kopia lustrzana https://github.com/gnea/grbl
support for helical motion
rodzic
8f3a69b37e
commit
e257fc195c
31
gcode.c
31
gcode.c
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@ -89,7 +89,7 @@ struct ParserState {
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double position[3]; /* Where the interpreter considers the tool to be at this point in the code */
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uint8_t tool;
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int16_t spindle_speed; /* RPM/100 */
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uint8_t plane_axis_0, plane_axis_1; // The axes of the selected plane
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uint8_t plane_axis_0, plane_axis_1, plane_axis_2; // The axes of the selected plane
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};
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struct ParserState gc;
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@ -103,21 +103,23 @@ int read_double(char *line, //!< string: line of RS274/NGC code being processed
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int next_statement(char *letter, double *double_ptr, char *line, int *counter);
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void select_plane(uint8_t axis_0, uint8_t axis_1, uint8_t axis_2)
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{
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gc.plane_axis_0 = axis_0;
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gc.plane_axis_1 = axis_1;
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gc.plane_axis_2 = axis_2;
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}
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void gc_init() {
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memset(&gc, 0, sizeof(gc));
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gc.feed_rate = DEFAULT_FEEDRATE;
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gc.plane_axis_0 = X_AXIS; gc.plane_axis_1 = Y_AXIS;
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select_plane(X_AXIS, Y_AXIS, Z_AXIS);
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}
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inline float to_millimeters(double value) {
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return(gc.inches_mode ? value * INCHES_PER_MM : value);
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}
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void select_plane(uint8_t axis_0, uint8_t axis_1)
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{
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gc.plane_axis_0 = axis_0;
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gc.plane_axis_1 = axis_1;
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}
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// Executes one line of 0-terminated G-Code. The line is assumed to contain only uppercase
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// characters and signed floats (no whitespace).
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@ -159,9 +161,9 @@ uint8_t gc_execute_line(char *line) {
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case 2: gc.motion_mode = MOTION_MODE_CW_ARC; break;
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case 3: gc.motion_mode = MOTION_MODE_CCW_ARC; break;
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case 4: next_action = NEXT_ACTION_DWELL; break;
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case 17: select_plane(X_AXIS, Y_AXIS); break;
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case 18: select_plane(X_AXIS, Z_AXIS); break;
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case 19: select_plane(Y_AXIS, Z_AXIS); break;
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case 17: select_plane(X_AXIS, Y_AXIS, Z_AXIS); break;
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case 18: select_plane(X_AXIS, Z_AXIS, Y_AXIS); break;
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case 19: select_plane(Y_AXIS, Z_AXIS, X_AXIS); break;
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case 20: gc.inches_mode = true; break;
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case 21: gc.inches_mode = false; break;
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case 28: case 30: next_action = NEXT_ACTION_GO_HOME; break;
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@ -306,6 +308,7 @@ uint8_t gc_execute_line(char *line) {
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// Calculate the change in position along each selected axis
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double x = target[gc.plane_axis_0]-gc.position[gc.plane_axis_0];
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double y = target[gc.plane_axis_1]-gc.position[gc.plane_axis_1];
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clear_vector(&offset);
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double h_x2_div_d = -sqrt(4 * r*r - x*x - y*y)/hypot(x,y); // == -(h * 2 / d)
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// If r is smaller than d, the arc is now traversing the complex plane beyond the reach of any
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@ -371,8 +374,14 @@ uint8_t gc_execute_line(char *line) {
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}
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// Find the radius
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double radius = hypot(offset[gc.plane_axis_0], offset[gc.plane_axis_1]);
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// Calculate the motion along the depth axis of the helix
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double depth = target[gc.plane_axis_2]-gc.position[gc.plane_axis_2];
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// Trace the arc
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mc_arc(theta_start, angular_travel, radius, gc.plane_axis_0, gc.plane_axis_1, gc.feed_rate);
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if (gc.inverse_feed_rate_mode) {
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mc_arc(theta_start, angular_travel, radius, depth, gc.plane_axis_0, gc.plane_axis_1, gc.plane_axis_2, inverse_feed_rate, true);
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} else {
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mc_arc(theta_start, angular_travel, radius, depth, gc.plane_axis_0, gc.plane_axis_1, gc.plane_axis_2, gc.feed_rate, false);
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}
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break;
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}
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}
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2
gcode.h
2
gcode.h
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@ -37,6 +37,6 @@ void gc_init();
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uint8_t gc_execute_line(char *line);
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// get the current logical position (in current units), the current status code and the unit mode
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void gc_get_status(double *position, uint8_t *status_code, int *inches_mode, uint32_t *line_number);
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void gc_get_status(double *position_, uint8_t *status_code_, int *inches_mode_, uint32_t *line_number_);
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#endif
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204
motion_control.c
204
motion_control.c
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@ -63,8 +63,21 @@ void mc_dwell(uint32_t milliseconds)
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mode = MC_MODE_AT_REST;
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}
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// Calculate the microseconds between steps that we should wait in order to travel the
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// designated amount of millimeters in the amount of steps we are going to generate
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void set_step_pace(double feed_rate, double millimeters_of_travel, uint32_t steps, int invert) {
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int32_t pace;
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if (invert) {
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pace = round(ONE_MINUTE_OF_MICROSECONDS/feed_rate/steps);
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} else {
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pace = round(((millimeters_of_travel * ONE_MINUTE_OF_MICROSECONDS) / feed_rate) / steps);
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}
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st_buffer_pace(pace);
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}
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// Execute linear motion in absolute millimeter coordinates. Feed rate given in millimeters/second
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// unless invert_feed_rate is true. Then the feed_rate states the number of seconds for the whole movement.
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// unless invert_feed_rate is true. Then the feed_rate means that the motion should be completed in
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// 1/feed_rate minutes.
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void mc_line(double x, double y, double z, float feed_rate, int invert_feed_rate)
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{
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// Flags to keep track of which axes to step
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@ -76,7 +89,6 @@ void mc_line(double x, double y, double z, float feed_rate, int invert_feed_rate
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counter[3], // A counter used in the bresenham algorithm for line plotting
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maximum_steps; // The larges absolute step-count of any axis
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// Setup ---------------------------------------------------------------------------------------------------
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target[X_AXIS] = x*X_STEPS_PER_MM;
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@ -98,25 +110,20 @@ void mc_line(double x, double y, double z, float feed_rate, int invert_feed_rate
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}
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// Set our direction pins
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set_stepper_directions(direction);
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// Calculate the microseconds we need to wait between each step to achieve the desired feed rate
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if (invert_feed_rate) {
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st_buffer_pace((feed_rate*1000000)/maximum_steps);
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} else {
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// Ask old Phytagoras to estimate how many mm our next move is going to take us:
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double millimeters_to_travel =
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sqrt(pow(X_STEPS_PER_MM*step_count[X_AXIS],2) +
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pow(Y_STEPS_PER_MM*step_count[Y_AXIS],2) +
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pow(Z_STEPS_PER_MM*step_count[Z_AXIS],2));
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// Calculate the microseconds between steps that we should wait in order to travel the
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// designated amount of millimeters in the amount of steps we are going to generate
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st_buffer_pace(((millimeters_to_travel * ONE_MINUTE_OF_MICROSECONDS) / feed_rate) / maximum_steps);
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}
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// Ask old Phytagoras to estimate how many mm our next move is going to take us
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double millimeters_of_travel =
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sqrt(pow(X_STEPS_PER_MM*step_count[X_AXIS],2) +
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pow(Y_STEPS_PER_MM*step_count[Y_AXIS],2) +
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pow(Z_STEPS_PER_MM*step_count[Z_AXIS],2));
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// And set the step pace
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set_step_pace(feed_rate, millimeters_of_travel, maximum_steps, invert_feed_rate);
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// Execution -----------------------------------------------------------------------------------------------
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mode = MC_MODE_LINEAR;
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while(mode) {
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do {
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// Trace the line
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step_bits = 0;
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for(axis = X_AXIS; axis <= Z_AXIS; axis++) {
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@ -131,23 +138,23 @@ void mc_line(double x, double y, double z, float feed_rate, int invert_feed_rate
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}
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}
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}
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if (step_bits) {
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step_steppers(step_bits);
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} else {
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mode = MC_MODE_AT_REST;
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}
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}
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if(step_bits) { step_steppers(step_bits); }
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} while (step_bits);
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mode = MC_MODE_AT_REST;
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}
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// Execute an arc. theta == start angle, angular_travel == number of radians to go along the arc,
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// positive angular_travel means clockwise, negative means counterclockwise. Radius == the radius of the
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// circle in millimeters. axis_1 and axis_2 selects the plane in tool space.
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// circle in millimeters. axis_1 and axis_2 selects the circle plane in tool space. Stick the remaining
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// axis in axis_l which will be the axis for linear travel if you are tracing a helical motion.
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// ISSUE: The arc interpolator assumes all axes have the same steps/mm as the X axis.
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void mc_arc(double theta, double angular_travel, double radius, int axis_1, int axis_2, double feed_rate)
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void mc_arc(double theta, double angular_travel, double radius, double linear_travel, int axis_1, int axis_2,
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int axis_linear, double feed_rate, int invert_feed_rate)
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{
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uint32_t start_x, start_y;
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uint32_t diagonal_error;
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uint32_t start_x, start_y; // The start position in the coordinate system local to the circle
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uint32_t diagonal_error; // A variable to keep track of varations in the error-value during
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// the tracing of the arc
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int8_t direction[3]; // The direction of travel along each axis (-1, 0 or 1)
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int8_t angular_direction; // 1 = clockwise, -1 = anticlockwise
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@ -156,19 +163,13 @@ void mc_arc(double theta, double angular_travel, double radius, int axis_1, int
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// center of the arc.
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int target_direction_x, target_direction_y; // signof(target_x)*angular_direction precalculated for speed
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int32_t error; // error is always == (x**2 + y**2 - radius**2),
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uint8_t axis_x, axis_y; // maps the arc axes to stepper axes
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int8_t diagonal_bits; // A bitmask with the stepper bits for both selected axes set
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int incomplete; // True if the arc has not reached its target yet
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int dx, dy; // Trace directions
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// Setup
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// Setup arc interpolation --------------------------------------------------------------------------------
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uint32_t radius_steps = round(radius*X_STEPS_PER_MM);
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if(radius_steps == 0) { return; }
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// Setup arc interpolation --------------------------------------------------------------------------------
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// Determine angular direction (+1 = clockwise, -1 = counterclockwise)
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angular_direction = signof(angular_travel);
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// Calculate the initial position and target position in the local coordinate system of the arc
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@ -183,12 +184,6 @@ void mc_arc(double theta, double angular_travel, double radius, int axis_1, int
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// <0 we are inside the arc, when it is >0 we are outside of the arc, and when it is 0 we
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// are exactly on top of the arc.
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error = x*x + y*y - radius_steps*radius_steps;
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// Set up a vector with the steppers we are going to use tracing the plane of this arc
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diagonal_bits = st_bit_for_stepper(axis_1);
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diagonal_bits |= st_bit_for_stepper(axis_2);
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// And map the local coordinate system of the arc onto the tool axes of the selected plane
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axis_x = axis_1;
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axis_y = axis_2;
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// Estimate length of arc in steps -------------------------------------------------------------------------
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@ -210,95 +205,126 @@ void mc_arc(double theta, double angular_travel, double radius, int axis_1, int
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+---- 2 ----+
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*/
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// Find the quadrants of the starting point and the target
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int start_quadrant = quadrant_of_the_circle(start_x, start_y);
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int target_quadrant = quadrant_of_the_circle(target_x, target_y);
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uint32_t steps_to_travel=0;
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// Is the start and target point in the same quadrant?
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uint32_t arc_steps=0;
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// Will this whole arc take place within the same quadrant?
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if (start_quadrant == target_quadrant && (abs(angular_travel) <= (M_PI/2))) {
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if(quadrant_horizontal(start_quadrant)) { // a horizontal quadrant where x will be the primary direction
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steps_to_travel = abs(target_x-start_x);
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arc_steps = abs(target_x-start_x);
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} else { // a vertical quadrant where y will be the primary direction
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steps_to_travel = abs(target_y-start_y);
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arc_steps = abs(target_y-start_y);
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}
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} else { // the start and target points are in different quadrants
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// Lets estimate the amount of steps along one full quadrant
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// Lets estimate the amount of steps along half a quadrant
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uint32_t steps_in_half_quadrant = ceil(radius_steps/sqrt(2));
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// Add the steps in the first partial quadrant
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steps_to_travel += steps_in_partial_quadrant(start_x, start_y,
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arc_steps += steps_in_partial_quadrant(start_x, start_y,
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start_quadrant, angular_direction, steps_in_half_quadrant);
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// Count the number of full quadrants between the start and end quadrants
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uint8_t full_quadrants_traveled = full_quadrants_between(start_quadrant, target_quadrant, angular_direction);
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// Add steps for the full quadrants plus some stray steps for "corners"
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steps_to_travel += full_quadrants_traveled*(steps_in_half_quadrant*2+1);
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arc_steps += full_quadrants_traveled*(steps_in_half_quadrant*2+1);
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// Add the steps in the final partial quadrant. By inverting the angular direction we get the correct number for
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// the target quadrant which steps through the opposite part of the quadrant with respect to the start quadrant.
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steps_to_travel += steps_in_partial_quadrant(target_x, target_y,
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arc_steps += steps_in_partial_quadrant(target_x, target_y,
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target_quadrant, -angular_direction, steps_in_half_quadrant);
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}
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// Set up the linear interpolation of the "depth" axis -----------------------------------------------------
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int32_t linear_steps = abs(st_millimeters_to_steps(linear_travel, axis_linear));
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int linear_direction = signof(linear_travel);
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// The number of steppings needed to trace this motion is equal to the motion that require the maximum
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// amount of steps: the arc or the line:
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int32_t maximum_steps = max(linear_steps, arc_steps);
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// Initialize the counters to do linear bresenham
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int32_t linear_counter = -maximum_steps/2;
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int32_t arc_counter = -maximum_steps/2;
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// Calculate feed rate -------------------------------------------------------------------------------------
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// The amount of steppings performed while tracing a half circle is equal to the sum of sides in a
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// square inscribed in the circle. We use this to estimate the amount of steps as if this arc was a half circle:
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uint32_t steps_in_half_circle = round((4*radius_steps)/sqrt(2));
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// We then calculate the millimeters of travel along the circumference of that same half circle
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double millimeters_half_circumference = radius*M_PI;
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// We then calculate the millimeters of helical travel
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double millimeters_of_travel = sqrt(pow(angular_travel*radius,2)+pow(abs(linear_travel),2));
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// Then we calculate the microseconds between each step as if we will trace the full circle.
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// It doesn't matter what fraction of the circle we are actually going to trace. The pace is the same.
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st_buffer_pace(((millimeters_half_circumference * ONE_MINUTE_OF_MICROSECONDS) / feed_rate) / steps_in_half_circle);
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set_step_pace(feed_rate, millimeters_of_travel, maximum_steps, invert_feed_rate);
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// Execution -----------------------------------------------------------------------------------------------
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mode = MC_MODE_ARC;
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direction[axis_linear] = linear_direction;
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uint8_t axis_1_bit = st_bit_for_stepper(axis_1);
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uint8_t axis_2_bit = st_bit_for_stepper(axis_2);
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uint8_t axis_linear_bit = st_bit_for_stepper(axis_linear);
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uint8_t diagonal_bits = (axis_1_bit | axis_2_bit);
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incomplete = true;
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while(incomplete)
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uint8_t step_bits;
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while(mode)
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{
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dx = (y!=0) ? signof(y) * angular_direction : -signof(x);
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dy = (x!=0) ? -signof(x) * angular_direction : -signof(y);
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// Take dx and dy which are local to the arc being generated and map them on to the
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// selected tool-space-axes for the current arc.
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direction[axis_x] = dx;
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direction[axis_y] = dy;
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set_stepper_directions(direction);
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// Check which axis will be "major" for this stepping
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if (abs(x)<abs(y)) {
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// Step arc horizontally
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error += 1 + 2*x * dx;
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x+=dx;
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diagonal_error = error + 1 + 2*y*dy;
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if(abs(error) >= abs(diagonal_error)) {
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y += dy;
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error = diagonal_error;
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step_steppers(diagonal_bits); // step diagonal
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// reset step bits
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step_bits = 0;
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// Do linear interpolation
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linear_counter += linear_steps;
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if (linear_counter > 0) {
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linear_counter -= maximum_steps;
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step_bits |= axis_linear_bit;
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}
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// Do arc interpolation
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arc_counter += arc_steps;
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if (arc_counter > 0) {
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arc_counter -= maximum_steps;
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// Determine directions for each axis at this point in the arc
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dx = (y!=0) ? signof(y) * angular_direction : -signof(x);
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dy = (x!=0) ? -signof(x) * angular_direction : -signof(y);
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// Take dx and dy which are local to the arc being generated and map them on to the
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// selected tool-space-axes for the current arc.
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direction[axis_1] = dx;
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direction[axis_2] = dy;
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// Check which axis will be "major" for this stepping
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if (abs(x)<abs(y)) {
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// X is major: Step arc horizontally
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error += 1 + 2*x * dx;
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x+=dx;
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diagonal_error = error + 1 + 2*y*dy;
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if(abs(error) >= abs(diagonal_error)) {
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y += dy;
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error = diagonal_error;
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step_bits |= diagonal_bits; // step diagonal
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} else {
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step_bits |= axis_1_bit; // step straight
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}
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} else {
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step_axis(axis_x); // step straight
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}
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} else {
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// Step arc vertically
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error += 1 + 2*y * dy;
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y+=dy;
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diagonal_error = error + 1 + 2*x * dx;
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if(abs(error) >= abs(diagonal_error)) {
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x += dx;
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error = diagonal_error;
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step_steppers(diagonal_bits); // step diagonal
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} else {
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step_axis(axis_y); // step straight
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// Y is major: Step arc vertically
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error += 1 + 2*y * dy;
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y+=dy;
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diagonal_error = error + 1 + 2*x * dx;
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if(abs(error) >= abs(diagonal_error)) {
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x += dx;
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error = diagonal_error;
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step_bits |= diagonal_bits; // step diagonal
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} else {
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step_bits |= axis_2_bit; // step straight
|
||||
}
|
||||
}
|
||||
}
|
||||
set_stepper_directions(direction);
|
||||
step_steppers(step_bits);
|
||||
|
||||
// Check if target has been reached. Todo: Simplify/optimize/clarify
|
||||
if ((x * target_direction_y >=
|
||||
target_x * target_direction_y) &&
|
||||
(y * target_direction_x <=
|
||||
target_y * target_direction_x))
|
||||
{ if ((signof(x) == signof(target_x)) && (signof(y) == signof(target_y)))
|
||||
{ incomplete = false; } }
|
||||
{ mode = MC_MODE_AT_REST; } }
|
||||
}
|
||||
// Update the tool position to the new actual position
|
||||
position[axis_x] += x-start_x;
|
||||
position[axis_y] += y-start_y;
|
||||
mode = MC_MODE_AT_REST;
|
||||
position[axis_1] += x-start_x;
|
||||
position[axis_2] += y-start_y;
|
||||
position[axis_2] += linear_steps*linear_direction;
|
||||
}
|
||||
|
||||
void mc_go_home()
|
||||
|
|
|
@ -32,8 +32,9 @@
|
|||
// Initializes the motion_control subsystem resources
|
||||
void mc_init();
|
||||
|
||||
// Prepare for linear motion in absolute millimeter coordinates. Feed rate given in millimeters/second
|
||||
// unless invert_feed_rate is true. Then the feed_rate states the number of seconds for the whole movement.
|
||||
// Execute linear motion in absolute millimeter coordinates. Feed rate given in millimeters/second
|
||||
// unless invert_feed_rate is true. Then the feed_rate means that the motion should be completed in
|
||||
// 1/feed_rate minutes.
|
||||
void mc_line(double x, double y, double z, float feed_rate, int invert_feed_rate);
|
||||
|
||||
// Prepare an arc. theta == start angle, angular_travel == number of radians to go along the arc,
|
||||
|
@ -41,19 +42,16 @@ void mc_line(double x, double y, double z, float feed_rate, int invert_feed_rate
|
|||
// circle in millimeters. axis_1 and axis_2 selects the plane in tool space.
|
||||
// Known issue: This method pretends that all axes uses the same steps/mm as the X axis. Which might
|
||||
// not be the case ... (To be continued)
|
||||
void mc_arc(double theta, double angular_travel, double radius, int axis_1, int axis_2, double feed_rate);
|
||||
// Regarding feed rate see note on mc_line.
|
||||
void mc_arc(double theta, double angular_travel, double radius, double linear_travel, int axis_1, int axis_2,
|
||||
int axis_linear, double feed_rate, int invert_feed_rate);
|
||||
|
||||
// Prepare linear motion relative to the current position.
|
||||
// Dwell for a couple of time units
|
||||
void mc_dwell(uint32_t milliseconds);
|
||||
|
||||
// Prepare to send the tool position home
|
||||
// Send the tool home
|
||||
void mc_go_home();
|
||||
|
||||
// Start the prepared operation. In the current implementation this will block for most of the task at hand.
|
||||
// In future implementations it might not block at all. If you want to make sure the system has reached
|
||||
// quiescence call mc_wait()
|
||||
void mc_execute();
|
||||
|
||||
// Check motion control status. result == 0: the system is idle. result > 0: the system is busy,
|
||||
// result < 0: the system is in an error state.
|
||||
int mc_status();
|
||||
|
|
11
stepper.c
11
stepper.c
|
@ -24,6 +24,7 @@
|
|||
|
||||
#include "stepper.h"
|
||||
#include "config.h"
|
||||
#include <math.h>
|
||||
#include "nuts_bolts.h"
|
||||
#include <avr/interrupt.h>
|
||||
|
||||
|
@ -286,3 +287,13 @@ void st_set_echo(int value)
|
|||
{
|
||||
echo_steps = value;
|
||||
}
|
||||
|
||||
// Convert from millimeters to step-counts along the designated axis
|
||||
int32_t st_millimeters_to_steps(double millimeters, int axis) {
|
||||
switch(axis) {
|
||||
case X_AXIS: return(round(millimeters*X_STEPS_PER_MM));
|
||||
case Y_AXIS: return(round(millimeters*Y_STEPS_PER_MM));
|
||||
case Z_AXIS: return(round(millimeters*Z_STEPS_PER_MM));
|
||||
}
|
||||
return(0);
|
||||
}
|
||||
|
|
|
@ -62,4 +62,7 @@ void st_go_home();
|
|||
// Echo steps to serial port? (true/false)
|
||||
void st_set_echo(int value);
|
||||
|
||||
// Convert from millimeters to step-counts along the designated axis
|
||||
int32_t st_millimeters_to_steps(double millimeters, int axis);
|
||||
|
||||
#endif
|
||||
|
|
Ładowanie…
Reference in New Issue