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All of the discussion to this point has focused on lowpass filters. Practical applications require other types, of course, including highpass,bandpass, and bandstop designs. In fact the analysis presented in the previous sections applies to all of these design criteria and the rulesfor filter length estimation can be used almost directly. In general Equation 1 and Equation 2 from the module titled "Filter Sizing" apply when one of the equal ripple specifications dominates all others and when one of thetransition band specifications dominates all others. As a practical matter this means that δ i dominates if it is less than one-tenth of all other rippple specifications and that Δ f i dominates if it is simply less than all others. Suppose we define δ and Δ f by the equations:

δ = m i n { δ i } , for all pass and stopbands i, and Δ f = m i n { Δf k } for all transition bands k

δ = min { δ i } , for all pass and stopbands i, and
Δ f = min { Δ f k } for all transition bands k

If so then equation Equation 1 from the module titled "Filter Sizing" can be used directly and the equation for α becomes

α = 0 . 22 - l o g e δ π .

A final hint - Watch out for the implicit boundary conditions present in the design of linear phase FIR digital filters in two cases: even order,symmetric response and odd order, antisymmetrical response. In both of these cases the underlying equations for the filter's frequency response constrainit to equal exactly zero at f s 2 . This is obviously not a problem for lowpass filters, since the desired gain at f s 2 is zero already. However, in the design of multiband and highpass filters aninordinate amount of engineering time has been spent trying to design even-order filters when in fact it is impossible to do so. The Parks-McClellanalgorithm will gamely try, but will fail. As a rule, use odd values of N for highpass and multiband filters requiring nonzero response at f s 2 and use even-order filters for differentiators.

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Source:  OpenStax, Notes on the design of optimal fir filters. OpenStax CNX. Sep 14, 2009 Download for free at http://cnx.org/content/col10553/1.3
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