R/SpecInciChao2bc.R
In JohnsonHsieh/ChaoSpecies: Statistical package 'ChaoSpecies'
SpecInciChao2bc <-
function(data, k, conf){
data <- as.numeric(data)
z <- -qnorm((1 - conf)/2)
t <- data[1]
dat <- data[-1]
x <- dat[which(dat != 0)]
Q <- function(i, data){length(data[which(data == i)])}
basicInci <- function(data, k){
data <- as.numeric(data)
t <- data[1]
dat <- data[-1]
x <- dat[which(dat != 0)]
Q <- function(i, data){length(data[which(data == i)])}
D <- length(x)
D_infreq <- length(x[which(x <= k)])
if (Q(1, x) > 0 & Q(2, x) > 0){
A <- 2*Q(2, x)/((t-1)*Q(1, x) + 2*Q(2, x))
} else if (Q(1, x) > 0 & Q(2, x) == 0){
A <- 2/((t-1)*(Q(1, x) - 1) + 2)
} else {
A <- 1
}
C_infreq <- 1 - Q(1, x)/sum(x[which(x <= k)])*(1-A)
j <- c(1:k)
b1 <- sum(sapply(j, function(j)j*(j-1)*Q(j, x)))
b2 <- sum(sapply(j, function(j)j*Q(j, x)))
gamma_infreq_square <- max(D_infreq/C_infreq*t/(t - 1)*b1/b2/(b2) - 1, 0)
CV_infreq <- sqrt(gamma_infreq_square)
D_freq <- length(x[which(x > k)])
BASIC.DATA <- matrix(paste(c("D", "t", "k", "D_infreq", "C_infreq", "CV_infreq", "D_freq"),
c(D,t,k,D_infreq,C_infreq,CV_infreq,D_freq),
sep = "="), ncol=1)
colnames(BASIC.DATA)=c("Value")
rownames(BASIC.DATA)=c("Number of observed species","Number of sample/quadrats","Cut-off point",
"Number of observed species for infrequent species","Estimated sample coverage for infrequent species",
"Estimated CV for infrequent species",
"Number of observed species for frequent species")
return(list(BASIC.DATA, D, t, D_infreq, C_infreq, CV_infreq, D_freq))
}
D <- basicInci(data, k)[[2]]
D_infreq <- basicInci(data, k)[[4]]
C_infreq <- basicInci(data, k)[[5]]
CV_infreq <- basicInci(data, k)[[6]]
D_freq <- basicInci(data, k)[[7]]
S_Chao2_bc <- D + (t - 1)/t*Q(1, x)*(Q(1, x) - 1)/(2*(Q(2, x) + 1))
var_Chao2_bc <- (t - 1)/t*Q(1, x)*(Q(1, x) - 1)/2/(Q(2, x) + 1) + ((t - 1)/t)^2*Q(1, x)*(2*Q(1, x) - 1)^2/4/(Q(2, x) + 1)^2 + ((t - 1)/t)^2*Q(1, x)^2*Q(2, x)*(Q(1, x) - 1)^2/4/(Q(2, x) + 1)^4
tt <- S_Chao2_bc - D
if (tt != 0){
K <- exp(z*sqrt(log(1 + var_Chao2_bc/tt^2)))
CI_Chao2_bc <- c(D + tt/K, D + tt*K)
} else {
i <- c(1:max(x))
i <- i[unique(x)]
var_obs <- sum(sapply(i, function(i)Q(i, x)*(exp(-i) - exp(-2*i)))) -
(sum(sapply(i, function(i)i*exp(-i)*Q(i, x))))^2/t
var_Chao2_bc <- var_obs
P <- sum(sapply(i, function(i)Q(i, x)*exp(-i)/D))
CI_Chao2_bc <- c(max(D, D/(1 - P) - z*sqrt(var_obs)/(1 - P)), D/(1 - P) + z*sqrt(var_obs)/(1 - P))
}
table <- matrix(c(S_Chao2_bc, sqrt(var_Chao2_bc), CI_Chao2_bc), ncol = 4)
colnames(table) <- c("Estimate", "Est_s.e.", paste(conf*100,"% Lower Bound"), paste(conf*100,"% Upper Bound"))
rownames(table) <- "Chao2-bc"
return(table)
}
JohnsonHsieh/ChaoSpecies documentation built on May 7, 2019, 12:02 p.m.
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SpecInciChao2bc <-
function(data, k, conf){
data <- as.numeric(data)
z <- -qnorm((1 - conf)/2)
t <- data[1]
dat <- data[-1]
x <- dat[which(dat != 0)]
Q <- function(i, data){length(data[which(data == i)])}
basicInci <- function(data, k){
data <- as.numeric(data)
t <- data[1]
dat <- data[-1]
x <- dat[which(dat != 0)]
Q <- function(i, data){length(data[which(data == i)])}
D <- length(x)
D_infreq <- length(x[which(x <= k)])
if (Q(1, x) > 0 & Q(2, x) > 0){
A <- 2*Q(2, x)/((t-1)*Q(1, x) + 2*Q(2, x))
} else if (Q(1, x) > 0 & Q(2, x) == 0){
A <- 2/((t-1)*(Q(1, x) - 1) + 2)
} else {
A <- 1
}
C_infreq <- 1 - Q(1, x)/sum(x[which(x <= k)])*(1-A)
j <- c(1:k)
b1 <- sum(sapply(j, function(j)j*(j-1)*Q(j, x)))
b2 <- sum(sapply(j, function(j)j*Q(j, x)))
gamma_infreq_square <- max(D_infreq/C_infreq*t/(t - 1)*b1/b2/(b2) - 1, 0)
CV_infreq <- sqrt(gamma_infreq_square)
D_freq <- length(x[which(x > k)])
BASIC.DATA <- matrix(paste(c("D", "t", "k", "D_infreq", "C_infreq", "CV_infreq", "D_freq"),
c(D,t,k,D_infreq,C_infreq,CV_infreq,D_freq),
sep = "="), ncol=1)
colnames(BASIC.DATA)=c("Value")
rownames(BASIC.DATA)=c("Number of observed species","Number of sample/quadrats","Cut-off point",
"Number of observed species for infrequent species","Estimated sample coverage for infrequent species",
"Estimated CV for infrequent species",
"Number of observed species for frequent species")
return(list(BASIC.DATA, D, t, D_infreq, C_infreq, CV_infreq, D_freq))
}
D <- basicInci(data, k)[[2]]
D_infreq <- basicInci(data, k)[[4]]
C_infreq <- basicInci(data, k)[[5]]
CV_infreq <- basicInci(data, k)[[6]]
D_freq <- basicInci(data, k)[[7]]
S_Chao2_bc <- D + (t - 1)/t*Q(1, x)*(Q(1, x) - 1)/(2*(Q(2, x) + 1))
var_Chao2_bc <- (t - 1)/t*Q(1, x)*(Q(1, x) - 1)/2/(Q(2, x) + 1) + ((t - 1)/t)^2*Q(1, x)*(2*Q(1, x) - 1)^2/4/(Q(2, x) + 1)^2 + ((t - 1)/t)^2*Q(1, x)^2*Q(2, x)*(Q(1, x) - 1)^2/4/(Q(2, x) + 1)^4
tt <- S_Chao2_bc - D
if (tt != 0){
K <- exp(z*sqrt(log(1 + var_Chao2_bc/tt^2)))
CI_Chao2_bc <- c(D + tt/K, D + tt*K)
} else {
i <- c(1:max(x))
i <- i[unique(x)]
var_obs <- sum(sapply(i, function(i)Q(i, x)*(exp(-i) - exp(-2*i)))) -
(sum(sapply(i, function(i)i*exp(-i)*Q(i, x))))^2/t
var_Chao2_bc <- var_obs
P <- sum(sapply(i, function(i)Q(i, x)*exp(-i)/D))
CI_Chao2_bc <- c(max(D, D/(1 - P) - z*sqrt(var_obs)/(1 - P)), D/(1 - P) + z*sqrt(var_obs)/(1 - P))
}
table <- matrix(c(S_Chao2_bc, sqrt(var_Chao2_bc), CI_Chao2_bc), ncol = 4)
colnames(table) <- c("Estimate", "Est_s.e.", paste(conf*100,"% Lower Bound"), paste(conf*100,"% Upper Bound"))
rownames(table) <- "Chao2-bc"
return(table)
}
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