def initialize(self):
self.autostep = Autostep(self.port)
self.autostep.set_step_mode(self.step_mode)
self.autostep.set_fullstep_per_rev(self.fullstep_per_rev)
self.autostep.set_gear_ratio(self.gear_ratio)
self.autostep.set_move_mode_to_jog()
self.autostep.set_jog_mode_params(self.jog_mode_params)
self.autostep.set_max_mode_params(self.max_mode_params)
self.have_sensor = False
plt.title('Constant Acceleration = {:1.2f}(deg/sec**2)'.format(acceleration))
plt.plot(velocity_array, period_list, '-o')
plt.ylabel('period (sec)')
plt.grid('on')
plt.subplot(212)
plt.plot(velocity_array, amplitude_list, '-o')
plt.ylabel('amplitute (deg)')
plt.grid('on')
plt.xlabel('velocity (deg/sec)')
plt.show()
port = '/dev/ttyACM0'
stepper = Autostep(port)
stepper.set_step_mode('STEP_FS_128')
stepper.set_fullstep_per_rev(200)
stepper.set_move_mode_to_jog()
stepper.set_gear_ratio(2.0)
stepper.enable()
stepper.set_position(0.0)
for i, velocity in enumerate(velocity_array):
period, amplitude = get_period_and_amplitude(velocity, acceleration)
print('cnt {}: vel: {:1.2f} per: {:1.2f} amp: {:1.2f}'.format(
i, velocity, period, amplitude))
param = {
from __future__ import print_function
from autostep import Autostep
import time
import numpy
port = '/dev/ttyACM0'
stepper = Autostep(port)
stepper.set_step_mode('STEP_FS_128')
stepper.set_fullstep_per_rev(200)
stepper.set_move_mode_to_jog()
stepper.set_gear_ratio(2.0)
stepper.enable()
stepper.set_position(0.0)
num_steps = 20
min_velo = 10
max_velo = 100
velo_array = numpy.linspace(min_velo, max_velo, num_steps)
for velo in velo_array:
position = stepper.run_with_feedback(velo)
print(velo, position)
time.sleep(0.5)
stepper.set_move_mode_to_jog()
stepper.move_to(0)
stepper.busy_wait()
from __future__ import print_function
from autostep import Autostep
import time
port = '/dev/ttyACM0'
stepper = Autostep(port)
stepper.set_step_mode('STEP_FS_128')
stepper.set_fullstep_per_rev(200)
stepper.set_move_mode_to_jog()
stepper.enable()
stepper.set_position(0.0)
pos_list = [180.0, 360.0, 2 * 360, 4 * 360, 0.0]
for pos in pos_list:
print(pos)
stepper.move_to(pos)
stepper.busy_wait()
time.sleep(2.0)
from __future__ import print_function
from autostep import Autostep
import time
port = '/dev/ttyACM0'
stepper = Autostep(port)
servo_angle = stepper.get_servo_angle()
print('servo_angle: {}'.format(servo_angle))
angle_list_fwd = range(0, 180, 1)
angle_list_rev = angle_list_fwd[::-1]
angle_list = angle_list_fwd + angle_list_rev
while True:
for i, angle in enumerate(angle_list):
print('i: {}, angle: {}'.format(i, angle))
stepper.set_servo_angle(angle)
time.sleep(0.01)
from __future__ import print_function from autostep import Autostep import time port = '/dev/ttyACM0' stepper = Autostep(port) stepper.run(100) time.sleep(2.0) stepper.soft_stop()
from __future__ import print_function from autostep import Autostep import time port = '/dev/ttyACM0' stepper = Autostep(port) stepper.enable() stepper.busy_wait()
from __future__ import print_function
import time
import numpy as np
from autostep import Autostep
port = '/dev/ttyACM0'
dt = 0.5
velo_array = np.linspace(100, 500, 10)
stepper = Autostep(port)
stepper.set_step_mode('STEP_FS_128')
stepper.set_fullstep_per_rev(200)
stepper.set_move_mode_to_max()
stepper.enable()
stepper.run(0.0)
time.sleep(dt)
for i, velo in enumerate(velo_array):
print(i, velo)
stepper.run(velo)
time.sleep(dt)
stepper.run(0.0)
import time
import scipy
import matplotlib.pyplot as plt
from autostep import Autostep
from autostep import AsynchronousTrajectory
from autostep.utility import get_ramp
port = '/dev/ttyACM0'
stepper = Autostep(port)
stepper.set_step_mode('STEP_FS_16')
stepper.set_fullstep_per_rev(200)
stepper.set_gear_ratio(1.0)
stepper.set_jog_mode_params({'speed': 200, 'accel': 1000, 'decel': 1000})
stepper.set_max_mode_params({'speed': 1000, 'accel': 30000, 'decel': 30000})
stepper.set_move_mode_to_jog()
stepper.enable()
traj = AsynchronousTrajectory(stepper)
dt = traj.dt
p0 = 0.0
p1 = 360.0
vmax = 100.0
accel = 50.0
pos = get_ramp(p0,p1,vmax,accel,dt)
t = scipy.arange(pos.shape[0])*dt
class AutostepNode(object):
def __init__(self, port='/dev/ttyACM0'):
# Parameters
self.port = rospy.get_param('port', '/dev/ttyACM0')
self.step_mode = rospy.get_param('step_mode', 'STEP_FS_128')
self.fullstep_per_rev = rospy.get_param('fullstep_per_rev', 200)
self.gear_ratio = rospy.get_param('gear_ratio', 2.0)
self.tracking_mode_gain = rospy.get_param('tracking_mode_gain', 5.0)
self.tracking_mode_absolute = rospy.get_param('tracking_mode_absolute',
True)
self.max_mode_params = rospy.get_param('max_mode_params', {
'speed': 1000,
'accel': 10000,
'decel': 10000
})
self.jog_mode_params = rospy.get_param('max_mode_params', {
'speed': 400,
'accel': 800,
'decel': 800
})
# Tracking mode state data
self.tracking_mode_is_first = False
self.tracking_mode_first_update_t = 0.0
self.tracking_mode_last_update_t = 0.0
self.tracking_mode_position = 0.0
self.tracking_mode_velocity = 0.0
self.tracking_mode_position_start = 0.0
self.initialize()
self.enable()
rospy.init_node('autostep')
self.motion_pub = rospy.Publisher('motion_data',
MotionData,
queue_size=10)
self.tracking_sub = rospy.Subscriber('tracking_data', TrackingData,
self.on_tracking_data_callback)
self.command_srv_table = {
'run': self.on_run_command,
'enable': self.on_enable_command,
'release': self.on_release_command,
'is_busy': self.on_is_busy_command,
'was_stopped': self.on_was_stopped_command,
'move_to': self.on_move_to_command,
'move_by': self.on_move_by_command,
'soft_stop': self.on_soft_stop_command,
'set_position': self.on_set_position_command,
'get_position': self.on_get_position_command,
'set_move_mode': self.on_set_move_mode_command,
'get_jog_mode_params': self.on_get_jog_mode_params,
'set_jog_mode_params': self.on_set_jog_mode_params,
'get_max_mode_params': self.on_get_max_mode_params,
'set_max_mode_params': self.on_set_max_mode_params,
'get_params': self.on_get_params_command,
'print_params': self.on_print_params_command,
'sinusoid': self.on_sinusoid_command,
'move_to_sinusoid_start': self.on_move_to_sinusoid_start_command,
'run_trajectory': self.on_run_trajectory_command,
'enable_tracking_mode': self.on_enable_tracking_mode_command,
'disable_tracking_mode': self.on_disable_tracking_mode_command,
}
self.command_srv = rospy.Service('command', Command,
self.command_srv_callback)
self.lock = threading.Lock()
self.tracking_mode_enabled = False
self.running_motion_cmd = False
self.stopped_flag = False
def initialize(self):
self.autostep = Autostep(self.port)
self.autostep.set_step_mode(self.step_mode)
self.autostep.set_fullstep_per_rev(self.fullstep_per_rev)
self.autostep.set_gear_ratio(self.gear_ratio)
self.autostep.set_move_mode_to_jog()
self.autostep.set_jog_mode_params(self.jog_mode_params)
self.autostep.set_max_mode_params(self.max_mode_params)
self.have_sensor = False
def enable(self):
self.autostep.enable()
self.enabled_flag = True
def release(self):
self.autostep.release()
self.enabled_flag = False
def command_srv_callback(self, req):
args_dict = {}
if req.args_json != '':
args_json = req.args_json.replace('\{', '{')
args_json = args_json.replace('\}', '}')
args_dict = json.loads(args_json)
ok = False
try:
command_method = self.command_srv_table[req.command]
ok = True
except KeyError:
rsp_dict = {'success': False, 'message': 'unknown command'}
if ok:
rsp_dict = command_method(args_dict)
return CommandResponse(json.dumps(rsp_dict))
def on_run_command(self, args_dict):
self.stopped_flag = False
ok = False
velocity = 0.0
rsp_dict = {}
try:
velocity = args_dict['velocity']
rsp_dict['success'] = True
rsp_dict['message'] = ''
ok = True
except KeyError:
rsp_dict['success'] = False
rsp_dict['message'] = 'velocity argument missing'
if ok:
self.autostep.run(velocity)
return rsp_dict
def on_enable_command(self, args_dict):
self.enable()
return {'success': True, 'message': ''}
def on_release_command(self, args_dict):
self.release()
return {'success': True, 'message': ''}
def on_move_to_command(self, args_dict):
self.stopped_flag = False
ok = False
position = 0.0
rsp_dict = {}
try:
position = args_dict['position']
rsp_dict['success'] = True
rsp_dict['message'] = ''
ok = True
except KeyError:
rsp_dict['success'] = False
rsp_dict['message'] = 'position argument missing'
if ok:
self.autostep.move_to(position)
return rsp_dict
def on_move_by_command(self, args_dict):
self.stopped_flag = False
ok = False
position = 0.0
rsp_dict = {}
try:
step = args_dict['step']
rsp_dict['success'] = True
rsp_dict['message'] = ''
ok = True
except KeyError:
rsp_dict['success'] = False
rsp_dict['message'] = 'step argument missing'
if ok:
self.autostep.move_by(step)
return rsp_dict
def on_soft_stop_command(self, args_dict):
self.stopped_flag = True
with self.lock:
self.tracking_mode_enabled = False
self.running_motion_cmd = False
self.autostep.soft_stop()
return {'success': True, 'message': ''}
def on_is_busy_command(self, args_dict):
is_busy = self.autostep.is_busy()
if is_busy or self.running_motion_cmd or self.tracking_mode_enabled:
return {'success': True, 'message': '', 'is_busy': True}
else:
return {'success': True, 'message': '', 'is_busy': False}
def on_was_stopped_command(self, args_dict):
return {
'success': True,
'message': '',
'was_stopped': self.stopped_flag
}
def on_get_position_command(self, args_dict):
position = self.autostep.get_position()
return {'success': True, 'message': '', 'position': position}
def on_set_position_command(self, args_dict):
ok = False
position = 0.0
rsp_dict = {}
try:
position = args_dict['position']
rsp_dict['success'] = True
rsp_dict['message'] = ''
ok = True
except KeyError:
rsp_dict['success'] = False
rsp_dict['message'] = 'position argument missing'
if ok:
self.autostep.set_position(position)
return rsp_dict
def on_sinusoid_command(self, args_dict):
self.stopped_flag = False
ok = True
param = {}
rsp_dict = {'message': ''}
param_keys = ['amplitude', 'period', 'phase', 'offset', 'num_cycle']
for key in param_keys:
try:
param[key] = args_dict[key]
except KeyError:
ok = False
if len(rsp_dict['message']) > 0:
rsp_dict['message'] += ', '
rsp_dict['message'] += '{} argument missing'.format(key)
if ok:
def motion_data_callback(elapsed_time, position, setpoint, sensor):
if not self.have_sensor:
sensor = 0.0
header = std_msgs.msg.Header()
header.stamp = rospy.Time.now()
self.motion_pub.publish(
MotionData(header, elapsed_time, position, setpoint,
sensor))
def motion_done_callback():
with self.lock:
self.autostep.set_move_mode_to_jog()
self.autostep.run(0.0)
self.running_motion_cmd = False
# Launch sinusoid in separate thread
thread_args = [param, motion_data_callback, motion_done_callback]
motion_thread = threading.Thread(target=self.autostep.sinusoid,
args=thread_args)
with self.lock:
self.running_motion_cmd = True
motion_thread.start()
rsp_dict['success'] = True
else:
rsp_dict['success'] = False
return rsp_dict
def on_move_to_sinusoid_start_command(self, args_dict):
ok = True
param = {}
rsp_dict = {'message': ''}
param_keys = ['amplitude', 'period', 'phase', 'offset', 'num_cycle']
for key in param_keys:
try:
param[key] = args_dict[key]
except KeyError:
ok = False
if len(rsp_dict['message']) > 0:
rsp_dict['message'] += ', '
rsp_dict['message'] += '{} argument missing'.format(key)
if ok:
self.autostep.move_to_sinusoid_start(param)
rsp_dict['success'] = True
else:
rsp_dict['success'] = False
return rsp_dict
def on_set_move_mode_command(self, args_dict):
ok = False
mode = ''
rsp_dict = {}
try:
mode = args_dict['mode']
rsp_dict['success'] = True
rsp_dict['message'] = ''
ok = True
except KeyError:
rsp_dict['success'] = False
rsp_dict['message'] = 'mode argument missing'
if ok:
if mode == 'max':
self.autostep.set_move_mode_to_max()
elif mode == 'jog':
self.autostep.set_move_mode_to_jog()
else:
rsp_dict['success'] = False
rsp_dict['message'] = "mode must be 'max' or 'jog'"
return rsp_dict
def on_get_jog_mode_params(self, args_dict):
jog_mode_params = self.autostep.get_jog_mode_params()
rsp_dict = {'success': True, 'message': '', 'params': jog_mode_params}
return rsp_dict
def on_set_jog_mode_params(self, args_dict):
ok = False
rsp_dict = {}
try:
jog_mode_params = args_dict['params']
rsp_dict['success'] = True
rsp_dict['message'] = ''
ok = True
except KeyError:
rsp_dict['success'] = False
rsp_dict['message'] = 'position argument missing'
if ok:
try:
self.autostep.set_jog_mode_params(jog_mode_params)
self.jog_mode_params = jog_mode_params
except AutostepException:
rsp_dict['success'] = False
rsp_dict['message'] = 'setting jog mode parameters failed'
return rsp_dict
def on_get_max_mode_params(self, args_dict):
max_mode_params = self.autostep.get_max_mode_params()
rsp_dict = {'success': True, 'message': '', 'params': max_mode_params}
return rsp_dict
def on_set_max_mode_params(self, args_dict):
ok = False
rsp_dict = {}
try:
max_mode_params = args_dict['params']
rsp_dict['success'] = True
rsp_dict['message'] = ''
ok = True
except KeyError:
rsp_dict['success'] = False
rsp_dict['message'] = 'position argument missing'
if ok:
try:
self.autostep.set_max_mode_params(max_mode_params)
self.max_mode_params = max_mode_params
except AutostepException:
rsp_dict['success'] = False
rsp_dict['message'] = 'setting max mode parameters failed'
return rsp_dict
def on_print_params_command(self, args_dict):
self.autostep.print_params()
return {'success': True, 'message': ''}
def on_print_params_command(self, args_dict):
self.autostep.print_params()
return {'success': True, 'message': ''}
def on_get_params_command(self, args_dict):
params = self.autostep.get_params()
return {'success': True, 'message': '', 'params': params}
def on_run_trajectory_command(self, args_dict):
self.stopped_flag = False
rsp_dict = {}
try:
position = args_dict['position']
except KeyError:
rsp_dict['success'] = False
rsp_dict['message'] = 'position (array) argument missing'
return rsp_dict
position = scipy.array(position)
dt = Autostep.TrajectoryDt
velocity = scipy.zeros(position.shape)
velocity[1:] = (position[1:] - position[:-1]) / dt
t = dt * scipy.arange(0, position.shape[0])
t_done = t[-1]
position_func = scipy.interpolate.interp1d(t, position, kind='linear')
velocity_func = scipy.interpolate.interp1d(t, velocity, kind='linear')
def motion_data_callback(elapsed_time, position, setpoint):
header = std_msgs.msg.Header()
header.stamp = rospy.Time.now()
self.motion_pub.publish(
MotionData(header, elapsed_time, position, setpoint, 0.0))
def motion_done_callback():
with self.lock:
self.autostep.set_move_mode_to_jog()
self.autostep.run(0.0)
self.running_motion_cmd = False
# Launch sinusoid in separate thread
thread_args = [
t_done, position_func, velocity_func, False, motion_data_callback,
motion_done_callback
]
motion_thread = threading.Thread(target=self.autostep.run_trajectory,
args=thread_args)
with self.lock:
self.running_motion_cmd = True
motion_thread.start()
return {'success': True, 'message': ''}
def on_enable_tracking_mode_command(self, args_dict):
self.stopped_flag = False
with self.lock:
self.autostep.run(0.0)
self.autostep.set_move_mode_to_max()
self.tracking_mode_enabled = True
self.tracking_mode_is_first = True
return {'success': True, 'message': ''}
def on_disable_tracking_mode_command(self, args_dict):
with self.lock:
self.tracking_mode_enabled = False
self.autostep.set_move_mode_to_jog()
self.autostep.run(0.0)
return {'success': True, 'message': ''}
def on_tracking_data_callback(self, msg):
with self.lock:
tracking_mode_enabled = self.tracking_mode_enabled
if self.tracking_mode_enabled:
if self.tracking_mode_is_first:
self.tracking_mode_is_first = False
self.tracking_mode_first_update_t = rospy.get_time()
self.tracking_mode_last_update_t = self.tracking_mode_first_update_t
self.tracking_mode_position_start = self.autostep.get_position(
)
self.tracking_mode_position = self.tracking_mode_position_start
predicted_position = self.tracking_mode_position
self.tracking_mode_velocity = 0.0
else:
current_time = rospy.get_time()
update_dt = current_time - self.tracking_mode_last_update_t
predicted_position = self.tracking_mode_position + update_dt * self.tracking_mode_velocity
if self.tracking_mode_absolute:
position_error = msg.position - predicted_position
else:
position_error = msg.position - (
predicted_position - self.tracking_mode_position_start)
new_velocity = self.tracking_mode_gain * position_error + msg.velocity
true_position = self.autostep.run_with_feedback(new_velocity)
self.tracking_mode_position = true_position
self.tracking_mode_velocity = new_velocity
self.tracking_mode_last_update_t = current_time
#rospy.logwarn(position_error)
header = std_msgs.msg.Header()
header.stamp = rospy.Time.now()
elapsed_time = self.tracking_mode_last_update_t - self.tracking_mode_first_update_t
self.motion_pub.publish(
MotionData(header, elapsed_time, self.tracking_mode_position,
predicted_position, 0.0))
def run(self):
while not rospy.is_shutdown():
rospy.sleep(0.1)
self.autostep.run(0.0)
from __future__ import print_function
from autostep import Autostep
port = '/dev/ttyACM0'
stepper = Autostep(port)
stepper.set_jog_mode_params({'speed': 500, 'accel': 1000, 'decel': 1000})
stepper.set_max_mode_params({'speed': 2000, 'accel': 2000, 'decel': 2000})
stepper.print_params()
from __future__ import print_function from autostep import Autostep import time port = '/dev/ttyACM0' stepper = Autostep(port) stepper.release() stepper.busy_wait()
vel_array = numpy.array(vel_list)
plt.subplot(211)
plt.plot(t_array,pos_array)
plt.ylabel('angle (deg)')
plt.grid('on')
plt.subplot(212)
plt.plot(t_array,vel_array)
plt.ylabel('velocity (deg/sec)')
plt.xlabel('time (sec)')
plt.grid('on')
plt.show()
port = '/dev/ttyACM0'
stepper = Autostep(port)
stepper.set_step_mode('STEP_FS_128')
stepper.set_fullstep_per_rev(200)
stepper.set_move_mode_to_jog()
stepper.set_gear_ratio(2.0)
stepper.enable()
stepper.set_position(0.0)
t, pos, pos_setpt = stepper.run_trajectory(t_done,position_func,velocity_func)
plt.plot(t,pos,'b')
plt.plot(t,pos_setpt, '.r')
plt.xlabel('time (sec)')
plt.ylabel('angle (deg)')
plt.grid('on')
plt.show()
import numpy as np
import matplotlib.pyplot as plt
from autostep import Autostep
port = '/dev/ttyACM0'
stepper = Autostep(port)
stepper.set_step_mode('STEP_FS_128')
stepper.set_fullstep_per_rev(200)
stepper.set_move_mode_to_max()
stepper.enable()
param = {
'amplitude': 180.0,
'period': 5.0,
'phase': 90.0,
'offset': 0.0,
'num_cycle': 2
}
vel = param['amplitude'] * (2.0 * np.pi / param['period'])
acc = param['amplitude'] * (2.0 * np.pi / param['period'])**2
print('vel: {0:1.2f}'.format(vel))
print('acc: {0:1.2f}'.format(acc))
data = stepper.sinusoid(param)
stepper.busy_wait()
data = np.array(data)
tsec = data[:, 0]
angl = data[:, 1]
port = '/dev/ttyACM0'
gain = 5.0
sleep_dt = 0.005
step_period = 4.0
step_amplitude = 45.0
rc_period = 8.0
rc_amplitude = 80.0
t_end = 2 * step_period
pos_set_func, vel_set_func, rc_set_func = get_kinematics_func(
step_period, step_amplitude, rc_period, rc_amplitude)
dev = Autostep(port)
dev.set_step_mode('STEP_FS_64')
dev.set_fullstep_per_rev(200)
dev.set_gear_ratio(1.0)
dev.set_jog_mode_params({'speed': 200, 'accel': 1000, 'decel': 1000})
dev.set_max_mode_params({'speed': 1000, 'accel': 30000, 'decel': 30000})
dev.set_move_mode_to_max()
dev.enable()
dev.print_params()
dev.run(0.0)
t_start = time.time()
t_last = t_start
t_list = []
pos_tru_list = []