help to pass version 2 mysensors



  • Hello
    I am a beginner in programming and excuse me
    my english
    i tried to go to v 2 his function not these you can m help thank you in advance[0_1514023990085_sketch_dec23b.ino](Envoi en cours 100%)



  • @zrom69 said in help to pass version 2 mysensors:

    Hello
    I am a beginner in programming and excuse me
    my english
    i tried to go to v 2 his function not these you can m help thank you in advance[0_1514023990085_sketch_dec23b.ino](Envoi en cours 100%)

    // Example sketch för a "light switch" where you can control light or something 
    // else from both vera and a local physical button (connected between digital
    // pin 3 and GND).
    // This node also works as a repeader for other nodes
    
    #include <MySensor.h>
    #include <SPI.h>
    #include <DHT.h> 
    
    unsigned long SLEEP_TIME = 120000; // Sleep time between reports (in milliseconds)
    
    //pin sensori
    #define PIR_PIN 2                   // The digital input you attached your motion sensor.  (Only 2 and 3 generates interrupt!)
    #define HUMIDITY_TEMPERATURE_PIN 3  // sensore temperatura umidita
    #define RELAY_PIN  4                // relay pin
    int BATTERY_SENSE_PIN = A1;         // Pin carica batteria o pannello solare
    int FOTORESIST_SENSE_PIN = A2;      // Pin fotoresistenza
    
    //interupt per sleep arduino
    #define INTERRUPT PIR_PIN-2 // Usually the interrupt = pin -2 (on uno/nano anyway)
    
    //id per vera
    #define CHILD_ID_RELE 1   // Id relay
    #define CHILD_ID_HUM 2    // id temperatura
    #define CHILD_ID_TEMP 3   // id umidita
    #define CHILD_ID_PIR 4    // Id pir
    #define CHILD_ID_LIGHT 5  // Id luminosita (fotoresistenza)
    
    //definizione per nodo vera
    #define NODE_ID 10
    #define SN "meteo station"
    #define SV "1.4"
    
    //variabili
    bool state_relay;                 //stato relay
    float batt_valore;                //dichiaro la variabile valore che memorizzerà il valore della batteria dal pin analogico
    float batt_volt;                  //volt batteria
    float batt_charged_percent;       //percentuale carica batteria
    float last_batt_charged_percent;  //percentuale carica batteria precedente
    float batt_min_voltage = 0.5;     //tensione minima batteria
    float batt_max_voltage = 5;       //tensione massima batteria
    float fotoresistenza_valore;      //dichiaro la variabile valore che memorizzerà il valore della fotoresistenza dal pin analogico
    float last_fotoresistenza_valore; //dichiaro la variabile valore precedente
    
    int lux_vera;                      //valore luminosita da inviare a vera
    
    MySensor gw;
    
    // sensore temperatura umidita
    DHT dht_int;
    float lastTemp_int = -1;
    float lastHum_int = -1;
    
    boolean metric = true; 
    
    MyMessage msgRelay(CHILD_ID_RELE,V_LIGHT);
    MyMessage msgHum(CHILD_ID_HUM, V_HUM);
    MyMessage msgTemp(CHILD_ID_TEMP, V_TEMP);
    MyMessage msgPir(CHILD_ID_PIR, V_TRIPPED);
    MyMessage msgLux(CHILD_ID_LIGHT, V_LIGHT_LEVEL);
    
    void setup()  
    {  
      gw.begin(incomingMessage, NODE_ID, false);    
      
      gw.sendSketchInfo(SN, SV); 
    
      //Sensore umidita temperatura
      dht_int.setup(HUMIDITY_TEMPERATURE_PIN);
      
      gw.present(CHILD_ID_RELE, S_LIGHT);       //light vera
      gw.present(CHILD_ID_HUM, S_HUM);          //umidity vera
      gw.present(CHILD_ID_TEMP, S_TEMP);           // temp vera
      gw.present(CHILD_ID_PIR, S_MOTION);          // motion vera
      gw.present(CHILD_ID_LIGHT, S_LIGHT_LEVEL);  //light level (fotoresistenza)
      
      metric = gw.getConfig().isMetric;
      
      // Then set relay pins in output mode
      pinMode(RELAY_PIN, OUTPUT);   
      
      //PIR
      pinMode(PIR_PIN, INPUT);
      
      state_relay = 0;  
      //GestisciRelay();
      digitalWrite(RELAY_PIN, LOW);
      gw.send(msgRelay.set(state_relay)); 
         
    }
    
    void loop() 
    { 
        gw.process();
      
        //sensore temperatura umidita
        delay(dht_int.getMinimumSamplingPeriod());
    
        float temperature_int = dht_int.getTemperature();
        if (isnan(temperature_int)) 
        {
            lastTemp_int = -1;
            Serial.println("Failed reading temperature from DHT");
        } 
        else if (temperature_int != lastTemp_int) 
        {
          lastTemp_int = temperature_int;
          if (!metric) 
          {
            temperature_int = dht_int.toFahrenheit(temperature_int);
          }
          gw.send(msgTemp.set(temperature_int, 1));
          Serial.print("T int: ");
          Serial.println(temperature_int);
        }
      
        float humidity_int = dht_int.getHumidity();
        if (isnan(humidity_int)) 
        {
            lastHum_int = -1;
            Serial.println("Failed reading humidity from DHT");
        } 
        else if (humidity_int != lastHum_int) 
        {
            lastHum_int = humidity_int;
            gw.send(msgHum.set(humidity_int, 1));
            Serial.print("H int: ");
            Serial.println(humidity_int);
        }
        //sensore temperatura umidita
        
        //fotoresistenza    
        for(int i=0;i<150;i++)
        {
          fotoresistenza_valore += analogRead(FOTORESIST_SENSE_PIN);  //read the input voltage from battery or solar panel      
          delay(2);
        }
        fotoresistenza_valore = fotoresistenza_valore / 150;    
               
        Serial.print ("fotoresistenza: ");
        Serial.println(fotoresistenza_valore); 
    
        if (fotoresistenza_valore != last_fotoresistenza_valore) 
        {
          lux_vera = (int) fotoresistenza_valore;
          gw.send(msgLux.set(lux_vera));
          last_fotoresistenza_valore = fotoresistenza_valore;
        }    
        //fotoresistenza
        
        //pir relay
        // Read digital motion value
        boolean tripped = digitalRead(PIR_PIN) == HIGH; 
        Serial.println("pir:");      
        Serial.println(tripped);
        gw.send(msgPir.set(tripped?"1":"0"));  // Send tripped value to gw 
        
        //accende la luce con il buio
        if (fotoresistenza_valore < 200)  //poca luce
        {
          if (tripped == 1) 
          {
             state_relay = 1;     
          }
          else
          {
             state_relay = 0;     
          }
        }
        //accende la luce con il buio
        
        GestisciRelay();
        //pir relay
        
        //battery    
        for(int i=0;i<150;i++)
        {
          batt_valore += analogRead(BATTERY_SENSE_PIN);  //read the input voltage from battery or solar panel      
          delay(2);
        }
        batt_valore = batt_valore / 150;    
               
        Serial.print ("batt_valore: ");
        Serial.println(batt_valore);
        
        batt_volt = (batt_valore / 1024) * batt_max_voltage;
        Serial.print ("batt_volt: ");
        Serial.println(batt_volt);
        
        ////////////////////////////////////////////////
       //The map() function uses integer math so will not generate fractions
       // so I multiply battery voltage with 10 to convert float into a intiger value
       // when battery voltage is 6.0volt it is totally discharged ( 6*10 =60)
       // when battery voltage is 7.2volt it is fully charged (7.2*10=72)
       // 6.0v =0% and 7.2v =100%
       //batt_charged_percent = batt_volt*10;   
       //batt_charged_percent = map(batt_volt*10, 60 , 72, 0, 100);
        batt_charged_percent = batt_volt * 10;   
        batt_charged_percent = map(batt_volt * 10, batt_min_voltage * 10 , batt_max_voltage * 10, 0, 100);
        //batt_charged_percent = (batt_volt / batt_max_voltage) * 100;
        Serial.print ("batt_charged_percent: ");
        Serial.println(batt_charged_percent);
           
        if (last_batt_charged_percent != batt_charged_percent) 
        {
            gw.sendBatteryLevel(batt_charged_percent);
            last_batt_charged_percent = batt_charged_percent;        
        }
        //battery
        
        delay(50);
        
        // Sleep until interrupt comes in on motion sensor. Send update every two minute.   
        gw.sleep(INTERRUPT, CHANGE, SLEEP_TIME);
        
        
    } 
     
    void incomingMessage(const MyMessage &message) {
      // We only expect one type of message from controller. But we better check anyway.
      if (message.isAck()) {
         Serial.println("This is an ack from gateway");
      }
    
      if (message.type == V_LIGHT) {
         // Change relay state_relay
         state_relay = message.getBool();
         GestisciRelay();
        
         // Write some debug info
         Serial.print("Incoming change for sensor:");
         Serial.print(message.sensor);
         Serial.print(", New status: ");
         Serial.println(message.getBool());
       } 
       
      
    }
    
    
    
    void GestisciRelay()
    {
        //Serial.print(" GestisciRelay state_relay:");
        //Serial.println(state_relay);
      
        if (state_relay == 0)
        {
          digitalWrite(RELAY_PIN, LOW);
          gw.send(msgRelay.set(state_relay));
          //Serial.println("SPENTO RELAY");
        }
        else 
       {
          digitalWrite(RELAY_PIN, HIGH);
          gw.send(msgRelay.set(state_relay));
          //Serial.println("ACCESO RELAY");
       } 
    
      
    }
    

  • Mod



  • @gohan

    you can check i add module rain

    // Example sketch för a "light switch" where you can control light or something 
    // else from both vera and a local physical button (connected between digital
    // pin 3 and GND).
    // This node also works as a repeader for other nodes
    // Enable debug prints to serial monitor
    #define MY_DEBUG 
    
    // Enable and select radio type attached
    #define MY_RADIO_NRF24
    //#define MY_RADIO_RFM69
    
    #define MY_NODE_ID 2
    #define MY_PARENT_NODE_ID  0
    #define MY_PARENT_NODE_IS_STATIC
    #include <MySensors.h>
    #include <SPI.h>
    #include <DHT.h> 
    
    unsigned long SLEEP_TIME = 120000; // Sleep time between reports (in milliseconds)
    
    //pin sensori
    #define PIR_PIN 6                   // The digital input you attached your motion sensor.  (Only 2 and 3 generates interrupt!)
    #define HUMIDITY_TEMPERATURE_PIN 3  // sensore temperatura umidita
    #define RELAY_PIN  4   // relay pin
    #define DIGITAL_INPUT_RAIN_SENSOR 5
    int BATTERY_SENSE_PIN = A1;         // Pin carica batteria o pannello solare
    int FOTORESIST_SENSE_PIN = A2;      // Pin fotoresistenza
    
    //interupt per sleep arduino
    #define INTERRUPT PIR_PIN-6 // Usually the interrupt = pin -2 (on uno/nano anyway)
    #define INTERRUPT DIGITAL_INPUT_RAIN_SENSOR-2
    
    //id per vera
    #define CHILD_ID_RELE 1   // Id relay
    #define CHILD_ID_HUM 2    // id temperatura
    #define CHILD_ID_TEMP 3   // id umidita
    #define CHILD_ID_PIR 4    // Id pir
    #define CHILD_ID_LIGHT 5  // Id luminosita (fotoresistenza)
    #define CHILD_ID_RAIN 6
    
    //definizione per nodo vera
    #define NODE_ID 10
    #define SN "meteo station"
    #define SV "1.4"
    
    //variabili
    bool state_relay;                 //stato relay
    float batt_valore;                //dichiaro la variabile valore che memorizzerà il valore della batteria dal pin analogico
    float batt_volt;                  //volt batteria
    float batt_charged_percent;       //percentuale carica batteria
    float last_batt_charged_percent;  //percentuale carica batteria precedente
    float batt_min_voltage = 0.5;     //tensione minima batteria
    float batt_max_voltage = 5;       //tensione massima batteria
    float fotoresistenza_valore;      //dichiaro la variabile valore che memorizzerà il valore della fotoresistenza dal pin analogico
    float last_fotoresistenza_valore; //dichiaro la variabile valore precedente
    int lastRainValue = -1;
    int nRainVal;
    boolean bIsRaining = false;
    String strRaining = "NO";
    int lux_vera;                      //valore luminosita da inviare a vera
    
    
    
    // sensore temperatura umidita
    DHT dht_int;
    float lastTemp_int = -1;
    float lastHum_int = -1;
    
    boolean metric = true; 
    
    MyMessage msgRelay(CHILD_ID_RELE,V_LIGHT);
    MyMessage msgHum(CHILD_ID_HUM, V_HUM);
    MyMessage msgTemp(CHILD_ID_TEMP, V_TEMP);
    MyMessage msgPir(CHILD_ID_PIR, V_TRIPPED);
    MyMessage msgLux(CHILD_ID_LIGHT, V_LIGHT_LEVEL);
    MyMessage msgRain(CHILD_ID_RAIN, V_TRIPPED);
    
    void setup()  
    {  
     metric = getControllerConfig().isMetric;
      // Then set relay pins in output mode
      pinMode(RELAY_PIN, OUTPUT);
    
      pinMode(DIGITAL_INPUT_RAIN_SENSOR, INPUT);
      
      //PIR
      pinMode(PIR_PIN, INPUT);
      
      state_relay = 0;  
      //GestisciRelay();
      digitalWrite(RELAY_PIN, LOW);
      send(msgRelay.set(state_relay)); 
         
    }
    
    
    void presentation() 
    {
          
      
      sendSketchInfo(SN, SV); 
    
      //Sensore umidita temperatura
      dht_int.setup(HUMIDITY_TEMPERATURE_PIN);
      
      present(CHILD_ID_RELE, S_LIGHT);       //light vera
      present(CHILD_ID_HUM, S_HUM);          //umidity vera
      present(CHILD_ID_TEMP, S_TEMP);           // temp vera
      present(CHILD_ID_PIR, S_MOTION);          // motion vera
      present(CHILD_ID_LIGHT, S_LIGHT_LEVEL);  //light level (fotoresistenza)
      present(CHILD_ID_RAIN, S_MOTION, "WS Rain");
    
    }
    void loop() 
    { 
        
      
        //sensore temperatura umidita
        delay(dht_int.getMinimumSamplingPeriod());
    
        float temperature_int = dht_int.getTemperature();
        if (isnan(temperature_int)) 
        {
            lastTemp_int = -1;
            Serial.println("Failed reading temperature from DHT");
        } 
        else if (temperature_int != lastTemp_int) 
        {
          lastTemp_int = temperature_int;
          if (!metric) 
          {
            temperature_int = dht_int.toFahrenheit(temperature_int);
          }
          send(msgTemp.set(temperature_int, 1));
          Serial.print("T int: ");
          Serial.println(temperature_int);
        }
      
        float humidity_int = dht_int.getHumidity();
        if (isnan(humidity_int)) 
        {
            lastHum_int = -1;
            Serial.println("Failed reading humidity from DHT");
        } 
        else if (humidity_int != lastHum_int) 
        {
            lastHum_int = humidity_int;
            send(msgHum.set(humidity_int, 1));
            Serial.print("H int: ");
            Serial.println(humidity_int);
        }
        //sensore temperatura umidita
        
        //fotoresistenza    
        for(int i=0;i<150;i++)
        {
          fotoresistenza_valore += analogRead(FOTORESIST_SENSE_PIN);  //read the input voltage from battery or solar panel      
          delay(2);
        }
        fotoresistenza_valore = fotoresistenza_valore / 150;    
               
        Serial.print ("fotoresistenza: ");
        Serial.println(fotoresistenza_valore); 
    
        if (fotoresistenza_valore != last_fotoresistenza_valore) 
        {
          lux_vera = (int) fotoresistenza_valore;
          send(msgLux.set(lux_vera));
          last_fotoresistenza_valore = fotoresistenza_valore;
        }    
        //fotoresistenza
        
        //pir relay
        // Read digital motion value
        boolean tripped = digitalRead(PIR_PIN) == HIGH; 
        Serial.println("pir:");      
        Serial.println(tripped);
        send(msgPir.set(tripped?"1":"0"));  // Send tripped value to gw 
        
        //accende la luce con il buio
        if (fotoresistenza_valore < 200)  //poca luce
        {
          if (tripped == 1) 
          {
             state_relay = 1;     
          }
          else
          {
             state_relay = 0;     
          }
        }
        //accende la luce con il buio
        
        GestisciRelay();
        //pir relay
        
        //battery    
        for(int i=0;i<150;i++)
        {
          batt_valore += analogRead(BATTERY_SENSE_PIN);  //read the input voltage from battery or solar panel      
          delay(2);
        }
        batt_valore = batt_valore / 150;    
               
        Serial.print ("batt_valore: ");
        Serial.println(batt_valore);
        
        batt_volt = (batt_valore / 1024) * batt_max_voltage;
        Serial.print ("batt_volt: ");
        Serial.println(batt_volt);
        
        ////////////////////////////////////////////////
       //The map() function uses integer math so will not generate fractions
       // so I multiply battery voltage with 10 to convert float into a intiger value
       // when battery voltage is 6.0volt it is totally discharged ( 6*10 =60)
       // when battery voltage is 7.2volt it is fully charged (7.2*10=72)
       // 6.0v =0% and 7.2v =100%
       //batt_charged_percent = batt_volt*10;   
       //batt_charged_percent = map(batt_volt*10, 60 , 72, 0, 100);
        batt_charged_percent = batt_volt * 10;   
        batt_charged_percent = map(batt_volt * 10, batt_min_voltage * 10 , batt_max_voltage * 10, 0, 100);
        //batt_charged_percent = (batt_volt / batt_max_voltage) * 100;
        Serial.print ("batt_charged_percent: ");
        Serial.println(batt_charged_percent);
           
        if (last_batt_charged_percent != batt_charged_percent) 
        {
            sendBatteryLevel(batt_charged_percent);
            last_batt_charged_percent = batt_charged_percent;        
        }
        
        bIsRaining = !(digitalRead(DIGITAL_INPUT_RAIN_SENSOR));
          if(bIsRaining){
              strRaining = "YES";
          }
          else{
              strRaining = "NO";
          }
      
          //Serial.print("Raining?: ");
          //Serial.print(strRaining);  
          //Serial.print("\t Moisture Level: ");
          //Serial.println(nRainVal);
          //http://henrysbench.capnfatz.com/henrys-bench/arduino-sensors-and-input/arduino-rain-sensor-module-guide-and-tutorial/
    
          send(msgRain.set(bIsRaining, 1));
        
        //battery
        
        delay(50);
        
        // Sleep until interrupt comes in on motion sensor. Send update every two minute.   
        sleep(INTERRUPT, CHANGE, SLEEP_TIME);
        
        
    } 
     
    void incomingMessage(const MyMessage &message) {
      // We only expect one type of message from controller. But we better check anyway.
      if (message.isAck()) {
         Serial.println("This is an ack from gateway");
      }
    
      if (message.type == V_LIGHT) {
         // Change relay state_relay
         state_relay = message.getBool();
         GestisciRelay();
        
         // Write some debug info
         Serial.print("Incoming change for sensor:");
         Serial.print(message.sensor);
         Serial.print(", New status: ");
         Serial.println(message.getBool());
       } 
       
      
    }
    
    
    
    void GestisciRelay()
    {
        //Serial.print(" GestisciRelay state_relay:");
        //Serial.println(state_relay);
      
        if (state_relay == 0)
        {
          digitalWrite(RELAY_PIN, LOW);
          send(msgRelay.set(state_relay));
          //Serial.println("SPENTO RELAY");
        }
        else 
       {
          digitalWrite(RELAY_PIN, HIGH);
          send(msgRelay.set(state_relay));
          //Serial.println("ACCESO RELAY");
       } 
    
      
    }
    

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