* 0x3D Angle (rad/s)
* 0x3E Angle (rad/s)
* 0x3F Angle (rad/s) LSB
- * free
* 0x40 Position x (m) MSB
* 0x41 Position x (m)
* 0x42 Position x (m)
* 0x91 Motor 2 switch
* 0x92 Motor 3 switch
* 0x93 Motor 4 switch
- * 0x94 TLE Error status
+ * 0x94 Front Handicap
+ * 0x95 Aft Handicap
+ * free
+ * 0xA0 Reset reason
+ * 0xA1 Error status
+ * 0xA2 count test
* free
* 0xff Bootloader
*/
-#define TWI_ACK TWCR = (1<<TWEA) | (1<<TWINT) | (1<<TWEN) | (1<<TWIE)
-#define TWI_RESET TWCR &= ~((1 << TWSTO) | (1 << TWEN)); TWI_ACK
-#define TWI_NAK TWCR = (1<<TWINT) | (1<<TWEN) | (1<<TWIE)
-
-#define KP 0.009
-#define KI 0.051429
-#define KD 0.000378
+#define KP 0.062
+#define KI 0.12
+#define KD 0.0
#define PID_T 0.01
-#define STEP_PER_M 3376.1 // wheel diameter=12cm, encoder=48cpr, gear ratio=1:34
-#define WHEEL_DIST 0.252
+// wheel diameter=12cm, encoder=48cpr, gear ratio=1:47
+// STEP_PER_M = 48*47/(d*pi)
+// Left real diameter: 0.12808, Right real diameter: 0.121
+#define STEP_PER_M 5770.8
+#define STEP_PER_M_LEFT (STEP_PER_M)
+#define STEP_PER_M_RIGHT (STEP_PER_M)
+#define WHEEL_DIST 0.39912 // Measured: 0.252
+#define PWM_BREAK INT16_MIN
+
+#define TWI_ACK TWCR = (1<<TWEA) | (1<<TWINT) | (1<<TWEN) | (1<<TWIE)
+#define TWI_RESET TWCR &= ~((1 << TWSTO) | (1 << TWEN)); TWI_ACK
+#define TWI_NAK TWCR = (1<<TWINT) | (1<<TWEN) | (1<<TWIE)
+#define ENABLE_PWM_MOTOR1 TCCR1A |= (1 << COM1A1)
+#define ENABLE_PWM_MOTOR2 TCCR1A |= (1 << COM1B1)
+#define ENABLE_PWM_MOTOR3 TCCR2 |= (1 << COM21);
+#define ENABLE_PWM_MOTOR4 TCCR0 |= (1 << COM01);
+#define DISABLE_PWM_MOTOR1 TCCR1A &= ~(1 << COM1A1)
+#define DISABLE_PWM_MOTOR2 TCCR1A &= ~(1 << COM1B1)
+#define DISABLE_PWM_MOTOR3 TCCR2 &= ~(1 << COM21);
+#define DISABLE_PWM_MOTOR4 TCCR0 &= ~(1 << COM01);
+
enum mode {
MOTOR_MANUAL,
static volatile enum mode motor2_mode=MOTOR_MANUAL;
static volatile enum mode motor3_mode=MOTOR_MANUAL;
static volatile enum mode motor4_mode=MOTOR_MANUAL;
-static volatile uint8_t motor1_switch=0;
-static volatile uint8_t motor2_switch=0;
+static volatile uint8_t motor1_switch=1;
+static volatile uint8_t motor2_switch=1;
static volatile uint8_t motor3_switch=0;
static volatile uint8_t motor4_switch=0;
static volatile int16_t speed1_wish=0; // step/s
static volatile int16_t speed2_wish=0;
static volatile int16_t speed3_wish=0;
static volatile int16_t speed4_wish=0;
-static volatile uint16_t run_update=0;
+static volatile int16_t speed1_wish_old=0;
+static volatile int16_t speed2_wish_old=0;
+static volatile int16_t speed3_wish_old=0;
+static volatile int16_t speed4_wish_old=0;
+static volatile uint8_t run_update=0;
static volatile int16_t speed1=0; // step/s
static volatile int16_t speed2=0;
static volatile int16_t speed3=0;
static volatile ufloat_t angle={0.0};
static volatile float cur_speed_lin=0;
static volatile float cur_speed_rot=0;
+static volatile uint8_t count_test=0;
+static volatile uint8_t front_handicap=0;
+static volatile uint8_t aft_handicap=0;
+static volatile uint8_t error_state=0;
ISR(TWI_vect)
{
static ufloat_t tmp_angle;
switch (TWSR & 0xF8)
- {
+ {
case 0x60: // start write
TWI_ACK;
ireg = 0;
break;
case 0x2B: // Left speed wish LSB
tmp_speed.i = tmp_speed.i << 8 | TWDR;
- speed1_wish = tmp_speed.f*STEP_PER_M;
- speed2_wish = tmp_speed.f*STEP_PER_M;
+ speed1_wish = tmp_speed.f*STEP_PER_M_LEFT;
+ speed2_wish = tmp_speed.f*STEP_PER_M_LEFT;
motor1_mode = MOTOR_PID;
motor2_mode = MOTOR_PID;
TWI_ACK;
break;
case 0x2F: // Right speed wish LSB
tmp_speed.i = tmp_speed.i << 8 | TWDR;
- speed1_wish = tmp_speed.f*STEP_PER_M;
- speed2_wish = tmp_speed.f*STEP_PER_M;
+ speed1_wish = tmp_speed.f*STEP_PER_M_RIGHT;
+ speed2_wish = tmp_speed.f*STEP_PER_M_RIGHT;
motor1_mode = MOTOR_PID;
motor2_mode = MOTOR_PID;
TWI_ACK;
motor4_switch = TWDR;
TWI_ACK;
break;
+ case 0x94: // Front Handicap
+ front_handicap = TWDR;
+ cmd_vel.bUpdate = 1;
+ TWI_ACK;
+ break;
+ case 0x95: // Aft Handicap
+ aft_handicap = TWDR;
+ cmd_vel.bUpdate = 1;
+ TWI_ACK;
+ break;
case 0xff: // bootloader
bootloader = TWDR;
default:
TWDR = OCR1A;
TWI_ACK;
break;
+ case 0x03: // Dummy to allow continous read
+ TWDR = 0;
+ TWI_ACK;
+ break;
case 0x04: // Motor 2 PWM
TWDR = OCR1B;
TWI_ACK;
break;
+ case 0x05: // Dummy to allow continous read
+ TWDR = 0;
+ TWI_ACK;
+ break;
case 0x06: // Motor 3 PWM
TWDR = OCR2;
TWI_ACK;
break;
+ case 0x07: // Dummy to allow continous read
+ TWDR = 0;
+ TWI_ACK;
+ break;
case 0x08: // Motor 4 PWM
TWDR = OCR0;
TWI_ACK;
break;
+ case 0x09: // Dummy to allow continous read
+ TWDR = 0;
+ TWI_ACK;
+ break;
case 0x10: // Hall 1 MSB
tmp16 = pos1;
TWDR = tmp16>>8;
TWI_ACK;
break;
case 0x48: // Position angle MSB
- TWDR = pos_y.i>>24;
+ TWDR = angle.i>>24;
TWI_ACK;
break;
case 0x49: // Position angle
- TWDR = pos_y.i>>16;
+ TWDR = angle.i>>16;
TWI_ACK;
break;
case 0x4A: // Position angle
- TWDR = pos_y.i>>8;
+ TWDR = angle.i>>8;
TWI_ACK;
break;
case 0x4B: // Position angle LSB
- TWDR = pos_y.i;
+ TWDR = angle.i;
TWI_ACK;
break;
- case 0x94: // TLE Error status
- TWDR = ~((PIND & 0x40)>>3 | (PINB & 0x07)) & 0xf;
+ case 0xA0: // Reset reason
+ TWDR = MCUCSR & 0x0f;
+ MCUCSR = 0x0;
TWI_ACK;
break;
+ case 0xA1: // Error status
+ TWDR = error_state;
+ TWI_ACK;
+ break;
+ case 0xA2: // count test
+ TWDR = count_test;
+ TWI_ACK;
default:
TWDR = 0;
TWI_NAK;
static int16_t m3_old=SHRT_MIN;
static int16_t m4_old=SHRT_MIN;
+ error_state &= 0xf0; // clear lower bits
+ error_state |= ~((PIND & 0x40)>>3 | (PINB & 0x07)) & 0xf;
+
if (m1_old != motor1) { // update only when changed
if (motor1 == 0) {
// stop
+ PORTC &= ~(1 << 3) & ~(1 << 2);
+ DISABLE_PWM_MOTOR1;
+ } else if (motor1 == PWM_BREAK) {
PORTC |= (1 << 3) | (1 << 2);
+ ENABLE_PWM_MOTOR1;
} else if ((!motor1_switch && motor1 > 0) || (motor1_switch && motor1 < 0)) {
// forward
- PORTC &= ~(1 << 3) & ~(1 << 2);
+ uint8_t tmp=PORTC;
+ tmp &= ~(1 << 3);
+ tmp |= (1 << 2);
+ PORTC = tmp;
+ ENABLE_PWM_MOTOR1;
} else { // motor1 < 0
// backward
- PORTC &= ~(1 << 2);
- PORTC |= (1 << 3);
+ uint8_t tmp=PORTC;
+ tmp &= ~(1 << 2);
+ tmp |= (1 << 3);
+ PORTC = tmp;
+ ENABLE_PWM_MOTOR1;
}
m1_old = motor1;
if (m2_old != motor2) { // update only when changed
if (motor2 == 0) {
// stop
+ PORTC &= ~(1 << 5) & ~(1 << 4);
+ DISABLE_PWM_MOTOR2;
+ } else if (motor2 == PWM_BREAK) {
PORTC |= (1 << 5) | (1 << 4);
+ ENABLE_PWM_MOTOR2;
} else if ((!motor2_switch && motor2 > 0) || (motor2_switch && motor2 < 0)) {
// forward
- PORTC &= ~(1 << 5) & ~(1 << 4);
+ uint8_t tmp=PORTC;
+ tmp &= ~(1 << 5);
+ tmp |= (1 << 4);
+ PORTC = tmp;
+ ENABLE_PWM_MOTOR2;
} else { // motor2 < 0
// backward
- PORTC &= ~(1 << 4);
- PORTC |= (1 << 5);
+ uint8_t tmp=PORTC;
+ tmp &= ~(1 << 4);
+ tmp |= (1 << 5);
+ PORTC = tmp;
+ ENABLE_PWM_MOTOR2;
}
m2_old = motor2;
if (m3_old != motor3) { // update only when changed
if (motor3 == 0) {
// stop
+ PORTC &= ~(1 << 7) & ~(1 << 6);
+ DISABLE_PWM_MOTOR3;
+ } else if (motor3 == PWM_BREAK) {
PORTC |= (1 << 7) | (1 << 6);
+ ENABLE_PWM_MOTOR3;
} else if ((!motor3_switch && motor3 > 0) || (motor3_switch && motor3 < 0)) {
// forward
- PORTC &= ~(1 << 7) & ~(1 << 6);
+ uint8_t tmp=PORTC;
+ tmp &= ~(1 << 7);
+ tmp |= (1 << 6);
+ PORTC = tmp;
+ ENABLE_PWM_MOTOR3;
} else { // motor3 < 0
// backward
- PORTC &= ~(1 << 6);
- PORTC |= (1 << 7);
+ uint8_t tmp=PORTC;
+ tmp &= ~(1 << 6);
+ tmp |= (1 << 7);
+ PORTC = tmp;
+ ENABLE_PWM_MOTOR3;
}
m3_old = motor3;
if (m4_old != motor4) { // update only when changed
if (motor4 == 0) {
// stop
+ PORTD &= ~(1 << 3) & ~(1 << 2);
+ DISABLE_PWM_MOTOR4;
+ } else if (motor4 == PWM_BREAK) {
PORTD |= (1 << 3) | (1 << 2);
+ ENABLE_PWM_MOTOR4;
} else if ((!motor4_switch && motor4 > 0) || (motor4_switch && motor4 < 0)) {
// forward
- PORTD &= ~(1 << 3) & ~(1 << 2);
+ uint8_t tmp=PORTD;
+ tmp &= ~(1 << 3);
+ tmp |= (1 << 2);
+ PORTD = tmp;
+ ENABLE_PWM_MOTOR4;
} else { // motor4 < 0
// backward
- PORTD &= ~(1 << 2);
- PORTD |= (1 << 3);
+ uint8_t tmp=PORTD;
+ tmp &= ~(1 << 2);
+ tmp |= (1 << 3);
+ PORTD = tmp;
+ ENABLE_PWM_MOTOR4;
}
m4_old = motor4;
int16_t pos3_diff;
int16_t pos4_diff;
float diff_left_m, diff_right_m, angle_diff, translation;
- float pos_x_diff, pos_y_diff, angle_new;
- int16_t speed_l, speed_r;
+ float pos_x_new, pos_y_new, angle_new;
float tmp_speed_lin, tmp_speed_rot;
+ int16_t cur_pos1, cur_pos2, cur_pos3, cur_pos4;
+ int16_t new_speed1, new_speed2, new_speed3, new_speed4;
+ // copy to tmp
cli();
- pos1_diff = pos1 - pos1_last;
- pos2_diff = pos2 - pos2_last;
- pos3_diff = pos3 - pos3_last;
- pos4_diff = pos4 - pos4_last;
- speed1 = pos1_diff/PID_T;
- speed2 = pos2_diff/PID_T;
- speed3 = pos3_diff/PID_T;
- speed4 = pos4_diff/PID_T;
+ cur_pos1 = pos1;
+ cur_pos2 = pos2;
+ cur_pos3 = pos3;
+ cur_pos4 = pos4;
sei();
- diff_left_m = (pos1_diff + pos2_diff)/(2*STEP_PER_M);
- diff_right_m = (pos3_diff + pos4_diff)/(2*STEP_PER_M);
+ pos1_diff = cur_pos1 - pos1_last;
+ pos2_diff = cur_pos2 - pos2_last;
+ pos3_diff = cur_pos3 - pos3_last;
+ pos4_diff = cur_pos4 - pos4_last;
+
+ new_speed1 = pos1_diff/PID_T;
+ new_speed2 = pos2_diff/PID_T;
+ new_speed3 = pos3_diff/PID_T;
+ new_speed4 = pos4_diff/PID_T;
+
+ diff_left_m = (pos1_diff + pos2_diff)/(2*STEP_PER_M_LEFT);
+ diff_right_m = (pos3_diff + pos4_diff)/(2*STEP_PER_M_RIGHT);
angle_diff = (diff_right_m - diff_left_m) / WHEEL_DIST;
angle_new = angle.f + angle_diff;
if (angle_new > 2*M_PI) angle_new-=2*M_PI;
- else if (angle_new < 2*M_PI) angle_new+=2*M_PI;
+ else if (angle_new < -2*M_PI) angle_new+=2*M_PI;
translation = (diff_left_m + diff_right_m)/2.0;
- pos_x_diff = cos(angle_new)*translation;
- pos_y_diff = sin(angle_new)*translation;
-
- cli();
- angle.f = angle_new;
- pos_x.f += pos_x_diff;
- pos_y.f += pos_y_diff;
- sei();
+ pos_x_new = pos_x.f + cos(angle_new)*translation;
+ pos_y_new = pos_y.f + sin(angle_new)*translation;
- speed_l = (speed1+speed2)/2;
- speed_r = (speed3+speed4)/2;
- tmp_speed_lin = (speed_l + speed_r)/(2.0*STEP_PER_M);
- tmp_speed_rot = (speed_r - speed_l)/(M_PI*WHEEL_DIST*STEP_PER_M);
+ tmp_speed_lin = translation/PID_T;
+ tmp_speed_rot = angle_diff/PID_T;
+ // copy from tmp
cli();
+ angle.f = angle_new;
+ pos_x.f = pos_x_new;
+ pos_y.f = pos_y_new;
+ speed1 = new_speed1;
+ speed2 = new_speed2;
+ speed3 = new_speed3;
+ speed4 = new_speed4;
cur_speed_lin = tmp_speed_lin;
cur_speed_rot = tmp_speed_rot;
sei();
- pos1_last = pos1;
- pos2_last = pos2;
- pos3_last = pos3;
- pos4_last = pos4;
+ pos1_last = cur_pos1;
+ pos2_last = cur_pos2;
+ pos3_last = cur_pos3;
+ pos4_last = cur_pos4;
}
static int32_t esum3=0;
static int32_t esum4=0;
+ // protect motors from damage if stalling
+ if (labs(esum1) > 140000 && speed1 == 0) {
+ motor1 = 0;
+ motor1_mode = MOTOR_MANUAL;
+ error_state |= (1<<4);
+ esum1 = 0;
+ }
+ if (labs(esum2) > 140000 && speed2 == 0) {
+ motor2 = 0;
+ motor2_mode = MOTOR_MANUAL;
+ error_state |= (1<<5);
+ esum2 = 0;
+ }
+ if (labs(esum3) > 140000 && speed3 == 0) {
+ motor3 = 0;
+ motor3_mode = MOTOR_MANUAL;
+ error_state |= (1<<6);
+ esum3 = 0;
+ }
+ if (labs(esum4) > 140000 && speed4 == 0) {
+ motor4 = 0;
+ motor4_mode = MOTOR_MANUAL;
+ error_state |= (1<<7);
+ esum4 = 0;
+ }
+
if (motor1_mode == MOTOR_PID) {
+ if (speed1_wish != speed1_wish_old) {
+ if (abs(speed1_wish - speed1_wish_old) > 500) esum1 = 0;
+ speed1_wish_old = speed1_wish;
+ }
+
if (speed1_wish == 0) {
motor1 = 0;
eold1 = 0;
- esum1 = 0;
+ error_state &= ~(1<<4);
} else {
int16_t e = speed1_wish - speed1;
esum1+=e;
- motor1 += KP*e + KI*PID_T*esum1 + KD/PID_T*(e - eold1);
+ motor1 = KP*e + KI*PID_T*esum1 + KD/PID_T*(e - eold1);
eold1 = e;
- if (motor1 > 255) motor1 = 255;
+ if (motor1 > 0 && speed1_wish < 0) motor1=PWM_BREAK;
+ else if (motor1 < 0 && speed1_wish > 0) motor1=PWM_BREAK;
+ else if (motor1 > 255) motor1 = 255;
else if (motor1 < -255) motor1 = -255;
}
}
if (motor2_mode == MOTOR_PID) {
+ if (speed2_wish != speed2_wish_old) {
+ if (abs(speed2_wish - speed2_wish_old) > 500) esum2 = 0;
+ speed2_wish_old = speed2_wish;
+ }
+
if (speed2_wish == 0) {
motor2 = 0;
eold2 = 0;
- esum2 = 0;
+ error_state &= ~(1<<5);
} else {
int16_t e = speed2_wish - speed2;
esum2+=e;
- motor2 += KP*e + KI*PID_T*esum2 + KD/PID_T*(e - eold2);
+ motor2 = KP*e + KI*PID_T*esum2 + KD/PID_T*(e - eold2);
eold2 = e;
- if (motor2 > 255) motor2 = 255;
+ if (motor2 > 0 && speed2_wish < 0) motor2=PWM_BREAK;
+ else if (motor2 < 0 && speed2_wish > 0) motor2=PWM_BREAK;
+ else if (motor2 > 255) motor2 = 255;
else if (motor2 < -255) motor2 = -255;
}
}
if (motor3_mode == MOTOR_PID) {
+ if (speed3_wish != speed3_wish_old) {
+ if (abs(speed3_wish - speed3_wish_old) > 500) esum3 = 0;
+ speed3_wish_old = speed3_wish;
+ }
+
if (speed3_wish == 0) {
motor3 = 0;
eold3 = 0;
- esum3 = 0;
+ error_state &= ~(1<<6);
} else {
int16_t e = speed3_wish - speed3;
esum3+=e;
- motor3 += KP*e + KI*PID_T*esum3 + KD/PID_T*(e - eold3);
+ motor3 = KP*e + KI*PID_T*esum3 + KD/PID_T*(e - eold3);
eold3 = e;
- if (motor3 > 255) motor3 = 255;
+ if (motor3 > 0 && speed3_wish < 0) motor3=PWM_BREAK;
+ else if (motor3 < 0 && speed3_wish > 0) motor3=PWM_BREAK;
+ else if (motor3 > 255) motor3 = 255;
else if (motor3 < -255) motor3 = -255;
}
}
if (motor4_mode == MOTOR_PID) {
+ if (speed4_wish != speed4_wish_old) {
+ if (abs(speed4_wish - speed4_wish_old) > 500) esum4 = 0;
+ speed4_wish_old = speed4_wish;
+ }
+
if (speed4_wish == 0) {
motor4 = 0;
eold4 = 0;
- esum4 = 0;
+ error_state &= ~(1<<7);
} else {
int16_t e = speed4_wish - speed4;
esum4+=e;
- motor4 += KP*e + KI*PID_T*esum4 + KD/PID_T*(e - eold4);
+ motor4 = KP*e + KI*PID_T*esum4 + KD/PID_T*(e - eold4);
eold4 = e;
- if (motor4 > 255) motor4 = 255;
+ if (motor4 > 0 && speed4_wish < 0) motor4=PWM_BREAK;
+ else if (motor4 < 0 && speed4_wish > 0) motor4=PWM_BREAK;
+ else if (motor4 > 255) motor4 = 255;
else if (motor4 < -255) motor4 = -255;
}
}
DDRB = (1 << 3);
DDRC = (1 << 7) | (1 << 6) | (1 << 5) | (1 << 4) | (1 << 3) | (1 << 2);
DDRD = (1 << 7) | (1 << 5) | (1 << 4) | (1 << 3) | (1 << 2);
+ // Pullup Diag/Enable
+ PORTB = (1 << 0) | (1 << 1) | (1 << 2);
+ PORTD = (1 << 6);
bootloader = 0x00;
setup_uart(9600);
TWI_RESET;
// Motor 1 & 2
- // Timer 1: Fast PWM inverting mode, Top=256 => 31.25kHz
+ // Also used for PWM frequency TIMER1_FREQ (F_CPU/256)
+ // Timer 1: Fast PWM non-inverting mode, Top=255 => 19.531kHz
// Prescaler=1
- TCCR1A = (1 << COM1A1) | (1 << COM1B1) | (1 << COM1A0) | (1 << COM1B0) | (1 << WGM10);
+ //TCCR1A = (1 << COM1A1) | (1 << COM1B1) | (1 << WGM10);
+ // Avoid narrow spike on extreme pwm value 0 by not setting COM1*1
+ TCCR1A = (1 << WGM10);
TCCR1B = (1 << WGM12) | (1 << CS10);
OCR1A = 0;
OCR1B = 0;
// Motor 3
- // Timer 2: Fast PWM inverting mode, Top=256
+ // Timer 2: Fast PWM non-inverting mode, Top=255
// Prescaler=1
- TCCR2 = (1 << WGM21) | (1 << WGM20) | (1 << COM21) | (1 << COM20) | (1 << CS20);
+ //TCCR2 = (1 << WGM21) | (1 << WGM20) | (1 << COM21) | (1 << CS20);
+ // Avoid narrow spike on extreme pwm value 0 by not setting COM21
+ TCCR2 = (1 << WGM21) | (1 << WGM20) | (1 << CS20);
OCR2 = 0;
// Motor 4
- // Timer 0: Fast PWM inverting mode, Top=256
+ // Timer 0: Fast PWM non-inverting mode, Top=255
// Prescaler=1
- TCCR0 = (1 << WGM01) | (1 << WGM00) | (1 << COM01) | (1 << COM00) | (1 << CS00);
+ //TCCR0 = (1 << WGM01) | (1 << WGM00) | (1 << COM01) | (1 << CS00);
+ // Avoid narrow spike on extreme pwm value 0 by not setting COM01
+ TCCR0 = (1 << WGM01) | (1 << WGM00) | (1 << CS00);
OCR0 = 0;
printf("\r\nStart\r\n");
}
if (cmd_vel.bUpdate) {
- float speed_wish_right = cmd_vel.angle*M_PI*WHEEL_DIST/2 + cmd_vel.speed;
- float speed_wish_left = cmd_vel.speed*2-speed_wish_right;
+ float speed_wish_right, speed_wish_left;
+ float speed, angle;
+ cli();
+ speed = cmd_vel.speed;
+ angle = cmd_vel.angle;
cmd_vel.bUpdate = 0;
- speed_wish_left*=STEP_PER_M;
- speed_wish_right*=STEP_PER_M;
+ sei();
+
+ speed_wish_right = (angle*WHEEL_DIST)/2 + speed;
+ speed_wish_left = speed*2-speed_wish_right;
- speed1_wish = speed_wish_left;
- speed2_wish = speed_wish_left;
- speed3_wish = speed_wish_right;
- speed4_wish = speed_wish_right;
+ speed_wish_left*=STEP_PER_M_LEFT;
+ speed_wish_right*=STEP_PER_M_RIGHT;
+
+ if (aft_handicap > 0) {
+ speed1_wish = speed_wish_left * (100-aft_handicap)/100.0;
+ speed3_wish = speed_wish_right * (100-aft_handicap)/100.0;
+ } else {
+ speed1_wish = speed_wish_left;
+ speed3_wish = speed_wish_right;
+ }
+ if (front_handicap > 0) {
+ speed2_wish = speed_wish_left * (100-front_handicap)/100.0;
+ speed4_wish = speed_wish_right * (100-front_handicap)/100.0;
+ } else {
+ speed2_wish = speed_wish_left;
+ speed4_wish = speed_wish_right;
+ }
motor1_mode = MOTOR_PID;
motor2_mode = MOTOR_PID;
motor3_mode = MOTOR_PID;
motor4_mode = MOTOR_PID;
}
- if (run_update >= 312) { // ~100Hz
+ if (run_update >= 195) { // TIMER1_FREQ/195 = ~100Hz
run_update=0;
update_pos();
update_pid();
update_motor();
+ count_test++;
}
sleep_mode();