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#include "EmonLib.h" // Include Emon Library
EnergyMonitor emon1,emon2,emon3,emon4,emon5,emon6,emon7,emon8,emon9,emon10,emon11,emon12 ; // Create an instance
int message = 0;
int ledPin = 13;
void capture()
{
digitalWrite(ledPin, HIGH);
emon1.calcVI(20,2000); // Calculate all. No.of half wavelengths (crossings), time-out
emon2.calcVI(20,2000); // Calculate all. No.of half wavelengths (crossings), time-out
emon3.calcVI(20,2000); // Calculate all. No.of half wavelengths (crossings), time-out
emon3.calcVI(20,2000); // Print out all variables (realpower, apparent power, Vrms, Irms, power factor)
emon4.calcVI(20,2000); // Print out all variables (realpower, apparent power, Vrms, Irms, power factor)
emon5.calcVI(20,2000); // Calculate all. No.of half wavelengths (crossings), time-out
emon6.calcVI(20,2000); // Calculate all. No.of half wavelengths (crossings), time-out
emon7.calcVI(20,2000); // Calculate all. No.of half wavelengths (crossings), time-out
emon8.calcVI(20,2000); // Calculate all. No.of half wavelengths (crossings), time-out
emon9.calcVI(20,2000); // Calculate all. No.of half wavelengths (crossings), time-out
emon10.calcVI(20,2000); // Calculate all. No.of half wavelengths (crossings), time-out
emon11.calcVI(20,2000); // Calculate all. No.of half wavelengths (crossings), time-out
emon12.calcVI(20,2000); // Calculate all. No.of half wavelengths (crossings), time-out
float realPower = emon1.realPower; //extract Real Power into variable
float apparentPower = emon1.apparentPower; //extract Apparent Power into variable
float powerFActor = emon1.powerFactor; //extract Power Factor into Variable
float supplyVoltage = emon1.Vrms; //extract Vrms into Variable
float Irms = emon1.Irms; //extract Irms into Variable
digitalWrite(ledPin, LOW);
}
void envoi()
{
// passage du float en int
int a1, a2, a3, a4, a5, a6, a7, a8, a9, a10, a11, a12;
a1 = ((int) emon1.realPower / random(100,350));
a2 = ((int) emon2.realPower / random(100,350));
a3 = ((int) emon3.realPower / random(100,350));
a4 = ((int) emon4.realPower / random(100,350));
a5 = ((int) emon5.realPower / random(100,350));
a6 = ((int) emon6.realPower / random(100,350));
a7 = ((int) emon7.realPower / random(100,350));
a8 = ((int) emon8.realPower / random(100,350));
a9 = ((int) emon9.realPower / random(100,350));
a10 = ((int) emon10.realPower / random(100,350));
a11 = ((int) emon11.realPower / random(100,350));
a12 = ((int) emon12.realPower / random(100,350));
Serial.print(", ");
Serial.print((char) 34);
Serial.print(a1);
Serial.print((char) 34);
Serial.print(", ");
Serial.print((char) 34);
Serial.print(a2);
Serial.print((char) 34);
Serial.print(", ");
Serial.print((char) 34);
Serial.print(a3);
Serial.print((char) 34);
Serial.print(", ");
Serial.print((char) 34);
Serial.print(a4);
Serial.print((char) 34);
Serial.print(", ");
Serial.print((char) 34);
Serial.print(a5);
Serial.print((char) 34);
Serial.print(", ");
Serial.print((char) 34);
Serial.print(a6);
Serial.print((char) 34);
Serial.print(", ");
Serial.print((char) 34);
Serial.print(a7);
Serial.print((char) 34);
Serial.print(", ");
Serial.print((char) 34);
Serial.print(a8);
Serial.print((char) 34);
Serial.print(", ");
Serial.print((char) 34);
Serial.print(a9);
Serial.print((char) 34);
Serial.print(", ");
Serial.print((char) 34);
Serial.print(a10);
Serial.print((char) 34);
Serial.print(", ");
Serial.print((char) 34);
Serial.print(a11);
Serial.print((char) 34);
Serial.print(", ");
Serial.print((char) 34);
Serial.print(a12);
Serial.print((char) 34);
Serial.println(")");
}
void setup()
{
Serial.begin(57600);
pinMode(ledPin, OUTPUT);
// Ref Voltage
emon1.voltage(0, 234.26, 1.7); // Voltage: input pin, calibration, phase_shift
emon2.voltage(0, 234.26, 1.7); // Voltage: input pin, calibration, phase_shift
emon3.voltage(0, 234.26, 1.7); // Voltage: input pin, calibration, phase_shift
emon4.voltage(0, 234.26, 1.7); // Voltage: input pin, calibration, phase_shift
emon5.voltage(0, 234.26, 1.7); // Voltage: input pin, calibration, phase_shift
emon6.voltage(0, 234.26, 1.7); // Voltage: input pin, calibration, phase_shift
emon7.voltage(0, 234.26, 1.7); // Voltage: input pin, calibration, phase_shift
emon8.voltage(0, 234.26, 1.7); // Voltage: input pin, calibration, phase_shift
emon9.voltage(0, 234.26, 1.7); // Voltage: input pin, calibration, phase_shift
emon10.voltage(0, 234.26, 1.7); // Voltage: input pin, calibration, phase_shift
emon11.voltage(0, 234.26, 1.7); // Voltage: input pin, calibration, phase_shift
emon12.voltage(0, 234.26, 1.7); // Voltage: input pin, calibration, phase_shift
// Pin Current
emon1.current(1, 111.1); // Current: input pin, calibration.
emon2.current(2, 111.1); // Current: input pin, calibration.
emon3.current(3, 111.1); // Current: input pin, calibration.
emon4.current(4, 111.1); // Current: input pin, calibration.
emon5.current(5, 111.1); // Current: input pin, calibration.
emon6.current(6, 111.1); // Current: input pin, calibration.
emon7.current(7, 111.1); // Current: input pin, calibration.
emon8.current(8, 111.1); // Current: input pin, calibration.
emon9.current(9, 111.1); // Current: input pin, calibration.
emon10.current(10, 111.1); // Current: input pin, calibration.
emon11.current(11, 111.1); // Current: input pin, calibration.
emon12.current(12, 111.1); // Current: input pin, calibration.
}
void loop() {
if (Serial.available()) {
message = Serial.read()-'0'; // on soustrait le caractère 0, qui vaut 48 en ASCII
switch (message) {
case 2:
capture();
break;
case 5:
envoi();
break;
}
}
} |