Helmut Tschemernjak
SX1276GenericLib to support sx1276 bassed LoRa modules, including HopeRF RFM95, Murata CMWX1ZZABZ and Semtech SX1276MB1MAS/SX1276MB1LAS modules
Dependents: DISCO-L072CZ-LRWAN1_LoRa_PingPong DISCO-L072CZ-LRWAN1_LoRa_PingPong DISCO-L072CZ-LRWAN1_LoRa_PingPong DISCO-L072CZ-LRWAN1_LoRa_USB_Rx ... more
sx1276/sx1276.cpp
- Committer:
- Helmut Tschemernjak
- Date:
- 2017-05-27
- Revision:
- 59:38e56c85fa44
- Parent:
- 58:113d2ef978d2
- Child:
- 62:835c5e20834e
File content as of revision 59:38e56c85fa44:
/*
/ _____) _ | |
( (____ _____ ____ _| |_ _____ ____| |__
\____ \| ___ | (_ _) ___ |/ ___) _ \
_____) ) ____| | | || |_| ____( (___| | | |
(______/|_____)_|_|_| \__)_____)\____)_| |_|
(C) 2014 Semtech
Description: Actual implementation of a SX1276 radio, inherits Radio
License: Revised BSD License, see LICENSE.TXT file include in the project
Maintainers: Miguel Luis, Gregory Cristian and Nicolas Huguenin
*/
/*
* additional development to make it more generic across multiple OS versions
* (c) 2017 Helmut Tschemernjak
* 30826 Garbsen (Hannover) Germany
*/
#include "sx1276.h"
const SX1276::BandwidthMap SX1276::FskBandwidths[] =
{
{ 2600 , 0x17 },
{ 3100 , 0x0F },
{ 3900 , 0x07 },
{ 5200 , 0x16 },
{ 6300 , 0x0E },
{ 7800 , 0x06 },
{ 10400 , 0x15 },
{ 12500 , 0x0D },
{ 15600 , 0x05 },
{ 20800 , 0x14 },
{ 25000 , 0x0C },
{ 31300 , 0x04 },
{ 41700 , 0x13 },
{ 50000 , 0x0B },
{ 62500 , 0x03 },
{ 83333 , 0x12 },
{ 100000, 0x0A },
{ 125000, 0x02 },
{ 166700, 0x11 },
{ 200000, 0x09 },
{ 250000, 0x01 },
{ 300000, 0x00 }, // Invalid Bandwidth
};
const SX1276::BandwidthMap SX1276::LoRaBandwidths[] =
{
{ 7800, 0 }, // 7.8 kHz requires TCXO
{ 10400, 1 }, // 10.4 kHz requires TCXO
{ 15600, 2 }, // 15.6 kHz requires TCXO
{ 20800, 3 }, // 20.8 kHz requires TCXO
{ 31200, 4 }, // 31.2 kHz requires TCXO
{ 41400, 5 }, // 41.4 kHz requires TCXO
{ 62500, 6 }, // 62.5 kHz requires TCXO
{ 125000, 7 }, // the LoRa protocol default
{ 250000, 8 },
{ 500000, 9 },
{ 0 , 10 }, // Invalid Bandwidth, reserved
};
/*!
* @brief Radio hardware registers initialization definition
*
* @remark Can be automatically generated by the SX1276 GUI (not yet implemented)
*/
const SX1276::RadioRegisters SX1276::RadioRegsInit[] = {
{ MODEM_FSK , REG_LNA , 0x23 },
{ MODEM_FSK , REG_RXCONFIG , 0x1E },
{ MODEM_FSK , REG_RSSICONFIG , 0xD2 },
{ MODEM_FSK , REG_AFCFEI , 0x01 },
{ MODEM_FSK , REG_PREAMBLEDETECT , 0xAA },
{ MODEM_FSK , REG_OSC , 0x07 },
{ MODEM_FSK , REG_SYNCCONFIG , 0x12 },
{ MODEM_FSK , REG_SYNCVALUE1 , 0xC1 },
{ MODEM_FSK , REG_SYNCVALUE2 , 0x94 },
{ MODEM_FSK , REG_SYNCVALUE3 , 0xC1 },
{ MODEM_FSK , REG_PACKETCONFIG1 , 0xD8 },
{ MODEM_FSK , REG_FIFOTHRESH , 0x8F },
{ MODEM_FSK , REG_IMAGECAL , 0x02 },
{ MODEM_FSK , REG_DIOMAPPING1 , 0x00 },
{ MODEM_FSK , REG_DIOMAPPING2 , 0x30 },
{ MODEM_LORA, REG_LR_PAYLOADMAXLENGTH, 0x40 },
};
SX1276::SX1276( RadioEvents_t *events) : Radio( events ), isRadioActive( false )
{
wait_ms( 10 );
this->rxtxBuffer = new uint8_t[RX_BUFFER_SIZE];
this->RadioEvents = events;
this->dioIrq = new DioIrqHandler[6];
this->dioIrq[0] = &SX1276::OnDio0Irq;
this->dioIrq[1] = &SX1276::OnDio1Irq;
this->dioIrq[2] = &SX1276::OnDio2Irq;
this->dioIrq[3] = &SX1276::OnDio3Irq;
this->dioIrq[4] = &SX1276::OnDio4Irq;
this->dioIrq[5] = NULL;
this->settings.State = RF_IDLE;
}
SX1276::~SX1276( )
{
delete this->rxtxBuffer;
delete this->dioIrq;
}
bool SX1276::Init( RadioEvents_t *events )
{
if (Read(REG_VERSION) == 0x00)
return false;
this->RadioEvents = events;
return true;
}
void SX1276::RadioRegistersInit( )
{
uint8_t i = 0;
for( i = 0; i < sizeof( RadioRegsInit ) / sizeof( RadioRegisters ); i++ )
{
SetModem( RadioRegsInit[i].Modem );
Write( RadioRegsInit[i].Addr, RadioRegsInit[i].Value );
}
}
RadioState SX1276::GetStatus( void )
{
return this->settings.State;
}
void SX1276::SetChannel( uint32_t freq )
{
this->settings.Channel = freq;
freq = ( uint32_t )( ( double )freq / ( double )FREQ_STEP );
Write( REG_FRFMSB, ( uint8_t )( ( freq >> 16 ) & 0xFF ) );
Write( REG_FRFMID, ( uint8_t )( ( freq >> 8 ) & 0xFF ) );
Write( REG_FRFLSB, ( uint8_t )( freq & 0xFF ) );
}
bool SX1276::IsChannelFree( RadioModems_t modem, uint32_t freq, int16_t rssiThresh )
{
int16_t rssi = 0;
SetModem( modem );
SetChannel( freq );
SetOpMode( RF_OPMODE_RECEIVER );
wait_ms( 1 );
rssi = GetRssi( modem );
Sleep( );
if( rssi > rssiThresh )
{
return false;
}
return true;
}
uint32_t SX1276::Random( void )
{
uint8_t i;
uint32_t rnd = 0;
/*
* Radio setup for random number generation
*/
// Set LoRa modem ON
SetModem( MODEM_LORA );
// Disable LoRa modem interrupts
Write( REG_LR_IRQFLAGSMASK, RFLR_IRQFLAGS_RXTIMEOUT |
RFLR_IRQFLAGS_RXDONE |
RFLR_IRQFLAGS_PAYLOADCRCERROR |
RFLR_IRQFLAGS_VALIDHEADER |
RFLR_IRQFLAGS_TXDONE |
RFLR_IRQFLAGS_CADDONE |
RFLR_IRQFLAGS_FHSSCHANGEDCHANNEL |
RFLR_IRQFLAGS_CADDETECTED );
// Set radio in continuous reception
SetOpMode( RF_OPMODE_RECEIVER );
for( i = 0; i < 32; i++ )
{
wait_ms( 1 );
// Unfiltered RSSI value reading. Only takes the LSB value
rnd |= ( ( uint32_t )Read( REG_LR_RSSIWIDEBAND ) & 0x01 ) << i;
}
Sleep( );
return rnd;
}
/*!
* Performs the Rx chain calibration for LF and HF bands
* \remark Must be called just after the reset so all registers are at their
* default values
*/
void SX1276::RxChainCalibration( void )
{
uint8_t regPaConfigInitVal;
uint32_t initialFreq;
// Save context
regPaConfigInitVal = this->Read( REG_PACONFIG );
initialFreq = ( double )( ( ( uint32_t )this->Read( REG_FRFMSB ) << 16 ) |
( ( uint32_t )this->Read( REG_FRFMID ) << 8 ) |
( ( uint32_t )this->Read( REG_FRFLSB ) ) ) * ( double )FREQ_STEP;
// Cut the PA just in case, RFO output, power = -1 dBm
this->Write( REG_PACONFIG, 0x00 );
// Launch Rx chain calibration for LF band
Write ( REG_IMAGECAL, ( Read( REG_IMAGECAL ) & RF_IMAGECAL_IMAGECAL_MASK ) | RF_IMAGECAL_IMAGECAL_START );
while( ( Read( REG_IMAGECAL ) & RF_IMAGECAL_IMAGECAL_RUNNING ) == RF_IMAGECAL_IMAGECAL_RUNNING )
{
}
// Sets a Frequency in HF band
SetChannel( 868000000 );
// Launch Rx chain calibration for HF band
Write ( REG_IMAGECAL, ( Read( REG_IMAGECAL ) & RF_IMAGECAL_IMAGECAL_MASK ) | RF_IMAGECAL_IMAGECAL_START );
while( ( Read( REG_IMAGECAL ) & RF_IMAGECAL_IMAGECAL_RUNNING ) == RF_IMAGECAL_IMAGECAL_RUNNING )
{
}
// Restore context
this->Write( REG_PACONFIG, regPaConfigInitVal );
SetChannel( initialFreq );
}
/*!
* Returns the known FSK bandwidth registers value
*
* \param [IN] bandwidth Bandwidth value in Hz
* \retval regValue Bandwidth register value.
*/
uint8_t SX1276::GetFskBandwidthRegValue( uint32_t bandwidth )
{
uint8_t i;
for( i = 0; i < ( sizeof( FskBandwidths ) / sizeof( BandwidthMap ) ) - 1; i++ )
{
if( ( bandwidth >= FskBandwidths[i].bandwidth ) && ( bandwidth < FskBandwidths[i + 1].bandwidth ) )
{
return FskBandwidths[i].RegValue;
}
}
// ERROR: Value not found
while( 1 );
}
/*!
* Returns the known LoRa bandwidth registers value
*
* \param [IN] bandwidth Bandwidth value in Hz
* \retval regValue Bandwidth register value.
*/
uint8_t SX1276::GetLoRaBandwidthRegValue( uint32_t bandwidth )
{
uint8_t i;
for( i = 0; i < ( sizeof( LoRaBandwidths ) / sizeof( BandwidthMap ) ) - 1; i++ )
{
if( ( bandwidth >= LoRaBandwidths[i].bandwidth ) && ( bandwidth < LoRaBandwidths[i + 1].bandwidth ) )
{
return LoRaBandwidths[i].RegValue;
}
}
// ERROR: Value not found
while( 1 );
}
void SX1276::SetRxConfig( RadioModems_t modem, uint32_t bandwidth,
uint32_t datarate, uint8_t coderate,
uint32_t bandwidthAfc, uint16_t preambleLen,
uint16_t symbTimeout, bool fixLen,
uint8_t payloadLen,
bool crcOn, bool freqHopOn, uint8_t hopPeriod,
bool iqInverted, bool rxContinuous )
{
SetModem( modem );
switch( modem )
{
case MODEM_FSK:
{
this->settings.Fsk.Bandwidth = bandwidth;
this->settings.Fsk.Datarate = datarate;
this->settings.Fsk.BandwidthAfc = bandwidthAfc;
this->settings.Fsk.FixLen = fixLen;
this->settings.Fsk.PayloadLen = payloadLen;
this->settings.Fsk.CrcOn = crcOn;
this->settings.Fsk.IqInverted = iqInverted;
this->settings.Fsk.RxContinuous = rxContinuous;
this->settings.Fsk.PreambleLen = preambleLen;
this->settings.Fsk.RxSingleTimeout = symbTimeout * ( ( 1.0 / ( double )datarate ) * 8.0 ) * 1e3;
datarate = ( uint16_t )( ( double )XTAL_FREQ / ( double )datarate );
Write( REG_BITRATEMSB, ( uint8_t )( datarate >> 8 ) );
Write( REG_BITRATELSB, ( uint8_t )( datarate & 0xFF ) );
Write( REG_RXBW, GetFskBandwidthRegValue( bandwidth ) );
Write( REG_AFCBW, GetFskBandwidthRegValue( bandwidthAfc ) );
Write( REG_PREAMBLEMSB, ( uint8_t )( ( preambleLen >> 8 ) & 0xFF ) );
Write( REG_PREAMBLELSB, ( uint8_t )( preambleLen & 0xFF ) );
if( fixLen == 1 )
{
Write( REG_PAYLOADLENGTH, payloadLen );
}
else
{
Write( REG_PAYLOADLENGTH, 0xFF ); // Set payload length to the maximum
}
Write( REG_PACKETCONFIG1,
( Read( REG_PACKETCONFIG1 ) &
RF_PACKETCONFIG1_CRC_MASK &
RF_PACKETCONFIG1_PACKETFORMAT_MASK ) |
( ( fixLen == 1 ) ? RF_PACKETCONFIG1_PACKETFORMAT_FIXED : RF_PACKETCONFIG1_PACKETFORMAT_VARIABLE ) |
( crcOn << 4 ) );
Write( REG_PACKETCONFIG2, ( Read( REG_PACKETCONFIG2 ) | RF_PACKETCONFIG2_DATAMODE_PACKET ) );
}
break;
case MODEM_LORA:
{
if (bandwidth > 11) // specified in Hz, needs mapping
bandwidth = GetLoRaBandwidthRegValue(bandwidth);
if( bandwidth > LORA_BANKWIDTH_500kHz )
{
// Fatal error: When using LoRa modem only bandwidths 125, 250 and 500 kHz are supported
while( 1 );
}
this->settings.LoRa.Bandwidth = bandwidth;
this->settings.LoRa.Datarate = datarate;
this->settings.LoRa.Coderate = coderate;
this->settings.LoRa.PreambleLen = preambleLen;
this->settings.LoRa.FixLen = fixLen;
this->settings.LoRa.PayloadLen = payloadLen;
this->settings.LoRa.CrcOn = crcOn;
this->settings.LoRa.FreqHopOn = freqHopOn;
this->settings.LoRa.HopPeriod = hopPeriod;
this->settings.LoRa.IqInverted = iqInverted;
this->settings.LoRa.RxContinuous = rxContinuous;
if( datarate > LORA_SF12 )
{
datarate = LORA_SF12;
}
else if( datarate < LORA_SF6 )
{
datarate = LORA_SF6;
}
if( ( ( bandwidth == LORA_BANKWIDTH_125kHz ) && ( ( datarate == LORA_SF11 ) || ( datarate == LORA_SF12 ) ) ) ||
( ( bandwidth == LORA_BANKWIDTH_250kHz ) && ( datarate == LORA_SF12 ) ) )
{
this->settings.LoRa.LowDatarateOptimize = 0x01;
}
else
{
this->settings.LoRa.LowDatarateOptimize = 0x00;
}
Write( REG_LR_MODEMCONFIG1,
( Read( REG_LR_MODEMCONFIG1 ) &
RFLR_MODEMCONFIG1_BW_MASK &
RFLR_MODEMCONFIG1_CODINGRATE_MASK &
RFLR_MODEMCONFIG1_IMPLICITHEADER_MASK ) |
( bandwidth << 4 ) | ( coderate << 1 ) |
fixLen );
Write( REG_LR_MODEMCONFIG2,
( Read( REG_LR_MODEMCONFIG2 ) &
RFLR_MODEMCONFIG2_SF_MASK &
RFLR_MODEMCONFIG2_RXPAYLOADCRC_MASK &
RFLR_MODEMCONFIG2_SYMBTIMEOUTMSB_MASK ) |
( datarate << 4 ) | ( crcOn << 2 ) |
( ( symbTimeout >> 8 ) & ~RFLR_MODEMCONFIG2_SYMBTIMEOUTMSB_MASK ) );
Write( REG_LR_MODEMCONFIG3,
( Read( REG_LR_MODEMCONFIG3 ) &
RFLR_MODEMCONFIG3_LOWDATARATEOPTIMIZE_MASK ) |
( this->settings.LoRa.LowDatarateOptimize << 3 ) );
Write( REG_LR_SYMBTIMEOUTLSB, ( uint8_t )( symbTimeout & 0xFF ) );
Write( REG_LR_PREAMBLEMSB, ( uint8_t )( ( preambleLen >> 8 ) & 0xFF ) );
Write( REG_LR_PREAMBLELSB, ( uint8_t )( preambleLen & 0xFF ) );
if( fixLen == 1 )
{
Write( REG_LR_PAYLOADLENGTH, payloadLen );
}
if( this->settings.LoRa.FreqHopOn == true )
{
Write( REG_LR_PLLHOP, ( Read( REG_LR_PLLHOP ) & RFLR_PLLHOP_FASTHOP_MASK ) | RFLR_PLLHOP_FASTHOP_ON );
Write( REG_LR_HOPPERIOD, this->settings.LoRa.HopPeriod );
}
if( ( bandwidth == LORA_BANKWIDTH_500kHz ) && ( this->settings.Channel > RF_MID_BAND_THRESH ) )
{
// ERRATA 2.1 - Sensitivity Optimization with a 500 kHz Bandwidth
Write( REG_LR_TEST36, 0x02 );
Write( REG_LR_TEST3A, 0x64 );
}
else if( bandwidth == LORA_BANKWIDTH_500kHz )
{
// ERRATA 2.1 - Sensitivity Optimization with a 500 kHz Bandwidth
Write( REG_LR_TEST36, 0x02 );
Write( REG_LR_TEST3A, 0x7F );
}
else
{
// ERRATA 2.1 - Sensitivity Optimization with a 500 kHz Bandwidth
Write( REG_LR_TEST36, 0x03 );
}
if( datarate == LORA_SF6 )
{
Write( REG_LR_DETECTOPTIMIZE,
( Read( REG_LR_DETECTOPTIMIZE ) &
RFLR_DETECTIONOPTIMIZE_MASK ) |
RFLR_DETECTIONOPTIMIZE_SF6 );
Write( REG_LR_DETECTIONTHRESHOLD,
RFLR_DETECTIONTHRESH_SF6 );
}
else
{
Write( REG_LR_DETECTOPTIMIZE,
( Read( REG_LR_DETECTOPTIMIZE ) &
RFLR_DETECTIONOPTIMIZE_MASK ) |
RFLR_DETECTIONOPTIMIZE_SF7_TO_SF12 );
Write( REG_LR_DETECTIONTHRESHOLD,
RFLR_DETECTIONTHRESH_SF7_TO_SF12 );
}
}
break;
}
}
void SX1276::SetTxConfig( RadioModems_t modem, int8_t power, uint32_t fdev,
uint32_t bandwidth, uint32_t datarate,
uint8_t coderate, uint16_t preambleLen,
bool fixLen, bool crcOn, bool freqHopOn,
uint8_t hopPeriod, bool iqInverted, uint32_t timeout )
{
SetModem( modem );
SetRfTxPower( power );
switch( modem )
{
case MODEM_FSK:
{
this->settings.Fsk.Power = power;
this->settings.Fsk.Fdev = fdev;
this->settings.Fsk.Bandwidth = bandwidth;
this->settings.Fsk.Datarate = datarate;
this->settings.Fsk.PreambleLen = preambleLen;
this->settings.Fsk.FixLen = fixLen;
this->settings.Fsk.CrcOn = crcOn;
this->settings.Fsk.IqInverted = iqInverted;
this->settings.Fsk.TxTimeout = timeout;
fdev = ( uint16_t )( ( double )fdev / ( double )FREQ_STEP );
Write( REG_FDEVMSB, ( uint8_t )( fdev >> 8 ) );
Write( REG_FDEVLSB, ( uint8_t )( fdev & 0xFF ) );
datarate = ( uint16_t )( ( double )XTAL_FREQ / ( double )datarate );
Write( REG_BITRATEMSB, ( uint8_t )( datarate >> 8 ) );
Write( REG_BITRATELSB, ( uint8_t )( datarate & 0xFF ) );
Write( REG_PREAMBLEMSB, ( preambleLen >> 8 ) & 0x00FF );
Write( REG_PREAMBLELSB, preambleLen & 0xFF );
Write( REG_PACKETCONFIG1,
( Read( REG_PACKETCONFIG1 ) &
RF_PACKETCONFIG1_CRC_MASK &
RF_PACKETCONFIG1_PACKETFORMAT_MASK ) |
( ( fixLen == 1 ) ? RF_PACKETCONFIG1_PACKETFORMAT_FIXED : RF_PACKETCONFIG1_PACKETFORMAT_VARIABLE ) |
( crcOn << 4 ) );
Write( REG_PACKETCONFIG2, ( Read( REG_PACKETCONFIG2 ) | RF_PACKETCONFIG2_DATAMODE_PACKET ) );
}
break;
case MODEM_LORA:
{
this->settings.LoRa.Power = power;
if (bandwidth > 11) // specified in Hz, needs mapping
bandwidth = GetLoRaBandwidthRegValue(bandwidth);
if( bandwidth > LORA_BANKWIDTH_500kHz )
{
// Fatal error: When using LoRa modem only bandwidths 125, 250 and 500 kHz are supported
while( 1 );
}
this->settings.LoRa.Bandwidth = bandwidth;
this->settings.LoRa.Datarate = datarate;
this->settings.LoRa.Coderate = coderate;
this->settings.LoRa.PreambleLen = preambleLen;
this->settings.LoRa.FixLen = fixLen;
this->settings.LoRa.FreqHopOn = freqHopOn;
this->settings.LoRa.HopPeriod = hopPeriod;
this->settings.LoRa.CrcOn = crcOn;
this->settings.LoRa.IqInverted = iqInverted;
this->settings.LoRa.TxTimeout = timeout;
if( datarate > LORA_SF12 )
{
datarate = LORA_SF12;
}
else if( datarate < LORA_SF6 )
{
datarate = LORA_SF6;
}
if( ( ( bandwidth == LORA_BANKWIDTH_125kHz ) && ( ( datarate == LORA_SF11 ) || ( datarate == LORA_SF12 ) ) ) ||
( ( bandwidth == LORA_BANKWIDTH_250kHz ) && ( datarate == LORA_SF12 ) ) )
{
this->settings.LoRa.LowDatarateOptimize = 0x01;
}
else
{
this->settings.LoRa.LowDatarateOptimize = 0x00;
}
if( this->settings.LoRa.FreqHopOn == true )
{
Write( REG_LR_PLLHOP, ( Read( REG_LR_PLLHOP ) & RFLR_PLLHOP_FASTHOP_MASK ) | RFLR_PLLHOP_FASTHOP_ON );
Write( REG_LR_HOPPERIOD, this->settings.LoRa.HopPeriod );
}
Write( REG_LR_MODEMCONFIG1,
( Read( REG_LR_MODEMCONFIG1 ) &
RFLR_MODEMCONFIG1_BW_MASK &
RFLR_MODEMCONFIG1_CODINGRATE_MASK &
RFLR_MODEMCONFIG1_IMPLICITHEADER_MASK ) |
( bandwidth << 4 ) | ( coderate << 1 ) |
fixLen );
Write( REG_LR_MODEMCONFIG2,
( Read( REG_LR_MODEMCONFIG2 ) &
RFLR_MODEMCONFIG2_SF_MASK &
RFLR_MODEMCONFIG2_RXPAYLOADCRC_MASK ) |
( datarate << 4 ) | ( crcOn << 2 ) );
Write( REG_LR_MODEMCONFIG3,
( Read( REG_LR_MODEMCONFIG3 ) &
RFLR_MODEMCONFIG3_LOWDATARATEOPTIMIZE_MASK ) |
( this->settings.LoRa.LowDatarateOptimize << 3 ) );
Write( REG_LR_PREAMBLEMSB, ( preambleLen >> 8 ) & 0x00FF );
Write( REG_LR_PREAMBLELSB, preambleLen & 0xFF );
if( datarate == LORA_SF6 )
{
Write( REG_LR_DETECTOPTIMIZE,
( Read( REG_LR_DETECTOPTIMIZE ) &
RFLR_DETECTIONOPTIMIZE_MASK ) |
RFLR_DETECTIONOPTIMIZE_SF6 );
Write( REG_LR_DETECTIONTHRESHOLD,
RFLR_DETECTIONTHRESH_SF6 );
}
else
{
Write( REG_LR_DETECTOPTIMIZE,
( Read( REG_LR_DETECTOPTIMIZE ) &
RFLR_DETECTIONOPTIMIZE_MASK ) |
RFLR_DETECTIONOPTIMIZE_SF7_TO_SF12 );
Write( REG_LR_DETECTIONTHRESHOLD,
RFLR_DETECTIONTHRESH_SF7_TO_SF12 );
}
}
break;
}
}
uint32_t SX1276::TimeOnAir( RadioModems_t modem, int16_t pktLen )
{
uint32_t airTime = 0;
switch( modem )
{
case MODEM_FSK:
{
airTime = rint( ( 8 * ( this->settings.Fsk.PreambleLen +
( ( Read( REG_SYNCCONFIG ) & ~RF_SYNCCONFIG_SYNCSIZE_MASK ) + 1 ) +
( ( this->settings.Fsk.FixLen == 0x01 ) ? 0.0 : 1.0 ) +
( ( ( Read( REG_PACKETCONFIG1 ) & ~RF_PACKETCONFIG1_ADDRSFILTERING_MASK ) != 0x00 ) ? 1.0 : 0 ) +
pktLen +
( ( this->settings.Fsk.CrcOn == 0x01 ) ? 2.0 : 0 ) ) /
this->settings.Fsk.Datarate ) * 1e3 );
}
break;
case MODEM_LORA:
{
double bw = 0.0;
// REMARK: When using LoRa modem only bandwidths 125, 250 and 500 kHz are supported
switch( this->settings.LoRa.Bandwidth )
{
case LORA_BANKWIDTH_7kHz: // 7.8 kHz
bw = 78e2;
break;
case LORA_BANKWIDTH_10kHz: // 10.4 kHz
bw = 104e2;
break;
case LORA_BANKWIDTH_15kHz: // 15.6 kHz
bw = 156e2;
break;
case LORA_BANKWIDTH_20kHz: // 20.8 kHz
bw = 208e2;
break;
case LORA_BANKWIDTH_31kHz: // 31.2 kHz
bw = 312e2;
break;
case LORA_BANKWIDTH_41kHz: // 41.4 kHz
bw = 414e2;
break;
case LORA_BANKWIDTH_62kHz: // 62.5 kHz
bw = 625e2;
break;
case LORA_BANKWIDTH_125kHz: // 125 kHz
bw = 125e3;
break;
case LORA_BANKWIDTH_250kHz: // 250 kHz
bw = 250e3;
break;
case LORA_BANKWIDTH_500kHz: // 500 kHz
bw = 500e3;
break;
}
// Symbol rate : time for one symbol (secs)
double rs = bw / ( 1 << this->settings.LoRa.Datarate );
double ts = 1 / rs;
// time of preamble
double tPreamble = ( this->settings.LoRa.PreambleLen + 4.25 ) * ts;
// Symbol length of payload and time
double tmp = ceil( ( 8 * pktLen - 4 * this->settings.LoRa.Datarate +
28 + 16 * this->settings.LoRa.CrcOn -
( this->settings.LoRa.FixLen ? 20 : 0 ) ) /
( double )( 4 * ( this->settings.LoRa.Datarate -
( ( this->settings.LoRa.LowDatarateOptimize > 0 ) ? 2 : 0 ) ) ) ) *
( this->settings.LoRa.Coderate + 4 );
double nPayload = 8 + ( ( tmp > 0 ) ? tmp : 0 );
double tPayload = nPayload * ts;
// Time on air
double tOnAir = tPreamble + tPayload;
// return ms secs
airTime = floor( tOnAir * 1e3 + 0.999 );
}
break;
}
return airTime;
}
void SX1276::Send( void *buffer, int16_t size, void *header, int16_t hsize )
{
uint32_t txTimeout = 0;
switch( this->settings.Modem )
{
case MODEM_FSK:
{
this->settings.FskPacketHandler.NbBytes = 0;
this->settings.FskPacketHandler.Size = size + hsize;
if( this->settings.Fsk.FixLen == false )
{
uint8_t tmpsize = size + hsize;
WriteFifo( ( uint8_t* )&tmpsize, 1 );
}
else
{
Write( REG_PAYLOADLENGTH, size + hsize);
}
if( ( size + hsize > 0 ) && ( size + hsize <= 64 ) )
{
this->settings.FskPacketHandler.ChunkSize = size + hsize;
}
else
{
if (header) {
WriteFifo( header, hsize );
memcpy( rxtxBuffer, header, hsize );
}
memcpy( rxtxBuffer+hsize, (uint8_t *)buffer+hsize, size );
this->settings.FskPacketHandler.ChunkSize = 32;
}
// Write payload buffer
if (header)
WriteFifo( header, hsize );
WriteFifo( buffer, this->settings.FskPacketHandler.ChunkSize );
this->settings.FskPacketHandler.NbBytes += this->settings.FskPacketHandler.ChunkSize;
txTimeout = this->settings.Fsk.TxTimeout;
}
break;
case MODEM_LORA:
{
if( this->settings.LoRa.IqInverted == true )
{
Write( REG_LR_INVERTIQ, ( ( Read( REG_LR_INVERTIQ ) & RFLR_INVERTIQ_TX_MASK & RFLR_INVERTIQ_RX_MASK ) | RFLR_INVERTIQ_RX_OFF | RFLR_INVERTIQ_TX_ON ) );
Write( REG_LR_INVERTIQ2, RFLR_INVERTIQ2_ON );
}
else
{
Write( REG_LR_INVERTIQ, ( ( Read( REG_LR_INVERTIQ ) & RFLR_INVERTIQ_TX_MASK & RFLR_INVERTIQ_RX_MASK ) | RFLR_INVERTIQ_RX_OFF | RFLR_INVERTIQ_TX_OFF ) );
Write( REG_LR_INVERTIQ2, RFLR_INVERTIQ2_OFF );
}
this->settings.LoRaPacketHandler.Size = size + hsize;
// Initializes the payload size
Write( REG_LR_PAYLOADLENGTH, size + hsize);
// Full buffer used for Tx
Write( REG_LR_FIFOTXBASEADDR, 0 );
Write( REG_LR_FIFOADDRPTR, 0 );
// FIFO operations can not take place in Sleep mode
if( ( Read( REG_OPMODE ) & ~RF_OPMODE_MASK ) == RF_OPMODE_SLEEP )
{
Standby( );
wait_ms( 1 );
}
// Write payload buffer
if (header)
WriteFifo( header, hsize );
WriteFifo( buffer, size );
txTimeout = this->settings.LoRa.TxTimeout;
}
break;
}
Tx( txTimeout );
}
void SX1276::Sleep( void )
{
SetTimeout(TXTimeoutTimer, NULL);
SetTimeout(RXTimeoutTimer, NULL);
SetOpMode( RF_OPMODE_SLEEP );
this->settings.State = RF_IDLE;
}
void SX1276::Standby( void )
{
SetTimeout(TXTimeoutTimer, NULL);
SetTimeout(RXTimeoutTimer, NULL);
SetOpMode( RF_OPMODE_STANDBY );
this->settings.State = RF_IDLE;
}
void SX1276::Rx( uint32_t timeout )
{
bool rxContinuous = false;
switch( this->settings.Modem )
{
case MODEM_FSK:
{
rxContinuous = this->settings.Fsk.RxContinuous;
// DIO0=PayloadReady
// DIO1=FifoLevel
// DIO2=SyncAddr
// DIO3=FifoEmpty
// DIO4=Preamble
// DIO5=ModeReady
Write( REG_DIOMAPPING1, ( Read( REG_DIOMAPPING1 ) & RF_DIOMAPPING1_DIO0_MASK &
RF_DIOMAPPING1_DIO1_MASK &
RF_DIOMAPPING1_DIO2_MASK ) |
RF_DIOMAPPING1_DIO0_00 |
RF_DIOMAPPING1_DIO1_00 |
RF_DIOMAPPING1_DIO2_11 );
Write( REG_DIOMAPPING2, ( Read( REG_DIOMAPPING2 ) & RF_DIOMAPPING2_DIO4_MASK &
RF_DIOMAPPING2_MAP_MASK ) |
RF_DIOMAPPING2_DIO4_11 |
RF_DIOMAPPING2_MAP_PREAMBLEDETECT );
this->settings.FskPacketHandler.FifoThresh = Read( REG_FIFOTHRESH ) & 0x3F;
Write( REG_RXCONFIG, RF_RXCONFIG_AFCAUTO_ON | RF_RXCONFIG_AGCAUTO_ON | RF_RXCONFIG_RXTRIGER_PREAMBLEDETECT );
this->settings.FskPacketHandler.PreambleDetected = false;
this->settings.FskPacketHandler.SyncWordDetected = false;
this->settings.FskPacketHandler.NbBytes = 0;
this->settings.FskPacketHandler.Size = 0;
}
break;
case MODEM_LORA:
{
if( this->settings.LoRa.IqInverted == true )
{
Write( REG_LR_INVERTIQ, ( ( Read( REG_LR_INVERTIQ ) & RFLR_INVERTIQ_TX_MASK & RFLR_INVERTIQ_RX_MASK ) | RFLR_INVERTIQ_RX_ON | RFLR_INVERTIQ_TX_OFF ) );
Write( REG_LR_INVERTIQ2, RFLR_INVERTIQ2_ON );
}
else
{
Write( REG_LR_INVERTIQ, ( ( Read( REG_LR_INVERTIQ ) & RFLR_INVERTIQ_TX_MASK & RFLR_INVERTIQ_RX_MASK ) | RFLR_INVERTIQ_RX_OFF | RFLR_INVERTIQ_TX_OFF ) );
Write( REG_LR_INVERTIQ2, RFLR_INVERTIQ2_OFF );
}
// ERRATA 2.3 - Receiver Spurious Reception of a LoRa Signal
if( this->settings.LoRa.Bandwidth < LORA_BANKWIDTH_500kHz )
{
Write( REG_LR_DETECTOPTIMIZE, Read( REG_LR_DETECTOPTIMIZE ) & 0x7F );
Write( REG_LR_TEST30, 0x00 );
switch( this->settings.LoRa.Bandwidth )
{
case LORA_BANKWIDTH_7kHz: // 7.8 kHz
Write( REG_LR_TEST2F, 0x48 );
SetChannel(this->settings.Channel + 7.81e3 );
break;
case LORA_BANKWIDTH_10kHz: // 10.4 kHz
Write( REG_LR_TEST2F, 0x44 );
SetChannel(this->settings.Channel + 10.42e3 );
break;
case LORA_BANKWIDTH_15kHz: // 15.6 kHz
Write( REG_LR_TEST2F, 0x44 );
SetChannel(this->settings.Channel + 15.62e3 );
break;
case LORA_BANKWIDTH_20kHz: // 20.8 kHz
Write( REG_LR_TEST2F, 0x44 );
SetChannel(this->settings.Channel + 20.83e3 );
break;
case LORA_BANKWIDTH_31kHz: // 31.2 kHz
Write( REG_LR_TEST2F, 0x44 );
SetChannel(this->settings.Channel + 31.25e3 );
break;
case LORA_BANKWIDTH_41kHz: // 41.4 kHz
Write( REG_LR_TEST2F, 0x44 );
SetChannel(this->settings.Channel + 41.67e3 );
break;
case LORA_BANKWIDTH_62kHz: // 62.5 kHz
Write( REG_LR_TEST2F, 0x40 );
break;
case LORA_BANKWIDTH_125kHz: // 125 kHz
Write( REG_LR_TEST2F, 0x40 );
break;
case LORA_BANKWIDTH_250kHz: // 250 kHz
Write( REG_LR_TEST2F, 0x40 );
break;
}
}
else
{
Write( REG_LR_DETECTOPTIMIZE, Read( REG_LR_DETECTOPTIMIZE ) | 0x80 );
}
rxContinuous = this->settings.LoRa.RxContinuous;
if( this->settings.LoRa.FreqHopOn == true )
{
Write( REG_LR_IRQFLAGSMASK, //RFLR_IRQFLAGS_RXTIMEOUT |
//RFLR_IRQFLAGS_RXDONE |
//RFLR_IRQFLAGS_PAYLOADCRCERROR |
RFLR_IRQFLAGS_VALIDHEADER |
RFLR_IRQFLAGS_TXDONE |
RFLR_IRQFLAGS_CADDONE |
//RFLR_IRQFLAGS_FHSSCHANGEDCHANNEL |
RFLR_IRQFLAGS_CADDETECTED );
// DIO0=RxDone, DIO2=FhssChangeChannel
Write( REG_DIOMAPPING1, ( Read( REG_DIOMAPPING1 ) & RFLR_DIOMAPPING1_DIO0_MASK & RFLR_DIOMAPPING1_DIO2_MASK ) | RFLR_DIOMAPPING1_DIO0_00 | RFLR_DIOMAPPING1_DIO2_00 );
}
else
{
Write( REG_LR_IRQFLAGSMASK, //RFLR_IRQFLAGS_RXTIMEOUT |
//RFLR_IRQFLAGS_RXDONE |
//RFLR_IRQFLAGS_PAYLOADCRCERROR |
RFLR_IRQFLAGS_VALIDHEADER |
RFLR_IRQFLAGS_TXDONE |
RFLR_IRQFLAGS_CADDONE |
RFLR_IRQFLAGS_FHSSCHANGEDCHANNEL |
RFLR_IRQFLAGS_CADDETECTED );
// DIO0=RxDone
Write( REG_DIOMAPPING1, ( Read( REG_DIOMAPPING1 ) & RFLR_DIOMAPPING1_DIO0_MASK ) | RFLR_DIOMAPPING1_DIO0_00 );
}
Write( REG_LR_FIFORXBASEADDR, 0 );
Write( REG_LR_FIFOADDRPTR, 0 );
}
break;
}
this->settings.State = RF_RX_RUNNING;
if( timeout != 0 )
{
SetTimeout(RXTimeoutTimer, &SX1276::OnTimeoutIrq, timeout * 1e3);
}
if( this->settings.Modem == MODEM_FSK )
{
SetOpMode( RF_OPMODE_RECEIVER );
if( rxContinuous == false )
{
SetTimeout(RXTimeoutSyncWordTimer, &SX1276::OnTimeoutIrq, this->settings.Fsk.RxSingleTimeout * 1e3);
}
}
else
{
if( rxContinuous == true )
{
SetOpMode( RFLR_OPMODE_RECEIVER );
}
else
{
SetOpMode( RFLR_OPMODE_RECEIVER_SINGLE );
}
}
}
bool SX1276::RxSignalPending()
{
if (this->settings.State != RF_RX_RUNNING)
return false;
switch( this->settings.Modem )
{
case MODEM_FSK:
break;
case MODEM_LORA:
if (Read(REG_LR_MODEMSTAT) & RFLR_MODEMSTAT_SIGNAL_DETECTED)
return true;
break;
}
return false;
}
void SX1276::Tx( uint32_t timeout )
{
switch( this->settings.Modem )
{
case MODEM_FSK:
{
// DIO0=PacketSent
// DIO1=FifoEmpty
// DIO2=FifoFull
// DIO3=FifoEmpty
// DIO4=LowBat
// DIO5=ModeReady
Write( REG_DIOMAPPING1, ( Read( REG_DIOMAPPING1 ) & RF_DIOMAPPING1_DIO0_MASK &
RF_DIOMAPPING1_DIO1_MASK &
RF_DIOMAPPING1_DIO2_MASK ) |
RF_DIOMAPPING1_DIO1_01 );
Write( REG_DIOMAPPING2, ( Read( REG_DIOMAPPING2 ) & RF_DIOMAPPING2_DIO4_MASK &
RF_DIOMAPPING2_MAP_MASK ) );
this->settings.FskPacketHandler.FifoThresh = Read( REG_FIFOTHRESH ) & 0x3F;
}
break;
case MODEM_LORA:
{
if( this->settings.LoRa.FreqHopOn == true )
{
Write( REG_LR_IRQFLAGSMASK, RFLR_IRQFLAGS_RXTIMEOUT |
RFLR_IRQFLAGS_RXDONE |
RFLR_IRQFLAGS_PAYLOADCRCERROR |
RFLR_IRQFLAGS_VALIDHEADER |
//RFLR_IRQFLAGS_TXDONE |
RFLR_IRQFLAGS_CADDONE |
//RFLR_IRQFLAGS_FHSSCHANGEDCHANNEL |
RFLR_IRQFLAGS_CADDETECTED );
// DIO0=TxDone, DIO2=FhssChangeChannel
Write( REG_DIOMAPPING1, ( Read( REG_DIOMAPPING1 ) & RFLR_DIOMAPPING1_DIO0_MASK & RFLR_DIOMAPPING1_DIO2_MASK ) | RFLR_DIOMAPPING1_DIO0_01 | RFLR_DIOMAPPING1_DIO2_00 );
}
else
{
Write( REG_LR_IRQFLAGSMASK, RFLR_IRQFLAGS_RXTIMEOUT |
RFLR_IRQFLAGS_RXDONE |
RFLR_IRQFLAGS_PAYLOADCRCERROR |
RFLR_IRQFLAGS_VALIDHEADER |
//RFLR_IRQFLAGS_TXDONE |
RFLR_IRQFLAGS_CADDONE |
RFLR_IRQFLAGS_FHSSCHANGEDCHANNEL |
RFLR_IRQFLAGS_CADDETECTED );
// DIO0=TxDone
Write( REG_DIOMAPPING1, ( Read( REG_DIOMAPPING1 ) & RFLR_DIOMAPPING1_DIO0_MASK ) | RFLR_DIOMAPPING1_DIO0_01 );
}
}
break;
}
this->settings.State = RF_TX_RUNNING;
SetTimeout(TXTimeoutTimer, &SX1276::OnTimeoutIrq, timeout * 1e3);
SetOpMode( RF_OPMODE_TRANSMITTER );
}
void SX1276::StartCad( void )
{
switch( this->settings.Modem )
{
case MODEM_FSK:
{
}
break;
case MODEM_LORA:
{
Write( REG_LR_IRQFLAGSMASK, RFLR_IRQFLAGS_RXTIMEOUT |
RFLR_IRQFLAGS_RXDONE |
RFLR_IRQFLAGS_PAYLOADCRCERROR |
RFLR_IRQFLAGS_VALIDHEADER |
RFLR_IRQFLAGS_TXDONE |
//RFLR_IRQFLAGS_CADDONE |
RFLR_IRQFLAGS_FHSSCHANGEDCHANNEL // |
//RFLR_IRQFLAGS_CADDETECTED
);
// DIO3=CADDone
Write( REG_DIOMAPPING1, ( Read( REG_DIOMAPPING1 ) & RFLR_DIOMAPPING1_DIO3_MASK ) | RFLR_DIOMAPPING1_DIO3_00 );
this->settings.State = RF_CAD;
SetOpMode( RFLR_OPMODE_CAD );
}
break;
default:
break;
}
}
void SX1276::SetTxContinuousWave( uint32_t freq, int8_t power, uint16_t time )
{
uint32_t timeout = ( uint32_t )( time * 1e6 );
SetChannel( freq );
SetTxConfig( MODEM_FSK, power, 0, 0, 4800, 0, 5, false, false, 0, 0, 0, timeout );
Write( REG_PACKETCONFIG2, ( Read( REG_PACKETCONFIG2 ) & RF_PACKETCONFIG2_DATAMODE_MASK ) );
// Disable radio interrupts
Write( REG_DIOMAPPING1, RF_DIOMAPPING1_DIO0_11 | RF_DIOMAPPING1_DIO1_11 );
Write( REG_DIOMAPPING2, RF_DIOMAPPING2_DIO4_10 | RF_DIOMAPPING2_DIO5_10 );
this->settings.State = RF_TX_RUNNING;
SetTimeout(TXTimeoutTimer, &SX1276::OnTimeoutIrq, timeout);
SetOpMode( RF_OPMODE_TRANSMITTER );
}
int16_t SX1276::MaxMTUSize( RadioModems_t modem )
{
int16_t mtuSize = 0;
switch( modem )
{
case MODEM_FSK:
mtuSize = RX_BUFFER_SIZE;
case MODEM_LORA:
mtuSize = RX_BUFFER_SIZE;
break;
default:
mtuSize = -1;
break;
}
return mtuSize;
}
int16_t SX1276::GetRssi( RadioModems_t modem )
{
int16_t rssi = 0;
switch( modem )
{
case MODEM_FSK:
rssi = -( Read( REG_RSSIVALUE ) >> 1 );
break;
case MODEM_LORA:
if( this->settings.Channel > RF_MID_BAND_THRESH )
{
rssi = RSSI_OFFSET_HF + Read( REG_LR_RSSIVALUE );
}
else
{
rssi = RSSI_OFFSET_LF + Read( REG_LR_RSSIVALUE );
}
break;
default:
rssi = -1;
break;
}
return rssi;
}
void SX1276::SetOpMode( uint8_t opMode )
{
if( opMode == RF_OPMODE_SLEEP )
{
SetAntSwLowPower( true );
}
else
{
SetAntSwLowPower( false );
SetAntSw( opMode );
}
Write( REG_OPMODE, ( Read( REG_OPMODE ) & RF_OPMODE_MASK ) | opMode );
}
void SX1276::SetModem( RadioModems_t modem )
{
if( ( Read( REG_OPMODE ) & RFLR_OPMODE_LONGRANGEMODE_ON ) != 0 )
{
this->settings.Modem = MODEM_LORA;
}
else
{
this->settings.Modem = MODEM_FSK;
}
if( this->settings.Modem == modem )
{
return;
}
this->settings.Modem = modem;
switch( this->settings.Modem )
{
default:
case MODEM_FSK:
Sleep( );
Write( REG_OPMODE, ( Read( REG_OPMODE ) & RFLR_OPMODE_LONGRANGEMODE_MASK ) | RFLR_OPMODE_LONGRANGEMODE_OFF );
Write( REG_DIOMAPPING1, 0x00 );
Write( REG_DIOMAPPING2, 0x30 ); // DIO5=ModeReady
break;
case MODEM_LORA:
Sleep( );
Write( REG_OPMODE, ( Read( REG_OPMODE ) & RFLR_OPMODE_LONGRANGEMODE_MASK ) | RFLR_OPMODE_LONGRANGEMODE_ON );
Write( REG_DIOMAPPING1, 0x00 );
Write( REG_DIOMAPPING2, 0x00 );
break;
}
}
void SX1276::SetMaxPayloadLength( RadioModems_t modem, uint8_t max )
{
this->SetModem( modem );
switch( modem )
{
case MODEM_FSK:
if( this->settings.Fsk.FixLen == false )
{
this->Write( REG_PAYLOADLENGTH, max );
}
break;
case MODEM_LORA:
this->Write( REG_LR_PAYLOADMAXLENGTH, max );
break;
}
}
void SX1276::SetPublicNetwork( bool enable )
{
SetModem( MODEM_LORA );
this->settings.LoRa.PublicNetwork = enable;
if( enable == true )
{
// Change LoRa modem SyncWord
Write( REG_LR_SYNCWORD, LORA_MAC_PUBLIC_SYNCWORD );
}
else
{
// Change LoRa modem SyncWord
Write( REG_LR_SYNCWORD, LORA_MAC_PRIVATE_SYNCWORD );
}
}
void SX1276::OnTimeoutIrq( void )
{
switch( this->settings.State )
{
case RF_RX_RUNNING:
if( this->settings.Modem == MODEM_FSK )
{
this->settings.FskPacketHandler.PreambleDetected = false;
this->settings.FskPacketHandler.SyncWordDetected = false;
this->settings.FskPacketHandler.NbBytes = 0;
this->settings.FskPacketHandler.Size = 0;
// Clear Irqs
Write( REG_IRQFLAGS1, RF_IRQFLAGS1_RSSI |
RF_IRQFLAGS1_PREAMBLEDETECT |
RF_IRQFLAGS1_SYNCADDRESSMATCH );
Write( REG_IRQFLAGS2, RF_IRQFLAGS2_FIFOOVERRUN );
if( this->settings.Fsk.RxContinuous == true )
{
// Continuous mode restart Rx chain
Write( REG_RXCONFIG, Read( REG_RXCONFIG ) | RF_RXCONFIG_RESTARTRXWITHOUTPLLLOCK );
SetTimeout(RXTimeoutSyncWordTimer, &SX1276::OnTimeoutIrq, this->settings.Fsk.RxSingleTimeout * 1e3);
}
else
{
this->settings.State = RF_IDLE;
SetTimeout(RXTimeoutSyncWordTimer, NULL);
}
}
if( ( this->RadioEvents != NULL ) && ( this->RadioEvents->RxTimeout != NULL ) )
{
this->RadioEvents->RxTimeout(this);
}
break;
case RF_TX_RUNNING:
// Tx timeout shouldn't happen.
// But it has been observed that when it happens it is a result of a corrupted SPI transfer
// it depends on the platform design.
//
// The workaround is to put the radio in a known state. Thus, we re-initialize it.
// BEGIN WORKAROUND
// Reset the radio
Reset( );
// Calibrate Rx chain
RxChainCalibration( );
// Initialize radio default values
SetOpMode( RF_OPMODE_SLEEP );
RadioRegistersInit( );
SetModem( MODEM_FSK );
// Restore previous network type setting.
SetPublicNetwork( this->settings.LoRa.PublicNetwork );
// END WORKAROUND
this->settings.State = RF_IDLE;
if( ( this->RadioEvents != NULL ) && ( this->RadioEvents->TxTimeout != NULL ) )
{
this->RadioEvents->TxTimeout(this);
}
break;
default:
break;
}
}
void SX1276::OnDio0Irq( void )
{
volatile uint8_t irqFlags = 0;
switch( this->settings.State )
{
case RF_RX_RUNNING:
//TimerStop( &RxTimeoutTimer );
// RxDone interrupt
switch( this->settings.Modem )
{
case MODEM_FSK:
if( this->settings.Fsk.CrcOn == true )
{
irqFlags = Read( REG_IRQFLAGS2 );
if( ( irqFlags & RF_IRQFLAGS2_CRCOK ) != RF_IRQFLAGS2_CRCOK )
{
// Clear Irqs
Write( REG_IRQFLAGS1, RF_IRQFLAGS1_RSSI |
RF_IRQFLAGS1_PREAMBLEDETECT |
RF_IRQFLAGS1_SYNCADDRESSMATCH );
Write( REG_IRQFLAGS2, RF_IRQFLAGS2_FIFOOVERRUN );
SetTimeout(RXTimeoutTimer, NULL);
if( this->settings.Fsk.RxContinuous == false )
{
SetTimeout(RXTimeoutSyncWordTimer, NULL);
this->settings.State = RF_IDLE;
}
else
{
// Continuous mode restart Rx chain
Write( REG_RXCONFIG, Read( REG_RXCONFIG ) | RF_RXCONFIG_RESTARTRXWITHOUTPLLLOCK );
SetTimeout(RXTimeoutSyncWordTimer, &SX1276::OnTimeoutIrq, this->settings.Fsk.RxSingleTimeout * 1e3);
}
if( ( this->RadioEvents != NULL ) && ( this->RadioEvents->RxError != NULL ) )
{
this->RadioEvents->RxError(this);
}
this->settings.FskPacketHandler.PreambleDetected = false;
this->settings.FskPacketHandler.SyncWordDetected = false;
this->settings.FskPacketHandler.NbBytes = 0;
this->settings.FskPacketHandler.Size = 0;
break;
}
}
// Read received packet size
if( ( this->settings.FskPacketHandler.Size == 0 ) && ( this->settings.FskPacketHandler.NbBytes == 0 ) )
{
if( this->settings.Fsk.FixLen == false )
{
ReadFifo( ( uint8_t* )&this->settings.FskPacketHandler.Size, 1 );
}
else
{
this->settings.FskPacketHandler.Size = Read( REG_PAYLOADLENGTH );
}
ReadFifo( rxtxBuffer + this->settings.FskPacketHandler.NbBytes, this->settings.FskPacketHandler.Size - this->settings.FskPacketHandler.NbBytes );
this->settings.FskPacketHandler.NbBytes += ( this->settings.FskPacketHandler.Size - this->settings.FskPacketHandler.NbBytes );
}
else
{
ReadFifo( rxtxBuffer + this->settings.FskPacketHandler.NbBytes, this->settings.FskPacketHandler.Size - this->settings.FskPacketHandler.NbBytes );
this->settings.FskPacketHandler.NbBytes += ( this->settings.FskPacketHandler.Size - this->settings.FskPacketHandler.NbBytes );
}
SetTimeout(RXTimeoutTimer, NULL);
if( this->settings.Fsk.RxContinuous == false )
{
this->settings.State = RF_IDLE;
SetTimeout(RXTimeoutSyncWordTimer, NULL);
}
else
{
// Continuous mode restart Rx chain
Write( REG_RXCONFIG, Read( REG_RXCONFIG ) | RF_RXCONFIG_RESTARTRXWITHOUTPLLLOCK );
SetTimeout(RXTimeoutSyncWordTimer, &SX1276::OnTimeoutIrq, this->settings.Fsk.RxSingleTimeout * 1e3);
}
if( ( this->RadioEvents != NULL ) && ( this->RadioEvents->RxDone != NULL ) )
{
this->RadioEvents->RxDone(this, rxtxBuffer, this->settings.FskPacketHandler.Size, this->settings.FskPacketHandler.RssiValue, 0 );
}
this->settings.FskPacketHandler.PreambleDetected = false;
this->settings.FskPacketHandler.SyncWordDetected = false;
this->settings.FskPacketHandler.NbBytes = 0;
this->settings.FskPacketHandler.Size = 0;
break;
case MODEM_LORA:
{
int8_t snr = 0;
// Clear Irq
Write( REG_LR_IRQFLAGS, RFLR_IRQFLAGS_RXDONE );
irqFlags = Read( REG_LR_IRQFLAGS );
if( ( irqFlags & RFLR_IRQFLAGS_PAYLOADCRCERROR_MASK ) == RFLR_IRQFLAGS_PAYLOADCRCERROR )
{
// Clear Irq
Write( REG_LR_IRQFLAGS, RFLR_IRQFLAGS_PAYLOADCRCERROR );
if( this->settings.LoRa.RxContinuous == false )
{
this->settings.State = RF_IDLE;
}
SetTimeout(RXTimeoutTimer, NULL);
if( ( this->RadioEvents != NULL ) && ( this->RadioEvents->RxError != NULL ) )
{
this->RadioEvents->RxError(this);
}
break;
}
this->settings.LoRaPacketHandler.SnrValue = Read( REG_LR_PKTSNRVALUE );
if( this->settings.LoRaPacketHandler.SnrValue & 0x80 ) // The SNR sign bit is 1
{
// Invert and divide by 4
snr = ( ( ~this->settings.LoRaPacketHandler.SnrValue + 1 ) & 0xFF ) >> 2;
snr = -snr;
}
else
{
// Divide by 4
snr = ( this->settings.LoRaPacketHandler.SnrValue & 0xFF ) >> 2;
}
int16_t rssi = Read( REG_LR_PKTRSSIVALUE );
if( snr < 0 )
{
if( this->settings.Channel > RF_MID_BAND_THRESH )
{
this->settings.LoRaPacketHandler.RssiValue = RSSI_OFFSET_HF + rssi + ( rssi >> 4 ) +
snr;
}
else
{
this->settings.LoRaPacketHandler.RssiValue = RSSI_OFFSET_LF + rssi + ( rssi >> 4 ) +
snr;
}
}
else
{
if( this->settings.Channel > RF_MID_BAND_THRESH )
{
this->settings.LoRaPacketHandler.RssiValue = RSSI_OFFSET_HF + rssi + ( rssi >> 4 );
}
else
{
this->settings.LoRaPacketHandler.RssiValue = RSSI_OFFSET_LF + rssi + ( rssi >> 4 );
}
}
this->settings.LoRaPacketHandler.Size = Read( REG_LR_RXNBBYTES );
ReadFifo( rxtxBuffer, this->settings.LoRaPacketHandler.Size );
if( this->settings.LoRa.RxContinuous == false )
{
this->settings.State = RF_IDLE;
}
SetTimeout(RXTimeoutTimer, NULL);
if( ( this->RadioEvents != NULL ) && ( this->RadioEvents->RxDone != NULL ) )
{
this->RadioEvents->RxDone(this, rxtxBuffer, this->settings.LoRaPacketHandler.Size, this->settings.LoRaPacketHandler.RssiValue, this->settings.LoRaPacketHandler.SnrValue );
}
}
break;
default:
break;
}
break;
case RF_TX_RUNNING:
SetTimeout(TXTimeoutTimer, NULL);
// TxDone interrupt
switch( this->settings.Modem )
{
case MODEM_LORA:
// Clear Irq
Write( REG_LR_IRQFLAGS, RFLR_IRQFLAGS_TXDONE );
// Intentional fall through
case MODEM_FSK:
default:
this->settings.State = RF_IDLE;
if( ( this->RadioEvents != NULL ) && ( this->RadioEvents->TxDone != NULL ) )
{
this->RadioEvents->TxDone(this);
}
break;
}
break;
default:
break;
}
}
void SX1276::OnDio1Irq( void )
{
switch( this->settings.State )
{
case RF_RX_RUNNING:
switch( this->settings.Modem )
{
case MODEM_FSK:
// FifoLevel interrupt
// Read received packet size
if( ( this->settings.FskPacketHandler.Size == 0 ) && ( this->settings.FskPacketHandler.NbBytes == 0 ) )
{
if( this->settings.Fsk.FixLen == false )
{
ReadFifo( ( uint8_t* )&this->settings.FskPacketHandler.Size, 1 );
}
else
{
this->settings.FskPacketHandler.Size = Read( REG_PAYLOADLENGTH );
}
}
if( ( this->settings.FskPacketHandler.Size - this->settings.FskPacketHandler.NbBytes ) > this->settings.FskPacketHandler.FifoThresh )
{
ReadFifo( ( rxtxBuffer + this->settings.FskPacketHandler.NbBytes ), this->settings.FskPacketHandler.FifoThresh );
this->settings.FskPacketHandler.NbBytes += this->settings.FskPacketHandler.FifoThresh;
}
else
{
ReadFifo( ( rxtxBuffer + this->settings.FskPacketHandler.NbBytes ), this->settings.FskPacketHandler.Size - this->settings.FskPacketHandler.NbBytes );
this->settings.FskPacketHandler.NbBytes += ( this->settings.FskPacketHandler.Size - this->settings.FskPacketHandler.NbBytes );
}
break;
case MODEM_LORA:
// Sync time out
SetTimeout(RXTimeoutTimer, NULL);
// Clear Irq
Write( REG_LR_IRQFLAGS, RFLR_IRQFLAGS_RXTIMEOUT );
this->settings.State = RF_IDLE;
if( ( this->RadioEvents != NULL ) && ( this->RadioEvents->RxTimeout != NULL ) )
{
this->RadioEvents->RxTimeout(this);
}
break;
default:
break;
}
break;
case RF_TX_RUNNING:
switch( this->settings.Modem )
{
case MODEM_FSK:
// FifoEmpty interrupt
if( ( this->settings.FskPacketHandler.Size - this->settings.FskPacketHandler.NbBytes ) > this->settings.FskPacketHandler.ChunkSize )
{
WriteFifo( ( rxtxBuffer + this->settings.FskPacketHandler.NbBytes ), this->settings.FskPacketHandler.ChunkSize );
this->settings.FskPacketHandler.NbBytes += this->settings.FskPacketHandler.ChunkSize;
}
else
{
// Write the last chunk of data
WriteFifo( rxtxBuffer + this->settings.FskPacketHandler.NbBytes, this->settings.FskPacketHandler.Size - this->settings.FskPacketHandler.NbBytes );
this->settings.FskPacketHandler.NbBytes += this->settings.FskPacketHandler.Size - this->settings.FskPacketHandler.NbBytes;
}
break;
case MODEM_LORA:
break;
default:
break;
}
break;
default:
break;
}
}
void SX1276::OnDio2Irq( void )
{
switch( this->settings.State )
{
case RF_RX_RUNNING:
switch( this->settings.Modem )
{
case MODEM_FSK:
// Checks if DIO4 is connected. If it is not PreambleDtected is set to true.
if( this->dioIrq[4] == NULL )
{
this->settings.FskPacketHandler.PreambleDetected = true;
}
if( ( this->settings.FskPacketHandler.PreambleDetected == true ) && ( this->settings.FskPacketHandler.SyncWordDetected == false ) )
{
SetTimeout(RXTimeoutSyncWordTimer, NULL);
this->settings.FskPacketHandler.SyncWordDetected = true;
this->settings.FskPacketHandler.RssiValue = -( Read( REG_RSSIVALUE ) >> 1 );
this->settings.FskPacketHandler.AfcValue = ( int32_t )( double )( ( ( uint16_t )Read( REG_AFCMSB ) << 8 ) |
( uint16_t )Read( REG_AFCLSB ) ) *
( double )FREQ_STEP;
this->settings.FskPacketHandler.RxGain = ( Read( REG_LNA ) >> 5 ) & 0x07;
}
break;
case MODEM_LORA:
if( this->settings.LoRa.FreqHopOn == true )
{
// Clear Irq
Write( REG_LR_IRQFLAGS, RFLR_IRQFLAGS_FHSSCHANGEDCHANNEL );
if( ( this->RadioEvents != NULL ) && ( this->RadioEvents->FhssChangeChannel != NULL ) )
{
this->RadioEvents->FhssChangeChannel(this, ( Read( REG_LR_HOPCHANNEL ) & RFLR_HOPCHANNEL_CHANNEL_MASK ) );
}
}
break;
default:
break;
}
break;
case RF_TX_RUNNING:
switch( this->settings.Modem )
{
case MODEM_FSK:
break;
case MODEM_LORA:
if( this->settings.LoRa.FreqHopOn == true )
{
// Clear Irq
Write( REG_LR_IRQFLAGS, RFLR_IRQFLAGS_FHSSCHANGEDCHANNEL );
if( ( this->RadioEvents != NULL ) && ( this->RadioEvents->FhssChangeChannel != NULL ) )
{
this->RadioEvents->FhssChangeChannel(this, ( Read( REG_LR_HOPCHANNEL ) & RFLR_HOPCHANNEL_CHANNEL_MASK ) );
}
}
break;
default:
break;
}
break;
default:
break;
}
}
void SX1276::OnDio3Irq( void )
{
switch( this->settings.Modem )
{
case MODEM_FSK:
break;
case MODEM_LORA:
if( ( Read( REG_LR_IRQFLAGS ) & RFLR_IRQFLAGS_CADDETECTED ) == RFLR_IRQFLAGS_CADDETECTED )
{
// Clear Irq
Write( REG_LR_IRQFLAGS, RFLR_IRQFLAGS_CADDETECTED | RFLR_IRQFLAGS_CADDONE );
if( ( this->RadioEvents != NULL ) && ( this->RadioEvents->CadDone != NULL ) )
{
this->RadioEvents->CadDone(this, true );
}
}
else
{
// Clear Irq
Write( REG_LR_IRQFLAGS, RFLR_IRQFLAGS_CADDONE );
if( ( this->RadioEvents != NULL ) && ( this->RadioEvents->CadDone != NULL ) )
{
this->RadioEvents->CadDone(this, false );
}
}
break;
default:
break;
}
}
void SX1276::OnDio4Irq( void )
{
switch( this->settings.Modem )
{
case MODEM_FSK:
{
if( this->settings.FskPacketHandler.PreambleDetected == false )
{
this->settings.FskPacketHandler.PreambleDetected = true;
}
}
break;
case MODEM_LORA:
break;
default:
break;
}
}
void SX1276::OnDio5Irq( void )
{
switch( this->settings.Modem )
{
case MODEM_FSK:
break;
case MODEM_LORA:
break;
default:
break;
}
}
