Nothing
###############################################################################
## Convex Contamination
## (1-size)*e1 + size*e2, size~Binom(1, size)
## e1: ideal distribution
## e2: contaminating distribution
## size: amout of contamination (gross errors)
###############################################################################
setMethod("ConvexContamination", signature(e1 = "AbscontDistribution",
e2 = "AbscontDistribution",
size = "numeric"),
function(e1, e2, size){
TruncQuantile <- getdistrOption("TruncQuantile")
if(length(size) != 1)
stop("length of 'size' has to be 1")
if((size < 0)|(size > 1))
stop("'size' has to be in [0,1]")
rfun <- function(n){}
body(rfun) <- substitute({ r1 <- r1fun; r2 <- r2fun
ind <- rbinom(n, prob=size, size=1)
(1-ind)*r1(n) + ind*r2(n)},
list(size = size, r1fun = r(e1), r2fun = r(e2)))
dfun <- function(x, log = FALSE){}
body(dfun) <- substitute({ d1 <- d1fun; d2 <- d2fun
d0 <- (1-size)*d1(x) + size*d2(x)
if (log) d0 <- log(d0)
return(d0)
},
list(size = size, d1fun = d(e1), d2fun = d(e2)))
pfun <- function(q, lower.tail = TRUE, log.p = FALSE){}
body(pfun) <- substitute({
p1 <- function(x){
if ("lower.tail" %in% names(formals(p1fun)))
p1fun(x, lower.tail)
else {p0 <- p1fun(x)
if(!lower.tail) p0 <- 1-p0
return(p0)} }
p2 <- function(x){
if ("lower.tail" %in% names(formals(p2fun)))
p2fun(x, lower.tail)
else {p0 <- p2fun(x)
if(!lower.tail) p0 <- 1-p0
return(p0)} }
p0 <- (1-size)*p1(q) + size*p2(q)
if (log.p) p0 <- log(p0)
return(p0)
},
list(size = size, p1fun = p(e1), p2fun = p(e2)))
m1 <- min(q.l(e1)(TruncQuantile), q.l(e2)(TruncQuantile))
m21 <- ifelse("lower.tail" %in% names(formals(e1@q)),
q.l(e1)(TruncQuantile, lower.tail = FALSE),
q.l(e1)(1-TruncQuantile))
m22 <- ifelse("lower.tail" %in% names(formals(e2@q)),
q.l(e2)(TruncQuantile, lower.tail = FALSE),
q.l(e2)(1-TruncQuantile))
m2 <- max(m21,m22); rm(m21,m22)
qfun <- function(p, lower.tail = TRUE, log.p = FALSE){}
body(qfun) <- substitute({ if (log.p) p <- exp(p)
pfunx <- seq(from = m1, to = m2, length = 1e5)
p0 <- pfun
pfuny <- p0(pfunx, lower.tail = lower.tail)
qfun1 <- approxfun(x = pfuny, y = pfunx,
rule = 2)
y <- ifelse(p > 1,
NaN,
ifelse(p < 0, NaN, qfun1(p)))
return(y)},
list(m1 = m1, m2 = m2, pfun = pfun))
Symmetry <- NoSymmetry()
if(is(e1@Symmetry,"SphericalSymmetry")&&
is(e2@Symmetry,"SphericalSymmetry"))
if(.isEqual(SymmCenter(e1@Symmetry),SymmCenter(e2@Symmetry)))
Symmetry <- SphericalSymmetry(SymmCenter(e1@Symmetry))
return(new("AbscontDistribution", r = rfun, d = dfun, p = pfun,
q = qfun,
.withSim = e1@.withSim|e2@.withSim,
.withArith = e1@.withArith|e2@.withArith,
.logExact = FALSE,
.lowerExact = e1@.lowerExact & e2@.lowerExact,
Symmetry = Symmetry))
})
setMethod("ConvexContamination", signature(e1 = "DiscreteDistribution",
e2 = "DiscreteDistribution",
size = "numeric"),
function(e1, e2, size){
if(length(size) != 1)
stop("length of 'size' has to be 1")
if((size < 0)|(size > 1))
stop("'size' has to be in [0,1]")
supp <- union(support(e1), support(e2))
len <- length(supp)
if(length(usupp <- unique(supp)) < len){
supp <- sort(usupp)
len <- length(supp)
}else{
o <- order(supp)
supp <- supp[o]
}
rfun <- function(n){}
body(rfun) <- substitute({ r1 <- r1fun; r2 <- r2fun
ind <- rbinom(n, prob=size, size=1)
(1-ind)*r1(n) + ind*r2(n)},
list(size = size, r1fun = r(e1), r2fun = r(e2)))
dfun <- function(x, log = FALSE){}
body(dfun) <- substitute({ d1 <- d1fun; d2 <- d2fun
d0 <- (1-size)*d1(x) + size*d2(x)
if(log) d0 <- log(d0)
return(d0) },
list(size = size, d1fun = d(e1), d2fun = d(e2)))
pfun <- function(q, lower.tail = TRUE, log.p = FALSE){}
body(pfun) <- substitute({
p1 <- function(x){
if ("lower.tail" %in% names(formals(p1fun)))
p1fun(x, lower.tail)
else {p0 <- p1fun(x)
if(!lower.tail) p0 <- 1-p0
return(p0)} }
p2 <- function(x){
if ("lower.tail" %in% names(formals(p2fun)))
p2fun(x, lower.tail)
else {p0 <- p2fun(x)
if(!lower.tail) p0 <- 1-p0
return(p0)} }
p0 <- (1-size)*p1(q) + size*p2(q)
if (log.p) p0 <- log(p0)
return(p0)
},
list(size = size, p1fun = p(e1), p2fun = p(e2)))
cumprob.l <- pfun(supp)
cumprob.u <- pfun(supp, lower.tail = FALSE)
qfun <- function(p, lower.tail = TRUE, log.p = FALSE)
{if(log.p) p <- exp(p)
i01 <- (0<=p)&(p<=1)
p01 <- p[i01]
q0 <- p
q0[!i01] <- NaN
if (lower.tail)
q0[i01] <- sapply(p01, function(x){
supp[ sum( cumprob.l < x ) + 1] })
else
q0[i01] <- sapply(p01, function(x){
(rev(supp))[sum( cumprob.u < x ) + 1] })
return(q0)
}
Symmetry <- NoSymmetry()
if(is(e1@Symmetry,"SphericalSymmetry")&&
is(e2@Symmetry,"SphericalSymmetry"))
if(.isEqual(SymmCenter(e1@Symmetry),SymmCenter(e2@Symmetry)))
Symmetry <- SphericalSymmetry(SymmCenter(e1@Symmetry))
return(new("DiscreteDistribution", r = rfun, d = dfun, p = pfun, q = qfun,
support = supp,
.withSim = e1@.withSim|e2@.withSim,
.withArith = e1@.withArith|e2@.withArith,
.logExact = FALSE,
.lowerExact = e1@.lowerExact & e2@.lowerExact,
Symmetry = Symmetry))
})
setMethod("ConvexContamination", signature(e1 = "UnivariateDistribution",
e2 = "UnivariateDistribution",
size = "numeric"),
function(e1, e2, size){
if(length(size) != 1)
stop("length of 'size' has to be 1")
if((size < 0)|(size > 1))
stop("'size' has to be in [0,1]")
rfun <- function(n){}
body(rfun) <- substitute({ r1 <- r1fun; r2 <- r2fun
ind <- rbinom(n, prob=size, size=1)
(1-ind)*r1(n) + ind*r2(n)},
list(size = size, r1fun = r(e1), r2fun = r(e2)))
pfun <- function(q, lower.tail = TRUE, log.p = FALSE){}
body(pfun) <- substitute({
p1 <- function(x){
if ("lower.tail" %in% names(formals(p1fun)))
p1fun(x, lower.tail)
else {p0 <- p1fun(x)
if(!lower.tail) p0 <- 1-p0
return(p0)} }
p2 <- function(x){
if ("lower.tail" %in% names(formals(p2fun)))
p2fun(x, lower.tail)
else {p0 <- p2fun(x)
if(!lower.tail) p0 <- 1-p0
return(p0)} }
p0 <- (1-size)*p1(q) + size*p2(q)
if (log.p) p0 <- log(p0)
return(p0)
},
list(size = size, p1fun = p(e1), p2fun = p(e2)))
TruncQuantile <- getdistrOption("TruncQuantile")
m1 <- min(q.l(e1)(TruncQuantile), q.l(e2)(TruncQuantile))
m21 <- ifelse("lower.tail" %in% names(formals(e1@q)),
q.l(e1)(TruncQuantile, lower.tail = FALSE),
q.l(e1)(1-TruncQuantile))
m22 <- ifelse("lower.tail" %in% names(formals(e2@q)),
q.l(e2)(TruncQuantile, lower.tail = FALSE),
q.l(e2)(1-TruncQuantile))
m2 <- max(m21,m22); rm(m21,m22)
qfun <- function(p, lower.tail = TRUE, log.p = FALSE){}
body(qfun) <- substitute({ if (log.p) p <- exp(p)
pfunx <- seq(from = m1, to = m2, length = 1e5)
p0 <- pfun
pfuny <- p0(pfunx, lower.tail = lower.tail)
qfun1 <- approxfun(x = pfuny, y = pfunx,
rule = 2)
y <- ifelse(p > 1,
NaN,
ifelse(p < 0, NaN, qfun1(p)))
return(y)},
list(m1 = m1, m2 = m2, pfun = pfun))
Symmetry <- NoSymmetry()
if(is(e1@Symmetry,"SphericalSymmetry")&&
is(e2@Symmetry,"SphericalSymmetry"))
if(.isEqual(SymmCenter(e1@Symmetry),SymmCenter(e2@Symmetry)))
Symmetry <- SphericalSymmetry(SymmCenter(e1@Symmetry))
return(new("UnivariateDistribution", img = img(e1), r = rfun, d = NULL,
p = pfun, q = qfun,
.withSim = e1@.withSim|e2@.withSim,
.withArith = e1@.withArith|e2@.withArith,
.logExact = FALSE,
.lowerExact = e1@.lowerExact & e2@.lowerExact,
Symmetry = Symmetry ))
})
setMethod("ConvexContamination", signature(e1 = "AcDcLcDistribution",
e2 = "AcDcLcDistribution",
size = "numeric"),
function(e1, e2, size){
e1 <- as(e1, "UnivarLebDecDistribution")
e2 <- as(e2, "UnivarLebDecDistribution")
if(length(size) != 1)
stop("length of 'size' has to be 1")
if((size < 0)|(size > 1))
stop("'size' has to be in [0,1]")
return(flat.mix(UnivarMixingDistribution(e1, e2,
mixCoeff = c(1-size,size))))
})
setMethod("ConvexContamination", signature(e1 = "LatticeDistribution",
e2 = "LatticeDistribution",
size = "numeric"),
getMethod("ConvexContamination", signature(e1 = "DiscreteDistribution",
e2 = "DiscreteDistribution",
size = "numeric")))
setMethod("ConvexContamination", signature(e1 = "LatticeDistribution",
e2 = "DiscreteDistribution",
size = "numeric"),
getMethod("ConvexContamination", signature(e1 = "DiscreteDistribution",
e2 = "DiscreteDistribution",
size = "numeric")))
setMethod("ConvexContamination", signature(e1 = "DiscreteDistribution",
e2 = "LatticeDistribution",
size = "numeric"),
getMethod("ConvexContamination", signature(e1 = "DiscreteDistribution",
e2 = "DiscreteDistribution",
size = "numeric")))
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