301 lines
10 KiB
C++
301 lines
10 KiB
C++
/**
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* Marlin 3D Printer Firmware
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* Copyright (C) 2016 MarlinFirmware [https://github.com/MarlinFirmware/Marlin]
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*
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* Based on Sprinter and grbl.
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* Copyright (C) 2011 Camiel Gubbels / Erik van der Zalm
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*
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* This program is free software: you can redistribute it and/or modify
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* it under the terms of the GNU General Public License as published by
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* the Free Software Foundation, either version 3 of the License, or
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* (at your option) any later version.
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*
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* This program is distributed in the hope that it will be useful,
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* but WITHOUT ANY WARRANTY; without even the implied warranty of
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
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* GNU General Public License for more details.
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*
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* You should have received a copy of the GNU General Public License
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* along with this program. If not, see <http://www.gnu.org/licenses/>.
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*
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*/
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/**
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* delta.cpp
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*/
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#include "../inc/MarlinConfig.h"
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#if ENABLED(DELTA)
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#include "delta.h"
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#include "motion.h"
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// For homing:
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#include "planner.h"
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#include "endstops.h"
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#include "../lcd/ultralcd.h"
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#include "../Marlin.h"
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#if ENABLED(SENSORLESS_HOMING)
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#include "../feature/tmc_util.h"
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#endif
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// Initialized by settings.load()
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float delta_height,
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delta_endstop_adj[ABC] = { 0 },
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delta_radius,
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delta_diagonal_rod,
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delta_segments_per_second,
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delta_calibration_radius,
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delta_tower_angle_trim[ABC];
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float delta_tower[ABC][2],
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delta_diagonal_rod_2_tower[ABC],
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delta_clip_start_height = Z_MAX_POS;
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float delta_safe_distance_from_top();
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/**
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* Recalculate factors used for delta kinematics whenever
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* settings have been changed (e.g., by M665).
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*/
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void recalc_delta_settings() {
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const float trt[ABC] = DELTA_RADIUS_TRIM_TOWER,
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drt[ABC] = DELTA_DIAGONAL_ROD_TRIM_TOWER;
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delta_tower[A_AXIS][X_AXIS] = cos(RADIANS(210 + delta_tower_angle_trim[A_AXIS])) * (delta_radius + trt[A_AXIS]); // front left tower
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delta_tower[A_AXIS][Y_AXIS] = sin(RADIANS(210 + delta_tower_angle_trim[A_AXIS])) * (delta_radius + trt[A_AXIS]);
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delta_tower[B_AXIS][X_AXIS] = cos(RADIANS(330 + delta_tower_angle_trim[B_AXIS])) * (delta_radius + trt[B_AXIS]); // front right tower
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delta_tower[B_AXIS][Y_AXIS] = sin(RADIANS(330 + delta_tower_angle_trim[B_AXIS])) * (delta_radius + trt[B_AXIS]);
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delta_tower[C_AXIS][X_AXIS] = cos(RADIANS( 90 + delta_tower_angle_trim[C_AXIS])) * (delta_radius + trt[C_AXIS]); // back middle tower
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delta_tower[C_AXIS][Y_AXIS] = sin(RADIANS( 90 + delta_tower_angle_trim[C_AXIS])) * (delta_radius + trt[C_AXIS]);
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delta_diagonal_rod_2_tower[A_AXIS] = sq(delta_diagonal_rod + drt[A_AXIS]);
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delta_diagonal_rod_2_tower[B_AXIS] = sq(delta_diagonal_rod + drt[B_AXIS]);
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delta_diagonal_rod_2_tower[C_AXIS] = sq(delta_diagonal_rod + drt[C_AXIS]);
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update_software_endstops(Z_AXIS);
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axis_homed[X_AXIS] = axis_homed[Y_AXIS] = axis_homed[Z_AXIS] = false;
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}
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/**
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* Delta Inverse Kinematics
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*
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* Calculate the tower positions for a given machine
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* position, storing the result in the delta[] array.
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*
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* This is an expensive calculation, requiring 3 square
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* roots per segmented linear move, and strains the limits
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* of a Mega2560 with a Graphical Display.
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*
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* Suggested optimizations include:
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*
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* - Disable the home_offset (M206) and/or position_shift (G92)
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* features to remove up to 12 float additions.
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*
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* - Use a fast-inverse-sqrt function and add the reciprocal.
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* (see above)
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*/
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#if ENABLED(DELTA_FAST_SQRT) && defined(__AVR__)
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/**
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* Fast inverse sqrt from Quake III Arena
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* See: https://en.wikipedia.org/wiki/Fast_inverse_square_root
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*/
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float Q_rsqrt(float number) {
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long i;
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float x2, y;
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const float threehalfs = 1.5f;
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x2 = number * 0.5f;
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y = number;
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i = * ( long * ) &y; // evil floating point bit level hacking
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i = 0x5F3759DF - ( i >> 1 ); // what the f***?
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y = * ( float * ) &i;
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y = y * ( threehalfs - ( x2 * y * y ) ); // 1st iteration
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// y = y * ( threehalfs - ( x2 * y * y ) ); // 2nd iteration, this can be removed
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return y;
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}
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#endif
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#define DELTA_DEBUG(VAR) do { \
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SERIAL_ECHOPAIR("cartesian X:", VAR[X_AXIS]); \
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SERIAL_ECHOPAIR(" Y:", VAR[Y_AXIS]); \
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SERIAL_ECHOLNPAIR(" Z:", VAR[Z_AXIS]); \
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SERIAL_ECHOPAIR("delta A:", delta[A_AXIS]); \
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SERIAL_ECHOPAIR(" B:", delta[B_AXIS]); \
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SERIAL_ECHOLNPAIR(" C:", delta[C_AXIS]); \
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}while(0)
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void inverse_kinematics(const float raw[XYZ]) {
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#if HOTENDS > 1
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// Delta hotend offsets must be applied in Cartesian space with no "spoofing"
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const float pos[XYZ] = {
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raw[X_AXIS] - hotend_offset[X_AXIS][active_extruder],
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raw[Y_AXIS] - hotend_offset[Y_AXIS][active_extruder],
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raw[Z_AXIS]
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};
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DELTA_IK(pos);
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//DELTA_DEBUG(pos);
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#else
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DELTA_IK(raw);
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//DELTA_DEBUG(raw);
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#endif
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}
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/**
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* Calculate the highest Z position where the
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* effector has the full range of XY motion.
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*/
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float delta_safe_distance_from_top() {
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float cartesian[XYZ] = { 0, 0, 0 };
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inverse_kinematics(cartesian);
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float centered_extent = delta[A_AXIS];
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cartesian[Y_AXIS] = DELTA_PRINTABLE_RADIUS;
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inverse_kinematics(cartesian);
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return ABS(centered_extent - delta[A_AXIS]);
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}
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/**
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* Delta Forward Kinematics
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*
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* See the Wikipedia article "Trilateration"
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* https://en.wikipedia.org/wiki/Trilateration
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*
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* Establish a new coordinate system in the plane of the
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* three carriage points. This system has its origin at
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* tower1, with tower2 on the X axis. Tower3 is in the X-Y
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* plane with a Z component of zero.
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* We will define unit vectors in this coordinate system
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* in our original coordinate system. Then when we calculate
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* the Xnew, Ynew and Znew values, we can translate back into
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* the original system by moving along those unit vectors
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* by the corresponding values.
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*
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* Variable names matched to Marlin, c-version, and avoid the
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* use of any vector library.
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*
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* by Andreas Hardtung 2016-06-07
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* based on a Java function from "Delta Robot Kinematics V3"
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* by Steve Graves
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*
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* The result is stored in the cartes[] array.
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*/
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void forward_kinematics_DELTA(float z1, float z2, float z3) {
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// Create a vector in old coordinates along x axis of new coordinate
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float p12[3] = { delta_tower[B_AXIS][X_AXIS] - delta_tower[A_AXIS][X_AXIS], delta_tower[B_AXIS][Y_AXIS] - delta_tower[A_AXIS][Y_AXIS], z2 - z1 };
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// Get the Magnitude of vector.
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float d = SQRT( sq(p12[0]) + sq(p12[1]) + sq(p12[2]) );
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// Create unit vector by dividing by magnitude.
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float ex[3] = { p12[0] / d, p12[1] / d, p12[2] / d };
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// Get the vector from the origin of the new system to the third point.
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float p13[3] = { delta_tower[C_AXIS][X_AXIS] - delta_tower[A_AXIS][X_AXIS], delta_tower[C_AXIS][Y_AXIS] - delta_tower[A_AXIS][Y_AXIS], z3 - z1 };
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// Use the dot product to find the component of this vector on the X axis.
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float i = ex[0] * p13[0] + ex[1] * p13[1] + ex[2] * p13[2];
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// Create a vector along the x axis that represents the x component of p13.
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float iex[3] = { ex[0] * i, ex[1] * i, ex[2] * i };
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// Subtract the X component from the original vector leaving only Y. We use the
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// variable that will be the unit vector after we scale it.
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float ey[3] = { p13[0] - iex[0], p13[1] - iex[1], p13[2] - iex[2] };
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// The magnitude of Y component
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float j = SQRT( sq(ey[0]) + sq(ey[1]) + sq(ey[2]) );
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// Convert to a unit vector
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ey[0] /= j; ey[1] /= j; ey[2] /= j;
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// The cross product of the unit x and y is the unit z
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// float[] ez = vectorCrossProd(ex, ey);
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float ez[3] = {
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ex[1] * ey[2] - ex[2] * ey[1],
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ex[2] * ey[0] - ex[0] * ey[2],
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ex[0] * ey[1] - ex[1] * ey[0]
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};
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// We now have the d, i and j values defined in Wikipedia.
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// Plug them into the equations defined in Wikipedia for Xnew, Ynew and Znew
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float Xnew = (delta_diagonal_rod_2_tower[A_AXIS] - delta_diagonal_rod_2_tower[B_AXIS] + sq(d)) / (d * 2),
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Ynew = ((delta_diagonal_rod_2_tower[A_AXIS] - delta_diagonal_rod_2_tower[C_AXIS] + HYPOT2(i, j)) / 2 - i * Xnew) / j,
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Znew = SQRT(delta_diagonal_rod_2_tower[A_AXIS] - HYPOT2(Xnew, Ynew));
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// Start from the origin of the old coordinates and add vectors in the
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// old coords that represent the Xnew, Ynew and Znew to find the point
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// in the old system.
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cartes[X_AXIS] = delta_tower[A_AXIS][X_AXIS] + ex[0] * Xnew + ey[0] * Ynew - ez[0] * Znew;
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cartes[Y_AXIS] = delta_tower[A_AXIS][Y_AXIS] + ex[1] * Xnew + ey[1] * Ynew - ez[1] * Znew;
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cartes[Z_AXIS] = z1 + ex[2] * Xnew + ey[2] * Ynew - ez[2] * Znew;
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}
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#if ENABLED(SENSORLESS_HOMING)
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inline void delta_sensorless_homing(const bool on=true) {
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sensorless_homing_per_axis(A_AXIS, on);
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sensorless_homing_per_axis(B_AXIS, on);
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sensorless_homing_per_axis(C_AXIS, on);
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}
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#endif
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/**
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* A delta can only safely home all axes at the same time
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* This is like quick_home_xy() but for 3 towers.
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*/
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bool home_delta() {
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#if ENABLED(DEBUG_LEVELING_FEATURE)
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if (DEBUGGING(LEVELING)) DEBUG_POS(">>> home_delta", current_position);
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#endif
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// Init the current position of all carriages to 0,0,0
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ZERO(current_position);
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sync_plan_position();
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// Disable stealthChop if used. Enable diag1 pin on driver.
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#if ENABLED(SENSORLESS_HOMING)
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delta_sensorless_homing();
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#endif
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// Move all carriages together linearly until an endstop is hit.
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current_position[X_AXIS] = current_position[Y_AXIS] = current_position[Z_AXIS] = (delta_height + 10);
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feedrate_mm_s = homing_feedrate(X_AXIS);
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line_to_current_position();
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planner.synchronize();
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// Re-enable stealthChop if used. Disable diag1 pin on driver.
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#if ENABLED(SENSORLESS_HOMING)
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delta_sensorless_homing(false);
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#endif
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// If an endstop was not hit, then damage can occur if homing is continued.
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// This can occur if the delta height not set correctly.
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if (!(endstops.trigger_state() & (_BV(X_MAX) | _BV(Y_MAX) | _BV(Z_MAX)))) {
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LCD_MESSAGEPGM(MSG_ERR_HOMING_FAILED);
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SERIAL_ERROR_START();
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SERIAL_ERRORLNPGM(MSG_ERR_HOMING_FAILED);
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return false;
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}
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endstops.hit_on_purpose(); // clear endstop hit flags
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// At least one carriage has reached the top.
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// Now re-home each carriage separately.
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HOMEAXIS(A);
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HOMEAXIS(B);
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HOMEAXIS(C);
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// Set all carriages to their home positions
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// Do this here all at once for Delta, because
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// XYZ isn't ABC. Applying this per-tower would
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// give the impression that they are the same.
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LOOP_XYZ(i) set_axis_is_at_home((AxisEnum)i);
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SYNC_PLAN_POSITION_KINEMATIC();
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#if ENABLED(DEBUG_LEVELING_FEATURE)
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if (DEBUGGING(LEVELING)) DEBUG_POS("<<< home_delta", current_position);
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#endif
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return true;
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}
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#endif // DELTA
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