/************************************************************************* * Arduino GPS/OBD-II/G-Force Data Logger * Distributed under GPL v2.0 * Copyright (c) 2013 Stanley Huang * All rights reserved. *************************************************************************/ #include #include #include "OBD.h" #include "SD.h" #include "MultiLCD.h" #include "TinyGPS.h" #include "MPU6050.h" #include "images.h" /************************************** * Choose SD pin here **************************************/ //#define SD_CS_PIN 4 // ethernet shield //#define SD_CS_PIN 7 // microduino #define SD_CS_PIN 10 // SD breakout /************************************** * Config GPS here **************************************/ #define USE_GPS #define GPS_BAUDRATE 115200 /* bps */ //#define GPS_OPEN_BAUDRATE 4800 /* bps */ /************************************** * Other options **************************************/ //#define USE_MPU6050 //#define OBD_MIN_INTERVAL 200 /* ms */ #define GPS_DATA_TIMEOUT 2000 /* ms */ //#define CONSOLE Serial // logger states #define STATE_SD_READY 0x1 #define STATE_OBD_READY 0x2 #define STATE_GPS_CONNECTED 0x4 #define STATE_GPS_READY 0x8 #define STATE_ACC_READY 0x10 #define STATE_DATE_SAVED 0x20 // additional PIDs (non-OBD) #define PID_GPS_DATETIME 0xF0 #define PID_GPS_SPEED 0xF01 #define PID_GPS_COORDINATE 0xF2 #define PID_GPS_ALTITUDE 0xF3 #define PID_ACC 0xF8 #define PID_GYRO 0xF9 #define FILE_NAME_FORMAT "OBD%05d.CSV" #ifdef USE_GPS // GPS logging can only be enabled when there is additional hardware serial UART #if defined(__AVR_ATmega2560__) || defined(__AVR_ATmega1280__) #define GPSUART Serial2 #elif defined(__AVR_ATmega644P__) #define GPSUART Serial1 #endif #ifdef GPSUART #define PMTK_SET_NMEA_UPDATE_1HZ "$PMTK220,1000*1F" #define PMTK_SET_NMEA_UPDATE_5HZ "$PMTK220,200*2C" #define PMTK_SET_NMEA_UPDATE_10HZ "$PMTK220,100*2F" #define PMTK_SET_NMEA_OUTPUT_ALLDATA "$PMTK314,1,1,1,1,1,1,0,0,0,0,0,0,0,0,0,0,0,0,0*28" #define PMTK_SET_BAUDRATE "$PMTK251,115200*1F" TinyGPS gps; #endif // GPSUART #endif // SD card Sd2Card card; SdVolume volume; File sdfile; LCD_ILI9325D lcd; /* for 2.8" TFT shield */ #define LCD_LINES 24 #define CHAR_WIDTH 6 static uint32_t fileSize = 0; static uint32_t lastFileSize = 0; static uint32_t lastDataTime; static uint32_t lastGPSDataTime = 0; static uint16_t lastSpeed = -1; static int startDistance = 0; static uint16_t fileIndex = 0; static uint32_t startTime = 0; // cached data to be displayed static byte lastPID = 0; static int lastData; class CLogger : public COBD { public: CLogger():state(0) {} void Setup() { lcd.setLineHeight(10); ShowStates(); #ifdef USE_MPU6050 if (MPU6050_init() == 0) state |= STATE_ACC_READY; ShowStates(); #endif #ifdef GPSUART unsigned long t = millis(); do { if (GPSUART.available()) { state |= STATE_GPS_CONNECTED; break; } } while (millis() - t <= 1000); #endif do { ShowStates(); } while (!Init()); state |= STATE_OBD_READY; ShowStates(); ShowPidsInfo(); delay(3000); ReadSensor(PID_DISTANCE, startDistance); // open file for logging if (!(state & STATE_SD_READY)) { if (CheckSD()) { state |= STATE_SD_READY; ShowStates(); } } fileSize = 0; char filename[13]; sprintf(filename, FILE_NAME_FORMAT, fileIndex); sdfile = SD.open(filename, FILE_WRITE); if (!sdfile) { } InitScreen(); lastDataTime = millis(); } void Loop() { static byte loopCount = 0; static uint32_t lastTime = millis(); static byte dataCount = 0; dataCount += 3; LogData(PID_RPM); #ifdef GPSUART if (millis() - lastGPSDataTime > GPS_DATA_TIMEOUT || gps.satellites() < 3) { // GPS not ready state &= ~STATE_GPS_READY; } else { // GPS ready state |= STATE_GPS_READY; } LogData(PID_SPEED); #else LogData(PID_SPEED); #endif LogData(PID_THROTTLE); if (state & STATE_ACC_READY) { ProcessAccelerometer(); } switch (loopCount++) { case 0: case 64: case 128: case 192: LogData(PID_DISTANCE); dataCount++; break; case 4: LogData(PID_COOLANT_TEMP); dataCount++; break; case 20: LogData(PID_INTAKE_TEMP); dataCount++; break; } uint32_t t = millis(); if (t >> 10 != lastTime >> 10) { char buf[10]; unsigned int sec = (t - startTime) / 1000; sprintf(buf, "%02u:%02u", sec / 60, sec % 60); lcd.setCursor(260, 3); lcd.print(buf); sprintf(buf, "%ums ", (uint16_t)(t - lastTime) / dataCount); lcd.setCursor(260, 9); lcd.print(buf); dataCount = 0; lastTime = t; } if (errors >= 5) { Reconnect(); loopCount = 0; } } bool CheckSD() { state &= ~STATE_SD_READY; pinMode(SS, OUTPUT); lcd.setCursor(0, 3); if (card.init(SPI_HALF_SPEED, SD_CS_PIN)) { const char* type; char buf[20]; switch(card.type()) { case SD_CARD_TYPE_SD1: type = "SD1"; break; case SD_CARD_TYPE_SD2: type = "SD2"; break; case SD_CARD_TYPE_SDHC: type = "SDHC"; break; default: type = "SDx"; } lcd.print(type); lcd.write(' '); if (!volume.init(card)) { lcd.print("No FAT!"); return false; } uint32_t volumesize = volume.blocksPerCluster(); volumesize >>= 1; // 512 bytes per block volumesize *= volume.clusterCount(); volumesize >>= 10; sprintf(buf, "%dGB", (int)((volumesize + 511) / 1000)); lcd.print(buf); } else { lcd.print("No SD Card "); return false; } if (!SD.begin(SD_CS_PIN)) { lcd.setCursor(8 * CHAR_WIDTH, 0); lcd.print("Bad SD"); return false; } char filename[13]; // now determine log file name for (fileIndex = 1; fileIndex; fileIndex++) { sprintf(filename, FILE_NAME_FORMAT, fileIndex); if (!SD.exists(filename)) { break; } } if (!fileIndex) { lcd.setCursor(8 * CHAR_WIDTH, 8); lcd.print("Bad File"); return false; } lcd.setCursor(10 * CHAR_WIDTH, 3); lcd.print(filename); state |= STATE_SD_READY; return true; } private: void InitIdleLoop() { // called while initializing char buf[10]; unsigned int t = (millis() - startTime) / 1000; sprintf(buf, "%02u:%02u", t / 60, t % 60); lcd.setCursor(0, 23); lcd.print(buf); #ifdef GPSUART // detect GPS signal if (GPSUART.available()) { char c = GPSUART.read(); if (gps.encode(c)) { state |= STATE_GPS_READY; lastGPSDataTime = millis(); unsigned long date, time; gps.get_datetime(&date, &time, 0); long lat, lon; gps.get_position(&lat, &lon, 0); lcd.setCursor(0, 8); lcd.print("Time:"); lcd.print(time); lcd.setCursor(0, 9); lcd.print("LAT: "); lcd.print(lat); lcd.setCursor(0, 10); lcd.print("LON: "); lcd.println(lon); } } #endif #ifdef USE_MPU6050 if (state & STATE_ACC_READY) { accel_t_gyro_union data; MPU6050_readout(&data); char buf[8]; sprintf(buf, "X:%4d", data.value.x_accel / 190); lcd.setCursor(10 * CHAR_WIDTH, 1); lcd.print(buf); sprintf(buf, "Y:%4d", data.value.y_accel / 190); lcd.setCursor(10 * CHAR_WIDTH, 2); lcd.print(buf); sprintf(buf, "Z:%4d", data.value.z_accel / 190); lcd.setCursor(10 * CHAR_WIDTH, 3); lcd.print(buf); delay(100); } #endif } #ifdef GPSUART void DataIdleLoop() { if (GPSUART.available()) ProcessGPS(); } void ProcessGPS() { // process GPS data char c = GPSUART.read(); if (!gps.encode(c)) return; // parsed GPS data is ready uint32_t dataTime = millis(); uint16_t elapsed = (uint16_t)(dataTime - lastDataTime); int len; char buf[32]; unsigned long date, time; gps.get_datetime(&date, &time, 0); len = sprintf(buf, "%u,F0,%ld %ld\n", elapsed, date, time); sdfile.write((uint8_t*)buf, len); unsigned int speed = (unsigned int)(gps.speed() * 1852 / 100 / 1000); // no need to log GPS data when vehicle has not been moving // that's when previous speed is zero and current speed is also zero if (!(speed == 0 && lastSpeed == 0) && gps.satellites() >= 3) { // lastSpeed will be updated //ShowSensorData(PID_SPEED, speed); len = sprintf(buf, "%u,F1,%u\n", elapsed, speed); sdfile.write((uint8_t*)buf, len); long lat, lon; gps.get_position(&lat, &lon, 0); len = sprintf(buf, "%u,F2,%ld %ld\n", elapsed, lat, lon); sdfile.write((uint8_t*)buf, len); if (((unsigned int)dataTime / 1000) & 1) sprintf(buf, "LAT:%d.%ld ", (int)(lat / 100000), lat % 100000); else sprintf(buf, "LON:%d.%ld ", (int)(lon / 100000), lon % 100000); lcd.setCursor(0, 7); lcd.print(buf); len = sprintf(buf, "%u,F3,%ld\n", elapsed, gps.altitude()); sdfile.write((uint8_t*)buf, len); } lastDataTime = dataTime; lastGPSDataTime = dataTime; } #endif void ProcessAccelerometer() { #ifdef USE_MPU6050 accel_t_gyro_union data; MPU6050_readout(&data); uint32_t dataTime = millis(); ShowGForce(data.value.y_accel); int len; uint16_t elapsed = (uint16_t)(dataTime - lastDataTime); char buf[20]; // log x/y/z of accelerometer len = sprintf(buf, "%u,F10,%d %d %d\n", data.value.x_accel, data.value.y_accel, data.value.z_accel); sdfile.write((uint8_t*)buf, len); // log x/y/z of gyro meter len = sprintf(buf, "%u,F11,%d %d %d\n", data.value.x_gyro, data.value.y_gyro, data.value.z_gyro); sdfile.write((uint8_t*)buf, len); lastDataTime = dataTime; #endif } void LogData(byte pid) { char buffer[OBD_RECV_BUF_SIZE]; int value; uint32_t start = millis(); // send a query to OBD adapter for specified OBD-II pid Query(pid); // wait for reponse bool hasData; do { DataIdleLoop(); } while (!(hasData = available()) && millis() - start < OBD_TIMEOUT_SHORT); // no need to continue if no data available if (!hasData) { errors++; return; } // display data while waiting for OBD response ShowSensorData(lastPID, lastData); // get response from OBD adapter pid = 0; char* data = GetResponse(pid, buffer); if (!data) { // try recover next time write('\r'); return; } // keep data timestamp of returned data as soon as possible uint32_t dataTime = millis(); // convert raw data to normal value value = GetConvertedValue(pid, data); lastPID = pid; lastData = value; // log data to SD card char buf[32]; uint16_t elapsed = (uint16_t)(dataTime - lastDataTime); byte len = sprintf(buf, "%u,%X,%d\n", elapsed, pid, value); // log OBD data sdfile.write((uint8_t*)buf, len); fileSize += len; lastDataTime = dataTime; // flush SD data every 1KB if (fileSize - lastFileSize >= 1024) { sdfile.flush(); // display logged data size char buf[7]; sprintf(buf, "%uKB", (int)(fileSize >> 10)); lcd.setCursor(260, 7); lcd.print(buf); lastFileSize = fileSize; } // if OBD response is very fast, go on processing other data for a while #ifdef OBD_MIN_INTERVAL while (millis() - start < OBD_MIN_INTERVAL) { DataIdleLoop(); } #endif } void ShowPidsInfo() { char buffer[24]; byte pidlist[] = {PID_RPM, PID_SPEED, PID_THROTTLE, PID_ENGINE_LOAD, PID_MAF_FLOW, PID_INTAKE_MAP, PID_FUEL_LEVEL, PID_FUEL_PRESSURE, PID_COOLANT_TEMP, PID_INTAKE_TEMP, PID_AMBIENT_TEMP, PID_TIMING_ADVANCE, PID_BAROMETRIC}; const char* namelist[] = {"ENGINE RPM", "SPEED", "THROTTLE", "ENGINE LOAD", "MAF", "MAP", "FUEL LEVEL", "FUEL PRESSURE", "COOLANT TEMP", "INTAKE TEMP","AMBIENT TEMP", "IGNITION TIMING", "BAROMETER"}; for (byte i = 0; i < sizeof(pidlist) / sizeof(pidlist[0]); i++) { lcd.setCursor(30 * CHAR_WIDTH, i + 4); sprintf(buffer, "%s: %s", namelist[i], IsValidPID(PID_RPM) ? "Yes" : "No"); lcd.print(buffer); } } void Reconnect() { sdfile.close(); lcd.clear(); lcd.print("Reconnecting..."); state &= ~(STATE_OBD_READY | STATE_ACC_READY | STATE_DATE_SAVED); //digitalWrite(SD_CS_PIN, LOW); for (int i = 0; !Init(); i++) { if (i == 10) lcd.clear(); } fileIndex++; Setup(); } byte state; // screen layout related stuff void ShowStates() { lcd.setCursor(0, 4); lcd.print("GPS:"); if (state & STATE_GPS_READY) lcd.print("Yes"); else if (state & STATE_GPS_CONNECTED) lcd.print("--"); else lcd.print("No"); lcd.setCursor(0, 5); lcd.print("ACC:"); lcd.print((state & STATE_ACC_READY) ? "Yes" : "No"); lcd.setCursor(0, 6); lcd.print("OBD:"); lcd.print((state & STATE_OBD_READY) ? "Yes" : "No"); } virtual void ShowSensorData(byte pid, int value) { char buf[8]; switch (pid) { case PID_RPM: lcd.setCursor(34, 9); lcd.printInt((unsigned int)value % 10000, FONT_SIZE_XLARGE, 4); break; case PID_SPEED: if (lastSpeed != value) { lcd.setCursor(50, 3); lcd.printInt((unsigned int)value % 1000, FONT_SIZE_XLARGE, 3); lastSpeed = value; } break; /* case PID_THROTTLE: lcd.setCursor(66, 8); lcd.printInt(value % 100, FONT_SIZE_XLARGE, 2); break; case PID_INTAKE_TEMP: lcd.setCursor(64, 3); lcd.printInt(value, FONT_SIZE_LARGE, 3); break; */ case PID_DISTANCE: if ((unsigned int)value >= startDistance) { sprintf(buf, "%ukm", ((unsigned int)value - startDistance) % 1000); lcd.setCursor(260, 5); lcd.print(buf); } break; } } virtual void ShowGForce(int g) { byte n; /* 0~1.5g -> 0~8 */ g /= 85 * 25; lcd.setCursor(0, 1); if (g == 0) { lcd.clearLine(1); } else if (g < 0 && g >= -8) { for (n = 0; n < 8 + g; n++) { lcd.write(' '); } for (; n < 8; n++) { lcd.write('<'); } lcd.print(" "); } else if (g > 0 && g < 8) { lcd.print(" "); for (n = 0; n < g; n++) { lcd.write('>'); } for (; n < 8; n++) { lcd.write(' '); } } } virtual void InitScreen() { //lcd.clear(); lcd.setLineHeight(8); lcd.backlight(true); lcd.clear(156, 0, 8, 240); lcd.clear(0, 116, 320, 8); lcd.draw2x(frame0[0], 0, 0, 78, 58); lcd.draw2x(frame0[0], 164, 0, 78, 58); lcd.draw2x(frame0[0], 0, 124, 78, 58); lcd.draw2x(frame0[0], 164, 124, 78, 58); lcd.setCursor(63, 2); lcd.print("SPEED"); lcd.setCursor(110, 5); lcd.print("km/h"); lcd.setCursor(60, 8); lcd.print("ENGINE"); lcd.setCursor(110, 11); lcd.print("rpm"); lcd.setCursor(190, 3); lcd.print("Elapsed:"); lcd.setCursor(190, 5); lcd.print("Distance:"); lcd.setCursor(190, 7); lcd.print("Data Size:"); lcd.setCursor(190, 9); lcd.print("OBD Time:"); /* lcd.setCursor(32, 4); lcd.print("%"); lcd.setCursor(68, 5); lcd.print("Intake Air"); lcd.setCursor(112, 4); lcd.print("C"); */ } }; static CLogger logger; void setup() { lcd.begin(); //lcd.clear(); lcd.backlight(true); lcd.print("MEGA LOGGER - OBD-II/GPS/G-FORCE DATA LOGGER"); lcd.setCursor(0, 1); lcd.print("Initializing..."); #ifdef CONSOLE CONSOLE.begin(115200); #endif // start serial communication at the adapter defined baudrate OBDUART.begin(OBD_SERIAL_BAUDRATE); #ifdef GPSUART #ifdef GPS_OPEN_BAUDRATE GPSUART.begin(GPS_OPEN_BAUDRATE); delay(10); GPSUART.println(PMTK_SET_BAUDRATE); GPSUART.end(); #endif GPSUART.begin(GPS_BAUDRATE); // switching to 10Hz mode, effective only for MTK3329 //GPSUART.println(PMTK_SET_NMEA_OUTPUT_ALLDATA); //GPSUART.println(PMTK_SET_NMEA_UPDATE_5HZ); #endif delay(500); //lcd.setColor(0x7FF); lcd.print("OK"); logger.CheckSD(); logger.Setup(); } void loop() { logger.Loop(); }