ellipord: Elliptic Filter Order

Description

Compute elliptic filter order and cutoff for the desired response characteristics.

Usage

ellipord(Wp, Ws, Rp, Rs, plane = c("z", "s"))

Value

A list of class FilterSpecs with the following list elements:

n: filter order
Wc: cutoff frequency
type: filter type, one of "low", "high", "stop", or "pass".
Rp: dB of passband ripple.
Rs: dB of stopband ripple.

Arguments

Wp, Ws: pass-band and stop-band edges. For a low-pass or high-pass filter, Wp and Ws are scalars. For a band-pass or band-rejection filter, both are vectors of length 2. For a low-pass filter, Wp < Ws. For a high-pass filter, Ws > Wp. For a band-pass (Ws[1] < Wp[1] < Wp[2] < Ws[2]) or band-reject (Wp[1] < Ws[1] < Ws[2] < Wp[2]) filter design, Wp gives the edges of the pass band, and Ws gives the edges of the stop band. For digital filters, frequencies are normalized to [0, 1], corresponding to the range [0, fs/2]. In case of an analog filter, all frequencies are specified in radians per second.
Rp: allowable decibels of ripple in the pass band.
Rs: minimum attenuation in the stop band in dB.
plane: "z" for a digital filter or "s" for an analog filter.

Author

Paulo Neis, p_neis@yahoo.com.br,
adapted by Charles Praplan.
Conversion to R by Tom Short,
adapted by Geert van Boxtel, G.J.M.vanBoxtel@gmail.com.

Examples

Run this code

fs <- 10000
spec <- ellipord(1000/(fs/2), 1200/(fs/2), 0.5, 29)
ef <- ellip(spec)
hf <- freqz(ef, fs = fs)
plot(c(0, 1000, 1000, 0, 0), c(0, 0, -0.5, -0.5, 0),
     type = "l", xlab = "Frequency (Hz)", ylab = "Attenuation (dB)",
     col = "red", ylim = c(-35,0), xlim = c(0,2000))
lines(c(5000, 1200, 1200, 5000, 5000), c(-1000, -1000, -29, -29, -1000),
      col = "red")
lines(hf$w, 20*log10(abs(hf$h)))