Meike Froklage
backup
Dependencies: HIDScope MODSERIAL Motordriver QEI Servo mbed
Fork of
The_Claw_with_EMG_Control
by 
Meike Froklage
main.cpp
- Committer:
- meikefrok
- Date:
- 2016-10-28
- Revision:
- 5:3d88f7506cd9
- Parent:
- 4:e62a2df0a5b5
- Child:
- 6:23b1ed826b59
File content as of revision 5:3d88f7506cd9:
#include "mbed.h"
#include "MODSERIAL.h"
#define SERIAL_BAUD 115200
#include "motordriver.h"
#include "QEI.h"
#include "Servo.h"
//======== Serial Communication ================================================
MODSERIAL pc(USBTX,USBRX);
//======== Motor and QEI =======================================================
int Brakeable;
int sign;
// motor
Motor Cart(D5, D4, D4, Brakeable); // right motor
Motor Arm(D6,D7, D7, Brakeable); // left motor
// qei
QEI Encoder_Cart(D10, D11, NC, 64);
QEI Encoder_Arm(D12, D13, NC, 64);
// servo
Servo servo(D9);
//======== Miscellaneous =======================================================
// button
InterruptIn btn(SW2);
InterruptIn btn2(SW3);
InterruptIn btn_cart(D1);
InterruptIn btn_arm(D2);
InterruptIn btn_claw(D3);
// led
DigitalOut led_r(LED_RED);
DigitalOut led_g(LED_GREEN);
DigitalOut led_b(LED_BLUE);
// potmeter
AnalogIn pot_cart(A2);
AnalogIn pot_arm(A3);
// ticker
Ticker tick_part; // ticker to switch parts
//======== Variables ===========================================================
// counters
int num_turned_on_0 = 0; // count number of times red LED turned on
int num_turned_on_1 = 0; // count number of times green LED turned on
int num_turned_on_2 = 0; // count number of times blue LED turned on
int num_claw_turned_on_0 = 0; // count number of times red LED turned on
int num_claw_turned_on_1 = 0; // count number of times green LED turned on
int num_claw_turned_on_2 = 0; // count number of times blue LED turned on
// speed
double cart_speed = 0.5;
double cart_stop = 0.2;
double arm_speed = 0.3;
double arm_stop = 0.1;
// position
float factor_cart = 0.06559;
float factor_arm = 0.1539;
int position_cart;
int position_arm;
float ain_cart; //Variable to store the analog input of the cart
float ain_arm; //Variable to store the analog input of the arm
// miscellaneous
const float kTimeToggle = 0.25f; // period with which to toggle the parts
const int LedOn = 0; // LED on if 0
volatile int part_id = 2; // ID of what part should move, begins with the cart
volatile int servo_id = 1; // ID to the side the servo should move, begins in center position
//>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>>
//======== Functions and main ==============================================================
// Switch between Cart, Arm and Claw
void SwitchPart()
{
switch (part_id) {
//Cart
case 2: {
led_r = LedOn;
if(led_r == LedOn){
num_turned_on_0++;
if(btn && btn2) {
Arm.speed(0) == 0;
Cart.speed(0) == 0;
}else if (btn && !btn2) {
if(position_cart <= -105){ //If the cart is at the right side, it stops
Cart.speed(-cart_stop)==-cart_stop;
}else if(position_cart >= 105 && position_arm <=-60){ //If the cart is at the left side and the arm is rotated 60 degrees to the left, the cart can't move to the right.
Cart.speed(cart_stop) == cart_stop;
}else{
Cart.speed(cart_speed)==cart_speed;
}
}else if (!btn && btn2) {
if(position_cart >= 105){ //If the cart is at the left side, it stops
Cart.speed(cart_stop)==cart_stop;
}else if(position_cart <= -105 && position_arm >=60){ //If the cart is at the right side and the arm is rotated 60 degrees to the right, the cart can't move to the left.
Cart.speed(-cart_stop) == -cart_stop;
}else{
Cart.speed(-cart_speed)==-cart_speed;
}
}else {
Arm.speed(0) == 0;
Cart.speed(0) == 0;
}
}
// controle LED
led_g = not LedOn;
led_b = not LedOn;
// encoder
position_cart = (Encoder_Cart.getPulses()*factor_cart) ;
ain_cart = pot_cart.read();
if (ain_cart == 0){
Encoder_Cart.reset();
}else {}
wait(0.1);
pc.baud(115200);
pc.printf("Distance in mm: %i\n", position_cart);
break;
}
//Arm
case 3: {
led_g = LedOn;
if(led_g == LedOn){
num_turned_on_1++;
if(btn && btn2) {
Arm.speed(0) == 0;
Cart.speed(0) == 0;
}
else if (btn && !btn2) {
if(position_cart > -105 && position_arm >= 30){ //If the cart is not at the end, the arm can't move any further than 30 degrees
Arm.speed(-arm_stop)==-arm_stop;
}else if(position_cart<= -105 && position_arm>=80){ //If the cart is at the right end, the arm can't move any further than 70 degrees
Arm.speed(-arm_stop)==-arm_stop;
}else{
Arm.speed(arm_speed)==arm_speed;
}
}else if (!btn && btn2) {
if(position_cart < 105 && position_arm <= -30){ //If the cart is not at the end, the arm can't move any further than 30 degrees
Arm.speed(arm_stop)==arm_stop;
}else if(position_cart>=105 && position_arm<=-80){ //If the cart is at the left end, the arm can't move any further than 70 degrees
Arm.speed(arm_stop)==arm_stop;
}else{
Arm.speed(-arm_speed)==-arm_speed;
}
}else {
Arm.speed(0) == 0;
Cart.speed(0) == 0;
}
}
// controle LED
led_r = not LedOn;
led_b = not LedOn;
// encoder
position_arm = (Encoder_Arm.getPulses()*factor_arm) ;
ain_arm = pot_arm.read();
if (ain_arm == 0){
Encoder_Arm.reset();
}else {}
wait(0.1);
pc.baud(115200);
pc.printf("Degrees: %i\n", position_arm);
break;
}
//Claw
case 4: {
led_b = LedOn;
if(led_b == LedOn){
num_turned_on_2++;
if(btn && btn2){
}else if(btn && !btn2){
servo_id ++;
switch (servo_id) {
case 0: {
led_r = LedOn;
if (led_r == LedOn) {
num_claw_turned_on_0++;
}
led_b = not LedOn;
led_g = not LedOn;
servo.position(27);
pc.printf("Servo position is: left \r\n");
break;
}
case 1: {
led_b = LedOn;
if (led_b == LedOn) {
num_claw_turned_on_1++;
}
led_r = not LedOn;
led_g = not LedOn;
servo.position(3);
pc.printf("Servo position is: center \r\n");
break;
}
case 2: {
led_g = LedOn;
if (led_g == LedOn) {
num_claw_turned_on_2++;
}
led_r = not LedOn;
led_b = not LedOn;
servo.position(-18);
pc.printf("Servo position is: right \r\n");
break;
}
}
}else if(!btn && btn2){
servo_id --;
switch (servo_id) {
case 0: {
led_r = LedOn;
if (led_r == LedOn) {
num_claw_turned_on_0++;
}
led_b = not LedOn;
led_g = not LedOn;
servo.position(27);
pc.printf("Servo position is: left \r\n");
break;
}
case 1: {
led_b = LedOn;
if (led_b == LedOn) {
num_claw_turned_on_1++;
}
led_r = not LedOn;
led_g = not LedOn;
servo.position(3);
pc.printf("Servo position is: center \r\n");
break;
}
case 2: {
led_g = LedOn;
if (led_g == LedOn) {
num_claw_turned_on_2++;
}
led_r = not LedOn;
led_b = not LedOn;
servo.position(-18);
pc.printf("Servo position is: right \r\n");
break;
}
}
}else{}
}
led_r = not LedOn;
led_g = not LedOn;
break;
}
}
}
// Switch the part
void SetValue2() {
part_id = 2;
}
void SetValue3() {
part_id = 3;
}
void SetValue4() {
part_id = 4;
}
// Main
int main()
{
led_r = not LedOn;
led_g = not LedOn;
led_b = not LedOn;
tick_part.attach(&SwitchPart,kTimeToggle);
btn_cart.fall(&SetValue2);
btn_arm.fall(&SetValue3);
btn_claw.fall(&SetValue4);
while (true);
}