Code for controlling mbed hardware (LED's, motors), as well as code for the Raspberry Pi to run a Support Vector Machine that identifies objects using the Pi camera
Dependencies: mbed Motordriver mbed-rtos PololuLedStrip
mbed/main.cpp
- Committer:
- arogliero3
- Date:
- 2019-12-06
- Revision:
- 3:a3ed7ff99772
- Parent:
- 0:e0dbd261724a
File content as of revision 3:a3ed7ff99772:
#include "mbed.h" #include "rtos.h" #include "motordriver.h" #include "PololuLedStrip.h" // Connect mbed to Pi USB Serial pi(USBTX, USBRX); Serial blue(p9, p10); // Set up motors Motor L(p24, p23, p22, 1); // pwmA, fwd, rev, can brake Motor R(p21, p8, p7, 1); // pwmB, fwd, rev, can brake PololuLedStrip ledStrip(p5); // for LED strip Timer timer; volatile bool disco_mode = false; volatile bool tornado_mode = false; volatile bool autonomous_mode = false; #define LED_COUNT 82 rgb_color colors[LED_COUNT]; // Converts a color from the HSV representation to RGB. rgb_color hsvToRgb(float h, float s, float v) { int i = floor(h * 6); float f = h * 6 - i; float p = v * (1 - s); float q = v * (1 - f * s); float t = v * (1 - (1 - f) * s); float r = 0, g = 0, b = 0; switch(i % 6){ case 0: r = v; g = t; b = p; break; case 1: r = q; g = v; b = p; break; case 2: r = p; g = v; b = t; break; case 3: r = p; g = q; b = v; break; case 4: r = t; g = p; b = v; break; case 5: r = v; g = p; b = q; break; } return (rgb_color){r * 255, g * 255, b * 255}; } #define TIME_SLICE 5.0f // LEDs for debugging // Invalid character was read DigitalOut led1(LED1); // Detected tornado DigitalOut led2(LED2); DigitalOut led3(LED3); // Detected disco_ball DigitalOut led4(LED4); void forward() { L.speed(0.5); R.speed(0.5); wait(TIME_SLICE/10); L.coast(); R.coast(); } void backward() { L.speed(-0.5); R.speed(-0.5); wait(TIME_SLICE/10); L.coast(); R.coast(); } void left() { L.speed(-0.5); R.speed(0.5); wait(TIME_SLICE/10); L.coast(); R.coast(); } void right() { L.speed(0.5); R.speed(-0.5); wait(TIME_SLICE/10); L.coast(); R.coast(); } void stop() { L.stop(0); R.stop(0); } void led_strip() { timer.start(); while(1) { if (disco_mode) { // Update the colors array. uint32_t time = timer.read_ms(); for(int i = 0; i < LED_COUNT; i++) { uint8_t phase = (time >> 4) - (i << 2); colors[i] = hsvToRgb(phase / 256.0, 1.0, 0.25); } // Send the colors to the LED strip. ledStrip.write(colors, LED_COUNT); } else if (tornado_mode) { rgb_color temp; temp.red = 64; temp.green = 64; temp.blue = 0; for (int i = 0; i < LED_COUNT; i++) { colors[i] = temp; } ledStrip.write(colors, LED_COUNT); } else { rgb_color temp; temp.red = 64; temp.green = 0; temp.blue = 0; for (int i = 0; i < LED_COUNT; i++) { if (i == LED_COUNT/2) { temp.red = 0; temp.green = 64; } colors[i] = temp; } ledStrip.write(colors, LED_COUNT); } } } void detected_tornado() { tornado_mode = true; for (int i = 0; i < 10; i++) { left(); wait(0.5); } stop(); tornado_mode = false; } void detected_disco_ball() { led4 = 1; disco_mode = true; left(); left(); right(); right(); left(); left(); right(); right(); forward(); backward(); disco_mode = false; } void execute(char c) { switch (c) { case 'f': forward(); break; case 'b': backward(); break; case 'l': left(); break; case 'r': right(); break; case 't': detected_tornado(); break; case 'd': detected_disco_ball(); break; case 's': stop(); break; default: // invalid character led1 = 1; break; } } int main() { led1 = 0; led2 = 0; led3 = 0; led4 = 0; pi.baud(9600); char bnum, bhit; Thread t1; t1.start(led_strip); while(1) { // pi commands are read first if(pi.readable()) { char c = pi.getc(); if (c != 'n') execute(c); switch (c) { case 'd': case 't': pi.putc('f'); autonomous_mode = false; break; default: pi.putc(c); break; } } // bluetooth commands are read later if (!blue.readable()) continue; if (blue.getc()=='!') { if (blue.getc()=='B') { //button data packet bnum = blue.getc(); //button number bhit = blue.getc(); //1=hit, 0=release if (blue.getc()==char(~('!' + 'B' + bnum + bhit))) { //checksum OK? //myled = bnum - '0'; //current button number will appear on LEDs switch (bnum) { case '1': //number button 1 if (bhit=='1') { autonomous_mode = !autonomous_mode; if (!autonomous_mode) { pi.putc('f'); } else { pi.putc('a'); } //add hit code here } break; case '2': //number button 2 if (bhit=='1') { // execute('t'); // add hit code here } else { //add release code here } break; case '3': //number button 3 if (bhit=='1') { //add hit code here } else { //add release code here } break; case '4': //number button 4 if (bhit=='1') { //add hit code here } else { //add release code here } break; case '5': //button 5 up arrow if (bhit=='1') { //add hit code here forward(); } else { //add release code here stop(); } break; case '6': //button 6 down arrow if (bhit=='1') { //add hit code here backward(); } else { //add release code here stop(); } break; case '7': //button 7 left arrow if (bhit=='1') { //add hit code here left(); } else { //add release code here stop(); } break; case '8': //button 8 right arrow if (bhit=='1') { //add hit code here right(); } else { //add release code here stop(); } break; default: // stop(); break; } } } } } }