An infinite impulse response (IIR) filter library for Linux, Mac OSX and Windows which implements Butterworth, RBJ, Chebychev filters and can easily import coefficients generated by Python (scipy).
The filter processes the data sample by sample for realtime processing.
It uses templates to allocate the required memory so that it can run without any malloc / new commands. Memory is allocated at compile time so that there is never the risk of memory leaks.
Add the following include statement to your code:
#include "Iir.h"
The general coding approach is that first the filter is
instantiated specifying its order, then the
parameters are set with the function setup and
then it's ready to be used for sample by sample realtime filtering.
All filters are available as lowpass, highpass, bandpass and bandstop/notch filters. Butterworth / Chebyshev offer also low/high/band-shelves with specified passband gain and 0dB gain in the stopband.
See the header files in \iir or the documentation for the arguments
of the setup commands.
The examples below are for lowpass filters:
- Butterworth --
Butterworth.hStandard filter suitable for most applications. Monotonic response.
const int order = 4; // 4th order (=2 biquads)
Iir::Butterworth::LowPass<order> f;
const float samplingrate = 1000; // Hz
const float cutoff_frequency = 5; // Hz
f.setup (samplingrate, cutoff_frequency);
- Chebyshev Type I --
ChebyshevI.hWith permissible passband ripple in dB.
Iir::ChebyshevI::LowPass<order> f;
const float passband_ripple_in_db = 5;
f.setup (samplingrate,
cutoff_frequency,
passband_ripple_in_dB);
- Chebyshev Type II --
ChebyshevII.hWith worst permissible stopband rejection in dB.
Iir::ChebyshevII::LowPass<order> f;
double stopband_ripple_in_dB = 20;
f.setup (samplingrate,
cutoff_frequency,
stopband_ripple_in_dB);
- RBJ --
RBJ.h2nd order filters with cutoff and Q factor.
Iir::RBJ::LowPass f;
const float cutoff_frequency = 100;
const float Q_factor = 5;
f.setup (samplingrate, cutoff_frequency, Q_factor);
- Designing filters with Python's scipy.signal --
Custom.h
########
# Python
# See "elliptic_design.py" for the complete code.
from scipy import signal
order = 4
sos = signal.ellip(order, 5, 40, 0.2, 'low', output='sos')
print(sos) # copy/paste the coefficients over & replace [] with {}
///////
// C++
// part of "iirdemo.cpp"
const double coeff[][6] = {
{1.665623674062209972e-02,
-3.924801366970616552e-03,
1.665623674062210319e-02,
1.000000000000000000e+00,
-1.715403014004022175e+00,
8.100474793174089472e-01},
{1.000000000000000000e+00,
-1.369778997100624895e+00,
1.000000000000000222e+00,
1.000000000000000000e+00,
-1.605878925999785656e+00,
9.538657786383895054e-01}
};
const int nSOS = sizeof(coeff) / sizeof(coeff[0]); // here: nSOS = 2
Iir::Custom::SOSCascade<nSOS> cust;
cust.setup(coeff);
Samples are processed one by one. In the example below
a sample x is processed with the filter
command and then saved in y. The types of x and y can either be
float or double
(integer is also allowed but is still processed internally as floating point):
y = f.filter(x);
This is then repeated for every incoming sample in a loop or event handler.
Invalid values provided to setup() will throw
an exception. Parameters provided to setup() which
result in coefficients being NAN will also
throw an exception.
If you use cmake as your build system then just add
to your CMakeLists.txt the following lines for the dynamic library:
find_package(iir)
target_link_libraries(... iir::iir)
or for the static one:
find_package(iir)
target_link_libraries(... iir::iir_static)
Link it against the dynamic library
(Unix/Mac: -liir, Windows: iir.lib)
or the static library (Unix/Mac: libiir_static.a,
Windows: libiir_static.lib).
If you have Ubuntu xenial or bionic then install it as a pre-compiled package:
sudo add-apt-repository ppa:berndporr/usbdux
It's available for 32,64 bit PC and 32,64 bit ARM (Raspberry PI etc). The documentation and the example programs are in:
/usr/share/doc/iir1-dev/
The build tool is cmake which generates the make- or project
files for the different platforms. cmake is available for
Linux, Windows and Mac. It also compiles directly on a
Raspberry PI.
Run
cmake .
which generates the Makefile. Then run:
make
sudo make install
which installs it under /usr/local/lib and /usr/local/include.
Both gcc and clang have been tested.
cmake -G "Visual Studio 15 2017 Win64" .
See cmake for the different build-options. Above is for a 64 bit build.
Then start Visual C++ and open the solution. This will create
the DLL and the LIB files. Under Windows it's highly recommended
to use the static library and link it into the application program.
Run unit tests by typing make test or just ctest.
These test if after a delta pulse all filters relax to zero and
that their outputs never become NaN.
The easiest way to learn is from the examples which are in the demo
directory. A delta pulse as a test signal is sent into the different
filters and saved in a file. With the Python script
plot_impulse_fresponse.py you can then plot the frequency responses.
Also the directory containing the unit tests provides examples for every filter type.
A PDF of all classes, methods and in particular setup functions
is in the doc/pdf directory.
Run doxygen to generate the HTML documentation.
These responses have been generated by iirdemo.cpp
in the /demo/ directory and then plotted with plot_impulse_fresponse.py.
This library has been further developed from Vinnie Falco's great original work which can be found here:
https://github.com/vinniefalco/DSPFilters
While the original library processes audio arrays this
library has been adapted to do fast realtime processing sample
by sample. The setup
command won't require the filter order and instead remembers
it from the template argument. The class structure has
been simplified and all functions documented for doxygen.
Instead of having assert() statements this libary throws
exceptions in case a parameter is wrong. Any filter design
requiring optimisation (for example Ellipic filters) has
been removed and instead a function has been added which can import easily
coefficients from scipy.
"High-Order Digital Parametric Equalizer Design"
Sophocles J. Orfanidis
(Journal of the Audio Engineering Society, vol 53. pp 1026-1046)
"Spectral Transformations for digital filters"
A. G. Constantinides, B.Sc.(Eng.) Ph.D.
(Proceedings of the IEEE, vol. 117, pp. 1585-1590, August 1970)
Enjoy!
Bernd Porr -- http://www.berndporr.me.uk