Prusa-Firmware/Firmware/tmc2130.cpp

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2019-09-27 13:42:31 +00:00
//! @file
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#include "Marlin.h"
#ifdef TMC2130
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#include "tmc2130.h"
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#include "ultralcd.h"
#include "language.h"
#include "spi.h"
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#define TMC2130_GCONF_NORMAL 0x00000000 // spreadCycle
#define TMC2130_GCONF_SGSENS 0x00003180 // spreadCycle with stallguard (stall activates DIAG0 and DIAG1 [pushpull])
#define TMC2130_GCONF_SILENT 0x00000004 // stealthChop
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//mode
uint8_t tmc2130_mode = TMC2130_MODE_NORMAL;
uint8_t tmc2130_current_h[4] = TMC2130_CURRENTS_H;
//running currents
uint8_t tmc2130_current_r[4] = TMC2130_CURRENTS_R;
//running currents for homing
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uint8_t tmc2130_current_r_home[4] = TMC2130_CURRENTS_R_HOME;
//pwm_ampl
uint8_t tmc2130_pwm_ampl[4] = {TMC2130_PWM_AMPL_X, TMC2130_PWM_AMPL_Y, TMC2130_PWM_AMPL_Z, TMC2130_PWM_AMPL_E};
//pwm_grad
uint8_t tmc2130_pwm_grad[4] = {TMC2130_PWM_GRAD_X, TMC2130_PWM_GRAD_Y, TMC2130_PWM_GRAD_Z, TMC2130_PWM_GRAD_E};
//pwm_auto
uint8_t tmc2130_pwm_auto[4] = {TMC2130_PWM_AUTO_X, TMC2130_PWM_AUTO_Y, TMC2130_PWM_AUTO_Z, TMC2130_PWM_AUTO_E};
//pwm_freq
uint8_t tmc2130_pwm_freq[4] = {TMC2130_PWM_FREQ_X, TMC2130_PWM_FREQ_Y, TMC2130_PWM_FREQ_Z, TMC2130_PWM_FREQ_E};
uint8_t tmc2130_mres[4] = {0, 0, 0, 0}; //will be filed at begin of init
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uint8_t tmc2130_sg_thr[4] = {TMC2130_SG_THRS_X, TMC2130_SG_THRS_Y, TMC2130_SG_THRS_Z, TMC2130_SG_THRS_E};
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uint8_t tmc2130_sg_thr_home[4] = TMC2130_SG_THRS_HOME;
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uint8_t tmc2130_sg_homing_axes_mask = 0x00;
Scale extruder motor current linearly with speed. (#2813) Scale extruder motor current linearly with speed. 49% less heating when running at low speed and standstill, 4% more torque at maximum extrusion rate (15mm^3/s), 15% more torque in high speed movements (un/retractions). StealthChop mode is used for low speeds (below 900mm/min) spreadCycle is used above. Transition speed is well above maximum extrusion rate of 15mm^3/s (275mm/min) so mode transition is not expected to be visible on printed surface. StealthChop is expected to improve printed surface quality (less artifacts). Warning you can burn extruder motor if it is not the same impedance as original Prusa i3 Extruder stepper motor. There is no current feedback in low speed so lower impedance motor can be burned by over current. Even there is no direct current feedback, there is no risk for original motor thermal runaway, as motor resistance increases with temperature, current decreases. Standstill peak phase current is expected to be 500 mA and linearly increase with speed to 970 mA at 900mm/min where spreadCycle constant current regulation takes over and keeps peak current at 805 mA to maximum speed possible. As motor heating increases with current squared, lowering low speed current from 700mA to 500mA decreases heating 49% in thate mode, where motor spends most of the time. Enable E-motor cool mode in farm mode only (and experimental menu) - the experimental menu is visible AND the EEPROM_ECOOL variable has a value of the universal answer to all problems of the universe - i.e. two conditions must be met at the start of the FW to enable the E-cool mode. If the user enables the experimental menu, sets the E-cool mode and disables the menu afterwards, on the next start of the FW the E-cool mode will be DISABLED. This is still subject to discussion how much obscure (security through obscurity) we'd like this option to have . Additional stuff: * Add serial debug msg to verify if E-cool mode is on * Avoid access to E-cool mode switch on machines without TMC2130 * Do not allow only M907 E in case of E-cool mode+warn the user on the serial line that the command was skipped Co-authored-by: D.R.racer <drracer@drracer.eu>
2021-04-23 14:06:28 +00:00
const char eMotorCurrentScalingEnabled[] PROGMEM = "E-motor current scaling enabled";
uint8_t tmc2130_sg_meassure = 0xff;
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uint32_t tmc2130_sg_meassure_cnt = 0;
uint32_t tmc2130_sg_meassure_val = 0;
uint8_t tmc2130_home_enabled = 0;
uint8_t tmc2130_home_origin[2] = {0, 0};
uint8_t tmc2130_home_bsteps[2] = {48, 48};
uint8_t tmc2130_home_fsteps[2] = {48, 48};
uint8_t tmc2130_wave_fac[4] = {0, 0, 0, 0};
tmc2130_chopper_config_t tmc2130_chopper_config[4] = {
{TMC2130_TOFF_XYZ, 5, 1, 2, 0},
{TMC2130_TOFF_XYZ, 5, 1, 2, 0},
{TMC2130_TOFF_XYZ, 5, 1, 2, 0},
{TMC2130_TOFF_E, 5, 1, 2, 0}
};
bool tmc2130_sg_stop_on_crash = true;
uint8_t tmc2130_sg_diag_mask = 0x00;
uint8_t tmc2130_sg_crash = 0;
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uint16_t tmc2130_sg_err[4] = {0, 0, 0, 0};
uint16_t tmc2130_sg_cnt[4] = {0, 0, 0, 0};
#ifdef DEBUG_CRASHDET_COUNTERS
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bool tmc2130_sg_change = false;
#endif
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bool skip_debug_msg = false;
#define DBG(args...)
//printf_P(args)
#ifndef _n
#define _n PSTR
#endif //_n
#ifndef _i
#define _i PSTR
#endif //_i
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//TMC2130 registers
#define TMC2130_REG_GCONF 0x00 // 17 bits
#define TMC2130_REG_GSTAT 0x01 // 3 bits
#define TMC2130_REG_IOIN 0x04 // 8+8 bits
#define TMC2130_REG_IHOLD_IRUN 0x10 // 5+5+4 bits
#define TMC2130_REG_TPOWERDOWN 0x11 // 8 bits
#define TMC2130_REG_TSTEP 0x12 // 20 bits
#define TMC2130_REG_TPWMTHRS 0x13 // 20 bits
#define TMC2130_REG_TCOOLTHRS 0x14 // 20 bits
#define TMC2130_REG_THIGH 0x15 // 20 bits
#define TMC2130_REG_XDIRECT 0x2d // 32 bits
#define TMC2130_REG_VDCMIN 0x33 // 23 bits
#define TMC2130_REG_MSLUT0 0x60 // 32 bits
#define TMC2130_REG_MSLUT1 0x61 // 32 bits
#define TMC2130_REG_MSLUT2 0x62 // 32 bits
#define TMC2130_REG_MSLUT3 0x63 // 32 bits
#define TMC2130_REG_MSLUT4 0x64 // 32 bits
#define TMC2130_REG_MSLUT5 0x65 // 32 bits
#define TMC2130_REG_MSLUT6 0x66 // 32 bits
#define TMC2130_REG_MSLUT7 0x67 // 32 bits
#define TMC2130_REG_MSLUTSEL 0x68 // 32 bits
#define TMC2130_REG_MSLUTSTART 0x69 // 8+8 bits
#define TMC2130_REG_MSCNT 0x6a // 10 bits
#define TMC2130_REG_MSCURACT 0x6b // 9+9 bits
#define TMC2130_REG_CHOPCONF 0x6c // 32 bits
#define TMC2130_REG_COOLCONF 0x6d // 25 bits
#define TMC2130_REG_DCCTRL 0x6e // 24 bits
#define TMC2130_REG_DRV_STATUS 0x6f // 32 bits
#define TMC2130_REG_PWMCONF 0x70 // 22 bits
#define TMC2130_REG_PWM_SCALE 0x71 // 8 bits
#define TMC2130_REG_ENCM_CTRL 0x72 // 2 bits
#define TMC2130_REG_LOST_STEPS 0x73 // 20 bits
uint16_t tmc2130_rd_TSTEP(uint8_t axis);
uint16_t tmc2130_rd_MSCNT(uint8_t axis);
uint32_t tmc2130_rd_MSCURACT(uint8_t axis);
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void tmc2130_wr_CHOPCONF(uint8_t axis, uint8_t toff = 3, uint8_t hstrt = 4, uint8_t hend = 1, uint8_t fd3 = 0, uint8_t disfdcc = 0, uint8_t rndtf = 0, uint8_t chm = 0, uint8_t tbl = 2, uint8_t vsense = 0, uint8_t vhighfs = 0, uint8_t vhighchm = 0, uint8_t sync = 0, uint8_t mres = 0b0100, uint8_t intpol = 1, uint8_t dedge = 0, uint8_t diss2g = 0);
void tmc2130_wr_PWMCONF(uint8_t axis, uint8_t pwm_ampl, uint8_t pwm_grad, uint8_t pwm_freq, uint8_t pwm_auto, uint8_t pwm_symm, uint8_t freewheel);
void tmc2130_wr_TPWMTHRS(uint8_t axis, uint32_t val32);
void tmc2130_wr_THIGH(uint8_t axis, uint32_t val32);
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#define tmc2130_rd(axis, addr, rval) tmc2130_rx(axis, addr, rval)
#define tmc2130_wr(axis, addr, wval) tmc2130_tx(axis, (addr) | 0x80, wval)
static void tmc2130_tx(uint8_t axis, uint8_t addr, uint32_t wval);
static uint8_t tmc2130_rx(uint8_t axis, uint8_t addr, uint32_t* rval);
void tmc2130_setup_chopper(uint8_t axis, uint8_t mres, uint8_t current_h, uint8_t current_r);
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uint16_t __tcoolthrs(uint8_t axis)
{
switch (axis)
{
case X_AXIS: return TMC2130_TCOOLTHRS_X;
case Y_AXIS: return TMC2130_TCOOLTHRS_Y;
case Z_AXIS: return TMC2130_TCOOLTHRS_Z;
}
return 0;
}
Scale extruder motor current linearly with speed. (#2813) Scale extruder motor current linearly with speed. 49% less heating when running at low speed and standstill, 4% more torque at maximum extrusion rate (15mm^3/s), 15% more torque in high speed movements (un/retractions). StealthChop mode is used for low speeds (below 900mm/min) spreadCycle is used above. Transition speed is well above maximum extrusion rate of 15mm^3/s (275mm/min) so mode transition is not expected to be visible on printed surface. StealthChop is expected to improve printed surface quality (less artifacts). Warning you can burn extruder motor if it is not the same impedance as original Prusa i3 Extruder stepper motor. There is no current feedback in low speed so lower impedance motor can be burned by over current. Even there is no direct current feedback, there is no risk for original motor thermal runaway, as motor resistance increases with temperature, current decreases. Standstill peak phase current is expected to be 500 mA and linearly increase with speed to 970 mA at 900mm/min where spreadCycle constant current regulation takes over and keeps peak current at 805 mA to maximum speed possible. As motor heating increases with current squared, lowering low speed current from 700mA to 500mA decreases heating 49% in thate mode, where motor spends most of the time. Enable E-motor cool mode in farm mode only (and experimental menu) - the experimental menu is visible AND the EEPROM_ECOOL variable has a value of the universal answer to all problems of the universe - i.e. two conditions must be met at the start of the FW to enable the E-cool mode. If the user enables the experimental menu, sets the E-cool mode and disables the menu afterwards, on the next start of the FW the E-cool mode will be DISABLED. This is still subject to discussion how much obscure (security through obscurity) we'd like this option to have . Additional stuff: * Add serial debug msg to verify if E-cool mode is on * Avoid access to E-cool mode switch on machines without TMC2130 * Do not allow only M907 E in case of E-cool mode+warn the user on the serial line that the command was skipped Co-authored-by: D.R.racer <drracer@drracer.eu>
2021-04-23 14:06:28 +00:00
void tmc2130_init(TMCInitParams params)
{
// DBG(_n("tmc2130_init(), mode=%S\n"), tmc2130_mode?_n("STEALTH"):_n("NORMAL"));
WRITE(X_TMC2130_CS, HIGH);
WRITE(Y_TMC2130_CS, HIGH);
WRITE(Z_TMC2130_CS, HIGH);
WRITE(E0_TMC2130_CS, HIGH);
SET_OUTPUT(X_TMC2130_CS);
SET_OUTPUT(Y_TMC2130_CS);
SET_OUTPUT(Z_TMC2130_CS);
SET_OUTPUT(E0_TMC2130_CS);
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SET_INPUT(X_TMC2130_DIAG);
SET_INPUT(Y_TMC2130_DIAG);
SET_INPUT(Z_TMC2130_DIAG);
SET_INPUT(E0_TMC2130_DIAG);
for (uint_least8_t axis = 0; axis < 2; axis++) // X Y axes
{
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tmc2130_setup_chopper(axis, tmc2130_mres[axis], tmc2130_current_h[axis], tmc2130_current_r[axis]);
tmc2130_wr(axis, TMC2130_REG_TPOWERDOWN, 0x00000000);
tmc2130_wr(axis, TMC2130_REG_COOLCONF, (((uint32_t)tmc2130_sg_thr[axis]) << 16));
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tmc2130_wr(axis, TMC2130_REG_TCOOLTHRS, (tmc2130_mode == TMC2130_MODE_SILENT)?0:__tcoolthrs(axis));
tmc2130_wr(axis, TMC2130_REG_GCONF, (tmc2130_mode == TMC2130_MODE_SILENT)?TMC2130_GCONF_SILENT:TMC2130_GCONF_SGSENS);
tmc2130_wr_PWMCONF(axis, tmc2130_pwm_ampl[axis], tmc2130_pwm_grad[axis], tmc2130_pwm_freq[axis], tmc2130_pwm_auto[axis], 0, 0);
tmc2130_wr_TPWMTHRS(axis, TMC2130_TPWMTHRS);
//tmc2130_wr_THIGH(axis, TMC2130_THIGH);
}
for (uint_least8_t axis = 2; axis < 3; axis++) // Z axis
{
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tmc2130_setup_chopper(axis, tmc2130_mres[axis], tmc2130_current_h[axis], tmc2130_current_r[axis]);
tmc2130_wr(axis, TMC2130_REG_TPOWERDOWN, 0x00000000);
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#ifndef TMC2130_STEALTH_Z
tmc2130_wr(axis, TMC2130_REG_GCONF, TMC2130_GCONF_SGSENS);
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#else //TMC2130_STEALTH_Z
tmc2130_wr(axis, TMC2130_REG_COOLCONF, (((uint32_t)tmc2130_sg_thr[axis]) << 16));
tmc2130_wr(axis, TMC2130_REG_TCOOLTHRS, (tmc2130_mode == TMC2130_MODE_SILENT)?0:__tcoolthrs(axis));
tmc2130_wr(axis, TMC2130_REG_GCONF, (tmc2130_mode == TMC2130_MODE_SILENT)?TMC2130_GCONF_SILENT:TMC2130_GCONF_SGSENS);
tmc2130_wr_PWMCONF(axis, tmc2130_pwm_ampl[axis], tmc2130_pwm_grad[axis], tmc2130_pwm_freq[axis], tmc2130_pwm_auto[axis], 0, 0);
tmc2130_wr_TPWMTHRS(axis, TMC2130_TPWMTHRS);
#endif //TMC2130_STEALTH_Z
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}
for (uint_least8_t axis = 3; axis < 4; axis++) // E axis
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{
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tmc2130_setup_chopper(axis, tmc2130_mres[axis], tmc2130_current_h[axis], tmc2130_current_r[axis]);
tmc2130_wr(axis, TMC2130_REG_TPOWERDOWN, 0x00000000);
#ifndef TMC2130_STEALTH_E
Scale extruder motor current linearly with speed. (#2813) Scale extruder motor current linearly with speed. 49% less heating when running at low speed and standstill, 4% more torque at maximum extrusion rate (15mm^3/s), 15% more torque in high speed movements (un/retractions). StealthChop mode is used for low speeds (below 900mm/min) spreadCycle is used above. Transition speed is well above maximum extrusion rate of 15mm^3/s (275mm/min) so mode transition is not expected to be visible on printed surface. StealthChop is expected to improve printed surface quality (less artifacts). Warning you can burn extruder motor if it is not the same impedance as original Prusa i3 Extruder stepper motor. There is no current feedback in low speed so lower impedance motor can be burned by over current. Even there is no direct current feedback, there is no risk for original motor thermal runaway, as motor resistance increases with temperature, current decreases. Standstill peak phase current is expected to be 500 mA and linearly increase with speed to 970 mA at 900mm/min where spreadCycle constant current regulation takes over and keeps peak current at 805 mA to maximum speed possible. As motor heating increases with current squared, lowering low speed current from 700mA to 500mA decreases heating 49% in thate mode, where motor spends most of the time. Enable E-motor cool mode in farm mode only (and experimental menu) - the experimental menu is visible AND the EEPROM_ECOOL variable has a value of the universal answer to all problems of the universe - i.e. two conditions must be met at the start of the FW to enable the E-cool mode. If the user enables the experimental menu, sets the E-cool mode and disables the menu afterwards, on the next start of the FW the E-cool mode will be DISABLED. This is still subject to discussion how much obscure (security through obscurity) we'd like this option to have . Additional stuff: * Add serial debug msg to verify if E-cool mode is on * Avoid access to E-cool mode switch on machines without TMC2130 * Do not allow only M907 E in case of E-cool mode+warn the user on the serial line that the command was skipped Co-authored-by: D.R.racer <drracer@drracer.eu>
2021-04-23 14:06:28 +00:00
if( ! params.enableECool ){
tmc2130_wr(axis, TMC2130_REG_GCONF, TMC2130_GCONF_SGSENS);
} else {
tmc2130_wr(axis, TMC2130_REG_COOLCONF, (((uint32_t)tmc2130_sg_thr[axis]) << 16));
tmc2130_wr(axis, TMC2130_REG_TCOOLTHRS, 0);
tmc2130_wr(axis, TMC2130_REG_GCONF, TMC2130_GCONF_SILENT);
tmc2130_wr_PWMCONF(axis, TMC2130_PWM_AMPL_Ecool, TMC2130_PWM_GRAD_Ecool, tmc2130_pwm_freq[axis], TMC2130_PWM_AUTO_Ecool, 0, 0);
tmc2130_wr_TPWMTHRS(axis, TMC2130_TPWMTHRS_E);
SERIAL_ECHOLNRPGM(eMotorCurrentScalingEnabled);
}
#else //TMC2130_STEALTH_E
tmc2130_wr(axis, TMC2130_REG_COOLCONF, (((uint32_t)tmc2130_sg_thr[axis]) << 16));
tmc2130_wr(axis, TMC2130_REG_TCOOLTHRS, 0);
tmc2130_wr(axis, TMC2130_REG_GCONF, TMC2130_GCONF_SILENT);
tmc2130_wr_PWMCONF(axis, tmc2130_pwm_ampl[axis], tmc2130_pwm_grad[axis], tmc2130_pwm_freq[axis], tmc2130_pwm_auto[axis], 0, 0);
tmc2130_wr_TPWMTHRS(axis, TMC2130_TPWMTHRS);
#endif //TMC2130_STEALTH_E
}
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tmc2130_sg_err[0] = 0;
tmc2130_sg_err[1] = 0;
tmc2130_sg_err[2] = 0;
tmc2130_sg_err[3] = 0;
tmc2130_sg_cnt[0] = 0;
tmc2130_sg_cnt[1] = 0;
tmc2130_sg_cnt[2] = 0;
tmc2130_sg_cnt[3] = 0;
#ifdef TMC2130_LINEARITY_CORRECTION
#ifdef TMC2130_LINEARITY_CORRECTION_XYZ
tmc2130_set_wave(X_AXIS, 247, tmc2130_wave_fac[X_AXIS]);
tmc2130_set_wave(Y_AXIS, 247, tmc2130_wave_fac[Y_AXIS]);
tmc2130_set_wave(Z_AXIS, 247, tmc2130_wave_fac[Z_AXIS]);
#endif //TMC2130_LINEARITY_CORRECTION_XYZ
tmc2130_set_wave(E_AXIS, 247, tmc2130_wave_fac[E_AXIS]);
#endif //TMC2130_LINEARITY_CORRECTION
#ifdef PSU_Delta
Scale extruder motor current linearly with speed. (#2813) Scale extruder motor current linearly with speed. 49% less heating when running at low speed and standstill, 4% more torque at maximum extrusion rate (15mm^3/s), 15% more torque in high speed movements (un/retractions). StealthChop mode is used for low speeds (below 900mm/min) spreadCycle is used above. Transition speed is well above maximum extrusion rate of 15mm^3/s (275mm/min) so mode transition is not expected to be visible on printed surface. StealthChop is expected to improve printed surface quality (less artifacts). Warning you can burn extruder motor if it is not the same impedance as original Prusa i3 Extruder stepper motor. There is no current feedback in low speed so lower impedance motor can be burned by over current. Even there is no direct current feedback, there is no risk for original motor thermal runaway, as motor resistance increases with temperature, current decreases. Standstill peak phase current is expected to be 500 mA and linearly increase with speed to 970 mA at 900mm/min where spreadCycle constant current regulation takes over and keeps peak current at 805 mA to maximum speed possible. As motor heating increases with current squared, lowering low speed current from 700mA to 500mA decreases heating 49% in thate mode, where motor spends most of the time. Enable E-motor cool mode in farm mode only (and experimental menu) - the experimental menu is visible AND the EEPROM_ECOOL variable has a value of the universal answer to all problems of the universe - i.e. two conditions must be met at the start of the FW to enable the E-cool mode. If the user enables the experimental menu, sets the E-cool mode and disables the menu afterwards, on the next start of the FW the E-cool mode will be DISABLED. This is still subject to discussion how much obscure (security through obscurity) we'd like this option to have . Additional stuff: * Add serial debug msg to verify if E-cool mode is on * Avoid access to E-cool mode switch on machines without TMC2130 * Do not allow only M907 E in case of E-cool mode+warn the user on the serial line that the command was skipped Co-authored-by: D.R.racer <drracer@drracer.eu>
2021-04-23 14:06:28 +00:00
if(!params.bSuppressFlag)
check_force_z();
#endif // PSU_Delta
}
2017-09-22 17:28:32 +00:00
uint8_t tmc2130_sample_diag()
{
uint8_t mask = 0;
if (READ(X_TMC2130_DIAG)) mask |= X_AXIS_MASK;
if (READ(Y_TMC2130_DIAG)) mask |= Y_AXIS_MASK;
// if (READ(Z_TMC2130_DIAG)) mask |= Z_AXIS_MASK;
// if (READ(E0_TMC2130_DIAG)) mask |= E_AXIS_MASK;
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return mask;
}
extern bool is_usb_printing;
void tmc2130_st_isr()
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{
if (tmc2130_mode == TMC2130_MODE_SILENT || tmc2130_sg_stop_on_crash == false) return;
uint8_t crash = 0;
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uint8_t diag_mask = tmc2130_sample_diag();
// for (uint8_t axis = X_AXIS; axis <= E_AXIS; axis++)
for (uint8_t axis = X_AXIS; axis <= Z_AXIS; axis++)
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{
uint8_t mask = (X_AXIS_MASK << axis);
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if (diag_mask & mask) tmc2130_sg_err[axis]++;
else
if (tmc2130_sg_err[axis] > 0) tmc2130_sg_err[axis]--;
if (tmc2130_sg_cnt[axis] < tmc2130_sg_err[axis])
{
tmc2130_sg_cnt[axis] = tmc2130_sg_err[axis];
#ifdef DEBUG_CRASHDET_COUNTERS
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tmc2130_sg_change = true;
#endif
uint8_t sg_thr = 64;
// if (axis == Y_AXIS) sg_thr = 64;
if (tmc2130_sg_err[axis] >= sg_thr)
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{
tmc2130_sg_err[axis] = 0;
crash |= mask;
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}
}
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}
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if (tmc2130_sg_homing_axes_mask == 0)
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{
if (tmc2130_sg_stop_on_crash && crash)
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{
tmc2130_sg_crash = crash;
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tmc2130_sg_stop_on_crash = false;
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crashdet_stop_and_save_print();
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}
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}
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}
bool tmc2130_update_sg()
{
if (tmc2130_sg_meassure <= E_AXIS)
{
uint32_t val32 = 0;
tmc2130_rd(tmc2130_sg_meassure, TMC2130_REG_DRV_STATUS, &val32);
tmc2130_sg_meassure_val += (val32 & 0x3ff);
tmc2130_sg_meassure_cnt++;
return true;
}
return false;
}
void tmc2130_home_enter(uint8_t axes_mask)
{
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printf_P(PSTR("tmc2130_home_enter(axes_mask=0x%02x)\n"), axes_mask);
#ifdef TMC2130_SG_HOMING
if (axes_mask & 0x03) //X or Y
tmc2130_wait_standstill_xy(1000);
for (uint8_t axis = X_AXIS; axis <= Z_AXIS; axis++) //X Y and Z axes
{
uint8_t mask = (X_AXIS_MASK << axis);
if (axes_mask & mask)
{
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tmc2130_sg_homing_axes_mask |= mask;
//Configuration to spreadCycle
tmc2130_wr(axis, TMC2130_REG_GCONF, TMC2130_GCONF_NORMAL);
tmc2130_wr(axis, TMC2130_REG_COOLCONF, (((uint32_t)tmc2130_sg_thr_home[axis]) << 16));
// tmc2130_wr(axis, TMC2130_REG_COOLCONF, (((uint32_t)tmc2130_sg_thr[axis]) << 16) | ((uint32_t)1 << 24));
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tmc2130_wr(axis, TMC2130_REG_TCOOLTHRS, __tcoolthrs(axis));
tmc2130_setup_chopper(axis, tmc2130_mres[axis], tmc2130_current_h[axis], tmc2130_current_r_home[axis]);
if (mask & (X_AXIS_MASK | Y_AXIS_MASK | Z_AXIS_MASK))
tmc2130_wr(axis, TMC2130_REG_GCONF, TMC2130_GCONF_SGSENS); //stallguard output DIAG1, DIAG1 = pushpull
}
}
#endif //TMC2130_SG_HOMING
}
void tmc2130_home_exit()
{
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printf_P(PSTR("tmc2130_home_exit tmc2130_sg_homing_axes_mask=0x%02x\n"), tmc2130_sg_homing_axes_mask);
#ifdef TMC2130_SG_HOMING
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if (tmc2130_sg_homing_axes_mask & 0x03) //X or Y
tmc2130_wait_standstill_xy(1000);
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if (tmc2130_sg_homing_axes_mask)
{
for (uint8_t axis = X_AXIS; axis <= Z_AXIS; axis++) //X Y and Z axes
{
uint8_t mask = (X_AXIS_MASK << axis);
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if (tmc2130_sg_homing_axes_mask & mask & (X_AXIS_MASK | Y_AXIS_MASK | Z_AXIS_MASK))
{
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#ifndef TMC2130_STEALTH_Z
if ((tmc2130_mode == TMC2130_MODE_SILENT) && (axis != Z_AXIS))
#else //TMC2130_STEALTH_Z
if (tmc2130_mode == TMC2130_MODE_SILENT)
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#endif //TMC2130_STEALTH_Z
{
tmc2130_wr(axis, TMC2130_REG_GCONF, TMC2130_GCONF_SILENT); // Configuration back to stealthChop
tmc2130_wr(axis, TMC2130_REG_TCOOLTHRS, 0);
// tmc2130_wr_PWMCONF(i, tmc2130_pwm_ampl[i], tmc2130_pwm_grad[i], tmc2130_pwm_freq[i], tmc2130_pwm_auto[i], 0, 0);
}
else
{
// tmc2130_wr(axis, TMC2130_REG_GCONF, TMC2130_GCONF_NORMAL);
tmc2130_setup_chopper(axis, tmc2130_mres[axis], tmc2130_current_h[axis], tmc2130_current_r[axis]);
// tmc2130_wr(axis, TMC2130_REG_COOLCONF, (((uint32_t)tmc2130_sg_thr[axis]) << 16) | ((uint32_t)1 << 24));
tmc2130_wr(axis, TMC2130_REG_COOLCONF, (((uint32_t)tmc2130_sg_thr[axis]) << 16));
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tmc2130_wr(axis, TMC2130_REG_TCOOLTHRS, __tcoolthrs(axis));
tmc2130_wr(axis, TMC2130_REG_GCONF, TMC2130_GCONF_SGSENS);
}
}
}
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tmc2130_sg_homing_axes_mask = 0x00;
}
tmc2130_sg_crash = false;
#endif
}
void tmc2130_sg_meassure_start(uint8_t axis)
{
tmc2130_sg_meassure = axis;
tmc2130_sg_meassure_cnt = 0;
tmc2130_sg_meassure_val = 0;
}
uint16_t tmc2130_sg_meassure_stop()
{
tmc2130_sg_meassure = 0xff;
return tmc2130_sg_meassure_val / tmc2130_sg_meassure_cnt;
}
bool tmc2130_wait_standstill_xy(int timeout)
{
// DBG(_n("tmc2130_wait_standstill_xy(timeout=%d)\n"), timeout);
bool standstill = false;
while (!standstill && (timeout > 0))
{
uint32_t drv_status_x = 0;
uint32_t drv_status_y = 0;
tmc2130_rd(X_AXIS, TMC2130_REG_DRV_STATUS, &drv_status_x);
tmc2130_rd(Y_AXIS, TMC2130_REG_DRV_STATUS, &drv_status_y);
// DBG(_n("\tdrv_status_x=0x%08x drv_status_x=0x%08x\n"), drv_status_x, drv_status_y);
standstill = (drv_status_x & 0x80000000) && (drv_status_y & 0x80000000);
tmc2130_check_overtemp();
timeout--;
}
return standstill;
}
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void tmc2130_check_overtemp()
{
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static uint32_t checktime = 0;
if (_millis() - checktime > 1000 )
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{
for (uint_least8_t i = 0; i < 4; i++)
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{
uint32_t drv_status = 0;
skip_debug_msg = true;
tmc2130_rd(i, TMC2130_REG_DRV_STATUS, &drv_status);
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if (drv_status & ((uint32_t)1 << 26))
{ // BIT 26 - over temp prewarning ~120C (+-20C)
SERIAL_ERRORRPGM(MSG_TMC_OVERTEMP);
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SERIAL_ECHOLN(i);
for (uint_least8_t j = 0; j < 4; j++)
tmc2130_wr(j, TMC2130_REG_CHOPCONF, 0x00010000);
kill(MSG_TMC_OVERTEMP);
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}
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}
checktime = _millis();
#ifdef DEBUG_CRASHDET_COUNTERS
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tmc2130_sg_change = true;
#endif
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}
#ifdef DEBUG_CRASHDET_COUNTERS
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if (tmc2130_sg_change)
{
for (int i = 0; i < 4; i++)
{
tmc2130_sg_change = false;
lcd_set_cursor(0 + i*4, 3);
lcd_print(itostr3(tmc2130_sg_cnt[i]));
lcd_print(' ');
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}
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}
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#endif //DEBUG_CRASHDET_COUNTERS
}
void tmc2130_setup_chopper(uint8_t axis, uint8_t mres, uint8_t current_h, uint8_t current_r)
{
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uint8_t intpol = (mres != 0); // intpol to 256 only if microsteps aren't 256
#ifdef TMC2130_DEDGE_STEPPING
uint8_t dedge = 1;
#else
uint8_t dedge = 0;
#endif
uint8_t toff = tmc2130_chopper_config[axis].toff; // toff = 3 (fchop = 27.778kHz)
uint8_t hstrt = tmc2130_chopper_config[axis].hstr; //initial 4, modified to 5
uint8_t hend = tmc2130_chopper_config[axis].hend; //original value = 1
uint8_t fd3 = 0;
uint8_t rndtf = 0; //random off time
uint8_t chm = 0; //spreadCycle
uint8_t tbl = tmc2130_chopper_config[axis].tbl; //blanking time, original value = 2
if (axis == E_AXIS)
{
#if defined(TMC2130_INTPOL_E) && (TMC2130_INTPOL_E == 0)
intpol = 0;
#endif
#ifdef TMC2130_CNSTOFF_E
// fd = 0 (slow decay only)
hstrt = 0; //fd0..2
fd3 = 0; //fd3
hend = 0; //sine wave offset
chm = 1; // constant off time mod
#endif //TMC2130_CNSTOFF_E
// toff = TMC2130_TOFF_E; // toff = 3-5
// rndtf = 1;
}
#if defined(TMC2130_INTPOL_XY) && (TMC2130_INTPOL_XY == 0)
else if (axis == X_AXIS || axis == Y_AXIS) {
intpol = 0;
}
#endif
#if defined(TMC2130_INTPOL_Z) && (TMC2130_INTPOL_Z == 0)
else if (axis == Z_AXIS) {
intpol = 0;
}
#endif
// DBG(_n("tmc2130_setup_chopper(axis=%hhd, mres=%hhd, curh=%hhd, curr=%hhd\n"), axis, mres, current_h, current_r);
// DBG(_n(" toff=%hhd, hstr=%hhd, hend=%hhd, tbl=%hhd\n"), toff, hstrt, hend, tbl);
if (current_r <= 31)
{
tmc2130_wr_CHOPCONF(axis, toff, hstrt, hend, fd3, 0, rndtf, chm, tbl, 1, 0, 0, 0, mres, intpol, dedge, 0);
tmc2130_wr(axis, TMC2130_REG_IHOLD_IRUN, 0x000f0000 | ((current_r & 0x1f) << 8) | (current_h & 0x1f));
}
else
{
tmc2130_wr_CHOPCONF(axis, toff, hstrt, hend, fd3, 0, rndtf, chm, tbl, 0, 0, 0, 0, mres, intpol, dedge, 0);
tmc2130_wr(axis, TMC2130_REG_IHOLD_IRUN, 0x000f0000 | (((current_r >> 1) & 0x1f) << 8) | ((current_h >> 1) & 0x1f));
}
}
void tmc2130_set_current_h(uint8_t axis, uint8_t current)
{
// DBG(_n("tmc2130_set_current_h(axis=%d, current=%d\n"), axis, current);
tmc2130_current_h[axis] = current;
tmc2130_setup_chopper(axis, tmc2130_mres[axis], tmc2130_current_h[axis], tmc2130_current_r[axis]);
}
void tmc2130_set_current_r(uint8_t axis, uint8_t current)
{
// DBG(_n("tmc2130_set_current_r(axis=%d, current=%d\n"), axis, current);
tmc2130_current_r[axis] = current;
tmc2130_setup_chopper(axis, tmc2130_mres[axis], tmc2130_current_h[axis], tmc2130_current_r[axis]);
}
void tmc2130_print_currents()
{
printf_P(_n("tmc2130_print_currents()\n\tH\tR\nX\t%d\t%d\nY\t%d\t%d\nZ\t%d\t%d\nE\t%d\t%d\n"),
tmc2130_current_h[0], tmc2130_current_r[0],
tmc2130_current_h[1], tmc2130_current_r[1],
tmc2130_current_h[2], tmc2130_current_r[2],
tmc2130_current_h[3], tmc2130_current_r[3]
);
}
void tmc2130_set_pwm_ampl(uint8_t axis, uint8_t pwm_ampl)
{
// DBG(_n("tmc2130_set_pwm_ampl(axis=%hhd, pwm_ampl=%hhd\n"), axis, pwm_ampl);
tmc2130_pwm_ampl[axis] = pwm_ampl;
if (((axis == 0) || (axis == 1)) && (tmc2130_mode == TMC2130_MODE_SILENT))
tmc2130_wr_PWMCONF(axis, tmc2130_pwm_ampl[axis], tmc2130_pwm_grad[axis], tmc2130_pwm_freq[axis], tmc2130_pwm_auto[axis], 0, 0);
}
void tmc2130_set_pwm_grad(uint8_t axis, uint8_t pwm_grad)
{
// DBG(_n("tmc2130_set_pwm_grad(axis=%hhd, pwm_grad=%hhd\n"), axis, pwm_grad);
tmc2130_pwm_grad[axis] = pwm_grad;
if (((axis == 0) || (axis == 1)) && (tmc2130_mode == TMC2130_MODE_SILENT))
tmc2130_wr_PWMCONF(axis, tmc2130_pwm_ampl[axis], tmc2130_pwm_grad[axis], tmc2130_pwm_freq[axis], tmc2130_pwm_auto[axis], 0, 0);
}
uint16_t tmc2130_rd_TSTEP(uint8_t axis)
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{
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uint32_t val32 = 0;
tmc2130_rd(axis, TMC2130_REG_TSTEP, &val32);
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if (val32 & 0x000f0000) return 0xffff;
return val32 & 0xffff;
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}
uint16_t tmc2130_rd_MSCNT(uint8_t axis)
{
uint32_t val32 = 0;
tmc2130_rd(axis, TMC2130_REG_MSCNT, &val32);
return val32 & 0x3ff;
}
uint32_t tmc2130_rd_MSCURACT(uint8_t axis)
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{
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uint32_t val32 = 0;
tmc2130_rd(axis, TMC2130_REG_MSCURACT, &val32);
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return val32;
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}
void tmc2130_wr_MSLUTSTART(uint8_t axis, uint8_t start_sin, uint8_t start_sin90)
{
uint32_t val = 0;
val |= (uint32_t)start_sin;
val |= ((uint32_t)start_sin90) << 16;
tmc2130_wr(axis, TMC2130_REG_MSLUTSTART, val);
//printf_P(PSTR("MSLUTSTART=%08lx (start_sin=%d start_sin90=%d)\n"), val, start_sin, start_sin90);
}
void tmc2130_wr_MSLUTSEL(uint8_t axis, uint8_t x1, uint8_t x2, uint8_t x3, uint8_t w0, uint8_t w1, uint8_t w2, uint8_t w3)
{
uint32_t val = 0;
val |= ((uint32_t)w0);
val |= ((uint32_t)w1) << 2;
val |= ((uint32_t)w2) << 4;
val |= ((uint32_t)w3) << 6;
val |= ((uint32_t)x1) << 8;
val |= ((uint32_t)x2) << 16;
val |= ((uint32_t)x3) << 24;
tmc2130_wr(axis, TMC2130_REG_MSLUTSEL, val);
//printf_P(PSTR("MSLUTSEL=%08lx (x1=%d x2=%d x3=%d w0=%d w1=%d w2=%d w3=%d)\n"), val, x1, x2, x3, w0, w1, w2, w3);
}
void tmc2130_wr_MSLUT(uint8_t axis, uint8_t i, uint32_t val)
{
tmc2130_wr(axis, TMC2130_REG_MSLUT0 + (i & 7), val);
//printf_P(PSTR("MSLUT[%d]=%08lx\n"), i, val);
}
void tmc2130_wr_CHOPCONF(uint8_t axis, uint8_t toff, uint8_t hstrt, uint8_t hend, uint8_t fd3, uint8_t disfdcc, uint8_t rndtf, uint8_t chm, uint8_t tbl, uint8_t vsense, uint8_t vhighfs, uint8_t vhighchm, uint8_t sync, uint8_t mres, uint8_t intpol, uint8_t dedge, uint8_t diss2g)
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{
uint32_t val = 0;
val |= (uint32_t)(toff & 15);
val |= (uint32_t)(hstrt & 7) << 4;
val |= (uint32_t)(hend & 15) << 7;
val |= (uint32_t)(fd3 & 1) << 11;
val |= (uint32_t)(disfdcc & 1) << 12;
val |= (uint32_t)(rndtf & 1) << 13;
val |= (uint32_t)(chm & 1) << 14;
val |= (uint32_t)(tbl & 3) << 15;
val |= (uint32_t)(vsense & 1) << 17;
val |= (uint32_t)(vhighfs & 1) << 18;
val |= (uint32_t)(vhighchm & 1) << 19;
val |= (uint32_t)(sync & 15) << 20;
val |= (uint32_t)(mres & 15) << 24;
val |= (uint32_t)(intpol & 1) << 28;
val |= (uint32_t)(dedge & 1) << 29;
val |= (uint32_t)(diss2g & 1) << 30;
tmc2130_wr(axis, TMC2130_REG_CHOPCONF, val);
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}
//void tmc2130_wr_PWMCONF(uint8_t axis, uint8_t PWMautoScale, uint8_t PWMfreq, uint8_t PWMgrad, uint8_t PWMampl)
void tmc2130_wr_PWMCONF(uint8_t axis, uint8_t pwm_ampl, uint8_t pwm_grad, uint8_t pwm_freq, uint8_t pwm_auto, uint8_t pwm_symm, uint8_t freewheel)
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{
uint32_t val = 0;
val |= (uint32_t)(pwm_ampl & 255);
val |= (uint32_t)(pwm_grad & 255) << 8;
val |= (uint32_t)(pwm_freq & 3) << 16;
val |= (uint32_t)(pwm_auto & 1) << 18;
val |= (uint32_t)(pwm_symm & 1) << 19;
val |= (uint32_t)(freewheel & 3) << 20;
tmc2130_wr(axis, TMC2130_REG_PWMCONF, val);
// tmc2130_wr(axis, TMC2130_REG_PWMCONF, ((uint32_t)(PWMautoScale+PWMfreq) << 16) | ((uint32_t)PWMgrad << 8) | PWMampl); // TMC LJ -> For better readability changed to 0x00 and added PWMautoScale and PWMfreq
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}
void tmc2130_wr_TPWMTHRS(uint8_t axis, uint32_t val32)
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{
tmc2130_wr(axis, TMC2130_REG_TPWMTHRS, val32);
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}
void tmc2130_wr_THIGH(uint8_t axis, uint32_t val32)
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{
tmc2130_wr(axis, TMC2130_REG_THIGH, val32);
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}
uint8_t tmc2130_usteps2mres(uint16_t usteps)
{
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uint8_t mres = 8; while (usteps >>= 1) mres--;
return mres;
}
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inline void tmc2130_cs_low(uint8_t axis)
{
switch (axis)
{
case X_AXIS: WRITE(X_TMC2130_CS, LOW); break;
case Y_AXIS: WRITE(Y_TMC2130_CS, LOW); break;
case Z_AXIS: WRITE(Z_TMC2130_CS, LOW); break;
case E_AXIS: WRITE(E0_TMC2130_CS, LOW); break;
}
}
inline void tmc2130_cs_high(uint8_t axis)
{
switch (axis)
{
case X_AXIS: WRITE(X_TMC2130_CS, HIGH); break;
case Y_AXIS: WRITE(Y_TMC2130_CS, HIGH); break;
case Z_AXIS: WRITE(Z_TMC2130_CS, HIGH); break;
case E_AXIS: WRITE(E0_TMC2130_CS, HIGH); break;
}
}
//spi
#define TMC2130_SPI_ENTER() spi_setup(TMC2130_SPCR, TMC2130_SPSR)
#define TMC2130_SPI_TXRX spi_txrx
#define TMC2130_SPI_LEAVE()
static void tmc2130_tx(uint8_t axis, uint8_t addr, uint32_t wval)
{
//datagram1 - request
TMC2130_SPI_ENTER();
tmc2130_cs_low(axis);
TMC2130_SPI_TXRX(addr); // address
TMC2130_SPI_TXRX((wval >> 24) & 0xff); // MSB
TMC2130_SPI_TXRX((wval >> 16) & 0xff);
TMC2130_SPI_TXRX((wval >> 8) & 0xff);
TMC2130_SPI_TXRX(wval & 0xff); // LSB
tmc2130_cs_high(axis);
TMC2130_SPI_LEAVE();
}
static uint8_t tmc2130_rx(uint8_t axis, uint8_t addr, uint32_t* rval)
{
//datagram1 - request
TMC2130_SPI_ENTER();
tmc2130_cs_low(axis);
TMC2130_SPI_TXRX(addr); // address
TMC2130_SPI_TXRX(0); // MSB
TMC2130_SPI_TXRX(0);
TMC2130_SPI_TXRX(0);
TMC2130_SPI_TXRX(0); // LSB
tmc2130_cs_high(axis);
TMC2130_SPI_LEAVE();
//datagram2 - response
TMC2130_SPI_ENTER();
tmc2130_cs_low(axis);
uint8_t stat = TMC2130_SPI_TXRX(0); // status
uint32_t val32 = 0;
val32 = TMC2130_SPI_TXRX(0); // MSB
val32 = (val32 << 8) | TMC2130_SPI_TXRX(0);
val32 = (val32 << 8) | TMC2130_SPI_TXRX(0);
val32 = (val32 << 8) | TMC2130_SPI_TXRX(0); // LSB
tmc2130_cs_high(axis);
TMC2130_SPI_LEAVE();
if (rval != 0) *rval = val32;
return stat;
}
#define _GET_PWR_X (READ(X_ENABLE_PIN) == X_ENABLE_ON)
#define _GET_PWR_Y (READ(Y_ENABLE_PIN) == Y_ENABLE_ON)
#define _GET_PWR_Z (READ(Z_ENABLE_PIN) == Z_ENABLE_ON)
#define _GET_PWR_E (READ(E0_ENABLE_PIN) == E_ENABLE_ON)
#define _SET_PWR_X(ena) WRITE(X_ENABLE_PIN, ena?X_ENABLE_ON:!X_ENABLE_ON)
#define _SET_PWR_Y(ena) WRITE(Y_ENABLE_PIN, ena?Y_ENABLE_ON:!Y_ENABLE_ON)
#define _SET_PWR_Z(ena) WRITE(Z_ENABLE_PIN, ena?Z_ENABLE_ON:!Z_ENABLE_ON)
#define _SET_PWR_E(ena) WRITE(E0_ENABLE_PIN, ena?E_ENABLE_ON:!E_ENABLE_ON)
#define _GET_DIR_X (READ(X_DIR_PIN) == INVERT_X_DIR)
#define _GET_DIR_Y (READ(Y_DIR_PIN) == INVERT_Y_DIR)
#define _GET_DIR_Z (READ(Z_DIR_PIN) == INVERT_Z_DIR)
#define _GET_DIR_E (READ(E0_DIR_PIN) == INVERT_E0_DIR)
#define _SET_DIR_X(dir) WRITE(X_DIR_PIN, dir?INVERT_X_DIR:!INVERT_X_DIR)
#define _SET_DIR_Y(dir) WRITE(Y_DIR_PIN, dir?INVERT_Y_DIR:!INVERT_Y_DIR)
#define _SET_DIR_Z(dir) WRITE(Z_DIR_PIN, dir?INVERT_Z_DIR:!INVERT_Z_DIR)
#define _SET_DIR_E(dir) WRITE(E0_DIR_PIN, dir?INVERT_E0_DIR:!INVERT_E0_DIR)
#ifdef TMC2130_DEDGE_STEPPING
#define _DO_STEP_X TOGGLE(X_STEP_PIN)
#define _DO_STEP_Y TOGGLE(Y_STEP_PIN)
#define _DO_STEP_Z TOGGLE(Z_STEP_PIN)
#define _DO_STEP_E TOGGLE(E0_STEP_PIN)
#else
#define _DO_STEP_X { WRITE(X_STEP_PIN, !INVERT_X_STEP_PIN); TMC2130_MINIMUM_DELAY; WRITE(X_STEP_PIN, INVERT_X_STEP_PIN); }
#define _DO_STEP_Y { WRITE(Y_STEP_PIN, !INVERT_Y_STEP_PIN); TMC2130_MINIMUM_DELAY; WRITE(Y_STEP_PIN, INVERT_Y_STEP_PIN); }
#define _DO_STEP_Z { WRITE(Z_STEP_PIN, !INVERT_Z_STEP_PIN); TMC2130_MINIMUM_DELAY; WRITE(Z_STEP_PIN, INVERT_Z_STEP_PIN); }
#define _DO_STEP_E { WRITE(E0_STEP_PIN, !INVERT_E_STEP_PIN); TMC2130_MINIMUM_DELAY; WRITE(E0_STEP_PIN, INVERT_E_STEP_PIN); }
#endif
uint16_t tmc2130_get_res(uint8_t axis)
{
return tmc2130_mres2usteps(tmc2130_mres[axis]);
}
void tmc2130_set_res(uint8_t axis, uint16_t res)
{
tmc2130_mres[axis] = tmc2130_usteps2mres(res);
// uint32_t u = _micros();
tmc2130_setup_chopper(axis, tmc2130_mres[axis], tmc2130_current_h[axis], tmc2130_current_r[axis]);
// u = _micros() - u;
// printf_P(PSTR("tmc2130_setup_chopper %c %lu us"), "XYZE"[axis], u);
}
uint8_t tmc2130_get_pwr(uint8_t axis)
{
switch (axis)
{
case X_AXIS: return _GET_PWR_X;
case Y_AXIS: return _GET_PWR_Y;
case Z_AXIS: return _GET_PWR_Z;
case E_AXIS: return _GET_PWR_E;
}
return 0;
}
//! @par pwr motor power
//! * 0 disabled
//! * non-zero enabled
void tmc2130_set_pwr(uint8_t axis, uint8_t pwr)
{
switch (axis)
{
case X_AXIS: _SET_PWR_X(pwr); break;
case Y_AXIS: _SET_PWR_Y(pwr); break;
case Z_AXIS: _SET_PWR_Z(pwr); break;
case E_AXIS: _SET_PWR_E(pwr); break;
}
delayMicroseconds(TMC2130_SET_PWR_DELAY);
}
uint8_t tmc2130_get_inv(uint8_t axis)
{
switch (axis)
{
case X_AXIS: return INVERT_X_DIR;
case Y_AXIS: return INVERT_Y_DIR;
case Z_AXIS: return INVERT_Z_DIR;
case E_AXIS: return INVERT_E0_DIR;
}
return 0;
}
uint8_t tmc2130_get_dir(uint8_t axis)
{
switch (axis)
{
case X_AXIS: return _GET_DIR_X;
case Y_AXIS: return _GET_DIR_Y;
case Z_AXIS: return _GET_DIR_Z;
case E_AXIS: return _GET_DIR_E;
}
return 0;
}
void tmc2130_set_dir(uint8_t axis, uint8_t dir)
{
switch (axis)
{
case X_AXIS: _SET_DIR_X(dir); break;
case Y_AXIS: _SET_DIR_Y(dir); break;
case Z_AXIS: _SET_DIR_Z(dir); break;
case E_AXIS: _SET_DIR_E(dir); break;
}
delayMicroseconds(TMC2130_SET_DIR_DELAY);
}
void tmc2130_do_step(uint8_t axis)
{
switch (axis)
{
case X_AXIS: _DO_STEP_X; break;
case Y_AXIS: _DO_STEP_Y; break;
case Z_AXIS: _DO_STEP_Z; break;
case E_AXIS: _DO_STEP_E; break;
}
}
void tmc2130_do_steps(uint8_t axis, uint16_t steps, uint8_t dir, uint16_t delay_us)
{
if (tmc2130_get_dir(axis) != dir)
tmc2130_set_dir(axis, dir);
while (steps--)
{
tmc2130_do_step(axis);
delayMicroseconds(delay_us);
}
}
void tmc2130_goto_step(uint8_t axis, uint8_t step, uint8_t dir, uint16_t delay_us, uint16_t microstep_resolution)
{
printf_P(PSTR("tmc2130_goto_step %d %d %d %d \n"), axis, step, dir, delay_us, microstep_resolution);
uint8_t shift; for (shift = 0; shift < 8; shift++) if (microstep_resolution == (256u >> shift)) break;
uint16_t cnt = 4 * (1 << (8 - shift));
uint16_t mscnt = tmc2130_rd_MSCNT(axis);
if (dir == 2)
{
dir = tmc2130_get_inv(axis)?0:1;
int steps = (int)step - (int)(mscnt >> shift);
if (steps > static_cast<int>(cnt / 2))
{
dir ^= 1;
steps = cnt - steps; // This can create a negative step value
}
if (steps < 0)
{
dir ^= 1;
steps = -steps;
}
cnt = steps;
}
tmc2130_set_dir(axis, dir);
mscnt = tmc2130_rd_MSCNT(axis);
while ((cnt--) && ((mscnt >> shift) != step))
{
tmc2130_do_step(axis);
delayMicroseconds(delay_us);
mscnt = tmc2130_rd_MSCNT(axis);
}
}
void tmc2130_get_wave(uint8_t axis, uint8_t* data, FILE* stream)
{
uint8_t pwr = tmc2130_get_pwr(axis);
tmc2130_set_pwr(axis, 0);
tmc2130_setup_chopper(axis, tmc2130_usteps2mres(256), tmc2130_current_h[axis], tmc2130_current_r[axis]);
tmc2130_goto_step(axis, 0, 2, 100, 256);
tmc2130_set_dir(axis, tmc2130_get_inv(axis)?0:1);
for (unsigned int i = 0; i <= 255; i++)
{
uint32_t val = tmc2130_rd_MSCURACT(axis);
uint16_t mscnt = tmc2130_rd_MSCNT(axis);
int curA = (val & 0xff) | ((val << 7) & 0x8000);
if (stream)
{
if (mscnt == i)
fprintf_P(stream, PSTR("%d\t%d\n"), i, curA);
else //TODO - remove this check
fprintf_P(stream, PSTR("!! (i=%d MSCNT=%d)\n"), i, mscnt);
}
if (data) *(data++) = curA;
tmc2130_do_step(axis);
delayMicroseconds(100);
}
tmc2130_setup_chopper(axis, tmc2130_mres[axis], tmc2130_current_h[axis], tmc2130_current_r[axis]);
tmc2130_set_pwr(axis, pwr);
}
void tmc2130_set_wave(uint8_t axis, uint8_t amp, uint8_t fac1000)
{
// TMC2130 wave compression algorithm
// optimized for minimal memory requirements
// printf_P(PSTR("tmc2130_set_wave %hhd %hhd\n"), axis, fac1000);
2018-03-22 18:53:58 +00:00
if (fac1000 < TMC2130_WAVE_FAC1000_MIN) fac1000 = 0;
if (fac1000 > TMC2130_WAVE_FAC1000_MAX) fac1000 = TMC2130_WAVE_FAC1000_MAX;
float fac = 0;
if (fac1000) fac = ((float)((uint16_t)fac1000 + 1000) / 1000); //correction factor
// printf_P(PSTR(" factor: %s\n"), ftostr43(fac));
uint8_t vA = 0; //value of currentA
uint8_t va = 0; //previous vA
2018-07-17 15:44:46 +00:00
int8_t d0 = 0; //delta0
int8_t d1 = 1; //delta1
uint8_t w[4] = {1,1,1,1}; //W bits (MSLUTSEL)
uint8_t x[3] = {255,255,255}; //X segment bounds (MSLUTSEL)
uint8_t s = 0; //current segment
int8_t b; //encoded bit value
int8_t dA; //delta value
int i; //microstep index
uint32_t reg = 0; //tmc2130 register
tmc2130_wr_MSLUTSTART(axis, 0, amp);
for (i = 0; i < 256; i++)
{
2018-07-17 15:44:46 +00:00
if ((i & 0x1f) == 0)
reg = 0;
// calculate value
if (fac == 0) // default TMC wave
vA = (uint8_t)((amp+1) * sin((2*PI*i + PI)/1024) + 0.5) - 1;
else // corrected wave
vA = (uint8_t)(amp * pow(sin(2*PI*i/1024), fac) + 0.5);
dA = vA - va; // calculate delta
va = vA;
b = -1;
if (dA == d0) b = 0; //delta == delta0 => bit=0
else if (dA == d1) b = 1; //delta == delta1 => bit=1
else
{
if (dA < d0) // delta < delta0 => switch wbit down
{
//printf("dn\n");
b = 0;
switch (dA)
{
case -1: d0 = -1; d1 = 0; w[s+1] = 0; break;
case 0: d0 = 0; d1 = 1; w[s+1] = 1; break;
case 1: d0 = 1; d1 = 2; w[s+1] = 2; break;
default: b = -1; break;
}
if (b >= 0) { x[s] = i; s++; }
}
else if (dA > d1) // delta > delta0 => switch wbit up
{
//printf("up\n");
b = 1;
switch (dA)
{
case 1: d0 = 0; d1 = 1; w[s+1] = 1; break;
case 2: d0 = 1; d1 = 2; w[s+1] = 2; break;
case 3: d0 = 2; d1 = 3; w[s+1] = 3; break;
default: b = -1; break;
}
if (b >= 0) { x[s] = i; s++; }
}
}
if (b < 0) break; // delta out of range (<-1 or >3)
if (s > 3) break; // segment out of range (> 3)
//printf("%d\n", vA);
if (b == 1) reg |= 0x80000000;
if ((i & 31) == 31)
tmc2130_wr_MSLUT(axis, (uint8_t)(i >> 5), reg);
else
reg >>= 1;
// printf("%3d\t%3d\t%2d\t%2d\t%2d\t%2d %08x\n", i, vA, dA, b, w[s], s, reg);
}
tmc2130_wr_MSLUTSEL(axis, x[0], x[1], x[2], w[0], w[1], w[2], w[3]);
}
void bubblesort_uint8(uint8_t* data, uint8_t size, uint8_t* data2)
{
uint8_t changed = 1;
while (changed)
{
changed = 0;
for (uint8_t i = 0; i < (size - 1); i++)
if (data[i] > data[i+1])
{
uint8_t register d = data[i];
data[i] = data[i+1];
data[i+1] = d;
if (data2)
{
d = data2[i];
data2[i] = data2[i+1];
data2[i+1] = d;
}
changed = 1;
}
}
}
uint8_t clusterize_uint8(uint8_t* data, uint8_t size, uint8_t* ccnt, uint8_t* cval, uint8_t tol)
{
uint8_t cnt = 1;
uint16_t sum = data[0];
uint8_t cl = 0;
for (uint8_t i = 1; i < size; i++)
{
uint8_t d = data[i];
uint8_t val = sum / cnt;
uint8_t dif = 0;
if (val > d) dif = val - d;
else dif = d - val;
if (dif <= tol)
{
cnt += 1;
sum += d;
}
else
{
if (ccnt) ccnt[cl] = cnt;
if (cval) cval[cl] = val;
cnt = 1;
sum = d;
cl += 1;
}
}
if (ccnt) ccnt[cl] = cnt;
if (cval) cval[cl] = sum / cnt;
return ++cl;
}
bool tmc2130_home_calibrate(uint8_t axis)
{
uint8_t step[16];
uint8_t cnt[16];
uint8_t val[16];
2020-04-02 11:44:44 +00:00
homeaxis(axis, 16, step);
bubblesort_uint8(step, 16, 0);
puts_P(PSTR("sorted samples:"));
for (uint8_t i = 0; i < 16; i++)
printf_P(PSTR(" i=%2d step=%2d\n"), i, step[i]);
uint8_t cl = clusterize_uint8(step, 16, cnt, val, 1);
puts_P(PSTR("clusters:"));
for (uint8_t i = 0; i < cl; i++)
printf_P(PSTR(" i=%2d cnt=%2d val=%2d\n"), i, cnt[i], val[i]);
bubblesort_uint8(cnt, cl, val);
tmc2130_home_origin[axis] = val[cl-1];
printf_P(PSTR("result value: %d\n"), tmc2130_home_origin[axis]);
if (axis == X_AXIS) eeprom_update_byte((uint8_t*)EEPROM_TMC2130_HOME_X_ORIGIN, tmc2130_home_origin[X_AXIS]);
else if (axis == Y_AXIS) eeprom_update_byte((uint8_t*)EEPROM_TMC2130_HOME_Y_ORIGIN, tmc2130_home_origin[Y_AXIS]);
return true;
}
2019-09-27 13:42:31 +00:00
//! @brief Translate current to tmc2130 vsense and IHOLD or IRUN
//! @param cur current in mA
//! @return 0 .. 63
//! @n most significant bit is CHOPCONF vsense bit (sense resistor voltage based current scaling)
//! @n rest is to be used in IRUN or IHOLD register
//!
//! | mA | trinamic register | note |
//! | --- | --- | --- |
//! | 0 | 0 | doesn't mean current off, lowest current is 1/32 current with vsense low range |
//! | 30 | 1 | |
//! | 40 | 2 | |
//! | 60 | 3 | |
//! | 90 | 4 | |
//! | 100 | 5 | |
//! | 120 | 6 | |
//! | 130 | 7 | |
//! | 150 | 8 | |
//! | 180 | 9 | |
//! | 190 | 10 | |
//! | 210 | 11 | |
//! | 230 | 12 | |
//! | 240 | 13 | |
//! | 250 | 13 | |
//! | 260 | 14 | |
//! | 280 | 15 | |
//! | 300 | 16 | |
//! | 320 | 17 | |
//! | 340 | 18 | |
//! | 350 | 19 | |
//! | 370 | 20 | |
//! | 390 | 21 | |
//! | 410 | 22 | |
//! | 430 | 23 | |
//! | 450 | 24 | |
//! | 460 | 25 | |
//! | 480 | 26 | |
//! | 500 | 27 | |
//! | 520 | 28 | |
//! | 535 | 29 | |
//! | N/D | 30 | extruder default |
//! | 540 | 33 | |
//! | 560 | 34 | |
//! | 580 | 35 | |
//! | 590 | 36 | farm mode extruder default |
//! | 610 | 37 | |
//! | 630 | 38 | |
//! | 640 | 39 | |
//! | 660 | 40 | |
//! | 670 | 41 | |
//! | 690 | 42 | |
//! | 710 | 43 | |
//! | 720 | 44 | |
//! | 730 | 45 | |
//! | 760 | 46 | |
//! | 770 | 47 | |
//! | 790 | 48 | |
//! | 810 | 49 | |
//! | 820 | 50 | |
//! | 840 | 51 | |
//! | 850 | 52 | |
//! | 870 | 53 | |
//! | 890 | 54 | |
//! | 900 | 55 | |
//! | 920 | 56 | |
//! | 940 | 57 | |
//! | 950 | 58 | |
//! | 970 | 59 | |
//! | 980 | 60 | |
//! | 1000 | 61 | |
//! | 1020 | 62 | |
//! | 1029 | 63 | |
2018-11-12 19:39:25 +00:00
uint8_t tmc2130_cur2val(float cur)
{
if (cur < 0) cur = 0; //limit min
if (cur > 1029) cur = 1029; //limit max
//540mA is threshold for switch from high sense to low sense
//for higher currents is maximum current 1029mA
if (cur >= 540) return 63 * (float)cur / 1029;
//for lower currents must be the value divided by 1.125 (= 0.18*2/0.32)
return 63 * (float)cur / (1029 * 1.125);
}
float tmc2130_val2cur(uint8_t val)
{
float rsense = 0.2; //0.2 ohm sense resistors
uint8_t vsense = (val & 0x20)?0:1; //vsense bit = val>31
float vfs = vsense?0.18:0.32; //vfs depends on vsense bit
uint8_t val2 = vsense?val:(val >> 1); //vals 32..63 shifted right (16..31)
// equation from datasheet (0.7071 ~= 1/sqrt(2))
float cur = ((float)(val2 + 1)/32) * (vfs/(rsense + 0.02)) * 0.7071;
return cur * 1000; //return current in mA
}
#endif //TMC2130