# NOT RUN {
library(oce)
Fs <- 1000
t <- seq(0, 0.296, 1/Fs)
x <- cos(2 * pi * t * 200) + rnorm(n=length(t))
X <- ts(x, frequency=Fs)
s <- spectrum(X, spans=c(3,2), main="random + 200 Hz", log='no')
w <- pwelch(X, plot=FALSE)
lines(w$freq, w$spec, col="red")
w2 <- pwelch(X, nfft=75, plot=FALSE)
lines(w2$freq, w2$spec, col='green')
abline(v=200, col="blue", lty="dotted")
cat("Checking spectral levels with Parseval's theorem:\n")
cat("var(x) = ", var(x), "\n")
cat("2 * sum(s$spec) * diff(s$freq[1:2]) = ", 2 * sum(s$spec) * diff(s$freq[1:2]), "\n")
cat("sum(w$spec) * diff(s$freq[1:2]) = ", sum(w$spec) * diff(w$freq[1:2]), "\n")
cat("sum(w2$spec) * diff(s$freq[1:2]) = ", sum(w2$spec) * diff(w2$freq[1:2]), "\n")
## co2
par(mar=c(3,3,2,1), mgp=c(2,0.7,0))
s <- spectrum(co2, plot=FALSE)
plot(log10(s$freq), s$spec * s$freq,
xlab=expression(log[10]*Frequency), ylab="Power*Frequency", type='l')
title("Variance-preserving spectrum")
pw <- pwelch(co2, nfft=256, plot=FALSE)
lines(log10(pw$freq), pw$spec * pw$freq, col='red')
# }
Run the code above in your browser using DataLab