pztf

Compute minimum phase envelope (for test purposes only)

Usage

Amip := eval pztf(Ac, nn, nd, 0)

Amip := eval pztf(Ae, nn, nd, 0)

Result

log. minimum phase amplitude response in dB (Amip[*,0])

Compute polyinomial coefficients of numerator and denominator of the p/z transfer function H(z)=N(z)/D(z)

Usage

ND := eval pztf(Ac, nn, nd, 1 | 2) 1=wlls, 2=nd

ND := eval pztf(Ae, nn, nd, 1 | 2) 1=wlls, 2=nd

Result

numerator and denominator coefficients:

ND[0,0]=nn, ND[1..nn,0]=an[0..nn-1],

ND[0,1]=nd, ND[1..nd,1]=ad[0..nd-1]

Compute amplitude response |H(z)| in dB

Usage

H := eval pztf(ND, nh)

Result

amplitude response in dB (H[*,0])

Compute poles and zeros

Usage

ZP := eval pztf(ND)

Result

zeros and poles

ZP[0,0]=nz, ZP[0,1..nz]=rz[0..nz-1], ZP[0,nz+1..nz+np]=rp[0..np-1]

ZP[1,0]=np, ZP[1,1..nz]=fz[0..nz-1], ZP[1,nz+1..nz+np]=fp[0..np-1]

Notes

1) relative frequencies fz/fp are computed as: fx[i] = (arg(x[i]) / pi

1) zeros and poles are sorted by increasing rel. frequency fz/fp

2) if fz/fp[i]=0 -> real pole/zero on the right side

3) if fz/fp[i]=1 -> real pole/zero on the left side

4) if 0<fz/fp[i]<1 conjugate complex pole/zero

Ac

complex minimum phase envelope (Ac[*,0] = re, Ac[*,1] = im)

Ae

log. envelope in dB (Ae[*,0])

nn

order of numerator

nd

order of denominator

nh

number of H frequency bins

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