313 lines
14 KiB
Python
313 lines
14 KiB
Python
# Code for handling the kinematics of linear delta robots
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#
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# Copyright (C) 2016 Kevin O'Connor <kevin@koconnor.net>
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#
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# This file may be distributed under the terms of the GNU GPLv3 license.
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import math, logging
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import stepper, homing
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StepList = (0, 1, 2)
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class DeltaKinematics:
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def __init__(self, printer, config):
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self.steppers = [stepper.PrinterStepper(
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printer, config.getsection('stepper_' + n), n)
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for n in ['a', 'b', 'c']]
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self.need_motor_enable = True
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self.max_z_velocity = config.getfloat('max_z_velocity', 9999999.9)
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radius = config.getfloat('delta_radius')
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arm_length = config.getfloat('delta_arm_length')
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self.arm_length2 = arm_length**2
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self.max_xy2 = min(radius, arm_length - radius)**2
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self.limit_xy2 = -1.
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tower_height_at_zeros = math.sqrt(self.arm_length2 - radius**2)
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self.max_z = self.steppers[0].position_max
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self.limit_z = self.max_z - (arm_length - tower_height_at_zeros)
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sin = lambda angle: math.sin(math.radians(angle))
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cos = lambda angle: math.cos(math.radians(angle))
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self.towers = [
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(cos(210.)*radius, sin(210.)*radius),
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(cos(330.)*radius, sin(330.)*radius),
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(cos(90.)*radius, sin(90.)*radius)]
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def set_max_jerk(self, max_xy_halt_velocity, max_accel):
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# XXX - this sets conservative values
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for stepper in self.steppers:
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stepper.set_max_jerk(max_xy_halt_velocity, max_accel)
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def build_config(self):
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for stepper in self.steppers:
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stepper.build_config()
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self.set_position([0., 0., 0.])
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def cartesian_to_actuator(self, coord):
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return [int((math.sqrt(self.arm_length2
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- (self.towers[i][0] - coord[0])**2
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- (self.towers[i][1] - coord[1])**2) + coord[2])
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* self.steppers[i].inv_step_dist + 0.5)
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for i in StepList]
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def actuator_to_cartesian(self, pos):
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# Based on code from Smoothieware
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tower1 = list(self.towers[0]) + [pos[0]]
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tower2 = list(self.towers[1]) + [pos[1]]
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tower3 = list(self.towers[2]) + [pos[2]]
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s12 = matrix_sub(tower1, tower2)
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s23 = matrix_sub(tower2, tower3)
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s13 = matrix_sub(tower1, tower3)
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normal = matrix_cross(s12, s23)
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magsq_s12 = matrix_magsq(s12)
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magsq_s23 = matrix_magsq(s23)
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magsq_s13 = matrix_magsq(s13)
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inv_nmag_sq = 1.0 / matrix_magsq(normal)
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q = 0.5 * inv_nmag_sq
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a = q * magsq_s23 * matrix_dot(s12, s13)
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b = -q * magsq_s13 * matrix_dot(s12, s23) # negate because we use s12 instead of s21
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c = q * magsq_s12 * matrix_dot(s13, s23)
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circumcenter = [tower1[0] * a + tower2[0] * b + tower3[0] * c,
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tower1[1] * a + tower2[1] * b + tower3[1] * c,
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tower1[2] * a + tower2[2] * b + tower3[2] * c]
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r_sq = 0.5 * q * magsq_s12 * magsq_s23 * magsq_s13
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dist = math.sqrt(inv_nmag_sq * (self.arm_length2 - r_sq))
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return matrix_sub(circumcenter, matrix_mul(normal, dist))
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def set_position(self, newpos):
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pos = self.cartesian_to_actuator(newpos)
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for i in StepList:
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self.steppers[i].mcu_stepper.set_position(pos[i])
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def get_homed_position(self, homing_state):
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pos = [(s.mcu_stepper.commanded_position + s.get_homed_offset())
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* s.step_dist
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for s in self.steppers]
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return self.actuator_to_cartesian(pos)
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def home(self, homing_state):
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# All axes are homed simultaneously
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homing_state.set_axes([0, 1, 2])
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s = self.steppers[0] # Assume homing parameters same for all steppers
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self.limit_xy2 = self.max_xy2
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# Initial homing
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homepos = [0., 0., s.position_endstop, None]
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coord = list(homepos)
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coord[2] -= 1.5*(s.position_endstop)
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homing_state.plan_home(list(coord), homepos, self.steppers
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, s.homing_speed)
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# Retract
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coord[2] = homepos[2] - s.homing_retract_dist
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homing_state.plan_retract(list(coord), self.steppers, s.homing_speed)
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# Home again
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coord[2] -= s.homing_retract_dist
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homing_state.plan_second_home(list(coord), homepos, self.steppers
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, s.homing_speed/2.0)
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homing_state.plan_calc_position(self.get_homed_position)
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def motor_off(self, move_time):
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self.limit_xy2 = -1.
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for stepper in self.steppers:
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stepper.motor_enable(move_time, 0)
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self.need_motor_enable = True
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def check_motor_enable(self, move_time):
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for i in StepList:
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self.steppers[i].motor_enable(move_time, 1)
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self.need_motor_enable = False
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def query_endstops(self, query_state):
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query_state.set_steppers(self.steppers)
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def check_move(self, move):
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end_pos = move.end_pos
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xy2 = end_pos[0]**2 + end_pos[1]**2
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if xy2 > self.limit_xy2 or end_pos[2] < 0.:
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if self.limit_xy2 < 0.:
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raise homing.EndstopMoveError(end_pos, "Must home first")
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raise homing.EndstopMoveError(end_pos)
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if end_pos[2] > self.limit_z:
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if end_pos[2] > self.max_z or xy2 > (self.max_z - end_pos[2])**2:
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raise homing.EndstopMoveError(end_pos)
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if move.axes_d[2]:
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move.limit_speed(self.max_z_velocity, 9999999.9)
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def move_z(self, move_time, move):
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if not move.axes_d[2]:
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return
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if self.need_motor_enable:
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self.check_motor_enable(move_time)
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inv_accel = 1. / move.accel
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inv_cruise_v = 1. / move.cruise_v
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for i in StepList:
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towerx_d = self.towers[i][0] - move.start_pos[0]
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towery_d = self.towers[i][1] - move.start_pos[1]
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tower_d2 = towerx_d**2 + towery_d**2
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height = math.sqrt(self.arm_length2 - tower_d2) + move.start_pos[2]
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mcu_stepper = self.steppers[i].mcu_stepper
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mcu_time = mcu_stepper.print_to_mcu_time(move_time)
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step_pos = mcu_stepper.commanded_position
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inv_step_dist = self.steppers[i].inv_step_dist
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step_offset = step_pos - height * inv_step_dist
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step_dist = self.steppers[i].step_dist
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steps = move.axes_d[2] * inv_step_dist
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# Acceleration steps
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accel_multiplier = 2.0 * step_dist * inv_accel
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if move.accel_r:
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#t = sqrt(2*pos/accel + (start_v/accel)**2) - start_v/accel
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accel_time_offset = move.start_v * inv_accel
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accel_sqrt_offset = accel_time_offset**2
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accel_steps = move.accel_r * steps
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count = mcu_stepper.step_sqrt(
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mcu_time - accel_time_offset, accel_steps, step_offset
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, accel_sqrt_offset, accel_multiplier)
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step_offset += count - accel_steps
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mcu_time += move.accel_t
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# Cruising steps
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if move.cruise_r:
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#t = pos/cruise_v
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cruise_multiplier = step_dist * inv_cruise_v
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cruise_steps = move.cruise_r * steps
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count = mcu_stepper.step_factor(
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mcu_time, cruise_steps, step_offset, cruise_multiplier)
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step_offset += count - cruise_steps
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mcu_time += move.cruise_t
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# Deceleration steps
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if move.decel_r:
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#t = cruise_v/accel - sqrt((cruise_v/accel)**2 - 2*pos/accel)
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decel_time_offset = move.cruise_v * inv_accel
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decel_sqrt_offset = decel_time_offset**2
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decel_steps = move.decel_r * steps
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count = mcu_stepper.step_sqrt(
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mcu_time + decel_time_offset, decel_steps, step_offset
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, decel_sqrt_offset, -accel_multiplier)
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def move(self, move_time, move):
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axes_d = move.axes_d
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if not axes_d[0] and not axes_d[1]:
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self.move_z(move_time, move)
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return
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if self.need_motor_enable:
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self.check_motor_enable(move_time)
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move_d = move.move_d
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movez_r = 0.
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inv_movexy_d = 1. / move_d
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inv_movexy_r = 1.
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if axes_d[2]:
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movez_r = axes_d[2] * inv_movexy_d
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inv_movexy_d = 1. / math.sqrt(axes_d[0]**2 + axes_d[1]**2)
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inv_movexy_r = move_d * inv_movexy_d
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origx, origy, origz = move.start_pos[:3]
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accel_t = move.accel_t
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cruise_end_t = accel_t + move.cruise_t
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accel_d = move.accel_r * move_d
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cruise_end_d = accel_d + move.cruise_r * move_d
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inv_cruise_v = 1. / move.cruise_v
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inv_accel = 1. / move.accel
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accel_time_offset = move.start_v * inv_accel
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accel_multiplier = 2.0 * inv_accel
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accel_offset = move.start_v**2 * 0.5 * inv_accel
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decel_time_offset = move.cruise_v * inv_accel + cruise_end_t
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decel_offset = move.cruise_v**2 * 0.5 * inv_accel + cruise_end_d
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for i in StepList:
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# Find point on line of movement closest to tower
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towerx_d = self.towers[i][0] - origx
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towery_d = self.towers[i][1] - origy
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closestxy_d = (towerx_d*axes_d[0] + towery_d*axes_d[1])*inv_movexy_d
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tangentxy_d2 = towerx_d**2 + towery_d**2 - closestxy_d**2
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closest_height2 = self.arm_length2 - tangentxy_d2
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closest_height = math.sqrt(closest_height2)
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closest_d = closestxy_d * inv_movexy_r
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closestz = origz + closest_d*movez_r
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# Calculate accel/cruise/decel portions of move
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reverse_d = closest_d + closest_height*movez_r*inv_movexy_r
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accel_up_d = cruise_up_d = decel_up_d = 0.
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accel_down_d = cruise_down_d = decel_down_d = 0.
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if reverse_d <= 0.:
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accel_down_d = accel_d
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cruise_down_d = cruise_end_d
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decel_down_d = move_d
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elif reverse_d >= move_d:
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accel_up_d = accel_d
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cruise_up_d = cruise_end_d
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decel_up_d = move_d
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elif reverse_d < accel_d:
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accel_up_d = reverse_d
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accel_down_d = accel_d
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cruise_down_d = cruise_end_d
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decel_down_d = move_d
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elif reverse_d < cruise_end_d:
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accel_up_d = accel_d
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cruise_up_d = reverse_d
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cruise_down_d = cruise_end_d
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decel_down_d = move_d
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else:
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accel_up_d = accel_d
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cruise_up_d = cruise_end_d
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decel_up_d = reverse_d
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decel_down_d = move_d
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# Generate steps
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mcu_stepper = self.steppers[i].mcu_stepper
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mcu_time = mcu_stepper.print_to_mcu_time(move_time)
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step_pos = mcu_stepper.commanded_position
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inv_step_dist = self.steppers[i].inv_step_dist
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step_dist = self.steppers[i].step_dist
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height = step_pos*step_dist - closestz
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if accel_up_d > 0.:
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count = mcu_stepper.step_delta_accel(
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mcu_time - accel_time_offset, closest_d - accel_up_d,
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step_dist, closest_d + accel_offset,
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closest_height2, height, movez_r, accel_multiplier)
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height += count * step_dist
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if cruise_up_d > 0.:
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count = mcu_stepper.step_delta_const(
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mcu_time + accel_t, closest_d - cruise_up_d,
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step_dist, closest_d - accel_d,
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closest_height2, height, movez_r, inv_cruise_v)
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height += count * step_dist
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if decel_up_d > 0.:
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count = mcu_stepper.step_delta_accel(
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mcu_time + decel_time_offset, closest_d - decel_up_d,
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step_dist, closest_d - decel_offset,
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closest_height2, height, movez_r, -accel_multiplier)
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height += count * step_dist
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if accel_down_d > 0.:
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count = mcu_stepper.step_delta_accel(
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mcu_time - accel_time_offset, closest_d - accel_down_d,
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-step_dist, closest_d + accel_offset,
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closest_height2, height, movez_r, accel_multiplier)
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height += count * step_dist
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if cruise_down_d > 0.:
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count = mcu_stepper.step_delta_const(
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mcu_time + accel_t, closest_d - cruise_down_d,
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-step_dist, closest_d - accel_d,
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closest_height2, height, movez_r, inv_cruise_v)
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height += count * step_dist
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if decel_down_d > 0.:
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count = mcu_stepper.step_delta_accel(
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mcu_time + decel_time_offset, closest_d - decel_down_d,
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-step_dist, closest_d - decel_offset,
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closest_height2, height, movez_r, -accel_multiplier)
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######################################################################
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# Matrix helper functions for 3x1 matrices
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######################################################################
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def matrix_cross(m1, m2):
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return [m1[1] * m2[2] - m1[2] * m2[1],
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m1[2] * m2[0] - m1[0] * m2[2],
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m1[0] * m2[1] - m1[1] * m2[0]]
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def matrix_dot(m1, m2):
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return m1[0] * m2[0] + m1[1] * m2[1] + m1[2] * m2[2]
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def matrix_magsq(m1):
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return m1[0]**2 + m1[1]**2 + m1[2]**2
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def matrix_sub(m1, m2):
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return [m1[0] - m2[0], m1[1] - m2[1], m1[2] - m2[2]]
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def matrix_mul(m1, s):
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return [m1[0]*s, m1[1]*s, m1[2]*s]
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