def prepare(self, odrive: ODriveComponent, uart_num: int, tx_gpio: list, rx_gpio: list, logger: Logger): logger.debug('Enabling UART {}...'.format(chr(ord('A') + uart_num))) # GPIOs might be in use by something other than UART and some components # might be configured so that they would fail in the later test. odrive.disable_mappings() odrive.handle.config.enable_uart_a = False odrive.handle.config.uart_a_baudrate = 115200 odrive.handle.config.enable_uart_b = False odrive.handle.config.uart_b_baudrate = 115200 odrive.handle.config.enable_uart_c = False odrive.handle.config.uart_c_baudrate = 115200 if uart_num == 0: odrive.handle.config.enable_uart_a = True mode = GPIO_MODE_UART_A elif uart_num == 1: odrive.handle.config.enable_uart_b = True mode = GPIO_MODE_UART_B elif uart_num == 2: odrive.handle.config.enable_uart_c = True mode = GPIO_MODE_UART_C else: raise TestFailed(f"unknown UART: {uart_num}") setattr(odrive.handle.config, f'gpio{tx_gpio}_mode', mode) setattr(odrive.handle.config, f'gpio{rx_gpio}_mode', mode) odrive.save_config_and_reboot()
def prepare(self, odrive: ODriveComponent, canbus: CanInterfaceComponent, axis_ctx: ODriveAxisComponent, motor_ctx: MotorComponent, enc_ctx: EncoderComponent, node_id: int, extended_id: bool, logger: Logger): # Make sure there are no funny configurations active logger.debug('Setting up clean configuration...') axis_ctx.parent.erase_config_and_reboot() axis_ctx.parent.handle.config.enable_brake_resistor = True axis_ctx.parent.save_config_and_reboot() # run calibration axis_ctx.handle.requested_state = AXIS_STATE_FULL_CALIBRATION_SEQUENCE while axis_ctx.handle.requested_state != AXIS_STATE_UNDEFINED or axis_ctx.handle.current_state != AXIS_STATE_IDLE: time.sleep(1) test_assert_eq(axis_ctx.handle.current_state, AXIS_STATE_IDLE) test_assert_no_error(axis_ctx) # Return a context that can be used in a with-statement. class safe_terminator(): def __enter__(self): pass def __exit__(self, exc_type, exc_val, exc_tb): logger.debug('clearing config...') axis_ctx.handle.requested_state = AXIS_STATE_IDLE time.sleep(0.005) axis_ctx.parent.erase_config_and_reboot() return safe_terminator()
def run_test(self, axis0_ctx: ODriveAxisComponent, motor0_ctx: MotorComponent, enc0_ctx: EncoderComponent, axis1_ctx: ODriveAxisComponent, motor1_ctx: MotorComponent, enc1_ctx: EncoderComponent, logger: Logger): with SafeTerminator(logger, axis0_ctx, axis1_ctx): nominal_rps = 3.0 nominal_vel = nominal_rps logger.debug( f'Testing closed loop velocity control at {nominal_rps} rounds/s...' ) axis0_ctx.handle.controller.config.control_mode = CONTROL_MODE_VELOCITY_CONTROL axis0_ctx.handle.controller.config.input_mode = INPUT_MODE_PASSTHROUGH axis0_ctx.handle.controller.input_vel = 0 request_state(axis0_ctx, AXIS_STATE_CLOSED_LOOP_CONTROL) axis0_ctx.handle.controller.config.vel_limit = nominal_vel axis0_ctx.handle.controller.config.vel_limit_tolerance = 2 axis0_ctx.handle.controller.input_vel = nominal_vel data = record_log(lambda: [ axis0_ctx.handle.encoder.vel_estimate, axis1_ctx.handle.encoder .vel_estimate, axis0_ctx.handle.encoder.pos_estimate ], duration=5.0) test_assert_no_error(axis0_ctx) test_assert_eq(axis0_ctx.handle.current_state, AXIS_STATE_CLOSED_LOOP_CONTROL) request_state(axis0_ctx, AXIS_STATE_IDLE) # axis0: encoder.vel_estimate slope, offset, fitted_curve = fit_line(data[:, (0, 1)]) test_assert_eq(slope, 0.0, range=nominal_vel * 0.02) test_assert_eq(offset, nominal_vel, accuracy=0.05) test_curve_fit(data[:, (0, 1)], fitted_curve, max_mean_err=nominal_vel * 0.3, inlier_range=nominal_vel * 0.5, max_outliers=len(data[:, 0]) * 0.1) # axis1: encoder.vel_estimate slope, offset, fitted_curve = fit_line(data[:, (0, 2)]) test_assert_eq(slope, 0.0, range=nominal_vel * 0.02) test_assert_eq(offset, -nominal_vel, accuracy=0.05) test_curve_fit(data[:, (0, 2)], fitted_curve, max_mean_err=nominal_vel * 0.3, inlier_range=nominal_vel * 0.5, max_outliers=len(data[:, 0]) * 0.1) # axis0: encoder.pos_estimate slope, offset, fitted_curve = fit_line(data[:, (0, 3)]) test_assert_eq(slope, nominal_vel, accuracy=0.01) test_curve_fit(data[:, (0, 3)], fitted_curve, max_mean_err=nominal_vel * 0.01, inlier_range=nominal_vel * 0.1, max_outliers=len(data[:, 0]) * 0.01)
def run_with_values(self, odrive: ODriveComponent, values: list, logger: Logger): logger.debug("storing configuration and rebooting...") for value in values: odrive.handle.config.brake_resistance = value odrive.save_config_and_reboot() odrive.prepare(logger) logger.debug("verifying configuration after reboot...") test_assert_eq(odrive.handle.config.brake_resistance, values[-1], accuracy=0.01)
def run_test(self, axis_ctx: ODriveAxisComponent, motor_ctx: MotorComponent, enc_ctx: EncoderComponent, logger: Logger): with self.prepare(axis_ctx, motor_ctx, enc_ctx, logger): nominal_rps = 6.0 nominal_vel = float(enc_ctx.yaml['cpr']) * nominal_rps # Accept a bit of noise on Ibus axis_ctx.parent.handle.config.dc_max_negative_current = -0.2 logger.debug(f'Brake control test from {nominal_rps} rounds/s...') axis_ctx.handle.controller.config.vel_limit = float( enc_ctx.yaml['cpr']) * 10.0 # max 10 rps axis_ctx.handle.controller.config.control_mode = CTRL_MODE_VELOCITY_CONTROL axis_ctx.handle.controller.config.input_mode = INPUT_MODE_PASSTHROUGH request_state(axis_ctx, AXIS_STATE_CLOSED_LOOP_CONTROL) # accelerate... axis_ctx.handle.controller.input_vel = nominal_vel time.sleep(1.0) test_assert_no_error(axis_ctx) # ... and brake axis_ctx.handle.controller.input_vel = 0 time.sleep(1.0) test_assert_no_error(axis_ctx) # once more, but this time without brake resistor axis_ctx.parent.handle.config.brake_resistance = 0 # accelerate... axis_ctx.handle.controller.input_vel = nominal_vel time.sleep(1.0) test_assert_no_error(axis_ctx) # ... and brake axis_ctx.handle.controller.input_vel = 0 # this should fail almost instantaneously time.sleep(0.1) test_assert_eq( axis_ctx.handle.error, errors.axis.ERROR_MOTOR_DISARMED | errors.axis.ERROR_BRAKE_RESISTOR_DISARMED) test_assert_eq(axis_ctx.handle.motor.error, errors.motor.ERROR_DC_BUS_OVER_REGEN_CURRENT)
def run_test(self, enc: ODriveEncoderComponent, teensy: TeensyComponent, teensy_gpio_a: TeensyGpio, teensy_gpio_b: TeensyGpio, logger: Logger): true_cps = 8192*0.5 # counts per second generated by the virtual encoder code = teensy_incremental_encoder_emulation_code.replace("{enc_a}", str(teensy_gpio_a.num)).replace("{enc_b}", str(teensy_gpio_b.num)) teensy.compile_and_program(code) if enc.handle.config.mode != ENCODER_MODE_INCREMENTAL: enc.handle.config.mode = ENCODER_MODE_INCREMENTAL enc.parent.save_config_and_reboot() else: time.sleep(1.0) # wait for PLLs to stabilize enc.handle.config.bandwidth = 1000 logger.debug("testing with 8192 CPR...") self.run_generic_encoder_test(enc.handle, 8192, true_cps / 8192) logger.debug("testing with 65536 CPR...") self.run_generic_encoder_test(enc.handle, 65536, true_cps / 65536) enc.handle.config.cpr = 8192
def prepare(self, axis_ctx: ODriveAxisComponent, motor_ctx: MotorComponent, enc_ctx: EncoderComponent, logger: Logger): # Make sure there are no funny configurations active logger.debug('Setting up clean configuration...') axis_ctx.parent.erase_config_and_reboot() # Set motor calibration values axis_ctx.handle.motor.config.phase_resistance = float( motor_ctx.yaml['phase-resistance']) axis_ctx.handle.motor.config.phase_inductance = float( motor_ctx.yaml['phase-inductance']) axis_ctx.handle.motor.config.pre_calibrated = True # Set calibration settings axis_ctx.handle.motor.config.direction = 0 axis_ctx.handle.encoder.config.use_index = False axis_ctx.handle.encoder.config.calib_scan_omega = 12.566 # 2 electrical revolutions per second axis_ctx.handle.encoder.config.calib_scan_distance = 50.265 # 8 revolutions axis_ctx.handle.encoder.config.bandwidth = 1000 axis_ctx.handle.clear_errors() logger.debug('Calibrating encoder offset...') request_state(axis_ctx, AXIS_STATE_ENCODER_OFFSET_CALIBRATION) time.sleep(9) # actual calibration takes 8 seconds test_assert_eq(axis_ctx.handle.current_state, AXIS_STATE_IDLE) test_assert_no_error(axis_ctx) # Return a context that can be used in a with-statement. class safe_terminator(): def __enter__(self): pass def __exit__(self, exc_type, exc_val, exc_tb): logger.debug('clearing config...') axis_ctx.handle.requested_state = AXIS_STATE_IDLE time.sleep(0.005) axis_ctx.parent.erase_config_and_reboot() return safe_terminator()
def run_with_values(self, odrive: ODriveComponent, values: list, logger: Logger): logger.debug("storing configuration and rebooting...") for value in values: odrive.handle.config.brake_resistance = value odrive.handle.save_configuration() try: odrive.handle.reboot() except fibre.ChannelBrokenException: pass # this is expected odrive.handle = None time.sleep(2) odrive.prepare(logger) logger.debug("verifying configuration after reboot...") test_assert_eq(odrive.handle.config.brake_resistance, values[-1], accuracy=0.01)
def run_test(self, odrive: ODriveComponent, canbus: CanInterfaceComponent, axis_ctx: ODriveAxisComponent, motor_ctx: MotorComponent, enc_ctx: EncoderComponent, node_id: int, extended_id: bool, logger: Logger): # this test is a sanity check to make sure that closed loop operation works # actual testing of closed loop functionality should be tested using closed_loop_test.py with self.prepare(odrive, canbus, axis_ctx, motor_ctx, enc_ctx, node_id, extended_id, logger): def my_cmd(cmd_name, **kwargs): command(canbus.handle, node_id, extended_id, cmd_name, **kwargs) def my_req(cmd_name, **kwargs): return asyncio.run( request(canbus.handle, node_id, extended_id, cmd_name, **kwargs)) def fence(): my_req('get_vbus_voltage' ) # fence to ensure the CAN command was sent def flush_rx(): while not canbus.handle.recv(timeout=0) is None: pass axis_ctx.handle.config.enable_watchdog = False odrive.handle.clear_errors() axis_ctx.handle.config.can.node_id = node_id axis_ctx.handle.config.can.is_extended = extended_id time.sleep(0.1) my_cmd('set_node_id', node_id=node_id + 20) flush_rx() asyncio.run( request(canbus.handle, node_id + 20, extended_id, 'get_vbus_voltage')) test_assert_eq(axis_ctx.handle.config.can.node_id, node_id + 20) # Reset node ID to default value command(canbus.handle, node_id + 20, extended_id, 'set_node_id', node_id=node_id) fence() test_assert_eq(axis_ctx.handle.config.can.node_id, node_id) vel_limit = 15.0 nominal_vel = 10.0 axis_ctx.handle.controller.config.vel_limit = vel_limit axis_ctx.handle.motor.config.current_lim = 20.0 my_cmd('set_requested_state', requested_state=AXIS_STATE_CLOSED_LOOP_CONTROL) fence() test_assert_eq(axis_ctx.handle.current_state, AXIS_STATE_CLOSED_LOOP_CONTROL) test_assert_no_error(axis_ctx) start_pos = axis_ctx.handle.encoder.pos_estimate # position test logger.debug('Position control test') my_cmd('set_controller_modes', control_mode=CONTROL_MODE_POSITION_CONTROL, input_mode=INPUT_MODE_PASSTHROUGH ) # position control, passthrough fence() my_cmd('set_input_pos', input_pos=1.0, vel_ff=0, torque_ff=0) fence() test_assert_eq(axis_ctx.handle.controller.input_pos, 1.0, range=0.1) time.sleep(2) test_assert_eq(axis_ctx.handle.encoder.pos_estimate, start_pos + 1.0, range=0.1) my_cmd('set_input_pos', input_pos=0, vel_ff=0, torque_ff=0) fence() time.sleep(2) test_assert_no_error(axis_ctx) # velocity test logger.debug('Velocity control test') my_cmd('set_controller_modes', control_mode=CONTROL_MODE_VELOCITY_CONTROL, input_mode=INPUT_MODE_PASSTHROUGH ) # velocity control, passthrough fence() my_cmd('set_input_vel', input_vel=nominal_vel, torque_ff=0) fence() time.sleep(5) test_assert_eq( axis_ctx.handle.encoder.vel_estimate, nominal_vel, range=nominal_vel * 0.05) # big range here due to cogging and other issues my_cmd('set_input_vel', input_vel=0, torque_ff=0) fence() time.sleep(2) test_assert_no_error(axis_ctx) # torque test logger.debug('Torque control test') my_cmd('set_controller_modes', control_mode=CONTROL_MODE_TORQUE_CONTROL, input_mode=INPUT_MODE_PASSTHROUGH ) # torque control, passthrough fence() my_cmd('set_input_torque', input_torque=0.5) fence() time.sleep(5) test_assert_eq(axis_ctx.handle.controller.input_torque, 0.5, range=0.1) my_cmd('set_input_torque', input_torque=0) fence() time.sleep(2) test_assert_no_error(axis_ctx) # go back to idle my_cmd('set_requested_state', requested_state=AXIS_STATE_IDLE) fence() test_assert_eq(axis_ctx.handle.current_state, AXIS_STATE_IDLE)
def run_test(self, axis_ctx: ODriveAxisComponent, motor_ctx: MotorComponent, enc_ctx: EncoderComponent, logger: Logger): with self.prepare(axis_ctx, motor_ctx, enc_ctx, logger): max_rps = 20.0 max_vel = float(enc_ctx.yaml['cpr']) * max_rps absolute_max_vel = max_vel * 1.2 max_current = 3.0 axis_ctx.handle.controller.config.vel_gain /= 10 # reduce the slope to make it easier to see what's going on vel_gain = axis_ctx.handle.controller.config.vel_gain logger.debug(f'vel gain is {vel_gain}') axis_ctx.handle.controller.config.vel_limit = max_vel axis_ctx.handle.controller.config.vel_limit_tolerance = inf # disable hard limit on velocity axis_ctx.handle.motor.config.current_lim = max_current axis_ctx.handle.controller.config.control_mode = CTRL_MODE_CURRENT_CONTROL # Returns the expected limited setpoint for a given velocity and current def get_expected_setpoint(input_setpoint, velocity): return clamp( clamp(input_setpoint, (velocity + max_vel) * -vel_gain, (velocity - max_vel) * -vel_gain), -max_current, max_current) def data_getter(): # sample velocity twice to avoid systematic bias velocity0 = axis_ctx.handle.encoder.vel_estimate current_setpoint = axis_ctx.handle.motor.current_control.Iq_setpoint velocity1 = axis_ctx.handle.encoder.vel_estimate velocity = ((velocity0 + velocity1) / 2) # Abort immediately if the absolute limits are exceeded test_assert_within(current_setpoint, -max_current, max_current) test_assert_within(velocity, -absolute_max_vel, absolute_max_vel) return input_current, velocity, current_setpoint, get_expected_setpoint( input_current, velocity) axis_ctx.handle.controller.input_current = input_current = 0.0 request_state(axis_ctx, AXIS_STATE_CLOSED_LOOP_CONTROL) # Move the system around its operating envelope axis_ctx.handle.controller.input_current = input_current = 2.0 dataA = record_log(data_getter, duration=1.0) axis_ctx.handle.controller.input_current = input_current = -2.0 dataA = np.concatenate( [dataA, record_log(data_getter, duration=1.0)]) axis_ctx.handle.controller.input_current = input_current = 4.0 dataA = np.concatenate( [dataA, record_log(data_getter, duration=1.0)]) axis_ctx.handle.controller.input_current = input_current = -4.0 dataA = np.concatenate( [dataA, record_log(data_getter, duration=1.0)]) # Shrink the operating envelope while motor is moving faster than the envelope allows max_rps = 5.0 max_vel = float(enc_ctx.yaml['cpr']) * max_rps axis_ctx.handle.controller.config.vel_limit = max_vel # Move the system around its operating envelope axis_ctx.handle.controller.input_current = input_current = 2.0 dataB = record_log(data_getter, duration=1.0) axis_ctx.handle.controller.input_current = input_current = -2.0 dataB = np.concatenate( [dataB, record_log(data_getter, duration=1.0)]) axis_ctx.handle.controller.input_current = input_current = 4.0 dataB = np.concatenate( [dataB, record_log(data_getter, duration=1.0)]) axis_ctx.handle.controller.input_current = input_current = -4.0 dataB = np.concatenate( [dataB, record_log(data_getter, duration=1.0)]) # Try the shrink maneuver again at positive velocity axis_ctx.handle.controller.config.vel_limit = 20.0 * float( enc_ctx.yaml['cpr']) axis_ctx.handle.controller.input_current = 4.0 time.sleep(0.5) axis_ctx.handle.controller.config.vel_limit = max_vel axis_ctx.handle.controller.input_current = input_current = 2.0 dataB = np.concatenate( [dataB, record_log(data_getter, duration=1.0)]) test_assert_no_error(axis_ctx) axis_ctx.handle.requested_state = 1 test_curve_fit(dataA[:, (0, 3)], dataA[:, 4], max_mean_err=0.02, inlier_range=0.05, max_outliers=len(dataA[:, 0] * 0.01)) test_curve_fit(dataB[:, (0, 3)], dataB[:, 4], max_mean_err=0.1, inlier_range=0.2, max_outliers=len(dataB[:, 0]) * 0.01)
def run_test(self, axis_ctx: ODriveAxisComponent, motor_ctx: MotorComponent, enc_ctx: EncoderComponent, logger: Logger): with SafeTerminator(logger, axis_ctx): nominal_rps = 15.0 max_current = 20.0 # Accept a bit of noise on Ibus axis_ctx.parent.handle.config.dc_max_negative_current = -0.5 logger.debug(f'Brake control test from {nominal_rps} rounds/s...') axis_ctx.handle.controller.config.vel_limit = 25.0 axis_ctx.handle.motor.config.current_lim = max_current axis_ctx.handle.controller.config.control_mode = CONTROL_MODE_VELOCITY_CONTROL axis_ctx.handle.controller.config.input_mode = INPUT_MODE_PASSTHROUGH request_state(axis_ctx, AXIS_STATE_CLOSED_LOOP_CONTROL) # accelerate... axis_ctx.handle.controller.input_vel = nominal_rps time.sleep(1.0) test_assert_no_error(axis_ctx) # ... and brake axis_ctx.handle.controller.input_vel = 0 time.sleep(1.0) test_assert_no_error(axis_ctx) logger.debug(f'Brake control test with brake resistor disabled') # once more, but this time without brake resistor axis_ctx.parent.handle.config.enable_brake_resistor = False # accelerate... axis_ctx.handle.controller.input_vel = nominal_rps time.sleep(1.0) test_assert_no_error(axis_ctx) # ... and brake axis_ctx.parent.handle.config.dc_max_negative_current = -0.2 axis_ctx.handle.controller.input_vel = 10 # this should fail almost instantaneously time.sleep(0.1) test_assert_eq(axis_ctx.parent.handle.error, ODRIVE_ERROR_DC_BUS_OVER_REGEN_CURRENT) test_assert_eq( axis_ctx.handle.motor.error & MOTOR_ERROR_SYSTEM_LEVEL, MOTOR_ERROR_SYSTEM_LEVEL) test_assert_eq(axis_ctx.handle.error, 0) # Do test again with wrong brake resistance setting logger.debug(f'Brake control test with brake resistor = 100') axis_ctx.parent.handle.clear_errors() time.sleep(1.0) axis_ctx.parent.handle.config.brake_resistance = 100 axis_ctx.parent.handle.config.dc_max_negative_current = -0.5 request_state(axis_ctx, AXIS_STATE_CLOSED_LOOP_CONTROL) # accelerate... axis_ctx.handle.controller.input_vel = nominal_rps time.sleep(1.0) test_assert_no_error(axis_ctx) # ... and brake axis_ctx.handle.controller.input_vel = 0 time.sleep(1.0) # expect DC_BUS_OVER_REGEN_CURRENT time.sleep(0.1) test_assert_eq(axis_ctx.parent.handle.error, ODRIVE_ERROR_DC_BUS_OVER_REGEN_CURRENT) test_assert_eq( axis_ctx.handle.motor.error & MOTOR_ERROR_SYSTEM_LEVEL, MOTOR_ERROR_SYSTEM_LEVEL) test_assert_eq(axis_ctx.handle.error, 0)
def run_test(self, odrive: ODriveComponent, canbus: CanInterfaceComponent, node_id: int, extended_id: bool, logger: Logger): # make sure no gpio input is overwriting our values odrive.unuse_gpios() axis = odrive.handle.axis0 axis.config.enable_watchdog = False axis.clear_errors() axis.config.can_node_id = node_id axis.config.can_node_id_extended = extended_id time.sleep(0.1) def my_cmd(cmd_name, **kwargs): command(canbus.handle, node_id, extended_id, cmd_name, **kwargs) def my_req(cmd_name, **kwargs): return asyncio.run(request(canbus.handle, node_id, extended_id, cmd_name, **kwargs)) def fence(): my_req('get_vbus_voltage') # fence to ensure the CAN command was sent test_assert_eq(my_req('get_vbus_voltage')['vbus_voltage'], odrive.handle.vbus_voltage, accuracy=0.01) my_cmd('set_node_id', node_id=node_id+20) asyncio.run(request(canbus.handle, node_id+20, extended_id, 'get_vbus_voltage')) test_assert_eq(axis.config.can_node_id, node_id+20) # Reset node ID to default value command(canbus.handle, node_id+20, extended_id, 'set_node_id', node_id=node_id) fence() test_assert_eq(axis.config.can_node_id, node_id) # Check that extended node IDs are not carelessly projected to 6-bit IDs extended_id = not extended_id my_cmd('estop') # should not be accepted extended_id = not extended_id fence() test_assert_eq(axis.error, AXIS_ERROR_NONE) axis.encoder.set_linear_count(123) test_assert_eq(my_req('get_encoder_estimates')['encoder_pos_estimate'], 123.0 / axis.encoder.config.cpr, accuracy=0.01) test_assert_eq(my_req('get_encoder_count')['encoder_shadow_count'], 123.0, accuracy=0.01) my_cmd('clear_errors') fence() test_assert_eq(axis.error, 0) my_cmd('estop') fence() test_assert_eq(axis.error, AXIS_ERROR_ESTOP_REQUESTED) my_cmd('set_requested_state', requested_state=42) # illegal state - should assert axis error fence() test_assert_eq(axis.current_state, 1) # idle test_assert_eq(axis.error, AXIS_ERROR_ESTOP_REQUESTED | AXIS_ERROR_INVALID_STATE) my_cmd('clear_errors') fence() test_assert_eq(axis.error, 0) my_cmd('set_controller_modes', control_mode=1, input_mode=5) # current conrol, traprzoidal trajectory fence() test_assert_eq(axis.controller.config.control_mode, 1) test_assert_eq(axis.controller.config.input_mode, 5) # Reset to safe values my_cmd('set_controller_modes', control_mode=3, input_mode=1) # position control, passthrough fence() test_assert_eq(axis.controller.config.control_mode, 3) test_assert_eq(axis.controller.config.input_mode, 1) axis.controller.input_pos = 1234 axis.controller.input_vel = 1234 axis.controller.input_torque = 1234 my_cmd('set_input_pos', input_pos=1.23, vel_ff=1.2, torque_ff=3.4) fence() test_assert_eq(axis.controller.input_pos, 1.23, range=0.1) test_assert_eq(axis.controller.input_vel, 1.2, range=0.01) test_assert_eq(axis.controller.input_torque, 3.4, range=0.001) axis.controller.config.control_mode = CONTROL_MODE_VELOCITY_CONTROL my_cmd('set_input_vel', input_vel=-10.5, torque_ff=0.1234) fence() test_assert_eq(axis.controller.input_vel, -10.5, range=0.01) test_assert_eq(axis.controller.input_torque, 0.1234, range=0.01) axis.controller.config.control_mode = CONTROL_MODE_TORQUE_CONTROL my_cmd('set_input_torque', input_torque=0.1) fence() test_assert_eq(axis.controller.input_torque, 0.1, range=0.01) my_cmd('set_velocity_limit', velocity_limit=2.345678) fence() test_assert_eq(axis.controller.config.vel_limit, 2.345678, range=0.001) my_cmd('set_traj_vel_limit', traj_vel_limit=123.456) fence() test_assert_eq(axis.trap_traj.config.vel_limit, 123.456, range=0.0001) my_cmd('set_traj_accel_limits', traj_accel_limit=98.231, traj_decel_limit=-12.234) fence() test_assert_eq(axis.trap_traj.config.accel_limit, 98.231, range=0.0001) test_assert_eq(axis.trap_traj.config.decel_limit, -12.234, range=0.0001) my_cmd('set_traj_inertia', inertia=55.086) fence() test_assert_eq(axis.controller.config.inertia, 55.086, range=0.0001) # any CAN cmd will feed the watchdog test_watchdog(axis, lambda: my_cmd('set_input_torque', input_torque=0.0), logger) logger.debug('testing heartbeat...') # note that this will include the heartbeats that were received during the # watchdog test (which takes 4.8s). heartbeats = asyncio.run(get_all(record_messages(canbus.handle, node_id, extended_id, 'heartbeat', timeout = 1.0))) test_assert_eq(len(heartbeats), 5.8 / 0.1, accuracy=0.05) test_assert_eq([msg['error'] for msg in heartbeats[0:35]], [0] * 35) # before watchdog expiry test_assert_eq([msg['error'] for msg in heartbeats[-10:]], [AXIS_ERROR_WATCHDOG_TIMER_EXPIRED] * 10) # after watchdog expiry test_assert_eq([msg['current_state'] for msg in heartbeats], [1] * len(heartbeats)) logger.debug('testing reboot...') my_cmd('reboot') time.sleep(0.5) if len(odrive.handle._remote_attributes) != 0: raise TestFailed("device didn't seem to reboot") odrive.handle = None time.sleep(2.0) odrive.prepare(logger)
def run_test(self, enc: ODriveEncoderComponent, odrive_ncs_gpio: int, teensy: TeensyComponent, teensy_gpio_sck: TeensyGpio, teensy_gpio_miso: TeensyGpio, teensy_gpio_mosi: TeensyGpio, teensy_gpio_ncs: TeensyGpio, teensy_gpio_reset: TeensyGpio, reset_gpio: LinuxGpioComponent, logger: Logger): true_cpr = 16384 true_rps = 1.0 reset_gpio.config(output=True) # hold encoder and disable its SPI reset_gpio.write(True) code = (teensy_spi_encoder_emulation_code .replace("{sck}", str(teensy_gpio_sck.num)) .replace("{miso}", str(teensy_gpio_miso.num)) .replace("{mosi}", str(teensy_gpio_mosi.num)) .replace("{ncs}", str(teensy_gpio_ncs.num)) .replace("{reset}", str(teensy_gpio_reset.num)) .replace("{mode}", str(self.mode))) teensy.compile_and_program(code) logger.debug(f'Configuring absolute encoder in mode 0x{self.mode:x}...') enc.handle.config.mode = self.mode enc.handle.config.abs_spi_cs_gpio_pin = odrive_ncs_gpio enc.handle.config.cpr = true_cpr # Also put the other encoder into SPI mode to make it more interesting other_enc = enc.parent.encoders[1 - enc.num] other_enc.handle.config.mode = self.mode other_enc.handle.config.abs_spi_cs_gpio_pin = odrive_ncs_gpio other_enc.handle.config.cpr = true_cpr enc.parent.save_config_and_reboot() time.sleep(1.0) logger.debug('Testing absolute readings and SPI errors...') # Encoder is still disabled - expect recurring error enc.handle.error = 0 time.sleep(0.002) # This fails from time to time because the pull-up on the ODrive only manages # to pull MISO to 1.8V, leaving it in the undefined range. test_assert_eq(enc.handle.error, ENCODER_ERROR_ABS_SPI_COM_FAIL) # Enable encoder and expect error to go away reset_gpio.write(False) release_time = time.monotonic() enc.handle.error = 0 time.sleep(0.002) test_assert_eq(enc.handle.error, 0) # Check absolute position after 1.5s time.sleep(1.5) true_delta_t = time.monotonic() - release_time test_assert_eq(enc.handle.pos_abs, (true_delta_t * true_rps * true_cpr) % true_cpr, range = true_cpr*0.001) test_assert_eq(enc.handle.error, 0) reset_gpio.write(True) time.sleep(0.002) test_assert_eq(enc.handle.error, ENCODER_ERROR_ABS_SPI_COM_FAIL) reset_gpio.write(False) release_time = time.monotonic() enc.handle.error = 0 time.sleep(0.002) test_assert_eq(enc.handle.error, 0) # Check absolute position after 1.5s time.sleep(1.5) true_delta_t = time.monotonic() - release_time test_assert_eq(enc.handle.pos_abs, (true_delta_t * true_rps * true_cpr) % true_cpr, range = true_cpr*0.001) self.run_generic_encoder_test(enc.handle, true_cpr, true_rps) enc.handle.config.cpr = 8192
def run_test(self, axis_ctx: ODriveAxisComponent, motor_ctx: MotorComponent, enc_ctx: EncoderComponent, logger: Logger): logger.debug(f'Encoder {axis_ctx.num} was passed through')
except: app_shutdown_token.set() raise finally: # Release all conflicting axes for axis_ctx in coupled_axes: axis_ctx.lock.release() for_all_parallel(couplings, lambda x: type(test).__name__ + " on " + "..".join([a.name for a in x]), dual_axis_test_thread) else: logger.warn("ignoring unknown test type {}".format(type(test))) except: logger.error(traceback.format_exc()) logger.debug('=> Test failed. Please wait while I secure the test rig...') try: dont_secure_after_failure = False # TODO: disable if not dont_secure_after_failure: def odrv_reset_thread(odrv_name): odrv_ctx = odrives_by_name[odrv_name] #run("make erase PROGRAMMER='" + odrv_ctx.yaml['programmer'] + "'", logger, timeout=30) odrv_ctx.handle.axis0.requested_state = AXIS_STATE_IDLE odrv_ctx.handle.axis1.requested_state = AXIS_STATE_IDLE dump_errors(odrv_ctx.axes[0], logger) dump_errors(odrv_ctx.axes[1], logger) for_all_parallel(odrives_by_name, lambda x: x['name'], odrv_reset_thread) except: logger.error('///////////////////////////////////////////') logger.error('/// CRITICAL: COULD NOT SECURE TEST RIG ///')
def run_test(self, odrive: ODriveComponent, port: SerialPortComponent, logger: Logger): logger.debug('Enabling UART...') # GPIOs might be in use by something other than UART and some components # might be configured so that they would fail in the later test. odrive.erase_config_and_reboot() odrive.handle.config.enable_uart = True with port.open(115200) as ser: # reset port to known state reset_state(ser) # Read a top-level attribute ser.write(b'r vbus_voltage\n') response = float(ser.readline().strip()) test_assert_eq(response, odrive.handle.vbus_voltage, accuracy=0.1) # Read an unknown attribute ser.write(b'r blahblah\n') response = ser.readline().strip() test_assert_eq(response, b'invalid property') # Send command with delays in between for byte in b'r vbus_voltage\n': ser.write([byte]) time.sleep(0.1) response = float(ser.readline().strip()) test_assert_eq(response, odrive.handle.vbus_voltage, accuracy=0.1) # Test GCode checksum and comments ser.write(b'r vbus_voltage *12\n') # invalid checksum test_assert_eq(ser.readline(), b'') ser.write(append_checksum(b'r vbus_voltage ') + b' ; this is a comment\n') # valid checksum response = float(strip_checksum(ser.readline()).strip()) test_assert_eq(response, odrive.handle.vbus_voltage, accuracy=0.1) # Read an attribute with a long name ser.write(b'r axis0.motor.current_control.v_current_control_integral_d\n') response = float(ser.readline().strip()) test_assert_eq(response, odrive.handle.axis0.motor.current_control.v_current_control_integral_d, accuracy=0.1) # Write an attribute ser.write(b'w test_property 12345\n') ser.write(b'r test_property\n') response = int(ser.readline().strip()) test_assert_eq(response, 12345) # Test 'c', 'v', 'p', 'q' and 'f' commands odrive.handle.axis0.controller.input_current = 0 ser.write(b'c 0 12.5\n') test_assert_eq(ser.readline(), b'') test_assert_eq(odrive.handle.axis0.controller.input_current, 12.5, accuracy=0.001) test_assert_eq(odrive.handle.axis0.controller.config.control_mode, CTRL_MODE_CURRENT_CONTROL) odrive.handle.axis0.controller.input_vel = 0 odrive.handle.axis0.controller.input_current = 0 ser.write(b'v 0 567.8 12.5\n') test_assert_eq(ser.readline(), b'') test_assert_eq(odrive.handle.axis0.controller.input_vel, 567.8, accuracy=0.001) test_assert_eq(odrive.handle.axis0.controller.input_current, 12.5, accuracy=0.001) test_assert_eq(odrive.handle.axis0.controller.config.control_mode, CTRL_MODE_VELOCITY_CONTROL) odrive.handle.axis0.controller.input_pos = 0 odrive.handle.axis0.controller.input_vel = 0 odrive.handle.axis0.controller.input_current = 0 ser.write(b'p 0 123.4 567.8 12.5\n') test_assert_eq(ser.readline(), b'') test_assert_eq(odrive.handle.axis0.controller.input_pos, 123.4, accuracy=0.001) test_assert_eq(odrive.handle.axis0.controller.input_vel, 567.8, accuracy=0.001) test_assert_eq(odrive.handle.axis0.controller.input_current, 12.5, accuracy=0.001) test_assert_eq(odrive.handle.axis0.controller.config.control_mode, CTRL_MODE_POSITION_CONTROL) odrive.handle.axis0.controller.input_pos = 0 odrive.handle.axis0.controller.config.vel_limit = 0 odrive.handle.axis0.motor.config.current_lim = 0 ser.write(b'q 0 123.4 567.8 12.5\n') test_assert_eq(ser.readline(), b'') test_assert_eq(odrive.handle.axis0.controller.input_pos, 123.4, accuracy=0.001) test_assert_eq(odrive.handle.axis0.controller.config.vel_limit, 567.8, accuracy=0.001) test_assert_eq(odrive.handle.axis0.motor.config.current_lim, 12.5, accuracy=0.001) test_assert_eq(odrive.handle.axis0.controller.config.control_mode, CTRL_MODE_POSITION_CONTROL) ser.write(b'f 0\n') response = ser.readline().strip() test_assert_eq(float(response.split()[0]), odrive.handle.axis0.encoder.pos_estimate, accuracy=0.001) test_assert_eq(float(response.split()[1]), odrive.handle.axis0.encoder.vel_estimate, accuracy=0.001) test_watchdog(odrive.handle.axis0, lambda: ser.write(b'u 0\n'), logger) test_assert_eq(ser.readline(), b'') # check if the device remained silent during the test
def run_test(self, axis_ctx: ODriveAxisComponent, motor_ctx: MotorComponent, enc_ctx: EncoderComponent, logger: Logger): with self.prepare(axis_ctx, motor_ctx, enc_ctx, logger): nominal_rps = 1.0 nominal_vel = float(enc_ctx.yaml['cpr']) * nominal_rps logger.debug( f'Testing closed loop velocity control at {nominal_rps} rounds/s...' ) axis_ctx.handle.controller.config.control_mode = CTRL_MODE_VELOCITY_CONTROL axis_ctx.handle.controller.config.input_mode = INPUT_MODE_PASSTHROUGH axis_ctx.handle.controller.input_vel = 0 request_state(axis_ctx, AXIS_STATE_CLOSED_LOOP_CONTROL) axis_ctx.handle.controller.input_vel = nominal_vel data = record_log(lambda: [ axis_ctx.handle.encoder.vel_estimate, axis_ctx.handle.encoder. pos_estimate ], duration=5.0) test_assert_eq(axis_ctx.handle.current_state, AXIS_STATE_CLOSED_LOOP_CONTROL) test_assert_no_error(axis_ctx) request_state(axis_ctx, AXIS_STATE_IDLE) # encoder.vel_estimate slope, offset, fitted_curve = fit_line(data[:, (0, 1)]) test_assert_eq(slope, 0.0, range=nominal_vel * 0.02) test_assert_eq(offset, nominal_vel, accuracy=0.05) test_curve_fit(data[:, (0, 1)], fitted_curve, max_mean_err=nominal_vel * 0.3, inlier_range=nominal_vel * 0.5, max_outliers=len(data[:, 0]) * 0.1) # encoder.pos_estimate slope, offset, fitted_curve = fit_line(data[:, (0, 2)]) test_assert_eq(slope, nominal_vel, accuracy=0.01) test_curve_fit(data[:, (0, 2)], fitted_curve, max_mean_err=nominal_vel * 0.01, inlier_range=nominal_vel * 0.1, max_outliers=len(data[:, 0]) * 0.01) logger.debug(f'Testing closed loop position control...') axis_ctx.handle.controller.config.control_mode = CTRL_MODE_POSITION_CONTROL axis_ctx.handle.controller.input_pos = 0 axis_ctx.handle.controller.config.vel_limit = float( enc_ctx.yaml['cpr']) * 5.0 # max 5 rps axis_ctx.handle.encoder.set_linear_count(0) request_state(axis_ctx, AXIS_STATE_CLOSED_LOOP_CONTROL) # Test small position changes axis_ctx.handle.controller.input_pos = 5000 time.sleep(0.3) test_assert_no_error(axis_ctx) test_assert_eq( axis_ctx.handle.encoder.pos_estimate, 5000, range=2000) # large range needed because of cogging torque axis_ctx.handle.controller.input_pos = -5000 time.sleep(0.3) test_assert_no_error(axis_ctx) test_assert_eq(axis_ctx.handle.encoder.pos_estimate, -5000, range=2000) axis_ctx.handle.controller.input_pos = 0 time.sleep(0.3) nominal_vel = float(enc_ctx.yaml['cpr']) * 5.0 axis_ctx.handle.controller.input_pos = nominal_vel * 2.0 # 10 turns (takes 2 seconds) # Test large position change with bounded velocity data = record_log(lambda: [ axis_ctx.handle.encoder.vel_estimate, axis_ctx.handle.encoder. pos_estimate ], duration=4.0) test_assert_eq(axis_ctx.handle.current_state, AXIS_STATE_CLOSED_LOOP_CONTROL) test_assert_no_error(axis_ctx) request_state(axis_ctx, AXIS_STATE_IDLE) data_motion = data[data[:, 0] < 1.9] data_still = data[data[:, 0] > 2.1] # encoder.vel_estimate slope, offset, fitted_curve = fit_line(data_motion[:, (0, 1)]) test_assert_eq(slope, 0.0, range=nominal_vel * 0.05) test_assert_eq(offset, nominal_vel, accuracy=0.05) test_curve_fit(data_motion[:, (0, 1)], fitted_curve, max_mean_err=nominal_vel * 0.05, inlier_range=nominal_vel * 0.1, max_outliers=len(data[:, 0]) * 0.01) # encoder.pos_estimate slope, offset, fitted_curve = fit_line(data_motion[:, (0, 2)]) test_assert_eq(slope, nominal_vel, accuracy=0.01) test_curve_fit(data_motion[:, (0, 2)], fitted_curve, max_mean_err=nominal_vel * 0.01, inlier_range=nominal_vel * 0.1, max_outliers=len(data[:, 0]) * 0.01) # encoder.vel_estimate slope, offset, fitted_curve = fit_line(data_still[:, (0, 1)]) test_assert_eq(slope, 0.0, range=nominal_vel * 0.05) test_assert_eq(offset, 0.0, range=nominal_vel * 0.05) test_curve_fit(data_still[:, (0, 1)], fitted_curve, max_mean_err=nominal_vel * 0.05, inlier_range=nominal_vel * 0.1, max_outliers=len(data[:, 0]) * 0.01) # encoder.pos_estimate slope, offset, fitted_curve = fit_line(data_still[:, (0, 2)]) test_assert_eq(slope, 0.0, range=nominal_vel * 0.05) test_assert_eq(offset, nominal_vel * 2, range=nominal_vel * 0.02) test_curve_fit(data_still[:, (0, 2)], fitted_curve, max_mean_err=nominal_vel * 0.01, inlier_range=nominal_vel * 0.01, max_outliers=len(data[:, 0]) * 0.01)
def run_test(self, odrive: ODriveComponent, canbus: CanInterfaceComponent, node_id: int, extended_id: bool, logger: Logger): odrive.disable_mappings() if odrive.yaml['board-version'].startswith("v3."): odrive.handle.config.gpio15_mode = GPIO_MODE_CAN_A odrive.handle.config.gpio16_mode = GPIO_MODE_CAN_A elif odrive.yaml['board-version'].startswith("v4."): pass # CAN pin configuration is hardcoded else: raise Exception("unknown board version {}".format( odrive.yaml['board-version'])) odrive.handle.config.enable_can_a = True odrive.save_config_and_reboot() axis = odrive.handle.axis0 axis.config.enable_watchdog = False odrive.handle.clear_errors() axis.config.can.node_id = node_id axis.config.can.is_extended = extended_id time.sleep(0.1) def my_cmd(cmd_name, **kwargs): command(canbus.handle, node_id, extended_id, cmd_name, **kwargs) def my_req(cmd_name, **kwargs): return asyncio.run( request(canbus.handle, node_id, extended_id, cmd_name, **kwargs)) def fence(): my_req( 'get_vbus_voltage') # fence to ensure the CAN command was sent def flush_rx(): while not canbus.handle.recv(timeout=0) is None: pass logger.debug('sending request...') test_assert_eq(my_req('get_vbus_voltage')['vbus_voltage'], odrive.handle.vbus_voltage, accuracy=0.01) my_cmd('set_node_id', node_id=node_id + 20) time.sleep(0.1) # TODO: remove this hack (see note in firmware) asyncio.run( request(canbus.handle, node_id + 20, extended_id, 'get_vbus_voltage')) test_assert_eq(axis.config.can.node_id, node_id + 20) # Reset node ID to default value command(canbus.handle, node_id + 20, extended_id, 'set_node_id', node_id=node_id) fence() test_assert_eq(axis.config.can.node_id, node_id) # Check that extended node IDs are not carelessly projected to 6-bit IDs extended_id = not extended_id my_cmd('estop') # should not be accepted extended_id = not extended_id fence() test_assert_eq(axis.error, AXIS_ERROR_NONE) axis.encoder.set_linear_count(123) flush_rx( ) # drop previous encoder estimates that were sent by the ODrive at a constant rate test_assert_eq(my_req('get_encoder_estimates')['encoder_pos_estimate'], 123.0 / axis.encoder.config.cpr, accuracy=0.01) test_assert_eq(my_req('get_encoder_count')['encoder_shadow_count'], 123.0, accuracy=0.01) my_cmd('clear_errors') fence() test_assert_eq(axis.error, 0) my_cmd('estop') fence() test_assert_eq(axis.error, AXIS_ERROR_ESTOP_REQUESTED) my_cmd('set_requested_state', requested_state=42) # illegal state - should assert axis error fence() test_assert_eq(axis.current_state, 1) # idle test_assert_eq(axis.error, AXIS_ERROR_ESTOP_REQUESTED | AXIS_ERROR_INVALID_STATE) my_cmd('clear_errors') fence() test_assert_eq(axis.error, 0) my_cmd('set_controller_modes', control_mode=1, input_mode=5) # current conrol, traprzoidal trajectory fence() test_assert_eq(axis.controller.config.control_mode, 1) test_assert_eq(axis.controller.config.input_mode, 5) # Reset to safe values my_cmd('set_controller_modes', control_mode=3, input_mode=1) # position control, passthrough fence() test_assert_eq(axis.controller.config.control_mode, 3) test_assert_eq(axis.controller.config.input_mode, 1) axis.controller.input_pos = 1234 axis.controller.input_vel = 1234 axis.controller.input_torque = 1234 my_cmd('set_input_pos', input_pos=1.23, vel_ff=1.2, torque_ff=3.4) fence() test_assert_eq(axis.controller.input_pos, 1.23, range=0.1) test_assert_eq(axis.controller.input_vel, 1.2, range=0.01) test_assert_eq(axis.controller.input_torque, 3.4, range=0.001) axis.controller.config.control_mode = CONTROL_MODE_VELOCITY_CONTROL my_cmd('set_input_vel', input_vel=-10.5, torque_ff=0.1234) fence() test_assert_eq(axis.controller.input_vel, -10.5, range=0.01) test_assert_eq(axis.controller.input_torque, 0.1234, range=0.01) axis.controller.config.control_mode = CONTROL_MODE_TORQUE_CONTROL my_cmd('set_input_torque', input_torque=0.1) fence() test_assert_eq(axis.controller.input_torque, 0.1, range=0.01) my_cmd('set_velocity_limit', velocity_limit=2.345678) fence() test_assert_eq(axis.controller.config.vel_limit, 2.345678, range=0.001) my_cmd('set_traj_vel_limit', traj_vel_limit=123.456) fence() test_assert_eq(axis.trap_traj.config.vel_limit, 123.456, range=0.0001) my_cmd('set_traj_accel_limits', traj_accel_limit=98.231, traj_decel_limit=-12.234) fence() test_assert_eq(axis.trap_traj.config.accel_limit, 98.231, range=0.0001) test_assert_eq(axis.trap_traj.config.decel_limit, -12.234, range=0.0001) my_cmd('set_traj_inertia', inertia=55.086) fence() test_assert_eq(axis.controller.config.inertia, 55.086, range=0.0001) # any CAN cmd will feed the watchdog test_watchdog(axis, lambda: my_cmd('set_input_torque', input_torque=0.0), logger) logger.debug('testing heartbeat...') flush_rx( ) # Flush RX buffer to get a clean state for the heartbeat test heartbeats = asyncio.run( get_all( record_messages(canbus.handle, node_id, extended_id, 'heartbeat', timeout=2.0))) test_assert_eq(len(heartbeats), 2.0 / 0.1, accuracy=0.05) test_assert_eq([msg['error'] for msg in heartbeats], [AXIS_ERROR_WATCHDOG_TIMER_EXPIRED] * len(heartbeats)) test_assert_eq([msg['current_state'] for msg in heartbeats], [1] * len(heartbeats)) logger.debug('testing reboot...') test_assert_eq(odrive.handle._on_lost.done(), False) my_cmd('reboot') time.sleep(0.5) if not odrive.handle._on_lost is None: raise TestFailed("device didn't seem to reboot") odrive.handle = None time.sleep(2.0) odrive.prepare(logger)
def run_test(self, axis_ctx: ODriveAxisComponent, motor_ctx: MotorComponent, enc_ctx: EncoderComponent, logger: Logger): with self.prepare(axis_ctx, motor_ctx, enc_ctx, logger): max_rps = 15.0 max_vel = max_rps max_current = 30.0 max_torque = 0.1 # must be less than max_current * torque_constant. torque_constant = axis_ctx.handle.motor.config.torque_constant test_pos = 5 test_vel = 10 test_torque = 0.5 axis_ctx.handle.controller.config.vel_limit = max_vel axis_ctx.handle.motor.config.current_lim = max_current axis_ctx.handle.motor.config.torque_lim = inf #disable torque limit axis_ctx.handle.controller.config.control_mode = CONTROL_MODE_VELOCITY_CONTROL def data_getter(): current_setpoint = axis_ctx.handle.motor.current_control.Iq_setpoint torque_setpoint = current_setpoint * torque_constant torque_limit = axis_ctx.handle.motor.config.torque_lim # Abort immediately if the absolute limits are exceeded test_assert_within(current_setpoint, -max_current, max_current) test_assert_within(torque_setpoint, -torque_limit, torque_limit) return max_current, current_setpoint, torque_limit, torque_setpoint # begin test axis_ctx.handle.motor.config.torque_lim = max_torque request_state(axis_ctx, AXIS_STATE_CLOSED_LOOP_CONTROL) # step input positions logger.debug('input_pos step test') axis_ctx.handle.controller.config.control_mode = CONTROL_MODE_POSITION_CONTROL axis_ctx.handle.controller.input_pos = test_pos dataPos = record_log(data_getter, duration=1.0) axis_ctx.handle.controller.input_pos = -test_pos dataPos = np.concatenate( [dataPos, record_log(data_getter, duration=1.0)]) axis_ctx.handle.controller.input_pos = test_pos dataPos = np.concatenate( [dataPos, record_log(data_getter, duration=1.0)]) axis_ctx.handle.controller.input_pos = -test_pos dataPos = np.concatenate( [dataPos, record_log(data_getter, duration=1.0)]) time.sleep(0.5) test_assert_no_error(axis_ctx) # step input velocities logger.debug('input_vel step test') axis_ctx.handle.controller.config.control_mode = CONTROL_MODE_VELOCITY_CONTROL axis_ctx.handle.controller.input_vel = test_vel dataVel = record_log(data_getter, duration=1.0) axis_ctx.handle.controller.input_vel = -test_vel dataVel = np.concatenate( [dataVel, record_log(data_getter, duration=1.0)]) axis_ctx.handle.controller.input_vel = test_vel dataVel = np.concatenate( [dataVel, record_log(data_getter, duration=1.0)]) axis_ctx.handle.controller.input_vel = -test_vel dataVel = np.concatenate( [dataVel, record_log(data_getter, duration=1.0)]) axis_ctx.handle.controller.input_vel = 0 time.sleep(0.5) # step input torques logger.debug('input_torque step test') axis_ctx.handle.controller.config.control_mode = CONTROL_MODE_TORQUE_CONTROL axis_ctx.handle.controller.input_torque = test_torque dataTq = record_log(data_getter, duration=1.0) axis_ctx.handle.controller.input_torque = -test_torque dataTq = np.concatenate( [dataTq, record_log(data_getter, duration=1.0)]) axis_ctx.handle.controller.input_torque = test_torque dataTq = np.concatenate( [dataTq, record_log(data_getter, duration=1.0)]) axis_ctx.handle.controller.input_torque = -test_torque dataTq = np.concatenate( [dataTq, record_log(data_getter, duration=1.0)]) axis_ctx.handle.controller.input_torque = 0 time.sleep(0.5) # did we pass? test_assert_no_error(axis_ctx) axis_ctx.handle.requested_state = 1
def run_test(self, odrive: ODriveComponent, uart_num: int, tx_gpio: list, rx_gpio: list, port: SerialPortComponent, logger: Logger): self.prepare(odrive, uart_num, tx_gpio, rx_gpio, logger) with port.open(115200) as ser: # reset port to known state reset_state(ser) # Read a top-level attribute ser.write(b'r vbus_voltage\n') response = float(ser.readline().strip()) test_assert_eq(response, odrive.handle.vbus_voltage, accuracy=0.1) # Read an unknown attribute ser.write(b'r blahblah\n') response = ser.readline().strip() test_assert_eq(response, b'invalid property') # Send command with delays in between for byte in b'r vbus_voltage\n': ser.write([byte]) time.sleep(0.1) response = float(ser.readline().strip()) test_assert_eq(response, odrive.handle.vbus_voltage, accuracy=0.1) # Test GCode checksum and comments ser.write(b'r vbus_voltage *12\n') # invalid checksum test_assert_eq(ser.readline(), b'') cmd = append_checksum( b'r vbus_voltage ') + b' ; this is a comment\n' # cmd evalutates to "r vbus_voltage *93 ; this is a comment" logger.debug(f'sending command with checksum: "{cmd}"') ser.write(cmd) # valid checksum response = float(strip_checksum(ser.readline()).strip()) test_assert_eq(response, odrive.handle.vbus_voltage, accuracy=0.1) # Read an attribute with a long name ser.write( b'r axis0.motor.current_control.v_current_control_integral_d\n' ) response = float(ser.readline().strip()) test_assert_eq(response, odrive.handle.axis0.motor.current_control. v_current_control_integral_d, accuracy=0.1) # Write an attribute ser.write(b'w test_property 12345\n') ser.write(b'r test_property\n') response = int(ser.readline().strip()) test_assert_eq(response, 12345) # Test custom setter (aka property write hook) odrive.handle.axis0.motor.config.phase_resistance = 1 odrive.handle.axis0.motor.config.phase_inductance = 1 odrive.handle.axis0.motor.config.current_control_bandwidth = 1000 old_gain = odrive.handle.axis0.motor.current_control.p_gain test_assert_eq(old_gain, 1000, accuracy=0.0001 ) # must be non-zero for subsequent check to work ser.write( 'w axis0.motor.config.current_control_bandwidth {}\n'.format( odrive.handle.axis0.motor.config.current_control_bandwidth / 2).encode('ascii')) test_assert_eq(ser.readline(), b'') test_assert_eq(odrive.handle.axis0.motor.current_control.p_gain, old_gain / 2, accuracy=0.0001) # Test 'c', 'v', 'p', 'q' and 'f' commands odrive.handle.axis0.controller.input_torque = 0 ser.write(b'c 0 12.5\n') test_assert_eq(ser.readline(), b'') test_assert_eq(odrive.handle.axis0.controller.input_torque, 12.5, accuracy=0.001) test_assert_eq(odrive.handle.axis0.controller.config.control_mode, CONTROL_MODE_TORQUE_CONTROL) odrive.handle.axis0.controller.input_vel = 0 odrive.handle.axis0.controller.input_torque = 0 ser.write(b'v 0 567.8 12.5\n') test_assert_eq(ser.readline(), b'') test_assert_eq(odrive.handle.axis0.controller.input_vel, 567.8, accuracy=0.001) test_assert_eq(odrive.handle.axis0.controller.input_torque, 12.5, accuracy=0.001) test_assert_eq(odrive.handle.axis0.controller.config.control_mode, CONTROL_MODE_VELOCITY_CONTROL) odrive.handle.axis0.controller.input_pos = 0 odrive.handle.axis0.controller.input_vel = 0 odrive.handle.axis0.controller.input_torque = 0 ser.write(b'p 0 123.4 567.8 12.5\n') test_assert_eq(ser.readline(), b'') test_assert_eq(odrive.handle.axis0.controller.input_pos, 123.4, accuracy=0.001) test_assert_eq(odrive.handle.axis0.controller.input_vel, 567.8, accuracy=0.001) test_assert_eq(odrive.handle.axis0.controller.input_torque, 12.5, accuracy=0.001) test_assert_eq(odrive.handle.axis0.controller.config.control_mode, CONTROL_MODE_POSITION_CONTROL) odrive.handle.axis0.controller.input_pos = 0 odrive.handle.axis0.controller.config.vel_limit = 0 odrive.handle.axis0.motor.config.current_lim = 0 ser.write(b'q 0 123.4 567.8 12.5\n') test_assert_eq(ser.readline(), b'') test_assert_eq(odrive.handle.axis0.controller.input_pos, 123.4, accuracy=0.001) test_assert_eq(odrive.handle.axis0.controller.config.vel_limit, 567.8, accuracy=0.001) test_assert_eq(odrive.handle.axis0.motor.config.torque_lim, 12.5, accuracy=0.001) test_assert_eq(odrive.handle.axis0.controller.config.control_mode, CONTROL_MODE_POSITION_CONTROL) ser.write(b'f 0\n') response = ser.readline().strip() test_assert_eq(float(response.split()[0]), odrive.handle.axis0.encoder.pos_estimate, accuracy=0.001) test_assert_eq(float(response.split()[1]), odrive.handle.axis0.encoder.vel_estimate, accuracy=0.001) test_watchdog(odrive.handle.axis0, lambda: ser.write(b'u 0\n'), logger) test_assert_eq( ser.readline(), b'') # check if the device remained silent during the test