dsp.ParametricEQFilter

(Removed) Tunable second-order parametric equalizer filter

The dsp.ParametricEQFilter object has been removed. Use the designParamEQ function or the MultibandParametricEQ object from Audio Toolbox™ instead. For more information, see Compatibility Considerations.

Description

The dsp.ParametricEQFilter object is a tunable, second-order parametric equalizer filter.

To apply the filter to each channel of the input:

Define and set up your equalizer filter. See Construction.
Call step to filter each channel according to the properties of dsp.ParametricEQFilter. The behavior of step is specific to each object in the toolbox.

Note

Starting in R2016b, instead of using the step method to perform the operation defined by the System object™, you can call the object with arguments, as if it were a function. For example, y = step(obj,x) and y = obj(x) perform equivalent operations.

Construction

H = dsp.ParametricEQFilter returns a second-order parametric equalizer filter that independently filters each channel of the input over time, using the default values for Bandwidth, CenterFrequency, and PeakGaindB. The center frequency and bandwidth are specified in Hz and are tunable. The peak gain (dip) is specified in dB and is also tunable. The bandwidth is measured at the arithmetic mean between the peak gain in absolute power units and one.

H = dsp.ParametricEQFilter('Specification', 'Quality factor and center frequency') specifies the quality factor (Q factor) of the filter. The Q factor is defined as the center frequency/bandwidth. A higher Q factor corresponds to a narrower peak/dip. The Q factor should be a scalar value greater than 0. The Q factor is tunable.

H = dsp.ParametricEQFilter('Specification', 'Coefficients') specifies the gain values for the bandwidth and center frequency. This removes the trigonometry calculations involved when the properties are tuned. The CenterFrequencyCoefficient should be a scalar between -1 and 1, with -1 corresponding to 0 Hz, and 1 corresponding to the Nyquist frequency. The BandwidthCoefficient should be a scalar between -1 and 1, with -1 corresponding to the largest bandwidth, and 1 corresponding to the smallest bandwidth. In this mode, the peak gain is specified in linear units rather than dB.

H = dsp.ParametricEQFilter('Name', Value, ...) returns a parametric equalizer filter with each specified property name set to the specified value. You can specify several name-value pair arguments in any order as ('Name1',Value1,...,'NameN',ValueN).

Properties

Specification

Design parameters or coefficients that specify the filter

Choose one of the following Specification values. Use the corresponding tunable properties to specify the filter:

Bandwidth and center frequency — Use Bandwidth, CenterFrequency, and PeakGaindB.
Quality factor and center frequency — Use QualityFactor, CenterFrequency, and PeakGaindB.
Coefficients — Use BandwidthCoefficient, CenterFrequencyCoefficient, and PeakGain.

The default value is Bandwidth and center frequency.

Using Coefficients specifies gain values for the bandwidth and center frequency. This approach does not require the trigonometric calculations of the other two approaches where design parameters are specified in Hz.

Bandwidth

bandwidth of filter

Specify the bandwidth of the filter as a finite positive numeric scalar that is less than half the sample rate of the input signal, in Hz. This property is applicable if Specification is set to Bandwidth and center frequency. The default is 2205 Hz. This property is tunable.

BandwidthCoefficient

Coefficient for bandwidth of filter

Specify the value that determines the filter's bandwidth as a finite numeric scalar in the range [-1 1]:

-1 corresponds to the maximum bandwidth (SampleRate/4).
1 corresponds to the minimum bandwidth (0 Hz, that is, an allpass filter).

This property is only applicable if Specification is set to Coefficients. The default is 0.72654. This property is tunable.

CenterFrequency

Center frequency of the filter

Specify the filter's center frequency as a finite positive numeric scalar that is less than half the sample rate of the input signal, in Hz. This property is only applicable if Specification is set to Bandwidth and center frequency or Quality factor and center frequency. The default is 11025 Hz. This property is tunable.

CenterFrequencyCoefficient

Coefficient for center frequency of filter

Specify the value that determines the filter's center frequency as a finite numeric scalar between -1 and 1:

-1 corresponds to the minimum center frequency (0 Hz).
1 corresponds to the maximum center frequency (SampleRate/2 Hz).

This property is only applicable if Specification is set to Coefficients. The default is 0, which corresponds to SampleRate/4 Hz.

This property is tunable.

PeakGain

Peak or dip gain of the filter in linear units

Specify the filter’s peak or dip gain in linear units. A value greater than one boosts the signal. A value less than one attenuates the signal. The default is 2 (6.0206 dB). This property is tunable.

PeakGaindB

Peak or dip gain of the filter in dB

Specify the filter’s peak or dip gain in dB. A positive value boosts the signal. A negative value attenuates the signal. The default is 6.0206 dB. This property is tunable.

QualityFactor

Quality factor of the parametric EQ filter

Specify the Quality factor (Q factor) of the filter. The Q factor is defined as the center frequency divided by the bandwidth. A higher Q factor corresponds to a narrower peak or dip. This property is only applicable if Specification is set to Quality factor and center frequency. The default value is 5. This property is tunable.

SampleRate

Input sample rate

Specify the sample rate of the input as a finite numeric scalar, in Hz. The default is 44100 Hz.

Methods

getBandwidth	Convert quality factor or bandwidth coefficient to bandwidth in Hz
getCenterFrequency	Convert center frequency coefficient to frequency in Hz
getOctaveBandwidth	Measure bandwidth of parametric equalizer filter in octaves
getPeakGain	Convert peak or notch gain from dB to absolute units
getPeakGaindB	Convert peak or notch gain from absolute units to dB
getQualityFactor	Convert bandwidth to quality factor
reset	Reset states of `ParametricEQFilter` object
step	Filter input with `ParametricEQFilter` object
tf	Compute transfer function

Common to All System Objects
`release`	Allow System object property value changes

Examples

collapse all

Tune Equalizer Filter

Create a ParametricEQFilter object where the center frequency and bandwidth of the equalizer filter are 5000 Hz and 500 Hz respectively. The sample rate for the filter is the default, 44,100 Hz.

h = dsp.ParametricEQFilter('CenterFrequency',5000,...
       'Bandwidth',500);

Create objects to estimate and display the transfer function of the filter.

htf = dsp.TransferFunctionEstimator('FrequencyRange','onesided',...
         'SpectralAverages',50);
hplot = dsp.ArrayPlot('PlotType','Line','YLimits',[-15 15],...
       'SampleIncrement',44100/1024);

Generate a random signal and filter the signal.

for i=1:1000
   x = randn(1024,1);       % Random signal
   y = h(x);           % Filter signal
   H = htf(x,y);       % Estimate transfer function
   magdB = 20*log10(abs(H));% Convert to dB
   hplot(magdB);       % Display transfer function
    
   if (i==1)                % Pause to display initial transfer function
      pause;  
   end
   if (i==500)              % Tune filter
      h.CenterFrequency = 10000;
      h.Bandwidth = 2000;
      h.PeakGaindB = -10;
   end
 end

The software displays the initial transfer function estimate.

To continue, press any key.

At i=500, the filter is tuned. The center frequency, bandwidth, and peak gain of the filter now have different values. The software displays the new transfer function.

Algorithm

The parametric equalizer is formed by a linear combination of a peak and a notch filter. See the Algorithm section of dsp.NotchPeakFilter for details.

$H (z) = H_{n o t c h} (z) + G H_{p e a k} (z)$

Here is a graph of the two cases (boost and cut) of the magnitude squared of the transfer functions:

The transfer function can be written as:

$\begin{array}{l} H (z) = \frac{(\frac{1 + G γ}{1 + γ}) - 2 (\frac{\cos ω_{0}}{1 + γ}) z^{- 1} + (\frac{1 - G γ}{1 + γ}) z^{- 2}}{1 - 2 (\frac{\cos ω_{0}}{1 + γ}) z^{- 1} + (\frac{1 - γ}{1 + γ}) z^{- 2}} \\ w h e r e \\ γ = \tan (\frac{Δ ω}{2}) \\ a n d \\ G_{B}^{2} = \frac{1 + G^{2}}{2} \end{array}$

G is the parametric equalizer gain, and G_B is the bandwidth gain, that is, the gain level at which the bandwidth Δω is measured.

The dsp.NotchPeakFilter that does most of the work is implemented in a decoupled way so that the center frequency can be tuned independently from the bandwidth. Note that the Q factor is defined as center frequency/bandwidth.

References

[1] Orfanidis, Sophocles J. Introduction to Signal Processing Upper Saddle River, NJ: Prentice-Hall, 1996

Compatibility Considerations

expand all