Workshop 1

Dependencies:   PM2_Libary Eigen

main.cpp

Committer:
pmic
Date:
2022-03-22
Revision:
30:1e8295770bc1
Parent:
29:d6f1ccf42a31
Child:
31:1b2a1bd1bccb

File content as of revision 30:1e8295770bc1:

#include "mbed.h"
#include "PM2_Libary.h"

// logical variable main task
bool do_execute_main_task = false;  // this variable will be toggled via the user button (blue button) to or not to execute the main task

// user button on nucleo board
Timer user_button_timer;            // create Timer object which we use to check if user button was pressed for a certain time (robust against signal bouncing)
InterruptIn user_button(PC_13);     // create InterruptIn interface object to evaluate user button falling and rising edge (no blocking code in ISR)
void user_button_pressed_fcn();     // custom functions which gets executed when user button gets pressed and released, definition below
void user_button_released_fcn();

// while loop gets executed every main_task_period_ms milliseconds
int main_task_period_ms = 50;   // define main task period time in ms e.g. 50 ms -> main task runns 20 times per second
Timer main_task_timer;          // create Timer object which we use to run the main task every main task period time in ms

// led on nucleo board
DigitalOut user_led(LED1);      // create DigitalOut object to command user led

// additional Led
DigitalOut extra_led(PB_9);     // create DigitalOut object to command extra led (do add an aditional resistor, e.g. 220...500 Ohm)

// mechanical button
DigitalIn mechanical_button(PC_5);  // create DigitalIn object to evaluate extra mechanical button, you need to specify the mode for proper usage, see below

// Sharp GP2Y0A41SK0F, 4-40 cm IR Sensor
float ir_distance_mV = 0.0f;    // define variable to store measurement
AnalogIn ir_analog_in(PC_2);    // create AnalogIn object to read in infrared distance sensor, 0...3.3V are mapped to 0...1

// 78:1, 100:1, ... Metal Gearmotor 20Dx44L mm 12V CB
DigitalOut enable_motors(PB_15);    // create DigitalOut object to enable dc motors

float   pwm_period_s = 0.00005f;    // define pwm period time in seconds and create FastPWM objects to command dc motors
FastPWM pwm_M1(PB_13);              // motor M1 is used open loop
FastPWM pwm_M2(PA_9);               // motor M2 is closed-loop speed controlled (angle velocity)
FastPWM pwm_M3(PA_10);              // motor M3 is closed-loop position controlled (angle controlled)

EncoderCounter  encoder_M1(PA_6, PC_7); // create encoder objects to read in the encoder counter values
EncoderCounter  encoder_M2(PB_6, PB_7);
EncoderCounter  encoder_M3(PA_0, PA_1);

// create SpeedController and PositionController objects, default parametrization is for 78.125:1 gear box
float max_voltage = 12.0f;                  // define maximum voltage of battery packs, adjust this to 6.0f V if you only use one batterypack
float counts_per_turn = 20.0f * 78.125f;    // define counts per turn at gearbox end: counts/turn * gearratio
float kn = 180.0f / 12.0f;                  // define motor constant in rpm per V
float k_gear = 100.0f / 78.125f;            // define additional ratio in case you are using a dc motor with a different gear box, e.g. 100:1
float kp = 0.1f;                            // define custom kp, this is the default speed controller gain for gear box 78.125:1

// SpeedController speedController_M2(counts_per_turn, kn, max_voltage, pwm_M2, encoder_M2); // default 78.125:1 gear box  with default contoller parameters
SpeedController speedController_M2(counts_per_turn * k_gear, kn / k_gear, max_voltage, pwm_M2, encoder_M2); // parameters adjusted to 100:1 gear

float max_speed_rps = 0.5f;                 // define maximum speed that the position controller is changig the speed, has to be smaller or equal to kn * max_voltage
// PositionController positionController_M3(counts_per_turn, kn, max_voltage, pwm_M3, encoder_M3); // default 78.125:1 gear with default contoller parameters
PositionController positionController_M3(counts_per_turn * k_gear, kn / k_gear, kp * k_gear, max_voltage, pwm_M3, encoder_M3); // parameters adjusted to 100:1 gear, we need a different speed controller gain here

// Futaba Servo S3001 20mm 3kg Analog
Servo servo_S1(PB_2);           // create servo objects
Servo servo_S2(PC_8);
float servo_S1_angle = 0;       // servo S1 normalized angle
float servo_S2_angle = 0;       // servo S2 normalized angle
int servo_period_mus = 20000;   // define servo period time in mus

int servo_counter = 0;          // define servo counter, this is an additional variable to make the servos move
int loops_per_seconds = static_cast<int>(ceilf(1.0f/(0.001f*(float)main_task_period_ms))); // define loops per second

// Groove Ultrasonic Ranger V2.0
float us_distance_cm = 0.0f;    // define variable to store measurement
RangeFinder us_range_finder(PB_12, 5782.0f, 0.02f, 17500); // create range finder object (ultra sonic distance sensor), 20 Hz parametrization
// RangeFinder us_range_finder(PB_12, 5782.0f, 0.02f,  7000); // create range finder object (ultra sonic distance sensor), 50 Hz parametrization

// LSM9DS1 IMU, carefull: not all PES boards have an imu (chip shortage)
// LSM9DS1 imu(PC_9, PA_8); // create LSM9DS1 comunication object, if you want to be able to use the imu you need to #include "LSM9DS1_i2c.h"

int main()
{
    // attach button fall and rise functions to user button object
    user_button.fall(&user_button_pressed_fcn);
    user_button.rise(&user_button_released_fcn);

    // start timer
    main_task_timer.start();

    // set pullup mode: add resistor between pin and 3.3 V, so that there is a defined potential
    mechanical_button.mode(PullUp);

    // enable hardwaredriver dc motors: 0 -> disabled, 1 -> enabled
    enable_motors = 1;

    // motor M1 is used open-loop, we need to initialize the pwm and set pwm output to zero at the beginning, range: 0...1 -> u_min...u_max: 0.5 -> 0 V
    pwm_M1.period(pwm_period_s);
    pwm_M1.write(0.5f);

    // enable servos, you can also disable them at any point in your program if you don't want your servos to become warm
    servo_S1.Enable(servo_S1_angle, servo_period_mus);
    servo_S2.Enable(servo_S2_angle, servo_period_mus);

    while (true) { // this loop will run forever

        main_task_timer.reset();

        if (do_execute_main_task) {

            // read analog input
            ir_distance_mV = 1.0e3f * ir_analog_in.read() * 3.3f;

            // command dc motors if mechanical button is pressed
            if (mechanical_button.read()) {
                pwm_M1.write(0.75f); // write output voltage to motor M1
                speedController_M2.setDesiredSpeedRPS(0.5f); // set a desired speed for speed controlled dc motors M2
                positionController_M3.setDesiredRotation(1.5f, max_speed_rps); // set a desired rotation for position controlled dc motors M3
            } else {
                pwm_M1.write(0.5f);
                speedController_M2.setDesiredSpeedRPS(0.0f);
                positionController_M3.setDesiredRotation(0.0f, max_speed_rps);
            }

            // check if servos are enabled
            if (!servo_S1.isEnabled()) servo_S1.Enable(servo_S1_angle, servo_period_mus);
            if (!servo_S2.isEnabled()) servo_S2.Enable(servo_S2_angle, servo_period_mus);
            // command servo position, this needs to be calibrated
            servo_S1.SetPosition(servo_S1_angle);
            if (servo_S1_angle <= 1.0f & servo_counter%loops_per_seconds == 0 & servo_counter != 0) {
                servo_S1_angle += 0.01f;
            }
            servo_S2.SetPosition(servo_S2_angle);
            if (servo_S2_angle <= 1.0f & servo_counter%loops_per_seconds == 0 & servo_counter != 0) {
                servo_S2_angle += 0.01f;
            }
            servo_counter++;

            // read ultra sonic distance sensor
            us_distance_cm = us_range_finder.read_cm();

            // visual feedback that the main task is executed
            extra_led = 1;

        } else {

            ir_distance_mV = 0.0f;

            pwm_M1.write(0.5f);
            speedController_M2.setDesiredSpeedRPS(0.0f);
            positionController_M3.setDesiredRotation(0.0f, max_speed_rps);

            servo_S1_angle = 0;
            servo_S2_angle = 0;
            // servo_S1.SetPosition(servo_S1_angle);
            // servo_S2.SetPosition(servo_S2_angle);
            if (servo_S1.isEnabled()) servo_S1.Disable();
            if (servo_S2.isEnabled()) servo_S2.Disable();

            us_distance_cm = 0.0f;

            extra_led = 0;
        }

        user_led = !user_led;

        // do only output via serial what's really necessary (this makes your code slow)
        printf("IR sensor (mV): %3.3f, Encoder M1: %3d, Speed M2 (rps) %3.3f, Position M3 (rot): %3.3f, Servo S1 angle (normalized): %3.3f, Servo S2 angle (normalized): %3.3f, US sensor (cm): %3.3f\r\n",
               ir_distance_mV,
               encoder_M1.read(),
               speedController_M2.getSpeedRPS(),
               positionController_M3.getRotation(),
               servo_S1_angle,
               servo_S2_angle,
               us_distance_cm);

        // read out the imu, the actual frames of the sensor reading needs to be figured out
        // imu.updateGyro();
        // imu.updateAcc();
        // imu.updateMag();
        // printf("%.6f, %.6f, %.6f, %.6f, %.6f, %.6f, %.6f, %.6f, %.6f\r\n", imu.readGyroX(), imu.readGyroY(), imu.readGyroZ(),
        // imu.readAccX(), imu.readAccY(), imu.readAccZ(), imu.readMagX(), imu.readMagY(), imu.readMagZ());

        // read timer and make the main thread sleep for the remaining time span (non blocking)
        int main_task_elapsed_time_ms = std::chrono::duration_cast<std::chrono::milliseconds>(main_task_timer.elapsed_time()).count();
        thread_sleep_for(main_task_period_ms - main_task_elapsed_time_ms);
    }
}

void user_button_pressed_fcn()
{
    user_button_timer.start();
    user_button_timer.reset();
}

void user_button_released_fcn()
{
    // read timer and toggle do_execute_main_task if the button was pressed longer than the below specified time
    int user_button_elapsed_time_ms = std::chrono::duration_cast<std::chrono::milliseconds>(user_button_timer.elapsed_time()).count();
    user_button_timer.stop();
    if (user_button_elapsed_time_ms > 200) {
        do_execute_main_task = !do_execute_main_task;
    }
}