Tasmota/tools/theov2_attiny85/TheoV2Sensor1/TheoV2Sensor1.ino

281 lines
11 KiB
C++

/****************************************************************************************************************************\
* Arduino project "TheoTinySensor" Copyright 2013 Theo Arends
* 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 3 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.
******************************************************************************************************************************
/***************************************************************************************************************\
* Purpose : Arduino Source code for Sensor based on Atmel ATTiny85, running on 8MHz
* Version : R109 - DS18B20 and BH1750 and Vcc test
* Date : 20140502
*
* This code turns an Atmel ATTiny85 chip into a Sensor using the TheoV2 protocol.
* This code is not of any use without running a Unit within RF range to receive sensor data.
\***************************************************************************************************************/
#define SENSOR_TYPE 1 // 1 = DS18B20 and BH1750 sensor
// Uncomment for test purpose
//#define THEO_TEST
//*****************************************************************************
#ifdef THEO_TEST
#define CHANNEL 0 // 0 - 7, 0 discard by plugin
#define SEND_DELAY 2 // Send Delay in multiples of 4 seconds, so 2 = 2x4=8 seconds
#define VCC_LOOP 2
#else
#define CHANNEL 1 // 0 - 7, 0 discard by plugin
#define SEND_DELAY 30 // Send Delay in multiples of 4 seconds, so 70 = 70x4=280 seconds
#define VCC_LOOP 24 // Send Vcc once every hour
#endif
#define VREF_35 10885 // Measured value for Vref at 3.5V Vcc * 10 (Chip dependent)
#define BATT_LOW 30 // 3.0V Battery low warning voltage * 10 (Functionality dependent)
//*****************************************************************************
#define DALLAS_PIN 1 // data to DS18B20, fysieke pin 6 on ATTiny85
#define BH1750_ADDRESS 0x23 // i2c address BH1750
#define RF_TransmitDataPin 4 // data to RF Transmitter, fysieke pin 3 on ATTiny85
// ATMEL ATTINY85
// AI=Analog Input
// o-\/-+
// reset 1| |8 VCC
// Pin 3 (AI 3) PB3 2| |7 PB2 (AI 1) Pin 2 - SCL
// Pin 4 (AI 2) PB4 3| |6 PB1 PWM Pin 1 - PCINT1
// GND 4| |5 PB0 PWM Pin 0 - SDA
// +----+
// Used by DS18B20
#include <OneWire.h> // http://www.pjrc.com/teensy/arduino_libraries/OneWire.zip
// Used by BH1750
// Prepare library TinyWireM for 8MHz by editing the following files:
// 1) file USI_TWI_Master.cpp define F_CPU from 1000000UL to 8000000UL
// 2) file USI_TWI_Master.h define SYS_CLK from 1000.0 to 8000.0
#include <TinyWireM.h> // http://playground.arduino.cc/Code/USIi2c
byte VccTest;
byte Voltage;
//*****************************************************************************
// Setup stuff
//*****************************************************************************
void setup()
{
VccTest = VCC_LOOP;
pinMode(RF_TransmitDataPin,OUTPUT);
TinyWireM.begin();
Watchdog_setup(8); // Setup watchdog to notify us every 4 seconds
}
//*****************************************************************************
// Main loop
//*****************************************************************************
void loop()
{
int payload1 = 0;
int payload2 = 0;
VccTest++;
if (GetPayload(payload1, payload2) == 0)
SendData(payload1, payload2);
Watchdog_sleep(SEND_DELAY + CHANNEL); // Go to deep sleep mode for some time
}
//*****************************************************************************
// Sleep stuff
//*****************************************************************************
#include <avr/sleep.h>
#include <avr/wdt.h>
void Watchdog_setup(int ii)
{
// 0=16ms, 1=32ms, 2=64ms, 3=125ms, 4=250ms, 5=500ms, 6=1s, 7=2s, 8=4s, 9=8s
// The prescale value is held in bits 5,2,1,0
// This block moves ii into these bits
byte bb;
if (ii > 9 ) ii=9;
bb=ii & 7;
if (ii > 7) bb|= (1<<5);
bb|= (1<<WDCE);
MCUSR &= ~(1<<WDRF); // Reset the watchdog reset flag
WDTCR |= (1<<WDCE) | (1<<WDE); // Start timed sequence
WDTCR = bb; // Set new watchdog timeout value
WDTCR |= _BV(WDIE); // Enable interrupts instead of reset
}
void Watchdog_sleep(int waitCounter)
{
while (waitCounter != 0)
{
bitClear(ADCSRA,ADEN); // Switch Analog to Digital converter OFF
set_sleep_mode(SLEEP_MODE_PWR_DOWN); // Set sleep mode
sleep_mode(); // System sleeps here
waitCounter--;
}
}
void Watchdog_delay(int prescale)
{
Watchdog_setup(prescale);
Watchdog_sleep(1);
Watchdog_setup(8);
}
ISR(WDT_vect)
{
// Don't do anything here but we must include this
// block of code otherwise the interrupt calls an
// uninitialized interrupt handler.
}
//*****************************************************************************
// Send data via RF
//*****************************************************************************
#define RF_PULSE_0 500 // PWM: Tijdsduur van de puls bij verzenden van een '0' in uSec.
#define RF_PULSE_MID 1000 // PWM: Pulsen langer zijn '1'
#define RF_PULSE_1 1500 // PWM: Tijdsduur van de puls bij verzenden van een '1' in uSec. (3x RF_PULSE_0)
#define RF_SPACE 500 // PWM: Tijdsduur van de space tussen de bitspuls bij verzenden van een '1' in uSec.
#define TransmitRepeat 2
void SendData(int payload1, int payload2)
{
struct
{
byte Checksum; // Checksum over following bytes
byte Channel: 3; // 3 bits channel
byte Type: 5; // 5 bits type
byte Voltage; // Vcc like 45 = 4.5V, bit 8 is batt low
int Payload1;
int Payload2;
} DataBlock;
byte Size = sizeof(DataBlock);
DataBlock.Type = SENSOR_TYPE;
DataBlock.Channel = CHANNEL;
if (VccTest >= VCC_LOOP) // Do not run the Vcc test too often to save Battery power
{
VccTest = 0;
Voltage = ReadVcc();
if (Voltage <= BATT_LOW)
Voltage |= 0x80;
}
DataBlock.Voltage = Voltage;
DataBlock.Payload1 = payload1;
DataBlock.Payload2 = payload2;
byte c = 0, *B = (byte*)&DataBlock; // bereken checksum: crc-8 uit bovenstaande bytes in de struct
for (byte x = 1; x < Size; x++)
c +=*(B+x);
DataBlock.Checksum = c;
pinMode(RF_TransmitDataPin, OUTPUT);
digitalWrite(RF_TransmitDataPin, LOW); // 0
for (byte y = 0; y < TransmitRepeat; y++) // herhaal verzenden RF code
{
digitalWrite(RF_TransmitDataPin, HIGH); // 1
delayMicroseconds(RF_PULSE_1 * 4);
digitalWrite(RF_TransmitDataPin, LOW); // 0
delayMicroseconds(RF_SPACE * 2);
for (byte x = 0; x < Size; x++)
{
for (byte Bit = 0; Bit <= 7; Bit++)
{
digitalWrite(RF_TransmitDataPin, HIGH); // 1
if ((*(B + x) >> Bit) & 1)
delayMicroseconds(RF_PULSE_1);
else
delayMicroseconds(RF_PULSE_0);
digitalWrite(RF_TransmitDataPin, LOW); // 0
delayMicroseconds(RF_SPACE);
}
}
delayMicroseconds(RF_PULSE_1 * 10);
}
}
//*****************************************************************************
// Measure battery voltage using internal bandgap voltage
//*****************************************************************************
byte ReadVcc()
{
int result;
bitSet(ADCSRA, ADEN); // switch Analog to Digital converter ON
ADMUX = 0x0C; // use VCC and internal bandgap (ATTiny85)
delayMicroseconds(250); // delay substantially improves accuracy
bitSet(ADCSRA, ADSC); // start conversion
while (bit_is_set(ADCSRA, ADSC)); // wait until ADSC is clear
bitClear(ADCSRA, ADEN); // Switch Analog to Digital converter OFF
result = ADCW;
return result ? VREF_35 / result : 0; // 35 = 3.5V
}
//*****************************************************************************
// DS18B20 Temperature Sensor and BH1750 light sensor support
//*****************************************************************************
byte GetPayload(int &temperature, int &light)
{
if (GetDS18B20(temperature) != 0) return 1;
if (GetBH1750(light) != 0) return 1;
return 0;
}
//*****************************************************************************
// DS18B20 Temperature
//*****************************************************************************
byte GetDS18B20(int &temperature)
{
byte msb, lsb;
int temp;
OneWire ds(DALLAS_PIN); // Setup a oneWire instance
ds.reset();
ds.skip();
ds.write(0x44); // Start conversion
Watchdog_delay(6); // Wait 750ms. Here 1 second
ds.reset(); // Read DS18B20
ds.skip();
ds.write(0xBE); // Read scratchpad
lsb = ds.read();
msb = ds.read();
ds.reset();
temp = (msb<< 8) | lsb;
temperature = ((((6 * temp) + temp / 4) + 5) / 10) * 10; // multiply by (100 * 0.0625) or 6.25 and round to tenth
return 0;
}
//*****************************************************************************
// BH1750 light
//*****************************************************************************
byte GetBH1750(int &light)
{
byte msb, lsb;
unsigned int value;
TinyWireM.beginTransmission(BH1750_ADDRESS); // Setup BH1750
TinyWireM.send(0x20); // One time high resolution low power
TinyWireM.endTransmission();
Watchdog_delay(4); // Wait 160-180ms. Here 250ms
TinyWireM.beginTransmission(BH1750_ADDRESS); // Read BH1750
TinyWireM.requestFrom(BH1750_ADDRESS, 2);
msb = TinyWireM.receive();
lsb = TinyWireM.receive();
value = (msb<<8 | lsb) / 1.2;
if (value > 0x7fff) value = 0x7fff;
light = int(value);
return 0;
}