Two-Wheel-Self-Balancing-Ro.../selfbalance-madgwick/selfbalance-madgwick.ino

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#include <QuickPID.h>
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#define MOT_DX_STEP 19
#define MOT_DX_DIR 18
#define MOT_SX_STEP 17
#define MOT_SX_DIR 16
// Nema 17 make 1.8° per step. Using A4988 drivers, and 1/16th microstepping, it results in 0.1125° per step
constexpr double ANGLE_PER_STEP = 0.1125;
// Just used a kitchen scale, good enough
constexpr double WEIGHT = 0.961;
constexpr double WHEEL_RADIUS = 0.0475;
// Experimentally, the lowest pulse my steppers can handle without stalling + some leeway
constexpr double MAX_HALF_PERIOD = 75; // in microseconds
// Which means there is a maximum velocity achievable
constexpr double MAX_VELOCITY = 1000000 * WHEEL_RADIUS / (2 * MAX_HALF_PERIOD * ANGLE_PER_STEP) * PI / 180;
// Derived and analytical model, linearized it and simulated in MATLAB.
// PID values are then calculated and verified by simulation in Simulink. I ain't calibrating a PID by hand on this robot
// I modified the ArduPID library to make it accept negative values for the parameters
constexpr double KP = 42;
constexpr double KI = KP * 10.8852;
constexpr double KD = 0.3;
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// IMU little bit tilted
// TODO: Implement an outer control loop for angular velocity. But that requires encoders on the motors
// TODO: try to achieve it crudely by just using a PI controller on the velocity given by the PID balance controller
float setpoint = 0.0;
float output = 0;
float input = 0;
float yaw{ 0 }, pitch{ 0 }, roll{ 0 };
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QuickPID pitchCtrl(&input, &output, &setpoint, KP, KI, KD, pitchCtrl.pMode::pOnError, pitchCtrl.dMode::dOnMeas, pitchCtrl.iAwMode::iAwCondition, pitchCtrl.Action::reverse);
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void setup() {
Serial.begin(9600);
delay(1000);
setup_imu();
// Just to signal it is working
pinMode(LED_BUILTIN, OUTPUT);
digitalWrite(LED_BUILTIN, HIGH);
// Let the initial error from madgwick filter discharge without affecting the integral term of the PID
unsigned long t = millis();
while (millis() - t < 5000) {
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update_imu();
}
// Backward because all coefficients need to be negative
pitchCtrl.SetOutputLimits(-MAX_VELOCITY, MAX_VELOCITY);
pitchCtrl.SetMode(pitchCtrl.Control::automatic);
pitchCtrl.SetSampleTimeUs(1000);
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digitalWrite(LED_BUILTIN, LOW);
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}
void setup1(){
pinMode(MOT_DX_DIR, OUTPUT);
pinMode(MOT_SX_DIR, OUTPUT);
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pinMode(MOT_DX_STEP, OUTPUT);
pinMode(MOT_SX_STEP, OUTPUT);
}
unsigned long last_time_motors = micros(), current_time_motors = micros();
bool b = true;
// Such a long halfperiod means that the motors are not moving
uint32_t t = INT_MAX;
int32_t period = INT_MAX, halfperiod1 = INT_MAX;
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void loop1(){
// TODO: handle the steppers using interrupt timers. The second core could be used for IMU processing, while the first one handles the different control loops
// Retrieve the half period value from core0. Non blocking call
if(rp2040.fifo.available()) {
rp2040.fifo.pop_nb(&t);
int32_t period = (int32_t)t;
// Direction need to be changed during motor pulse
// Doing it here unsure it happens at the correct time
if(period > 0){
// Positivie direction
digitalWriteFast(MOT_DX_DIR, HIGH);
digitalWriteFast(MOT_SX_DIR, HIGH);
halfperiod1 = (uint32_t)(period);
}else{
// Negative direction
digitalWriteFast(MOT_DX_DIR, LOW);
digitalWriteFast(MOT_SX_DIR, LOW);
halfperiod1 = (uint32_t)(-period);
}
}
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current_time_motors = micros();
if(current_time_motors - last_time_motors > halfperiod1){
// Half a pulse. Next cycle will be the rest
digitalWriteFast(MOT_DX_STEP, b);
digitalWriteFast(MOT_SX_STEP, b);
b = !b;
last_time_motors = current_time_motors;
}
}
double frequency = 0;
int32_t half_period0 = 0;
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double velocity = 0;
uint32_t current_time = millis(), last_time = millis();
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void loop() {
update_imu();
input = pitch;
//if(abs(input -setpoint) <= 0.01) input = setpoint;
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// I also modified the ArduPID library to use compute as a boolean. If calculations were done, it returns true. If not enough time has elapsed, it returns false
if(pitchCtrl.Compute()){
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double tvelocity = output;
tvelocity = tvelocity / WHEEL_RADIUS * 180 / PI;
frequency = tvelocity * 0.1125;
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half_period0 = 1000000 / (2*frequency);
// Send the half period to core 1. Non blocking
rp2040.fifo.push_nb(half_period0);
}
}