Everything about Elliptic Filter totally explained
An
elliptic filter (also known as a
Cauer filter) is an
electronic filter with equalized ripple (
equiripple) behavior in both the
passband and the
stopband. The amount of ripple in each band is independently adjustable, and no other filter of equal order can have a faster transition in
gain between the
passband and the
stopband, for the given values of ripple (whether the ripple is equalized or not). Alternatively, one may give up the ability to independently adjust the passband and stopband ripple, and instead design a filter which is maximally insensitive to component variations.
As the ripple in the stopband approaches zero, the filter becomes a type I
Chebyshev filter. As the ripple in the passband approaches zero, the filter becomes a type II
Chebyshev filter and finally, as both ripple values approach zero, the filter becomes a
Butterworth filter.
The gain of a
lowpass elliptic filter as a function of angular frequency ω is given by:
»
This results in a filter which is maximally insensitive to component variations, but the ability to independently specify the passband and stopband ripples will be lost. For such filters, as the order increases, the ripple in both bands will decrease and the rate of cutoff will increase. If one decides to use a minimum-Q elliptic filter in order to achieve a particular minimum ripple in the filter bands along with a particular rate of cutoff, the order needed will generally be greater than the order one would otherwise need without the minimum-Q restriction. An image of the absolute value of the gain will look very much like the image in the previous section, except that the poles are arranged in a circle rather than an ellipse. They won't be evenly spaced and there will be zeroes on the ω axis, unlike the
Butterworth filter, whose poles are also arranged in a circle.
Comparison with other linear filters
Here is an image showing the elliptic filter next to other common kind of filters obtained with the same number of coefficients:
As is clear from the image, elliptic filters are sharper than all the others, but they show ripples on the whole bandwidth.
Further Information
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