miguelalonso/sqflex.piscina

## sqflex.piscina
// which analog pin to connect
#define THERMISTORPIN A0
// resistance at 25 degrees C
#define THERMISTORNOMINAL 5000
// temp. for nominal resistance (almost always 25 C)
#define TEMPERATURENOMINAL 25
// how many samples to take and average, more takes longer
// but is more 'smooth'
#define NUMSAMPLES 5
// The beta coefficient of the thermistor (usually 3000-4000)
#define BCOEFFICIENT 3500
// the value of the 'other' resistor
#define SERIESRESISTOR 10000

 #include <virtuabotixRTC.h>
 // Creation of the Real Time Clock Object
//SCLK -> 4, I/O -> 5, CE -> 6
virtuabotixRTC myRTC(4, 5, 6);

int samples[NUMSAMPLES];

const int relepin = 8;
float temperatura;
float limite_temperatura =38.5;

void setup(void) {
  Serial.begin(9600);
  //analogReference(EXTERNAL);
  // seconds, minutes, hours, day of the week, day of the month, month, year
  //para ponerlo en hora alimentar el reloj a 5V
 //myRTC.setDS1302Time(00, 02, 10, 2, 2, 3, 2015);
  // myRTC.updateTime();
  pinMode(relepin, OUTPUT);
}

void loop(void) {
  myRTC.updateTime();
  print_datetime();
  uint8_t i;
  float average;

  // take N samples in a row, with a slight delay
  for (i=0; i< NUMSAMPLES; i++) {
   samples[i] = analogRead(THERMISTORPIN);
   delay(10);
  }

  // average all the samples out
  average = 0;
  for (i=0; i< NUMSAMPLES; i++) {
     average += samples[i];
  }
  average /= NUMSAMPLES;

  Serial.print("Average analog reading ");
  Serial.println(average);

  // convert the value to resistance
  average = 1023 / average - 1;
  average = SERIESRESISTOR / average;
  Serial.print("Thermistor resistance ");
  Serial.println(average);

  float steinhart;
  steinhart = average / THERMISTORNOMINAL;     // (R/Ro)
  steinhart = log(steinhart);                  // ln(R/Ro)
  steinhart /= BCOEFFICIENT;                   // 1/B * ln(R/Ro)
  steinhart += 1.0 / (TEMPERATURENOMINAL + 273.15); // + (1/To)
  steinhart = 1.0 / steinhart;                 // Invert
  steinhart -= 273.15;                         // convert to C

  Serial.print("Temperature ");
  Serial.print(steinhart);
  Serial.println(" *C");

 temperatura= steinhart;
controla_rele();
  delay(1000);
}

void print_datetime(){
  // Start printing elements as individuals

Serial.print("Current Date / Time: ");
Serial.print(myRTC.dayofmonth);
Serial.print("/");
Serial.print(myRTC.month);
Serial.print("/");
Serial.print(myRTC.year);
Serial.print(" ");
Serial.print(myRTC.hours);
Serial.print(":");
Serial.print(myRTC.minutes);
Serial.print(":");
Serial.println(myRTC.seconds);
// Delay so the program doesn't print non-stop
}

void controla_rele(){
  if (temperatura > limite_temperatura) {
    // turn LED on:
    digitalWrite(relepin, LOW);
    Serial.println("RELE OFF"); //bomba conectada
  }
  else {
    // turn LED off:
    digitalWrite(relepin, HIGH);
     Serial.println("RELE ON"); //bomba desconectada

  }

 /*
  if (myRTC.hours > 10) {
    // turn LED on:
    digitalWrite(relepin, LOW);
    Serial.println("RELE OFF");
  }
  else {
    // turn LED off:
    digitalWrite(relepin, HIGH);
     Serial.println("RELE ON");

  }

  */
}
	// which analog pin to connect
	#define THERMISTORPIN A0
	// resistance at 25 degrees C
	#define THERMISTORNOMINAL 5000
	// temp. for nominal resistance (almost always 25 C)
	#define TEMPERATURENOMINAL 25
	// how many samples to take and average, more takes longer
	// but is more 'smooth'
	#define NUMSAMPLES 5
	// The beta coefficient of the thermistor (usually 3000-4000)
	#define BCOEFFICIENT 3500
	// the value of the 'other' resistor
	#define SERIESRESISTOR 10000

	#include <virtuabotixRTC.h>
	// Creation of the Real Time Clock Object
	//SCLK -> 4, I/O -> 5, CE -> 6
	virtuabotixRTC myRTC(4, 5, 6);

	int samples[NUMSAMPLES];

	const int relepin = 8;
	float temperatura;
	float limite_temperatura =38.5;

	void setup(void) {
	Serial.begin(9600);
	//analogReference(EXTERNAL);
	// seconds, minutes, hours, day of the week, day of the month, month, year
	//para ponerlo en hora alimentar el reloj a 5V
	//myRTC.setDS1302Time(00, 02, 10, 2, 2, 3, 2015);
	// myRTC.updateTime();
	pinMode(relepin, OUTPUT);
	}

	void loop(void) {
	myRTC.updateTime();
	print_datetime();
	uint8_t i;
	float average;

	// take N samples in a row, with a slight delay
	for (i=0; i< NUMSAMPLES; i++) {
	samples[i] = analogRead(THERMISTORPIN);
	delay(10);
	}

	// average all the samples out
	average = 0;
	for (i=0; i< NUMSAMPLES; i++) {
	average += samples[i];
	}
	average /= NUMSAMPLES;

	Serial.print("Average analog reading ");
	Serial.println(average);

	// convert the value to resistance
	average = 1023 / average - 1;
	average = SERIESRESISTOR / average;
	Serial.print("Thermistor resistance ");
	Serial.println(average);

	float steinhart;
	steinhart = average / THERMISTORNOMINAL; // (R/Ro)
	steinhart = log(steinhart); // ln(R/Ro)
	steinhart /= BCOEFFICIENT; // 1/B * ln(R/Ro)
	steinhart += 1.0 / (TEMPERATURENOMINAL + 273.15); // + (1/To)
	steinhart = 1.0 / steinhart; // Invert
	steinhart -= 273.15; // convert to C

	Serial.print("Temperature ");
	Serial.print(steinhart);
	Serial.println(" *C");

	temperatura= steinhart;
	controla_rele();
	delay(1000);
	}

	void print_datetime(){
	// Start printing elements as individuals

	Serial.print("Current Date / Time: ");
	Serial.print(myRTC.dayofmonth);
	Serial.print("/");
	Serial.print(myRTC.month);
	Serial.print("/");
	Serial.print(myRTC.year);
	Serial.print(" ");
	Serial.print(myRTC.hours);
	Serial.print(":");
	Serial.print(myRTC.minutes);
	Serial.print(":");
	Serial.println(myRTC.seconds);
	// Delay so the program doesn't print non-stop
	}

	void controla_rele(){
	if (temperatura > limite_temperatura) {
	// turn LED on:
	digitalWrite(relepin, LOW);
	Serial.println("RELE OFF"); //bomba conectada
	}
	else {
	// turn LED off:
	digitalWrite(relepin, HIGH);
	Serial.println("RELE ON"); //bomba desconectada

	}

	/*
	if (myRTC.hours > 10) {
	// turn LED on:
	digitalWrite(relepin, LOW);
	Serial.println("RELE OFF");
	}
	else {
	// turn LED off:
	digitalWrite(relepin, HIGH);
	Serial.println("RELE ON");

	}

	*/
	}