Constant K Low Pass Filter Pdf 16
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The primary disadvantage of FIR filters is that they often requirea much higher filter order than IIR filters to achieve a given levelof performance. Correspondingly, the delay of these filters is oftenmuch greater than for an equal performance IIR filter.
The phase delay and groupdelay of linear phase FIR filters are equal and constant over thefrequency band. For an order n linear phase FIRfilter, the group delay is n/2, and the filteredsignal is simply delayed by n/2 time steps (andthe magnitude of its Fourier transform is scaled by the filter's magnituderesponse). This property preserves the wave shape of signals in thepassband; that is, there is no phase distortion.
The functions fir1, fir2, firls, firpm, fircls,and fircls1 all design typeI and II linear phase FIR filters by default. rcosdesign designsonly type I filters. Both firls and firpm designtype III and IV linear phase FIR filters given a 'hilbert' or 'differentiator' flag. cfirpm can design any type of linearphase filter, and nonlinear phase filters as well.
Using a Hamming window greatly reduces the ringing. This improvement is at the expense of transition width (the windowed version takes longer to ramp from passband to stopband) and optimality (the windowed version does not minimize the integrated squared error).
fir1 uses a least-squares approximation to compute filter coefficients and then smooths the impulse response with a window. For an overview of windows and their properties, see Windows. fir1 resembles the IIR filter design functions in that it is formulated to design filters in standard band configurations: lowpass, bandpass, highpass, and bandstop.
create row vector b containingthe coefficients of the order n Hamming-windowedfilter. This is a lowpass, linear phase FIR filter with cutoff frequency Wn. Wn isa number between 0 and 1, where 1 corresponds to the Nyquist frequency,half the sampling frequency. (Unlike other methods, here Wn correspondsto the 6 dB point.) For a highpass filter, simply append 'high' tothe function's parameter list. For a bandpass or bandstop filter,specify Wn as a two-element vector containing thepassband edge frequencies. Append 'stop' for thebandstop configuration.
Kaiser Window Order Estimation. The kaiserord functionestimates the filter order, cutoff frequency, and Kaiser window betaparameter needed to meet a given set of specifications. Given a vectorof frequency band edges and a corresponding vector of magnitudes,as well as maximum allowable ripple, kaiserord returnsappropriate input parameters for the fir1 function.
The fir2 function alsodesigns windowed FIR filters, but with an arbitrarily shaped piecewiselinear frequency response. This is in contrast to fir1, which only designs filters in standardlowpass, highpass, bandpass, and bandstop configurations.
return row vector b containing the n+1 coefficients of the order n FIR filter whose frequency-magnitude characteristics match those given by vectors f and m. f is a vector of frequency points ranging from 0 to 1, where 1 represents the Nyquist frequency. m is a vector containing the specified magnitude response at the points specified in f. (The IIR counterpart of this function is yulewalk, which also designs filters based on arbitrary piecewise linear magnitude responses. See IIR Filter Design for details.)
The firpm function implements the Parks-McClellan algorithm, which uses the Remez exchange algorithm and Chebyshev approximation theory to design filters with optimal fits between the specified and actual frequency responses. The filters are optimal in the sense that they minimize the maximum error between the specified frequency response and the actual frequency response; they are sometimes called minimax filters. Filters designed in this way exhibit an equiripple behavior in their frequency response, and hence are also known as equiripple filters. The Parks-McClellan FIR filter design algorithm is perhaps the most popular and widely used FIR filter design methodology.
The default mode of operation of firls and firpm is to design type I or type II linear phase filters, depending on whether the order you want is even or odd, respectively. A lowpass example with approximate amplitude 1 from 0 to 0.4 Hz, and approximate amplitude 0 from 0.5 to 1.0 Hz is
The filter designed with firpm exhibits equiripplebehavior. Also note that the firls filter has abetter response over most of the passband and stopband, but at theband edges (f = 0.4 and f = 0.5), the responseis further away from the ideal than the firpm filter.This shows that the firpm filter's maximum errorover the passband and stopband is smaller and, in fact, it is thesmallest possible for this band edge configuration and filter length.
Think of frequency bands as lines over short frequency intervals. firpm and firls use this scheme to represent any piecewise linear frequency-response function with any transition bands. firls and firpm design lowpass, highpass, bandpass, and bandstop filters; a bandpass example is
Both firls and firpm allowyou to place more or less emphasis on minimizing the error in certainfrequency bands relative to others. To do this, specify a weight vectorfollowing the frequency and amplitude vectors. An example lowpassequiripple filter with 10 times less ripple in the stopband than thepassband is
When called with a trailing 'h' or 'Hilbert' option, firpm and firls designFIR filters with odd symmetry, that is, type III (for even order)or type IV (for odd order) linear phase filters. An ideal Hilberttransformer has this anti-symmetry property and an amplitude of 1across the entire frequency range. Try the following approximate Hilberttransformers and plot them using FVTool:
The analytic signal corresponding to x isthe complex signal that has x as its real partand the Hilbert transform of x as its imaginarypart. For this FIR method (an alternative to the hilbert function),you must delay x by half the filter order to createthe analytic signal:
This method does not work directly for filters of odd order,which require a noninteger delay. In this case, the hilbert function,described in Hilbert Transform, estimates the analytic signal. Alternatively,use the resample function to delay the signal bya noninteger number of samples.
Differentiation of a signal in the time domain is equivalentto multiplication of the signal's Fourier transform by an imaginaryramp function. That is, to differentiate a signal, pass it througha filter that has a response H(ω) = jω.Approximate the ideal differentiator (with a delay) using firpm or firls witha 'd' or 'differentiator' option:
The Constrained Least Squares (CLS) FIR filter design functionsimplement a technique that enables you to design FIR filters withoutexplicitly defining the transition bands for the magnitude response.The ability to omit the specification of transition bands is usefulin several situations. For example, it may not be clear where a rigidlydefined transition band should appear if noise and signal informationappear together in the same frequency band. Similarly, it may makesense to omit the specification of transition bands if they appearonly to control the results of Gibbs phenomena that appear in thefilter's response. See Selesnick, Lang, and Burrus [2] for discussionof this method.
Instead of defining passbands, stopbands, and transition regions, the CLS method accepts a cutoff frequency (for the highpass, lowpass, bandpass, or bandstop cases), or passband and stopband edges (for multiband cases), for the response you specify. In this way, the CLS method defines transition regions implicitly, rather than explicitly.
The key feature of the CLS method is that it enables you to define upper and lower thresholds that contain the maximum allowable ripple in the magnitude response. Given this constraint, the technique applies the least square error minimization technique over the frequency range of the filter's response, instead of over specific bands. The error minimization includes any areas of discontinuity in the ideal, \"brick wall\" response. An additional benefit is that the technique enables you to specify arbitrarily small peaks resulting from the Gibbs phenomenon.
The most basic of the CLS design functions, fircls1,uses this technique to design lowpass and highpass FIR filters. Asan example, consider designing a filter with order 61 impulse responseand cutoff frequency of 0.3 (normalized). Further, define the upperand lower bounds that constrain the design process as:
fircls uses the same technique to design FIR filters with a specified piecewise constant magnitude response. In this case, you can specify a vector of band edges and a corresponding vector of band amplitudes. In addition, you can specify the maximum amount of ripple for each band.
Weighted CLS filter design lets you design lowpass or highpassFIR filters with relative weighting of the error minimization in eachband. The fircls1 function enables you to specifythe passband and stopband edges for the least squares weighting function,as well as a constant k that specifies the ratioof the stopband to passband weighting.
For example, consider specifications that call for an FIR filterwith impulse response order of 55 and cutoff frequency of 0.3 (normalized).Also assume maximum allowable passband ripple of 0.02 and maximumallowable stopband ripple of 0.004. In addition, add weighting requirements:
The cfirpm filter designfunction provides a tool for designing FIR filters with arbitrarycomplex responses. It differs from the other filter design functionsin how the frequency response of the filter is specified: it acceptsthe name of a function which returns the filter response calculatedover a grid of frequencies. This capability makes cfirpm ahighly versatile and powerful technique for filter design.
The design algorithm optimizes the Chebyshev (or minimax) errorusing an extended Remez-exchange algorithm for an initial estimate.If this exchange method fails to obtain the optimal filter, the algorithmswitches to an ascent-descent algorithm that takes over to finishthe convergence to the optimal solution. 153554b96e
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