ref: c43ebefdc2817594fd65ee2899b5fb58699e5a1b
dir: /python/demos/demo_pitch_sinusoid.py/
#! /usr/bin/env python
import numpy as np
import aubio
def build_sinusoid(length, freqs, samplerate):
return np.sin( 2. * np.pi * np.arange(length) * freqs / samplerate).astype(aubio.float_type)
def run_pitch(p, input_vec):
cands = []
for vec_slice in input_vec.reshape((-1, p.hop_size)):
a = p(vec_slice)[0]
cands.append(a)
return cands
methods = ['default', 'schmitt', 'fcomb', 'mcomb', 'yin', 'yinfft']
cands = {}
buf_size = 2048
hop_size = 512
samplerate = 44100
sin_length = (samplerate * 10) % 512 * 512
freqs = np.zeros(sin_length)
partition = sin_length // 8
pointer = 0
pointer += partition
freqs[pointer: pointer + partition] = 440
pointer += partition
pointer += partition
freqs[ pointer : pointer + partition ] = 740
pointer += partition
freqs[ pointer : pointer + partition ] = 1480
pointer += partition
pointer += partition
freqs[ pointer : pointer + partition ] = 400 + 5 * np.random.random(sin_length//8)
a = build_sinusoid(sin_length, freqs, samplerate)
for method in methods:
p = aubio.pitch(method, buf_size, hop_size, samplerate)
cands[method] = run_pitch(p, a)
print(method)
print(cands[method])
print("done computing")
if 1:
import matplotlib.pyplot as plt
# times
ramp = np.arange(0, sin_length / hop_size).astype('float') * hop_size / samplerate
# plot each result
for method in methods:
plt.plot(ramp, cands[method], '.-', label=method)
# plot ground truth
ramp = np.arange(0, sin_length).astype('float') / samplerate
plt.plot(ramp, freqs, ':', label = 'ground truth')
plt.legend(loc='upper left')
plt.xlabel('time (s)')
plt.ylabel('frequency (Hz)')
plt.ylim([0,2000])
plt.show()