harmon2 — Analyze an audio input and generate harmonizing voices in synchrony with formants preserved.
ares harmon2 asig, koct, kfrq1, kfrq2, icpsmode, ilowest[, ipolarity]
ares harmon3 asig, koct, kfrq1, \
kfrq2, kfrq3, icpsmode, ilowest[, ipolarity]
ares harmon4 asig, koct, kfrq1, \
kfrq2, kfrq3, kfrq4, icpsmode, ilowest[, ipolarity]
icpsmode -- interpreting mode for the generating frequency inputs kfrq1, kfrq2, kfrq3 and kfrq4: 0: input values are ratios w.r.t. the cps equivalent of koct. 1: input values are the actual requested frequencies in cps.
ilowest -- lowest value of the koct input for which harmonizing voices will be generated.
ipolarity -- polarity of asig input, 1 = positive glottal pulses, 0 = negative. Default is 1.
Harmon2, harmon3 and harmon4 are high-performance harmonizers, able to provide up to four pitch-shifted copies of the input asig with spectral formants preserved. The pitch-shifting algorithm requires an accurate running estimate (koct, in decimal oct units) of the pitched content of asig, normally gained from an independent pitch tracker such as specptrk. The algorithm then isolates the most recent full pulse within asig, and uses this to generate the other voices at their required pulse rates.
If the frequency (or ratio) presented to kfrq1, kfrq2, kfrq3 or kfrq4 is zero, then no signal is generated for that voice. If any of them is non-zero, but the koct input is below the value ilowest, then that voice will output a direct copy of the input asig. As a consequence, the data arriving at the k-rate inputs can variously cause the generated voices to be turned on or off, to pass a direct copy of a non-voiced fricative source, or to harmonize the source according to some constructed algorithm. The transition from one mode to another is cross-faded, giving seemless alternating between voiced (harmonized) and non-voiced fricatives during spoken or sung input.
harmon2, harmon3, harmon4 are especially matched to the output of specptrk. The latter generates pitch data in decimal octave format; it also emits its base value if no pitch is identified (as in fricative noise) and emits zero if the energy falls below a threshold, so that harmon2, harmon3, harmon4 can be set to pass the direct signal in both cases. Of course, any other form of pitch estimation could also be used. Since pitch trackers usually incur a slight delay for accurate estimation (for specptrk the delay is printed by the spectrum unit), it is normal to delay the audio signal by the same amount so that harmon2, harmon3, harmon4 can work from a fully concurrent estimate.
Here is an example of the harmon2 opcode. Play harmon.csd
Example 433. Example of the harmon2 opcode.
a1,a2 ins ; get mic input w1 spectrum a1, .02, 7, 24, 12, 1, 3 ; and examine it koct,kamp specptrk w1, 1, 6.5, 9.5, 7.5, 10, 7, .7, 0, 3, 1 a3 delay a1, .065 ; allow for ptrk delay a4 harmon2 a3, koct, 1.25, 0.75, 0, 6.9 ; output a fixed 6-4 harmony outs a3, a4 ; as well as the original
Here is a complete example of the harmon3 opcode. Play harmon3.csd
Example 434. Example of the harmon3 opcode.
See the sections Real-time Audio and Command Line Flags for more information on using command line flags.
<CsoundSynthesizer> <CsOptions> ; Select audio/midi flags here according to platform -odac ;;;realtime audio out ;-iadc ;;;uncomment -iadc if realtime audio input is needed too ; For Non-realtime ouput leave only the line below: ; -o harmon3.wav -W ;;; for file output any platform </CsOptions> <CsInstruments> sr = 44100 ksmps = 32 nchnls = 2 0dbfs = 1 instr 1 ilow = p4 ;lowest value to harmonize aout diskin2 "sing.wav", 1, 0, 1 koct, kamp pitch aout, .01, 6, 10, 10 ;track pitch asig harmon3 aout, koct, .9, 1.5, 0.7, 0, ilow outs (asig + aout)*.4, (asig + aout)*.4 ;mix dry&wet signal endin </CsInstruments> <CsScore> i1 0 2.2 8.8 i1 3 2.2 8.2 i1 6 2.2 7.0 e </CsScore> </CsoundSynthesizer>