klipper-dgus/klippy/extras/resonance_tester.py

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# A utility class to test resonances of the printer
#
# Copyright (C) 2020 Dmitry Butyugin <dmbutyugin@google.com>
#
# This file may be distributed under the terms of the GNU GPLv3 license.
import logging, math, os, time
from . import shaper_calibrate
class TestAxis:
def __init__(self, axis=None, vib_dir=None):
if axis is None:
self._name = "axis=%.3f,%.3f" % (vib_dir[0], vib_dir[1])
else:
self._name = axis
if vib_dir is None:
self._vib_dir = (1., 0.) if axis == 'x' else (0., 1.)
else:
s = math.sqrt(sum([d*d for d in vib_dir]))
self._vib_dir = [d / s for d in vib_dir]
def matches(self, chip_axis):
if self._vib_dir[0] and 'x' in chip_axis:
return True
if self._vib_dir[1] and 'y' in chip_axis:
return True
return False
def get_name(self):
return self._name
def get_point(self, l):
return (self._vib_dir[0] * l, self._vib_dir[1] * l)
def _parse_axis(gcmd, raw_axis):
if raw_axis is None:
return None
raw_axis = raw_axis.lower()
if raw_axis in ['x', 'y']:
return TestAxis(axis=raw_axis)
dirs = raw_axis.split(',')
if len(dirs) != 2:
raise gcmd.error("Invalid format of axis '%s'" % (raw_axis,))
try:
dir_x = float(dirs[0].strip())
dir_y = float(dirs[1].strip())
except:
raise gcmd.error(
"Unable to parse axis direction '%s'" % (raw_axis,))
return TestAxis(vib_dir=(dir_x, dir_y))
class VibrationPulseTest:
def __init__(self, config):
self.printer = config.get_printer()
self.gcode = self.printer.lookup_object('gcode')
self.min_freq = config.getfloat('min_freq', 5., minval=1.)
# Defaults are such that max_freq * accel_per_hz == 10000 (max_accel)
self.max_freq = config.getfloat('max_freq', 10000. / 75.,
minval=self.min_freq, maxval=200.)
self.accel_per_hz = config.getfloat('accel_per_hz', 75., above=0.)
self.hz_per_sec = config.getfloat('hz_per_sec', 1.,
minval=0.1, maxval=2.)
self.probe_points = config.getlists('probe_points', seps=(',', '\n'),
parser=float, count=3)
def get_start_test_points(self):
return self.probe_points
def prepare_test(self, gcmd):
self.freq_start = gcmd.get_float("FREQ_START", self.min_freq, minval=1.)
self.freq_end = gcmd.get_float("FREQ_END", self.max_freq,
minval=self.freq_start, maxval=200.)
self.hz_per_sec = gcmd.get_float("HZ_PER_SEC", self.hz_per_sec,
above=0., maxval=2.)
def run_test(self, axis, gcmd):
toolhead = self.printer.lookup_object('toolhead')
X, Y, Z, E = toolhead.get_position()
sign = 1.
freq = self.freq_start
# Override maximum acceleration and acceleration to
# deceleration based on the maximum test frequency
systime = self.printer.get_reactor().monotonic()
toolhead_info = toolhead.get_status(systime)
old_max_accel = toolhead_info['max_accel']
old_max_accel_to_decel = toolhead_info['max_accel_to_decel']
max_accel = self.freq_end * self.accel_per_hz
self.gcode.run_script_from_command(
"SET_VELOCITY_LIMIT ACCEL=%.3f ACCEL_TO_DECEL=%.3f" % (
max_accel, max_accel))
input_shaper = self.printer.lookup_object('input_shaper', None)
if input_shaper is not None and not gcmd.get_int('INPUT_SHAPING', 0):
input_shaper.disable_shaping()
gcmd.respond_info("Disabled [input_shaper] for resonance testing")
else:
input_shaper = None
gcmd.respond_info("Testing frequency %.0f Hz" % (freq,))
while freq <= self.freq_end + 0.000001:
t_seg = .25 / freq
accel = self.accel_per_hz * freq
max_v = accel * t_seg
toolhead.cmd_M204(self.gcode.create_gcode_command(
"M204", "M204", {"S": accel}))
L = .5 * accel * t_seg**2
dX, dY = axis.get_point(L)
nX = X + sign * dX
nY = Y + sign * dY
toolhead.move([nX, nY, Z, E], max_v)
toolhead.move([X, Y, Z, E], max_v)
sign = -sign
old_freq = freq
freq += 2. * t_seg * self.hz_per_sec
if math.floor(freq) > math.floor(old_freq):
gcmd.respond_info("Testing frequency %.0f Hz" % (freq,))
# Restore the original acceleration values
self.gcode.run_script_from_command(
"SET_VELOCITY_LIMIT ACCEL=%.3f ACCEL_TO_DECEL=%.3f" % (
old_max_accel, old_max_accel_to_decel))
# Restore input shaper if it was disabled for resonance testing
if input_shaper is not None:
input_shaper.enable_shaping()
gcmd.respond_info("Re-enabled [input_shaper]")
class ResonanceTester:
def __init__(self, config):
self.printer = config.get_printer()
self.move_speed = config.getfloat('move_speed', 50., above=0.)
self.test = VibrationPulseTest(config)
if not config.get('accel_chip_x', None):
self.accel_chip_names = [('xy', config.get('accel_chip').strip())]
else:
self.accel_chip_names = [
('x', config.get('accel_chip_x').strip()),
('y', config.get('accel_chip_y').strip())]
if self.accel_chip_names[0][1] == self.accel_chip_names[1][1]:
self.accel_chip_names = [('xy', self.accel_chip_names[0][1])]
self.max_smoothing = config.getfloat('max_smoothing', None, minval=0.05)
self.gcode = self.printer.lookup_object('gcode')
self.gcode.register_command("MEASURE_AXES_NOISE",
self.cmd_MEASURE_AXES_NOISE,
desc=self.cmd_MEASURE_AXES_NOISE_help)
self.gcode.register_command("TEST_RESONANCES",
self.cmd_TEST_RESONANCES,
desc=self.cmd_TEST_RESONANCES_help)
self.gcode.register_command("SHAPER_CALIBRATE",
self.cmd_SHAPER_CALIBRATE,
desc=self.cmd_SHAPER_CALIBRATE_help)
self.printer.register_event_handler("klippy:connect", self.connect)
def connect(self):
self.accel_chips = [
(chip_axis, self.printer.lookup_object(chip_name))
for chip_axis, chip_name in self.accel_chip_names]
def _run_test(self, gcmd, axes, helper, raw_name_suffix=None):
toolhead = self.printer.lookup_object('toolhead')
calibration_data = {axis: None for axis in axes}
self.test.prepare_test(gcmd)
test_points = self.test.get_start_test_points()
for point in test_points:
toolhead.manual_move(point, self.move_speed)
if len(test_points) > 1:
gcmd.respond_info(
"Probing point (%.3f, %.3f, %.3f)" % tuple(point))
for axis in axes:
toolhead.wait_moves()
toolhead.dwell(0.500)
if len(axes) > 1:
gcmd.respond_info("Testing axis %s" % axis.get_name())
raw_values = []
for chip_axis, chip in self.accel_chips:
if axis.matches(chip_axis):
aclient = chip.start_internal_client()
raw_values.append((chip_axis, aclient))
# Generate moves
self.test.run_test(axis, gcmd)
for chip_axis, aclient in raw_values:
aclient.finish_measurements()
if raw_name_suffix is not None:
raw_name = self.get_filename(
'raw_data', raw_name_suffix, axis,
point if len(test_points) > 1 else None)
aclient.write_to_file(raw_name)
gcmd.respond_info(
"Writing raw accelerometer data to "
"%s file" % (raw_name,))
if helper is None:
continue
for chip_axis, aclient in raw_values:
if not aclient.has_valid_samples():
raise gcmd.error(
"%s-axis accelerometer measured no data" % (
chip_axis,))
new_data = helper.process_accelerometer_data(aclient)
if calibration_data[axis] is None:
calibration_data[axis] = new_data
else:
calibration_data[axis].add_data(new_data)
return calibration_data
cmd_TEST_RESONANCES_help = ("Runs the resonance test for a specifed axis")
def cmd_TEST_RESONANCES(self, gcmd):
# Parse parameters
axis = _parse_axis(gcmd, gcmd.get("AXIS").lower())
outputs = gcmd.get("OUTPUT", "resonances").lower().split(',')
for output in outputs:
if output not in ['resonances', 'raw_data']:
raise gcmd.error("Unsupported output '%s', only 'resonances'"
" and 'raw_data' are supported" % (output,))
if not outputs:
raise gcmd.error("No output specified, at least one of 'resonances'"
" or 'raw_data' must be set in OUTPUT parameter")
name_suffix = gcmd.get("NAME", time.strftime("%Y%m%d_%H%M%S"))
if not self.is_valid_name_suffix(name_suffix):
raise gcmd.error("Invalid NAME parameter")
csv_output = 'resonances' in outputs
raw_output = 'raw_data' in outputs
# Setup calculation of resonances
if csv_output:
helper = shaper_calibrate.ShaperCalibrate(self.printer)
else:
helper = None
data = self._run_test(
gcmd, [axis], helper,
raw_name_suffix=name_suffix if raw_output else None)[axis]
if csv_output:
csv_name = self.save_calibration_data('resonances', name_suffix,
helper, axis, data)
gcmd.respond_info(
"Resonances data written to %s file" % (csv_name,))
cmd_SHAPER_CALIBRATE_help = (
"Simular to TEST_RESONANCES but suggest input shaper config")
def cmd_SHAPER_CALIBRATE(self, gcmd):
# Parse parameters
axis = gcmd.get("AXIS", None)
if not axis:
calibrate_axes = [TestAxis('x'), TestAxis('y')]
elif axis.lower() not in 'xy':
raise gcmd.error("Unsupported axis '%s'" % (axis,))
else:
calibrate_axes = [TestAxis(axis.lower())]
max_smoothing = gcmd.get_float(
"MAX_SMOOTHING", self.max_smoothing, minval=0.05)
name_suffix = gcmd.get("NAME", time.strftime("%Y%m%d_%H%M%S"))
if not self.is_valid_name_suffix(name_suffix):
raise gcmd.error("Invalid NAME parameter")
# Setup shaper calibration
helper = shaper_calibrate.ShaperCalibrate(self.printer)
calibration_data = self._run_test(gcmd, calibrate_axes, helper)
configfile = self.printer.lookup_object('configfile')
for axis in calibrate_axes:
axis_name = axis.get_name()
gcmd.respond_info(
"Calculating the best input shaper parameters for %s axis"
% (axis_name,))
calibration_data[axis].normalize_to_frequencies()
best_shaper, all_shapers = helper.find_best_shaper(
calibration_data[axis], max_smoothing, gcmd.respond_info)
gcmd.respond_info(
"Recommended shaper_type_%s = %s, shaper_freq_%s = %.1f Hz"
% (axis_name, best_shaper.name,
axis_name, best_shaper.freq))
helper.save_params(configfile, axis_name,
best_shaper.name, best_shaper.freq)
csv_name = self.save_calibration_data(
'calibration_data', name_suffix, helper, axis,
calibration_data[axis], all_shapers)
gcmd.respond_info(
"Shaper calibration data written to %s file" % (csv_name,))
gcmd.respond_info(
"The SAVE_CONFIG command will update the printer config file\n"
"with these parameters and restart the printer.")
cmd_MEASURE_AXES_NOISE_help = (
"Measures noise of all enabled accelerometer chips")
def cmd_MEASURE_AXES_NOISE(self, gcmd):
meas_time = gcmd.get_float("MEAS_TIME", 2.)
raw_values = [(chip_axis, chip.start_internal_client())
for chip_axis, chip in self.accel_chips]
self.printer.lookup_object('toolhead').dwell(meas_time)
for chip_axis, aclient in raw_values:
aclient.finish_measurements()
helper = shaper_calibrate.ShaperCalibrate(self.printer)
for chip_axis, aclient in raw_values:
if not aclient.has_valid_samples():
raise gcmd.error(
"%s-axis accelerometer measured no data" % (chip_axis,))
data = helper.process_accelerometer_data(aclient)
vx = data.psd_x.mean()
vy = data.psd_y.mean()
vz = data.psd_z.mean()
gcmd.respond_info("Axes noise for %s-axis accelerometer: "
"%.6f (x), %.6f (y), %.6f (z)" % (
chip_axis, vx, vy, vz))
def is_valid_name_suffix(self, name_suffix):
return name_suffix.replace('-', '').replace('_', '').isalnum()
def get_filename(self, base, name_suffix, axis=None, point=None):
name = base
if axis:
name += '_' + axis.get_name()
if point:
name += "_%.3f_%.3f_%.3f" % (point[0], point[1], point[2])
name += '_' + name_suffix
return os.path.join("/tmp", name + ".csv")
def save_calibration_data(self, base_name, name_suffix, shaper_calibrate,
axis, calibration_data, all_shapers=None):
output = self.get_filename(base_name, name_suffix, axis)
shaper_calibrate.save_calibration_data(output, calibration_data,
all_shapers)
return output
def load_config(config):
return ResonanceTester(config)