scipy.signal.iirfilter#
- scipy.signal.iirfilter(N, Wn, rp=None, rs=None, btype='band', analog=False, ftype='butter', output='ba', fs=None)[source]#
IIR digital and analog filter design given order and critical points.
Design an Nth-order digital or analog filter and return the filter coefficients.
- Parameters
- Nint
The order of the filter.
- Wnarray_like
A scalar or length-2 sequence giving the critical frequencies.
For digital filters, Wn are in the same units as fs. By default, fs is 2 half-cycles/sample, so these are normalized from 0 to 1, where 1 is the Nyquist frequency. (Wn is thus in half-cycles / sample.)
For analog filters, Wn is an angular frequency (e.g., rad/s).
When Wn is a length-2 sequence,
Wn[0]
must be less thanWn[1]
.- rpfloat, optional
For Chebyshev and elliptic filters, provides the maximum ripple in the passband. (dB)
- rsfloat, optional
For Chebyshev and elliptic filters, provides the minimum attenuation in the stop band. (dB)
- btype{‘bandpass’, ‘lowpass’, ‘highpass’, ‘bandstop’}, optional
The type of filter. Default is ‘bandpass’.
- analogbool, optional
When True, return an analog filter, otherwise a digital filter is returned.
- ftypestr, optional
The type of IIR filter to design:
Butterworth : ‘butter’
Chebyshev I : ‘cheby1’
Chebyshev II : ‘cheby2’
Cauer/elliptic: ‘ellip’
Bessel/Thomson: ‘bessel’
- output{‘ba’, ‘zpk’, ‘sos’}, optional
Filter form of the output:
second-order sections (recommended): ‘sos’
numerator/denominator (default) : ‘ba’
pole-zero : ‘zpk’
In general the second-order sections (‘sos’) form is recommended because inferring the coefficients for the numerator/denominator form (‘ba’) suffers from numerical instabilities. For reasons of backward compatibility the default form is the numerator/denominator form (‘ba’), where the ‘b’ and the ‘a’ in ‘ba’ refer to the commonly used names of the coefficients used.
Note: Using the second-order sections form (‘sos’) is sometimes associated with additional computational costs: for data-intense use cases it is therefore recommended to also investigate the numerator/denominator form (‘ba’).
- fsfloat, optional
The sampling frequency of the digital system.
New in version 1.2.0.
- Returns
- b, andarray, ndarray
Numerator (b) and denominator (a) polynomials of the IIR filter. Only returned if
output='ba'
.- z, p, kndarray, ndarray, float
Zeros, poles, and system gain of the IIR filter transfer function. Only returned if
output='zpk'
.- sosndarray
Second-order sections representation of the IIR filter. Only returned if
output=='sos'
.
See also
Notes
The
'sos'
output parameter was added in 0.16.0.Examples
Generate a 17th-order Chebyshev II analog bandpass filter from 50 Hz to 200 Hz and plot the frequency response:
>>> from scipy import signal >>> import matplotlib.pyplot as plt
>>> b, a = signal.iirfilter(17, [2*np.pi*50, 2*np.pi*200], rs=60, ... btype='band', analog=True, ftype='cheby2') >>> w, h = signal.freqs(b, a, 1000) >>> fig = plt.figure() >>> ax = fig.add_subplot(1, 1, 1) >>> ax.semilogx(w / (2*np.pi), 20 * np.log10(np.maximum(abs(h), 1e-5))) >>> ax.set_title('Chebyshev Type II bandpass frequency response') >>> ax.set_xlabel('Frequency [Hz]') >>> ax.set_ylabel('Amplitude [dB]') >>> ax.axis((10, 1000, -100, 10)) >>> ax.grid(which='both', axis='both') >>> plt.show()
Create a digital filter with the same properties, in a system with sampling rate of 2000 Hz, and plot the frequency response. (Second-order sections implementation is required to ensure stability of a filter of this order):
>>> sos = signal.iirfilter(17, [50, 200], rs=60, btype='band', ... analog=False, ftype='cheby2', fs=2000, ... output='sos') >>> w, h = signal.sosfreqz(sos, 2000, fs=2000) >>> fig = plt.figure() >>> ax = fig.add_subplot(1, 1, 1) >>> ax.semilogx(w, 20 * np.log10(np.maximum(abs(h), 1e-5))) >>> ax.set_title('Chebyshev Type II bandpass frequency response') >>> ax.set_xlabel('Frequency [Hz]') >>> ax.set_ylabel('Amplitude [dB]') >>> ax.axis((10, 1000, -100, 10)) >>> ax.grid(which='both', axis='both') >>> plt.show()