KINBII: K-inflated Negative Binomial type II distributions for...
In gamlss.countKinf: Generating and Fitting K-Inflated 'discrete gamlss.family' Distributions
Description
Usage
Arguments
Details
Value
Author(s)
References
See Also
Examples
Description
The function KINBII defines the K-inflated Negative Binomial type II distribution, a three parameter distribution, for a gamlss.family object to be used in GAMLSS fitting using the function gamlss(). The functions dKINBII, pKINBII, qKINBII and rKINBII define the density, distribution function, quantile function and random generation for the K-inflated Negative Binomial type II, KINBII(), distribution.
Usage
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KINBII(mu.link = "log", sigma.link = "log", nu.link = "logit", kinf="K")
dKINBII(x, mu = 1, sigma = 1, nu = 0.3, kinf=0 ,log = FALSE)
pKINBII(q, mu = 1, sigma = 1, nu = 0.3, kinf=0, lower.tail = TRUE,
log.p = FALSE)
qKINBII(p, mu = 1, sigma = 1, nu = 0.3, kinf=0, lower.tail = TRUE,
log.p = FALSE)
rKINBII(n, mu = 1, sigma = 1, nu = 0.3, kinf=0)
Arguments
mu.link
Defines the mu.link, with "log" link as the default for the mu parameter
sigma.link
Defines the sigma.link, with "log" link as the default for the sigma parameter
nu.link
Defines the nu.link, with "logit" link as the default for the nu parameter
x
vector of (non-negative integer) quantiles
mu
vector of positive means
sigma
vector of positive despersion parameter
nu
vector of inflated point probability
p
vector of probabilities
q
vector of quantiles
n
number of random values to return
kinf
defines inflated point in generating K-inflated distribution
log,log.p
logical; if TRUE, probabilities p are given as log(p)
lower.tail
logical; if TRUE (default), probabilities are P[X <= x],
otherwise, P[X > x]
Details
The definition for the K-inflated Negative Binomial type II distribution.
Value
The functions KINBII return a gamlss.family object which can be used to fit K-inflated Negative Binomial type II distribution in the gamlss() function.
Author(s)
Saeed Mohammadpour <s.mohammadpour1111@gamlil.com>, Mikis Stasinopoulos <d.stasinopoulos@londonmet.ac.uk>
References
Rigby, R. A. and Stasinopoulos D. M. (2005). Generalized additive models for location, scale and shape,(with discussion),Appl. Statist.,54, part 3, pp 507-554.
Stasinopoulos D. M., Rigby R.A. and Akantziliotou C. (2006) Instructions on how to use the GAMLSS package in R. Accompanying documentation in the current GAMLSS help files, (see also http://www.gamlss.org/).
Stasinopoulos D. M. Rigby R.A. (2007) Generalized additive models for location scale and shape (GAMLSS) in R.Journal of Statistical Software, Vol. 23, Issue 7, Dec 2007, http://www.jstatsoft.org/v23/i07.
Rigby, R. A. and Stasinopoulos D. M. (2010) The gamlss.family distributions, (distributed with this package or seehttp://www.gamlss.org/)
Stasinopoulos D. M., Rigby R.A., Heller G., Voudouris V., and De Bastiani F., (2017)Flexible Regression and Smoothing: Using GAMLSS in R, Chapman and Hall/CRC.
Najafabadi, A. T. P. and MohammadPour, S. (2017). A k-Inflated Negative Binomial Mixture Regression Model: Application to Rate-Making Systems. Asia-Pacific Journal of Risk and Insurance, 12.
See Also
Examples
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#--------------------------------------------------------------------------------
# gives default links for the Negative Binomial distribution type II
KINBII()
#--------------------------------------------------------------------------------
# generate zero inflated Negative Binomial type II distribution
gen.Kinf(family=NBII, kinf=0)
# generate random sample from zero inflated Negative Binomial type II distribution
x<-rinf0NBII(1000, mu=1, sigma=.5, nu=.2)
# fit the zero inflated Negative Binomial type II distribution using gamlss
data<-data.frame(x=x)
## Not run:
gamlss(x~1, family=inf0NBII, data=data)
histDist(x, family=inf0NBII)
## End(Not run)
#--------------------------------------------------------------------------------
# generated one inflated Negative Binomial type II distribution
gen.Kinf(family=NBII, kinf=1)
# generate random sample from one inflated Negative Binomial type II distribution
x<-rinf1NBII(1000,mu=1, sigma=.5, nu=.2)
# fit the one inflated Negative Binomial type II distribution using gamlss
data<-data.frame(x=x)
## Not run:
gamlss(x~1, family=inf1NBII, data=data)
histDist(x, family=inf1NBII)
## End(Not run)
#--------------------------------------------------------------------------------
mu=4; sigma=.5; nu=.2; tau=.2;
par(mgp=c(2,1,0),mar=c(4,4,4,1)+0.1)
#plot the pdf using plot
plot(function(x) dinf1NBII(x, mu=mu, sigma=sigma, nu=nu), from=0, to=20, n=20+1,
type="h",xlab="x",ylab="f(x)",cex.lab=1.5)
#--------------------------------------------------------------------------------
#plot the cdf using plot
cdf <- stepfun(0:19, c(0,pinf1NBII(0:19, mu=mu, sigma=sigma, nu=nu)), f = 0)
plot(cdf, xlab="x", ylab="F(x)", verticals=FALSE, cex.points=.8, pch=16, main="",cex.lab=1.5)
#--------------------------------------------------------------------------------
#plot the qdf using plot
invcdf <- stepfun(seq(0.01,.99,length=19), qinf1NBII(seq(0.1,.99,length=20),mu, sigma), f = 0)
plot(invcdf, ylab=expression(x[p]==F^{-1}(p)), do.points=FALSE,verticals=TRUE,
cex.points=.8, pch=16, main="",cex.lab=1.5, xlab="p")
#--------------------------------------------------------------------------------
# generate random sample
Ni <- rinf1NBII(1000, mu=mu, sigma=sigma, nu=nu)
hist(Ni,breaks=seq(min(Ni)-0.5,max(Ni)+0.5,by=1),col="lightgray", main="",cex.lab=2)
barplot(table(Ni))
#--------------------------------------------------------------------------------
gamlss.countKinf documentation built on May 2, 2019, 2:10 p.m.
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Description Usage Arguments Details Value Author(s) References See Also Examples
Description
The function KINBII defines the K-inflated Negative Binomial type II distribution, a three parameter distribution, for a gamlss.family object to be used in GAMLSS fitting using the function gamlss(). The functions dKINBII, pKINBII, qKINBII and rKINBII define the density, distribution function, quantile function and random generation for the K-inflated Negative Binomial type II, KINBII(), distribution.
Usage
1 2 3 4 5 6 7 8 9 10 11 | KINBII(mu.link = "log", sigma.link = "log", nu.link = "logit", kinf="K")
dKINBII(x, mu = 1, sigma = 1, nu = 0.3, kinf=0 ,log = FALSE)
pKINBII(q, mu = 1, sigma = 1, nu = 0.3, kinf=0, lower.tail = TRUE,
log.p = FALSE)
qKINBII(p, mu = 1, sigma = 1, nu = 0.3, kinf=0, lower.tail = TRUE,
log.p = FALSE)
rKINBII(n, mu = 1, sigma = 1, nu = 0.3, kinf=0)
|
Arguments
mu.link |
Defines the |
sigma.link |
Defines the |
nu.link |
Defines the |
x |
vector of (non-negative integer) quantiles |
mu |
vector of positive means |
sigma |
vector of positive despersion parameter |
nu |
vector of inflated point probability |
p |
vector of probabilities |
q |
vector of quantiles |
n |
number of random values to return |
kinf |
defines inflated point in generating K-inflated distribution |
log,log.p |
logical; if TRUE, probabilities p are given as log(p) |
lower.tail |
logical; if TRUE (default), probabilities are P[X <= x], otherwise, P[X > x] |
Details
The definition for the K-inflated Negative Binomial type II distribution.
Value
The functions KINBII return a gamlss.family object which can be used to fit K-inflated Negative Binomial type II distribution in the gamlss() function.
Author(s)
Saeed Mohammadpour <s.mohammadpour1111@gamlil.com>, Mikis Stasinopoulos <d.stasinopoulos@londonmet.ac.uk>
References
Rigby, R. A. and Stasinopoulos D. M. (2005). Generalized additive models for location, scale and shape,(with discussion),Appl. Statist.,54, part 3, pp 507-554.
Stasinopoulos D. M., Rigby R.A. and Akantziliotou C. (2006) Instructions on how to use the GAMLSS package in R. Accompanying documentation in the current GAMLSS help files, (see also http://www.gamlss.org/).
Stasinopoulos D. M. Rigby R.A. (2007) Generalized additive models for location scale and shape (GAMLSS) in R.Journal of Statistical Software, Vol. 23, Issue 7, Dec 2007, http://www.jstatsoft.org/v23/i07.
Rigby, R. A. and Stasinopoulos D. M. (2010) The gamlss.family distributions, (distributed with this package or seehttp://www.gamlss.org/)
Stasinopoulos D. M., Rigby R.A., Heller G., Voudouris V., and De Bastiani F., (2017)Flexible Regression and Smoothing: Using GAMLSS in R, Chapman and Hall/CRC.
Najafabadi, A. T. P. and MohammadPour, S. (2017). A k-Inflated Negative Binomial Mixture Regression Model: Application to Rate-Making Systems. Asia-Pacific Journal of Risk and Insurance, 12.
See Also
Examples
1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 16 17 18 19 20 21 22 23 24 25 26 27 28 29 30 31 32 33 34 35 36 37 38 39 40 41 42 43 44 45 46 47 48 49 50 51 52 53 54 55 56 57 58 | #--------------------------------------------------------------------------------
# gives default links for the Negative Binomial distribution type II
KINBII()
#--------------------------------------------------------------------------------
# generate zero inflated Negative Binomial type II distribution
gen.Kinf(family=NBII, kinf=0)
# generate random sample from zero inflated Negative Binomial type II distribution
x<-rinf0NBII(1000, mu=1, sigma=.5, nu=.2)
# fit the zero inflated Negative Binomial type II distribution using gamlss
data<-data.frame(x=x)
## Not run:
gamlss(x~1, family=inf0NBII, data=data)
histDist(x, family=inf0NBII)
## End(Not run)
#--------------------------------------------------------------------------------
# generated one inflated Negative Binomial type II distribution
gen.Kinf(family=NBII, kinf=1)
# generate random sample from one inflated Negative Binomial type II distribution
x<-rinf1NBII(1000,mu=1, sigma=.5, nu=.2)
# fit the one inflated Negative Binomial type II distribution using gamlss
data<-data.frame(x=x)
## Not run:
gamlss(x~1, family=inf1NBII, data=data)
histDist(x, family=inf1NBII)
## End(Not run)
#--------------------------------------------------------------------------------
mu=4; sigma=.5; nu=.2; tau=.2;
par(mgp=c(2,1,0),mar=c(4,4,4,1)+0.1)
#plot the pdf using plot
plot(function(x) dinf1NBII(x, mu=mu, sigma=sigma, nu=nu), from=0, to=20, n=20+1,
type="h",xlab="x",ylab="f(x)",cex.lab=1.5)
#--------------------------------------------------------------------------------
#plot the cdf using plot
cdf <- stepfun(0:19, c(0,pinf1NBII(0:19, mu=mu, sigma=sigma, nu=nu)), f = 0)
plot(cdf, xlab="x", ylab="F(x)", verticals=FALSE, cex.points=.8, pch=16, main="",cex.lab=1.5)
#--------------------------------------------------------------------------------
#plot the qdf using plot
invcdf <- stepfun(seq(0.01,.99,length=19), qinf1NBII(seq(0.1,.99,length=20),mu, sigma), f = 0)
plot(invcdf, ylab=expression(x[p]==F^{-1}(p)), do.points=FALSE,verticals=TRUE,
cex.points=.8, pch=16, main="",cex.lab=1.5, xlab="p")
#--------------------------------------------------------------------------------
# generate random sample
Ni <- rinf1NBII(1000, mu=mu, sigma=sigma, nu=nu)
hist(Ni,breaks=seq(min(Ni)-0.5,max(Ni)+0.5,by=1),col="lightgray", main="",cex.lab=2)
barplot(table(Ni))
#--------------------------------------------------------------------------------
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