ellip
Create an Elliptic filter.
Syntax
[b,a] = ellip(n,Rp,Rs,Wp)
[b,a] = ellip(n,Rp,Rs,Wp,band)
[b,a] = ellip(n,Rp,Rs,Wp,domain)
[b,a] = ellip(n,Rp,Rs,Wp,band,domain)
Inputs
- n
- The filter order.
- Rp
- The maximum attenuation in decibels in the passband, Wp.
- Rs
- The minimum attenuation in decibels in the stop band.
- Wp
- A scalar specifying the cutoff frequency of a low or high pass filter, or a two element vector specifying the cutoff frequencies of a bandpass or bandstop filter. For a digital filter the values (in Hz) are normalized relative to the Nyquist frequency. For an analog filter the values are in radians/sec.
- band
- The band type of the filter. Omit for low pass or bandpass. Use 'high' for high pass, and 'stop' for bandstop.
- domain
-
- Use 'z' for digital filters (default).
- Use 's' for analog filters.
Outputs
- b
- The numerator polynomial coefficients of the filter.
- a
- The denominator polynomial coefficients of the filter.
Example
Create a third order Elliptic low pass digital filter with a 300 Hz cutoff, a 1000 Hz sampling frequency, and a maximum passband attenuation of 1 dB.
[b,a] = ellip(3,1,20,300/500)
b = [Matrix] 1 x 4
0.33901 0.74185 0.74185 0.33901
a = [Matrix] 1 x 4
1.00000 0.50193 0.70451 -0.04473
Comments
Filters can become unstable for high orders, and more easily so for bandpass or stopband filters.