dfilt (Signal Processing Toolbox)

Construct a discrete-time, filter object

Syntax

```
Hd = dfilt.structure(input1,...)
```

Description

Hd = dfilt.structure returns a discrete-time filter object, Hd, of type structure. You must use a structure with dfilt. Each structure takes one or more inputs. If you specify a dfilt.structure with no inputs, a default filter is created.

Structures

Structures for dfilt specify the type of filter structure. Available structures for dfilt are shown below.

dfilt.structure
Description

dfilt.df1
Direct form I

dfilt.df1sos
Direct form I, second-order sections

dfilt.df1t
Direct form I transposed

dfilt.df1tsos
Direct form I transposed, second-order sections

dfilt.df2
Direct form II

dfilt.df2sos
Direct form II, second-order sections

dfilt.df2t
Direct form II transposed

dfilt.df2tsos
Direct form II transposed, second-order sections

dfilt.dffir
Direct form FIR

dfilt.dffirt
Direct form FIR transposed

dfilt.dfsymfir
Direct form symmetric FIR

dfilt.dfasymfir
Direct form antisymmetric FIR

dfilt.latticeallpass
Lattice allpass

dfilt.latticear
Lattice autoregressive (AR)

dfilt.latticearma
Lattice auto-regressive moving- average (ARMA)

dfilt.latticemamax
Lattice moving average (MA) for maximum phase

dfilt.latticemamin
Lattice moving average (MA) for minimum phase

dfilt.calattice
Coupled, allpass lattice (available only with the Filter Design Toolbox)

dfilt.calatticepc
Coupled, allpass lattice with power complementary output (available only with the Filter Design Toolbox)

dfilt.statespace
State-space

dfilt.cascade
dfilt objects arranged in series

dfilt.parallel
dfilt objects arranged in parallel

dfilt.structure	Description
`dfilt.df1`	Direct form I
`dfilt.df1sos`	Direct form I, second-order sections
`dfilt.df1t`	Direct form I transposed
`dfilt.df1tsos`	Direct form I transposed, second-order sections
`dfilt.df2`	Direct form II
`dfilt.df2sos`	Direct form II, second-order sections
`dfilt.df2t`	Direct form II transposed
`dfilt.df2tsos`	Direct form II transposed, second-order sections

`dfilt.dffir`	Direct form FIR
`dfilt.dffirt`	Direct form FIR transposed
`dfilt.dfsymfir`	Direct form symmetric FIR
`dfilt.dfasymfir`	Direct form antisymmetric FIR

`dfilt.latticeallpass`	Lattice allpass
`dfilt.latticear`	Lattice autoregressive (AR)
`dfilt.latticearma`	Lattice auto-regressive moving- average (ARMA)
`dfilt.latticemamax`	Lattice moving average (MA) for maximum phase
`dfilt.latticemamin`	Lattice moving average (MA) for minimum phase

`dfilt.calattice`	Coupled, allpass lattice (available only with the Filter Design Toolbox)
`dfilt.calatticepc`	Coupled, allpass lattice with power complementary output (available only with the Filter Design Toolbox)

`dfilt.statespace`	State-space

`dfilt.cascade`	`dfilt` objects arranged in series
`dfilt.parallel`	`dfilt` objects arranged in parallel

For more information on each structure, refer to its reference page.

Methods

Methods provide ways of performing functions directly on your dfilt object without having to specify the filter parameters again. You can apply these methods directly on the variable you assigned to your dfilt object.

For example, if you create a dfilt object, Hd, you can check whether it has linear phase with islinphase(Hd), view its frequency response plot with fvtool(Hd), or obtain its frequency response values with h=freqz(Hd). You can use all of the methods below in this way.

Some of these methods have the same name as functions in the Signal Processing Toolbox and they behave similarly. This is called overloading of functions.

Method
Description

addsection

Adds a section to a cascade or parallel object. See dfilt.cascade and dfilt.parallel.

cascade

Returns the series combination of two dfilt objects. See dfilt.cascade.

coefficients
Returns the filter coefficients.

filter
Performs filtering using the dfilt object.

convert
Converts a dfilt object from one filter structure to another filter structure.

freqz
Returns the frequency response in fvtool.

grpdelay
Returns the group delay in fvtool.

impz
Returns the impulse response in fvtool.

isallpass
Returns 1 if the dfilt object has allpass filter sections or 0 if it does not.

iscascade
Returns 1 if the dfilt object is cascaded or 0 if it is not.

isfir
Returns 1 if the dfilt object has finite impulse response (FIR) or 0 if it does not.

islinphase
Returns 1 if the dfilt object has linear phase sections or 0 if it does not.

ismaxphase
Returns 1 if the dfilt object has maximum-phase sections or 0 if it does not.

isminphase
Returns 1 if the dfilt object has minimum-phase sections or 0 if it does not.

isparallel
Returns 1 if the dfilt object has parallel sections or 0 if it does not.

isreal
Returns 1 if the dfilt object has real-valued coefficient or 0 if it does not.

isscalar
Returns 1 if the dfilt object is scalar or 0 if it is not scalar.

issos
Returns 1 if the dfilt object has second-order sections or 0 if it does not.

isstable
Returns 1 if all sections of the dfilt object are stable or 0 if they are not.

nstates
Returns the number of states for state-space objects.

order
Returns the filter order. If Hd is a single-section filter, the order is given by the number of delays needed for a minimum realization of the filter. If Hd has multiple sections, the order is given by the the number of delays needed for a minimum realization of the overall filter.

parallel

Returns the parallel combination of two dfilt objects. See dfilt.parallel.

realizemdl

(Available only with the DSP Blockset.)

realizemdl(Hd) creates a Simulink model containing a subsystem block realization of your dfilt object.

realizemdl(Hd,p1,v1,p2,v2,...) creates the block using the properties p1, p2,... and values v1, v2,... specified.

The following properties are available.

'Blockname' specifies the name of the block. The default value is 'Filter'.

'Destination' specifies whether to add the block to a current Simulink model or create a new model. Valid values are 'Current' and 'New'.

'OverwriteBlock' specifies whether to overwrite an existing block or create a new block. Valid values are 'on' and 'off'.

The following properties optimize the block structure. Specifying the value 'on' turns the optimization on and 'off' creates the block without optimization. The default for each block is 'off'.

'OptimizeZeros' removes zero-gain blocks.

'OptimizeOnes' replaces unity-gain blocks with a direct connection.

'OptimizeNegOnes' replaces negative unity-gain blocks with a sign change at the nearest summation block.

'OptimizeDelayChains' replaces cascaded chains of delay block with a single integer delay block set to the appropriate delay.

removesection

Removes a section from a cascade or parallel object. See dfilt.cascade and dfilt.parallel.

setsection
Overwrites a section of a cascade or parallel object. See dfilt.cascade and dfilt.parallel.

sos
Converts the object to a second-order sections object. If Hd has a single section, the returned filter has the same class.

sos(Hd,flag) specifies the ordering of the second-order sections. If flag='UP', the first row contains the poles closest to the origin, and the last row contains the poles closest to the unit circle. If flag='down', the sections are ordered in the opposite direction. The zeros are always paired with the poles closest to them.

sos(Hd,flag,scale) specifies the scaling of the gain and the numerator coefficients of all second-order sections. scale can be 'none', 'inf' (infinity-norm) or 'two' (2-norm). Using infinity-norm scaling with up ordering minimizes the probability of overflow in the realization. Using 2-norm scaling with down ordering minimizes the peak roundoff noise.

ss
Converts the object to state-space. To see the separate A,B,C,D matrices for the state-space model, use [A,B,C,D]=ss(Hd).

stepz
Returns the step response in fvtool.

stepz(Hd,n) computes the first n samples of the step response.

stepz(Hd,n,Fs) separates the time samples by T = 1/Fs, where Fs is assumed to be in Hz.

tf
Converts the object to a transfer function.

zpk
Converts the object to zeros-pole-gain form.

zplane
Returns a pole-zero plot in fvtool.

Method	Description
`addsection`	Adds a section to a cascade or parallel object. See `dfilt.cascade` and `dfilt.parallel`.
`cascade`	Returns the series combination of two `dfilt` objects. See `dfilt.cascade`.
`coefficients`	Returns the filter coefficients.
`filter`	Performs filtering using the `dfilt` object.
`convert`	Converts a `dfilt` object from one filter structure to another filter structure.
`freqz`	Returns the frequency response in `fvtool`.
`grpdelay`	Returns the group delay in `fvtool`.
`impz`	Returns the impulse response in `fvtool`.
`isallpass`	Returns `1` if the `dfilt` object has allpass filter sections or `0` if it does not.
`iscascade`	Returns `1` if the `dfilt` object is cascaded or `0` if it is not.
`isfir`	Returns `1` if the `dfilt` object has finite impulse response (FIR) or `0` if it does not.
`islinphase`	Returns `1` if the `dfilt` object has linear phase sections or `0` if it does not.
`ismaxphase`	Returns `1` if the `dfilt` object has maximum-phase sections or `0` if it does not.
`isminphase`	Returns `1` if the `dfilt` object has minimum-phase sections or `0` if it does not.
`isparallel`	Returns `1` if the `dfilt` object has parallel sections or `0` if it does not.
`isreal`	Returns `1` if the `dfilt` object has real-valued coefficient or 0 if it does not.
`isscalar`	Returns `1` if the `dfilt` object is scalar or `0` if it is not scalar.
`issos`	Returns `1` if the `dfilt` object has second-order sections or `0` if it does not.
`isstable`	Returns `1` if all sections of the `dfilt` object are stable or `0` if they are not.
`nstates`	Returns the number of states for state-space objects.
`order`	Returns the filter order. If `Hd` is a single-section filter, the order is given by the number of delays needed for a minimum realization of the filter. If `Hd` has multiple sections, the order is given by the the number of delays needed for a minimum realization of the overall filter.
parallel	Returns the parallel combination of two `dfilt` objects. See `dfilt.parallel`.
realizemdl	(Available only with the DSP Blockset.) `realizemdl(Hd)` creates a Simulink model containing a subsystem block realization of your `dfilt` object. `realizemdl(Hd,p1,v1,p2,v2,...)` creates the block using the properties `p1`, `p2`,... and values `v1`, `v2`,... specified. The following properties are available. `'Blockname'` specifies the name of the block. The default value is `'Filter'`. `'Destination'` specifies whether to add the block to a current Simulink model or create a new model. Valid values are `'Current'` and `'New'`. `'OverwriteBlock'` specifies whether to overwrite an existing block or create a new block. Valid values are `'on'` and `'off'`. The following properties optimize the block structure. Specifying the value `'on'` turns the optimization on and `'off'` creates the block without optimization. The default for each block is `'off'.` `'OptimizeZeros'` removes zero-gain blocks. `'OptimizeOnes'` replaces unity-gain blocks with a direct connection. `'OptimizeNegOnes'` replaces negative unity-gain blocks with a sign change at the nearest summation block. `'OptimizeDelayChains'` replaces cascaded chains of delay block with a single integer delay block set to the appropriate delay.
`removesection`	Removes a section from a cascade or parallel object. See `dfilt.cascade` and `dfilt.parallel`.
`setsection`	Overwrites a section of a cascade or parallel object. See `dfilt.cascade` and `dfilt.parallel`.
`sos`	Converts the object to a second-order sections object. If `Hd` has a single section, the returned filter has the same class. `sos(Hd,flag)` specifies the ordering of the second-order sections. If `flag='UP'`, the first row contains the poles closest to the origin, and the last row contains the poles closest to the unit circle. If `flag='down'`, the sections are ordered in the opposite direction. The zeros are always paired with the poles closest to them. `sos(Hd,flag,scale)` specifies the scaling of the gain and the numerator coefficients of all second-order sections. `scale` can be `'none'`, `'inf'` (infinity-norm) or `'two'` (2-norm). Using infinity-norm scaling with `up` ordering minimizes the probability of overflow in the realization. Using 2-norm scaling with `down` ordering minimizes the peak roundoff noise.
`ss`	Converts the object to state-space. To see the separate `A,B,C,D` matrices for the state-space model, use `[A,B,C,D]=ss(Hd).`
`stepz`	Returns the step response in `fvtool`. `stepz(Hd,n)` computes the first `n` samples of the step response. `stepz(Hd,n,Fs)` separates the time samples by `T = 1/Fs`, where `Fs` is assumed to be in Hz.
`tf`	Converts the object to a transfer function.
`zpk`	Converts the object to zeros-pole-gain form.
`zplane`	Returns a pole-zero plot in `fvtool`.

Viewing Object Parameters

As with any object, you can use get to view a dfilt object's parameters. To see a specific parameter, use

```
 get(Hd,'parameter') 
```

To see all parameters for an object, use

```
get(Hd)
```

You can also view the names of the parameters that hold the filter coefficients with

```
coefficientnames(Hd)
```

Changing Object Parameters

To set specific parameters, use

set(Hd,'parameter1',value,'parameter2',value,...)

Note that you must use single quotation marks around the parameter name.

Converting Between Filter Structures

To change the filter structure of a dfilt object Hd, use

```
Hd2=convert(Hd,'structure_string');
```

where structure_string is any valid structure name in single quotation marks. If Hd is a cascade or parallel structures, each of its sections is converted to the new structure.

Copying an Object

To create a copy of an object, use the copy method.

```
H2 = copy(Hd)
```

Using the syntax H2 = Hd copies only the object handle and does not create a new object.

Examples

Create a direct form I filter object and use a method to see if it is stable:

[b,a] = butter(8,0.25);
Hd = dfilt.df1(b,a)
 
Hd =
   FilterStructure: 'Direct form I'
   Numerator: [1x9 double]
   Denominator: [1 -3.9838 7.5362 -8.5998 6.4002 -3.1560 1.0017
                -0.1863 0.0155]

isstable(Hd)

ans =
     1

If a dfilt's numerator values do not fit on a single line, a description of the vector is displayed. To see the specific numerator values for this example, use

get(Hd,'numerator')

ans =
    0.0001    0.0009    0.0030    0.0060    0.0076    0.0060
        0.0030    0.0009    0.0001

Refer to the reference pages for each structure for more examples.

demod dfilt.cascade