)
RMflatpower <- function(alpha, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMflatpower',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMflatpower <- new(CLASS_RM,
.Data = RMflatpower,
type = c('variogram'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'Bernstein',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMfbm <- function(alpha, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMfbm',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMfbm <- new(CLASS_RM,
.Data = RMfbm,
type = c('variogram'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'Bernstein',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMfractgauss <- function(alpha, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMfractgauss',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMfractgauss <- new(CLASS_RM,
.Data = RMfractgauss,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 1,
vdim = 1
)
RMgauss <- function(var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMgauss',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMgauss <- new(CLASS_RM,
.Data = RMgauss,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'normal mixture',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMgenfbm <- function(alpha, beta, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('beta') && !is.null(subst <- substitute(beta)))
par.model[['beta']] <- CheckArg(beta, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMgenfbm',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMgenfbm <- new(CLASS_RM,
.Data = RMgenfbm,
type = c('variogram'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMgencauchy <- function(alpha, beta, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('beta') && !is.null(subst <- substitute(beta)))
par.model[['beta']] <- CheckArg(beta, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMgencauchy',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMgencauchy <- new(CLASS_RM,
.Data = RMgencauchy,
type = c('positive definite', 'tail correlation', 'positive definite'),
isotropy = c('isotropic', 'isotropic', 'spherical isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'parameter dependent monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMbicauchy <- function(alpha, beta, s, rho, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('beta') && !is.null(subst <- substitute(beta)))
par.model[['beta']] <- CheckArg(beta, subst, TRUE)
if (hasArg('s') && !is.null(subst <- substitute(s)))
par.model[['s']] <- CheckArg(s, subst, TRUE)
if (hasArg('rho') && !is.null(subst <- substitute(rho)))
par.model[['rho']] <- CheckArg(rho, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMbicauchy',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMbicauchy <- new(CLASS_RM,
.Data = RMbicauchy,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 3,
vdim = 2
)
RMgengneiting <- function(kappa, mu, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('kappa') && !is.null(subst <- substitute(kappa)))
par.model[['kappa']] <- CheckArg(kappa, subst, TRUE)
if (hasArg('mu') && !is.null(subst <- substitute(mu)))
par.model[['mu']] <- CheckArg(mu, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMgengneiting',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMgengneiting <- new(CLASS_RM,
.Data = RMgengneiting,
type = c('positive definite', 'positive definite', 'positive definite', 'positive definite', 'positive definite', 'positive definite'),
isotropy = c('isotropic', 'spherical isotropic', 'isotropic', 'spherical isotropic', 'isotropic', 'spherical isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'monotone',
finiterange = TRUE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMgneiting <- function(orig, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('orig') && !is.null(subst <- substitute(orig)))
par.model[['orig']] <- CheckArg(orig, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMgneiting',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMgneiting <- new(CLASS_RM,
.Data = RMgneiting,
type = c('positive definite', 'positive definite'),
isotropy = c('isotropic', 'spherical isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'monotone',
finiterange = TRUE,
simpleArguments = TRUE,
maxdim = -1,
vdim = 1
)
RMgennsst <- function(phi, psi, dim_u, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg(psi)) submodels[['psi']] <- psi
if (hasArg('dim_u') && !is.null(subst <- substitute(dim_u)))
par.model[['dim_u']] <- CheckArg(dim_u, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMgennsst',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMgennsst <- new(CLASS_RM,
.Data = RMgennsst,
type = c('positive definite', 'positive definite'),
isotropy = c('symmetric', 'symmetric'),
domain = c('submodel dependent'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -3,
vdim = 1
)
RMhyperbolic <- function(nu, lambda, delta, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('nu') && !is.null(subst <- substitute(nu)))
par.model[['nu']] <- CheckArg(nu, subst, TRUE)
if (hasArg('lambda') && !is.null(subst <- substitute(lambda)))
par.model[['lambda']] <- CheckArg(lambda, subst, TRUE)
if (hasArg('delta') && !is.null(subst <- substitute(delta)))
par.model[['delta']] <- CheckArg(delta, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMhyperbolic',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMhyperbolic <- new(CLASS_RM,
.Data = RMhyperbolic,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'normal mixture',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMiaco <- function(nu, lambda, delta, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('nu') && !is.null(subst <- substitute(nu)))
par.model[['nu']] <- CheckArg(nu, subst, TRUE)
if (hasArg('lambda') && !is.null(subst <- substitute(lambda)))
par.model[['lambda']] <- CheckArg(lambda, subst, TRUE)
if (hasArg('delta') && !is.null(subst <- substitute(delta)))
par.model[['delta']] <- CheckArg(delta, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMiaco',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMiaco <- new(CLASS_RM,
.Data = RMiaco,
type = c('positive definite'),
isotropy = c('space-isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMidmodel <- function(phi, vdim, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('vdim') && !is.null(subst <- substitute(vdim)))
par.model[['vdim']] <- CheckArg(vdim, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMidmodel',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMidmodel <- new(CLASS_RM,
.Data = RMidmodel,
type = c('of manifold type'),
isotropy = c('framework dependent'),
domain = c('single variable', 'kernel'),
operator = TRUE,
monotone = 'submodel dependent monotonicity',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = -3
)
RMkolmogorov <- function(var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMkolmogorov',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMkolmogorov <- new(CLASS_RM,
.Data = RMkolmogorov,
type = c('variogram'),
isotropy = c('vector-isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 3,
vdim = 3
)
RMlgd <- function(alpha, beta, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('beta') && !is.null(subst <- substitute(beta)))
par.model[['beta']] <- CheckArg(beta, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMlgd',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMlgd <- new(CLASS_RM,
.Data = RMlgd,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -1,
vdim = 1
)
RMmastein <- function(phi, nu, delta, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('nu') && !is.null(subst <- substitute(nu)))
par.model[['nu']] <- CheckArg(nu, subst, TRUE)
if (hasArg('delta') && !is.null(subst <- substitute(delta)))
par.model[['delta']] <- CheckArg(delta, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMmastein',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMmastein <- new(CLASS_RM,
.Data = RMmastein,
type = c('positive definite'),
isotropy = c('space-isotropic'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -3,
vdim = 1
)
RMma <- function(phi, alpha, theta, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('theta') && !is.null(subst <- substitute(theta)))
par.model[['theta']] <- CheckArg(theta, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMma',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMma <- new(CLASS_RM,
.Data = RMma,
type = c('positive definite'),
isotropy = c('symmetric'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -3,
vdim = 1
)
RMintexp <- function(phi, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMintexp',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMintexp <- new(CLASS_RM,
.Data = RMintexp,
type = c('positive definite'),
isotropy = c('symmetric'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -3,
vdim = 1
)
RMmatrix <- function(C0, C1, C2, C3, C4, C5, C6, C7, C8, C9, M, vdim, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(C0)) submodels[['C0']] <- C0
if (hasArg(C1)) submodels[['C1']] <- C1
if (hasArg(C2)) submodels[['C2']] <- C2
if (hasArg(C3)) submodels[['C3']] <- C3
if (hasArg(C4)) submodels[['C4']] <- C4
if (hasArg(C5)) submodels[['C5']] <- C5
if (hasArg(C6)) submodels[['C6']] <- C6
if (hasArg(C7)) submodels[['C7']] <- C7
if (hasArg(C8)) submodels[['C8']] <- C8
if (hasArg(C9)) submodels[['C9']] <- C9
if (hasArg('M') && !is.null(subst <- substitute(M)))
par.model[['M']] <- CheckArg(M, subst, TRUE)
if (hasArg('vdim') && !is.null(subst <- substitute(vdim)))
par.model[['vdim']] <- CheckArg(vdim, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMmatrix',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMmatrix <- new(CLASS_RM,
.Data = RMmatrix,
type = c('of manifold type'),
isotropy = c('submodel dependent'),
domain = c('submodel dependent'),
operator = TRUE,
monotone = 'not monotone',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = -1
)
RMmatern <- function(nu, notinvnu, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('nu') && !is.null(subst <- substitute(nu)))
par.model[['nu']] <- CheckArg(nu, subst, TRUE)
if (hasArg('notinvnu') && !is.null(subst <- substitute(notinvnu)))
par.model[['notinvnu']] <- CheckArg(notinvnu, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMmatern',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMmatern <- new(CLASS_RM,
.Data = RMmatern,
type = c('positive definite'),
isotropy = c('parameter dependent'),
domain = c('parameter dependent'),
operator = FALSE,
monotone = 'submodel dependent monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMmqam <- function(phi, C1, C2, C3, C4, C5, C6, C7, C8, C9, theta, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg(C1)) submodels[['C1']] <- C1
if (hasArg(C2)) submodels[['C2']] <- C2
if (hasArg(C3)) submodels[['C3']] <- C3
if (hasArg(C4)) submodels[['C4']] <- C4
if (hasArg(C5)) submodels[['C5']] <- C5
if (hasArg(C6)) submodels[['C6']] <- C6
if (hasArg(C7)) submodels[['C7']] <- C7
if (hasArg(C8)) submodels[['C8']] <- C8
if (hasArg(C9)) submodels[['C9']] <- C9
if (hasArg('theta') && !is.null(subst <- substitute(theta)))
par.model[['theta']] <- CheckArg(theta, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMmqam',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMmqam <- new(CLASS_RM,
.Data = RMmqam,
type = c('positive definite'),
isotropy = c('symmetric'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -3,
vdim = -1
)
RMmultiquad <- function(delta, tau, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('delta') && !is.null(subst <- substitute(delta)))
par.model[['delta']] <- CheckArg(delta, subst, TRUE)
if (hasArg('tau') && !is.null(subst <- substitute(tau)))
par.model[['tau']] <- CheckArg(tau, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMmultiquad',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMmultiquad <- new(CLASS_RM,
.Data = RMmultiquad,
type = c('positive definite'),
isotropy = c('spherical isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 2,
vdim = 1
)
RMnatsc <- function(phi, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMnatsc',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMnatsc <- new(CLASS_RM,
.Data = RMnatsc,
type = c('positive definite', 'tail correlation'),
isotropy = c('isotropic', 'isotropic'),
domain = c('single variable'),
operator = TRUE,
monotone = 'submodel dependent monotonicity',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = 1
)
RMnsst <- function(phi, psi, delta, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg(psi)) submodels[['psi']] <- psi
if (hasArg('delta') && !is.null(subst <- substitute(delta)))
par.model[['delta']] <- CheckArg(delta, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMnsst',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMnsst <- new(CLASS_RM,
.Data = RMnsst,
type = c('positive definite'),
isotropy = c('space-isotropic'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -3,
vdim = 1
)
RMparswm <- function(nudiag, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('nudiag') && !is.null(subst <- substitute(nudiag)))
par.model[['nudiag']] <- CheckArg(nudiag, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMparswm',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMparswm <- new(CLASS_RM,
.Data = RMparswm,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -1
)
RMpenta <- function(var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMpenta',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMpenta <- new(CLASS_RM,
.Data = RMpenta,
type = c('positive definite', 'positive definite'),
isotropy = c('isotropic', 'spherical isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'monotone',
finiterange = TRUE,
simpleArguments = TRUE,
maxdim = 3,
vdim = 1
)
RMaskey <- function(alpha, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMaskey',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMaskey <- new(CLASS_RM,
.Data = RMaskey,
type = c('positive definite', 'positive definite', 'tail correlation'),
isotropy = c('isotropic', 'spherical isotropic', 'isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'monotone',
finiterange = TRUE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMpower <- function(phi, alpha, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMpower',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMpower <- new(CLASS_RM,
.Data = RMpower,
type = c('shape function', 'negative definite', 'positive definite', 'tail correlation'),
isotropy = c('submodel dependent', 'submodel dependent', 'submodel dependent', 'isotropic'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = 1
)
RMprod <- function(phi, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMprod',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMprod <- new(CLASS_RM,
.Data = RMprod,
type = c('positive definite'),
isotropy = c('non-dimension-reducing'),
domain = c('kernel'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -3
)
RMqam <- function(phi, C1, C2, C3, C4, C5, C6, C7, C8, C9, theta, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg(C1)) submodels[['C1']] <- C1
if (hasArg(C2)) submodels[['C2']] <- C2
if (hasArg(C3)) submodels[['C3']] <- C3
if (hasArg(C4)) submodels[['C4']] <- C4
if (hasArg(C5)) submodels[['C5']] <- C5
if (hasArg(C6)) submodels[['C6']] <- C6
if (hasArg(C7)) submodels[['C7']] <- C7
if (hasArg(C8)) submodels[['C8']] <- C8
if (hasArg(C9)) submodels[['C9']] <- C9
if (hasArg('theta') && !is.null(subst <- substitute(theta)))
par.model[['theta']] <- CheckArg(theta, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMqam',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMqam <- new(CLASS_RM,
.Data = RMqam,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -3,
vdim = 1
)
RMqexp <- function(alpha, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMqexp',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMqexp <- new(CLASS_RM,
.Data = RMqexp,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMscale <- function(phi, scaling, penalty, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg(scaling)) submodels[['scaling']] <- scaling
if (hasArg(penalty)) submodels[['penalty']] <- penalty
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMscale',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMscale <- new(CLASS_RM,
.Data = RMscale,
type = c('positive definite'),
isotropy = c('symmetric'),
domain = c('kernel'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMschur <- function(phi, M, diag, rhored, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('M') && !is.null(subst <- substitute(M)))
par.model[['M']] <- CheckArg(M, subst, TRUE)
if (hasArg('diag') && !is.null(subst <- substitute(diag)))
par.model[['diag']] <- CheckArg(diag, subst, TRUE)
if (hasArg('rhored') && !is.null(subst <- substitute(rhored)))
par.model[['rhored']] <- CheckArg(rhored, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMschur',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMschur <- new(CLASS_RM,
.Data = RMschur,
type = c('positive definite'),
isotropy = c('framework dependent'),
domain = c('single variable', 'kernel'),
operator = TRUE,
monotone = 'not monotone',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = -3
)
RMdelay <- function(phi, s, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('s') && !is.null(subst <- substitute(s)))
par.model[['s']] <- CheckArg(s, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMdelay',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMdelay <- new(CLASS_RM,
.Data = RMdelay,
type = c('positive definite'),
isotropy = c('cartesian system'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = -1
)
RMsinepower <- function(alpha, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMsinepower',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMsinepower <- new(CLASS_RM,
.Data = RMsinepower,
type = c('positive definite'),
isotropy = c('spherical isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 2,
vdim = 1
)
RMspheric <- function(var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMspheric',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMspheric <- new(CLASS_RM,
.Data = RMspheric,
type = c('tail correlation', 'positive definite'),
isotropy = c('isotropic', 'spherical isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'Gneiting-Schaback class',
finiterange = TRUE,
simpleArguments = TRUE,
maxdim = 3,
vdim = 1
)
RMstable <- function(alpha, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMstable',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMstable <- new(CLASS_RM,
.Data = RMstable,
type = c('positive definite', 'tail correlation', 'positive definite'),
isotropy = c('isotropic', 'isotropic', 'spherical isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'parameter dependent monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMintrinsic <- function(phi, diameter, rawR, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('diameter') && !is.null(subst <- substitute(diameter)))
par.model[['diameter']] <- CheckArg(diameter, subst, TRUE)
if (hasArg('rawR') && !is.null(subst <- substitute(rawR)))
par.model[['rawR']] <- CheckArg(rawR, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMintrinsic',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMintrinsic <- new(CLASS_RM,
.Data = RMintrinsic,
type = c('positive definite', 'positive definite'),
isotropy = c('isotropic', 'spherical isotropic'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = TRUE,
simpleArguments = TRUE,
maxdim = 13,
vdim = 1
)
RMstein <- function(nu, z, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('nu') && !is.null(subst <- substitute(nu)))
par.model[['nu']] <- CheckArg(nu, subst, TRUE)
if (hasArg('z') && !is.null(subst <- substitute(z)))
par.model[['z']] <- CheckArg(z, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMstein',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMstein <- new(CLASS_RM,
.Data = RMstein,
type = c('positive definite'),
isotropy = c('symmetric'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMstp <- function(xi, phi, S, z, M, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(xi)) submodels[['xi']] <- xi
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('S') && !is.null(subst <- substitute(S)))
par.model[['S']] <- CheckArg(S, subst, TRUE)
if (hasArg('z') && !is.null(subst <- substitute(z)))
par.model[['z']] <- CheckArg(z, subst, TRUE)
if (hasArg('M') && !is.null(subst <- substitute(M)))
par.model[['M']] <- CheckArg(M, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMstp',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMstp <- new(CLASS_RM,
.Data = RMstp,
type = c('positive definite'),
isotropy = c('symmetric'),
domain = c('kernel'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 10,
vdim = 1
)
RMtbm <- function(phi, fulldim, reduceddim, layers, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('fulldim') && !is.null(subst <- substitute(fulldim)))
par.model[['fulldim']] <- CheckArg(fulldim, subst, TRUE)
if (hasArg('reduceddim') && !is.null(subst <- substitute(reduceddim)))
par.model[['reduceddim']] <- CheckArg(reduceddim, subst, TRUE)
if (hasArg('layers') && !is.null(subst <- substitute(layers)))
par.model[['layers']] <- CheckArg(layers, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMtbm',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMtbm <- new(CLASS_RM,
.Data = RMtbm,
type = c('of manifold type'),
isotropy = c('parameter dependent'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -1,
vdim = -3
)
RMsum <- function(phi, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMsum',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMsum <- new(CLASS_RM,
.Data = RMsum,
type = c('negative definite'),
isotropy = c('non-dimension-reducing'),
domain = c('kernel'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -3
)
iRMcov <- function(gamma, x, a, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(gamma)) submodels[['gamma']] <- gamma
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckArg(x, subst, TRUE)
if (hasArg('a') && !is.null(subst <- substitute(a)))
par.model[['a']] <- CheckArg(a, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMcov',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
iRMcov <- new(CLASS_RM,
.Data = iRMcov,
type = c('positive definite'),
isotropy = c('cartesian system'),
domain = c('kernel'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = FALSE,
maxdim = Inf,
vdim = 1
)
RMvector <- function(phi, a, Dspace, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('a') && !is.null(subst <- substitute(a)))
par.model[['a']] <- CheckArg(a, subst, TRUE)
if (hasArg('Dspace') && !is.null(subst <- substitute(Dspace)))
par.model[['Dspace']] <- CheckArg(Dspace, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMvector',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMvector <- new(CLASS_RM,
.Data = RMvector,
type = c('positive definite', 'positive definite'),
isotropy = c('cartesian system', 'cartesian system'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = -1
)
RMwave <- function(var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMwave',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMwave <- new(CLASS_RM,
.Data = RMwave,
type = c('positive definite'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 3,
vdim = 1
)
RMwhittle <- function(nu, notinvnu, var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('nu') && !is.null(subst <- substitute(nu)))
par.model[['nu']] <- CheckArg(nu, subst, TRUE)
if (hasArg('notinvnu') && !is.null(subst <- substitute(notinvnu)))
par.model[['notinvnu']] <- CheckArg(notinvnu, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMwhittle',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMwhittle <- new(CLASS_RM,
.Data = RMwhittle,
type = c('positive definite'),
isotropy = c('parameter dependent'),
domain = c('parameter dependent'),
operator = FALSE,
monotone = 'normal mixture',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMnugget <- function(tol, vdim, var, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('tol') && !is.null(subst <- substitute(tol)))
par.model[['tol']] <- CheckArg(tol, subst, TRUE)
if (hasArg('vdim') && !is.null(subst <- substitute(vdim)))
par.model[['vdim']] <- CheckArg(vdim, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMnugget',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMnugget <- new(CLASS_RM,
.Data = RMnugget,
type = c('tail correlation'),
isotropy = c('parameter dependent'),
domain = c('parameter dependent'),
operator = FALSE,
monotone = 'monotone',
finiterange = TRUE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -2
)
RMtrend <- function(mean) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('mean') && !is.null(subst <- substitute(mean)))
par.model[['mean']] <- CheckArg(mean, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RMtrend',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMtrend <- new(CLASS_RM,
.Data = RMtrend,
type = c('trend'),
isotropy = c('parameter dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -1
)
RMangle <- function(angle, lat.angle, ratio, diag) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('angle') && !is.null(subst <- substitute(angle)))
par.model[['angle']] <- CheckArg(angle, subst, TRUE)
if (hasArg('lat.angle') && !is.null(subst <- substitute(lat.angle)))
par.model[['lat.angle']] <- CheckArg(lat.angle, subst, TRUE)
if (hasArg('ratio') && !is.null(subst <- substitute(ratio)))
par.model[['ratio']] <- CheckArg(ratio, subst, TRUE)
if (hasArg('diag') && !is.null(subst <- substitute(diag)))
par.model[['diag']] <- CheckArg(diag, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'RMangle',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMangle <- new(CLASS_RM,
.Data = RMangle,
type = c('shape function'),
isotropy = c('cartesian system'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -1
)
RMball <- function(var, scale, Aniso, proj) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.general[['scale']] <- CheckArg(scale, subst, TRUE)
if (hasArg('Aniso') && !is.null(subst <- substitute(Aniso)))
par.general[['Aniso']] <- CheckArg(Aniso, subst, TRUE)
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.general[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
model <- methods::new('RMmodel', call = cl, name = 'RMball',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMball <- new(CLASS_RM,
.Data = RMball,
type = c('shape function'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = FALSE,
monotone = 'monotone',
finiterange = TRUE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
iRMcovariate <- function(norm, data, x, raw, addNA, factor, var) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(norm)) submodels[['norm']] <- norm
if (hasArg('data') && !is.null(subst <- substitute(data)))
par.model[['data']] <- CheckArg(data, subst, TRUE)
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckArg(x, subst, TRUE)
if (hasArg('raw') && !is.null(subst <- substitute(raw)))
par.model[['raw']] <- CheckArg(raw, subst, TRUE)
if (hasArg('addNA') && !is.null(subst <- substitute(addNA)))
par.model[['addNA']] <- CheckArg(addNA, subst, TRUE)
if (hasArg('factor') && !is.null(subst <- substitute(factor)))
par.model[['factor']] <- CheckArg(factor, subst, TRUE)
if (hasArg('var') && !is.null(subst <- substitute(var)))
par.general[['var']] <- CheckArg(var, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'RMcovariate',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
iRMcovariate <- new(CLASS_RM,
.Data = iRMcovariate,
type = c('shape function', 'shape function', 'shape function', 'trend'),
isotropy = c('non-dimension-reducing', 'isotropic', 'earth isotropic', 'non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = FALSE,
maxdim = Inf,
vdim = -1
)
RMeaxxa <- function(E, A) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('E') && !is.null(subst <- substitute(E)))
par.model[['E']] <- CheckArg(E, subst, TRUE)
if (hasArg('A') && !is.null(subst <- substitute(A)))
par.model[['A']] <- CheckArg(A, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'RMeaxxa',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMeaxxa <- new(CLASS_RM,
.Data = RMeaxxa,
type = c('shape function'),
isotropy = c('cartesian system'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 10,
vdim = -1
)
RMetaxxa <- function(E, A, alpha) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('E') && !is.null(subst <- substitute(E)))
par.model[['E']] <- CheckArg(E, subst, TRUE)
if (hasArg('A') && !is.null(subst <- substitute(A)))
par.model[['A']] <- CheckArg(A, subst, TRUE)
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'RMetaxxa',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMetaxxa <- new(CLASS_RM,
.Data = RMetaxxa,
type = c('shape function'),
isotropy = c('cartesian system'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 10,
vdim = 3
)
RMid <- function() {
cl <- match.call()
submodels <- par.general <- par.model <- list()
model <- methods::new('RMmodel', call = cl, name = 'RMid',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMid <- new(CLASS_RM,
.Data = RMid,
type = c('shape function'),
isotropy = c('framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -1
)
RMtrafo <- function(phi, new) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('new') && !is.null(subst <- substitute(new)))
par.model[['new']] <- CheckChar(new, subst, ISO_NAMES, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'RMtrafo',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMtrafo <- new(CLASS_RM,
.Data = RMtrafo,
type = c('of manifold type'),
isotropy = c('parameter dependent'),
domain = c('parameter dependent'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -1
)
RMpolygon <- function(lambda) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('lambda') && !is.null(subst <- substitute(lambda)))
par.model[['lambda']] <- CheckArg(lambda, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'RMpolygon',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMpolygon <- new(CLASS_RM,
.Data = RMpolygon,
type = c('shape function'),
isotropy = c('cartesian system'),
domain = c('single variable'),
operator = FALSE,
monotone = 'monotone',
finiterange = TRUE,
simpleArguments = TRUE,
maxdim = 2,
vdim = 1
)
RMrational <- function(A, a) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('A') && !is.null(subst <- substitute(A)))
par.model[['A']] <- CheckArg(A, subst, TRUE)
if (hasArg('a') && !is.null(subst <- substitute(a)))
par.model[['a']] <- CheckArg(a, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'RMrational',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMrational <- new(CLASS_RM,
.Data = RMrational,
type = c('shape function'),
isotropy = c('cartesian system'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMrotat <- function(speed, phi) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('speed') && !is.null(subst <- substitute(speed)))
par.model[['speed']] <- CheckArg(speed, subst, TRUE)
if (hasArg('phi') && !is.null(subst <- substitute(phi)))
par.model[['phi']] <- CheckArg(phi, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'RMrotat',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMrotat <- new(CLASS_RM,
.Data = RMrotat,
type = c('shape function'),
isotropy = c('cartesian system'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 3,
vdim = 1
)
RMrotation <- function(phi) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('phi') && !is.null(subst <- substitute(phi)))
par.model[['phi']] <- CheckArg(phi, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'RMrotation',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMrotation <- new(CLASS_RM,
.Data = RMrotation,
type = c('shape function'),
isotropy = c('cartesian system'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 3,
vdim = -1
)
RMsign <- function(phi, p) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('p') && !is.null(subst <- substitute(p)))
par.model[['p']] <- CheckArg(p, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'RMsign',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMsign <- new(CLASS_RM,
.Data = RMsign,
type = c('shape function'),
isotropy = c('framework dependent'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = 1
)
RMm2r <- function(phi) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
model <- methods::new('RMmodel', call = cl, name = 'RMm2r',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMm2r <- new(CLASS_RM,
.Data = RMm2r,
type = c('shape function'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = TRUE,
monotone = 'submodel dependent monotonicity',
finiterange = NA,
simpleArguments = TRUE,
maxdim = 3,
vdim = 1
)
RMm3b <- function(phi) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
model <- methods::new('RMmodel', call = cl, name = 'RMm3b',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMm3b <- new(CLASS_RM,
.Data = RMm3b,
type = c('shape function'),
isotropy = c('isotropic'),
domain = c('single variable'),
operator = TRUE,
monotone = 'monotone',
finiterange = TRUE,
simpleArguments = TRUE,
maxdim = 3,
vdim = 1
)
RMmps <- function(phi) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
model <- methods::new('RMmodel', call = cl, name = 'RMmps',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMmps <- new(CLASS_RM,
.Data = RMmps,
type = c('shape function'),
isotropy = c('cartesian system'),
domain = c('single variable'),
operator = TRUE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RMtruncsupport <- function(phi, radius) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('radius') && !is.null(subst <- substitute(radius)))
par.model[['radius']] <- CheckArg(radius, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'RMtruncsupport',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMtruncsupport <- new(CLASS_RM,
.Data = RMtruncsupport,
type = c('shape function'),
isotropy = c('framework dependent'),
domain = c('single variable'),
operator = TRUE,
monotone = 'submodel dependent monotonicity',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = 1
)
RRdeterm <- function(mean) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('mean') && !is.null(subst <- substitute(mean)))
par.model[['mean']] <- CheckArg(mean, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RRdeterm',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RRdeterm <- new(CLASS_RM,
.Data = RRdeterm,
type = c('distribution family'),
isotropy = c('cartesian system'),
domain = c('single variable', 'kernel'),
operator = FALSE,
monotone = 'mismatch in monotonicity',
finiterange = NA,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -3
)
RRgauss <- function(mu, sd, log) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('mu') && !is.null(subst <- substitute(mu)))
par.model[['mu']] <- CheckArg(mu, subst, FALSE)
if (hasArg('sd') && !is.null(subst <- substitute(sd)))
par.model[['sd']] <- CheckArg(sd, subst, FALSE)
if (hasArg('log') && !is.null(subst <- substitute(log)))
par.model[['log']] <- CheckArg(log, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RRgauss',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RRgauss <- new(CLASS_RM,
.Data = RRgauss,
type = c('distribution family'),
isotropy = c('cartesian system'),
domain = c('single variable', 'kernel'),
operator = FALSE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -1
)
RRloc <- function(phi, mu, scale, pow) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('mu') && !is.null(subst <- substitute(mu)))
par.model[['mu']] <- CheckArg(mu, subst, FALSE)
if (hasArg('scale') && !is.null(subst <- substitute(scale)))
par.model[['scale']] <- CheckArg(scale, subst, FALSE)
if (hasArg('pow') && !is.null(subst <- substitute(pow)))
par.model[['pow']] <- CheckArg(pow, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RRloc',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RRloc <- new(CLASS_RM,
.Data = RRloc,
type = c('distribution family'),
isotropy = c('cartesian system'),
domain = c('single variable', 'kernel'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = -3
)
RRmcmc <- function(phi, mcmc_n, sigma, normed, maxdensity, rand.loc, gibbs) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('mcmc_n') && !is.null(subst <- substitute(mcmc_n)))
par.model[['mcmc_n']] <- CheckArg(mcmc_n, subst, FALSE)
if (hasArg('sigma') && !is.null(subst <- substitute(sigma)))
par.model[['sigma']] <- CheckArg(sigma, subst, FALSE)
if (hasArg('normed') && !is.null(subst <- substitute(normed)))
par.model[['normed']] <- CheckArg(normed, subst, FALSE)
if (hasArg('maxdensity') && !is.null(subst <- substitute(maxdensity)))
par.model[['maxdensity']] <- CheckArg(maxdensity, subst, FALSE)
if (hasArg('rand.loc') && !is.null(subst <- substitute(rand.loc)))
par.model[['rand.loc']] <- CheckArg(rand.loc, subst, FALSE)
if (hasArg('gibbs') && !is.null(subst <- substitute(gibbs)))
par.model[['gibbs']] <- CheckArg(gibbs, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RRmcmc',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RRmcmc <- new(CLASS_RM,
.Data = RRmcmc,
type = c('distribution family'),
isotropy = c('cartesian system'),
domain = c('single variable', 'kernel'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = TRUE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -1
)
RRrectangular <- function(phi, safety, minsteplen, maxsteps, parts, maxit, innermin, outermax, mcmc_n, normed, approx, onesided) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('safety') && !is.null(subst <- substitute(safety)))
par.model[['safety']] <- CheckArg(safety, subst, FALSE)
if (hasArg('minsteplen') && !is.null(subst <- substitute(minsteplen)))
par.model[['minsteplen']] <- CheckArg(minsteplen, subst, FALSE)
if (hasArg('maxsteps') && !is.null(subst <- substitute(maxsteps)))
par.model[['maxsteps']] <- CheckArg(maxsteps, subst, FALSE)
if (hasArg('parts') && !is.null(subst <- substitute(parts)))
par.model[['parts']] <- CheckArg(parts, subst, FALSE)
if (hasArg('maxit') && !is.null(subst <- substitute(maxit)))
par.model[['maxit']] <- CheckArg(maxit, subst, FALSE)
if (hasArg('innermin') && !is.null(subst <- substitute(innermin)))
par.model[['innermin']] <- CheckArg(innermin, subst, FALSE)
if (hasArg('outermax') && !is.null(subst <- substitute(outermax)))
par.model[['outermax']] <- CheckArg(outermax, subst, FALSE)
if (hasArg('mcmc_n') && !is.null(subst <- substitute(mcmc_n)))
par.model[['mcmc_n']] <- CheckArg(mcmc_n, subst, FALSE)
if (hasArg('normed') && !is.null(subst <- substitute(normed)))
par.model[['normed']] <- CheckArg(normed, subst, FALSE)
if (hasArg('approx') && !is.null(subst <- substitute(approx)))
par.model[['approx']] <- CheckArg(approx, subst, FALSE)
if (hasArg('onesided') && !is.null(subst <- substitute(onesided)))
par.model[['onesided']] <- CheckArg(onesided, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RRrectangular',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RRrectangular <- new(CLASS_RM,
.Data = RRrectangular,
type = c('distribution family'),
isotropy = c('cartesian system'),
domain = c('single variable', 'kernel'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = TRUE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -1
)
RRspheric <- function(spacedim, balldim, R) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('spacedim') && !is.null(subst <- substitute(spacedim)))
par.model[['spacedim']] <- CheckArg(spacedim, subst, FALSE)
if (hasArg('balldim') && !is.null(subst <- substitute(balldim)))
par.model[['balldim']] <- CheckArg(balldim, subst, FALSE)
if (hasArg('R') && !is.null(subst <- substitute(R)))
par.model[['R']] <- CheckArg(R, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RRspheric',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RRspheric <- new(CLASS_RM,
.Data = RRspheric,
type = c('distribution family'),
isotropy = c('cartesian system'),
domain = c('single variable'),
operator = FALSE,
monotone = 'mismatch in monotonicity',
finiterange = TRUE,
simpleArguments = TRUE,
maxdim = 1,
vdim = 1
)
RRunif <- function(min, max, normed) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('min') && !is.null(subst <- substitute(min)))
par.model[['min']] <- CheckArg(min, subst, FALSE)
if (hasArg('max') && !is.null(subst <- substitute(max)))
par.model[['max']] <- CheckArg(max, subst, FALSE)
if (hasArg('normed') && !is.null(subst <- substitute(normed)))
par.model[['normed']] <- CheckArg(normed, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RRunif',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RRunif <- new(CLASS_RM,
.Data = RRunif,
type = c('distribution family'),
isotropy = c('cartesian system'),
domain = c('single variable', 'kernel'),
operator = FALSE,
monotone = 'mismatch in monotonicity',
finiterange = TRUE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -1
)
RMmppplus <- function(C0, C1, C2, C3, C4, C5, C6, C7, C8, C9, p) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(C0)) submodels[['C0']] <- C0
if (hasArg(C1)) submodels[['C1']] <- C1
if (hasArg(C2)) submodels[['C2']] <- C2
if (hasArg(C3)) submodels[['C3']] <- C3
if (hasArg(C4)) submodels[['C4']] <- C4
if (hasArg(C5)) submodels[['C5']] <- C5
if (hasArg(C6)) submodels[['C6']] <- C6
if (hasArg(C7)) submodels[['C7']] <- C7
if (hasArg(C8)) submodels[['C8']] <- C8
if (hasArg(C9)) submodels[['C9']] <- C9
if (hasArg('p') && !is.null(subst <- substitute(p)))
par.model[['p']] <- CheckArg(p, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RMmppplus',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RMmppplus <- new(CLASS_RM,
.Data = RMmppplus,
type = c('point-shape function'),
isotropy = c('framework dependent'),
domain = c('single variable', 'kernel'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = -3
)
iRFcov <- function(phi) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
model <- methods::new('RMmodel', call = cl, name = 'RFcov',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
iRFcov <- new(CLASS_RM,
.Data = iRFcov,
type = c('interface'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = -3
)
iRFcovmatrix <- function(phi) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
model <- methods::new('RMmodel', call = cl, name = 'RFcovmatrix',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
iRFcovmatrix <- new(CLASS_RM,
.Data = iRFcovmatrix,
type = c('interface'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = -3
)
iRFloglikelihood <- function(phi, data, estimate_variance, betas_separate, ignore_trend) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('data') && !is.null(subst <- substitute(data)))
par.model[['data']] <- CheckArg(data, subst, FALSE)
if (hasArg('estimate_variance') && !is.null(subst <- substitute(estimate_variance)))
par.model[['estimate_variance']] <- CheckArg(estimate_variance, subst, FALSE)
if (hasArg('betas_separate') && !is.null(subst <- substitute(betas_separate)))
par.model[['betas_separate']] <- CheckArg(betas_separate, subst, FALSE)
if (hasArg('ignore_trend') && !is.null(subst <- substitute(ignore_trend)))
par.model[['ignore_trend']] <- CheckArg(ignore_trend, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RFloglikelihood',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
iRFloglikelihood <- new(CLASS_RM,
.Data = iRFloglikelihood,
type = c('interface'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = NA,
simpleArguments = FALSE,
maxdim = -3,
vdim = -3
)
iRFpseudovariogra <- function(phi) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
model <- methods::new('RMmodel', call = cl, name = 'RFpseudovariogra',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
iRFpseudovariogra <- new(CLASS_RM,
.Data = iRFpseudovariogra,
type = c('interface'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = -3
)
iRFvariogram <- function(phi) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
model <- methods::new('RMmodel', call = cl, name = 'RFvariogram',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
iRFvariogram <- new(CLASS_RM,
.Data = iRFvariogram,
type = c('interface'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = NA,
simpleArguments = TRUE,
maxdim = -3,
vdim = -3
)
iRFsimulate <- function(phi, checkonly, setseed, env) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('checkonly') && !is.null(subst <- substitute(checkonly)))
par.model[['checkonly']] <- CheckArg(checkonly, subst, FALSE)
if (hasArg('setseed') && !is.null(subst <- substitute(setseed)))
par.model[['setseed']] <- CheckArg(setseed, subst, FALSE)
if (hasArg('env') && !is.null(subst <- substitute(env)))
par.model[['env']] <- CheckArg(env, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RFsimulate',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
iRFsimulate <- new(CLASS_RM,
.Data = iRFsimulate,
type = c('interface'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = NA,
simpleArguments = FALSE,
maxdim = -3,
vdim = -3
)
RPtrend <- function(phi, mean) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('mean') && !is.null(subst <- substitute(mean)))
par.model[['mean']] <- CheckArg(mean, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPtrend',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPtrend <- new(CLASS_RM,
.Data = RPtrend,
type = c('process', 'method for Gauss process'),
isotropy = c('non-dimension-reducing', 'non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -3
)
RPaverage <- function(phi, shape, boxcox, intensity, method) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg(shape)) submodels[['shape']] <- shape
if (hasArg('boxcox') && !is.null(subst <- substitute(boxcox)))
par.model[['boxcox']] <- CheckArg(boxcox, subst, FALSE)
if (hasArg('intensity') && !is.null(subst <- substitute(intensity)))
par.model[['intensity']] <- CheckArg(intensity, subst, FALSE)
if (hasArg('method') && !is.null(subst <- substitute(method)))
par.model[['method']] <- CheckArg(method, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPaverage',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPaverage <- new(CLASS_RM,
.Data = RPaverage,
type = c('method for Gauss process'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 4,
vdim = 1
)
RPcoins <- function(phi, shape, boxcox, intensity, method) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg(shape)) submodels[['shape']] <- shape
if (hasArg('boxcox') && !is.null(subst <- substitute(boxcox)))
par.model[['boxcox']] <- CheckArg(boxcox, subst, FALSE)
if (hasArg('intensity') && !is.null(subst <- substitute(intensity)))
par.model[['intensity']] <- CheckArg(intensity, subst, FALSE)
if (hasArg('method') && !is.null(subst <- substitute(method)))
par.model[['method']] <- CheckArg(method, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPcoins',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPcoins <- new(CLASS_RM,
.Data = RPcoins,
type = c('method for Gauss process'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 4,
vdim = 1
)
RPcirculant <- function(phi, boxcox, force, mmin, strategy, maxGB, maxmem, tolIm, tolRe, trials, useprimes, dependent, approx_step, approx_maxgrid) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('boxcox') && !is.null(subst <- substitute(boxcox)))
par.model[['boxcox']] <- CheckArg(boxcox, subst, FALSE)
if (hasArg('force') && !is.null(subst <- substitute(force)))
par.model[['force']] <- CheckArg(force, subst, FALSE)
if (hasArg('mmin') && !is.null(subst <- substitute(mmin)))
par.model[['mmin']] <- CheckArg(mmin, subst, FALSE)
if (hasArg('strategy') && !is.null(subst <- substitute(strategy)))
par.model[['strategy']] <- CheckArg(strategy, subst, FALSE)
if (hasArg('maxGB') && !is.null(subst <- substitute(maxGB)))
par.model[['maxGB']] <- CheckArg(maxGB, subst, FALSE)
if (hasArg('maxmem') && !is.null(subst <- substitute(maxmem)))
par.model[['maxmem']] <- CheckArg(maxmem, subst, FALSE)
if (hasArg('tolIm') && !is.null(subst <- substitute(tolIm)))
par.model[['tolIm']] <- CheckArg(tolIm, subst, FALSE)
if (hasArg('tolRe') && !is.null(subst <- substitute(tolRe)))
par.model[['tolRe']] <- CheckArg(tolRe, subst, FALSE)
if (hasArg('trials') && !is.null(subst <- substitute(trials)))
par.model[['trials']] <- CheckArg(trials, subst, FALSE)
if (hasArg('useprimes') && !is.null(subst <- substitute(useprimes)))
par.model[['useprimes']] <- CheckArg(useprimes, subst, FALSE)
if (hasArg('dependent') && !is.null(subst <- substitute(dependent)))
par.model[['dependent']] <- CheckArg(dependent, subst, FALSE)
if (hasArg('approx_step') && !is.null(subst <- substitute(approx_step)))
par.model[['approx_step']] <- CheckArg(approx_step, subst, FALSE)
if (hasArg('approx_maxgrid') && !is.null(subst <- substitute(approx_maxgrid)))
par.model[['approx_maxgrid']] <- CheckArg(approx_maxgrid, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPcirculant',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPcirculant <- new(CLASS_RM,
.Data = RPcirculant,
type = c('method for Gauss process'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 13,
vdim = -3
)
RPcutoff <- function(phi, boxcox, force, mmin, strategy, maxGB, maxmem, tolIm, tolRe, trials, useprimes, dependent, approx_step, approx_maxgrid, diameter, a) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('boxcox') && !is.null(subst <- substitute(boxcox)))
par.model[['boxcox']] <- CheckArg(boxcox, subst, FALSE)
if (hasArg('force') && !is.null(subst <- substitute(force)))
par.model[['force']] <- CheckArg(force, subst, FALSE)
if (hasArg('mmin') && !is.null(subst <- substitute(mmin)))
par.model[['mmin']] <- CheckArg(mmin, subst, FALSE)
if (hasArg('strategy') && !is.null(subst <- substitute(strategy)))
par.model[['strategy']] <- CheckArg(strategy, subst, FALSE)
if (hasArg('maxGB') && !is.null(subst <- substitute(maxGB)))
par.model[['maxGB']] <- CheckArg(maxGB, subst, FALSE)
if (hasArg('maxmem') && !is.null(subst <- substitute(maxmem)))
par.model[['maxmem']] <- CheckArg(maxmem, subst, FALSE)
if (hasArg('tolIm') && !is.null(subst <- substitute(tolIm)))
par.model[['tolIm']] <- CheckArg(tolIm, subst, FALSE)
if (hasArg('tolRe') && !is.null(subst <- substitute(tolRe)))
par.model[['tolRe']] <- CheckArg(tolRe, subst, FALSE)
if (hasArg('trials') && !is.null(subst <- substitute(trials)))
par.model[['trials']] <- CheckArg(trials, subst, FALSE)
if (hasArg('useprimes') && !is.null(subst <- substitute(useprimes)))
par.model[['useprimes']] <- CheckArg(useprimes, subst, FALSE)
if (hasArg('dependent') && !is.null(subst <- substitute(dependent)))
par.model[['dependent']] <- CheckArg(dependent, subst, FALSE)
if (hasArg('approx_step') && !is.null(subst <- substitute(approx_step)))
par.model[['approx_step']] <- CheckArg(approx_step, subst, FALSE)
if (hasArg('approx_maxgrid') && !is.null(subst <- substitute(approx_maxgrid)))
par.model[['approx_maxgrid']] <- CheckArg(approx_maxgrid, subst, FALSE)
if (hasArg('diameter') && !is.null(subst <- substitute(diameter)))
par.model[['diameter']] <- CheckArg(diameter, subst, FALSE)
if (hasArg('a') && !is.null(subst <- substitute(a)))
par.model[['a']] <- CheckArg(a, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPcutoff',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPcutoff <- new(CLASS_RM,
.Data = RPcutoff,
type = c('method for Gauss process', 'method for Gauss process'),
isotropy = c('non-dimension-reducing', 'non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 13,
vdim = 1
)
RPintrinsic <- function(phi, boxcox, force, mmin, strategy, maxGB, maxmem, tolIm, tolRe, trials, useprimes, dependent, approx_step, approx_maxgrid, diameter, rawR) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('boxcox') && !is.null(subst <- substitute(boxcox)))
par.model[['boxcox']] <- CheckArg(boxcox, subst, FALSE)
if (hasArg('force') && !is.null(subst <- substitute(force)))
par.model[['force']] <- CheckArg(force, subst, FALSE)
if (hasArg('mmin') && !is.null(subst <- substitute(mmin)))
par.model[['mmin']] <- CheckArg(mmin, subst, FALSE)
if (hasArg('strategy') && !is.null(subst <- substitute(strategy)))
par.model[['strategy']] <- CheckArg(strategy, subst, FALSE)
if (hasArg('maxGB') && !is.null(subst <- substitute(maxGB)))
par.model[['maxGB']] <- CheckArg(maxGB, subst, FALSE)
if (hasArg('maxmem') && !is.null(subst <- substitute(maxmem)))
par.model[['maxmem']] <- CheckArg(maxmem, subst, FALSE)
if (hasArg('tolIm') && !is.null(subst <- substitute(tolIm)))
par.model[['tolIm']] <- CheckArg(tolIm, subst, FALSE)
if (hasArg('tolRe') && !is.null(subst <- substitute(tolRe)))
par.model[['tolRe']] <- CheckArg(tolRe, subst, FALSE)
if (hasArg('trials') && !is.null(subst <- substitute(trials)))
par.model[['trials']] <- CheckArg(trials, subst, FALSE)
if (hasArg('useprimes') && !is.null(subst <- substitute(useprimes)))
par.model[['useprimes']] <- CheckArg(useprimes, subst, FALSE)
if (hasArg('dependent') && !is.null(subst <- substitute(dependent)))
par.model[['dependent']] <- CheckArg(dependent, subst, FALSE)
if (hasArg('approx_step') && !is.null(subst <- substitute(approx_step)))
par.model[['approx_step']] <- CheckArg(approx_step, subst, FALSE)
if (hasArg('approx_maxgrid') && !is.null(subst <- substitute(approx_maxgrid)))
par.model[['approx_maxgrid']] <- CheckArg(approx_maxgrid, subst, FALSE)
if (hasArg('diameter') && !is.null(subst <- substitute(diameter)))
par.model[['diameter']] <- CheckArg(diameter, subst, FALSE)
if (hasArg('rawR') && !is.null(subst <- substitute(rawR)))
par.model[['rawR']] <- CheckArg(rawR, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPintrinsic',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPintrinsic <- new(CLASS_RM,
.Data = RPintrinsic,
type = c('method for Gauss process', 'method for Gauss process'),
isotropy = c('non-dimension-reducing', 'non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 13,
vdim = 1
)
RPdirect <- function(phi, boxcox) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('boxcox') && !is.null(subst <- substitute(boxcox)))
par.model[['boxcox']] <- CheckArg(boxcox, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPdirect',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPdirect <- new(CLASS_RM,
.Data = RPdirect,
type = c('method for Gauss process'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -3
)
RPhyperplane <- function(phi, boxcox, superpos, maxlines, mar_distr, mar_param, additive) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('boxcox') && !is.null(subst <- substitute(boxcox)))
par.model[['boxcox']] <- CheckArg(boxcox, subst, FALSE)
if (hasArg('superpos') && !is.null(subst <- substitute(superpos)))
par.model[['superpos']] <- CheckArg(superpos, subst, FALSE)
if (hasArg('maxlines') && !is.null(subst <- substitute(maxlines)))
par.model[['maxlines']] <- CheckArg(maxlines, subst, FALSE)
if (hasArg('mar_distr') && !is.null(subst <- substitute(mar_distr)))
par.model[['mar_distr']] <- CheckArg(mar_distr, subst, FALSE)
if (hasArg('mar_param') && !is.null(subst <- substitute(mar_param)))
par.model[['mar_param']] <- CheckArg(mar_param, subst, FALSE)
if (hasArg('additive') && !is.null(subst <- substitute(additive)))
par.model[['additive']] <- CheckArg(additive, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPhyperplane',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPhyperplane <- new(CLASS_RM,
.Data = RPhyperplane,
type = c('method for Gauss process', 'method for Gauss process'),
isotropy = c('non-dimension-reducing', 'non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 2,
vdim = 1
)
RPnugget <- function(phi, boxcox, tol, vdim) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('boxcox') && !is.null(subst <- substitute(boxcox)))
par.model[['boxcox']] <- CheckArg(boxcox, subst, FALSE)
if (hasArg('tol') && !is.null(subst <- substitute(tol)))
par.model[['tol']] <- CheckArg(tol, subst, FALSE)
if (hasArg('vdim') && !is.null(subst <- substitute(vdim)))
par.model[['vdim']] <- CheckArg(vdim, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPnugget',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPnugget <- new(CLASS_RM,
.Data = RPnugget,
type = c('method for Gauss process', 'method for Gauss process'),
isotropy = c('non-dimension-reducing', 'non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = TRUE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -2
)
RPsequential <- function(phi, boxcox, back_steps, initial) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('boxcox') && !is.null(subst <- substitute(boxcox)))
par.model[['boxcox']] <- CheckArg(boxcox, subst, FALSE)
if (hasArg('back_steps') && !is.null(subst <- substitute(back_steps)))
par.model[['back_steps']] <- CheckArg(back_steps, subst, FALSE)
if (hasArg('initial') && !is.null(subst <- substitute(initial)))
par.model[['initial']] <- CheckArg(initial, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPsequential',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPsequential <- new(CLASS_RM,
.Data = RPsequential,
type = c('method for Gauss process'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RPspectral <- function(phi, boxcox, sp_lines, sp_grid, prop_factor, sigma) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('boxcox') && !is.null(subst <- substitute(boxcox)))
par.model[['boxcox']] <- CheckArg(boxcox, subst, FALSE)
if (hasArg('sp_lines') && !is.null(subst <- substitute(sp_lines)))
par.model[['sp_lines']] <- CheckArg(sp_lines, subst, FALSE)
if (hasArg('sp_grid') && !is.null(subst <- substitute(sp_grid)))
par.model[['sp_grid']] <- CheckArg(sp_grid, subst, FALSE)
if (hasArg('prop_factor') && !is.null(subst <- substitute(prop_factor)))
par.model[['prop_factor']] <- CheckArg(prop_factor, subst, FALSE)
if (hasArg('sigma') && !is.null(subst <- substitute(sigma)))
par.model[['sigma']] <- CheckArg(sigma, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPspectral',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPspectral <- new(CLASS_RM,
.Data = RPspectral,
type = c('method for Gauss process', 'method for Gauss process'),
isotropy = c('non-dimension-reducing', 'non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 4,
vdim = 1
)
RPspecific <- function(phi, boxcox) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('boxcox') && !is.null(subst <- substitute(boxcox)))
par.model[['boxcox']] <- CheckArg(boxcox, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPspecific',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPspecific <- new(CLASS_RM,
.Data = RPspecific,
type = c('method for Gauss process'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 4,
vdim = -3
)
RPtbm <- function(phi, boxcox, fulldim, reduceddim, layers, lines, linessimufactor, linesimustep, center, points) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('boxcox') && !is.null(subst <- substitute(boxcox)))
par.model[['boxcox']] <- CheckArg(boxcox, subst, FALSE)
if (hasArg('fulldim') && !is.null(subst <- substitute(fulldim)))
par.model[['fulldim']] <- CheckArg(fulldim, subst, FALSE)
if (hasArg('reduceddim') && !is.null(subst <- substitute(reduceddim)))
par.model[['reduceddim']] <- CheckArg(reduceddim, subst, FALSE)
if (hasArg('layers') && !is.null(subst <- substitute(layers)))
par.model[['layers']] <- CheckArg(layers, subst, FALSE)
if (hasArg('lines') && !is.null(subst <- substitute(lines)))
par.model[['lines']] <- CheckArg(lines, subst, FALSE)
if (hasArg('linessimufactor') && !is.null(subst <- substitute(linessimufactor)))
par.model[['linessimufactor']] <- CheckArg(linessimufactor, subst, FALSE)
if (hasArg('linesimustep') && !is.null(subst <- substitute(linesimustep)))
par.model[['linesimustep']] <- CheckArg(linesimustep, subst, FALSE)
if (hasArg('center') && !is.null(subst <- substitute(center)))
par.model[['center']] <- CheckArg(center, subst, FALSE)
if (hasArg('points') && !is.null(subst <- substitute(points)))
par.model[['points']] <- CheckArg(points, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPtbm',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPtbm <- new(CLASS_RM,
.Data = RPtbm,
type = c('method for Gauss process', 'method for Gauss process'),
isotropy = c('non-dimension-reducing', 'non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -3,
vdim = -1
)
RPloggaussnormed <- function(variogram, prob, optimize_p, nth, burn.in, rejection) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(variogram)) submodels[['variogram']] <- variogram
if (hasArg('prob') && !is.null(subst <- substitute(prob)))
par.model[['prob']] <- CheckArg(prob, subst, FALSE)
if (hasArg('optimize_p') && !is.null(subst <- substitute(optimize_p)))
par.model[['optimize_p']] <- CheckArg(optimize_p, subst, FALSE)
if (hasArg('nth') && !is.null(subst <- substitute(nth)))
par.model[['nth']] <- CheckArg(nth, subst, FALSE)
if (hasArg('burn.in') && !is.null(subst <- substitute(burn.in)))
par.model[['burn.in']] <- CheckArg(burn.in, subst, FALSE)
if (hasArg('rejection') && !is.null(subst <- substitute(rejection)))
par.model[['rejection']] <- CheckArg(rejection, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPloggaussnormed',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPloggaussnormed <- new(CLASS_RM,
.Data = RPloggaussnormed,
type = c('normed process (non-negative values with maximum value being 0 or 1)'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 4,
vdim = -3
)
RPbrorig <- function(phi, tcf, xi, mu, s) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg(tcf)) submodels[['tcf']] <- tcf
if (hasArg('xi') && !is.null(subst <- substitute(xi)))
par.model[['xi']] <- CheckArg(xi, subst, FALSE)
if (hasArg('mu') && !is.null(subst <- substitute(mu)))
par.model[['mu']] <- CheckArg(mu, subst, FALSE)
if (hasArg('s') && !is.null(subst <- substitute(s)))
par.model[['s']] <- CheckArg(s, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPbrorig',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPbrorig <- new(CLASS_RM,
.Data = RPbrorig,
type = c('method for Brown-Resnick process'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 4,
vdim = 1
)
RPbrmixed <- function(phi, tcf, xi, mu, s, meshsize, vertnumber, optim_mixed, optim_mixed_tol, lambda, areamat, variobound) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg(tcf)) submodels[['tcf']] <- tcf
if (hasArg('xi') && !is.null(subst <- substitute(xi)))
par.model[['xi']] <- CheckArg(xi, subst, FALSE)
if (hasArg('mu') && !is.null(subst <- substitute(mu)))
par.model[['mu']] <- CheckArg(mu, subst, FALSE)
if (hasArg('s') && !is.null(subst <- substitute(s)))
par.model[['s']] <- CheckArg(s, subst, FALSE)
if (hasArg('meshsize') && !is.null(subst <- substitute(meshsize)))
par.model[['meshsize']] <- CheckArg(meshsize, subst, FALSE)
if (hasArg('vertnumber') && !is.null(subst <- substitute(vertnumber)))
par.model[['vertnumber']] <- CheckArg(vertnumber, subst, FALSE)
if (hasArg('optim_mixed') && !is.null(subst <- substitute(optim_mixed)))
par.model[['optim_mixed']] <- CheckArg(optim_mixed, subst, FALSE)
if (hasArg('optim_mixed_tol') && !is.null(subst <- substitute(optim_mixed_tol)))
par.model[['optim_mixed_tol']] <- CheckArg(optim_mixed_tol, subst, FALSE)
if (hasArg('lambda') && !is.null(subst <- substitute(lambda)))
par.model[['lambda']] <- CheckArg(lambda, subst, FALSE)
if (hasArg('areamat') && !is.null(subst <- substitute(areamat)))
par.model[['areamat']] <- CheckArg(areamat, subst, FALSE)
if (hasArg('variobound') && !is.null(subst <- substitute(variobound)))
par.model[['variobound']] <- CheckArg(variobound, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPbrmixed',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPbrmixed <- new(CLASS_RM,
.Data = RPbrmixed,
type = c('method for Brown-Resnick process'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 4,
vdim = -3
)
RPbrshifted <- function(phi, tcf, xi, mu, s) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg(tcf)) submodels[['tcf']] <- tcf
if (hasArg('xi') && !is.null(subst <- substitute(xi)))
par.model[['xi']] <- CheckArg(xi, subst, FALSE)
if (hasArg('mu') && !is.null(subst <- substitute(mu)))
par.model[['mu']] <- CheckArg(mu, subst, FALSE)
if (hasArg('s') && !is.null(subst <- substitute(s)))
par.model[['s']] <- CheckArg(s, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPbrshifted',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPbrshifted <- new(CLASS_RM,
.Data = RPbrshifted,
type = c('method for Brown-Resnick process'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 4,
vdim = 1
)
RPbrownresnick <- function(phi, tcf, xi, mu, s) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg(tcf)) submodels[['tcf']] <- tcf
if (hasArg('xi') && !is.null(subst <- substitute(xi)))
par.model[['xi']] <- CheckArg(xi, subst, FALSE)
if (hasArg('mu') && !is.null(subst <- substitute(mu)))
par.model[['mu']] <- CheckArg(mu, subst, FALSE)
if (hasArg('s') && !is.null(subst <- substitute(s)))
par.model[['s']] <- CheckArg(s, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPbrownresnick',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPbrownresnick <- new(CLASS_RM,
.Data = RPbrownresnick,
type = c('method for Brown-Resnick process'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 4,
vdim = 1
)
RPbernoulli <- function(phi, stationary_only, threshold) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('stationary_only') && !is.null(subst <- substitute(stationary_only)))
par.model[['stationary_only']] <- CheckArg(stationary_only, subst, FALSE)
if (hasArg('threshold') && !is.null(subst <- substitute(threshold)))
par.model[['threshold']] <- CheckArg(threshold, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPbernoulli',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPbernoulli <- new(CLASS_RM,
.Data = RPbernoulli,
type = c('normed process (non-negative values with maximum value being 0 or 1)'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -3
)
RPgauss <- function(phi, boxcox, stationary_only) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('boxcox') && !is.null(subst <- substitute(boxcox)))
par.model[['boxcox']] <- CheckArg(boxcox, subst, FALSE)
if (hasArg('stationary_only') && !is.null(subst <- substitute(stationary_only)))
par.model[['stationary_only']] <- CheckArg(stationary_only, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPgauss',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPgauss <- new(CLASS_RM,
.Data = RPgauss,
type = c('method for Gauss process'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -3
)
RPpoisson <- function(phi, intensity) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('intensity') && !is.null(subst <- substitute(intensity)))
par.model[['intensity']] <- CheckArg(intensity, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPpoisson',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPpoisson <- new(CLASS_RM,
.Data = RPpoisson,
type = c('Poisson'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 4,
vdim = -3
)
RPschlather <- function(phi, tcf, xi, mu, s) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg(tcf)) submodels[['tcf']] <- tcf
if (hasArg('xi') && !is.null(subst <- substitute(xi)))
par.model[['xi']] <- CheckArg(xi, subst, FALSE)
if (hasArg('mu') && !is.null(subst <- substitute(mu)))
par.model[['mu']] <- CheckArg(mu, subst, FALSE)
if (hasArg('s') && !is.null(subst <- substitute(s)))
par.model[['s']] <- CheckArg(s, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPschlather',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPschlather <- new(CLASS_RM,
.Data = RPschlather,
type = c('Schlather'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RPopitz <- function(phi, xi, mu, s, alpha) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('xi') && !is.null(subst <- substitute(xi)))
par.model[['xi']] <- CheckArg(xi, subst, FALSE)
if (hasArg('mu') && !is.null(subst <- substitute(mu)))
par.model[['mu']] <- CheckArg(mu, subst, FALSE)
if (hasArg('s') && !is.null(subst <- substitute(s)))
par.model[['s']] <- CheckArg(s, subst, FALSE)
if (hasArg('alpha') && !is.null(subst <- substitute(alpha)))
par.model[['alpha']] <- CheckArg(alpha, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPopitz',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPopitz <- new(CLASS_RM,
.Data = RPopitz,
type = c('Schlather'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
RPsmith <- function(shape, tcf, xi, mu, s) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(shape)) submodels[['shape']] <- shape
if (hasArg(tcf)) submodels[['tcf']] <- tcf
if (hasArg('xi') && !is.null(subst <- substitute(xi)))
par.model[['xi']] <- CheckArg(xi, subst, FALSE)
if (hasArg('mu') && !is.null(subst <- substitute(mu)))
par.model[['mu']] <- CheckArg(mu, subst, FALSE)
if (hasArg('s') && !is.null(subst <- substitute(s)))
par.model[['s']] <- CheckArg(s, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPsmith',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPsmith <- new(CLASS_RM,
.Data = RPsmith,
type = c('Smith'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 4,
vdim = 1
)
RPchi2 <- function(phi, boxcox, f) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('boxcox') && !is.null(subst <- substitute(boxcox)))
par.model[['boxcox']] <- CheckArg(boxcox, subst, FALSE)
if (hasArg('f') && !is.null(subst <- substitute(f)))
par.model[['f']] <- CheckArg(f, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPchi2',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPchi2 <- new(CLASS_RM,
.Data = RPchi2,
type = c('process'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -3
)
RPt <- function(phi, boxcox, nu) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg(phi)) submodels[['phi']] <- phi
if (hasArg('boxcox') && !is.null(subst <- substitute(boxcox)))
par.model[['boxcox']] <- CheckArg(boxcox, subst, FALSE)
if (hasArg('nu') && !is.null(subst <- substitute(nu)))
par.model[['nu']] <- CheckArg(nu, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'RPt',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
RPt <- new(CLASS_RM,
.Data = RPt,
type = c('process'),
isotropy = c('non-dimension-reducing'),
domain = c('single variable'),
operator = TRUE,
monotone = 'mismatch in monotonicity',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = -3
)
R.minus <- function(x, y, factor) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
if (hasArg('y') && !is.null(subst <- substitute(y)))
par.model[['y']] <- CheckMaths(y, subst, TRUE)
if (hasArg('factor') && !is.null(subst <- substitute(factor)))
par.model[['factor']] <- CheckMaths(factor, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.minus',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.minus <- new(CLASS_RM,
.Data = R.minus,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.plus <- function(x, y, factor) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, FALSE)
if (hasArg('y') && !is.null(subst <- substitute(y)))
par.model[['y']] <- CheckMaths(y, subst, FALSE)
if (hasArg('factor') && !is.null(subst <- substitute(factor)))
par.model[['factor']] <- CheckMaths(factor, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'R.plus',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.plus <- new(CLASS_RM,
.Data = R.plus,
type = c('mathematical operator', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 1,
vdim = 1
)
R.div <- function(x, y, factor) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, FALSE)
if (hasArg('y') && !is.null(subst <- substitute(y)))
par.model[['y']] <- CheckMaths(y, subst, FALSE)
if (hasArg('factor') && !is.null(subst <- substitute(factor)))
par.model[['factor']] <- CheckMaths(factor, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'R.div',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.div <- new(CLASS_RM,
.Data = R.div,
type = c('mathematical operator', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 1,
vdim = 1
)
R.mult <- function(x, y, factor) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, FALSE)
if (hasArg('y') && !is.null(subst <- substitute(y)))
par.model[['y']] <- CheckMaths(y, subst, FALSE)
if (hasArg('factor') && !is.null(subst <- substitute(factor)))
par.model[['factor']] <- CheckMaths(factor, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'R.mult',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.mult <- new(CLASS_RM,
.Data = R.mult,
type = c('mathematical operator', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 1,
vdim = 1
)
R.const <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.const',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.const <- new(CLASS_RM,
.Data = R.const,
type = c('mathematical operator', 'trend', 'negative definite', 'tail correlation'),
isotropy = c('framework dependent', 'framework dependent', 'framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.p <- function(proj, new, factor) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('proj') && !is.null(subst <- substitute(proj)))
par.model[['proj']] <- CheckMixed(proj, subst, PROJECTION_NAMES)
if (!(hasArg('new') && !is.null(subst <- substitute(new)))) new <- UNREDUCED
par.model[['new']] <- CheckChar(new, subst, ISO_NAMES, FALSE)
if (hasArg('factor') && !is.null(subst <- substitute(factor)))
par.model[['factor']] <- CheckMaths(factor, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'R.p',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.p <- new(CLASS_RM,
.Data = R.p,
type = c('mathematical operator', 'trend'),
isotropy = c('parameter dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = Inf,
vdim = 1
)
R.c <- function(a, b, c, d, e, f, g, h, i, j, l, m, n, o, p, q, ncol, factor) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('a') && !is.null(subst <- substitute(a)))
par.model[['a']] <- CheckMaths(a, subst, TRUE)
if (hasArg('b') && !is.null(subst <- substitute(b)))
par.model[['b']] <- CheckMaths(b, subst, TRUE)
if (hasArg('c') && !is.null(subst <- substitute(c)))
par.model[['c']] <- CheckMaths(c, subst, TRUE)
if (hasArg('d') && !is.null(subst <- substitute(d)))
par.model[['d']] <- CheckMaths(d, subst, TRUE)
if (hasArg('e') && !is.null(subst <- substitute(e)))
par.model[['e']] <- CheckMaths(e, subst, TRUE)
if (hasArg('f') && !is.null(subst <- substitute(f)))
par.model[['f']] <- CheckMaths(f, subst, TRUE)
if (hasArg('g') && !is.null(subst <- substitute(g)))
par.model[['g']] <- CheckMaths(g, subst, TRUE)
if (hasArg('h') && !is.null(subst <- substitute(h)))
par.model[['h']] <- CheckMaths(h, subst, TRUE)
if (hasArg('i') && !is.null(subst <- substitute(i)))
par.model[['i']] <- CheckMaths(i, subst, TRUE)
if (hasArg('j') && !is.null(subst <- substitute(j)))
par.model[['j']] <- CheckMaths(j, subst, TRUE)
if (hasArg('l') && !is.null(subst <- substitute(l)))
par.model[['l']] <- CheckMaths(l, subst, TRUE)
if (hasArg('m') && !is.null(subst <- substitute(m)))
par.model[['m']] <- CheckMaths(m, subst, TRUE)
if (hasArg('n') && !is.null(subst <- substitute(n)))
par.model[['n']] <- CheckMaths(n, subst, TRUE)
if (hasArg('o') && !is.null(subst <- substitute(o)))
par.model[['o']] <- CheckMaths(o, subst, TRUE)
if (hasArg('p') && !is.null(subst <- substitute(p)))
par.model[['p']] <- CheckMaths(p, subst, TRUE)
if (hasArg('q') && !is.null(subst <- substitute(q)))
par.model[['q']] <- CheckMaths(q, subst, TRUE)
if (hasArg('ncol') && !is.null(subst <- substitute(ncol)))
par.model[['ncol']] <- CheckMaths(ncol, subst, TRUE)
if (hasArg('factor') && !is.null(subst <- substitute(factor)))
par.model[['factor']] <- CheckMaths(factor, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.c',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.c <- new(CLASS_RM,
.Data = R.c,
type = c('shape function', 'trend'),
isotropy = c('submodel dependent', 'submodel dependent'),
domain = c('submodel dependent'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 1,
vdim = -1
)
R.is <- function(x, is, y) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
if (hasArg('is') && !is.null(subst <- substitute(is)))
par.model[['is']] <- CheckChar(is, subst, EQ_NAMES, TRUE)
if (hasArg('y') && !is.null(subst <- substitute(y)))
par.model[['y']] <- CheckMaths(y, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.is',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.is <- new(CLASS_RM,
.Data = R.is,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = 1,
vdim = 1
)
R.asin <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.asin',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.asin <- new(CLASS_RM,
.Data = R.asin,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.atan <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.atan',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.atan <- new(CLASS_RM,
.Data = R.atan,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.atan2 <- function(y, x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('y') && !is.null(subst <- substitute(y)))
par.model[['y']] <- CheckMaths(y, subst, TRUE)
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.atan2',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.atan2 <- new(CLASS_RM,
.Data = R.atan2,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.cos <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.cos',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.cos <- new(CLASS_RM,
.Data = R.cos,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.sin <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.sin',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.sin <- new(CLASS_RM,
.Data = R.sin,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.tan <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.tan',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.tan <- new(CLASS_RM,
.Data = R.tan,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.asinh <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.asinh',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.asinh <- new(CLASS_RM,
.Data = R.asinh,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.atanh <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.atanh',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.atanh <- new(CLASS_RM,
.Data = R.atanh,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.cosh <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.cosh',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.cosh <- new(CLASS_RM,
.Data = R.cosh,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.sinh <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.sinh',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.sinh <- new(CLASS_RM,
.Data = R.sinh,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.tanh <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.tanh',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.tanh <- new(CLASS_RM,
.Data = R.tanh,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.log <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.log',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.log <- new(CLASS_RM,
.Data = R.log,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.expm1 <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.expm1',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.expm1 <- new(CLASS_RM,
.Data = R.expm1,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.log1p <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.log1p',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.log1p <- new(CLASS_RM,
.Data = R.log1p,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.exp2 <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.exp2',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.exp2 <- new(CLASS_RM,
.Data = R.exp2,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.log2 <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.log2',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.log2 <- new(CLASS_RM,
.Data = R.log2,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.hypot <- function(x, y) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
if (hasArg('y') && !is.null(subst <- substitute(y)))
par.model[['y']] <- CheckMaths(y, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.hypot',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.hypot <- new(CLASS_RM,
.Data = R.hypot,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.cbrt <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.cbrt',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.cbrt <- new(CLASS_RM,
.Data = R.cbrt,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.ceil <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.ceil',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.ceil <- new(CLASS_RM,
.Data = R.ceil,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.floor <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.floor',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.floor <- new(CLASS_RM,
.Data = R.floor,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.fmod <- function(x, y) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
if (hasArg('y') && !is.null(subst <- substitute(y)))
par.model[['y']] <- CheckMaths(y, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.fmod',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.fmod <- new(CLASS_RM,
.Data = R.fmod,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.round <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.round',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.round <- new(CLASS_RM,
.Data = R.round,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.trunc <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.trunc',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.trunc <- new(CLASS_RM,
.Data = R.trunc,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.erfc <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.erfc',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.erfc <- new(CLASS_RM,
.Data = R.erfc,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.lgamma <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.lgamma',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.lgamma <- new(CLASS_RM,
.Data = R.lgamma,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.remainder <- function(x, y) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
if (hasArg('y') && !is.null(subst <- substitute(y)))
par.model[['y']] <- CheckMaths(y, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.remainder',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.remainder <- new(CLASS_RM,
.Data = R.remainder,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.fdim <- function(x, y) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
if (hasArg('y') && !is.null(subst <- substitute(y)))
par.model[['y']] <- CheckMaths(y, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.fdim',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.fdim <- new(CLASS_RM,
.Data = R.fdim,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.fmax <- function(x, y) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
if (hasArg('y') && !is.null(subst <- substitute(y)))
par.model[['y']] <- CheckMaths(y, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.fmax',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.fmax <- new(CLASS_RM,
.Data = R.fmax,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.fmin <- function(x, y) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, TRUE)
if (hasArg('y') && !is.null(subst <- substitute(y)))
par.model[['y']] <- CheckMaths(y, subst, TRUE)
model <- methods::new('RMmodel', call = cl, name = 'R.fmin',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.fmin <- new(CLASS_RM,
.Data = R.fmin,
type = c('shape function', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.gamma <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'R.gamma',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.gamma <- new(CLASS_RM,
.Data = R.gamma,
type = c('mathematical operator', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.exp <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'R.exp',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.exp <- new(CLASS_RM,
.Data = R.exp,
type = c('mathematical operator', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.erf <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'R.erf',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.erf <- new(CLASS_RM,
.Data = R.erf,
type = c('mathematical operator', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.fabs <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'R.fabs',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.fabs <- new(CLASS_RM,
.Data = R.fabs,
type = c('mathematical operator', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.acos <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'R.acos',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.acos <- new(CLASS_RM,
.Data = R.acos,
type = c('mathematical operator', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.acosh <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'R.acosh',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.acosh <- new(CLASS_RM,
.Data = R.acosh,
type = c('mathematical operator', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.pow <- function(x, y) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, FALSE)
if (hasArg('y') && !is.null(subst <- substitute(y)))
par.model[['y']] <- CheckMaths(y, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'R.pow',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.pow <- new(CLASS_RM,
.Data = R.pow,
type = c('mathematical operator', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)
R.sqrt <- function(x) {
cl <- match.call()
submodels <- par.general <- par.model <- list()
if (hasArg('x') && !is.null(subst <- substitute(x)))
par.model[['x']] <- CheckMaths(x, subst, FALSE)
model <- methods::new('RMmodel', call = cl, name = 'R.sqrt',
submodels = submodels,
par.model = par.model, par.general = par.general)
return(model)
}
R.sqrt <- new(CLASS_RM,
.Data = R.sqrt,
type = c('mathematical operator', 'trend'),
isotropy = c('framework dependent', 'framework dependent'),
domain = c('single variable'),
operator = FALSE,
monotone = 'not monotone',
finiterange = FALSE,
simpleArguments = TRUE,
maxdim = -2,
vdim = 1
)