Biorobotics 7
State machine
Dependencies: mbed Adafruit_GFX BioroboticsMotorControl MODSERIAL BioroboticsEMGFilter
main.cpp
- Committer:
- brass_phoenix
- Date:
- 2018-11-01
- Revision:
- 40:7e8d0632757c
- Parent:
- 39:f119ca6fc821
- Child:
- 41:8640b5782bc7
File content as of revision 40:7e8d0632757c:
#include "mbed.h"
#include "constants.h"
#include "Button.h"
#include "Screen.h"
#include "motor.h"
#include "EMGFilter.h"
#include "motor_calibration.h"
#include "forward_kinematics.h"
#include "inverse_kinematics.h"
#include "end_effector_control.h"
#include "EMG_calibration.h"
enum States {waiting, calib_motor, calib_bicep1, calib_bicep2, homing, operation, demo, failure}; // The possible states of the state machine
// Controll directions for the demo controller.
enum DebugControlDirection {debug_up, debug_down, debug_left, debug_right};
Motor main_motor(D6, D7, D13, D12);
Motor sec_motor(D5, D4, D10, D11);
AnalogIn potmeter1(A5); // Analoge input van potmeter 1 -> Motor 1
AnalogIn potmeter2(A4); // Analoge input van potmeter 2 -> Motor 2
EMGFilter emg_1(A0);
EMGFilter emg_2(A1);
States current_state; // Defining the state we are currently in
States last_state; // To detect state changes.
Ticker loop_ticker; // Ticker for the loop function
// Order of buttons: up_down, left_right, panic
// D2, D3, D8
Button ud_button(D2);
Button lr_button(D3);
Button p_button(D8);
Ticker button_ticker;
DigitalOut led_red(LED_RED);
DigitalOut led_green(LED_GREEN);
DigitalOut led_blue(LED_BLUE);
// The last arguent is the reset pin.
// The screen doesn't use it, but the library requires it
// So pick a pin we don't use.
Screen screen(D14, D15, D9);
// Which direction the emg will control the arm.
// Up or down.
// Left or right.
bool control_goes_up = false;
bool control_goes_right = false;
void do_state_waiting()
{
if(last_state != current_state) {
last_state = current_state;
// State just changed to this one.
led_green = 1;
screen.clear_display();
screen.display_state_name("Waiting");
screen.get_screen_handle()->printf(" Press to start ");
screen.get_screen_handle()->printf(" | ");
screen.get_screen_handle()->printf(" V ");
screen.display();
}
if (ud_button.has_just_been_pressed()) {
current_state = calib_motor;
}
}
void do_state_calib_motor()
{
static double main_last_angle;
static double sec_last_angle;
static int main_iterations_not_moving;
static int sec_iterations_not_moving;
static bool main_is_calibrated;
static bool sec_is_calibrated;
if(last_state != current_state) {
last_state = current_state;
// State just changed to this one.
led_green = 1;
led_blue = 1;
screen.clear_display();
screen.display_state_name("Motor calibration");
main_last_angle = -10;
sec_last_angle = -10;
main_iterations_not_moving = 0;
sec_iterations_not_moving = 0;
main_is_calibrated = false;
sec_is_calibrated = false;
}
if (!main_is_calibrated) {
led_green = 1;
main_is_calibrated = calibrate_motor(main_motor, main_last_angle, main_iterations_not_moving);
if (main_is_calibrated) {
main_motor.define_current_angle_as_x_radians(main_motor_calibration_angle);
//main_motor.set_target_angle(main_motor_calibration_angle - 0.2); // Give the arm some breathing space.
led_green = 0;
}
}
if (!sec_is_calibrated) {
led_blue = 1;
sec_is_calibrated = calibrate_motor(sec_motor, sec_last_angle, sec_iterations_not_moving);
if (sec_is_calibrated) {
sec_motor.define_current_angle_as_x_radians(sec_motor_calibration_angle); // -42 degrees.
//main_motor.set_target_angle(sec_motor_calibration_angle + 0.2); // Give the arm some breathing space.
led_blue = 0;
}
}
screen.get_screen_handle()->setTextCursor(0, 8);
screen.get_screen_handle()->printf("M: %i \n", main_iterations_not_moving);
screen.get_screen_handle()->printf("S: %i \n", sec_iterations_not_moving);
screen.display();
if (main_is_calibrated && sec_is_calibrated) {
current_state = homing;
}
}
void do_state_homing()
{
const double home_x = 0.6524; // Meters.
const double home_y = 0.3409;
double main_home;
double sec_home;
if(last_state != current_state) {
last_state = current_state;
// State just changed to this one.
screen.clear_display();
screen.display_state_name("Homing");
inverse_kinematics(home_x, home_y, main_home, sec_home);
main_motor.set_target_angle(main_home);
sec_motor.set_target_angle(sec_home);
screen.get_screen_handle()->setTextCursor(0, 8);
screen.get_screen_handle()->printf("Ma: %.6f \n", main_home);
screen.get_screen_handle()->printf("Sa: %.6f \n", sec_home);
screen.display();
}
if (ud_button.has_just_been_pressed()) {
current_state = calib_bicep1;
}
if (lr_button.has_just_been_pressed()) {
current_state = demo;
}
}
void do_state_calib_bicep1()
{
static EMG_calibration calibration = EMG_calibration(&screen, &emg_1);
if(last_state != current_state) {
last_state = current_state;
// State just changed to this one.
screen.clear_display();
screen.display_state_name("EMG 1 calibration");
calibration.start();
}
if (ud_button.has_just_been_pressed() && calibration.is_calibrated()) {
current_state = calib_bicep2;
}
}
void do_state_calib_bicep2()
{
static EMG_calibration calibration = EMG_calibration(&screen, &emg_2);
if(last_state != current_state) {
last_state = current_state;
// State just changed to this one.
screen.clear_display();
screen.display_state_name("EMG 2 calibration");
calibration.start();
}
if (ud_button.has_just_been_pressed() && calibration.is_calibrated()) {
current_state = operation;
}
}
void do_state_operation()
{
static bool debug_forward_kinematics;
if(last_state != current_state) {
last_state = current_state;
// State just changed to this one.
screen.clear_display();
screen.display_state_name("Normal operation");
control_goes_up = true;
control_goes_right = true;
screen.display_up_down_arrow(control_goes_up);
screen.display_left_right_arrow(control_goes_right);
debug_forward_kinematics = true;
}
/*
if (debug_forward_kinematics) {
// Using potmeters for debugging purposes;
double main_angle = ((potmeter1.read() * 2) - 1) * PI;
double sec_angle = ((potmeter2.read() * 2) - 1) * PI;
double e_x = 0.0;
double e_y = 0.0;
forward_kinematics(main_angle, sec_angle, e_x, e_y);
screen.get_screen_handle()->setTextCursor(0, 0);
screen.get_screen_handle()->printf("M_a: %.6f \n", main_angle);
screen.get_screen_handle()->printf("S_a: %.6f \n", sec_angle);
screen.get_screen_handle()->printf("X: %.6f \n", e_x);
screen.get_screen_handle()->printf("Y: %.6f ", e_y);
screen.display();
} else {
// Using potmeters for debugging purposes;
double e_x = potmeter1.read();
double e_y = potmeter2.read();
double main_angle = 0.0;
double sec_angle = 0.0;
inverse_kinematics(e_x, e_y, main_angle, sec_angle);
screen.get_screen_handle()->setTextCursor(0, 0);
screen.get_screen_handle()->printf("E_x: %.6f \n", e_x);
screen.get_screen_handle()->printf("E_y: %.6f \n", e_y);
screen.get_screen_handle()->printf("M_a: %.6f \n", main_angle);
screen.get_screen_handle()->printf("S_a: %.6f ", sec_angle);
screen.display();
}
if (lr_button.has_just_been_pressed()) {
debug_forward_kinematics = !debug_forward_kinematics;
}*/
// Debug emg calibration.
led_blue = emg_1.get_is_envelope_over_threshold();
led_green = emg_2.get_is_envelope_over_threshold();
/*
double main_target = ((potmeter1.read() * 2) - 1) * PI;
main_motor.set_target_angle(main_target);
double sec_target = ((potmeter2.read() * 2) - 1) * PI;
sec_motor.set_target_angle(sec_target);
if (lr_button.has_just_been_pressed()) {
control_goes_right = !control_goes_right;
screen.display_left_right_arrow(control_goes_right);
}
*/
if (ud_button.has_just_been_pressed()) {
control_goes_up = !control_goes_up;
control_goes_right = !control_goes_right;
screen.display_up_down_arrow(control_goes_up);
screen.display_left_right_arrow(control_goes_right);
}
}
void do_state_demo() {
static DebugControlDirection control_direction;
static const double max_speed = 0.01;
static double speed_x;
static double speed_y;
if(last_state != current_state) {
last_state = current_state;
// State just changed.
// Update the display.
led_red = 1;
led_green = 0;
led_blue = 1;
screen.clear_display();
screen.display_state_name("Demo mode!");
control_direction = debug_up;
speed_x = 0;
speed_y = 0;
screen.display_up_down_arrow(control_goes_up);
screen.display_left_right_arrow(control_goes_right);
}
if (lr_button.has_just_been_pressed()) {
switch (control_direction) {
case debug_up:
control_direction = debug_right;
speed_x = max_speed;
speed_y = 0;
break;
case debug_right:
control_direction = debug_down;
speed_x = 0;
speed_y = -max_speed;
break;
case debug_down:
control_direction = debug_left;
speed_x = -max_speed;
speed_y = 0;
break;
case debug_left:
control_direction = debug_up;
speed_x = 0;
speed_y = max_speed;
break;
}
}
if (ud_button.is_pressed()) {
led_blue = 0;
double main_cur_angle = main_motor.get_current_angle();
double sec_cur_angle = sec_motor.get_current_angle();
double main_target, sec_target;
end_effector_control(speed_x, speed_y, main_cur_angle, sec_cur_angle, main_target, sec_target);
main_motor.set_target_angle(main_target);
sec_motor.set_target_angle(sec_target);
screen.get_screen_handle()->setTextCursor(0, 0);
screen.get_screen_handle()->printf("M_a: %.6f \n", main_cur_angle);
screen.get_screen_handle()->printf("S_a: %.6f \n", sec_cur_angle);
screen.get_screen_handle()->printf("Vx: %.6f \n", main_target);
screen.get_screen_handle()->printf("Vy: %.6f ", sec_target);
screen.display();
}
}
void do_state_failure()
{
if(last_state != current_state) {
last_state = current_state;
// State just changed.
// Update the display.
led_red = 0;
led_green = 1;
led_blue = 1;
screen.clear_display();
screen.display_state_name("STOP");
}
// Stop the motors!
main_motor.stop();
sec_motor.stop();
}
void main_loop()
{
ud_button.update();
lr_button.update();
p_button.update();
switch (current_state) {
case waiting:
do_state_waiting();
break;
case calib_motor:
do_state_calib_motor();
break;
case calib_bicep1:
do_state_calib_bicep1();
break;
case calib_bicep2:
do_state_calib_bicep2();
break;
case homing:
do_state_homing();
break;
case operation:
do_state_operation();
break;
case demo:
do_state_demo();
break;
case failure:
do_state_failure();
break;
}
// Check if the panic button was pressed.
// Doesn't matter in which state we are, we need to go to failure.
if (p_button.is_pressed()) {
current_state = failure;
}
}
void poll_buttons() {
// We need to poll the pins periodically.
// Normally one would use rise and fall interrupts, so this wouldn't be
// needed. But the buttons we use generate so much chatter that
// sometimes a rising or a falling edge doesn't get registered.
// With all the confusion that accompanies it.
ud_button.poll_pin();
lr_button.poll_pin();
p_button.poll_pin();
}
int main()
{
led_red = 1;
led_green = 1;
led_blue = 1;
screen.clear_display();
main_motor.set_pid_k_values(Kp, Ki, Kd);
sec_motor.set_pid_k_values(Kp, Ki, Kd);
// One of the motors is reversed in the electronics.
// This is fixed in the motor controll board, so we have to account
// for it in software.
main_motor.set_extra_reduction_ratio(-main_gear_ratio);
sec_motor.set_extra_reduction_ratio(sec_gear_ratio);
// Set the maximum speed for both motors.
main_motor.set_max_speed(0.5);
sec_motor.set_max_speed(0.5);
// Start the motor controller at the desired frequency.
main_motor.start(pid_period);
sec_motor.start(pid_period);
// Start in the waiting state.
current_state = waiting;
// Pretend we come from the operation state.
// So that the waiting state knows it just got started.
last_state = operation;
emg_1.start(emg_period);
emg_2.start(emg_period);
// Start the button polling ticker.
button_ticker.attach(&poll_buttons, button_poll_interval);
while (true) {
main_loop();
wait(main_loop_wait_time);
}
}