WIP

2025-09-02 19:02:35 +02:00 · 2020-09-30 10:54:42 -05:00
parent f866a57828
commit ed157d7f25
3 changed files with 23 additions and 138 deletions
--- a/Grbl_Esp32/Custom/parallel_delta.cpp
+++ b/Grbl_Esp32/Custom/parallel_delta.cpp
@@ -90,7 +90,7 @@ void machine_init() {
    calc_forward_kinematics(angles, cartesian);  // Sets the cartesian values
    delta_z_offset = cartesian[Z_AXIS];

-    // print a startup message to show the kinematics are enables
+    // print a startup message to show the kinematics are enabled. Print the offset for reference
    grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Delta Kinematics Init: %s Z Offset:%4.3f", MACHINE_NAME, delta_z_offset);
 }

@@ -98,11 +98,18 @@ bool user_defined_homing() {  // true = do not continue with normal Grbl homing
 #ifdef USE_CUSTOM_HOMING
    return true;
 #else
-    //grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "User defined homing");
    return false;
 #endif
 }

+void inverse_kinematics(float* position) {
+    float motor_angles[3];
+    delta_calcInverse(position, motor_angles);
+    position[0] = motor_angles[0];
+    position[1] = motor_angles[1];
+    position[2] = motor_angles[2];
+}
+
 void inverse_kinematics(float* target, plan_line_data_t* pl_data, float* position)  //The target and position are provided in MPos
 {
    float dx, dy, dz;  // distances in each cartesian axis
@@ -110,31 +117,33 @@ void inverse_kinematics(float* target, plan_line_data_t* pl_data, float* positio

    float seg_target[3];                              // The target of the current segment
    float feed_rate            = pl_data->feed_rate;  // save original feed rate
-    bool           start_position_erorr = false;
+    bool  start_position_error = false;
    bool  show_error           = true;  // shows error once

    KinematicError status;

-    //grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Target:  %3.3f %3.3f %3.3f", target[0], target[1], target[2]);
-    //grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Position:  %3.3f %3.3f %3.3f", position[0], position[1], position[2]);
+    grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Start %3.3f %3.3f %3.3f", position[0], position[1], position[2]);
+    grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Target %3.3f %3.3f %3.3f", target[0], target[1], target[2]);
+    

    status = delta_calcInverse(position, motor_angles);
    if (status == KinematicError::OUT_OF_RANGE) {
        grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Start position error %3.3f %3.3f %3.3f", position[0], position[1], position[2]);
-        //start_position_erorr = true;
+        start_position_error = true;
    }

    // Check the destination to see if it is in work area
    status = delta_calcInverse(target, motor_angles);
    if (status == KinematicError::OUT_OF_RANGE) {
        grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Target unreachable  error %3.3f %3.3f %3.3f", target[0], target[1], target[2]);
-        //return;
+        return;
    }

    position[X_AXIS] += gc_state.coord_offset[X_AXIS];
    position[Y_AXIS] += gc_state.coord_offset[Y_AXIS];
    position[Z_AXIS] += gc_state.coord_offset[Z_AXIS];

+    // calculate cartesian move distance for each axis
    dx         = target[X_AXIS] - position[X_AXIS];
    dy         = target[Y_AXIS] - position[Y_AXIS];
    dz         = target[Z_AXIS] - position[Z_AXIS];
@@ -143,19 +152,14 @@ void inverse_kinematics(float* target, plan_line_data_t* pl_data, float* positio
    // determine the number of segments we need	... round up so there is at least 1 (except when dist is 0)
    uint32_t segment_count = ceil(dist / KINEMATIC_SEGMENT_LENGTH);

-    //grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Dist %3.3f Segemnts %d", dist, segment_count);
-
    float segment_dist = dist / ((float)segment_count);  // distance of each segment...will be used for feedrate conversion

-
    for (uint32_t segment = 1; segment <= segment_count; segment++) {
        // determine this segment's target
        seg_target[X_AXIS] = position[X_AXIS] + (dx / float(segment_count) * segment);
        seg_target[Y_AXIS] = position[Y_AXIS] + (dy / float(segment_count) * segment);
        seg_target[Z_AXIS] = position[Z_AXIS] + (dz / float(segment_count) * segment);

-        //grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Segment Target: %3.3f %3.3f %3.3f", seg_target[0], seg_target[1], seg_target[2]);
-
        // calculate the delta motor angles
        KinematicError status = delta_calcInverse(seg_target, motor_angles);

@@ -171,7 +175,6 @@ void inverse_kinematics(float* target, plan_line_data_t* pl_data, float* positio
                pl_data->feed_rate = (feed_rate * delta_distance / segment_dist);
            }

-           
            mc_line(motor_angles, pl_data);

        } else {
@@ -187,128 +190,6 @@ void inverse_kinematics(float* target, plan_line_data_t* pl_data, float* positio
            }
        }
    }
-    
-}
-
-void inverse_kinematic2(float* target, plan_line_data_t* pl_data, float* position)  //The target and position are provided in MPos
-{
-    float dx, dy, dz;  // distances in each cartesian axis
-    float motor_angles[3];
-
-    float seg_target[3];                   // The target of the current segment
-    float feed_rate = pl_data->feed_rate;  // save original feed rate
-    //bool           start_position_erorr = false;
-    bool  show_error = true;  // shows error once
-    float pos_cart[3];
-    float inital_position[3];
-
-    KinematicError status;
-
-    //memcpy(inital_position, position, sizeof(position));
-
-    // determine the initial position.
-    inital_position[X_AXIS] = position[X_AXIS] + gc_state.coord_system[X_AXIS];
-    inital_position[Y_AXIS] = position[Y_AXIS] + gc_state.coord_system[Y_AXIS];
-    inital_position[Z_AXIS] = position[Z_AXIS] + gc_state.coord_system[Z_AXIS];
-
-    //grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Init Pos:  %3.3f %3.3f %3.3f", inital_position[0], inital_position[1], inital_position[2]);
-    grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Target:  %3.3f %3.3f %3.3f", target[0], target[1], target[2]);
-    grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Position:  %3.3f %3.3f %3.3f", position[0], position[1], position[2]);
-
-    status = delta_calcInverse(inital_position, motor_angles);
-
-    if (status == KinematicError::OUT_OF_RANGE) {
-        grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Start position error %3.3f %3.3f %3.3f", position[0], position[1], position[2]);
-        //start_position_erorr = true;
-    }
-
-    // Check the destination to see if it is in work area
-    status = delta_calcInverse(target, motor_angles);
-
-    if (status == KinematicError::OUT_OF_RANGE) {
-        grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Target unreachable  error %3.3f %3.3f %3.3f", target[0], target[1], target[2]);
-        //return;
-    }
-
-    //target[Z_AXIS] -= delta_z_offset;  // restore it
-    //memcpy(position, target, sizeof(target));
-    //memcpy(last_angle, motor_angles, sizeof(motor_angles));
-
-    // calculate cartesian move distance for each axis
-    //return;
-    dx         = target[X_AXIS] - inital_position[X_AXIS];
-    dy         = target[Y_AXIS] - inital_position[Y_AXIS];
-    dz         = target[Z_AXIS] - inital_position[Z_AXIS];
-    float dist = sqrt((dx * dx) + (dy * dy) + (dz * dz));
-
-    // determine the number of segments we need	... round up so there is at least 1 (except when dist is 0)
-    uint32_t segment_count = ceil(dist / KINEMATIC_SEGMENT_LENGTH);
-
-    grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Dist %3.3f Segemnts %d", dist, segment_count);
-
-    float segment_dist = dist / ((float)segment_count);  // distance of each segment...will be used for feedrate conversion
-
-    //position[X_AXIS] = target[X_AXIS] + gc_state.coord_system[X_AXIS];
-    //position[Y_AXIS] = target[Y_AXIS] + gc_state.coord_system[Y_AXIS];
-    //position[Z_AXIS] = target[Z_AXIS] + gc_state.coord_system[Z_AXIS];
-    // grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Position Return: %3.3f %3.3f %3.3f", position[0], position[1], position[2]);
-    // mc_line(motor_angles, pl_data);
-    // return;
-
-    for (uint32_t segment = 1; segment <= segment_count; segment++) {
-        // determine this segment's target
-        seg_target[X_AXIS] = inital_position[X_AXIS] + (dx / float(segment_count) * segment);
-        seg_target[Y_AXIS] = inital_position[Y_AXIS] + (dy / float(segment_count) * segment);
-        seg_target[Z_AXIS] = inital_position[Z_AXIS] + (dz / float(segment_count) * segment);
-
-        // seg_target[X_AXIS] = target[X_AXIS] + (dx / float(segment_count) * segment);
-        // seg_target[Y_AXIS] = target[Y_AXIS] + (dy / float(segment_count) * segment);
-        // seg_target[Z_AXIS] = target[Z_AXIS] + (dz / float(segment_count) * segment);
-
-        grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Segment Target: %3.3f %3.3f %3.3f", seg_target[0], seg_target[1], seg_target[2]);
-
-        // calculate the delta motor angles
-        KinematicError status = delta_calcInverse(seg_target, motor_angles);
-
-        if (status == KinematicError ::NONE) {
-            float delta_distance = three_axis_dist(motor_angles, last_angle);
-
-            // save angles for next distance calc
-            memcpy(last_angle, motor_angles, sizeof(motor_angles));
-
-            if (pl_data->motion.rapidMotion) {
-                pl_data->feed_rate = feed_rate;
-            } else {
-                pl_data->feed_rate = (feed_rate * delta_distance / segment_dist);
-            }
-
-            //position[X_AXIS] = seg_target[X_AXIS] + gc_state.coord_system[X_AXIS];
-            //position[Y_AXIS] = seg_target[Y_AXIS] + gc_state.coord_system[Y_AXIS];
-            //position[Z_AXIS] = seg_target[Z_AXIS] + gc_state.coord_system[Z_AXIS];
-
-            mc_line(motor_angles, pl_data);
-
-        } else {
-            if (show_error) {
-                grbl_msg_sendf(CLIENT_SERIAL,
-                               MsgLevel::Info,
-                               "Error:%d, Angs X:%4.3f Y:%4.3f Z:%4.3f]\r\n\r\n",
-                               status,
-                               motor_angles[0],
-                               motor_angles[1],
-                               motor_angles[2]);
-                show_error = false;
-            }
-        }
-    }
-    position[X_AXIS] = target[X_AXIS] - gc_state.coord_system[X_AXIS];
-    position[Y_AXIS] = target[Y_AXIS] - gc_state.coord_system[Y_AXIS];
-    position[Z_AXIS] = target[Z_AXIS] - gc_state.coord_system[Z_AXIS];
-
-    // position[X_AXIS] = target[X_AXIS];
-    // position[Y_AXIS] = target[Y_AXIS];
-    // position[Z_AXIS] = target[Z_AXIS];
-    grbl_msg_sendf(CLIENT_SERIAL, MsgLevel::Info, "Position Return: %3.3f %3.3f %3.3f", position[0], position[1], position[2]);
 }

 // inverse kinematics: cartesian -> angles
--- a/Grbl_Esp32/src/GCode.cpp
+++ b/Grbl_Esp32/src/GCode.cpp
@@ -1477,6 +1477,8 @@ Error gc_execute_line(char* line, uint8_t client) {
            }
            mc_line(coord_data, pl_data);
            memcpy(gc_state.position, coord_data, sizeof(gc_state.position));
+            == == == = mc_line_kins(gc_block.values.ijk, pl_data, gc_state.position);
+            memcpy(gc_state.position, gc_block.values.ijk, MAX_N_AXIS * sizeof(float));
            break;
        case NonModal::SetHome0:
            coords[CoordIndex::G28]->set(gc_state.position);
--- a/Grbl_Esp32/src/Grbl.h
+++ b/Grbl_Esp32/src/Grbl.h
@@ -99,11 +99,13 @@ void machine_init();
 bool user_defined_homing();

 // Called if USE_KINEMATICS is defined
+
 void inverse_kinematics(float* target, plan_line_data_t* pl_data, float* position);
 bool kinematics_pre_homing(uint8_t cycle_mask);
 void kinematics_post_homing();

 // Called if USE_FWD_KINEMATICS is defined
+void inverse_kinematics(float* position);  // used to return a converted value
 void forward_kinematics(float* position);

 // Called if MACRO_BUTTON_0_PIN or MACRO_BUTTON_1_PIN or MACRO_BUTTON_2_PIN is defined