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I am porting code from Matlab to Python and am having trouble finding a replacement for the firls( ) routine. It is used for, least-squares linear-phase Finite Impulse Response (FIR) filter design.

I looked at scipy.signal and nothing there looked like it would do the trick. Of course I was able to replace my remez and freqz algorithsm, so that's good.

On one blog I found an algorithm that implemented this filter without weighting, but I need one with weights.

Thanks, David

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Which toolbox is that from? – SamB Apr 2 '10 at 21:10

This blog post contains code detailing how to use scipy.signal to implement FIR filters.

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Well, that was intereseting blog post, but not exactly what I was looking for. I saw the firwin( ) function, but it does not have have the ability to express the frequency response the way I need it for Magnetic resonance imaging... I was hoping not to reinvent the wheel, but it's looking more likely that I will need to do that. Thanks, – delicasso Apr 5 '10 at 18:26

Obviously, this post is somewhat dated, but maybe it is still interesting for some:

I think there are two near-equivalents to firls in Python:

  • You can try the firwin function with window='boxcar'. This is similar to Matlab where fir1 with a boxcar window delivers the same (? or at least very similar results) as firls.
  • You could also try the firwin2 method (frequency sampling method, similar to fir2 in Matlab), again using window='boxcar'

I did try one example from the Matlab firls reference and achieved near-identical results for:

Matlab:

F = [0 0.3  0.4 0.6  0.7 0.9];
A = [0  1   0  0  0.5 0.5];
b = firls(24,F,A,'hilbert');

Python:

F = [0, 0.3,  0.4, 0.6,  0.7, 0.9, 1]
A = [0,  1,   0,  0,  0.5, 0.5, 0]
bb = sig.firwin2( 25, F,A, window='boxcar', antisymmetric=True )

I had to increase the order to N = 25 and I also had to add another data point (F = 1, A = 0) which Python insisted upon; the option antisymmetric = True is only necessary for this special case (Hilbert filter)

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I found a firls() implementation attached here in SciPy ticket 648

Minor changes to get it working:

  1. Swap the following two lines: bands, desired, weight = array(bands), array(desired), array(weight) if weight==None : weight = ones(len(bands)/2)

  2. import roots from numpy instead of scipy.signal

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It seems unlikely that you'll find exactly what you seek already written in Python, but perhaps the Matlab function's help page gives or references a description of the algorithm?

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This post is really in response to

You can try the firwin function with window='boxcar'...

Do don't use boxcar it means no window at all (it is ideal but only works "ideally" with an infinite number of multipliers - sinc in time). The whole perpose of using a window is the reduce the number of multipliers required to get good stop band attenuation. See Window function

When comparing filters please use dB/log scale.

Scipy not having firls (FIR least squares filter) function is a large limitation (as it generates the optimum filter in many situations).

REMEZ has it's place but the flat roll off is a real killer when your trying to get the best results (and not just meeting some managers spec). ( warning scipy remez implementation can give amplification in stop band - see plot at bottom)

If you are using python (or need to use some window) I recommend using the kasiar window which gets very good results and can easily be tweaked for your attenuation vs transition vs multipliers requirement(attenuation (in dB) = 2.285 * (multipliers - 1) * pi * width + 7.95). It performance is not quite as good as firls but it has the benefit of being fast and easy to calculate (great if you don't store the coefficients).

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