wayne roberts
Sending IKS01A1 temperature sensor to LoRaWAN port-5 uplink
Dependencies: X_NUCLEO_IKS01A1 mbed LoRaWAN-lib SX1276Lib
Fork of
LoRaWAN-demo-76
by 
Semtech
Use IKS01A1 sensor shield with SX1272 shield or SX1276 shield.
Sends temperature sensor to LoRaWAN uplink port 5.
Remove SB22 and SB23 from IKS01A1 before using
SB28 conflicts with DIO0 on radio. (TxDone RxDone)
SB22 conflicts with RxTx on radio. (antenna switch)
app/main.cpp
- Committer:
- mluis
- Date:
- 2016-03-14
- Revision:
- 4:00cf2370c99d
- Parent:
- 3:9c6f7f082151
- Child:
- 5:1e9f6a365854
File content as of revision 4:00cf2370c99d:
/*
/ _____) _ | |
( (____ _____ ____ _| |_ _____ ____| |__
\____ \| ___ | (_ _) ___ |/ ___) _ \
_____) ) ____| | | || |_| ____( (___| | | |
(______/|_____)_|_|_| \__)_____)\____)_| |_|
(C)2015 Semtech
Description: LoRaMac classA device implementation
License: Revised BSD License, see LICENSE.TXT file include in the project
Maintainer: Miguel Luis and Gregory Cristian
*/
#include "mbed.h"
#include "board.h"
#include "radio.h"
#include "LoRaMac.h"
#include "Comissioning.h"
#include "SerialDisplay.h"
/*!
* Join requests trials duty cycle.
*/
#define OVER_THE_AIR_ACTIVATION_DUTYCYCLE 10000000 // 10 [s] value in us
/*!
* Defines the application data transmission duty cycle. 5s, value in [us].
*/
#define APP_TX_DUTYCYCLE 5000000
/*!
* Defines a random delay for application data transmission duty cycle. 1s,
* value in [us].
*/
#define APP_TX_DUTYCYCLE_RND 1000000
/*!
* Default mote datarate
*/
#define LORAWAN_DEFAULT_DATARATE DR_0
/*!
* LoRaWAN confirmed messages
*/
#define LORAWAN_CONFIRMED_MSG_ON true
/*!
* LoRaWAN Adaptive Data Rate
*
* \remark Please note that when ADR is enabled the end-device should be static
*/
#define LORAWAN_ADR_ON 1
#if defined( USE_BAND_868 )
#include "LoRaMacTest.h"
/*!
* LoRaWAN ETSI duty cycle control enable/disable
*
* \remark Please note that ETSI mandates duty cycled transmissions. Use only for test purposes
*/
#define LORAWAN_DUTYCYCLE_ON true
#endif
/*!
* LoRaWAN application port
*/
#define LORAWAN_APP_PORT 15
/*!
* User application data buffer size
*/
#if ( LORAWAN_CONFIRMED_MSG_ON == 1 )
#define LORAWAN_APP_DATA_SIZE 6
#else
#define LORAWAN_APP_DATA_SIZE 1
#endif
#if( OVER_THE_AIR_ACTIVATION != 0 )
static uint8_t DevEui[] = LORAWAN_DEVICE_EUI;
static uint8_t AppEui[] = LORAWAN_APPLICATION_EUI;
static uint8_t AppKey[] = LORAWAN_APPLICATION_KEY;
#else
static uint8_t NwkSKey[] = LORAWAN_NWKSKEY;
static uint8_t AppSKey[] = LORAWAN_APPSKEY;
/*!
* Device address
*/
static uint32_t DevAddr = LORAWAN_DEVICE_ADDRESS;
#endif
/*!
* Application port
*/
static uint8_t AppPort = LORAWAN_APP_PORT;
/*!
* User application data size
*/
static uint8_t AppDataSize = LORAWAN_APP_DATA_SIZE;
/*!
* User application data buffer size
*/
#define LORAWAN_APP_DATA_MAX_SIZE 64
/*!
* User application data
*/
static uint8_t AppData[LORAWAN_APP_DATA_MAX_SIZE];
/*!
* Indicates if the node is sending confirmed or unconfirmed messages
*/
static uint8_t IsTxConfirmed = LORAWAN_CONFIRMED_MSG_ON;
/*!
* Defines the application data transmission duty cycle
*/
static uint32_t TxDutyCycleTime;
/*!
* Timer to handle the application data transmission duty cycle
*/
static TimerEvent_t TxNextPacketTimer;
/*!
* Specifies the state of the application LED
*/
static bool AppLedStateOn = false;
volatile bool Led3StateChanged = false;
/*!
* Timer to handle the state of LED1
*/
static TimerEvent_t Led1Timer;
volatile bool Led1State = false;
volatile bool Led1StateChanged = false;
/*!
* Timer to handle the state of LED2
*/
static TimerEvent_t Led2Timer;
volatile bool Led2State = false;
volatile bool Led2StateChanged = false;
/*!
* Indicates if a new packet can be sent
*/
static bool NextTx = true;
/*!
* Device states
*/
static enum eDevicState
{
DEVICE_STATE_INIT,
DEVICE_STATE_JOIN,
DEVICE_STATE_SEND,
DEVICE_STATE_CYCLE,
DEVICE_STATE_SLEEP
}DeviceState;
/*!
* LoRaWAN compliance tests support data
*/
struct ComplianceTest_s
{
bool Running;
uint8_t State;
bool IsTxConfirmed;
uint8_t AppPort;
uint8_t AppDataSize;
uint8_t *AppDataBuffer;
uint16_t DownLinkCounter;
bool LinkCheck;
uint8_t DemodMargin;
uint8_t NbGateways;
}ComplianceTest;
/*
* SerialDisplay managment variables
*/
/*!
* Indicates if the MAC layer network join status has changed.
*/
static bool IsNetworkJoinedStatusUpdate = false;
/*!
* Strucure containing the Uplink status
*/
struct sLoRaMacUplinkStatus
{
uint8_t Acked;
int8_t Datarate;
uint16_t UplinkCounter;
uint8_t Port;
uint8_t *Buffer;
uint8_t BufferSize;
}LoRaMacUplinkStatus;
volatile bool UplinkStatusUpdated = false;
/*!
* Strucure containing the Downlink status
*/
struct sLoRaMacDownlinkStatus
{
int16_t Rssi;
int8_t Snr;
uint16_t DownlinkCounter;
bool RxData;
uint8_t Port;
uint8_t *Buffer;
uint8_t BufferSize;
}LoRaMacDownlinkStatus;
volatile bool DownlinkStatusUpdated = false;
void SerialDisplayRefresh( void )
{
MibRequestConfirm_t mibReq;
SerialDisplayInit( );
SerialDisplayUpdateActivationMode( OVER_THE_AIR_ACTIVATION );
#if( OVER_THE_AIR_ACTIVATION == 0 )
SerialDisplayUpdateNwkId( LORAWAN_NETWORK_ID );
SerialDisplayUpdateDevAddr( DevAddr );
SerialDisplayUpdateKey( 12, NwkSKey );
SerialDisplayUpdateKey( 13, AppSKey );
#else
SerialDisplayUpdateEui( 5, DevEui );
SerialDisplayUpdateEui( 6, AppEui );
SerialDisplayUpdateKey( 7, AppKey );
#endif
mibReq.Type = MIB_NETWORK_JOINED;
LoRaMacMibGetRequestConfirm( &mibReq );
SerialDisplayUpdateNetworkIsJoined( mibReq.Param.IsNetworkJoined );
SerialDisplayUpdateAdr( LORAWAN_ADR_ON );
#if defined( USE_BAND_868 )
SerialDisplayUpdateDutyCycle( LORAWAN_DUTYCYCLE_ON );
#else
SerialDisplayUpdateDutyCycle( false );
#endif
SerialDisplayUpdatePublicNetwork( LORAWAN_PUBLIC_NETWORK );
SerialDisplayUpdateLedState( 3, AppLedStateOn );
}
void SerialRxProcess( void )
{
if( SerialDisplayReadable( ) == true )
{
switch( SerialDisplayGetChar( ) )
{
case 'R':
case 'r':
// Refresh Serial screen
SerialDisplayRefresh( );
break;
default:
break;
}
}
}
/*!
* \brief Prepares the payload of the frame
*/
static void PrepareTxFrame( uint8_t port )
{
switch( port )
{
case 15:
{
AppData[0] = AppLedStateOn;
if( IsTxConfirmed == true )
{
AppData[1] = LoRaMacDownlinkStatus.DownlinkCounter >> 8;
AppData[2] = LoRaMacDownlinkStatus.DownlinkCounter;
AppData[3] = LoRaMacDownlinkStatus.Rssi >> 8;
AppData[4] = LoRaMacDownlinkStatus.Rssi;
AppData[5] = LoRaMacDownlinkStatus.Snr;
}
}
break;
case 224:
if( ComplianceTest.LinkCheck == true )
{
ComplianceTest.LinkCheck = false;
AppDataSize = 3;
AppData[0] = 5;
AppData[1] = ComplianceTest.DemodMargin;
AppData[2] = ComplianceTest.NbGateways;
ComplianceTest.State = 1;
}
else
{
switch( ComplianceTest.State )
{
case 4:
ComplianceTest.State = 1;
break;
case 1:
AppDataSize = 2;
AppData[0] = ComplianceTest.DownLinkCounter >> 8;
AppData[1] = ComplianceTest.DownLinkCounter;
break;
}
}
break;
default:
break;
}
}
/*!
* \brief Prepares the payload of the frame
*
* \retval [0: frame could be send, 1: error]
*/
static bool SendFrame( void )
{
McpsReq_t mcpsReq;
LoRaMacTxInfo_t txInfo;
if( LoRaMacQueryTxPossible( AppDataSize, &txInfo ) != LORAMAC_STATUS_OK )
{
// Send empty frame in order to flush MAC commands
mcpsReq.Type = MCPS_UNCONFIRMED;
mcpsReq.Req.Unconfirmed.fBuffer = NULL;
mcpsReq.Req.Unconfirmed.fBufferSize = 0;
mcpsReq.Req.Unconfirmed.Datarate = LORAWAN_DEFAULT_DATARATE;
LoRaMacUplinkStatus.Acked = false;
LoRaMacUplinkStatus.Port = 0;
LoRaMacUplinkStatus.Buffer = NULL;
LoRaMacUplinkStatus.BufferSize = 0;
SerialDisplayUpdateFrameType( false );
}
else
{
LoRaMacUplinkStatus.Acked = false;
LoRaMacUplinkStatus.Port = AppPort;
LoRaMacUplinkStatus.Buffer = AppData;
LoRaMacUplinkStatus.BufferSize = AppDataSize;
SerialDisplayUpdateFrameType( IsTxConfirmed );
if( IsTxConfirmed == false )
{
mcpsReq.Type = MCPS_UNCONFIRMED;
mcpsReq.Req.Unconfirmed.fPort = AppPort;
mcpsReq.Req.Unconfirmed.fBuffer = AppData;
mcpsReq.Req.Unconfirmed.fBufferSize = AppDataSize;
mcpsReq.Req.Unconfirmed.Datarate = LORAWAN_DEFAULT_DATARATE;
}
else
{
mcpsReq.Type = MCPS_CONFIRMED;
mcpsReq.Req.Confirmed.fPort = AppPort;
mcpsReq.Req.Confirmed.fBuffer = AppData;
mcpsReq.Req.Confirmed.fBufferSize = AppDataSize;
mcpsReq.Req.Confirmed.NbTrials = 8;
mcpsReq.Req.Confirmed.Datarate = LORAWAN_DEFAULT_DATARATE;
}
}
if( LoRaMacMcpsRequest( &mcpsReq ) == LORAMAC_STATUS_OK )
{
return false;
}
return true;
}
/*!
* \brief Function executed on TxNextPacket Timeout event
*/
static void OnTxNextPacketTimerEvent( void )
{
MibRequestConfirm_t mibReq;
LoRaMacStatus_t status;
TimerStop( &TxNextPacketTimer );
mibReq.Type = MIB_NETWORK_JOINED;
status = LoRaMacMibGetRequestConfirm( &mibReq );
if( status == LORAMAC_STATUS_OK )
{
if( mibReq.Param.IsNetworkJoined == true )
{
DeviceState = DEVICE_STATE_SEND;
NextTx = true;
}
else
{
DeviceState = DEVICE_STATE_JOIN;
}
}
}
/*!
* \brief Function executed on Led 1 Timeout event
*/
static void OnLed1TimerEvent( void )
{
TimerStop( &Led1Timer );
// Switch LED 1 OFF
Led1State = false;
Led1StateChanged = true;
}
/*!
* \brief Function executed on Led 2 Timeout event
*/
static void OnLed2TimerEvent( void )
{
TimerStop( &Led2Timer );
// Switch LED 2 OFF
Led2State = false;
Led2StateChanged = true;
}
/*!
* \brief MCPS-Confirm event function
*
* \param [IN] McpsConfirm - Pointer to the confirm structure,
* containing confirm attributes.
*/
static void McpsConfirm( McpsConfirm_t *McpsConfirm )
{
if( McpsConfirm->Status == LORAMAC_EVENT_INFO_STATUS_OK )
{
switch( McpsConfirm->McpsRequest )
{
case MCPS_UNCONFIRMED:
{
// Check Datarate
// Check TxPower
break;
}
case MCPS_CONFIRMED:
{
// Check Datarate
// Check TxPower
// Check AckReceived
// Check NbRetries
LoRaMacUplinkStatus.Acked = McpsConfirm->AckReceived;
break;
}
case MCPS_PROPRIETARY:
{
break;
}
default:
break;
}
LoRaMacUplinkStatus.Datarate = McpsConfirm->Datarate;
LoRaMacUplinkStatus.UplinkCounter = McpsConfirm->UpLinkCounter;
UplinkStatusUpdated = true;
}
NextTx = true;
}
/*!
* \brief MCPS-Indication event function
*
* \param [IN] McpsIndication - Pointer to the indication structure,
* containing indication attributes.
*/
static void McpsIndication( McpsIndication_t *McpsIndication )
{
if( McpsIndication->Status != LORAMAC_EVENT_INFO_STATUS_OK )
{
return;
}
switch( McpsIndication->McpsIndication )
{
case MCPS_UNCONFIRMED:
{
break;
}
case MCPS_CONFIRMED:
{
break;
}
case MCPS_PROPRIETARY:
{
break;
}
case MCPS_MULTICAST:
{
break;
}
default:
break;
}
// Check Multicast
// Check Port
// Check Datarate
// Check FramePending
// Check Buffer
// Check BufferSize
// Check Rssi
// Check Snr
// Check RxSlot
LoRaMacDownlinkStatus.Rssi = McpsIndication->Rssi;
if( McpsIndication->Snr & 0x80 ) // The SNR sign bit is 1
{
// Invert and divide by 4
LoRaMacDownlinkStatus.Snr = ( ( ~McpsIndication->Snr + 1 ) & 0xFF ) >> 2;
LoRaMacDownlinkStatus.Snr = -LoRaMacDownlinkStatus.Snr;
}
else
{
// Divide by 4
LoRaMacDownlinkStatus.Snr = ( McpsIndication->Snr & 0xFF ) >> 2;
}
LoRaMacDownlinkStatus.DownlinkCounter++;
LoRaMacDownlinkStatus.RxData = McpsIndication->RxData;
LoRaMacDownlinkStatus.Port = McpsIndication->Port;
LoRaMacDownlinkStatus.Buffer = McpsIndication->Buffer;
LoRaMacDownlinkStatus.BufferSize = McpsIndication->BufferSize;
if( ComplianceTest.Running == true )
{
ComplianceTest.DownLinkCounter++;
}
if( McpsIndication->RxData == true )
{
switch( McpsIndication->Port )
{
case 1: // The application LED can be controlled on port 1 or 2
case 2:
if( McpsIndication->BufferSize == 1 )
{
AppLedStateOn = McpsIndication->Buffer[0] & 0x01;
Led3StateChanged = true;
}
break;
case 224:
if( ComplianceTest.Running == false )
{
// Check compliance test enable command (i)
if( ( McpsIndication->BufferSize == 4 ) &&
( McpsIndication->Buffer[0] == 0x01 ) &&
( McpsIndication->Buffer[1] == 0x01 ) &&
( McpsIndication->Buffer[2] == 0x01 ) &&
( McpsIndication->Buffer[3] == 0x01 ) )
{
IsTxConfirmed = false;
AppPort = 224;
AppDataSize = 2;
ComplianceTest.DownLinkCounter = 0;
ComplianceTest.LinkCheck = false;
ComplianceTest.DemodMargin = 0;
ComplianceTest.NbGateways = 0;
ComplianceTest.Running = true;
ComplianceTest.State = 1;
MibRequestConfirm_t mibReq;
mibReq.Type = MIB_ADR;
mibReq.Param.AdrEnable = true;
LoRaMacMibSetRequestConfirm( &mibReq );
#if defined( USE_BAND_868 )
LoRaMacTestSetDutyCycleOn( false );
#endif
}
}
else
{
ComplianceTest.State = McpsIndication->Buffer[0];
switch( ComplianceTest.State )
{
case 0: // Check compliance test disable command (ii)
IsTxConfirmed = LORAWAN_CONFIRMED_MSG_ON;
AppPort = LORAWAN_APP_PORT;
AppDataSize = LORAWAN_APP_DATA_SIZE;
ComplianceTest.DownLinkCounter = 0;
ComplianceTest.Running = false;
MibRequestConfirm_t mibReq;
mibReq.Type = MIB_ADR;
mibReq.Param.AdrEnable = LORAWAN_ADR_ON;
LoRaMacMibSetRequestConfirm( &mibReq );
#if defined( USE_BAND_868 )
LoRaMacTestSetDutyCycleOn( LORAWAN_DUTYCYCLE_ON );
#endif
break;
case 1: // (iii, iv)
AppDataSize = 2;
break;
case 2: // Enable confirmed messages (v)
IsTxConfirmed = true;
ComplianceTest.State = 1;
break;
case 3: // Disable confirmed messages (vi)
IsTxConfirmed = false;
ComplianceTest.State = 1;
break;
case 4: // (vii)
AppDataSize = McpsIndication->BufferSize;
AppData[0] = 4;
for( uint8_t i = 1; i < AppDataSize; i++ )
{
AppData[i] = McpsIndication->Buffer[i] + 1;
}
break;
case 5: // (viii)
{
MlmeReq_t mlmeReq;
mlmeReq.Type = MLME_LINK_CHECK;
LoRaMacMlmeRequest( &mlmeReq );
}
break;
default:
break;
}
}
break;
default:
break;
}
}
// Switch LED 2 ON for each received downlink
Led2State = true;
Led2StateChanged = true;
TimerStart( &Led2Timer );
DownlinkStatusUpdated = true;
}
/*!
* \brief MLME-Confirm event function
*
* \param [IN] MlmeConfirm - Pointer to the confirm structure,
* containing confirm attributes.
*/
static void MlmeConfirm( MlmeConfirm_t *MlmeConfirm )
{
if( MlmeConfirm->Status == LORAMAC_EVENT_INFO_STATUS_OK )
{
switch( MlmeConfirm->MlmeRequest )
{
case MLME_JOIN:
{
// Status is OK, node has joined the network
IsNetworkJoinedStatusUpdate = true;
break;
}
case MLME_LINK_CHECK:
{
// Check DemodMargin
// Check NbGateways
if( ComplianceTest.Running == true )
{
ComplianceTest.LinkCheck = true;
ComplianceTest.DemodMargin = MlmeConfirm->DemodMargin;
ComplianceTest.NbGateways = MlmeConfirm->NbGateways;
}
break;
}
default:
break;
}
}
NextTx = true;
UplinkStatusUpdated = true;
}
/**
* Main application entry point.
*/
int main( void )
{
LoRaMacPrimitives_t LoRaMacPrimitives;
LoRaMacCallback_t LoRaMacCallbacks;
MibRequestConfirm_t mibReq;
BoardInit( );
SerialDisplayInit( );
DeviceState = DEVICE_STATE_INIT;
while( 1 )
{
SerialRxProcess( );
if( IsNetworkJoinedStatusUpdate == true )
{
IsNetworkJoinedStatusUpdate = false;
mibReq.Type = MIB_NETWORK_JOINED;
LoRaMacMibGetRequestConfirm( &mibReq );
SerialDisplayUpdateNetworkIsJoined( mibReq.Param.IsNetworkJoined );
}
if( Led1StateChanged == true )
{
Led1StateChanged = false;
SerialDisplayUpdateLedState( 1, Led1State );
}
if( Led2StateChanged == true )
{
Led2StateChanged = false;
SerialDisplayUpdateLedState( 2, Led2State );
}
if( Led3StateChanged == true )
{
Led3StateChanged = false;
SerialDisplayUpdateLedState( 3, AppLedStateOn );
}
if( UplinkStatusUpdated == true )
{
UplinkStatusUpdated = false;
SerialDisplayUpdateUplink( LoRaMacUplinkStatus.Acked, LoRaMacUplinkStatus.Datarate, LoRaMacUplinkStatus.UplinkCounter, LoRaMacUplinkStatus.Port, LoRaMacUplinkStatus.Buffer, LoRaMacUplinkStatus.BufferSize );
}
if( DownlinkStatusUpdated == true )
{
DownlinkStatusUpdated = false;
SerialDisplayUpdateLedState( 2, Led2State );
SerialDisplayUpdateDownlink( LoRaMacDownlinkStatus.RxData, LoRaMacDownlinkStatus.Rssi, LoRaMacDownlinkStatus.Snr, LoRaMacDownlinkStatus.DownlinkCounter, LoRaMacDownlinkStatus.Port, LoRaMacDownlinkStatus.Buffer, LoRaMacDownlinkStatus.BufferSize );
}
switch( DeviceState )
{
case DEVICE_STATE_INIT:
{
LoRaMacPrimitives.MacMcpsConfirm = McpsConfirm;
LoRaMacPrimitives.MacMcpsIndication = McpsIndication;
LoRaMacPrimitives.MacMlmeConfirm = MlmeConfirm;
LoRaMacCallbacks.GetBatteryLevel = BoardGetBatteryLevel;
LoRaMacInitialization( &LoRaMacPrimitives, &LoRaMacCallbacks );
TimerInit( &TxNextPacketTimer, OnTxNextPacketTimerEvent );
TimerInit( &Led1Timer, OnLed1TimerEvent );
TimerSetValue( &Led1Timer, 25000 );
TimerInit( &Led2Timer, OnLed2TimerEvent );
TimerSetValue( &Led2Timer, 25000 );
mibReq.Type = MIB_ADR;
mibReq.Param.AdrEnable = LORAWAN_ADR_ON;
LoRaMacMibSetRequestConfirm( &mibReq );
mibReq.Type = MIB_PUBLIC_NETWORK;
mibReq.Param.EnablePublicNetwork = LORAWAN_PUBLIC_NETWORK;
LoRaMacMibSetRequestConfirm( &mibReq );
#if defined( USE_BAND_868 )
LoRaMacTestSetDutyCycleOn( LORAWAN_DUTYCYCLE_ON );
SerialDisplayUpdateDutyCycle( LORAWAN_DUTYCYCLE_ON );
#endif
SerialDisplayUpdateActivationMode( OVER_THE_AIR_ACTIVATION );
SerialDisplayUpdateAdr( LORAWAN_ADR_ON );
SerialDisplayUpdatePublicNetwork( LORAWAN_PUBLIC_NETWORK );
LoRaMacDownlinkStatus.DownlinkCounter = 0;
DeviceState = DEVICE_STATE_JOIN;
break;
}
case DEVICE_STATE_JOIN:
{
#if( OVER_THE_AIR_ACTIVATION != 0 )
MlmeReq_t mlmeReq;
mlmeReq.Type = MLME_JOIN;
mlmeReq.Req.Join.DevEui = DevEui;
mlmeReq.Req.Join.AppEui = AppEui;
mlmeReq.Req.Join.AppKey = AppKey;
if( NextTx == true )
{
LoRaMacMlmeRequest( &mlmeReq );
}
SerialDisplayUpdateEui( 5, DevEui );
SerialDisplayUpdateEui( 6, AppEui );
SerialDisplayUpdateKey( 7, AppKey );
// Schedule next packet transmission
TxDutyCycleTime = OVER_THE_AIR_ACTIVATION_DUTYCYCLE;
DeviceState = DEVICE_STATE_CYCLE;
#else
mibReq.Type = MIB_NET_ID;
mibReq.Param.NetID = LORAWAN_NETWORK_ID;
LoRaMacMibSetRequestConfirm( &mibReq );
mibReq.Type = MIB_DEV_ADDR;
mibReq.Param.DevAddr = DevAddr;
LoRaMacMibSetRequestConfirm( &mibReq );
mibReq.Type = MIB_NWK_SKEY;
mibReq.Param.NwkSKey = NwkSKey;
LoRaMacMibSetRequestConfirm( &mibReq );
mibReq.Type = MIB_APP_SKEY;
mibReq.Param.AppSKey = AppSKey;
LoRaMacMibSetRequestConfirm( &mibReq );
mibReq.Type = MIB_NETWORK_JOINED;
mibReq.Param.IsNetworkJoined = true;
LoRaMacMibSetRequestConfirm( &mibReq );
SerialDisplayUpdateNwkId( LORAWAN_NETWORK_ID );
SerialDisplayUpdateDevAddr( DevAddr );
SerialDisplayUpdateKey( 12, NwkSKey );
SerialDisplayUpdateKey( 13, AppSKey );
DeviceState = DEVICE_STATE_SEND;
#endif
IsNetworkJoinedStatusUpdate = true;
break;
}
case DEVICE_STATE_SEND:
{
if( NextTx == true )
{
SerialDisplayUpdateUplinkAcked( false );
SerialDisplayUpdateDonwlinkRxData( false );
PrepareTxFrame( AppPort );
NextTx = SendFrame( );
// Switch LED 1 ON
Led1State = true;
Led1StateChanged = true;
TimerStart( &Led1Timer );
}
if( ComplianceTest.Running == true )
{
// Schedule next packet transmission as soon as possible
TxDutyCycleTime = 1000; // 1 ms
}
else
{
// Schedule next packet transmission
TxDutyCycleTime = APP_TX_DUTYCYCLE + randr( -APP_TX_DUTYCYCLE_RND, APP_TX_DUTYCYCLE_RND );
}
DeviceState = DEVICE_STATE_CYCLE;
break;
}
case DEVICE_STATE_CYCLE:
{
// Schedule next packet transmission
TimerSetValue( &TxNextPacketTimer, TxDutyCycleTime );
TimerStart( &TxNextPacketTimer );
DeviceState = DEVICE_STATE_SLEEP;
break;
}
case DEVICE_STATE_SLEEP:
{
// Wake up through events
break;
}
default:
{
DeviceState = DEVICE_STATE_INIT;
break;
}
}
}
}