Arduino/Oregon433_2_BMP_Narco/Oregon433_2_BMP_Narco.ino

/*
 * connectingStuff, Oregon Scientific v2.1 Emitter
 * http://connectingstuff.net/blog/encodage-protocoles-oregon-scientific-sur-arduino
 * and 
 * http://blog.idleman.fr/raspberry-pi-18-construire-une-sonde-de-temperature-radio-pour-7e/
 *
 * This program is free software; you can redistribute it and/or
 * modify it under the terms of the GNU General Public License
 * as published by the Free Software Foundation; either version 2
 * of the License, or (at your option) any later version.
 *
 * This program is distributed in the hope that it will be useful,
 * but WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
 * GNU General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License
 * along with this program; if not, write to the Free Software
 * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA  02110-1301, USA.
*/
#include <OneWire.h>
//#include <DallasTemperature.h>
#include <Wire.h>
#include <Adafruit_BMP085.h>
#include <Narcoleptic.h> // Economie d'énergie


const byte TRANSMITTER_PIN = 9;


// 
float temperature = 0.0;

// ################# Barometre ####
Adafruit_BMP085 bmp;
// #####################

const unsigned long TIME = 512;
const unsigned long TWOTIME = TIME*2;
 
#define SEND_HIGH() digitalWrite(TRANSMITTER_PIN, HIGH)
#define SEND_LOW() digitalWrite(TRANSMITTER_PIN, LOW)
 
// Buffer for Oregon message
#ifdef THN132N
  byte OregonMessageBuffer[8];
#else
  byte OregonMessageBuffer[9];
#endif
 
/**
 * \brief    Send logical "0" over RF
 * \details  azero bit be represented by an off-to-on transition
 * \         of the RF signal at the middle of a clock period.
 * \         Remenber, the Oregon v2.1 protocol add an inverted bit first 
 */
inline void sendZero(void) 
{
  SEND_HIGH();
  delayMicroseconds(TIME);
  SEND_LOW();
  delayMicroseconds(TWOTIME);
  SEND_HIGH();
  delayMicroseconds(TIME);
}
 
/**
 * \brief    Send logical "1" over RF
 * \details  a one bit be represented by an on-to-off transition
 * \         of the RF signal at the middle of a clock period.
 * \         Remenber, the Oregon v2.1 protocol add an inverted bit first 
 */
inline void sendOne(void) 
{
   SEND_LOW();
   delayMicroseconds(TIME);
   SEND_HIGH();
   delayMicroseconds(TWOTIME);
   SEND_LOW();
   delayMicroseconds(TIME);
}
 
/**
* Send a bits quarter (4 bits = MSB from 8 bits value) over RF
*
* @param data Source data to process and sent
*/
 
/**
 * \brief    Send a bits quarter (4 bits = MSB from 8 bits value) over RF
 * \param    data   Data to send
 */
inline void sendQuarterMSB(const byte data) 
{
  (bitRead(data, 4)) ? sendOne() : sendZero();
  (bitRead(data, 5)) ? sendOne() : sendZero();
  (bitRead(data, 6)) ? sendOne() : sendZero();
  (bitRead(data, 7)) ? sendOne() : sendZero();
}
 
/**
 * \brief    Send a bits quarter (4 bits = LSB from 8 bits value) over RF
 * \param    data   Data to send
 */
inline void sendQuarterLSB(const byte data) 
{
  (bitRead(data, 0)) ? sendOne() : sendZero();
  (bitRead(data, 1)) ? sendOne() : sendZero();
  (bitRead(data, 2)) ? sendOne() : sendZero();
  (bitRead(data, 3)) ? sendOne() : sendZero();
}
 
/******************************************************************/
/******************************************************************/
/******************************************************************/
 
/**
 * \brief    Send a buffer over RF
 * \param    data   Data to send
 * \param    size   size of data to send
 */
void sendData(byte *data, byte size)
{
  for(byte i = 0; i < size; ++i)
  {
    sendQuarterLSB(data[i]);
    sendQuarterMSB(data[i]);
  }
}
 
/**
 * \brief    Send an Oregon message
 * \param    data   The Oregon message
 */
void sendOregon(byte *data, byte size)
{
    sendPreamble();
    //sendSync();
    sendData(data, size);
    sendPostamble();
}
 
/**
 * \brief    Send preamble
 * \details  The preamble consists of 16 "1" bits
 */
inline void sendPreamble(void)
{
  byte PREAMBLE[]={0xFF,0xFF};
  sendData(PREAMBLE, 2);
}
 
/**
 * \brief    Send postamble
 * \details  The postamble consists of 8 "0" bits
 */
inline void sendPostamble(void)
{
#ifdef THN132N
  sendQuarterLSB(0x00);
#else
  byte POSTAMBLE[]={0x00};
  sendData(POSTAMBLE, 1);  
#endif
}
 
/**
 * \brief    Send sync nibble
 * \details  The sync is 0xA. It is not use in this version since the sync nibble
 * \         is include in the Oregon message to send.
 */
inline void sendSync(void)
{
  sendQuarterLSB(0xA);
}
 
/******************************************************************/
/******************************************************************/
/******************************************************************/
 
/**
 * \brief    Set the sensor type
 * \param    data       Oregon message
 * \param    type       Sensor type
 */
inline void setType(byte *data, byte* type) 
{
  data[0] = type[0];
  data[1] = type[1];
}
 
/**
 * \brief    Set the sensor channel
 * \param    data       Oregon message
 * \param    channel    Sensor channel (0x10, 0x20, 0x30)
 */
inline void setChannel(byte *data, byte channel) 
{
    data[2] = channel;
}
 
/**
 * \brief    Set the sensor ID
 * \param    data       Oregon message
 * \param    ID         Sensor unique ID
 */
inline void setId(byte *data, byte ID) 
{
  data[3] = ID;
}
 
/**
 * \brief    Set the sensor battery level
 * \param    data       Oregon message
 * \param    level      Battery level (0 = low, 1 = high)
 */
void setBatteryLevel(byte *data, byte level)
{
  if(!level) data[4] = 0x0C;
  else data[4] = 0x00;
}
 
/**
 * \brief    Set the sensor temperature
 * \param    data       Oregon message
 * \param    temp       the temperature
 */
void setTemperature(byte *data, float temp) 
{
  // Set temperature sign
  if(temp < 0)
  {
    data[6] = 0x08;
    temp *= -1;  
  }
  else
  {
    data[6] = 0x00;
  }
 
  // Determine decimal and float part
  int tempInt = (int)temp;
  int td = (int)(tempInt / 10);
  int tf = (int)round((float)((float)tempInt/10 - (float)td) * 10);
 
  int tempFloat =  (int)round((float)(temp - (float)tempInt) * 10);
 
  // Set temperature decimal part
  data[5] = (td << 4);
  data[5] |= tf;
 
  // Set temperature float part
  data[4] |= (tempFloat << 4);
}
 
/**
 * \brief    Set the sensor humidity
 * \param    data       Oregon message
 * \param    hum        the humidity
 */
void setHumidity(byte* data, float hum)
{
    
    int h = (int) hum;
    data[7] = (int) h / 10; //(hum/10);
    data[6] |= (h - data[7]*10) << 4;
    
    Serial.print("Hum=");
   Serial.println(h);
}
 
/**
 * \brief    Sum data for checksum
 * \param    count      number of bit to sum
 * \param    data       Oregon message
 */
int Sum(byte count, const byte* data)
{
  int s = 0;
 
  for(byte i = 0; i<count;i++)
  {
    s += (data[i]&0xF0) >> 4;
    s += (data[i]&0xF);
  }
 
  if(int(count) != count)
    s += (data[count]&0xF0) >> 4;
 
  return s;
}
 
/**
 * \brief    Calculate checksum
 * \param    data       Oregon message
 */
void calculateAndSetChecksum(byte* data)
{
#ifdef THN132N
    int s = ((Sum(6, data) + (data[6]&0xF) - 0xa) & 0xff);
 
    data[6] |=  (s&0x0F) << 4;     data[7] =  (s&0xF0) >> 4;
#else
    data[8] = ((Sum(8, data) - 0xa) & 0xFF);
#endif
}
 
/******************************************************************/
/******************************************************************/
/******************************************************************/
 
void setup()
{
  pinMode(TRANSMITTER_PIN, OUTPUT);
 
  Serial.begin(9600);
  Serial.println("\n[Oregon V2.1 encoder]");
 
  SEND_LOW();  
  

      
    // BMP
   if (!bmp.begin()) {
     Serial.println("nu exita senzor compatibil BMP085 sau BMP180");
     while (1) {}
  }
}
 
void loop()
{
  // en premier pour la température
  barometre();
  
  do433();
  
  
  Narcoleptic.delay(30000); // During this time power consumption is minimised(5000);
}

void barometre() {
  Serial.print("Temperature=");
  temperature = bmp.readTemperature();
    Serial.print(temperature);
    //Serial.print(" *C");
    
    Serial.print(" Pression=");
    Serial.print(bmp.readPressure() / 100.0);
    //Serial.print(" hPa / ");
    
 //   Serial.print("Presiune = ");
    float pression = bmp.readPressure()/101.325;
    pression = pression * 0.760;
    Serial.print(" Mercure=");
    Serial.print(pression);
    //Serial.print(" mmHg");
    
    
    // Calculate altitude assuming 'standard' barometric
    // pressure of 1013.25 millibar = 101325 Pascal
    Serial.print(" Altitude=");
    Serial.print(bmp.readAltitude());
    // Serial.print(" m");

    //Serial.print(" Pression au niveau de la mer (calculee) = ");
    Serial.print(" Mer=");
    Serial.print(bmp.readSealevelPressure());
    //Serial.print(" Pa / ");
    
    // http://en.wikipedia.org/wiki/Atmospheric_pressure#Mean_sea_level_pressure
  //  Serial.print("Presiure la nivelul marii (calculata) = ");
    float presiune = bmp.readSealevelPressure()/101.325;
    presiune = presiune * 0.760;
    Serial.print(" MerMercure=");
    Serial.print(presiune);
    Serial.println(" mmHg");
    

  // you can get a more precise measurement of altitude
  // if you know the current sea level pressure which will
  // vary with weather and such. If it is 1015 millibars
  // that is equal to 101500 Pascals.
//    Serial.print("Altitude reelle = ");
//    Serial.print(bmp.readAltitude(101500));
//    Serial.println(" m");
//    
//    Serial.println();
}

void readSensors() {
  // ##########################################"
  // Analogic read
  // ------------------------------------------
  int sensorValue = analogRead(A0);  
  int sensorValue2 = analogRead(A1);
  int sensorValue3 = analogRead(A2);  
 // int sensorValue4 =  digitalRead(10);   
  
  //vol = (float)sensorValue / 1024 * 5.0;
  Serial.print("fumee=");
  Serial.print(sensorValue); 
  Serial.print(" gaz=");
  Serial.print(sensorValue2); 
  Serial.print(" photo="); 
 
  Serial.println((int) (sensorValue3 / 10.24)); 

  // ##########################################

}

void do433() {
  readSensors();

  // Get Temperature, humidity and battery level from sensors
  // (ie: 1wire DS18B20 for température, ...)
  setBatteryLevel(OregonMessageBuffer, 0); // 0 : low, 1 : high

  setTemperature(OregonMessageBuffer, temperature); //sensors.getTempCByIndex(0));

//  setTemperature(OregonMessageBuffer, 11.2);
 byte ID[] = {0x1A,0x2D};
 initMessage(ID); 
 sendMessage();
  
}

void initMessage(byte ID[]) {
//#ifdef THN132N  
//  // Create the Oregon message for a temperature only sensor (TNHN132N)
//  byte ID[] = {0xEA,0x4C};
//  Serial.println("Def THN132");
//#else
//  // Create the Oregon message for a temperature/humidity sensor (THGR228N)
//  byte ID[] = {0x1A,0x2D};
//  
//  // Rain jauge
//  //byte ID[] = {0x3A,0x0D};
//  
//  Serial.println("UnDef THN132");
//#endif  
 
  setType(OregonMessageBuffer,  ID);
  setChannel(OregonMessageBuffer, 0x20);
  setId(OregonMessageBuffer, 0xBB);
}

void sendMessage() {

  
   // Calculate the checksum
  calculateAndSetChecksum(OregonMessageBuffer);
 
  // Show the Oregon Message
  for (byte i = 0; i < sizeof(OregonMessageBuffer); ++i)   {     
    Serial.print(OregonMessageBuffer[i] >> 4, HEX);
    Serial.print(OregonMessageBuffer[i] & 0x0F, HEX);
    
  }
 Serial.println("");
   // Send the Message over RF
  sendOregon(OregonMessageBuffer, sizeof(OregonMessageBuffer));
  // Send a "pause"
  SEND_LOW();
  delayMicroseconds(TWOTIME*8);
  // Send a copie of the first message. The v2.1 protocol send the
  // message two time 
  sendOregon(OregonMessageBuffer, sizeof(OregonMessageBuffer));
 
  // Wait for 30 seconds before send a new message 
  SEND_LOW();
}