klipper-dgus/scripts/graph_accelerometer.py

243 lines
8.9 KiB
Python
Executable File

#!/usr/bin/env python2
# Generate adxl345 accelerometer graphs
#
# Copyright (C) 2020 Kevin O'Connor <kevin@koconnor.net>
# Copyright (C) 2020 Dmitry Butyugin <dmbutyugin@google.com>
#
# This file may be distributed under the terms of the GNU GPLv3 license.
import optparse, os, sys
from textwrap import wrap
import numpy as np, matplotlib
sys.path.append(os.path.join(os.path.dirname(os.path.realpath(__file__)),
'..', 'klippy', 'extras'))
from shaper_calibrate import ShaperCalibrate
MAX_TITLE_LENGTH=80
def parse_log(logname):
return np.loadtxt(logname, comments='#', delimiter=',')
######################################################################
# Raw accelerometer graphing
######################################################################
def plot_accel(data, logname):
first_time = data[0, 0]
times = data[:,0] - first_time
fig, axes = matplotlib.pyplot.subplots(nrows=3, sharex=True)
axes[0].set_title("\n".join(wrap("Accelerometer data (%s)" % (logname,),
MAX_TITLE_LENGTH)))
axis_names = ['x', 'y', 'z']
for i in range(len(axis_names)):
avg = data[:,i+1].mean()
adata = data[:,i+1] - data[:,i+1].mean()
ax = axes[i]
ax.plot(times, adata, alpha=0.8)
ax.grid(True)
ax.set_ylabel('%s accel (%+.3f)\n(mm/s^2)' % (axis_names[i], -avg))
axes[-1].set_xlabel('Time (%+.3f)\n(s)' % (-first_time,))
fig.tight_layout()
return fig
######################################################################
# Frequency graphing
######################################################################
# Calculate estimated "power spectral density"
def calc_freq_response(data, max_freq):
helper = ShaperCalibrate(printer=None)
return helper.process_accelerometer_data(data)
def calc_specgram(data, axis):
N = data.shape[0]
Fs = N / (data[-1,0] - data[0,0])
# Round up to a power of 2 for faster FFT
M = 1 << int(.5 * Fs - 1).bit_length()
window = np.kaiser(M, 6.)
def _specgram(x):
return matplotlib.mlab.specgram(
x, Fs=Fs, NFFT=M, noverlap=M//2, window=window,
mode='psd', detrend='mean', scale_by_freq=False)
d = {'x': data[:,1], 'y': data[:,2], 'z': data[:,3]}
if axis != 'all':
pdata, bins, t = _specgram(d[axis])
else:
pdata, bins, t = _specgram(d['x'])
for ax in 'yz':
pdata += _specgram(d[ax])[0]
return pdata, bins, t
def plot_frequency(datas, lognames, max_freq):
calibration_data = calc_freq_response(datas[0], max_freq)
for data in datas[1:]:
calibration_data.join(calc_freq_response(data, max_freq))
freqs = calibration_data.freq_bins
psd = calibration_data.psd_sum[freqs <= max_freq]
px = calibration_data.psd_x[freqs <= max_freq]
py = calibration_data.psd_y[freqs <= max_freq]
pz = calibration_data.psd_z[freqs <= max_freq]
freqs = freqs[freqs <= max_freq]
fig, ax = matplotlib.pyplot.subplots()
ax.set_title("\n".join(wrap(
"Frequency response (%s)" % (', '.join(lognames)), MAX_TITLE_LENGTH)))
ax.set_xlabel('Frequency (Hz)')
ax.set_ylabel('Power spectral density')
ax.plot(freqs, psd, label='X+Y+Z', alpha=0.6)
ax.plot(freqs, px, label='X', alpha=0.6)
ax.plot(freqs, py, label='Y', alpha=0.6)
ax.plot(freqs, pz, label='Z', alpha=0.6)
ax.xaxis.set_minor_locator(matplotlib.ticker.AutoMinorLocator())
ax.yaxis.set_minor_locator(matplotlib.ticker.AutoMinorLocator())
ax.grid(which='major', color='grey')
ax.grid(which='minor', color='lightgrey')
ax.ticklabel_format(axis='y', style='scientific', scilimits=(0,0))
fontP = matplotlib.font_manager.FontProperties()
fontP.set_size('x-small')
ax.legend(loc='best', prop=fontP)
fig.tight_layout()
return fig
def plot_compare_frequency(datas, lognames, max_freq):
fig, ax = matplotlib.pyplot.subplots()
ax.set_title('Frequency responses comparison')
ax.set_xlabel('Frequency (Hz)')
ax.set_ylabel('Power spectral density')
for data, logname in zip(datas, lognames):
calibration_data = calc_freq_response(data, max_freq)
freqs = calibration_data.freq_bins
psd = calibration_data.psd_sum[freqs <= max_freq]
freqs = freqs[freqs <= max_freq]
ax.plot(freqs, psd, label="\n".join(wrap(logname, 60)), alpha=0.6)
ax.xaxis.set_minor_locator(matplotlib.ticker.AutoMinorLocator())
ax.yaxis.set_minor_locator(matplotlib.ticker.AutoMinorLocator())
ax.grid(which='major', color='grey')
ax.grid(which='minor', color='lightgrey')
fontP = matplotlib.font_manager.FontProperties()
fontP.set_size('x-small')
ax.legend(loc='best', prop=fontP)
fig.tight_layout()
return fig
# Plot data in a "spectrogram colormap"
def plot_specgram(data, logname, max_freq, axis):
pdata, bins, t = calc_specgram(data, axis)
fig, ax = matplotlib.pyplot.subplots()
ax.set_title("\n".join(wrap("Spectrogram %s (%s)" % (axis, logname),
MAX_TITLE_LENGTH)))
ax.pcolormesh(t, bins, pdata, norm=matplotlib.colors.LogNorm())
ax.set_ylim([0., max_freq])
ax.set_ylabel('frequency (hz)')
ax.set_xlabel('Time (s)')
fig.tight_layout()
return fig
######################################################################
# CSV output
######################################################################
def write_frequency_response(datas, output):
helper = ShaperCalibrate(printer=None)
calibration_data = helper.process_accelerometer_data(datas[0])
for data in datas[1:]:
calibration_data.join(helper.process_accelerometer_data(data))
helper.save_calibration_data(output, calibration_data)
def write_specgram(psd, freq_bins, time, output):
M = freq_bins.shape[0]
with open(output, "w") as csvfile:
csvfile.write("freq\\t")
for ts in time:
csvfile.write(",%.6f" % (ts,))
csvfile.write("\n")
for i in range(M):
csvfile.write("%.1f" % (freq_bins[i],))
for value in psd[i,:]:
csvfile.write(",%.6e" % (value,))
csvfile.write("\n")
######################################################################
# Startup
######################################################################
def is_csv_output(output):
return output and os.path.splitext(output)[1].lower() == '.csv'
def setup_matplotlib(output):
global matplotlib
if is_csv_output(output):
# Only mlab may be necessary with CSV output
import matplotlib.mlab
return
if output:
matplotlib.rcParams.update({'figure.autolayout': True})
matplotlib.use('Agg')
import matplotlib.pyplot, matplotlib.dates, matplotlib.font_manager
import matplotlib.ticker
def main():
# Parse command-line arguments
usage = "%prog [options] <logs>"
opts = optparse.OptionParser(usage)
opts.add_option("-o", "--output", type="string", dest="output",
default=None, help="filename of output graph")
opts.add_option("-f", "--max_freq", type="float", default=200.,
help="maximum frequency to graph")
opts.add_option("-r", "--raw", action="store_true",
help="graph raw accelerometer data")
opts.add_option("-c", "--compare", action="store_true",
help="graph comparison of power spectral density "
"between different accelerometer data files")
opts.add_option("-s", "--specgram", action="store_true",
help="graph spectrogram of accelerometer data")
opts.add_option("-a", type="string", dest="axis", default="all",
help="axis to graph (one of 'all', 'x', 'y', or 'z')")
options, args = opts.parse_args()
if len(args) < 1:
opts.error("Incorrect number of arguments")
# Parse data
datas = [parse_log(fn) for fn in args]
setup_matplotlib(options.output)
if is_csv_output(options.output):
if options.raw:
opts.error("raw mode is not supported with csv output")
if options.compare:
opts.error("comparison mode is not supported with csv output")
if options.specgram:
pdata, bins, t = calc_specgram(datas[0], options.axis)
write_specgram(pdata, bins, t, options.output)
else:
write_frequency_response(datas, options.output)
return
# Draw graph
if options.raw:
fig = plot_accel(datas[0], args[0])
elif options.specgram:
fig = plot_specgram(datas[0], args[0], options.max_freq, options.axis)
elif options.compare:
fig = plot_compare_frequency(datas, args, options.max_freq)
else:
fig = plot_frequency(datas, args, options.max_freq)
# Show graph
if options.output is None:
matplotlib.pyplot.show()
else:
fig.set_size_inches(8, 6)
fig.savefig(options.output)
if __name__ == '__main__':
main()