On Nov 16, 6:01 pm, "Ron N." <rhnlo...@yahoo.com> wrote:
> On Nov 15, 5:48 am, Richard Owlett <rowl...@atlascomm.net> wrote:
> > Looking at Wikipedia article on Goertzel algorithm I thought
> > I might be able to use it as a quick and dirty filter.
...
> The Goertzel algorithm produces roughly the same thing
> as the magnitude from 1-bin of a DFT/FFT. The bandwidth
> will vary inversely proportional to the length N
> (with the bin spacing being fs/N).
...
> For the raw 1-bit DFT or Goertzel filter, I get this
> frequency response:
>
> f0 = Goertzel or bin center frequency
> sr = sample rate
> n is the DFT or filter length
> (f-f0)/sr = bin offset
>
> H(f) = sin(n * pi*(f-f0)/sr) / (n * sin(pi*(f-f0)/sr))
> +- correction_factor
>
> The correction_factor is
> sin(n * pi*(f+f0)/sr) / (n * sin(pi*(f+f0)/sr))
>
> The correction_factor is added if the data is an even
> function in the window, subtracted if the data is an odd
> function in the window, and some ratio in-between for data
> that has a mix of evenness/oddness. So the phase of the
> data, relative to the window center, does make a difference.
> This is due to fact that the negative frequency Sinc
> convolution is the the complex conjugate of the positive
> frequency Sinc convolution for real data.
Just to complete the above frequency response equation,
if the phase ph(f) of the input spectrum with respect to
the center of the rectangular window is known, then you
can correct the frequency response using the vector sum:
s1 = sin(n * pi*(f-f0)/sr) / (n * sin(pi*(f-f0)/sr))
s2 = sin(n * pi*(f+f0)/sr) / (n * sin(pi*(f+f0)/sr))
H(f) = (s1^2 + s2^2 + 2*s1*s2*cos(2 * ph(f))
This equation seems to work even if neither f or f0 is
periodic in a window of length n. That's turns out to
be another difference between a 1-bin DFT and Goertzel.
A DFT/FFT only calculates correlations against periodic
sinusoids in the DFT aperature. A Goertzel filter can
be used for correlation against any frequency, irrespective
of window length or periodicity.
> The correction factor is "small" if the bin number
> (f0/sr) is "big", and thus usually ignored, as Clay
> said earlier in this thread.
Also, n * sin(w) is close to n * w for very small w,
giving the standard Sinc formulation.
Reply by Richard Owlett●November 17, 20072007-11-17
Ron N. wrote:
> On Nov 15, 5:48 am, Richard Owlett <rowl...@atlascomm.net> wrote:
>
>>Looking at Wikipedia article on Goertzel algorithm I thought I might be
>>able to use it as a quick and dirty filter.
>>
>>I'm interested in looking at formants.
>>Looking at the spectra of my specific test case, I'd want something from
>>10% of center to 1/3 octave but being>= 20db down an octave away.
>
>
> The Goertzel algorithm produces roughly the same thing
> as the magnitude from 1-bin of a DFT/FFT. The bandwidth
> will vary inversely proportional to the length N
> (with the bin spacing being fs/N).
>
> But the window applied (or lack thereof) is the real
> issue for your bandwidth requirements.
>
> If you don't window your data (that's the same thing as
> a rectangular window), the 1st side lobe in the frequency
> response is only about 13 db down. If you want > 20 db
> down without a window, you will have to go more than
> 3.5 bins away from your Goertzel bin center. Or you
> could window your data pre-Goertzel.
>
> For the raw 1-bit DFT or Goertzel filter, I get this
> frequency response:
>
> f0 = Goertzel or bin center frequency
> sr = sample rate
> n is the DFT or filter length
> (f-f0)/sr = bin offset
>
> H(f) = sin(n * pi*(f-f0)/sr) / (n * sin(pi*(f-f0)/sr))
> +- correction_factor
>
> The correction_factor is
> sin(n * pi*(f+f0)/sr) / (n * sin(pi*(f+f0)/sr))
>
> The correction_factor is added if the data is an even
> function in the window, subtracted if the data is an odd
> function in the window, and some ratio in-between for data
> that has a mix of evenness/oddness. So the phase of the
> data, relative to the window center, does make a difference.
> This is due to fact that the negative frequency Sinc
> convolution is the the complex conjugate of the positive
> frequency Sinc convolution for real data.
>
> The correction factor is "small" if the bin number
> (f0/sr) is "big", and thus usually ignored, as Clay
> said earlier in this thread.
>
>
>
> IMHO. YMMV.
>
MMDV -- My Mileage *DOES* Vary :)
Actually I get more mileage from your answer than you might expect.
1. You saved me the arithmetic of applying the formula. Actually +-4
bins for 20db down is a nice match for my problem. Judicious choice of
window width can make it a good match.
2. It also gave me an idea idea on how to apply something Tim Wescott
said in my related thread "Am I reinventing Goertzel etc?"
Reply by Ron N.●November 16, 20072007-11-16
On Nov 15, 5:48 am, Richard Owlett <rowl...@atlascomm.net> wrote:
> Looking at Wikipedia article on Goertzel algorithm I thought I might be
> able to use it as a quick and dirty filter.
>
> I'm interested in looking at formants.
> Looking at the spectra of my specific test case, I'd want something from
> 10% of center to 1/3 octave but being>= 20db down an octave away.
The Goertzel algorithm produces roughly the same thing
as the magnitude from 1-bin of a DFT/FFT. The bandwidth
will vary inversely proportional to the length N
(with the bin spacing being fs/N).
But the window applied (or lack thereof) is the real
issue for your bandwidth requirements.
If you don't window your data (that's the same thing as
a rectangular window), the 1st side lobe in the frequency
response is only about 13 db down. If you want > 20 db
down without a window, you will have to go more than
3.5 bins away from your Goertzel bin center. Or you
could window your data pre-Goertzel.
For the raw 1-bit DFT or Goertzel filter, I get this
frequency response:
f0 = Goertzel or bin center frequency
sr = sample rate
n is the DFT or filter length
(f-f0)/sr = bin offset
H(f) = sin(n * pi*(f-f0)/sr) / (n * sin(pi*(f-f0)/sr))
+- correction_factor
The correction_factor is
sin(n * pi*(f+f0)/sr) / (n * sin(pi*(f+f0)/sr))
The correction_factor is added if the data is an even
function in the window, subtracted if the data is an odd
function in the window, and some ratio in-between for data
that has a mix of evenness/oddness. So the phase of the
data, relative to the window center, does make a difference.
This is due to fact that the negative frequency Sinc
convolution is the the complex conjugate of the positive
frequency Sinc convolution for real data.
The correction factor is "small" if the bin number
(f0/sr) is "big", and thus usually ignored, as Clay
said earlier in this thread.
IMHO. YMMV.
--
rhn A.T nicholson d.0.t C-o-M
Reply by Clay●November 15, 20072007-11-15
On Nov 15, 4:38 pm, "Ron N." <rhnlo...@yahoo.com> wrote:
> On Nov 15, 1:26 pm, "Ron N." <rhnlo...@yahoo.com> wrote:
>
>
>
>
>
> > On Nov 15, 7:45 am, Clay <phys...@bellsouth.net> wrote:
>
> > > On Nov 15, 8:48 am, Richard Owlett <rowl...@atlascomm.net> wrote:
>
> > > > Looking at Wikipedia article on Goertzel algorithm I thought I might be
> > > > able to use it as a quick and dirty filter.
>
> > > > I'm interested in looking at formants.
> > > > Looking at the spectra of my specific test case, I'd want something from
> > > > 10% of center to 1/3 octave but being>= 20db down an octave away.
>
> > > Hello Richard,
>
> > > I answered this one a while back see
>
> > >http://groups.google.com/group/comp.dsp/browse_thread/thread/68806908...
>
> > > for details.
>
> > Interesting...
> > In the above referenced thread, for the gain, Clay writes:
>
> > > X(f) = (1/N)*sin(pi*f*N/F)/sin(pi*f/F)
> > and Tim writes:
> > > H(theta) = sin((q0 - theta) * N/2) / (q0 - theta) +
> > > sin((q0 + theta) * N/2) / (q0 + theta)
>
> > and neither seems to reference the starting or ending
> > phase of the Goertzel filter's impulse response, which
> > should make some difference if the filter's frequency
> > is not exactly periodic within N samples.
>
> I'll retract this last statement for Tim's formulation,
> since whether or not the zeros of the sine or Sinc functions
> overlap seems to contain information about any fractional
> remainders of a period.
>
>
>
>
>
> > IMHO. YMMV.
> > --
> > rhn A.T nicholson d.0.t C-o-M- Hide quoted text -
>
> - Show quoted text -- Hide quoted text -
>
> - Show quoted text -
Hello Ron,
A phase correction term can be added to make it exact, but if one is
looking at least several cycles and the frequency error is less than
half of a bin spacing, I've found the relative error for this simple
formula due to phase to be under 1%. This should be good enough for
most applications.
Clay
Reply by Ron N.●November 15, 20072007-11-15
On Nov 15, 1:26 pm, "Ron N." <rhnlo...@yahoo.com> wrote:
> On Nov 15, 7:45 am, Clay <phys...@bellsouth.net> wrote:
>
>
>
> > On Nov 15, 8:48 am, Richard Owlett <rowl...@atlascomm.net> wrote:
>
> > > Looking at Wikipedia article on Goertzel algorithm I thought I might be
> > > able to use it as a quick and dirty filter.
>
> > > I'm interested in looking at formants.
> > > Looking at the spectra of my specific test case, I'd want something from
> > > 10% of center to 1/3 octave but being>= 20db down an octave away.
>
> > Hello Richard,
>
> > I answered this one a while back see
>
> >http://groups.google.com/group/comp.dsp/browse_thread/thread/68806908...
>
> > for details.
>
> Interesting...
> In the above referenced thread, for the gain, Clay writes:
>
> > X(f) = (1/N)*sin(pi*f*N/F)/sin(pi*f/F)
> and Tim writes:
> > H(theta) = sin((q0 - theta) * N/2) / (q0 - theta) +
> > sin((q0 + theta) * N/2) / (q0 + theta)
>
> and neither seems to reference the starting or ending
> phase of the Goertzel filter's impulse response, which
> should make some difference if the filter's frequency
> is not exactly periodic within N samples.
I'll retract this last statement for Tim's formulation,
since whether or not the zeros of the sine or Sinc functions
overlap seems to contain information about any fractional
remainders of a period.
On Nov 15, 7:45 am, Clay <phys...@bellsouth.net> wrote:
> On Nov 15, 8:48 am, Richard Owlett <rowl...@atlascomm.net> wrote:
>
> > Looking at Wikipedia article on Goertzel algorithm I thought I might be
> > able to use it as a quick and dirty filter.
>
> > I'm interested in looking at formants.
> > Looking at the spectra of my specific test case, I'd want something from
> > 10% of center to 1/3 octave but being>= 20db down an octave away.
>
> Hello Richard,
>
> I answered this one a while back see
>
> http://groups.google.com/group/comp.dsp/browse_thread/thread/68806908...
>
> for details.
Interesting...
In the above referenced thread, for the gain, Clay writes:
and neither seems to reference the starting or ending
phase of the Goertzel filter's impulse response, which
should make some difference if the filter's frequency
is not exactly periodic within N samples.
IMHO. YMMV.
--
rhn A.T nicholson d.0.t C-o-M
Reply by Tim Wescott●November 15, 20072007-11-15
On Thu, 15 Nov 2007 07:48:26 -0600, Richard Owlett wrote:
> Looking at Wikipedia article on Goertzel algorithm I thought I might be
> able to use it as a quick and dirty filter.
>
> I'm interested in looking at formants.
> Looking at the spectra of my specific test case, I'd want something from
> 10% of center to 1/3 octave but being>= 20db down an octave away.
To find the pass characteristics of the Goertzel algorithm, take the
Fourier transform of the impulse response of the kernel, truncated to the
length of the sample you're going to take. You'll find that what you get
is a sinc function that's centered around your desired frequency. You'll
also find that response added to a sinc function that's centered around
the negative of your desired frequency, but if you take the Goertzel for
many cycles of the tone then that second response won't confound your
answers too much.
--
Tim Wescott
Control systems and communications consulting
http://www.wescottdesign.com
Need to learn how to apply control theory in your embedded system?
"Applied Control Theory for Embedded Systems" by Tim Wescott
Elsevier/Newnes, http://www.wescottdesign.com/actfes/actfes.html
Reply by Clay●November 15, 20072007-11-15
On Nov 15, 8:48 am, Richard Owlett <rowl...@atlascomm.net> wrote:
> Looking at Wikipedia article on Goertzel algorithm I thought I might be
> able to use it as a quick and dirty filter.
>
> I'm interested in looking at formants.
> Looking at the spectra of my specific test case, I'd want something from
> 10% of center to 1/3 octave but being>= 20db down an octave away.
Reply by Richard Owlett●November 15, 20072007-11-15
Looking at Wikipedia article on Goertzel algorithm I thought I might be
able to use it as a quick and dirty filter.
I'm interested in looking at formants.
Looking at the spectra of my specific test case, I'd want something from
10% of center to 1/3 octave but being>= 20db down an octave away.