Use last probe point to correct Z when possible
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@ -3397,6 +3397,8 @@ inline void gcode_G28() {
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bed_leveling_in_progress = true;
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float xProbe, yProbe, measured_z = 0;
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#if ENABLED(AUTO_BED_LEVELING_GRID)
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// probe at the points of a lattice grid
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@ -3434,8 +3436,8 @@ inline void gcode_G28() {
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bool zig = auto_bed_leveling_grid_points & 1; //always end at [RIGHT_PROBE_BED_POSITION, BACK_PROBE_BED_POSITION]
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for (uint8_t yCount = 0; yCount < auto_bed_leveling_grid_points; yCount++) {
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float yBase = front_probe_bed_position + yGridSpacing * yCount,
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yProbe = floor(yBase + (yBase < 0 ? 0 : 0.5));
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float yBase = front_probe_bed_position + yGridSpacing * yCount;
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yProbe = floor(yBase + (yBase < 0 ? 0 : 0.5));
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int8_t xStart, xStop, xInc;
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if (zig) {
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@ -3452,8 +3454,8 @@ inline void gcode_G28() {
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zig = !zig;
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for (int8_t xCount = xStart; xCount != xStop; xCount += xInc) {
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float xBase = left_probe_bed_position + xGridSpacing * xCount,
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xProbe = floor(xBase + (xBase < 0 ? 0 : 0.5));
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float xBase = left_probe_bed_position + xGridSpacing * xCount;
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xProbe = floor(xBase + (xBase < 0 ? 0 : 0.5));
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#if ENABLED(DELTA)
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// Avoid probing outside the round or hexagonal area of a delta printer
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@ -3497,12 +3499,12 @@ inline void gcode_G28() {
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vector_3(ABL_PROBE_PT_3_X, ABL_PROBE_PT_3_Y, 0)
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};
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for (uint8_t i = 0; i < 3; ++i)
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points[i].z = probe_pt(
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LOGICAL_X_POSITION(points[i].x),
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LOGICAL_Y_POSITION(points[i].y),
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stow_probe_after_each, verbose_level
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);
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for (uint8_t i = 0; i < 3; ++i) {
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// Retain the last probe position
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xProbe = LOGICAL_X_POSITION(points[i].x);
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yProbe = LOGICAL_Y_POSITION(points[i].y);
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measured_z = points[i].z = probe_pt(xProbe, yProbe, stow_probe_after_each, verbose_level);
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}
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if (!dryrun) {
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vector_3 planeNormal = vector_3::cross(points[0] - points[1], points[2] - points[1]).get_normal();
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@ -3635,42 +3637,50 @@ inline void gcode_G28() {
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// Correct the current XYZ position based on the tilted plane.
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//
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// Get the distance from the reference point to the current position
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// The current XY is in sync with the planner/steppers at this point
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// but the current Z is only known to the steppers.
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// 1. Get the distance from the current position to the reference point.
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float x_dist = RAW_CURRENT_POSITION(X_AXIS) - X_TILT_FULCRUM,
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y_dist = RAW_CURRENT_POSITION(Y_AXIS) - Y_TILT_FULCRUM,
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z_real = RAW_Z_POSITION(stepper.get_axis_position_mm(Z_AXIS));
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z_real = RAW_CURRENT_POSITION(Z_AXIS),
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z_zero = 0;
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#if ENABLED(DEBUG_LEVELING_FEATURE)
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if (DEBUGGING(LEVELING)) {
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SERIAL_ECHOPAIR("BEFORE ROTATION ... x_dist:", x_dist);
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SERIAL_ECHOPAIR("y_dist:", y_dist);
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SERIAL_ECHOPAIR("z_real:", z_real);
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}
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if (DEBUGGING(LEVELING)) DEBUG_POS("G29 uncorrected XYZ", current_position);
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#endif
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// Apply the matrix to the distance from the reference point to XY,
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// and from the homed Z to the current Z.
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apply_rotation_xyz(planner.bed_level_matrix, x_dist, y_dist, z_real);
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matrix_3x3 inverse = matrix_3x3::transpose(planner.bed_level_matrix);
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#if ENABLED(DEBUG_LEVELING_FEATURE)
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if (DEBUGGING(LEVELING)) {
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SERIAL_ECHOPAIR("AFTER ROTATION ... x_dist:", x_dist);
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SERIAL_ECHOPAIR("y_dist:", y_dist);
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SERIAL_ECHOPAIR("z_real:", z_real);
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}
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#endif
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// 2. Apply the inverse matrix to the distance
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// from the reference point to X, Y, and zero.
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apply_rotation_xyz(inverse, x_dist, y_dist, z_zero);
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// Apply the rotated distance and Z to the current position
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current_position[X_AXIS] = LOGICAL_X_POSITION(X_TILT_FULCRUM + x_dist);
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current_position[Y_AXIS] = LOGICAL_Y_POSITION(Y_TILT_FULCRUM + y_dist);
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current_position[Z_AXIS] = LOGICAL_Z_POSITION(z_real);
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// 3. Get the matrix-based corrected Z.
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// (Even if not used, get it for comparison.)
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float new_z = z_real + z_zero;
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// 4. Use the last measured distance to the bed, if possible
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if ( NEAR(current_position[X_AXIS], xProbe - (X_PROBE_OFFSET_FROM_EXTRUDER))
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&& NEAR(current_position[Y_AXIS], yProbe - (Y_PROBE_OFFSET_FROM_EXTRUDER))
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) {
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float simple_z = z_real - (measured_z - (-zprobe_zoffset));
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#if ENABLED(DEBUG_LEVELING_FEATURE)
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if (DEBUGGING(LEVELING)) {
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SERIAL_ECHOPAIR("Z from Probe:", simple_z);
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SERIAL_ECHOPAIR(" Matrix:", new_z);
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SERIAL_ECHOLNPAIR(" Discrepancy:", simple_z - new_z);
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}
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#endif
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new_z = simple_z;
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}
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// 5. The rotated XY and corrected Z are now current_position
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current_position[X_AXIS] = LOGICAL_X_POSITION(x_dist) + X_TILT_FULCRUM;
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current_position[Y_AXIS] = LOGICAL_Y_POSITION(y_dist) + Y_TILT_FULCRUM;
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current_position[Z_AXIS] = LOGICAL_Z_POSITION(new_z);
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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("> corrected XYZ in G29", current_position);
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if (DEBUGGING(LEVELING)) DEBUG_POS("G29 corrected XYZ", current_position);
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#endif
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}
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@ -7962,8 +7972,8 @@ void set_current_from_steppers_for_axis(AxisEnum axis) {
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LOOP_XYZE(i) difference[i] = target[i] - current_position[i];
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float cartesian_mm = sqrt(sq(difference[X_AXIS]) + sq(difference[Y_AXIS]) + sq(difference[Z_AXIS]));
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if (cartesian_mm < 0.000001) cartesian_mm = abs(difference[E_AXIS]);
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if (cartesian_mm < 0.000001) return false;
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if (UNEAR_ZERO(cartesian_mm)) cartesian_mm = abs(difference[E_AXIS]);
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if (UNEAR_ZERO(cartesian_mm)) return false;
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float _feedrate_mm_s = MMS_SCALED(feedrate_mm_s);
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float seconds = cartesian_mm / _feedrate_mm_s;
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int steps = max(1, int(delta_segments_per_second * seconds));
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