simCNVdataPois: Simulate Poisson data
In isglobal-brge/CNVassoc: Association analysis of CNVs and imputed SNPs incorporating uncertainty
Description
Usage
Arguments
Details
Value
See Also
Examples
Description
This function simulates intensity for a CNV and a discrete counting trait
response for different scenarios
Usage
1
simCNVdataPois(n, mu.surrog, sd.surrog, w, lambda, cnv.random = FALSE)
Arguments
n
An integer indicating the desired number of individuals to be
simulated
mu.surrog
A vector containing the signal (surrogate variable) means
for every copy number status (latent classes). Its length must be equal to
the number of latent classes
sd.surrog
A vector containing the signal standard deviation for every
copy number status. Its length must be equal to mu.surrog.
w
A vector containing the frequencies for every copy number status.
Its length must be equal to mu.surrog and its components must sum up one.
lambda
A vector containing the means of the response variable for
every copy number status. Its length must be equal to mu.surrog.
cnv.random
A logical value. TRUE means that copy number status is
drawn under a multinomial distribution with proportions indicated by 'w'.
FALSE means that the real simulated frequency is always the same and is
rounded to the most similar integer to the frequencies indicated by 'w'.
Default value is FALSE
Details
This function is useful to calculate the power of association models for
discrete counting trait under different scenarios ,e.g. setting different
degrees of association (risk ratios), considering different degrees of
uncertainty controlled by the distribution of intensity signal data, i.e.
mean mu.surrog, standard deviation sd.surrog and proportion
w, etc.
Value
Data frame with individual simulated data per row and with the following
variables:
resp
Discrete variable with simulated counts (response)
surrog
Signal intensity following a mixture of normals with means,
standard deviations
and proportions specified by mu.surrog, sd.surrog and
w respectively
cnv
True copy number status
See Also
simCNVdataBinary,
simCNVdataCaseCon,
simCNVdataNorm,
simCNVdataWeibull,
cnv,
CNVassoc
Examples
1
2
3
4
5
6
7
8
9
10
11
set.seed(123)
rr<-1.5
maf<-0.3
simData<-simCNVdataPois(n=1000, mu.surrog=c(0,0.5,1), sd.surrog=rep(0.15,3),
w=c((1-maf)^2,2*maf*(1-maf), maf^2), lambda=3*c(1,rr,rr^2),
cnv.random = FALSE)
CNV<-cnv(simData$surrog,mix.method="EMmixt")
getQualityScore(CNV,type="CNVtools")
mod<-CNVassoc(resp~CNV,data=simData,family="poisson",emsteps=10)
CNVtest(mod)
summary(mod)
isglobal-brge/CNVassoc documentation built on May 30, 2019, 9:48 p.m.
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Description Usage Arguments Details Value See Also Examples
Description
This function simulates intensity for a CNV and a discrete counting trait response for different scenarios
Usage
1 | simCNVdataPois(n, mu.surrog, sd.surrog, w, lambda, cnv.random = FALSE)
|
Arguments
n |
An integer indicating the desired number of individuals to be simulated |
mu.surrog |
A vector containing the signal (surrogate variable) means for every copy number status (latent classes). Its length must be equal to the number of latent classes |
sd.surrog |
A vector containing the signal standard deviation for every copy number status. Its length must be equal to mu.surrog. |
w |
A vector containing the frequencies for every copy number status. Its length must be equal to mu.surrog and its components must sum up one. |
lambda |
A vector containing the means of the response variable for every copy number status. Its length must be equal to mu.surrog. |
cnv.random |
A logical value. TRUE means that copy number status is drawn under a multinomial distribution with proportions indicated by 'w'. FALSE means that the real simulated frequency is always the same and is rounded to the most similar integer to the frequencies indicated by 'w'. Default value is FALSE |
Details
This function is useful to calculate the power of association models for
discrete counting trait under different scenarios ,e.g. setting different
degrees of association (risk ratios), considering different degrees of
uncertainty controlled by the distribution of intensity signal data, i.e.
mean mu.surrog, standard deviation sd.surrog and proportion
w, etc.
Value
Data frame with individual simulated data per row and with the following variables:
resp |
Discrete variable with simulated counts (response) |
surrog |
Signal intensity following a mixture of normals with means,
standard deviations
and proportions specified by |
cnv |
True copy number status |
See Also
simCNVdataBinary,
simCNVdataCaseCon,
simCNVdataNorm,
simCNVdataWeibull,
cnv,
CNVassoc
Examples
1 2 3 4 5 6 7 8 9 10 11 | set.seed(123)
rr<-1.5
maf<-0.3
simData<-simCNVdataPois(n=1000, mu.surrog=c(0,0.5,1), sd.surrog=rep(0.15,3),
w=c((1-maf)^2,2*maf*(1-maf), maf^2), lambda=3*c(1,rr,rr^2),
cnv.random = FALSE)
CNV<-cnv(simData$surrog,mix.method="EMmixt")
getQualityScore(CNV,type="CNVtools")
mod<-CNVassoc(resp~CNV,data=simData,family="poisson",emsteps=10)
CNVtest(mod)
summary(mod)
|
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