rarefaction.individual: Rarefied species richness with Hill numbers
In rareNMtests: Ecological and Biogeographical Null Model Tests for Comparing Rarefaction Curves
rarefaction.individual R Documentation
Rarefied species richness with Hill numbers
Description
Individual-based (abundance data), sample-based (incidence data), and coveraged-based (based on both abundance and incidence data) rarefaction with Hill numbers.
Usage
rarefaction.individual(x, method = "sample-size", q = 0, powerfun = 1,
log.scale = FALSE, inds = NULL)
rarefaction.sample(x, method = "sample-size", q = 0)
Arguments
x
Community data, a vector (for individual-based rarefaction) or a matrix-like object (for sample-based rarefaction).
method
Either "sample-size" (default) or "coverage". "sample-size" uses either abundance data (in individual-based rarefaction) or incidence data (in sample-based rarefaction), whereas "coverage" uses the estimated coverage (see Details) of either abundance or number of samples as the x-axis in the sampling curve.
q
First three Hill numbers, namely species richness (q = 0), the exponential Shannon index (q = 1), and the inverse Simpson index (q = 2).
powerfun
By default rarefied richness is estimated for all subsample sizes, from 1 to n, where n is the total number of individuals in the sample. If powerfun is less than 1, it decreases the total number of subsamples as a power function of n.
log.scale
If FALSE (default), subsample sizes for rarefying community are spaced apart at regular intervals. Otherwise (log.scale = TRUE), subsample sizes are spaced apart on a log-scale.
inds
Subsample size for rarefying community, either a single value or a vector. If not specified (default), rarefaction is calculated for all subsample sizes.
Details
Consider a complete assemblage for which all species and their relative abundance are known. In this complete assemblage, there are i=1 to S species and N* total individuals, with Ni individuals of species i. For individual-based (abundance) data, the reference sample consists of n individuals drawn at random from N*, with Sobs species present, each represented by Xi individuals. Individual-based data is represented as a single vector of length Sobs, the elements of which are the observed abundances Xi. For sample-based (incidence) data, the reference sample consists of a set of R standardized sampling units, such as traps, plots, transect lines, etc. Within each of these sampling units, the presence (1) or absence (0) of each species are the required data, even though abundance data may have been collected. Sample-based incidence data can be represented as a single matrix, with i=1 to R rows and j=1 to Sobs columns, and entries Wij=1 or Wij=0 to indicate the presence or absence of species j in sampling unit i.
In the past, rarefaction curves have been estimated by repeated subsampling, but it is no longer necessary. Analytic estimators for individual-based, sample-based, and coverage-based rarefaction on Hill numbers were derived by Chao et al. (2014). In standard rarefaction curves the x-axis is either the abundance (individual-based) or number of samples (sample-based). Additionally, the x-axis can also be the estimated coverage of either abundance or number of samples. Coverage is defined as the proportion of total individuals or samples from the complete assemblage that is represented by the species present in the sample or subset of samples (Chao and Jost 2012).
Functions rarefaction.individual and rarefaction.sample rarefies a series of diversity indices known as Hill numbers (Hill 1973), which can be algebraically transformed into more familiar diversity indices. The order q of the Hill number determines the weighting given to more common species, with species richness defined by q=0. Other Hill numbers are the exponential Shannon index (q=1), and the inverse Simpson index (q=2).
By default, rarefaction is estimated for all subsample sizes, from 1 to n in individual-based rarefaction, or from 1 to R in sample-based rarefaction, where n is the total number of individuals in the sample, and R is the total number of sampling units, respectively. In individual-based rarefaction, computation of Hill numbers for different subsample sizes can be very time consuming when total number of individuals, n, is high (e.g. > 1000) to extremely high (e.g. > 10000). To reduce computation time, one can select a given number of subsample sizes by setting powerfun below 1. This decreases the total number of subsamples as a power function of n. Subsample sizes can be spaced apart at regular intervals if log.scale=FALSE, or at log-intervals if log.scale=TRUE. This allows getting the entire rarefaction curve profile at faster speed. It is not advisable to set the value of powerfun below 0.5, and recommended values are between 0.6 and 0.8.
Value
A data frame with entries for sample-size (this refers either to number of individuals in individual-based rarefaction, or to number of sampling units in sample-based rarefaction) or coverage (in coverage-based rarefaction), and the corresponding Hill number.
Author(s)
Luis Cayuela and Nicholas J. Gotelli
References
Chao, A., Gotelli, N.J., Hsieh, T.C., Sander, E.L., Ma, K.H., Colwell, R.K. & Ellison, A.M. (2014). Rarefaction and extrapolation with Hill numbers: a framework for sampling and estimation in species diversity studies. emphEcological Monographs 84: 45-67.
Chao, A. & Jost, J. (2012). Coverage-based rarefaction and extrapolation: standardizing samples by completeness rather than size. emphEcology 93: 2533-2547.
Hill, M.O. (1973). Diversity and evenness: a unifying notation and its consequences. emphEcology 54: 427-432.
See Also
rarecurve
Examples
## Not run:
## Individual-based and coverage-based rarefaction
# Simulate a community with number of species (sr) and evenness randomly selected
spn <- rlnorm(runif(1, 10, 200))
evenness <- runif(1, log(1.1), log(33))
com <- round(rlnorm(spn, 3, evenness))
# Sample the community (with sample size n = 500 individuals)
sample1 <- sample(paste("sp",1:length(com)), 500, replace=TRUE, prob=com)
sample1 <- table(sample1)
# Get the individual-based and coverage-based rarefaction curves for different Hill numbers
ibr.q0 <- rarefaction.individual(sample1)
ibr.q1 <- rarefaction.individual(sample1, q=1)
ibr.q2 <- rarefaction.individual(sample1, q=2)
ibr.q0.cov <- rarefaction.individual(sample1, method="coverage")
ibr.q1.cov <- rarefaction.individual(sample1, q=1, method="coverage")
ibr.q2.cov <- rarefaction.individual(sample1, q=2, method="coverage")
# Plot the results
par(mfcol=c(1,2))
plot(ibr.q0[,1], ibr.q0[,2], lwd=2, xlab="Number of individuals", ylab="Hill numbers",
type="l", main="Individual-based rarefaction")
lines(ibr.q1[,1], ibr.q1[,2], lwd=2, lty=2)
lines(ibr.q2[,1], ibr.q2[,2], lwd=2, lty=3)
legend("bottomright", lty=c(1,2,3), lwd=2, legend=c("q = 0", "q = 1", "q = 2"), cex=1.2)
plot(ibr.q0.cov[,1], ibr.q0.cov[,2], lwd=2, xlab="Coverage", ylab="Hill numbers",
type="l", main="Coverage-based rarefaction")
lines(ibr.q1.cov[,1], ibr.q1.cov[,2], lwd=2, lty=2)
lines(ibr.q2.cov[,1], ibr.q2.cov[,2], lwd=2, lty=3)
legend("topleft", lty=c(1,2,3), lwd=2, legend=c("q = 0", "q = 1", "q = 2"), cex=1.2)
## Sample-based and coverage-based rarefaction
# Load the data
data(Chiapas)
Chiapas <- subset(Chiapas, Region=="El Triunfo")
str(Chiapas)
# Get sample-based and coverage-based rarefaction curves for different Hill numbers
sbr.q0 <- rarefaction.sample(Chiapas[,-1])
sbr.q1 <- rarefaction.sample(Chiapas[,-1], q=1)
sbr.q2 <- rarefaction.sample(Chiapas[,-1], q=2)
sbr.q0.cov <- rarefaction.sample(Chiapas[,-1], method="coverage")
sbr.q1.cov <- rarefaction.sample(Chiapas[,-1], q=1, method="coverage")
sbr.q2.cov <- rarefaction.sample(Chiapas[,-1], q=2, method="coverage")
# Plot the results
par(mfcol=c(1,2))
plot(sbr.q0[,1], sbr.q0[,2], lwd=2, xlab="Sampling units", ylab="Hill numbers",
type="l", main="Sample-based rarefaction")
lines(sbr.q1[,1], sbr.q1[,2], lwd=2, lty=2)
lines(sbr.q2[,1], sbr.q2[,2], lwd=2, lty=3)
legend("bottomright", lty=c(1,2,3), lwd=2, legend=c("q = 0", "q = 1", "q = 2"), cex=1.2)
plot(sbr.q0.cov[,1], sbr.q0.cov[,2], lwd=2, xlab="Coverage", ylab="Hill numbers",
type="l", main="Coverage-based rarefaction")
lines(sbr.q1.cov[,1], sbr.q1.cov[,2], lwd=2, lty=2)
lines(sbr.q2.cov[,1], sbr.q2.cov[,2], lwd=2, lty=3)
legend("topleft", lty=c(1,2,3), lwd=2, legend=c("q = 0", "q = 1", "q = 2"), cex=1.2)
## End(Not run)
rareNMtests documentation built on June 7, 2022, 5:10 p.m.
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| rarefaction.individual | R Documentation |
Rarefied species richness with Hill numbers
Description
Individual-based (abundance data), sample-based (incidence data), and coveraged-based (based on both abundance and incidence data) rarefaction with Hill numbers.
Usage
rarefaction.individual(x, method = "sample-size", q = 0, powerfun = 1, log.scale = FALSE, inds = NULL) rarefaction.sample(x, method = "sample-size", q = 0)
Arguments
x |
Community data, a vector (for individual-based rarefaction) or a matrix-like object (for sample-based rarefaction). |
method |
Either |
q |
First three Hill numbers, namely species richness ( |
powerfun |
By default rarefied richness is estimated for all subsample sizes, from 1 to n, where n is the total number of individuals in the sample. If |
log.scale |
If |
inds |
Subsample size for rarefying community, either a single value or a vector. If not specified (default), rarefaction is calculated for all subsample sizes. |
Details
Consider a complete assemblage for which all species and their relative abundance are known. In this complete assemblage, there are i=1 to S species and N* total individuals, with Ni individuals of species i. For individual-based (abundance) data, the reference sample consists of n individuals drawn at random from N*, with Sobs species present, each represented by Xi individuals. Individual-based data is represented as a single vector of length Sobs, the elements of which are the observed abundances Xi. For sample-based (incidence) data, the reference sample consists of a set of R standardized sampling units, such as traps, plots, transect lines, etc. Within each of these sampling units, the presence (1) or absence (0) of each species are the required data, even though abundance data may have been collected. Sample-based incidence data can be represented as a single matrix, with i=1 to R rows and j=1 to Sobs columns, and entries Wij=1 or Wij=0 to indicate the presence or absence of species j in sampling unit i.
In the past, rarefaction curves have been estimated by repeated subsampling, but it is no longer necessary. Analytic estimators for individual-based, sample-based, and coverage-based rarefaction on Hill numbers were derived by Chao et al. (2014). In standard rarefaction curves the x-axis is either the abundance (individual-based) or number of samples (sample-based). Additionally, the x-axis can also be the estimated coverage of either abundance or number of samples. Coverage is defined as the proportion of total individuals or samples from the complete assemblage that is represented by the species present in the sample or subset of samples (Chao and Jost 2012).
Functions rarefaction.individual and rarefaction.sample rarefies a series of diversity indices known as Hill numbers (Hill 1973), which can be algebraically transformed into more familiar diversity indices. The order q of the Hill number determines the weighting given to more common species, with species richness defined by q=0. Other Hill numbers are the exponential Shannon index (q=1), and the inverse Simpson index (q=2).
By default, rarefaction is estimated for all subsample sizes, from 1 to n in individual-based rarefaction, or from 1 to R in sample-based rarefaction, where n is the total number of individuals in the sample, and R is the total number of sampling units, respectively. In individual-based rarefaction, computation of Hill numbers for different subsample sizes can be very time consuming when total number of individuals, n, is high (e.g. > 1000) to extremely high (e.g. > 10000). To reduce computation time, one can select a given number of subsample sizes by setting powerfun below 1. This decreases the total number of subsamples as a power function of n. Subsample sizes can be spaced apart at regular intervals if log.scale=FALSE, or at log-intervals if log.scale=TRUE. This allows getting the entire rarefaction curve profile at faster speed. It is not advisable to set the value of powerfun below 0.5, and recommended values are between 0.6 and 0.8.
Value
A data frame with entries for sample-size (this refers either to number of individuals in individual-based rarefaction, or to number of sampling units in sample-based rarefaction) or coverage (in coverage-based rarefaction), and the corresponding Hill number.
Author(s)
Luis Cayuela and Nicholas J. Gotelli
References
Chao, A., Gotelli, N.J., Hsieh, T.C., Sander, E.L., Ma, K.H., Colwell, R.K. & Ellison, A.M. (2014). Rarefaction and extrapolation with Hill numbers: a framework for sampling and estimation in species diversity studies. emphEcological Monographs 84: 45-67.
Chao, A. & Jost, J. (2012). Coverage-based rarefaction and extrapolation: standardizing samples by completeness rather than size. emphEcology 93: 2533-2547.
Hill, M.O. (1973). Diversity and evenness: a unifying notation and its consequences. emphEcology 54: 427-432.
See Also
rarecurve
Examples
## Not run:
## Individual-based and coverage-based rarefaction
# Simulate a community with number of species (sr) and evenness randomly selected
spn <- rlnorm(runif(1, 10, 200))
evenness <- runif(1, log(1.1), log(33))
com <- round(rlnorm(spn, 3, evenness))
# Sample the community (with sample size n = 500 individuals)
sample1 <- sample(paste("sp",1:length(com)), 500, replace=TRUE, prob=com)
sample1 <- table(sample1)
# Get the individual-based and coverage-based rarefaction curves for different Hill numbers
ibr.q0 <- rarefaction.individual(sample1)
ibr.q1 <- rarefaction.individual(sample1, q=1)
ibr.q2 <- rarefaction.individual(sample1, q=2)
ibr.q0.cov <- rarefaction.individual(sample1, method="coverage")
ibr.q1.cov <- rarefaction.individual(sample1, q=1, method="coverage")
ibr.q2.cov <- rarefaction.individual(sample1, q=2, method="coverage")
# Plot the results
par(mfcol=c(1,2))
plot(ibr.q0[,1], ibr.q0[,2], lwd=2, xlab="Number of individuals", ylab="Hill numbers",
type="l", main="Individual-based rarefaction")
lines(ibr.q1[,1], ibr.q1[,2], lwd=2, lty=2)
lines(ibr.q2[,1], ibr.q2[,2], lwd=2, lty=3)
legend("bottomright", lty=c(1,2,3), lwd=2, legend=c("q = 0", "q = 1", "q = 2"), cex=1.2)
plot(ibr.q0.cov[,1], ibr.q0.cov[,2], lwd=2, xlab="Coverage", ylab="Hill numbers",
type="l", main="Coverage-based rarefaction")
lines(ibr.q1.cov[,1], ibr.q1.cov[,2], lwd=2, lty=2)
lines(ibr.q2.cov[,1], ibr.q2.cov[,2], lwd=2, lty=3)
legend("topleft", lty=c(1,2,3), lwd=2, legend=c("q = 0", "q = 1", "q = 2"), cex=1.2)
## Sample-based and coverage-based rarefaction
# Load the data
data(Chiapas)
Chiapas <- subset(Chiapas, Region=="El Triunfo")
str(Chiapas)
# Get sample-based and coverage-based rarefaction curves for different Hill numbers
sbr.q0 <- rarefaction.sample(Chiapas[,-1])
sbr.q1 <- rarefaction.sample(Chiapas[,-1], q=1)
sbr.q2 <- rarefaction.sample(Chiapas[,-1], q=2)
sbr.q0.cov <- rarefaction.sample(Chiapas[,-1], method="coverage")
sbr.q1.cov <- rarefaction.sample(Chiapas[,-1], q=1, method="coverage")
sbr.q2.cov <- rarefaction.sample(Chiapas[,-1], q=2, method="coverage")
# Plot the results
par(mfcol=c(1,2))
plot(sbr.q0[,1], sbr.q0[,2], lwd=2, xlab="Sampling units", ylab="Hill numbers",
type="l", main="Sample-based rarefaction")
lines(sbr.q1[,1], sbr.q1[,2], lwd=2, lty=2)
lines(sbr.q2[,1], sbr.q2[,2], lwd=2, lty=3)
legend("bottomright", lty=c(1,2,3), lwd=2, legend=c("q = 0", "q = 1", "q = 2"), cex=1.2)
plot(sbr.q0.cov[,1], sbr.q0.cov[,2], lwd=2, xlab="Coverage", ylab="Hill numbers",
type="l", main="Coverage-based rarefaction")
lines(sbr.q1.cov[,1], sbr.q1.cov[,2], lwd=2, lty=2)
lines(sbr.q2.cov[,1], sbr.q2.cov[,2], lwd=2, lty=3)
legend("topleft", lty=c(1,2,3), lwd=2, legend=c("q = 0", "q = 1", "q = 2"), cex=1.2)
## End(Not run)
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