Overview
Cascade of second order filters. High precision implementation
Discussion
This module implements a general purpose second order cascaded filter that is capable of realizing many different filter types. The module performs internal smoothing allowing the filters to be updated without introducing clicks. In all cases, the module implements an underlying second order filter. First order filters are realized by setting some of the second order coefficients to zero.
The behavior of the filter is controlled by the filterType parameter. filterType is an integer in the range from 0 to 14 inclusive. After specifying filterType, set you adjust the filter parameters by setting the fields .gain, .freq, and .Q. Some filter types use only a subset of these parameters and ignore the others.
The following table discusses the various filter types and which variables are active in each case. The .freq variable controls the center frequency of the filter; .gain determines the boost or cut, in dB; .Q determines how sharp the filter is. Low .Q values lead to broad filters. High .Q values lead to narrow filters.
filterType = 0, Simple pass through with unity gain.
filterType = 1, Linear gain [.gain].
filterType = 2, 1st order Butterworth low pass filter [.freq]
filterType = 3, 2nd order Butterworth low pass filter [.freq]
filterType = 4, 1st order Butterworth high pass filter [.freq]
filterType = 5, 2nd order Butterworth high pass filter [.freq]
filterType = 6, 1st order allpass filter [.freq]
filterType = 7, 2nd order allpass filter [.freq, .Q]
filterType = 8, 2nd order low shelf. It allows you to vary the gain of the low frequencies. The high frequencies have a gain of 1.0. [.freq, .gain].
filterType = 9, 2nd order low shelf w/Q. It allows you to vary the gain of the low frequencies. The high frequencies have a gain of 1.0. This module also has an adjustable Q parameter. [.freq, .gain, .Q].
filterType = 10, 2nd order high shelf. It allows you to vary the gain of the high frequencies. The low frequencies have a gain of 1.0. [.freq, .gain].
filterType = 11, 2nd order high shelf w/Q. It allows you to vary the gain of the high frequencies. The low frequencies have a gain of 1.0. This module also has an adjustable Q parameter. [.freq, .gain, .Q].
filterType = 12, 2nd order peaking filter. It has unity gain except around the specified frequency. By varying .gain, you can get a peak or a notch in the frequency band. [.freq, .gain, .Q].
filterType = 13, 2nd order notch filter. It has unity gain except around the specified frequency. At the specified frequency, the filter has a true notch with -inf dB gain. [.freq, .Q].
filterType = 14, 2nd order bandpass filter. It has unity gain at the specified frequency and falls off in both directions. The bandwidth of the filter is determined by Q. [.freq, .Q]
filterType = 15, 1st order Bessel low pass filter [.freq]
filterType = 16, 1st order Bessel low pass filter [.freq]
filterType = 17, 1st order asymmetrical low shelf [.freq, .gain]
filterType = 18, 1st order asymmetrical high shelf [.freq, .gain]
filterType = 19, 1st order symmetrical low shelf [.freq, .gain]
filterType=20, 1st order symmetrical high shelf. [freq, gain].
filterType=21, 2nd order Butterworth low pass filter with variable Q. [freq, Q].
filterType=22, 2nd order Butterworth high pass filter with variable Q. [freq, Q].
Type Definition
typedef struct _ModuleSOFCascadeHPFract32 { ModuleInstanceDescriptor instance; // Common Audio Weaver module instance structure INT32 numStages; // Number of cascaded stages of the second order filter. FLOAT32 smoothingTime; // Time constant of the smoothing process INT32 updateActive; // Specifies whether the filter coefficients are updating (=1) or fixed (=0) fract32 smoothingCoeff; // Smoothing coefficient. This is computed based on the smoothingTime, sample rate, and block size of the module INT32 bShift; // Number of bits to shift of Numerator coefficients INT32 aShift; // Number of bits to shift of Denominator coefficients INT32* filterType; // Selects the type of filter that is implemented by the module: Bypass=0, Gain=1, Butter1stLPF=2, Butter2ndLPF=3, Butter1stHPF=4, Butter2ndHPF=5, Allpass1st=6, Allpass2nd=7, Shelf2ndLow=8, Shelf2ndLowQ=9, Shelf2ndHigh=10, Shelf2ndHighQ=11, PeakEQ=12, Notch=13, Bandpass=14, Bessel1stLPF=15, Bessel1stHPF=16, AsymShelf1stLow=17, AsymShelf1stHigh=18, SymShelf1stLow=19, SymShelf1stHigh=20, VariableQLPF=21, VariableQHPF=22. FLOAT32* freq; // Cutoff frequency of the filter, in Hz. FLOAT32* gain; // Amount of boost or cut to apply, in dB if applicable. FLOAT32* Q; // Specifies the Q of the filter, if applicable. fract32* targetCoeffs; // Target coefficients in Fract32 fract32* currentCoeffs; // Instantaneous coefficients in Fract32 fract32* state; // State variables. 6 per channel. } ModuleSOFCascadeHPFract32Class;
Variables
Properties
Name | Type | Usage | isHidden | Default value | Range | Units |
numStages | int | const | 0 | 1 | 1:1:32 | |
smoothingTime | float | parameter | 0 | 0 | 0:1:1000 | msec |
updateActive | int | parameter | 1 | 1 | 0:1 | |
smoothingCoeff | fract32 | derived | 1 | 1 | Unrestricted | |
bShift | int | parameter | 1 | 1 | Unrestricted | |
aShift | int | parameter | 1 | 1 | Unrestricted | |
filterType | int* | parameter | 0 | [1 x 1] | 0:22 | |
freq | float* | parameter | 0 | [1 x 1] | 10:0.1:20000 | Hz |
gain | float* | parameter | 0 | [1 x 1] | -24:0.1:24 | dB |
Q | float* | parameter | 0 | [1 x 1] | 0:0.1:20 | |
targetCoeffs | fract32* | derived | 0 | [5 x 1] | Unrestricted | |
currentCoeffs | fract32* | state | 0 | [5 x 1] | Unrestricted | |
state | fract32* | state | 1 | [6 x 1] | Unrestricted |
Pins
Input Pins
Name: in
Description: audio input
Data type: fract32
Channel range: Unrestricted
Block size range: Unrestricted
Sample rate range: Unrestricted
Complex support: Real
Output Pins
Name: out
Description: audio output
Data type: fract32
MATLAB Usage
File Name: second_order_filter_cascadeHP_fract32_module.m
M=second_order_filter_cascadeHP_fract32_module(NAME, NUMSTAGES) Creates a general purpose second order cascade filter that implements a number of High Precision filter types. The filter operates on multiple interleaved channels, with all channels being processed by the same set of coefficients. Arguments: NAME - name of the module. NUMSTAGES - number of second order filter stages. The module has the following variables that control the design: filterType - integer specifying the type of the design (details below). freq - frequency argument (in Hz) Q - the sharpness or Q of the filter (dimensionless) gain - cut or boost, in dB. The argument filterType determines what design routine is run, and not all input arguments are used in all cases: 0 = Pass through mode (gain = 1) 1 = Scaler with level gain 2 = 1st order Butterworth LPF. [freq]. 3 = 2nd order Butterworth LPF. [freq]. 4 = 1st order Butterworth HPF. [freq]. 5 = 2nd order Butterworth HPF. [freq]. 6 = 1st order Allpass. [freq]. 7 = 2nd order Allpass. [freq, Q]. 8 = 2nd order low shelf [freq, gain]. 9 = 2nd order low shelf [freq, gain, Q]. 10 = 2nd order high shelf [freq, gain]. 11 = 2nd order high shelf [freq, gain, Q]. 12 = 2nd order Peak EQ [freq, gain, Q]. 13 = 2nd order Notch [freq, Q]. 14 = 2nd order bandpass [freq, Q]. 15 = 1st order Bessel LPF [freq] 16 = 1st order Bessel HPF [freq] 17 = 1st order asymmetrical low shelf [freq, gain] 18 = 1st order asymmetrical high shelf [freq, gain] 19 = 1st order symmetrical low shelf [freq, gain] 20 = 1st order symmetrical high shelf [freq, gain]