Mel visualization is now globally normalized instead of individually normalized.

Also added realtime adaptive brightness correction to avoid having the
LED strip under or over saturated
This commit is contained in:
Scott Lawson 2016-11-11 15:52:57 -08:00
parent 627f67d3dd
commit cdc4c2976c

View File

@ -75,24 +75,32 @@ def normalize(f):
return np.floor((f - lmin) / (lmax - lmin) * 255.0)
# r_filt = dsp.ExpFilter(np.tile(0.01, config.N_PIXELS),
# alpha_decay=0.075, alpha_rise=0.6)
# g_filt = dsp.ExpFilter(np.tile(0.01, config.N_PIXELS),
# alpha_decay=0.25, alpha_rise=0.9)
# b_filt = dsp.ExpFilter(np.tile(0.01, config.N_PIXELS),
# alpha_decay=0.5, alpha_rise=0.95)
r_filt = dsp.ExpFilter(np.tile(0.01, config.N_PIXELS),
alpha_decay=0.075, alpha_rise=0.6)
alpha_decay=0.1, alpha_rise=0.6)
g_filt = dsp.ExpFilter(np.tile(0.01, config.N_PIXELS),
alpha_decay=0.25, alpha_rise=0.9)
alpha_decay=0.75, alpha_rise=0.95)
b_filt = dsp.ExpFilter(np.tile(0.01, config.N_PIXELS),
alpha_decay=0.5, alpha_rise=0.95)
alpha_decay=0.2, alpha_rise=0.4)
def visualize(y):
y = np.copy(interpolate(y, config.N_PIXELS)) * 255.0
# Blur the color channels with different strengths
r = gaussian_filter1d(y, sigma=0.15)
g = gaussian_filter1d(y, sigma=2.0)
r = gaussian_filter1d(y, sigma=1.0)
g = gaussian_filter1d(y, sigma=0.0)
b = gaussian_filter1d(y, sigma=0.0)
# Take the geometric mean of the raw and normalized histograms
r = np.sqrt(r * normalize(r))
g = np.sqrt(g * normalize(g))
b = np.sqrt(b * normalize(b))
# r = np.sqrt(r * normalize(r))
# g = np.sqrt(g * normalize(g))
# b = np.sqrt(b * normalize(b))
r = np.roll(g, 0)
g = np.roll(g, 0)
b = np.roll(g, 0)
# Update the low pass filters for each color channel
r_filt.update(r)
g_filt.update(g)
@ -110,12 +118,17 @@ def visualize(y):
mel_gain = dsp.ExpFilter(np.tile(1e-1, config.N_PIXELS),
alpha_decay=0.01, alpha_rise=0.99)
# mel_gain = dsp.ExpFilter(np.tile(1e-1, config.N_PIXELS),
# alpha_decay=0.01, alpha_rise=0.99)
volume = dsp.ExpFilter(config.MIN_VOLUME_THRESHOLD,
alpha_decay=0.02, alpha_rise=0.02)
rms = dsp.ExpFilter(0.1, alpha_decay=0.001, alpha_rise=0.001)
exp = dsp.ExpFilter(0.5, alpha_decay=0.001, alpha_rise=0.001)
prev_rms = 1.0
prev_exp = 1.0
def microphone_update(stream):
global y_roll
global y_roll, prev_rms, prev_exp
# Normalize new audio samples
y = np.fromstring(stream.read(samples_per_frame), dtype=np.int16)
y = y / 2.0**15
@ -137,13 +150,29 @@ def microphone_update(stream):
YS = np.sum(YS, axis=0)**2.0
mel = np.concatenate((YS[::-1], YS))
mel = interpolate(mel, config.N_PIXELS)
mel = (mel)**2.
mel_gain.update(mel)
# mel = mel**0.4
mel = mel**exp.value
mel_gain.update(np.max(mel))
mel = mel / mel_gain.value
rms.update(np.sqrt(np.mean(mel**2.0)))
if rms.value > 4e-1:
exp.update(exp.value * 1.2)
elif rms.value < 5e-2:
exp.update(exp.value * 0.8)
rms_delta = '^' if rms.value - prev_rms > 0 else 'v'
exp_delta = '^' if exp.value - prev_exp > 0 else 'v'
print('|{}| {:.0e}, |{}| {:.2}'.format(rms_delta, rms.value, exp_delta, exp.value))
# WHAT IF I TAKE THE TEMPORAL VARIANCE OF EACH INDIVIDUAL BIN
# AND THEN CALCULATE THE COVARIANCE OF HOW THE DIFFERENT BIN VARIANCES
# CHANGE TOGETHER
# COULD COLOR BY COVARIANCE? BLUE PIXELS CHANGE TOGETHER, ETC
prev_exp = exp.value
prev_rms = rms.value
visualize(mel)
GUI.app.processEvents()
print('FPS {:.0f} / {:.0f}'.format(frames_per_second(), config.FPS))
#print('FPS {:.0f} / {:.0f}'.format(frames_per_second(), config.FPS))
# Number of audio samples to read every time frame
@ -158,13 +187,13 @@ if __name__ == '__main__':
GUI = gui.GUI(width=800, height=400, title='Audio Visualization')
# Audio plot
GUI.add_plot('Color Channels')
r_pen = pg.mkPen((255, 30, 30, 200), width=3)
g_pen = pg.mkPen((30, 255, 30, 200), width=3)
b_pen = pg.mkPen((30, 30, 255, 200), width=3)
r_pen = pg.mkPen((255, 30, 30, 200), width=6)
g_pen = pg.mkPen((30, 255, 30, 200), width=6)
b_pen = pg.mkPen((30, 30, 255, 200), width=6)
GUI.add_curve(plot_index=0, pen=r_pen)
GUI.add_curve(plot_index=0, pen=g_pen)
GUI.add_curve(plot_index=0, pen=b_pen)
GUI.plot[0].setRange(xRange=(0, 60), yRange=(-40, 275))
GUI.plot[0].setRange(xRange=(0, config.N_PIXELS), yRange=(-5, 275))
# Initialize LEDs
led.update()
# Start listening to live audio stream