Слияние кода завершено, страница обновится автоматически
/*!
* \file sx126x.c
*
* \brief SX126x driver implementation
*
* \copyright Revised BSD License, see section \ref LICENSE.
*
* \code
* ______ _
* / _____) _ | |
* ( (____ _____ ____ _| |_ _____ ____| |__
* \____ \| ___ | (_ _) ___ |/ ___) _ \
* _____) ) ____| | | || |_| ____( (___| | | |
* (______/|_____)_|_|_| \__)_____)\____)_| |_|
* (C)2013-2017 Semtech
*
* \endcode
*
* \author Miguel Luis ( Semtech )
*
* \author Gregory Cristian ( Semtech )
*/
#include <string.h>
#include "utilities.h"
#include "timer.h"
#include "radio.h"
#include "delay.h"
#include "sx126x.h"
#include "sx126x-board.h"
/*!
* \brief Internal frequency of the radio
*/
#define SX126X_XTAL_FREQ 32000000UL
/*!
* \brief Scaling factor used to perform fixed-point operations
*/
#define SX126X_PLL_STEP_SHIFT_AMOUNT ( 14 )
/*!
* \brief PLL step - scaled with SX126X_PLL_STEP_SHIFT_AMOUNT
*/
#define SX126X_PLL_STEP_SCALED ( SX126X_XTAL_FREQ >> ( 25 - SX126X_PLL_STEP_SHIFT_AMOUNT ) )
/*!
* \brief Maximum value for parameter symbNum in \ref SX126xSetLoRaSymbNumTimeout
*/
#define SX126X_MAX_LORA_SYMB_NUM_TIMEOUT 248
/*!
* \brief Radio registers definition
*/
typedef struct
{
uint16_t Addr; //!< The address of the register
uint8_t Value; //!< The value of the register
}RadioRegisters_t;
/*!
* \brief Stores the current packet type set in the radio
*/
static RadioPacketTypes_t PacketType;
/*!
* \brief Stores the current packet header type set in the radio
*/
static volatile RadioLoRaPacketLengthsMode_t LoRaHeaderType;
/*!
* \brief Stores the last frequency error measured on LoRa received packet
*/
volatile uint32_t FrequencyError = 0;
/*!
* \brief Hold the status of the Image calibration
*/
static bool ImageCalibrated = false;
/*!
* \brief Get the number of PLL steps for a given frequency in Hertz
*
* \param [in] freqInHz Frequency in Hertz
*
* \returns Number of PLL steps
*/
static uint32_t SX126xConvertFreqInHzToPllStep( uint32_t freqInHz );
/*
* SX126x DIO IRQ callback functions prototype
*/
/*!
* \brief DIO 0 IRQ callback
*/
void SX126xOnDioIrq( void );
/*!
* \brief DIO 0 IRQ callback
*/
void SX126xSetPollingMode( void );
/*!
* \brief DIO 0 IRQ callback
*/
void SX126xSetInterruptMode( void );
/*
* \brief Process the IRQ if handled by the driver
*/
void SX126xProcessIrqs( void );
void SX126xInit( DioIrqHandler dioIrq )
{
SX126xReset( );
SX126xIoIrqInit( dioIrq );
SX126xWakeup( );
SX126xSetStandby( STDBY_RC );
// Initialize TCXO control
SX126xIoTcxoInit( );
// Initialize RF switch control
SX126xIoRfSwitchInit( );
SX126xSetOperatingMode( MODE_STDBY_RC );
}
void SX126xCheckDeviceReady( void )
{
if( ( SX126xGetOperatingMode( ) == MODE_SLEEP ) || ( SX126xGetOperatingMode( ) == MODE_RX_DC ) )
{
SX126xWakeup( );
// Switch is turned off when device is in sleep mode and turned on is all other modes
SX126xAntSwOn( );
}
SX126xWaitOnBusy( );
}
void SX126xSetPayload( uint8_t *payload, uint8_t size )
{
SX126xWriteBuffer( 0x00, payload, size );
}
uint8_t SX126xGetPayload( uint8_t *buffer, uint8_t *size, uint8_t maxSize )
{
uint8_t offset = 0;
SX126xGetRxBufferStatus( size, &offset );
if( *size > maxSize )
{
return 1;
}
SX126xReadBuffer( offset, buffer, *size );
return 0;
}
void SX126xSendPayload( uint8_t *payload, uint8_t size, uint32_t timeout )
{
SX126xSetPayload( payload, size );
SX126xSetTx( timeout );
}
uint8_t SX126xSetSyncWord( uint8_t *syncWord )
{
SX126xWriteRegisters( REG_LR_SYNCWORDBASEADDRESS, syncWord, 8 );
return 0;
}
void SX126xSetCrcSeed( uint16_t seed )
{
uint8_t buf[2];
buf[0] = ( uint8_t )( ( seed >> 8 ) & 0xFF );
buf[1] = ( uint8_t )( seed & 0xFF );
switch( SX126xGetPacketType( ) )
{
case PACKET_TYPE_GFSK:
SX126xWriteRegisters( REG_LR_CRCSEEDBASEADDR, buf, 2 );
break;
default:
break;
}
}
void SX126xSetCrcPolynomial( uint16_t polynomial )
{
uint8_t buf[2];
buf[0] = ( uint8_t )( ( polynomial >> 8 ) & 0xFF );
buf[1] = ( uint8_t )( polynomial & 0xFF );
switch( SX126xGetPacketType( ) )
{
case PACKET_TYPE_GFSK:
SX126xWriteRegisters( REG_LR_CRCPOLYBASEADDR, buf, 2 );
break;
default:
break;
}
}
void SX126xSetWhiteningSeed( uint16_t seed )
{
uint8_t regValue = 0;
switch( SX126xGetPacketType( ) )
{
case PACKET_TYPE_GFSK:
regValue = SX126xReadRegister( REG_LR_WHITSEEDBASEADDR_MSB ) & 0xFE;
regValue = ( ( seed >> 8 ) & 0x01 ) | regValue;
SX126xWriteRegister( REG_LR_WHITSEEDBASEADDR_MSB, regValue ); // only 1 bit.
SX126xWriteRegister( REG_LR_WHITSEEDBASEADDR_LSB, ( uint8_t )seed );
break;
default:
break;
}
}
uint32_t SX126xGetRandom( void )
{
uint32_t number = 0;
uint8_t regAnaLna = 0;
uint8_t regAnaMixer = 0;
regAnaLna = SX126xReadRegister( REG_ANA_LNA );
SX126xWriteRegister( REG_ANA_LNA, regAnaLna & ~( 1 << 0 ) );
regAnaMixer = SX126xReadRegister( REG_ANA_MIXER );
SX126xWriteRegister( REG_ANA_MIXER, regAnaMixer & ~( 1 << 7 ) );
// Set radio in continuous reception
SX126xSetRx( 0xFFFFFF ); // Rx Continuous
SX126xReadRegisters( RANDOM_NUMBER_GENERATORBASEADDR, ( uint8_t* )&number, 4 );
SX126xSetStandby( STDBY_RC );
SX126xWriteRegister( REG_ANA_LNA, regAnaLna );
SX126xWriteRegister( REG_ANA_MIXER, regAnaMixer );
return number;
}
void SX126xSetSleep( SleepParams_t sleepConfig )
{
SX126xAntSwOff( );
uint8_t value = ( ( ( uint8_t )sleepConfig.Fields.WarmStart << 2 ) |
( ( uint8_t )sleepConfig.Fields.Reset << 1 ) |
( ( uint8_t )sleepConfig.Fields.WakeUpRTC ) );
SX126xWriteCommand( RADIO_SET_SLEEP, &value, 1 );
SX126xSetOperatingMode( MODE_SLEEP );
}
void SX126xSetStandby( RadioStandbyModes_t standbyConfig )
{
SX126xWriteCommand( RADIO_SET_STANDBY, ( uint8_t* )&standbyConfig, 1 );
if( standbyConfig == STDBY_RC )
{
SX126xSetOperatingMode( MODE_STDBY_RC );
}
else
{
SX126xSetOperatingMode( MODE_STDBY_XOSC );
}
}
void SX126xSetFs( void )
{
SX126xWriteCommand( RADIO_SET_FS, 0, 0 );
SX126xSetOperatingMode( MODE_FS );
}
void SX126xSetTx( uint32_t timeout )
{
uint8_t buf[3];
SX126xSetOperatingMode( MODE_TX );
buf[0] = ( uint8_t )( ( timeout >> 16 ) & 0xFF );
buf[1] = ( uint8_t )( ( timeout >> 8 ) & 0xFF );
buf[2] = ( uint8_t )( timeout & 0xFF );
SX126xWriteCommand( RADIO_SET_TX, buf, 3 );
}
void SX126xSetRx( uint32_t timeout )
{
uint8_t buf[3];
SX126xSetOperatingMode( MODE_RX );
buf[0] = ( uint8_t )( ( timeout >> 16 ) & 0xFF );
buf[1] = ( uint8_t )( ( timeout >> 8 ) & 0xFF );
buf[2] = ( uint8_t )( timeout & 0xFF );
SX126xWriteCommand( RADIO_SET_RX, buf, 3 );
}
void SX126xSetRxBoosted( uint32_t timeout )
{
uint8_t buf[3];
SX126xSetOperatingMode( MODE_RX );
SX126xWriteRegister( REG_RX_GAIN, 0x96 ); // max LNA gain, increase current by ~2mA for around ~3dB in sensivity
buf[0] = ( uint8_t )( ( timeout >> 16 ) & 0xFF );
buf[1] = ( uint8_t )( ( timeout >> 8 ) & 0xFF );
buf[2] = ( uint8_t )( timeout & 0xFF );
SX126xWriteCommand( RADIO_SET_RX, buf, 3 );
}
void SX126xSetRxDutyCycle( uint32_t rxTime, uint32_t sleepTime )
{
uint8_t buf[6];
buf[0] = ( uint8_t )( ( rxTime >> 16 ) & 0xFF );
buf[1] = ( uint8_t )( ( rxTime >> 8 ) & 0xFF );
buf[2] = ( uint8_t )( rxTime & 0xFF );
buf[3] = ( uint8_t )( ( sleepTime >> 16 ) & 0xFF );
buf[4] = ( uint8_t )( ( sleepTime >> 8 ) & 0xFF );
buf[5] = ( uint8_t )( sleepTime & 0xFF );
SX126xWriteCommand( RADIO_SET_RXDUTYCYCLE, buf, 6 );
SX126xSetOperatingMode( MODE_RX_DC );
}
void SX126xSetCad( void )
{
SX126xWriteCommand( RADIO_SET_CAD, 0, 0 );
SX126xSetOperatingMode( MODE_CAD );
}
void SX126xSetTxContinuousWave( void )
{
SX126xWriteCommand( RADIO_SET_TXCONTINUOUSWAVE, 0, 0 );
SX126xSetOperatingMode( MODE_TX );
}
void SX126xSetTxInfinitePreamble( void )
{
SX126xWriteCommand( RADIO_SET_TXCONTINUOUSPREAMBLE, 0, 0 );
SX126xSetOperatingMode( MODE_TX );
}
void SX126xSetStopRxTimerOnPreambleDetect( bool enable )
{
SX126xWriteCommand( RADIO_SET_STOPRXTIMERONPREAMBLE, ( uint8_t* )&enable, 1 );
}
void SX126xSetLoRaSymbNumTimeout( uint8_t symbNum )
{
uint8_t mant = ( ( ( symbNum > SX126X_MAX_LORA_SYMB_NUM_TIMEOUT ) ?
SX126X_MAX_LORA_SYMB_NUM_TIMEOUT :
symbNum ) + 1 ) >> 1;
uint8_t exp = 0;
uint8_t reg = 0;
while( mant > 31 )
{
mant = ( mant + 3 ) >> 2;
exp++;
}
reg = mant << ( 2 * exp + 1 );
SX126xWriteCommand( RADIO_SET_LORASYMBTIMEOUT, ®, 1 );
if( symbNum != 0 )
{
reg = exp + ( mant << 3 );
SX126xWriteRegister( REG_LR_SYNCH_TIMEOUT, reg );
}
}
void SX126xSetRegulatorMode( RadioRegulatorMode_t mode )
{
SX126xWriteCommand( RADIO_SET_REGULATORMODE, ( uint8_t* )&mode, 1 );
}
void SX126xCalibrate( CalibrationParams_t calibParam )
{
uint8_t value = ( ( ( uint8_t )calibParam.Fields.ImgEnable << 6 ) |
( ( uint8_t )calibParam.Fields.ADCBulkPEnable << 5 ) |
( ( uint8_t )calibParam.Fields.ADCBulkNEnable << 4 ) |
( ( uint8_t )calibParam.Fields.ADCPulseEnable << 3 ) |
( ( uint8_t )calibParam.Fields.PLLEnable << 2 ) |
( ( uint8_t )calibParam.Fields.RC13MEnable << 1 ) |
( ( uint8_t )calibParam.Fields.RC64KEnable ) );
SX126xWriteCommand( RADIO_CALIBRATE, &value, 1 );
}
void SX126xCalibrateImage( uint32_t freq )
{
uint8_t calFreq[2];
if( freq > 900000000 )
{
calFreq[0] = 0xE1;
calFreq[1] = 0xE9;
}
else if( freq > 850000000 )
{
calFreq[0] = 0xD7;
calFreq[1] = 0xDB;
}
else if( freq > 770000000 )
{
calFreq[0] = 0xC1;
calFreq[1] = 0xC5;
}
else if( freq > 460000000 )
{
calFreq[0] = 0x75;
calFreq[1] = 0x81;
}
else if( freq > 425000000 )
{
calFreq[0] = 0x6B;
calFreq[1] = 0x6F;
}
SX126xWriteCommand( RADIO_CALIBRATEIMAGE, calFreq, 2 );
}
void SX126xSetPaConfig( uint8_t paDutyCycle, uint8_t hpMax, uint8_t deviceSel, uint8_t paLut )
{
uint8_t buf[4];
buf[0] = paDutyCycle;
buf[1] = hpMax;
buf[2] = deviceSel;
buf[3] = paLut;
SX126xWriteCommand( RADIO_SET_PACONFIG, buf, 4 );
}
void SX126xSetRxTxFallbackMode( uint8_t fallbackMode )
{
SX126xWriteCommand( RADIO_SET_TXFALLBACKMODE, &fallbackMode, 1 );
}
void SX126xSetDioIrqParams( uint16_t irqMask, uint16_t dio1Mask, uint16_t dio2Mask, uint16_t dio3Mask )
{
uint8_t buf[8];
buf[0] = ( uint8_t )( ( irqMask >> 8 ) & 0x00FF );
buf[1] = ( uint8_t )( irqMask & 0x00FF );
buf[2] = ( uint8_t )( ( dio1Mask >> 8 ) & 0x00FF );
buf[3] = ( uint8_t )( dio1Mask & 0x00FF );
buf[4] = ( uint8_t )( ( dio2Mask >> 8 ) & 0x00FF );
buf[5] = ( uint8_t )( dio2Mask & 0x00FF );
buf[6] = ( uint8_t )( ( dio3Mask >> 8 ) & 0x00FF );
buf[7] = ( uint8_t )( dio3Mask & 0x00FF );
SX126xWriteCommand( RADIO_CFG_DIOIRQ, buf, 8 );
}
uint16_t SX126xGetIrqStatus( void )
{
uint8_t irqStatus[2];
SX126xReadCommand( RADIO_GET_IRQSTATUS, irqStatus, 2 );
return ( irqStatus[0] << 8 ) | irqStatus[1];
}
void SX126xSetDio2AsRfSwitchCtrl( uint8_t enable )
{
SX126xWriteCommand( RADIO_SET_RFSWITCHMODE, &enable, 1 );
}
void SX126xSetDio3AsTcxoCtrl( RadioTcxoCtrlVoltage_t tcxoVoltage, uint32_t timeout )
{
uint8_t buf[4];
buf[0] = tcxoVoltage & 0x07;
buf[1] = ( uint8_t )( ( timeout >> 16 ) & 0xFF );
buf[2] = ( uint8_t )( ( timeout >> 8 ) & 0xFF );
buf[3] = ( uint8_t )( timeout & 0xFF );
SX126xWriteCommand( RADIO_SET_TCXOMODE, buf, 4 );
}
void SX126xSetRfFrequency( uint32_t frequency )
{
uint8_t buf[4];
if( ImageCalibrated == false )
{
SX126xCalibrateImage( frequency );
ImageCalibrated = true;
}
uint32_t freqInPllSteps = SX126xConvertFreqInHzToPllStep( frequency );
buf[0] = ( uint8_t )( ( freqInPllSteps >> 24 ) & 0xFF );
buf[1] = ( uint8_t )( ( freqInPllSteps >> 16 ) & 0xFF );
buf[2] = ( uint8_t )( ( freqInPllSteps >> 8 ) & 0xFF );
buf[3] = ( uint8_t )( freqInPllSteps & 0xFF );
SX126xWriteCommand( RADIO_SET_RFFREQUENCY, buf, 4 );
}
void SX126xSetPacketType( RadioPacketTypes_t packetType )
{
// Save packet type internally to avoid questioning the radio
PacketType = packetType;
SX126xWriteCommand( RADIO_SET_PACKETTYPE, ( uint8_t* )&packetType, 1 );
}
RadioPacketTypes_t SX126xGetPacketType( void )
{
return PacketType;
}
void SX126xSetTxParams( int8_t power, RadioRampTimes_t rampTime )
{
uint8_t buf[2];
if( SX126xGetDeviceId( ) == SX1261 )
{
if( power == 15 )
{
SX126xSetPaConfig( 0x06, 0x00, 0x01, 0x01 );
}
else
{
SX126xSetPaConfig( 0x04, 0x00, 0x01, 0x01 );
}
if( power >= 14 )
{
power = 14;
}
else if( power < -17 )
{
power = -17;
}
}
else // sx1262
{
// WORKAROUND - Better Resistance of the SX1262 Tx to Antenna Mismatch, see DS_SX1261-2_V1.2 datasheet chapter 15.2
// RegTxClampConfig = @address 0x08D8
SX126xWriteRegister( 0x08D8, SX126xReadRegister( 0x08D8 ) | ( 0x0F << 1 ) );
// WORKAROUND END
SX126xSetPaConfig( 0x04, 0x07, 0x00, 0x01 );
if( power > 22 )
{
power = 22;
}
else if( power < -9 )
{
power = -9;
}
}
buf[0] = power;
buf[1] = ( uint8_t )rampTime;
SX126xWriteCommand( RADIO_SET_TXPARAMS, buf, 2 );
}
void SX126xSetModulationParams( ModulationParams_t *modulationParams )
{
uint8_t n;
uint32_t tempVal = 0;
uint8_t buf[8] = { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 };
// Check if required configuration corresponds to the stored packet type
// If not, silently update radio packet type
if( PacketType != modulationParams->PacketType )
{
SX126xSetPacketType( modulationParams->PacketType );
}
switch( modulationParams->PacketType )
{
case PACKET_TYPE_GFSK:
n = 8;
tempVal = ( uint32_t )( 32 * SX126X_XTAL_FREQ / modulationParams->Params.Gfsk.BitRate );
buf[0] = ( tempVal >> 16 ) & 0xFF;
buf[1] = ( tempVal >> 8 ) & 0xFF;
buf[2] = tempVal & 0xFF;
buf[3] = modulationParams->Params.Gfsk.ModulationShaping;
buf[4] = modulationParams->Params.Gfsk.Bandwidth;
tempVal = SX126xConvertFreqInHzToPllStep( modulationParams->Params.Gfsk.Fdev );
buf[5] = ( tempVal >> 16 ) & 0xFF;
buf[6] = ( tempVal >> 8 ) & 0xFF;
buf[7] = ( tempVal& 0xFF );
SX126xWriteCommand( RADIO_SET_MODULATIONPARAMS, buf, n );
break;
case PACKET_TYPE_LORA:
n = 4;
buf[0] = modulationParams->Params.LoRa.SpreadingFactor;
buf[1] = modulationParams->Params.LoRa.Bandwidth;
buf[2] = modulationParams->Params.LoRa.CodingRate;
buf[3] = modulationParams->Params.LoRa.LowDatarateOptimize;
SX126xWriteCommand( RADIO_SET_MODULATIONPARAMS, buf, n );
break;
default:
case PACKET_TYPE_NONE:
return;
}
}
void SX126xSetPacketParams( PacketParams_t *packetParams )
{
uint8_t n;
uint8_t crcVal = 0;
uint8_t buf[9] = { 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00, 0x00 };
// Check if required configuration corresponds to the stored packet type
// If not, silently update radio packet type
if( PacketType != packetParams->PacketType )
{
SX126xSetPacketType( packetParams->PacketType );
}
switch( packetParams->PacketType )
{
case PACKET_TYPE_GFSK:
if( packetParams->Params.Gfsk.CrcLength == RADIO_CRC_2_BYTES_IBM )
{
SX126xSetCrcSeed( CRC_IBM_SEED );
SX126xSetCrcPolynomial( CRC_POLYNOMIAL_IBM );
crcVal = RADIO_CRC_2_BYTES;
}
else if( packetParams->Params.Gfsk.CrcLength == RADIO_CRC_2_BYTES_CCIT )
{
SX126xSetCrcSeed( CRC_CCITT_SEED );
SX126xSetCrcPolynomial( CRC_POLYNOMIAL_CCITT );
crcVal = RADIO_CRC_2_BYTES_INV;
}
else
{
crcVal = packetParams->Params.Gfsk.CrcLength;
}
n = 9;
buf[0] = ( packetParams->Params.Gfsk.PreambleLength >> 8 ) & 0xFF;
buf[1] = packetParams->Params.Gfsk.PreambleLength;
buf[2] = packetParams->Params.Gfsk.PreambleMinDetect;
buf[3] = ( packetParams->Params.Gfsk.SyncWordLength /*<< 3*/ ); // convert from byte to bit
buf[4] = packetParams->Params.Gfsk.AddrComp;
buf[5] = packetParams->Params.Gfsk.HeaderType;
buf[6] = packetParams->Params.Gfsk.PayloadLength;
buf[7] = crcVal;
buf[8] = packetParams->Params.Gfsk.DcFree;
break;
case PACKET_TYPE_LORA:
n = 6;
buf[0] = ( packetParams->Params.LoRa.PreambleLength >> 8 ) & 0xFF;
buf[1] = packetParams->Params.LoRa.PreambleLength;
buf[2] = LoRaHeaderType = packetParams->Params.LoRa.HeaderType;
buf[3] = packetParams->Params.LoRa.PayloadLength;
buf[4] = packetParams->Params.LoRa.CrcMode;
buf[5] = packetParams->Params.LoRa.InvertIQ;
break;
default:
case PACKET_TYPE_NONE:
return;
}
SX126xWriteCommand( RADIO_SET_PACKETPARAMS, buf, n );
}
void SX126xSetCadParams( RadioLoRaCadSymbols_t cadSymbolNum, uint8_t cadDetPeak, uint8_t cadDetMin, RadioCadExitModes_t cadExitMode, uint32_t cadTimeout )
{
uint8_t buf[7];
buf[0] = ( uint8_t )cadSymbolNum;
buf[1] = cadDetPeak;
buf[2] = cadDetMin;
buf[3] = ( uint8_t )cadExitMode;
buf[4] = ( uint8_t )( ( cadTimeout >> 16 ) & 0xFF );
buf[5] = ( uint8_t )( ( cadTimeout >> 8 ) & 0xFF );
buf[6] = ( uint8_t )( cadTimeout & 0xFF );
SX126xWriteCommand( RADIO_SET_CADPARAMS, buf, 7 );
SX126xSetOperatingMode( MODE_CAD );
}
void SX126xSetBufferBaseAddress( uint8_t txBaseAddress, uint8_t rxBaseAddress )
{
uint8_t buf[2];
buf[0] = txBaseAddress;
buf[1] = rxBaseAddress;
SX126xWriteCommand( RADIO_SET_BUFFERBASEADDRESS, buf, 2 );
}
RadioStatus_t SX126xGetStatus( void )
{
uint8_t stat = 0;
RadioStatus_t status = { .Value = 0 };
stat = SX126xReadCommand( RADIO_GET_STATUS, NULL, 0 );
status.Fields.CmdStatus = ( stat & ( 0x07 << 1 ) ) >> 1;
status.Fields.ChipMode = ( stat & ( 0x07 << 4 ) ) >> 4;
return status;
}
int8_t SX126xGetRssiInst( void )
{
uint8_t buf[1];
int8_t rssi = 0;
SX126xReadCommand( RADIO_GET_RSSIINST, buf, 1 );
rssi = -buf[0] >> 1;
return rssi;
}
void SX126xGetRxBufferStatus( uint8_t *payloadLength, uint8_t *rxStartBufferPointer )
{
uint8_t status[2];
SX126xReadCommand( RADIO_GET_RXBUFFERSTATUS, status, 2 );
// In case of LORA fixed header, the payloadLength is obtained by reading
// the register REG_LR_PAYLOADLENGTH
if( ( SX126xGetPacketType( ) == PACKET_TYPE_LORA ) && ( LoRaHeaderType == LORA_PACKET_FIXED_LENGTH ) )
{
*payloadLength = SX126xReadRegister( REG_LR_PAYLOADLENGTH );
}
else
{
*payloadLength = status[0];
}
*rxStartBufferPointer = status[1];
}
void SX126xGetPacketStatus( PacketStatus_t *pktStatus )
{
uint8_t status[3];
SX126xReadCommand( RADIO_GET_PACKETSTATUS, status, 3 );
pktStatus->packetType = SX126xGetPacketType( );
switch( pktStatus->packetType )
{
case PACKET_TYPE_GFSK:
pktStatus->Params.Gfsk.RxStatus = status[0];
pktStatus->Params.Gfsk.RssiSync = -status[1] >> 1;
pktStatus->Params.Gfsk.RssiAvg = -status[2] >> 1;
pktStatus->Params.Gfsk.FreqError = 0;
break;
case PACKET_TYPE_LORA:
pktStatus->Params.LoRa.RssiPkt = -status[0] >> 1;
// Returns SNR value [dB] rounded to the nearest integer value
pktStatus->Params.LoRa.SnrPkt = ( ( ( int8_t )status[1] ) + 2 ) >> 2;
pktStatus->Params.LoRa.SignalRssiPkt = -status[2] >> 1;
pktStatus->Params.LoRa.FreqError = FrequencyError;
break;
default:
case PACKET_TYPE_NONE:
// In that specific case, we set everything in the pktStatus to zeros
// and reset the packet type accordingly
memset( pktStatus, 0, sizeof( PacketStatus_t ) );
pktStatus->packetType = PACKET_TYPE_NONE;
break;
}
}
RadioError_t SX126xGetDeviceErrors( void )
{
uint8_t err[] = { 0, 0 };
RadioError_t error = { .Value = 0 };
SX126xReadCommand( RADIO_GET_ERROR, ( uint8_t* )err, 2 );
error.Fields.PaRamp = ( err[0] & ( 1 << 0 ) ) >> 0;
error.Fields.PllLock = ( err[1] & ( 1 << 6 ) ) >> 6;
error.Fields.XoscStart = ( err[1] & ( 1 << 5 ) ) >> 5;
error.Fields.ImgCalib = ( err[1] & ( 1 << 4 ) ) >> 4;
error.Fields.AdcCalib = ( err[1] & ( 1 << 3 ) ) >> 3;
error.Fields.PllCalib = ( err[1] & ( 1 << 2 ) ) >> 2;
error.Fields.Rc13mCalib = ( err[1] & ( 1 << 1 ) ) >> 1;
error.Fields.Rc64kCalib = ( err[1] & ( 1 << 0 ) ) >> 0;
return error;
}
void SX126xClearDeviceErrors( void )
{
uint8_t buf[2] = { 0x00, 0x00 };
SX126xWriteCommand( RADIO_CLR_ERROR, buf, 2 );
}
void SX126xClearIrqStatus( uint16_t irq )
{
uint8_t buf[2];
buf[0] = ( uint8_t )( ( ( uint16_t )irq >> 8 ) & 0x00FF );
buf[1] = ( uint8_t )( ( uint16_t )irq & 0x00FF );
SX126xWriteCommand( RADIO_CLR_IRQSTATUS, buf, 2 );
}
static uint32_t SX126xConvertFreqInHzToPllStep( uint32_t freqInHz )
{
uint32_t stepsInt;
uint32_t stepsFrac;
// pllSteps = freqInHz / (SX126X_XTAL_FREQ / 2^19 )
// Get integer and fractional parts of the frequency computed with a PLL step scaled value
stepsInt = freqInHz / SX126X_PLL_STEP_SCALED;
stepsFrac = freqInHz - ( stepsInt * SX126X_PLL_STEP_SCALED );
// Apply the scaling factor to retrieve a frequency in Hz (+ ceiling)
return ( stepsInt << SX126X_PLL_STEP_SHIFT_AMOUNT ) +
( ( ( stepsFrac << SX126X_PLL_STEP_SHIFT_AMOUNT ) + ( SX126X_PLL_STEP_SCALED >> 1 ) ) /
SX126X_PLL_STEP_SCALED );
}
Вы можете оставить комментарий после Вход в систему
Неприемлемый контент может быть отображен здесь и не будет показан на странице. Вы можете проверить и изменить его с помощью соответствующей функции редактирования.
Если вы подтверждаете, что содержание не содержит непристойной лексики/перенаправления на рекламу/насилия/вульгарной порнографии/нарушений/пиратства/ложного/незначительного или незаконного контента, связанного с национальными законами и предписаниями, вы можете нажать «Отправить» для подачи апелляции, и мы обработаем ее как можно скорее.
Комментарий ( 0 )