# SuperCollider: automatic phase and frequency alignment of oscillators

Anyone has an idea for automatic phase and frequency alignment?

To explain: assume, you have an Impulse

``````in = Impulse.ar(Rand(2, 5), Rand(0, 1));
``````

now I'd like to manipulate the frequency of another Impulse such that it adapts its phase and frequency to match the input. Any suggestions, even for a google search are highly appreciated.

[question asked on behalf of a colleague]

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I feel as if there should be a way to do it using FFT division to recover the impulse-response between the two sources (although that's mainly useful for phase alignment not freq) - have a look at the PV_Div helpfile which has an example maybe useful. –  Dan S May 3 '13 at 7:25
I think FFT is overkill here. Impulse is pretty much the canonical way of indicating phase sync (think analog trigger signals) and a naked phasor/sawtooth is pretty much the definitional phase counter. We might want to use spectral techniques if we have some kind of noise in the signal with some nice spectral representation and a nasty time-domain representation, but that is not given here. OTOH PV_Div is a sweet hack and I would love the excuse to give it try. ;-) –  dan mackinlay May 6 '13 at 10:01

I don't agree that this, as frame is a tough problem. Impulses are simple to track - that's why, for example, old rotary dial phones used pulse trains.

Here's some code that generates an impulse at a random frequency, then resynthesises another impulse at the same frequency. It also outputs a pitch estimate.

``````(
var left, right, master, slave, periodestimatebus, secretfrequency;
s = Server.default;
left = Bus.new(\audio, 0,1);
right = Bus.new(\audio, 1,1);
periodestimatebus = Bus.control(s,1);
//choose our secret frequency here for later comparison:
secretfrequency = rrand(2.0,5.0);

//generate impulse with secret frequency at some arbitrary phase
master = {Impulse.ar(secretfrequency, Rand(0, 1));}.play(s, left);

slave = {
var masterin, clockcount, clockoffset, syncedclock, periodestimate, tracking;
masterin = In.ar(left);
//This 1 Hz LFSaw is the "clock" against which we measure stuff
clockcount = LFSaw.ar(1, 0, 0.5, 0.5);
clockoffset = Latch.ar(clockcount, Delay1.ar(masterin));
syncedclock = (clockcount - clockoffset).frac;
//syncedclock is a version of the clock hard-reset (one sample after) every impulse trigger
periodestimate = Latch.ar(syncedclock, masterin);
//sanity-check our f impulse
Out.kr(periodestimatebus, periodestimate);
//there is no phase estimate per se - what would we measure it against? -
//but we can resynthesise a new impulse up to a 1 sample delay from the matched clock.
tracking = (Slope.ar(syncedclock)>0);

//Let's see how we performed
{
periodestimatebus.get({|periodestimate|
["actual/estimated frequency", secretfrequency, periodestimate.reciprocal].postln;
});
}.defer(1);
)
``````

Notes to this code:

The `periodestimate` is generated by tricksy use of `Delay1` to make sure that it samples the value of the clock just before it is reset. As such it is off by one sample.

The current implementation will produce a good period estimate with varying frequencies, down to 1Hz at least. Any lower and you'd need to change the `clockcount` clock to have a different frequency and tweak the arithmetic.

Many improvements are possible. For example, if you wish to track varying frequencies you might want to tweak it a little bit so that the resynthesized signal does not click too often as it underestimates the signal.

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Here is some typical output for this code: `[ actual/estimated frequency, 2.289421081543, 2.2894819330855 ]` That is, accurate up to a factor of 0.9999734213. –  dan mackinlay May 5 '13 at 7:47

This is a tough problem, as you are dealing with a noisy source with a low frequency. If this were a sine wave I'd recommend a FFT, but FFTs don't do very well with noisy sources and low frequencies. It's still worth a shot. FFTs can match phase too. I believe you can use pitch.ar to help find the frequency.

The Chrip-Z algorithm is something you could use instead of the FFT -http://www.embedded.com/design/configurable-systems/4006427/A-DSP-algorithm-for-frequency-analysis http://en.wikipedia.org/wiki/Bluestein%27s_FFT_algorithm

Another thing you could try is to use a neural net to try and guess it's way to the right information. You could use active training to help it achieve this goal. There is a very general discussion of this on SO: Pitch detection using neural networks

One method some folks are coming around to is simulating the neurons of Cochlea to detect pitch.

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You may want to read up on Phase-locked loops: http://en.wikipedia.org/wiki/Phase-locked_loop

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