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_P199_RF443_KaKu.ino
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_P199_RF443_KaKu.ino
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//#######################################################################################################
//#################################### Plugin 199: RF KaKu receiver/sender ##############################
//#######################################################################################################
// Purpose: Control Klik-Aan-Klik-Uit RF 433MHz devices directly from ESP Easy (receive and send)
// Status : "Proof of concept"
// Connect the RF Receiver data pin to the first pin selected in the webgui
// Connect the RF Transmitter data pin to the second pin selected in the webgui
// Events:
// newKaku_<address>#<Channel>=<state> (0=off, 1-15=dimvalue, 16=on)
// Kaku_<address>#<Channel>=<state> (0=off, 1=on)
// HE300EU_<address>#<Channel>=<state> (0=off, 1=on)
// Commands:
// newKakuSend <address>, <Channel>, <state/dim>
// KakuSend <address>, <Channel>, <state>
// This is a Work in Progress mini project!
// It has limited use because in most cases, your fancy Home Automation controller can handle 433MHz devices quite well using RFLink.
// It was implemented because in some cases i would like to have local "Klik-Aan-Klik-Uit" support using a standalone ESP Easy.
// (Just because i own quite a lot of these Kaku devices)
// Current state / limitations:
// Implemented send and receive support for KaKu with automatic code (no code wheel)
// Implemented send and receive support for old KaKu unit's with code wheels
// Implemented receive support for HomeEasy HE300EU remotes
// RF Sender and RF receiver each need their own antenna! (as opposed to using a transceiver)
#define MIN_PULSE_LENGTH 100 // Too short pulses are considered to be noise...
#define SIGNAL_TIMEOUT 5 // gap between transmissions
#define MIN_RAW_PULSES 32 // Minimum number of pulses to be received, otherwise considered to be noise...
#define RAW_BUFFER_SIZE 256
#define RAWSIGNAL_MULTIPLY 25
void RF_ISR() ICACHE_RAM_ATTR;
// We need our own rawsignal buffer here.
// During plugin rawsignal checks, the IRQ routine will alPlugin_199_ready be working on the next signal burst...
volatile byte Plugin_199_RFBuffer[RAW_BUFFER_SIZE];
volatile boolean Plugin_199_ready = false;
volatile byte Plugin_199_pulses[RAW_BUFFER_SIZE + 2];
volatile int Plugin_199_number;
unsigned long Plugin_199_codeHash;
unsigned long Plugin_199_lastTime;
unsigned long elapsed;
int8_t Plugin_199_RXpin = -1;
int8_t Plugin_199_TXpin = -1;
#define PLUGIN_199
#define PLUGIN_ID_199 199
#define PLUGIN_NAME_199 "RF Receiver/Sender"
#define PLUGIN_VALUENAME1_199 "Address"
#define PLUGIN_VALUENAME2_199 "Channel"
#define PLUGIN_VALUENAME3_199 "State"
boolean Plugin_199(byte function, struct EventStruct *event, String& string)
{
boolean success = false;
switch (function)
{
case PLUGIN_DEVICE_ADD:
{
Device[++deviceCount].Number = PLUGIN_ID_199;
Device[deviceCount].Type = DEVICE_TYPE_DUAL;
Device[deviceCount].VType = SENSOR_TYPE_DUAL;
Device[deviceCount].Ports = 0;
Device[deviceCount].PullUpOption = false;
Device[deviceCount].InverseLogicOption = false;
Device[deviceCount].FormulaOption = false;
Device[deviceCount].ValueCount = 3;
break;
}
case PLUGIN_GET_DEVICENAME:
{
string = F(PLUGIN_NAME_199);
break;
}
case PLUGIN_GET_DEVICEVALUENAMES:
{
strcpy_P(ExtraTaskSettings.TaskDeviceValueNames[0], PSTR(PLUGIN_VALUENAME1_199));
strcpy_P(ExtraTaskSettings.TaskDeviceValueNames[1], PSTR(PLUGIN_VALUENAME2_199));
strcpy_P(ExtraTaskSettings.TaskDeviceValueNames[2], PSTR(PLUGIN_VALUENAME3_199));
break;
}
case PLUGIN_INIT:
{
if (Settings.TaskDevicePin1[event->TaskIndex] != -1)
{
Plugin_199_RXpin = Settings.TaskDevicePin1[event->TaskIndex];
pinMode(Plugin_199_RXpin, INPUT_PULLUP);
attachInterrupt(Plugin_199_RXpin, RF_ISR, CHANGE);
success = true;
}
if (Settings.TaskDevicePin1[event->TaskIndex] != -1)
{
Plugin_199_TXpin = Settings.TaskDevicePin2[event->TaskIndex];
pinMode(Plugin_199_TXpin, OUTPUT);
}
break;
}
case PLUGIN_TEN_PER_SECOND:
{
if (Plugin_199_ready)
{
if (decodeNewKaku(event->BaseVarIndex));
else if (decodeKaku());
else if (decodeHE300EU());
Plugin_199_ready = false;
}
break;
}
case PLUGIN_WRITE:
{
String command = parseString(string, 1);
if (command == F("newkakusend"))
{
success = true;
sendNewKaku(event->Par1, event->Par2, event->Par3);
}
if (command == F("kakusend"))
{
success = true;
sendKaku(event->Par1, event->Par2, event->Par3);
}
break;
}
}
return success;
}
//********************************************************************************
// Interrupt handler for RF messages
//********************************************************************************
void RF_ISR()
{
static unsigned int counter = 0;
static unsigned long TimeStamp = 0;
unsigned long TimeElapsed = 0;
TimeElapsed = micros() - TimeStamp;
TimeStamp = micros();
if (TimeElapsed > MIN_PULSE_LENGTH && counter < RAW_BUFFER_SIZE)
{
counter++;
Plugin_199_RFBuffer[counter] = TimeElapsed / 25;
}
else
counter = 0;
if (TimeElapsed > (SIGNAL_TIMEOUT * 1000) )
{
if (counter > MIN_RAW_PULSES)
{
Plugin_199_number = counter;
// copy IRQ RF working buffer to RawSignal struct
for (unsigned int x = 0; x <= counter; x++)
Plugin_199_pulses[x] = Plugin_199_RFBuffer[x];
Plugin_199_ready = true;
counter = 0;
}
else
counter = 0;
}
if (counter >= RAW_BUFFER_SIZE)
counter = 0;
}
//********************************************************************************
// Transmit pulses using pulse array
//********************************************************************************
void RawSendRF(void)
{
if (Plugin_199_RXpin != -1)
detachInterrupt(Plugin_199_RXpin);
int x;
//digitalWrite(PIN_RF_RX_VCC,LOW); // Turn off RF receiver
//digitalWrite(PIN_RF_TX_VCC,HIGH); // Turn on RF sender
delay(5); // small delay between switching send/receive
Plugin_199_pulses[Plugin_199_number] = 1; // force last duration as 1 msec
for (byte y = 0; y < 7; y++) // repeats RF code
{
x = 1;
noInterrupts();
while (x < Plugin_199_number)
{
digitalWrite(Plugin_199_TXpin, HIGH);
delayMicroseconds(Plugin_199_pulses[x++] * 25 - 5);
digitalWrite(Plugin_199_TXpin, LOW);
delayMicroseconds(Plugin_199_pulses[x++] * 25 - 7);
}
interrupts();
delay(20);// Delay must run outside interrupt blocked code.
}
delay(5);
//digitalWrite(PIN_RF_TX_VCC,LOW); // turn off RF sender
//digitalWrite(PIN_RF_RX_VCC,HIGH); // turn on RF receiver
if (Plugin_199_RXpin != -1)
attachInterrupt(Plugin_199_RXpin, RF_ISR, CHANGE);
}
//********************************************************************************
// Decode NewKaku protocol (without code wheel)
//********************************************************************************
#define NewKAKU_RawSignalLength 132
#define NewKAKUdim_RawSignalLength 148
#define NewKAKU_1T 275 // us
#define NewKAKU_mT 650 // us
#define NewKAKU_4T 1100 // us
#define NewKAKU_8T 2200 // us
boolean decodeNewKaku(byte BaseVarIndex)
{
boolean success = false;
byte Par1 = 0;
unsigned long Par2 = 0;
unsigned long bitstream = 0L;
unsigned long address = 0L;
byte channel = 0;
byte command = 0;
boolean Bit;
int i;
int P0, P1, P2, P3;
Par1 = 0;
if (Plugin_199_number == NewKAKU_RawSignalLength || Plugin_199_number == NewKAKUdim_RawSignalLength)
{
i = 3; // Plugin_199_pulses[3] is de eerste van een T,xT,T,xT combinatie
do
{
P0 = Plugin_199_pulses[i] * 25;
P1 = Plugin_199_pulses[i + 1] * 25;
P2 = Plugin_199_pulses[i + 2] * 25;
P3 = Plugin_199_pulses[i + 3] * 25;
if (P0 < NewKAKU_mT && P1 < NewKAKU_mT && P2 < NewKAKU_mT && P3 > NewKAKU_mT)Bit = 0; // T,T,T,4T
else if (P0 < NewKAKU_mT && P1 > NewKAKU_mT && P2 < NewKAKU_mT && P3 < NewKAKU_mT)Bit = 1; // T,4T,T,T
else if (P0 < NewKAKU_mT && P1 < NewKAKU_mT && P2 < NewKAKU_mT && P3 < NewKAKU_mT) // T,T,T,T Deze hoort te zitten op i=111 want: 27e NewKAKU bit maal 4 plus 2 posities voor startbit
{
if (Plugin_199_number != NewKAKUdim_RawSignalLength) // als de dim-bits er niet zijn
return false;
}
else
return false; // andere mogelijkheden zijn niet geldig in NewKAKU signaal.
if (i < 130) // alle bits die tot de 32-bit pulstrein behoren 32bits * 4posities per bit + pulse/space voor startbit
bitstream = (bitstream << 1) | Bit;
else // de resterende vier bits die tot het dimlevel behoren
Par1 = (Par1 << 1) | Bit;
i += 4; // volgende pulsenquartet
} while (i < Plugin_199_number - 2); //-2 omdat de space/pulse van de stopbit geen deel meer van signaal uit maakt.
if (i > 140) // Commando en Dim deel
Par1++; // Dim level. +1 omdat gebruiker dim level begint bij één.
else
Par1 = ((bitstream >> 4) & 0x01) ? 16 : 0; // On/Off bit omzetten naar een Nodo waarde.
Par2 = bitstream;
address = bitstream >> 6;
channel = (bitstream & 0x0f) + 1;
command = (bitstream >> 4) & 0x03;
if (command > 1)
channel = 0;
// valid signal, remember timestamp to suppress repeats...
elapsed = millis() - Plugin_199_lastTime;
Plugin_199_lastTime = millis();
unsigned long codeHash = Par2 + Par1;
if (codeHash != Plugin_199_codeHash || (codeHash == Plugin_199_codeHash && elapsed > 250))
{
UserVar[BaseVarIndex] = address;
UserVar[BaseVarIndex + 1] = channel;
UserVar[BaseVarIndex + 2] = Par1;
String eventString = F("NewKaku_");
eventString += address;
eventString += F("#");
eventString += channel;
eventString += F("=");
eventString += Par1;
rulesProcessing(eventString);
success = true;
}
Plugin_199_codeHash = Par2 + Par1;
}
return success;
}
//********************************************************************************
// Send NewKaku protocol (without code wheel)
//********************************************************************************
void sendNewKaku(unsigned long address, byte channel, byte state)
{
unsigned long bitstream = 0L;
byte i = 1;
byte x; // aantal posities voor pulsen/spaces in RawSignal
bitstream = address << 6;
bitstream |= (channel - 1);
//RawSignal.Repeats = 7; // Aantal herhalingen van het signaal.
//RawSignal.Delay = 20; // Tussen iedere pulsenreeks enige tijd rust.
if (state == 16 || state == 0)
{
bitstream |= (state == 16) << 4; // bit-5 is het on/off commando in KAKU signaal
x = 130; // verzend startbit + 32-bits = 130
}
else
x = 146; // verzend startbit + 32-bits = 130 + 4dimbits = 146
// bitstream bevat nu de KAKU-bits die verzonden moeten worden.
for (i = 3; i <= x; i++)Plugin_199_pulses[i] = NewKAKU_1T / 25; // De meeste tijden in signaal zijn T. Vul alle pulstijden met deze waarde. Later worden de 4T waarden op hun plek gezet
i = 1;
Plugin_199_pulses[i++] = NewKAKU_1T / 25; //pulse van de startbit
Plugin_199_pulses[i++] = NewKAKU_8T / 25; //space na de startbit
byte y = 31; // bit uit de bitstream
while (i < x)
{
if ((bitstream >> (y--)) & 1)
Plugin_199_pulses[i + 1] = NewKAKU_4T / 25; // Bit=1; // T,4T,T,T
else
Plugin_199_pulses[i + 3] = NewKAKU_4T / 25; // Bit=0; // T,T,T,4T
if (x == 146) // als het een dim opdracht betreft
{
if (i == 111) // Plaats van de Commando-bit uit KAKU
Plugin_199_pulses[i + 3] = NewKAKU_1T / 25; // moet een T,T,T,T zijn bij een dim commando.
if (i == 127) // als alle pulsen van de 32-bits weggeschreven zijn
{
bitstream = (unsigned long)state; // nog vier extra dim-bits om te verzenden.
y = 3;
}
}
i += 4;
}
Plugin_199_pulses[i++] = NewKAKU_1T / 25; //pulse van de stopbit
Plugin_199_pulses[i] = 0; //space van de stopbit
Plugin_199_number = i; // aantal bits*2 die zich in het opgebouwde RawSignal bevinden
RawSendRF();
}
//********************************************************************************
// Decode Kaku protocol (with code wheel)
//********************************************************************************
#define KAKU_CodeLength 12
#define KAKU_T 350
boolean decodeKaku()
{
boolean success = false;
byte Par1 = 0;
unsigned long Par2 = 0;
int i, j;
unsigned long bitstream = 0;
if (Plugin_199_number != (KAKU_CodeLength * 4) + 2)return false; // conventionele KAKU bestaat altijd uit 12 data bits plus stop. Ongelijk, dan geen KAKU!
for (i = 0; i < KAKU_CodeLength; i++)
{
j = (KAKU_T * 2) / 25;
if (Plugin_199_pulses[4 * i + 1] < j && Plugin_199_pulses[4 * i + 2] > j && Plugin_199_pulses[4 * i + 3] < j && Plugin_199_pulses[4 * i + 4] > j) {
bitstream = (bitstream >> 1); // 0
}
else if (Plugin_199_pulses[4 * i + 1] < j && Plugin_199_pulses[4 * i + 2] > j && Plugin_199_pulses[4 * i + 3] > j && Plugin_199_pulses[4 * i + 4] < j) {
bitstream = (bitstream >> 1 | (1 << (KAKU_CodeLength - 1))); // 1
}
else if (Plugin_199_pulses[4 * i + 1] < j && Plugin_199_pulses[4 * i + 2] > j && Plugin_199_pulses[4 * i + 3] < j && Plugin_199_pulses[4 * i + 4] < j) {
bitstream = (bitstream >> 1); // Short 0, Groep commando op 2e bit.
Par1 = 2;
}
else {
return false; // foutief signaal
}
}
if ((bitstream & 0x600) == 0x600) // twee vaste bits van KAKU gebruiken als checksum
{ // Alles is in orde, bouw event op
Par2 = bitstream & 0xFF;
Par1 |= (bitstream >> 11) & 0x01;
// valid signal, remember timestamp to suppress repeats...
elapsed = millis() - Plugin_199_lastTime;
Plugin_199_lastTime = millis();
unsigned long codeHash = Par2 + Par1;
if (codeHash != Plugin_199_codeHash || (codeHash == Plugin_199_codeHash && elapsed > 250))
{
String eventString = F("Kaku_");
eventString += (Par2 & 0x0f) + 1;
eventString += F("#");
eventString += (Par2 >> 4) + 1;
eventString += F("=");
eventString += Par1;
rulesProcessing(eventString);
success = true;
}
Plugin_199_codeHash = Par2 + Par1;
}
return success;
}
//********************************************************************************
// Send Kaku protocol (with code wheel)
//********************************************************************************
void sendKaku(unsigned long address, byte channel, byte state)
{
byte Par1 = state;
unsigned long Par2 = ((channel-1) << 4) + address-1;
unsigned long Bitstream = Par2 | (0x600 | ((Par1 & 1 /*Commando*/) << 11)); // Stel een bitstream samen
// loop de 12-bits langs en vertaal naar pulse/space signalen.
for (byte i = 0; i < KAKU_CodeLength; i++)
{
Plugin_199_pulses[4 * i + 1] = KAKU_T / RAWSIGNAL_MULTIPLY;
Plugin_199_pulses[4 * i + 2] = (KAKU_T * 3) / RAWSIGNAL_MULTIPLY;
if (((Par1 >> 1) & 1) /* Groep */ && i >= 4 && i < 8)
{
Plugin_199_pulses[4 * i + 3] = KAKU_T / RAWSIGNAL_MULTIPLY;
Plugin_199_pulses[4 * i + 4] = KAKU_T / RAWSIGNAL_MULTIPLY;
} // short 0
else
{
if ((Bitstream >> i) & 1) // 1
{
Plugin_199_pulses[4 * i + 3] = (KAKU_T * 3) / RAWSIGNAL_MULTIPLY;
Plugin_199_pulses[4 * i + 4] = KAKU_T / RAWSIGNAL_MULTIPLY;
}
else //0
{
Plugin_199_pulses[4 * i + 3] = KAKU_T / RAWSIGNAL_MULTIPLY;
Plugin_199_pulses[4 * i + 4] = (KAKU_T * 3) / RAWSIGNAL_MULTIPLY;
}
}
// Stopbit
Plugin_199_pulses[4 * KAKU_CodeLength + 1] = KAKU_T / RAWSIGNAL_MULTIPLY;
Plugin_199_pulses[4 * KAKU_CodeLength + 2] = KAKU_T / RAWSIGNAL_MULTIPLY;
}
Plugin_199_number=KAKU_CodeLength*4+2;
RawSendRF();
}
//********************************************************************************
// Decode HomeEasy 3xx series EU protocol (without code wheel)
//********************************************************************************
boolean decodeHE300EU()
{
boolean success = false;
byte Par1 = 0;
unsigned long Par2 = 0;
unsigned long address = 0;
unsigned long bitstream = 0;
int counter = 0;
byte rfbit = 0;
byte state = 0;
unsigned long channel = 0;
// valid messages are 116 pulses
if (Plugin_199_number != 116) return false;
for (byte x = 1; x <= Plugin_199_number; x = x + 2)
{
if ((Plugin_199_pulses[x] * 25 < 500) & (Plugin_199_pulses[x + 1] * 25 > 500))
rfbit = 1;
else
rfbit = 0;
if ((x >= 23) && (x <= 86)) address = (address << 1) | rfbit;
if ((x >= 87) && (x <= 114)) bitstream = (bitstream << 1) | rfbit;
}
state = ((bitstream >> 8) & 0x3) - 1;
channel = (bitstream) & 0x3f;
Par1 = state;
Par2 = address + channel;
// valid signal, remember timestamp to suppress repeats...
elapsed = millis() - Plugin_199_lastTime;
Plugin_199_lastTime = millis();
unsigned long codeHash = Par2 + Par1;
if (codeHash != Plugin_199_codeHash || (codeHash == Plugin_199_codeHash && elapsed > 250))
{
String eventString = F("HE300EU_");
eventString += address;
eventString += F("#");
eventString += channel;
eventString += F("=");
eventString += Par1;
rulesProcessing(eventString);
success = true;
}
Plugin_199_codeHash = Par2 + Par1;
}
//********************************************************************************
// Decode generic protocol, deriving hash value
//********************************************************************************
boolean decodeUnknown()
{
boolean success = false;
byte Par1 = 0;
unsigned long Par2 = 0;
int x;
unsigned int MinPulse = 0xffff;
unsigned int MinSpace = 0xffff;
unsigned long CodeM = 0L;
unsigned long CodeS = 0L;
if (Plugin_199_number < MIN_RAW_PULSES) return false;
for (x = 5; x < Plugin_199_number - 2; x += 2)
{
if (Plugin_199_pulses[x] < MinPulse)MinPulse = Plugin_199_pulses[x];
if (Plugin_199_pulses[x + 1] < MinSpace)MinSpace = Plugin_199_pulses[x + 1];
}
MinPulse += (MinPulse * 100) / 100;
MinSpace += (MinSpace * 100) / 100;
// Data kan zowel in de mark als de space zitten. Daarom pakken we beide voor data opbouw.
for (x = 3; x <= Plugin_199_number; x += 2)
{
CodeM = (CodeM << 1) | (Plugin_199_pulses[x] > MinPulse);
CodeS = (CodeS << 1) | (Plugin_199_pulses[x + 1] > MinSpace);
}
// Data kan zowel in de mark als de space zitten. We nemen de grootste waarde voor de data.
if (CodeM > CodeS)
Par2 = CodeM;
else
Par2 = CodeS;
// valid signal, remember timestamp to suppress repeats...
elapsed = millis() - Plugin_199_lastTime;
Plugin_199_lastTime = millis();
unsigned long codeHash = Par2;
if (codeHash != Plugin_199_codeHash || (codeHash == Plugin_199_codeHash && elapsed > 250))
{
String eventString = F("UnknownRF_");
eventString += Par2;
rulesProcessing(eventString);
success = true;
}
Plugin_199_codeHash = Par2;
}