Hi Jay,
Here is the filter
[be,ae] = ellip(4,1,40,0.2);
f = 0:0.001:0.2;
g = grpdelay(be,ae,f,2); % Equalize only the passband.
a = max(g)-g;
[num,den]=iirgrpdelay(8, f, [0 0.2], a);
Here is its frequency response. Note that the deviations are around 1e-9 dB, so the magnitude is very close to 1
freqz(num,den)
Plote the magnnitude on an absolute scale to better visualize closeness to 1
[h,w] = freqz(num,den);
plot(w,abs(h))
Using the sos form cleans up the "noise", but still not a perfect allpass.
sos = tf2sos(num,den);
[h,w] = freqz(sos);
plot(w,abs(h))
Check the poles and zeros.
zplane(num,den)
The magnitudes of the poles and zeros should be reciprocals of each other. They are close, but not exact.
diff(sort([abs(roots(den)) 1./abs(roots(num))]),1,2)
I'm suprised that iirgrpdelay doesn't enforce that relationship. I checked the code and iirgrpdelay actually develops the filter in sos form, which should be far superior, and then converts to num,den as the last step. That's surprising to me, i.e., why not just stay in sos form? I checked in the debugger, and the low frequency deviation from unity of the sos form inside iirgrpdelay was no more than 1e-14 and usually smaller, so quite a bit better.
Anyway, we can verify with the Symbolic Math Toolbox that the very small deviation at low frequency is not just numerical error in freqz with the sos form.
syms z
numz = simplify(poly2sym(num,z)/z^8);
denz = simplify(poly2sym(den,z)/z^8);
syms h(z)
h(z) = simplify(numz/denz);
figure
plot(w,double(abs(h(exp(1j*w)))))
