I understand this is an old question, but I'd like to add something that does not seem to have been mentioned before.

The first thing you should realize is that:

- There are several different types of (digital) filters.
- There are several different ways to design filters.
- There are several different implementations of filters.

When you need to use a filter in your application, you'll have to choose a certain type of filter, choose a specific design method for that kind of filter, apply that method to find the filter coefficients that satisfy your constraints and, finally, copy those coefficients to your filter implementation.

Choosing the type of filter and applying the design method is something you do once, using an appropriate software, such as Matlab or Octave or Scilab. This may involve a bit of experimentation and observation of the obtained characteristics of the filter, such as the frequency response (both amplitude and phase) and/or the impulse response, to see if they match your specifications. Once you settle on the solution, you will have a set of constant coefficients. These numbers, or some linear combination of these numbers, is all you need to copy to your program (Java or otherwise) as a table of constants.

Then, in your program, you just need a function that applies some filter implementation that uses these coefficients to do linear combinations of the input stream samples (and possibly previous output samples) to produce the new output sample in each time instant.

I assume you will probably be interested in Linear Time-Invariant filters, either with finite impulse response (FIR) or infinite impulse response (IIR). The design methods differ between these two subclasses. Butterworth, Chebyshev, elliptic filters are merely the result of different techniques (or optimizations) for designing IIR filters. These can achieve very good frequency responses with a small order, meaning you need few coefficients and therefore a small number of multiplications/additions per sample in the implementation.
But if you really want a linear-phase response, say, then you'll need FIR filters.
These have different design techniques and generally require higher orders for similar frequency characteristics. There are efficient implementations using Fast Fourier Transforms, but I doubt you would need such a thing.

The possible different filter implementations differ mainly in numerical stability. You probably won't notice the difference unless you're using very low precision arithmetic and/or quite exotic coefficients. I believe the Matlab/Octave filter function uses the "Direct-form II" implementation, which is quite simple. You'll find a description on DSP books or the web, I'm sure.

João Manuel Rodrigues