182 lines
4.3 KiB
Text
182 lines
4.3 KiB
Text
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class:: KeyTrack
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summary:: Key tracker
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categories:: UGens>Analysis>Pitch
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related:: Classes/BeatTrack, Classes/Loudness, Classes/MFCC, Classes/Onsets, Classes/Pitch
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description::
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A (12TET major/minor) key tracker based on a pitch class profile of energy across FFT bins and matching this to templates for major and minor scales in all transpositions. It assumes a 440 Hz concert A reference. Output is 0-11 C major to B major, 12-23 C minor to B minor.
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classmethods::
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method:: kr
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argument:: chain
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[fft] Audio input to track. This must have been pre-analysed by a 4096 size FFT. No other FFT sizes are valid except as noted below.
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code::
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// With standard hop of half FFT size = 2048 samples
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b = Buffer.alloc(s,4096,1); // for sampling rates 44100 and 48000
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//b = Buffer.alloc(s,8192,1); // for sampling rates 88200 and 96000
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::
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argument:: keydecay
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[sk] Number of seconds for the influence of a window on the final key decision to decay by 40dB (to 0.01 its original value).
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argument:: chromaleak
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[sk] Each frame, the chroma values are set to the previous value multiplied by the chromadecay. 0.0 will start each frame afresh with no memory.
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examples::
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code::
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// The following files are test materials on my machine; you will subsitute your own filenames here
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// A major
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d = Buffer.read(s,"/Volumes/data/stevebeattrack/samples/100.wav");
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// F major; hard to track!
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d = Buffer.read(s,"/Volumes/data/stevebeattrack/samples/115.wav");
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// straight forward since no transients; training set from MIREX2006
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// 01 = A major
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// 57 = b minor
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// 78 e minor
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// 08 Bb major
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d = Buffer.read(s, "/Users/nickcollins/Desktop/ML/training_wav/78.wav")
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b = Buffer.alloc(s, 4096, 1); // for sampling rates 44100 and 48000
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(
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{
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var in, fft, resample;
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var key, transientdetection;
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in = PlayBuf.ar(1, d, BufRateScale.kr(d), 1, 0, 1);
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fft = FFT(b, in);
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key=KeyTrack.kr(fft, 2.0, 0.5);
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key.poll;
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Out.ar(0,Pan2.ar(in));
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}.play
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)
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::
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code::
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// alternating major and minor chords as a test
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(
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{
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var in, fft, resample;
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var key, transientdetection;
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in = Mix(SinOsc.ar((60 + [0, MouseX.kr(3, 4).round(1), 7]).midicps, 0, 0.1));
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// major dom 7 and minor 7; major keys preferred here
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//in = Mix(SinOsc.ar((60 + (MouseY.kr(0, 11).round(1.0)) + [0, MouseX.kr(3, 4).round(1), 7, 10]).midicps, 0, 0.1));
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fft = FFT(b, in);
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key = KeyTrack.kr(fft);
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key.poll;
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Out.ar(0,Pan2.ar(in));
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}.play
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)
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::
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code::
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// Nice to hear what KeyTrack thinks:
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d = Buffer.read(s, "/Users/nickcollins/Desktop/ML/training_wav/78.wav")
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b = Buffer.alloc(s, 4096, 1); // for sampling rates 44100 and 48000
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(
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{
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var in, fft, resample, chord, rootnote, sympath;
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var key, transientdetection;
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in = PlayBuf.ar(1, d, BufRateScale.kr(d), 1, 0, 1);
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fft = FFT(b, in);
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key = KeyTrack.kr(fft, 2.0, 0.5);
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key.poll;
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key = Median.kr(101, key); // Remove outlier wibbles
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chord = if(key<12, #[0, 4, 7], #[0, 3, 7]);
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rootnote = if(key<12, key, key-12) + 60;
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sympath = SinOsc.ar((rootnote + chord).midicps, 0, 0.4).mean;
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Out.ar(0,Pan2.ar(in, -0.5) + Pan2.ar(sympath, 0.5));
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}.play
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)
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::
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code::
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// Research Notes:
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// See the MIREX2006 audio key tracking competition and Emilia Gomez's PhD thesis, Tonal Description of Music Audio Signals
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// The following code was used to create the datasets for the UGen, and would be the basis of extensions
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// Need one set of bin data for 44100 and one for 48000
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// KeyTrack calculations, need to make arrays of FFT bins and weights for each chromatic tone.
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// greater resolution, 4096 FFT, avoid lower octaves, too messy there
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// 60*6*2 output arrays
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(
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var fftN, fftBins, binsize;
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var midinotes;
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var sr;
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var wtlist, binlist;
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sr = 48000; //44100;
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fftN = 4096;
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fftBins = fftN.div(2);
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binsize = sr / fftN;
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midinotes = (33..92); // 60 notes, 55 Hz up to 1661.2187903198 Hz
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wtlist = List[];
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binlist = List[];
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// for each note have six harmonic locations
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midinotes.do{ |note|
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var freq, whichbin, lowerbin, prop;
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freq = note.midicps;
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6.do{|j|
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var partialfreq, partialamp;
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partialamp = 1.0 / (j + 1);
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partialfreq = freq * (j + 1);
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whichbin = partialfreq / binsize;
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lowerbin = whichbin.asInteger;
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prop = 1.0 - (whichbin - lowerbin);
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binlist.add(lowerbin).add(lowerbin + 1);
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wtlist.add(prop * partialamp).add((1.0 - prop) * partialamp);
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};
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};
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Post << (binlist) << nl<< nl;
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Post << (wtlist) << nl<< nl;
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binlist.size.postln;
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wtlist.size.postln;
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)
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::
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