fdesign.isinchp
Inverse sinc highpass filter specification
Syntax
D = fdesign.isinchp
D = fdesign.isinchp(SPEC)
D = fdesign.isinchp(SPEC,specvalue1,specvalue2,...)
D = fdesign.isinchp(specvalue1,specvalue2,specvalue3,specvalue4)
D = fdesign.isinchp(...,Fs)
D = fdesign.isinchp(...,MAGUNITS)
Description
D = fdesign.isinchp constructs
an inverse sinc highpass filter specification object D,
applying default values for the default specification 'Fst,Fp,Ast,Ap'.
D = fdesign.isinchp(SPEC) constructs
object D and sets the Specification property
to SPEC. Entries in the SPEC represent
various filter response features, such as the filter order, that govern
the filter design. Valid entries for SPEC are shown
below. The entries are not case sensitive.
'Fst,Fp,Ast,Ap'(defaultspec)'N,Fc,Ast,Ap''N,Fst,Fp''N,Fp,Ast,Ap''N,Fst,Ast,Ap'
The filter specifications are defined as follows:
Ast— attenuation in the stopband in decibels (the default units). Also called Astop.Ap— amount of ripple allowed in the passband in decibels (the default units). Also called Apass.Fp— frequency at the start of the passband. Specified in normalized frequency units. Also called Fpass.Fst— frequency at the end of the stopband. Specified in normalized frequency units. Also called Fstop.N— filter order.
The filter design methods that apply to an inverse sinc highpass
filter specification object change depending on the value of the Specification property.
Use designmethods to determine
which design method applies to a specific Specification.
Use designopts to see the
available design options for a specific design method. Enter help(D,METHOD) at
the MATLAB® command line to obtain detailed information on the
design options for a given design method, METHOD.
D = fdesign.isinchp(SPEC,specvalue1,specvalue2,...) constructs
an object D and sets the specifications at construction
time.
D = fdesign.isinchp(specvalue1,specvalue2,specvalue3,specvalue4) constructs
an object D assuming the default Specification property 'Fst,Fp,Ast,Ap',
using the values you provide in specvalue1,specvalue2, specvalue3,
and specvalue4.
D = fdesign.isinchp(...,Fs) adds
the argument Fs, specified in Hz to define the
sampling frequency to use. In this case, all frequencies in the specifications
are in Hz as well.
D = fdesign.isinchp(...,MAGUNITS)
specifies the units for any magnitude specification you provide in
the input arguments. MAGUNITS can be one of
'linear'— specify the magnitude in linear units'dB'— specify the magnitude in dB (decibels)'squared'— specify the magnitude in power units
When you omit the MAGUNITS argument, fdesign assumes
that all magnitudes are in decibels. Note that fdesign stores
all magnitude specifications in decibels (converting to decibels when
necessary) regardless of how you specify the magnitudes.
The design method of fdesign.isinchp implements
a filter with a passband magnitude response equal to:
You can control the values of the sinc frequency
factor, C, and the sinc power, P,
using the 'SincFrequencyFactor' and 'SincPower' options
in the design method. 'SincFrequencyFactor' and 'SincPower' default
to 0.5 and 1 respectively.
Examples
Construct an Inverse Sinc Highpass Filter Using fdesign Object
Design a minimum order inverse sinc highpass filter and shape the stopband to have a slope of 20 dB/radian/sample.
d = fdesign.isinchp('Fst,Fp,Ast,Ap',.4,.5,40,0.01); Hd = design(d,'SystemObject',true);
Shape the stopband to have a linear slope of 20 dB/rad/sample
Hd1 = design(d,'StopbandShape','linear','StopbandDecay',20,'SystemObject',... true); fvtool(Hd,Hd1);
Design a 50th order inverse sinc highpass filter. Set the sinc frequency factor to 0.25, and the sinc power to 16 to achieve a magnitude response in the passband of the form H(?) = sinc(0.25*(1-?))^(-16) .
d = fdesign.isinchp('N,Fst,Fp',50,.4,.5); Hd = design(d,'SincFrequencyFactor',0.25,'SincPower',16,... 'SystemObject',true); fvtool(Hd);
See Also
design | designmethods | fdesign | fdesign.ciccomp | fdesign.highpass | fdesign.isinclp | fdesign.nyquist