Practical use of Phase Delay for IIR Filter on Pure Sinusoid

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Matt Gaidica
Matt Gaidica el 5 de Oct. de 2020
Comentada: Star Strider el 6 de Oct. de 2020
I recently asked a question about Finding Dominant Frequency and Phase using FFT. My follow-up question has to do with the phase shift induced by an IIR filter. For example, consider a situation where I want to forecast a signal into the future. The original, noisy signal gets filtered (Row 1). The dominant frequency is determined (Row 2). The phase angle of the dominant frequency is determined (Row 3). Finally, the forecasted signal is aligned with the filtered signal based on the phase angle to the dominant frequency (Row 4).
However, the true goal is to align the forecasted signal with the original signal, but I don't understand how—other than empirically—to determine the phase shift. Is this information in phasedelay() (below)?
This essentially results in two phase shifts of the forecasted signal: one based on the original signal's phase (gathered from fft()), one to correct for the shift due to the IIR (unsure about this).
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Matt Gaidica
Matt Gaidica el 6 de Oct. de 2020
Mathieu, assuming a 2Hz sine wave is the raw data, where would I gather information on the delay of the filter? For example, if I'm forecasting using a sine wave, my delay should be bounded by -π and π.
Mathieu NOE
Mathieu NOE el 6 de Oct. de 2020
Matt
i am not 100% sure of what you intend to do , but if you want to smooth some noisy sine waves without adding delay , you should try to use bandpass filters and not only low pass filters.
If you know or measure first the sine wave frequency (f0) set the bandpass filter low and high pass frequency like this :
f_low = f0/a
f_high = f0*a
a defines the bandwith (selectivity) of you filter (start with a = 2 for example and see the diffeence when increasing / decreasing a)
the benefit of doing this way is that your bandpass filter will have zero delay at the f0 frequency, so if you implement it on a DSP , you can observe both raw and filtered signals without delay.
to furtehr comment on phase behaviour of filters, there is NO filter that has not a phase roll with frequency - even Bessel filters. This applies for analog and digital filters as well. Only if there is need for it , there are "linear" phase filters and "non linear" phase filters - but there is no "phase neutral" filter on earth - not sure what neutral means here...

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Star Strider
Star Strider el 6 de Oct. de 2020
To avoid the phase shift, use the filtfilt function instead of filter.
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Matt Gaidica
Matt Gaidica el 6 de Oct. de 2020
Editada: Matt Gaidica el 6 de Oct. de 2020
Thanks, Star. The IIR selection might be a bit outside the scope of this thread: A Fast EEG Forecasting Algorithm for Phase-Locked Transcranial Electrical Stimulation of the Human Brain
In any case, my best attempt at characterizing the filter is as follows. I swept from the low to high cutoff frequencies of my filter (0.5–4Hz) using each frequency to construct a pure sine wave, which was then passed through my filter. I used the FFT to extract the phase at each frequency, ultimately building a phase delay curve (or 'lookup table') based on the dominant frequency of the filtered data (this is the phase shift I need to apply to the forecasted signal to re-align it to the raw data).
Those data can be unwrapped and fit with a third order polynomial (adequate for my application) which makes the phase shift lookup basically one line of code (or use feval() in MATLAB).
Together: the raw data is a 2.3Hz sine wave arbitrarily shifted (here, 0.65π, Row 1). That phase delay is found by the FFT (Rows 2,3) and forecasted, then corrected by the phase delay from my polynomial lookup equation (Row 4).
This feels very convoluted, but arriving at a simple one-liner phase correction is something I'm happy with. Here's another example where the raw data is modulated at 3.15Hz with an arbitrary shift of 1.6π.
Star Strider
Star Strider el 6 de Oct. de 2020
I’m not certain what you want to do. If you’re doing anything in real-time, the Bessel filter (or several cascaded if necessary to get a shorter transition region) is likely the way to go for the reasons I stated. For real-time applications, it would be necessary to minimise the phase delay and phase distortion inherent in other filter designs.
I’ve not done anything with EEG for a while, and nothing about using (what appears to me to be) a feedback system for transcranial stimulation. That’s beyond the scope of my current expertise.
In any event, while you can use Bessel filters for real-time applications, to prototype them in MATLAB it is necessary to use filtfilt, since it provides phase-neutral filtering for all discrete filter designs.

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