- This library contains classes to perform encoding of radio signals in a radio
- band like 433 Mhz, which are typical for home automation, while the intention was, to use
- them for various self made Arduino sensors to transmit temperatures, humidity,
- light, doorswitch info, ...
- As this is an early state of the developpment, two encoding approaches
- are realized. One uses manchester encoding and the other uses common pulse pause modulation.
- The decoding can be done with the RFD-FHEM/SIGNALduino. Modules for useage in FHEM exists also RFD-FHEM/RFFHEM.
- Please note, that manchester decoding is not fully implemented in fhem
This lib is based and ispired on the sensor transmitter lib from Randy Simons: https://bitbucket.org/fuzzillogic/433mhzforarduino/wiki/Home
Usage hints for your own sensor:
Define some basic things:
#define TRANSMITTER 3 // 433Mhz Transmitter DATA PIN
#include <SensorTransmitter.h>
asTransmitter voltage(8,0,TRANSMITTER);// (DeviceType, DeviceID, OutputPin)
asTransmitter temp(6,0,TRANSMITTER);// (DeviceType, DeviceID, OutputPin)
asTransmitter hum(9,0,TRANSMITTER);// (DeviceType, DeviceID, OutputPin)Measure your temp and humidity value from your sensors, then convert data for temp and humidity:
tempVal=(uint16_t)(tempVal+0x8000);
humVal=(uint16_t)(humVal+0x8000);You can also measure vcc, and send it as a sensor value...
You need to calibrate your ADC with a voltmeter:
void calibrate(){
///////////////////////// calibration ///////////////////////////////////////////
static long mean = 0;
static int cnt = 0; // this will overflow after 4.5 hours, make shure you take your measurement before ;-)
mean += measureVcc();
++cnt;
Serial.print("Vcc: "); Serial.print((float)mean/cnt); Serial.println("mV");
delay(500);
}Then you can modify your sketch with the measured data:
/************************************
* Calibration of Vcc
* Calibration of the 1.1V reference requires an external measurement of Vcc with a voltmeter, for example.
* Follow these steps:
* 1. Measure Vcc with the voltmeter => Vcc1
* 2. Define CALVCC to let Arduino measure Vcc internal and print the result to Serial
* 3. Enter the above measured values in the formula, overwriting the default values
* Make shure to use the same units.
************************************/
//internal1.1Ref = 1.1 * Vcc1 (per voltmeter) / Vcc2 (per readVcc() function)
#ifndef CALVCC
//const int internalRef = 1.1 * 3160 / 3120; //with compensation
const float internalRef=0.96173822714;
const long scale_constant = internalRef * 1023 * 1000;
#else
const float internalRef = 1.1; // for calibration no compensation is required
#endif
uint16_t measureVcc() {
// Read 1.1V reference against AVcc
// set the reference to Vcc and the measurement to the internal 1.1V reference
ADMUX = _BV(MUX3) | _BV(MUX2);
delay(2); // Wait for Vref to settle
ADCSRA |= _BV(ADSC); // Start conversion
while (bit_is_set(ADCSRA,ADSC)); // measuring
uint8_t oldSREG = SREG;
uint16_t adc_result = ADC; //In one read?
SREG = oldSREG;
long result=adc_result;
result = scale_constant / result; // Calculate Vcc (in mV); 1126400 = 1.1*1024*1000
return (uint16_t)result; // Vcc in millivolts
//return result; // Vcc in millivolts
}Now we are ready to send data:
temp.send(tempVal, battery, trigger);//(value[16bit], battery[2bit], trigger[1bit])
hum.send(humVal, battery, trigger);//(value[16bit], battery[2bit], trigger[1bit])
voltage.send(vcc, battery, trigger);//(value[16bit], battery[2bit], trigger[1bit])