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= PCA/Eigensoft/Eigenstrat = | = PCA/Eigensoft/Eigenstrat = | ||
<pre> | <pre> | ||
eigenstrat<-function(geno,maxMis=0,minMaf=0.01){ | |||
## geno: snp x ind matrix of genotypes \in 0,1,2 | |||
##maxMis maximum allowed missing genotypes for a site | |||
nMis <- rowSums(is.na(geno)) | |||
freq <- rowMeans(geno,na.rm=T)/2 # get allele frequency | |||
keep <- freq>minMaf&freq<(1-minMaf) & nMis<=maxMis # remove sites with non-polymorphic data | |||
freq<-freq[keep] | |||
geno<-geno[keep,] | |||
snp<-nrow(geno) #number of snps used in analysis | |||
ind<-ncol(geno) #number of individuals used in analuysis | |||
M <- (geno-freq*2)/sqrt(freq*(1-freq)) #normalize the genotype matrix | |||
M[is.na(M)]<-0 | |||
X<-t(M)%*%M #get the (almost) covariance matrix | |||
X<-X/(sum(diag(X))/(snp-1)) | |||
E<-eigen(X) | |||
mu<-(sqrt(snp-1)+sqrt(ind))^2/snp #for testing significance (assuming no LD!) | |||
sigma<-(sqrt(snp-1)+sqrt(ind))/snp*(1/sqrt(snp-1)+1/sqrt(ind))^(1/3) | |||
E$TW<-(E$values[1]*ind/sum(E$values)-mu)/sigma | |||
E$mu<-mu | |||
E$sigma<-sigma | |||
E$nSNP <- nrow(geno) | |||
E$nInd <- ncol(geno) | |||
class(E)<-"eigenstrat" | |||
E | |||
} | |||
plot.eigenstrat<-function(x,col=1,...) | |||
plot(x$vectors[,1:2],col=col,...) | |||
print.eigenstrat<-function(x) | |||
cat("statistic",x$TW,"\n") | |||
</pre> | </pre> | ||
Example | |||
<pre> | <pre> | ||
ind<-c(100,100,100) | |||
snp<-10000 | |||
freq<-cbind(runif(snp),runif(snp),runif(snp)) | |||
l<-lapply(1:length(ind),function(x) matrix(rbinom(snp*ind[x],2,freq[,x]),snp)) | |||
geno<-do.call(cbind,l) | |||
e<-eigenstrat(geno) | |||
plot(e,col=rep(1:length(ind),ind),xlab="PC1",ylab="PC2") | |||
</pre> | </pre> | ||
= Fst = | = Fst = | ||
The same as the faster "fstat" from the geneland package but this script also gives the total variance, variance within individuals, variance within population and variance between populations both on a SNP level and on as a joint estimate. | |||
<pre> | <pre> | ||
WC84<-function(x,pop){ | |||
x<-x[,!apply(is.na(x),2,any)] | |||
popNam<-sort(unique(pop)) | |||
#number ind each population | |||
n<-table(pop) | |||
#number of populations | |||
npop<-nrow(n) | |||
#average sample size of each population | |||
n_avg<-mean(n) | |||
#total number of samples | |||
N<-length(pop) | |||
#frequency in samples | |||
p<-t(sapply(popNam,function(y) colMeans(x[pop==y,])/2)) | |||
# p<-apply(x,2,function(x,pop){tapply(x,pop,mean)/2},pop=pop) | |||
#average frequency in all samples (apply(x,2,mean)/2) | |||
p_avg<-as.vector(n%*%p/N ) | |||
#the sample variance of allele 1 over populations | |||
s2<-1/(npop-1)*(apply(p,1,function(x){((x-p_avg)^2)})%*%n)/n_avg | |||
#average heterozygouts | |||
# h<-apply(x==1,2,function(x,pop)tapply(x,pop,mean),pop=pop) | |||
#average heterozygote frequency for allele 1 | |||
# h_avg<-as.vector(n%*%h/N) | |||
#faster version than above: | |||
h_avg<-apply(x==1,2,sum)/N | |||
#nc (see page 1360 in wier and cockerhamm, 1984) | |||
n_c<-1/(npop-1)*(N-sum(n^2)/N) | |||
#variance betwen populations | |||
a <- n_avg/n_c*(s2-(p_avg*(1-p_avg)-(npop-1)*s2/npop-h_avg/4)/(n_avg-1)) | |||
#variance between individuals within populations | |||
b <- n_avg/(n_avg-1)*(p_avg*(1-p_avg)-(npop-1)*s2/npop-(2*n_avg-1)*h_avg/(4*n_avg)) | |||
#variance within individuals | |||
c <- h_avg/2 | |||
#inbreedning (F_it) | |||
F <- 1-c/(a+b+c) | |||
#(F_st) | |||
theta <- a/(a+b+c) | |||
#(F_is) | |||
f <- 1-c(b+c) | |||
#weigted average of theta | |||
theta_w<-sum(a)/sum(a+b+c) | |||
list(F=F,theta=theta,f=f,theta_w=theta_w,a=a,b=b,c=c,total=c+b+a) | |||
} | |||
</pre> | </pre> | ||
| Line 20: | Line 108: | ||
<pre> | <pre> | ||
#example of use | |||
nsnp=10000 | |||
x<-matrix(rbinom(160*nsnp,2,0.02),160) | |||
pop<-rep(1:4,40) | |||
res<-WC84(x,pop) | |||
res$theta_w | |||
</pre> | </pre> | ||
= LD pruning in R = | = LD pruning in R = | ||
Install R package | |||
<pre> | <pre> | ||
wget http://www.popgen.dk/albrecht/misc_Rpackages/Rpakker/pruning_0.51.tar.gz | |||
R CMD INSTALL pruning_0.51.tar.gz | |||
</pre> | </pre> | ||
Latest revision as of 15:25, 12 March 2015
PCA/Eigensoft/Eigenstrat
eigenstrat<-function(geno,maxMis=0,minMaf=0.01){
## geno: snp x ind matrix of genotypes \in 0,1,2
##maxMis maximum allowed missing genotypes for a site
nMis <- rowSums(is.na(geno))
freq <- rowMeans(geno,na.rm=T)/2 # get allele frequency
keep <- freq>minMaf&freq<(1-minMaf) & nMis<=maxMis # remove sites with non-polymorphic data
freq<-freq[keep]
geno<-geno[keep,]
snp<-nrow(geno) #number of snps used in analysis
ind<-ncol(geno) #number of individuals used in analuysis
M <- (geno-freq*2)/sqrt(freq*(1-freq)) #normalize the genotype matrix
M[is.na(M)]<-0
X<-t(M)%*%M #get the (almost) covariance matrix
X<-X/(sum(diag(X))/(snp-1))
E<-eigen(X)
mu<-(sqrt(snp-1)+sqrt(ind))^2/snp #for testing significance (assuming no LD!)
sigma<-(sqrt(snp-1)+sqrt(ind))/snp*(1/sqrt(snp-1)+1/sqrt(ind))^(1/3)
E$TW<-(E$values[1]*ind/sum(E$values)-mu)/sigma
E$mu<-mu
E$sigma<-sigma
E$nSNP <- nrow(geno)
E$nInd <- ncol(geno)
class(E)<-"eigenstrat"
E
}
plot.eigenstrat<-function(x,col=1,...)
plot(x$vectors[,1:2],col=col,...)
print.eigenstrat<-function(x)
cat("statistic",x$TW,"\n")
Example
ind<-c(100,100,100) snp<-10000 freq<-cbind(runif(snp),runif(snp),runif(snp)) l<-lapply(1:length(ind),function(x) matrix(rbinom(snp*ind[x],2,freq[,x]),snp)) geno<-do.call(cbind,l) e<-eigenstrat(geno) plot(e,col=rep(1:length(ind),ind),xlab="PC1",ylab="PC2")
Fst
The same as the faster "fstat" from the geneland package but this script also gives the total variance, variance within individuals, variance within population and variance between populations both on a SNP level and on as a joint estimate.
WC84<-function(x,pop){
x<-x[,!apply(is.na(x),2,any)]
popNam<-sort(unique(pop))
#number ind each population
n<-table(pop)
#number of populations
npop<-nrow(n)
#average sample size of each population
n_avg<-mean(n)
#total number of samples
N<-length(pop)
#frequency in samples
p<-t(sapply(popNam,function(y) colMeans(x[pop==y,])/2))
# p<-apply(x,2,function(x,pop){tapply(x,pop,mean)/2},pop=pop)
#average frequency in all samples (apply(x,2,mean)/2)
p_avg<-as.vector(n%*%p/N )
#the sample variance of allele 1 over populations
s2<-1/(npop-1)*(apply(p,1,function(x){((x-p_avg)^2)})%*%n)/n_avg
#average heterozygouts
# h<-apply(x==1,2,function(x,pop)tapply(x,pop,mean),pop=pop)
#average heterozygote frequency for allele 1
# h_avg<-as.vector(n%*%h/N)
#faster version than above:
h_avg<-apply(x==1,2,sum)/N
#nc (see page 1360 in wier and cockerhamm, 1984)
n_c<-1/(npop-1)*(N-sum(n^2)/N)
#variance betwen populations
a <- n_avg/n_c*(s2-(p_avg*(1-p_avg)-(npop-1)*s2/npop-h_avg/4)/(n_avg-1))
#variance between individuals within populations
b <- n_avg/(n_avg-1)*(p_avg*(1-p_avg)-(npop-1)*s2/npop-(2*n_avg-1)*h_avg/(4*n_avg))
#variance within individuals
c <- h_avg/2
#inbreedning (F_it)
F <- 1-c/(a+b+c)
#(F_st)
theta <- a/(a+b+c)
#(F_is)
f <- 1-c(b+c)
#weigted average of theta
theta_w<-sum(a)/sum(a+b+c)
list(F=F,theta=theta,f=f,theta_w=theta_w,a=a,b=b,c=c,total=c+b+a)
}
#example of use nsnp=10000 x<-matrix(rbinom(160*nsnp,2,0.02),160) pop<-rep(1:4,40) res<-WC84(x,pop) res$theta_w
LD pruning in R
Install R package
wget http://www.popgen.dk/albrecht/misc_Rpackages/Rpakker/pruning_0.51.tar.gz R CMD INSTALL pruning_0.51.tar.gz