kin_extruder: Apply pressure advance in kin_extruder.c
Implement the pressure advance calculations while performing the definitive integral calculations. This simplifies both the extruder.py and kin_extruder.c code. Signed-off-by: Kevin O'Connor <kevin@koconnor.net>
This commit is contained in:
parent
730a6d868b
commit
080ee0b512
|
@ -91,8 +91,8 @@ defs_kin_winch = """
|
|||
|
||||
defs_kin_extruder = """
|
||||
struct stepper_kinematics *extruder_stepper_alloc(void);
|
||||
void extruder_set_pressure(struct stepper_kinematics *sk
|
||||
, double pressure_advance, double half_smooth_time);
|
||||
void extruder_set_smooth_time(struct stepper_kinematics *sk
|
||||
, double smooth_time);
|
||||
"""
|
||||
|
||||
defs_serialqueue = """
|
||||
|
|
|
@ -12,9 +12,9 @@
|
|||
#include "pyhelper.h" // errorf
|
||||
#include "trapq.h" // move_get_distance
|
||||
|
||||
// Helper code for integrating acceleration
|
||||
// Calculate the definitive integral of the move distance
|
||||
static double
|
||||
integrate_accel(struct move *m, double start, double end)
|
||||
move_integrate_distance(struct move *m, double start, double end)
|
||||
{
|
||||
double half_v = .5 * m->start_v, sixth_a = (1. / 3.) * m->half_accel;
|
||||
double si = start * start * (half_v + sixth_a * start);
|
||||
|
@ -22,64 +22,45 @@ integrate_accel(struct move *m, double start, double end)
|
|||
return ei - si;
|
||||
}
|
||||
|
||||
// Calculate the definitive integral on part of a move
|
||||
// Calculate the definitive integral of extruder with pressure advance
|
||||
static double
|
||||
move_integrate(struct move *m, int axis, double start, double end)
|
||||
pa_move_integrate(struct move *m, double start, double end)
|
||||
{
|
||||
if (start < 0.)
|
||||
start = 0.;
|
||||
if (end > m->move_t)
|
||||
end = m->move_t;
|
||||
double base = m->start_pos.axis[axis - 'x'] * (end - start);
|
||||
double integral = integrate_accel(m, start, end);
|
||||
return base + integral * m->axes_r.axis[axis - 'x'];
|
||||
double pressure_advance = m->axes_r.y;
|
||||
double avg_v = m->start_v + (start + end) * m->half_accel;
|
||||
double pa_add = pressure_advance * avg_v;
|
||||
double base = (m->start_pos.x + pa_add) * (end - start);
|
||||
return base + move_integrate_distance(m, start, end);
|
||||
}
|
||||
|
||||
// Calculate the definitive integral for a cartesian axis
|
||||
// Calculate the definitive integral of the extruder over a range of moves
|
||||
static double
|
||||
trapq_integrate(struct move *m, int axis, double start, double end)
|
||||
pa_range_integrate(struct move *m, double start, double end)
|
||||
{
|
||||
double res = move_integrate(m, axis, start, end);
|
||||
double res = pa_move_integrate(m, start, end);
|
||||
// Integrate over previous moves
|
||||
struct move *prev = m;
|
||||
while (unlikely(start < 0.)) {
|
||||
prev = list_prev_entry(prev, node);
|
||||
start += prev->move_t;
|
||||
res += move_integrate(prev, axis, start, prev->move_t);
|
||||
res += pa_move_integrate(prev, start, prev->move_t);
|
||||
}
|
||||
// Integrate over future moves
|
||||
while (unlikely(end > m->move_t)) {
|
||||
end -= m->move_t;
|
||||
m = list_next_entry(m, node);
|
||||
res += move_integrate(m, axis, 0., end);
|
||||
res += pa_move_integrate(m, 0., end);
|
||||
}
|
||||
return res;
|
||||
}
|
||||
|
||||
// Find a move associated with a given time
|
||||
static struct move *
|
||||
trapq_find_move(struct move *m, double *ptime)
|
||||
{
|
||||
double move_time = *ptime;
|
||||
for (;;) {
|
||||
if (unlikely(move_time < 0.)) {
|
||||
// Check previous move in list
|
||||
m = list_prev_entry(m, node);
|
||||
move_time += m->move_t;
|
||||
} else if (unlikely(move_time > m->move_t)) {
|
||||
// Check next move in list
|
||||
move_time -= m->move_t;
|
||||
m = list_next_entry(m, node);
|
||||
} else {
|
||||
*ptime = move_time;
|
||||
return m;
|
||||
}
|
||||
}
|
||||
}
|
||||
|
||||
struct extruder_stepper {
|
||||
struct stepper_kinematics sk;
|
||||
double pressure_advance_factor, half_smooth_time, inv_smooth_time;
|
||||
double half_smooth_time, inv_smooth_time;
|
||||
};
|
||||
|
||||
static double
|
||||
|
@ -91,36 +72,20 @@ extruder_calc_position(struct stepper_kinematics *sk, struct move *m
|
|||
if (!hst)
|
||||
// Pressure advance not enabled
|
||||
return m->start_pos.x + move_get_distance(m, move_time);
|
||||
// Calculate average position over smooth_time
|
||||
double area = trapq_integrate(m, 'x', move_time - hst, move_time + hst);
|
||||
double base_pos = area * es->inv_smooth_time;
|
||||
// Calculate position 'half_smooth_time' in the past
|
||||
double start_time = move_time - hst;
|
||||
struct move *sm = trapq_find_move(m, &start_time);
|
||||
double start_dist = move_get_distance(sm, start_time);
|
||||
double pa_start_pos = sm->start_pos.y + (sm->axes_r.y ? start_dist : 0.);
|
||||
// Calculate position 'half_smooth_time' in the future
|
||||
double end_time = move_time + hst;
|
||||
struct move *em = trapq_find_move(m, &end_time);
|
||||
double end_dist = move_get_distance(em, end_time);
|
||||
double pa_end_pos = em->start_pos.y + (em->axes_r.y ? end_dist : 0.);
|
||||
// Calculate position with pressure advance
|
||||
return base_pos + (pa_end_pos - pa_start_pos) * es->pressure_advance_factor;
|
||||
// Apply pressure advance and average over smooth_time
|
||||
double area = pa_range_integrate(m, move_time - hst, move_time + hst);
|
||||
return area * es->inv_smooth_time;
|
||||
}
|
||||
|
||||
void __visible
|
||||
extruder_set_pressure(struct stepper_kinematics *sk
|
||||
, double pressure_advance, double half_smooth_time)
|
||||
extruder_set_smooth_time(struct stepper_kinematics *sk, double smooth_time)
|
||||
{
|
||||
struct extruder_stepper *es = container_of(sk, struct extruder_stepper, sk);
|
||||
if (! half_smooth_time) {
|
||||
es->pressure_advance_factor = es->half_smooth_time = 0.;
|
||||
double hst = smooth_time * .5;
|
||||
es->sk.scan_past = es->sk.scan_future = es->half_smooth_time = hst;
|
||||
if (! hst)
|
||||
return;
|
||||
}
|
||||
es->sk.scan_past = es->sk.scan_future = half_smooth_time;
|
||||
es->half_smooth_time = half_smooth_time;
|
||||
es->inv_smooth_time = .5 / half_smooth_time;
|
||||
es->pressure_advance_factor = pressure_advance * es->inv_smooth_time;
|
||||
es->inv_smooth_time = 1. / smooth_time;
|
||||
}
|
||||
|
||||
struct stepper_kinematics * __visible
|
||||
|
|
|
@ -50,7 +50,7 @@ class PrinterExtruder:
|
|||
pressure_advance = config.getfloat('pressure_advance', 0., minval=0.)
|
||||
smooth_time = config.getfloat('pressure_advance_smooth_time',
|
||||
0.040, above=0., maxval=.200)
|
||||
self.extrude_pos = self.extrude_pa_pos = 0.
|
||||
self.extrude_pos = 0.
|
||||
# Setup iterative solver
|
||||
ffi_main, ffi_lib = chelper.get_ffi()
|
||||
self.trapq = ffi_main.gc(ffi_lib.trapq_alloc(), ffi_lib.trapq_free)
|
||||
|
@ -61,7 +61,7 @@ class PrinterExtruder:
|
|||
self.stepper.set_stepper_kinematics(self.sk_extruder)
|
||||
self.stepper.set_trapq(self.trapq)
|
||||
toolhead.register_step_generator(self.stepper.generate_steps)
|
||||
self.extruder_set_pressure = ffi_lib.extruder_set_pressure
|
||||
self.extruder_set_smooth_time = ffi_lib.extruder_set_smooth_time
|
||||
self._set_pressure_advance(pressure_advance, smooth_time)
|
||||
# Register commands
|
||||
gcode = self.printer.lookup_object('gcode')
|
||||
|
@ -76,17 +76,16 @@ class PrinterExtruder:
|
|||
def update_move_time(self, flush_time):
|
||||
self.trapq_free_moves(self.trapq, flush_time)
|
||||
def _set_pressure_advance(self, pressure_advance, smooth_time):
|
||||
old_smooth_time = self.pressure_advance_smooth_time * .5
|
||||
old_smooth_time = self.pressure_advance_smooth_time
|
||||
if not self.pressure_advance:
|
||||
old_smooth_time = 0.
|
||||
new_smooth_time = smooth_time * .5
|
||||
new_smooth_time = smooth_time
|
||||
if not pressure_advance:
|
||||
new_smooth_time = 0.
|
||||
toolhead = self.printer.lookup_object("toolhead")
|
||||
toolhead.note_step_generation_scan_time(new_smooth_time,
|
||||
old_delay=old_smooth_time)
|
||||
self.extruder_set_pressure(self.sk_extruder,
|
||||
pressure_advance, new_smooth_time)
|
||||
toolhead.note_step_generation_scan_time(new_smooth_time * .5,
|
||||
old_delay=old_smooth_time * .5)
|
||||
self.extruder_set_smooth_time(self.sk_extruder, new_smooth_time)
|
||||
self.pressure_advance = pressure_advance
|
||||
self.pressure_advance_smooth_time = smooth_time
|
||||
def get_status(self, eventtime):
|
||||
|
@ -142,18 +141,16 @@ class PrinterExtruder:
|
|||
accel = move.accel * axis_r
|
||||
start_v = move.start_v * axis_r
|
||||
cruise_v = move.cruise_v * axis_r
|
||||
is_pa = 0.
|
||||
pressure_advance = 0.
|
||||
if axis_r > 0. and (move.axes_d[0] or move.axes_d[1]):
|
||||
is_pa = 1.
|
||||
# Queue movement (x is extruder movement, y is movement with pa)
|
||||
pressure_advance = self.pressure_advance
|
||||
# Queue movement (x is extruder movement, y is pressure advance)
|
||||
self.trapq_append(self.trapq, print_time,
|
||||
move.accel_t, move.cruise_t, move.decel_t,
|
||||
move.start_pos[3], self.extrude_pa_pos, 0.,
|
||||
1., is_pa, 0.,
|
||||
move.start_pos[3], 0., 0.,
|
||||
1., pressure_advance, 0.,
|
||||
start_v, cruise_v, accel)
|
||||
self.extrude_pos = move.end_pos[3]
|
||||
if is_pa:
|
||||
self.extrude_pa_pos += move.axes_d[3]
|
||||
cmd_SET_PRESSURE_ADVANCE_help = "Set pressure advance parameters"
|
||||
def cmd_default_SET_PRESSURE_ADVANCE(self, params):
|
||||
extruder = self.printer.lookup_object('toolhead').get_extruder()
|
||||
|
|
Loading…
Reference in New Issue