sabas1080/weather_station.ino

## weather_station.ino
include "SparkFunMPL3115A2.h" //Pressure sensor - Search "SparkFun MPL3115" and install from Library Manager
#include "SparkFunHTU21D.h" //Humidity sensor - Search "SparkFun HTU21D" and install from Library Manager
#include <lmic.h>
#include <hal/hal.h>
#include <SPI.h>
#include<CayenneLPP.h>

CayenneLPP lpp(51);

MPL3115A2 myPressure; //Create an instance of the pressure sensor
HTU21D myHumidity; //Create an instance of the humidity sensor

//Hardware pin definitions
//-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=
// digital I/O pins
const byte WSPEED = 18; //3; //Pines empalmados
const byte RAIN = 19;   //2; //Pines empalmados
const byte STAT1 = 7;
const byte STAT2 = 8;

// analog I/O pins
const byte REFERENCE_3V3 = A3;
const byte LIGHT = A1;
const byte BATT = A2;
const byte WDIR = A0;
//-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=

//Global Variables
//-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=
long lastSecond; //The millis counter to see when a second rolls by
byte seconds; //When it hits 60, increase the current minute
byte seconds_2m; //Keeps track of the "wind speed/dir avg" over last 2 minutes array of data
byte minutes; //Keeps track of where we are in various arrays of data
byte minutes_10m; //Keeps track of where we are in wind gust/dir over last 10 minutes array of data

long lastWindCheck = 0;
volatile long lastWindIRQ = 0;
volatile byte windClicks = 0;

//We need to keep track of the following variables:
//Wind speed/dir each update (no storage)
//Wind gust/dir over the day (no storage)
//Wind speed/dir, avg over 2 minutes (store 1 per second)
//Wind gust/dir over last 10 minutes (store 1 per minute)
//Rain over the past hour (store 1 per minute)
//Total rain over date (store one per day)

byte windspdavg[120]; //120 bytes to keep track of 2 minute average

#define WIND_DIR_AVG_SIZE 120
int winddiravg[WIND_DIR_AVG_SIZE]; //120 ints to keep track of 2 minute average
float windgust_10m[10]; //10 floats to keep track of 10 minute max
int windgustdirection_10m[10]; //10 ints to keep track of 10 minute max
volatile float rainHour[60]; //60 floating numbers to keep track of 60 minutes of rain

//These are all the weather values that wunderground expects:
int winddir = 0; // [0-360 instantaneous wind direction]
float windspeedmph = 0; // [mph instantaneous wind speed]
float windgustmph = 0; // [mph current wind gust, using software specific time period]
int windgustdir = 0; // [0-360 using software specific time period]
float windspdmph_avg2m = 0; // [mph 2 minute average wind speed mph]
int winddir_avg2m = 0; // [0-360 2 minute average wind direction]
float windgustmph_10m = 0; // [mph past 10 minutes wind gust mph ]
int windgustdir_10m = 0; // [0-360 past 10 minutes wind gust direction]
float humidity = 0; // [%]
float tempf = 0; // [temperature F]
float rainin = 0; // [rain inches over the past hour)] -- the accumulated rainfall in the past 60 min
volatile float dailyrainin = 0; // [rain inches so far today in local time]
//float baromin = 30.03;// [barom in] - It's hard to calculate baromin locally, do this in the agent
float pressure = 0;
//float dewptf; // [dewpoint F] - It's hard to calculate dewpoint locally, do this in the agent

float batt_lvl = 11.8; //[analog value from 0 to 1023]
float light_lvl = 455; //[analog value from 0 to 1023]

// This EUI must be in little-endian format, so least-significant-byte
// first. When copying an EUI from ttnctl output, this means to reverse
// the bytes. For TTN issued EUIs the last bytes should be 0xD5, 0xB3,
// 0x70.
static const u1_t PROGMEM APPEUI[8]= {0x04,0x23,0x89,0x23,0x37,0x14,0x82,0x23};
void os_getArtEui (u1_t* buf) { memcpy_P(buf, APPEUI, 8);}

// This should also be in little endian format, see above.
static const u1_t PROGMEM DEVEUI[8]= {0x82,0x47,0x47,0x47,0x38,0x92,0x91,0x12};
void os_getDevEui (u1_t* buf) { memcpy_P(buf, DEVEUI, 8);}

// This key should be in big endian format (or, since it is not really a
// number but a block of memory, endianness does not really apply). In
// practice, a key taken from ttnctl can be copied as-is.
// The key shown here is the semtech default key.
static const u1_t PROGMEM APPKEY[16] = {0xAA,0xAF,0xFF,0xBB,0x12,0x82,0x31,0x98,0x94,0x24,0x92,0x39,0x83,0x42,0x14,0x82};
void os_getDevKey (u1_t* buf) {  memcpy_P(buf, APPKEY, 16);}

//static uint8_t mydata[] = "Hello, world!";
static osjob_t sendjob;

// Schedule TX every this many seconds (might become longer due to duty
// cycle limitations).
const unsigned TX_INTERVAL = 10;

// Pin mapping
const lmic_pinmap lmic_pins = {
    .nss = 53,
    .rxtx = LMIC_UNUSED_PIN,
    .rst = 9,
    .dio = {2, 3, 4}, //Pines empalmados
};

void onEvent (ev_t ev) {
    Serial.print(os_getTime());
    Serial.print(": ");
    switch(ev) {
        case EV_SCAN_TIMEOUT:
            Serial.println(F("EV_SCAN_TIMEOUT"));
            break;
        case EV_BEACON_FOUND:
            Serial.println(F("EV_BEACON_FOUND"));
            break;
        case EV_BEACON_MISSED:
            Serial.println(F("EV_BEACON_MISSED"));
            break;
        case EV_BEACON_TRACKED:
            Serial.println(F("EV_BEACON_TRACKED"));
            break;
        case EV_JOINING:
            Serial.println(F("EV_JOINING"));
            break;
        case EV_JOINED:
            Serial.println(F("EV_JOINED"));

            // Disable link check validation (automatically enabled
            // during join, but not supported by TTN at this time).
            LMIC_setLinkCheckMode(0);
            // turn on interrupts
            interrupts();
            break;
        case EV_RFU1:
            Serial.println(F("EV_RFU1"));
            break;
        case EV_JOIN_FAILED:
            Serial.println(F("EV_JOIN_FAILED"));
            break;
        case EV_REJOIN_FAILED:
            Serial.println(F("EV_REJOIN_FAILED"));
            break;
            break;
        case EV_TXCOMPLETE:
            Serial.println(F("EV_TXCOMPLETE (includes waiting for RX windows)"));
            if (LMIC.txrxFlags & TXRX_ACK)
              Serial.println(F("Received ack"));
            if (LMIC.dataLen) {
              Serial.println(F("Received "));
              Serial.println(LMIC.dataLen);
              Serial.println(F(" bytes of payload"));
            }
            // Schedule next transmission
            os_setTimedCallback(&sendjob, os_getTime()+sec2osticks(TX_INTERVAL), do_send);
            break;
        case EV_LOST_TSYNC:
            Serial.println(F("EV_LOST_TSYNC"));
            break;
        case EV_RESET:
            Serial.println(F("EV_RESET"));
            break;
        case EV_RXCOMPLETE:
            // data received in ping slot
            Serial.println(F("EV_RXCOMPLETE"));
            break;
        case EV_LINK_DEAD:
            Serial.println(F("EV_LINK_DEAD"));
            break;
        case EV_LINK_ALIVE:
            Serial.println(F("EV_LINK_ALIVE"));
            break;
         default:
            Serial.println(F("Unknown event"));
            break;
    }
}

void do_send(osjob_t* j){
    // Check if there is not a current TX/RX job running
    if (LMIC.opmode & OP_TXRXPEND) {
        Serial.println(F("OP_TXRXPEND, not sending"));
    } else {
        // Prepare upstream data transmission at the next possible time.
        printWeather();
        LMIC_setTxData2(1, lpp.getBuffer(), lpp.getSize(), 0);
        Serial.println(F("Packet queued"));

    }
    // Next TX is scheduled after TX_COMPLETE event.
}

// volatiles are subject to modification by IRQs
volatile unsigned long raintime, rainlast, raininterval, rain;

//-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=

//Interrupt routines (these are called by the hardware interrupts, not by the main code)
//-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=
void rainIRQ()
// Count rain gauge bucket tips as they occur
// Activated by the magnet and reed switch in the rain gauge, attached to input D2
{
  raintime = millis(); // grab current time
  raininterval = raintime - rainlast; // calculate interval between this and last event

  if (raininterval > 10) // ignore switch-bounce glitches less than 10mS after initial edge
  {
    dailyrainin += 0.011; //Each dump is 0.011" of water
    rainHour[minutes] += 0.011; //Increase this minute's amount of rain

    rainlast = raintime; // set up for next event
  }
}

void wspeedIRQ()
// Activated by the magnet in the anemometer (2 ticks per rotation), attached to input D3
{
  if (millis() - lastWindIRQ > 10) // Ignore switch-bounce glitches less than 10ms (142MPH max reading) after the reed switch closes
  {
    lastWindIRQ = millis(); //Grab the current time
    windClicks++; //There is 1.492MPH for each click per second.
  }
}


void setup()
{
  Serial.begin(115200);

  pinMode(STAT1, OUTPUT); //Status LED Blue
  pinMode(STAT2, OUTPUT); //Status LED Green

  pinMode(WSPEED, INPUT_PULLUP); // input from wind meters windspeed sensor
  pinMode(RAIN, INPUT_PULLUP); // input from wind meters rain gauge sensor

  pinMode(REFERENCE_3V3, INPUT);
  pinMode(LIGHT, INPUT);

  // LMIC init
  os_init();
  // Reset the MAC state. Session and pending data transfers will be discarded.
  LMIC_reset();

  //Configuration for SubBand 7
      for (int channel=0; channel<72; ++channel) {
      LMIC_disableChannel(channel);
    }

      LMIC_enableChannel(48);
      LMIC_enableChannel(49);
      LMIC_enableChannel(50);
      LMIC_enableChannel(51);
      LMIC_enableChannel(52);
      LMIC_enableChannel(53);
      LMIC_enableChannel(54);
      LMIC_enableChannel(55);
      LMIC_enableChannel(70);

      // TTN uses SF9 for its RX2 window. This is configured in the
      // join accept message, but the LMIC library does not currently
      // process this part of the join accept yet (see Arduino-LMIC issue #20).
      LMIC.dn2Dr = DR_SF9;

      // Use a fixed data rate of SF9 (not sure if tx power is
      // actually used). SF9 is the lowest datarate that (withing the
      // TTN fair-usage-policy of 30 seconds of airtime per day)
      // allows us to send at least 4 packets every hour.
      LMIC_setDrTxpow(DR_SF7, 14);

      // Let LMIC compensate for +/- 1% clock error
      LMIC_setClockError(MAX_CLOCK_ERROR * 1 / 100);


  //Configure the pressure sensor
  myPressure.begin(); // Get sensor online
  myPressure.setModeBarometer(); // Measure pressure in Pascals from 20 to 110 kPa
  myPressure.setOversampleRate(7); // Set Oversample to the recommended 128
  myPressure.enableEventFlags(); // Enable all three pressure and temp event flags

  //Configure the humidity sensor
  myHumidity.begin();

  seconds = 0;
  lastSecond = millis();

  // attach external interrupt pins to IRQ functions
  attachInterrupt(0, rainIRQ, FALLING);
  attachInterrupt(1, wspeedIRQ, FALLING);

  // turn on interrupts
  //interrupts();

  Serial.println(F("Weather Shield online!"));

  // Start job (sending automatically starts OTAA too)
  do_send(&sendjob);

}

void loop()
{

  //Keep track of which minute it is
  if(millis() - lastSecond >= 1000)
  {
    digitalWrite(STAT1, HIGH); //Blink stat LED

    lastSecond += 1000;

    //Take a speed and direction reading every second for 2 minute average
    if(++seconds_2m > 119) seconds_2m = 0;

    //Calc the wind speed and direction every second for 120 second to get 2 minute average
    float currentSpeed = get_wind_speed();
    windspeedmph = currentSpeed; //update global variable for windspeed when using the printWeather() function
    //float currentSpeed = random(5); //For testing
    int currentDirection = get_wind_direction();
    windspdavg[seconds_2m] = (int)currentSpeed;
    winddiravg[seconds_2m] = currentDirection;
    //if(seconds_2m % 10 == 0) displayArrays(); //For testing

    //Check to see if this is a gust for the minute
    if(currentSpeed > windgust_10m[minutes_10m])
    {
      windgust_10m[minutes_10m] = currentSpeed;
      windgustdirection_10m[minutes_10m] = currentDirection;
    }

    //Check to see if this is a gust for the day
    if(currentSpeed > windgustmph)
    {
      windgustmph = currentSpeed;
      windgustdir = currentDirection;
    }

    if(++seconds > 59)
    {
      seconds = 0;

      if(++minutes > 59) minutes = 0;
      if(++minutes_10m > 9) minutes_10m = 0;

      rainHour[minutes] = 0; //Zero out this minute's rainfall amount
      windgust_10m[minutes_10m] = 0; //Zero out this minute's gust
    }

    //Report all readings every second
    //printWeather();

    digitalWrite(STAT1, LOW); //Turn off stat LED
  }

  //delay(100);

  os_runloop_once();
}

//Calculates each of the variables that wunderground is expecting
void calcWeather()
{
  //Calc winddir
  winddir = get_wind_direction();

  //Calc windspeed
  //windspeedmph = get_wind_speed(); //This is calculated in the main loop on line 179

  //Calc windgustmph
  //Calc windgustdir
  //These are calculated in the main loop

  //Calc windspdmph_avg2m
  float temp = 0;
  for(int i = 0 ; i < 120 ; i++)
    temp += windspdavg[i];
  temp /= 120.0;
  windspdmph_avg2m = temp;

  //Calc winddir_avg2m, Wind Direction
  //You can't just take the average. Google "mean of circular quantities" for more info
  //We will use the Mitsuta method because it doesn't require trig functions
  //And because it sounds cool.
  //Based on: http://abelian.org/vlf/bearings.html
  //Based on: http://stackoverflow.com/questions/1813483/averaging-angles-again
  long sum = winddiravg[0];
  int D = winddiravg[0];
  for(int i = 1 ; i < WIND_DIR_AVG_SIZE ; i++)
  {
    int delta = winddiravg[i] - D;

    if(delta < -180)
      D += delta + 360;
    else if(delta > 180)
      D += delta - 360;
    else
      D += delta;

    sum += D;
  }
  winddir_avg2m = sum / WIND_DIR_AVG_SIZE;
  if(winddir_avg2m >= 360) winddir_avg2m -= 360;
  if(winddir_avg2m < 0) winddir_avg2m += 360;

  //Calc windgustmph_10m
  //Calc windgustdir_10m
  //Find the largest windgust in the last 10 minutes
  windgustmph_10m = 0;
  windgustdir_10m = 0;
  //Step through the 10 minutes
  for(int i = 0; i < 10 ; i++)
  {
    if(windgust_10m[i] > windgustmph_10m)
    {
      windgustmph_10m = windgust_10m[i];
      windgustdir_10m = windgustdirection_10m[i];
    }
  }

  //Calc humidity
  humidity = myHumidity.readHumidity();
  //float temp_h = myHumidity.readTemperature();
  //Serial.print(" TempH:");
  //Serial.print(temp_h, 2);

  //Calc tempf from pressure sensor
  tempf = myPressure.readTempF();
  //Serial.print(" TempP:");
  //Serial.print(tempf, 2);

  //Total rainfall for the day is calculated within the interrupt
  //Calculate amount of rainfall for the last 60 minutes
  rainin = 0;
  for(int i = 0 ; i < 60 ; i++)
    rainin += rainHour[i];

  //Calc pressure
  pressure = myPressure.readPressure();

  //Calc dewptf

  //Calc light level
  light_lvl = get_light_level();

  //Calc battery level
  batt_lvl = get_battery_level();
}

//Returns the voltage of the light sensor based on the 3.3V rail
//This allows us to ignore what VCC might be (an Arduino plugged into USB has VCC of 4.5 to 5.2V)
float get_light_level()
{
  float operatingVoltage = analogRead(REFERENCE_3V3);

  float lightSensor = analogRead(LIGHT);

  operatingVoltage = 3.3 / operatingVoltage; //The reference voltage is 3.3V

  lightSensor = operatingVoltage * lightSensor;

  return(lightSensor);
}

//Returns the voltage of the raw pin based on the 3.3V rail
//This allows us to ignore what VCC might be (an Arduino plugged into USB has VCC of 4.5 to 5.2V)
//Battery level is connected to the RAW pin on Arduino and is fed through two 5% resistors:
//3.9K on the high side (R1), and 1K on the low side (R2)
float get_battery_level()
{
  float operatingVoltage = analogRead(REFERENCE_3V3);

  float rawVoltage = analogRead(BATT);

  operatingVoltage = 3.30 / operatingVoltage; //The reference voltage is 3.3V

  rawVoltage = operatingVoltage * rawVoltage; //Convert the 0 to 1023 int to actual voltage on BATT pin

  rawVoltage *= 4.90; //(3.9k+1k)/1k - multiple BATT voltage by the voltage divider to get actual system voltage

  return(rawVoltage);
}

//Returns the instataneous wind speed
float get_wind_speed()
{
  float deltaTime = millis() - lastWindCheck; //750ms

  deltaTime /= 1000.0; //Covert to seconds

  float windSpeed = (float)windClicks / deltaTime; //3 / 0.750s = 4

  windClicks = 0; //Reset and start watching for new wind
  lastWindCheck = millis();

  windSpeed *= 1.492; //4 * 1.492 = 5.968MPH

  /* Serial.println();
   Serial.print("Windspeed:");
   Serial.println(windSpeed);*/

  return(windSpeed);
}

//Read the wind direction sensor, return heading in degrees
int get_wind_direction()
{
  unsigned int adc;

  adc = analogRead(WDIR); // get the current reading from the sensor

  // The following table is ADC readings for the wind direction sensor output, sorted from low to high.
  // Each threshold is the midpoint between adjacent headings. The output is degrees for that ADC reading.
  // Note that these are not in compass degree order! See Weather Meters datasheet for more information.

  if (adc < 380) return (113);
  if (adc < 393) return (68);
  if (adc < 414) return (90);
  if (adc < 456) return (158);
  if (adc < 508) return (135);
  if (adc < 551) return (203);
  if (adc < 615) return (180);
  if (adc < 680) return (23);
  if (adc < 746) return (45);
  if (adc < 801) return (248);
  if (adc < 833) return (225);
  if (adc < 878) return (338);
  if (adc < 913) return (0);
  if (adc < 940) return (293);
  if (adc < 967) return (315);
  if (adc < 990) return (270);
  return (-1); // error, disconnected?
}


//Prints the various variables directly to the port
//I don't like the way this function is written but Arduino doesn't support floats under sprintf
void printWeather()
{
  calcWeather(); //Go calc all the various sensors
  lpp.reset();

  Serial.println();
  Serial.print(F("$,winddir="));
  Serial.print(winddir);
  lpp.addAnalogInput(1, winddir);

  Serial.print(F(",windspeedmph="));
  Serial.print(windspeedmph, 1);
  lpp.addAnalogInput(2, windspeedmph);

  Serial.print(F(",humidity="));
  Serial.print(humidity, 1);
  lpp.addRelativeHumidity(3, humidity);

  Serial.print(F(",tempf="));
  Serial.print(tempf, 1);
  lpp.addTemperature(4, tempf);

  Serial.print(F(",rainin="));
  Serial.print(rainin, 2);
  lpp.addAnalogInput(5, rainin);

  Serial.print(F(",dailyrainin="));
  Serial.print(dailyrainin, 2);
  lpp.addAnalogInput(6, dailyrainin);

  Serial.print(F(",pressure="));
  Serial.print(pressure, 2);
  lpp.addBarometricPressure(7,pressure);

  Serial.print(F(",batt_lvl="));
  Serial.print(batt_lvl, 2);
  lpp.addAnalogInput(8, batt_lvl);

  Serial.print(F(",light_lvl="));
  Serial.println(light_lvl, 2);
  lpp.addLuminosity(9,light_lvl);
}
	include "SparkFunMPL3115A2.h" //Pressure sensor - Search "SparkFun MPL3115" and install from Library Manager
	#include "SparkFunHTU21D.h" //Humidity sensor - Search "SparkFun HTU21D" and install from Library Manager
	#include <lmic.h>
	#include <hal/hal.h>
	#include <SPI.h>
	#include<CayenneLPP.h>

	CayenneLPP lpp(51);

	MPL3115A2 myPressure; //Create an instance of the pressure sensor
	HTU21D myHumidity; //Create an instance of the humidity sensor

	//Hardware pin definitions
	//-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=
	// digital I/O pins
	const byte WSPEED = 18; //3; //Pines empalmados
	const byte RAIN = 19; //2; //Pines empalmados
	const byte STAT1 = 7;
	const byte STAT2 = 8;

	// analog I/O pins
	const byte REFERENCE_3V3 = A3;
	const byte LIGHT = A1;
	const byte BATT = A2;
	const byte WDIR = A0;
	//-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=

	//Global Variables
	//-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=
	long lastSecond; //The millis counter to see when a second rolls by
	byte seconds; //When it hits 60, increase the current minute
	byte seconds_2m; //Keeps track of the "wind speed/dir avg" over last 2 minutes array of data
	byte minutes; //Keeps track of where we are in various arrays of data
	byte minutes_10m; //Keeps track of where we are in wind gust/dir over last 10 minutes array of data

	long lastWindCheck = 0;
	volatile long lastWindIRQ = 0;
	volatile byte windClicks = 0;

	//We need to keep track of the following variables:
	//Wind speed/dir each update (no storage)
	//Wind gust/dir over the day (no storage)
	//Wind speed/dir, avg over 2 minutes (store 1 per second)
	//Wind gust/dir over last 10 minutes (store 1 per minute)
	//Rain over the past hour (store 1 per minute)
	//Total rain over date (store one per day)

	byte windspdavg[120]; //120 bytes to keep track of 2 minute average

	#define WIND_DIR_AVG_SIZE 120
	int winddiravg[WIND_DIR_AVG_SIZE]; //120 ints to keep track of 2 minute average
	float windgust_10m[10]; //10 floats to keep track of 10 minute max
	int windgustdirection_10m[10]; //10 ints to keep track of 10 minute max
	volatile float rainHour[60]; //60 floating numbers to keep track of 60 minutes of rain

	//These are all the weather values that wunderground expects:
	int winddir = 0; // [0-360 instantaneous wind direction]
	float windspeedmph = 0; // [mph instantaneous wind speed]
	float windgustmph = 0; // [mph current wind gust, using software specific time period]
	int windgustdir = 0; // [0-360 using software specific time period]
	float windspdmph_avg2m = 0; // [mph 2 minute average wind speed mph]
	int winddir_avg2m = 0; // [0-360 2 minute average wind direction]
	float windgustmph_10m = 0; // [mph past 10 minutes wind gust mph ]
	int windgustdir_10m = 0; // [0-360 past 10 minutes wind gust direction]
	float humidity = 0; // [%]
	float tempf = 0; // [temperature F]
	float rainin = 0; // [rain inches over the past hour)] -- the accumulated rainfall in the past 60 min
	volatile float dailyrainin = 0; // [rain inches so far today in local time]
	//float baromin = 30.03;// [barom in] - It's hard to calculate baromin locally, do this in the agent
	float pressure = 0;
	//float dewptf; // [dewpoint F] - It's hard to calculate dewpoint locally, do this in the agent

	float batt_lvl = 11.8; //[analog value from 0 to 1023]
	float light_lvl = 455; //[analog value from 0 to 1023]

	// This EUI must be in little-endian format, so least-significant-byte
	// first. When copying an EUI from ttnctl output, this means to reverse
	// the bytes. For TTN issued EUIs the last bytes should be 0xD5, 0xB3,
	// 0x70.
	static const u1_t PROGMEM APPEUI[8]= {0x04,0x23,0x89,0x23,0x37,0x14,0x82,0x23};
	void os_getArtEui (u1_t* buf) { memcpy_P(buf, APPEUI, 8);}

	// This should also be in little endian format, see above.
	static const u1_t PROGMEM DEVEUI[8]= {0x82,0x47,0x47,0x47,0x38,0x92,0x91,0x12};
	void os_getDevEui (u1_t* buf) { memcpy_P(buf, DEVEUI, 8);}

	// This key should be in big endian format (or, since it is not really a
	// number but a block of memory, endianness does not really apply). In
	// practice, a key taken from ttnctl can be copied as-is.
	// The key shown here is the semtech default key.
	static const u1_t PROGMEM APPKEY[16] = {0xAA,0xAF,0xFF,0xBB,0x12,0x82,0x31,0x98,0x94,0x24,0x92,0x39,0x83,0x42,0x14,0x82};
	void os_getDevKey (u1_t* buf) { memcpy_P(buf, APPKEY, 16);}

	//static uint8_t mydata[] = "Hello, world!";
	static osjob_t sendjob;

	// Schedule TX every this many seconds (might become longer due to duty
	// cycle limitations).
	const unsigned TX_INTERVAL = 10;

	// Pin mapping
	const lmic_pinmap lmic_pins = {
	.nss = 53,
	.rxtx = LMIC_UNUSED_PIN,
	.rst = 9,
	.dio = {2, 3, 4}, //Pines empalmados
	};

	void onEvent (ev_t ev) {
	Serial.print(os_getTime());
	Serial.print(": ");
	switch(ev) {
	case EV_SCAN_TIMEOUT:
	Serial.println(F("EV_SCAN_TIMEOUT"));
	break;
	case EV_BEACON_FOUND:
	Serial.println(F("EV_BEACON_FOUND"));
	break;
	case EV_BEACON_MISSED:
	Serial.println(F("EV_BEACON_MISSED"));
	break;
	case EV_BEACON_TRACKED:
	Serial.println(F("EV_BEACON_TRACKED"));
	break;
	case EV_JOINING:
	Serial.println(F("EV_JOINING"));
	break;
	case EV_JOINED:
	Serial.println(F("EV_JOINED"));

	// Disable link check validation (automatically enabled
	// during join, but not supported by TTN at this time).
	LMIC_setLinkCheckMode(0);
	// turn on interrupts
	interrupts();
	break;
	case EV_RFU1:
	Serial.println(F("EV_RFU1"));
	break;
	case EV_JOIN_FAILED:
	Serial.println(F("EV_JOIN_FAILED"));
	break;
	case EV_REJOIN_FAILED:
	Serial.println(F("EV_REJOIN_FAILED"));
	break;
	break;
	case EV_TXCOMPLETE:
	Serial.println(F("EV_TXCOMPLETE (includes waiting for RX windows)"));
	if (LMIC.txrxFlags & TXRX_ACK)
	Serial.println(F("Received ack"));
	if (LMIC.dataLen) {
	Serial.println(F("Received "));
	Serial.println(LMIC.dataLen);
	Serial.println(F(" bytes of payload"));
	}
	// Schedule next transmission
	os_setTimedCallback(&sendjob, os_getTime()+sec2osticks(TX_INTERVAL), do_send);
	break;
	case EV_LOST_TSYNC:
	Serial.println(F("EV_LOST_TSYNC"));
	break;
	case EV_RESET:
	Serial.println(F("EV_RESET"));
	break;
	case EV_RXCOMPLETE:
	// data received in ping slot
	Serial.println(F("EV_RXCOMPLETE"));
	break;
	case EV_LINK_DEAD:
	Serial.println(F("EV_LINK_DEAD"));
	break;
	case EV_LINK_ALIVE:
	Serial.println(F("EV_LINK_ALIVE"));
	break;
	default:
	Serial.println(F("Unknown event"));
	break;
	}
	}

	void do_send(osjob_t* j){
	// Check if there is not a current TX/RX job running
	if (LMIC.opmode & OP_TXRXPEND) {
	Serial.println(F("OP_TXRXPEND, not sending"));
	} else {
	// Prepare upstream data transmission at the next possible time.
	printWeather();
	LMIC_setTxData2(1, lpp.getBuffer(), lpp.getSize(), 0);
	Serial.println(F("Packet queued"));

	}
	// Next TX is scheduled after TX_COMPLETE event.
	}

	// volatiles are subject to modification by IRQs
	volatile unsigned long raintime, rainlast, raininterval, rain;

	//-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=

	//Interrupt routines (these are called by the hardware interrupts, not by the main code)
	//-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=-=
	void rainIRQ()
	// Count rain gauge bucket tips as they occur
	// Activated by the magnet and reed switch in the rain gauge, attached to input D2
	{
	raintime = millis(); // grab current time
	raininterval = raintime - rainlast; // calculate interval between this and last event

	if (raininterval > 10) // ignore switch-bounce glitches less than 10mS after initial edge
	{
	dailyrainin += 0.011; //Each dump is 0.011" of water
	rainHour[minutes] += 0.011; //Increase this minute's amount of rain

	rainlast = raintime; // set up for next event
	}
	}

	void wspeedIRQ()
	// Activated by the magnet in the anemometer (2 ticks per rotation), attached to input D3
	{
	if (millis() - lastWindIRQ > 10) // Ignore switch-bounce glitches less than 10ms (142MPH max reading) after the reed switch closes
	{
	lastWindIRQ = millis(); //Grab the current time
	windClicks++; //There is 1.492MPH for each click per second.
	}
	}


	void setup()
	{
	Serial.begin(115200);

	pinMode(STAT1, OUTPUT); //Status LED Blue
	pinMode(STAT2, OUTPUT); //Status LED Green

	pinMode(WSPEED, INPUT_PULLUP); // input from wind meters windspeed sensor
	pinMode(RAIN, INPUT_PULLUP); // input from wind meters rain gauge sensor

	pinMode(REFERENCE_3V3, INPUT);
	pinMode(LIGHT, INPUT);

	// LMIC init
	os_init();
	// Reset the MAC state. Session and pending data transfers will be discarded.
	LMIC_reset();

	//Configuration for SubBand 7
	for (int channel=0; channel<72; ++channel) {
	LMIC_disableChannel(channel);
	}

	LMIC_enableChannel(48);
	LMIC_enableChannel(49);
	LMIC_enableChannel(50);
	LMIC_enableChannel(51);
	LMIC_enableChannel(52);
	LMIC_enableChannel(53);
	LMIC_enableChannel(54);
	LMIC_enableChannel(55);
	LMIC_enableChannel(70);

	// TTN uses SF9 for its RX2 window. This is configured in the
	// join accept message, but the LMIC library does not currently
	// process this part of the join accept yet (see Arduino-LMIC issue #20).
	LMIC.dn2Dr = DR_SF9;

	// Use a fixed data rate of SF9 (not sure if tx power is
	// actually used). SF9 is the lowest datarate that (withing the
	// TTN fair-usage-policy of 30 seconds of airtime per day)
	// allows us to send at least 4 packets every hour.
	LMIC_setDrTxpow(DR_SF7, 14);

	// Let LMIC compensate for +/- 1% clock error
	LMIC_setClockError(MAX_CLOCK_ERROR * 1 / 100);


	//Configure the pressure sensor
	myPressure.begin(); // Get sensor online
	myPressure.setModeBarometer(); // Measure pressure in Pascals from 20 to 110 kPa
	myPressure.setOversampleRate(7); // Set Oversample to the recommended 128
	myPressure.enableEventFlags(); // Enable all three pressure and temp event flags

	//Configure the humidity sensor
	myHumidity.begin();

	seconds = 0;
	lastSecond = millis();

	// attach external interrupt pins to IRQ functions
	attachInterrupt(0, rainIRQ, FALLING);
	attachInterrupt(1, wspeedIRQ, FALLING);

	// turn on interrupts
	//interrupts();

	Serial.println(F("Weather Shield online!"));

	// Start job (sending automatically starts OTAA too)
	do_send(&sendjob);

	}

	void loop()
	{

	//Keep track of which minute it is
	if(millis() - lastSecond >= 1000)
	{
	digitalWrite(STAT1, HIGH); //Blink stat LED

	lastSecond += 1000;

	//Take a speed and direction reading every second for 2 minute average
	if(++seconds_2m > 119) seconds_2m = 0;

	//Calc the wind speed and direction every second for 120 second to get 2 minute average
	float currentSpeed = get_wind_speed();
	windspeedmph = currentSpeed; //update global variable for windspeed when using the printWeather() function
	//float currentSpeed = random(5); //For testing
	int currentDirection = get_wind_direction();
	windspdavg[seconds_2m] = (int)currentSpeed;
	winddiravg[seconds_2m] = currentDirection;
	//if(seconds_2m % 10 == 0) displayArrays(); //For testing

	//Check to see if this is a gust for the minute
	if(currentSpeed > windgust_10m[minutes_10m])
	{
	windgust_10m[minutes_10m] = currentSpeed;
	windgustdirection_10m[minutes_10m] = currentDirection;
	}

	//Check to see if this is a gust for the day
	if(currentSpeed > windgustmph)
	{
	windgustmph = currentSpeed;
	windgustdir = currentDirection;
	}

	if(++seconds > 59)
	{
	seconds = 0;

	if(++minutes > 59) minutes = 0;
	if(++minutes_10m > 9) minutes_10m = 0;

	rainHour[minutes] = 0; //Zero out this minute's rainfall amount
	windgust_10m[minutes_10m] = 0; //Zero out this minute's gust
	}

	//Report all readings every second
	//printWeather();

	digitalWrite(STAT1, LOW); //Turn off stat LED
	}

	//delay(100);

	os_runloop_once();
	}

	//Calculates each of the variables that wunderground is expecting
	void calcWeather()
	{
	//Calc winddir
	winddir = get_wind_direction();

	//Calc windspeed
	//windspeedmph = get_wind_speed(); //This is calculated in the main loop on line 179

	//Calc windgustmph
	//Calc windgustdir
	//These are calculated in the main loop

	//Calc windspdmph_avg2m
	float temp = 0;
	for(int i = 0 ; i < 120 ; i++)
	temp += windspdavg[i];
	temp /= 120.0;
	windspdmph_avg2m = temp;

	//Calc winddir_avg2m, Wind Direction
	//You can't just take the average. Google "mean of circular quantities" for more info
	//We will use the Mitsuta method because it doesn't require trig functions
	//And because it sounds cool.
	//Based on: http://abelian.org/vlf/bearings.html
	//Based on: http://stackoverflow.com/questions/1813483/averaging-angles-again
	long sum = winddiravg[0];
	int D = winddiravg[0];
	for(int i = 1 ; i < WIND_DIR_AVG_SIZE ; i++)
	{
	int delta = winddiravg[i] - D;

	if(delta < -180)
	D += delta + 360;
	else if(delta > 180)
	D += delta - 360;
	else
	D += delta;

	sum += D;
	}
	winddir_avg2m = sum / WIND_DIR_AVG_SIZE;
	if(winddir_avg2m >= 360) winddir_avg2m -= 360;
	if(winddir_avg2m < 0) winddir_avg2m += 360;

	//Calc windgustmph_10m
	//Calc windgustdir_10m
	//Find the largest windgust in the last 10 minutes
	windgustmph_10m = 0;
	windgustdir_10m = 0;
	//Step through the 10 minutes
	for(int i = 0; i < 10 ; i++)
	{
	if(windgust_10m[i] > windgustmph_10m)
	{
	windgustmph_10m = windgust_10m[i];
	windgustdir_10m = windgustdirection_10m[i];
	}
	}

	//Calc humidity
	humidity = myHumidity.readHumidity();
	//float temp_h = myHumidity.readTemperature();
	//Serial.print(" TempH:");
	//Serial.print(temp_h, 2);

	//Calc tempf from pressure sensor
	tempf = myPressure.readTempF();
	//Serial.print(" TempP:");
	//Serial.print(tempf, 2);

	//Total rainfall for the day is calculated within the interrupt
	//Calculate amount of rainfall for the last 60 minutes
	rainin = 0;
	for(int i = 0 ; i < 60 ; i++)
	rainin += rainHour[i];

	//Calc pressure
	pressure = myPressure.readPressure();

	//Calc dewptf

	//Calc light level
	light_lvl = get_light_level();

	//Calc battery level
	batt_lvl = get_battery_level();
	}

	//Returns the voltage of the light sensor based on the 3.3V rail
	//This allows us to ignore what VCC might be (an Arduino plugged into USB has VCC of 4.5 to 5.2V)
	float get_light_level()
	{
	float operatingVoltage = analogRead(REFERENCE_3V3);

	float lightSensor = analogRead(LIGHT);

	operatingVoltage = 3.3 / operatingVoltage; //The reference voltage is 3.3V

	lightSensor = operatingVoltage * lightSensor;

	return(lightSensor);
	}

	//Returns the voltage of the raw pin based on the 3.3V rail
	//This allows us to ignore what VCC might be (an Arduino plugged into USB has VCC of 4.5 to 5.2V)
	//Battery level is connected to the RAW pin on Arduino and is fed through two 5% resistors:
	//3.9K on the high side (R1), and 1K on the low side (R2)
	float get_battery_level()
	{
	float operatingVoltage = analogRead(REFERENCE_3V3);

	float rawVoltage = analogRead(BATT);

	operatingVoltage = 3.30 / operatingVoltage; //The reference voltage is 3.3V

	rawVoltage = operatingVoltage * rawVoltage; //Convert the 0 to 1023 int to actual voltage on BATT pin

	rawVoltage *= 4.90; //(3.9k+1k)/1k - multiple BATT voltage by the voltage divider to get actual system voltage

	return(rawVoltage);
	}

	//Returns the instataneous wind speed
	float get_wind_speed()
	{
	float deltaTime = millis() - lastWindCheck; //750ms

	deltaTime /= 1000.0; //Covert to seconds

	float windSpeed = (float)windClicks / deltaTime; //3 / 0.750s = 4

	windClicks = 0; //Reset and start watching for new wind
	lastWindCheck = millis();

	windSpeed = 1.492; //4 1.492 = 5.968MPH

	/* Serial.println();
	Serial.print("Windspeed:");
	Serial.println(windSpeed);*/

	return(windSpeed);
	}

	//Read the wind direction sensor, return heading in degrees
	int get_wind_direction()
	{
	unsigned int adc;

	adc = analogRead(WDIR); // get the current reading from the sensor

	// The following table is ADC readings for the wind direction sensor output, sorted from low to high.
	// Each threshold is the midpoint between adjacent headings. The output is degrees for that ADC reading.
	// Note that these are not in compass degree order! See Weather Meters datasheet for more information.

	if (adc < 380) return (113);
	if (adc < 393) return (68);
	if (adc < 414) return (90);
	if (adc < 456) return (158);
	if (adc < 508) return (135);
	if (adc < 551) return (203);
	if (adc < 615) return (180);
	if (adc < 680) return (23);
	if (adc < 746) return (45);
	if (adc < 801) return (248);
	if (adc < 833) return (225);
	if (adc < 878) return (338);
	if (adc < 913) return (0);
	if (adc < 940) return (293);
	if (adc < 967) return (315);
	if (adc < 990) return (270);
	return (-1); // error, disconnected?
	}


	//Prints the various variables directly to the port
	//I don't like the way this function is written but Arduino doesn't support floats under sprintf
	void printWeather()
	{
	calcWeather(); //Go calc all the various sensors
	lpp.reset();

	Serial.println();
	Serial.print(F("$,winddir="));
	Serial.print(winddir);
	lpp.addAnalogInput(1, winddir);

	Serial.print(F(",windspeedmph="));
	Serial.print(windspeedmph, 1);
	lpp.addAnalogInput(2, windspeedmph);

	Serial.print(F(",humidity="));
	Serial.print(humidity, 1);
	lpp.addRelativeHumidity(3, humidity);

	Serial.print(F(",tempf="));
	Serial.print(tempf, 1);
	lpp.addTemperature(4, tempf);

	Serial.print(F(",rainin="));
	Serial.print(rainin, 2);
	lpp.addAnalogInput(5, rainin);

	Serial.print(F(",dailyrainin="));
	Serial.print(dailyrainin, 2);
	lpp.addAnalogInput(6, dailyrainin);

	Serial.print(F(",pressure="));
	Serial.print(pressure, 2);
	lpp.addBarometricPressure(7,pressure);

	Serial.print(F(",batt_lvl="));
	Serial.print(batt_lvl, 2);
	lpp.addAnalogInput(8, batt_lvl);

	Serial.print(F(",light_lvl="));
	Serial.println(light_lvl, 2);
	lpp.addLuminosity(9,light_lvl);
	}