/*************************************************************************
* Arduino GPS/OBD-II/G-Force Data Logger
* Distributed under GPL v2.0
* Copyright (c) 2013 Stanley Huang <stanleyhuangyc@gmail.com>
* All rights reserved.
*************************************************************************/
#include <Arduino.h>
#if OBD_MODEL == OBD_MODEL_I2C
#include <Wire.h>
#endif
#include <OBD.h>
#include <SD.h>
#include <MultiLCD.h>
#include <TinyGPS.h>
#include <MPU6050.h>
#include <SPI.h>
#include "config.h"
#include "images.h"
#if ENABLE_DATA_OUT
#include <SoftwareSerial.h>
#endif
#include "datalogger.h"
// 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
#ifdef USE_GPS
// GPS logging can only be enabled when there is additional hardware serial UART
#if defined(__AVR_ATmega2560__) || defined(__AVR_ATmega1280__) || defined(__SAM3X8E__)
#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
#if !defined(__AVR_ATmega2560__) && !defined(__AVR_ATmega1280__) && !defined(__AVR_ATmega644P__) && !defined(__SAM3X8E__)
#define MEMORY_SAVING
#endif
static uint8_t lastFileSize = 0;
static uint32_t lastGPSDataTime = 0;
static uint32_t lastACCDataTime = 0;
static uint8_t lastRefreshTime = 0;
static uint16_t lastSpeed = -1;
static uint16_t startDistance = 0;
static uint16_t fileIndex = 0;
static uint32_t startTime = 0;
static byte pidTier1[]= {PID_RPM, PID_SPEED, PID_ENGINE_LOAD, PID_THROTTLE};
static byte pidTier2[] = {PID_INTAKE_MAP, PID_MAF_FLOW, PID_TIMING_ADVANCE};
static byte pidTier3[] = {PID_COOLANT_TEMP, PID_INTAKE_TEMP, PID_AMBIENT_TEMP, PID_FUEL_LEVEL};
#define TIER_NUM1 sizeof(pidTier1)
#define TIER_NUM2 sizeof(pidTier2)
#define TIER_NUM3 sizeof(pidTier3)
#if OBD_MODEL == OBD_MODEL_I2C
class COBDLogger : public COBDI2C, public CDataLogger
#else
class COBDLogger : public COBD, public CDataLogger
#endif
{
public:
COBDLogger():state(0) {}
void setup()
{
lastGPSDataTime = 0;
showStates();
#if USE_MPU6050
if (MPU6050_init() == 0) state |= STATE_ACC_READY;
showStates();
#endif
#ifdef GPSUART
unsigned long t = millis();
do {
if (GPSUART.available() && GPSUART.read() == '\r') {
state |= STATE_GPS_CONNECTED;
break;
}
} while (millis() - t <= 2000);
#endif
do {
showStates();
} while (!init(OBD_PROTOCOL));
state |= STATE_OBD_READY;
showStates();
//lcd.setFont(FONT_SIZE_MEDIUM);
//lcd.setCursor(0, 14);
//lcd.print("VIN: XXXXXXXX");
// open file for logging
if (!(state & STATE_SD_READY)) {
if (checkSD()) {
state |= STATE_SD_READY;
showStates();
}
}
#if ENABLE_DATA_LOG
uint16_t index = openFile();
lcd.setCursor(0, 6);
lcd.print("File ID:");
lcd.printInt(index);
#endif
#if 0
showECUCap();
delay(1000);
#endif
read(PID_DISTANCE, (int&)startDistance);
initScreen();
lastRefreshTime = millis() >> 10;
}
void loop()
{
static byte index = 0;
static byte index2 = 0;
static byte index3 = 0;
uint32_t t = millis();
logOBDData(pidTier1[index++]);
t = millis() - t;
if (index == TIER_NUM1) {
index = 0;
if (index2 == TIER_NUM2) {
index2 = 0;
logOBDData(pidTier3[index3]);
index3 = (index3 + 1) % TIER_NUM3;
} else {
logOBDData(pidTier2[index2++]);
}
}
if (dataTime >> 10 != lastRefreshTime) {
char buf[10];
unsigned int sec = (dataTime - startTime) / 1000;
sprintf(buf, "%02u:%02u", sec / 60, sec % 60);
lcd.setFont(FONT_SIZE_MEDIUM);
lcd.setCursor(250, 2);
lcd.print(buf);
lcd.setCursor(250, 11);
lcd.printInt((uint16_t)t);
lcd.print("ms ");
lastRefreshTime = dataTime >> 10;
}
if (errors >= 10) {
reconnect();
}
#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;
}
#endif
}
bool checkSD()
{
#if ENABLE_DATA_LOG
Sd2Card card;
SdVolume volume;
state &= ~STATE_SD_READY;
pinMode(SS, OUTPUT);
lcd.setCursor(0, 4);
lcd.setFont(FONT_SIZE_MEDIUM);
if (card.init(SPI_FULL_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, "%dMB", (int)volumesize);
lcd.print(buf);
} else {
lcd.print("No SD Card ");
return false;
}
lcd.setCursor(0, 6);
if (!SD.begin(SD_CS_PIN)) {
lcd.print("Bad SD");
return false;
}
state |= STATE_SD_READY;
return true;
#else
return false;
#endif
}
private:
void dataIdleLoop()
{
// callback while waiting OBD data
if (getState() == OBD_CONNECTED) {
if (state & STATE_ACC_READY) {
processAccelerometer();
}
#ifdef GPSUART
uint32_t t = millis();
while (GPSUART.available() && millis() - t < MAX_GPS_PROCESS_TIME) {
processGPS();
}
#endif
return;
}
// display while initializing
char buf[10];
unsigned int t = (millis() - startTime) / 1000;
sprintf(buf, "%02u:%02u", t / 60, t % 60);
lcd.setFont(FONT_SIZE_SMALL);
lcd.setCursor(0, 28);
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, 14);
lcd.print("Time:");
lcd.print(time);
lcd.setCursor(0, 16);
lcd.print("LAT: ");
lcd.print(lat);
lcd.setCursor(0, 18);
lcd.print("LON: ");
lcd.println(lon);
}
}
#endif
}
#ifdef GPSUART
void processGPS()
{
// process GPS data
char c = GPSUART.read();
if (!gps.encode(c))
return;
// parsed GPS data is ready
static uint32_t lastAltTime = 0;
uint32_t time;
uint32_t date;
dataTime = millis();
gps.get_datetime(&date, &time, 0);
logData(PID_GPS_TIME, time, date);
float speed = gps.speed() * 1852 / 100000;
logData(PID_GPS_SPEED, speed);
// 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
byte sat = gps.satellites();
if (sat >= 3 && sat < 100) {
// lastSpeed will be updated
//ShowSensorData(PID_SPEED, speed);
long lat, lon;
gps.get_position(&lat, &lon, 0);
logData(PID_GPS_COORDINATES, (float)lat / 100000, (float)lon / 100000);
if (dataTime - lastAltTime > 10000) {
logData(PID_GPS_ALTITUDE, (float)gps.altitude());
}
lcd.setFont(FONT_SIZE_MEDIUM);
char buf[16];
sprintf(buf, "%d.%ld", (int)(lat / 100000), abs(lat) % 100000);
lcd.setCursor(50, 18);
lcd.print(buf);
sprintf(buf, "%d.%ld", (int)(lon / 100000), abs(lon) % 100000);
lcd.setCursor(50, 21);
lcd.print(buf);
int32_t alt = gps.altitude();
if (alt < 1000000) {
sprintf(buf, "%dm ", (int)(alt / 100));
lcd.setCursor(50, 24);
lcd.print(buf);
}
lcd.setCursor(50, 27);
lcd.printInt(gps.satellites());
}
lastGPSDataTime = dataTime;
}
#endif
void processAccelerometer()
{
#if USE_MPU6050
dataTime = millis();
if (dataTime - lastACCDataTime < ACC_DATA_INTERVAL) {
return;
}
char buf[20];
accel_t_gyro_union data;
MPU6050_readout(&data);
lcd.setFont(FONT_SIZE_SMALL);
sprintf(buf, "%3d", data.value.x_accel / 160);
lcd.setCursor(197, 21);
lcd.print(buf);
sprintf(buf, "%3d", data.value.y_accel / 160);
lcd.setCursor(239, 21);
lcd.print(buf);
sprintf(buf, "%3d", data.value.z_accel / 160);
lcd.setCursor(281, 21);
lcd.print(buf);
sprintf(buf, "%3d", data.value.x_gyro / 256);
lcd.setCursor(197, 26);
lcd.print(buf);
sprintf(buf, "%3d", data.value.y_gyro / 256);
lcd.setCursor(239, 26);
lcd.print(buf);
sprintf(buf, "%3d", data.value.z_gyro / 256);
lcd.setCursor(281, 26);
lcd.print(buf);
// log x/y/z of accelerometer
logData(PID_ACC, data.value.x_accel, data.value.y_accel, data.value.z_accel);
// log x/y/z of gyro meter
logData(PID_GYRO, data.value.x_gyro, data.value.y_gyro, data.value.z_gyro);
lastACCDataTime = dataTime;
#endif
}
void logOBDData(byte pid)
{
char buffer[OBD_RECV_BUF_SIZE];
uint32_t start = millis();
// read OBD-II data
int value;
if (!read(pid, value)) {
return;
}
dataTime = millis();
// display data
showSensorData(pid, value);
// log data to SD card
logData(0x100 | pid, value);
#if ENABLE_DATA_LOG
// flush SD data every 1KB
if ((dataSize >> 10) != lastFileSize) {
flushFile();
// display logged data size
lcd.setFont(FONT_SIZE_MEDIUM);
lcd.setCursor(250, 8);
lcd.printInt((unsigned int)(dataSize >> 10));
lcd.setFont(FONT_SIZE_SMALL);
lcd.print(" KB");
lastFileSize = dataSize >> 10;
}
#endif
// 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 showECUCap()
{
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"};
lcd.setFont(FONT_SIZE_MEDIUM);
for (byte i = 0; i < sizeof(pidlist) / sizeof(pidlist[0]); i++) {
lcd.setCursor(160, i * 2 + 4);
lcd.print(namelist[i]);
lcd.write(' ');
bool valid = isValidPID(pidlist[i]);
lcd.setTextColor(valid ? RGB16_GREEN : RGB16_RED);
lcd.draw(valid ? tick : cross, 16, 16);
lcd.setTextColor(RGB16_WHITE);
}
}
void reconnect()
{
#if ENABLE_DATA_LOG
closeFile();
#endif
lcd.clear();
lcd.setFont(FONT_SIZE_MEDIUM);
lcd.print("Reconnecting...");
state &= ~(STATE_OBD_READY | STATE_ACC_READY | STATE_DATE_SAVED);
//digitalWrite(SD_CS_PIN, LOW);
for (uint16_t i = 0; ; i++) {
if (i == 5) {
lcd.backlight(false);
lcd.clear();
}
if (init()) {
int value;
if (read(PID_RPM, value) && value > 0)
break;
}
}
fileIndex++;
setup();
}
byte state;
// screen layout related stuff
void showStates()
{
lcd.setFont(FONT_SIZE_MEDIUM);
lcd.setCursor(0, 8);
lcd.print("OBD ");
lcd.setTextColor((state & STATE_OBD_READY) ? RGB16_GREEN : RGB16_RED);
lcd.draw((state & STATE_OBD_READY) ? tick : cross, 16, 16);
lcd.setTextColor(RGB16_WHITE);
lcd.setCursor(0, 10);
lcd.print("ACC ");
lcd.setTextColor((state & STATE_ACC_READY) ? RGB16_GREEN : RGB16_RED);
lcd.draw((state & STATE_ACC_READY) ? tick : cross, 16, 16);
lcd.setTextColor(RGB16_WHITE);
lcd.setCursor(0, 12);
lcd.print("GPS ");
if (state & STATE_GPS_READY) {
lcd.setTextColor(RGB16_GREEN);
lcd.draw(tick, 16, 16);
} else if (state & STATE_GPS_CONNECTED)
lcd.print("--");
else {
lcd.setTextColor(RGB16_RED);
lcd.draw(cross, 16, 16);
}
lcd.setTextColor(RGB16_WHITE);
}
void showSensorData(byte pid, int value)
{
char buf[8];
switch (pid) {
case PID_RPM:
lcd.setFont(FONT_SIZE_XLARGE);
lcd.setCursor(34, 7);
lcd.printInt((unsigned int)value % 10000, 4);
break;
case PID_SPEED:
if (lastSpeed != value) {
lcd.setFont(FONT_SIZE_XLARGE);
lcd.setCursor(50, 2);
lcd.printInt((unsigned int)value % 1000, 3);
lastSpeed = value;
}
break;
case PID_THROTTLE:
lcd.setFont(FONT_SIZE_SMALL);
lcd.setCursor(39, 12);
lcd.printInt(value % 100, 3);
break;
case PID_INTAKE_TEMP:
lcd.setFont(FONT_SIZE_SMALL);
lcd.setCursor(102, 12);
lcd.printInt(value % 1000, 3);
break;
case PID_DISTANCE:
if ((unsigned int)value >= startDistance) {
lcd.setFont(FONT_SIZE_MEDIUM);
lcd.setCursor(250, 5);
lcd.printInt(((unsigned int)value - startDistance) % 1000);
lcd.print("km");
}
break;
}
}
void initScreen()
{
lcd.clear();
#ifndef MEMORY_SAVING
lcd.draw2x(frame0[0], 78, 58);
lcd.setXY(164, 0);
lcd.draw2x(frame0[0], 78, 58);
lcd.setXY(0, 124);
lcd.draw2x(frame0[0], 78, 58);
lcd.setXY(164, 124);
lcd.draw2x(frame0[0], 78, 58);
#endif
//lcd.setColor(RGB16(0x7f, 0x7f, 0x7f));
lcd.setFont(FONT_SIZE_SMALL);
lcd.setCursor(110, 4);
lcd.print("km/h");
lcd.setCursor(110, 8);
lcd.print("rpm");
lcd.setCursor(15, 12);
lcd.print("THR: %");
lcd.setCursor(78, 12);
lcd.print("AIR: C");
//lcd.setFont(FONT_SIZE_MEDIUM);
lcd.setCursor(185, 2);
lcd.print("ELAPSED:");
lcd.setCursor(185, 5);
lcd.print("DISTANCE:");
lcd.setCursor(185, 8);
lcd.print("LOG SIZE:");
lcd.setCursor(185, 11);
lcd.print("OBD TIME:");
lcd.setCursor(20, 18);
lcd.print("LAT:");
lcd.setCursor(20, 21);
lcd.print("LON:");
lcd.setCursor(20, 24);
lcd.print("ALT:");
lcd.setCursor(20, 27);
lcd.print("SAT:");
lcd.setFont(FONT_SIZE_MEDIUM);
lcd.setCursor(185, 18);
lcd.print("Accelerometer");
lcd.setCursor(200, 23);
lcd.print("Gyroscope");
lcd.setFont(FONT_SIZE_SMALL);
lcd.setCursor(185, 21);
lcd.print("X: Y: Z:");
lcd.setCursor(185, 26);
lcd.print("X: Y: Z:");
//lcd.setColor(0xFFFF);
/*
lcd.setCursor(32, 4);
lcd.print("%");
lcd.setCursor(68, 5);
lcd.print("Intake Air");
lcd.setCursor(112, 4);
lcd.print("C");
*/
}
};
static COBDLogger logger;
#if ENABLE_DATA_OUT && USE_OBD_BT
void btInit(int baudrate)
{
logger.btInit(baudrate);
}
void btSend(byte* data, byte length)
{
logger.btSend(data, length);
}
#endif
void setup()
{
lcd.begin();
lcd.setFont(FONT_SIZE_MEDIUM);
lcd.backlight(true);
lcd.setTextColor(0xFFE0);
lcd.print("MEGA LOGGER - OBD-II/GPS/G-FORCE");
lcd.setTextColor(RGB16_WHITE);
#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_10HZ);
#endif
logger.begin();
logger.initSender();
logger.checkSD();
logger.setup();
}
void loop()
{
logger.loop();
}