LoRaWAN end device MAC layer for SX1272 and SX1276. Supports LoRaWAN-1.0 and LoRaWAN-1.1
Dependents: LoRaWAN-SanJose_Bootcamp LoRaWAN-grove-cayenne LoRaWAN-classC-demo LoRaWAN-grove-cayenne ... more
radio chip selection
Radio chip driver is not included, because two options are available.
If you're using SX1272 or SX1276, then import sx127x driver into your program.
if you're using SX1261 or SX1262, then import sx126x driver into your program.
If you're using NAmote72 or Murata discovery, then you must import only sx127x driver.
application project requirements
This library requires mbed TLS to be enabled.
The file mbed_app.json
must be present in the project using this library:
{ "macros": [ "MBEDTLS_CMAC_C" ] }
regional PHY selection
All end device configuration is done in Commissioning.h, define desired radio frequency band of operation in this header file.
Commissioning.h is located in the application using this library.
end device provisioning
End device is provisioned by editing Commissioning.h in the application which is using this library
To use LoRaWAN-1.0 OTA: make sure LORAWAN_ROOT_APPKEY
is undefined.
To use LoRaWAN-1.1 OTA, define LORAWAN_ROOT_APPKEY
.
To select OTA operation, define LORAWAN_JOIN_EUI
, then LORAWAN_DEVICE_EUI
must be defined, along with root key(s).
To select ABP operation, undefine LORAWAN_JOIN_EUI
: then define session keys
LoRaWAN 1.0 name | LoRaWAN 1.1 name | Comissioning.h defne | description | |
---|---|---|---|---|
OTA | DevEUI | DevEUI | LORAWAN_DEVICE_EUI | uniquely identifies end device |
OTA | AppEUI | JoinEUI | LORAWAN_JOIN_EUI | |
OTA | AppKey | NwkKey | LORAWAN_ROOT_NWKKEY | root key for network server |
OTA | (note 1) | AppKey | LORAWAN_ROOT_APPKEY | root key for application server |
ABP | NwkSKey | (note 3) | LORAWAN_FNwkSIntKey | network session key |
ABP | (note 2) | SNwkSIntKey | LORAWAN_SNwkSIntKey | mac layer network integrity key |
ABP | (note 2) | NwkSEncKey | LORAWAN_NwkSEncKey | network session encryption key |
ABP | (note 2) | FNwkSIntKey | LORAWAN_FNwkSIntKey | forwarding network session integrity key |
ABP | AppSKey | AppSKey | LORAWAN_APPSKEY | application session encryption key |
(note 1): LoRaWAN-1.0 OTA uses a single root key for both network server and application server.
In LoRaWAN-1.0 OTA: the single root AppKey is used to generate NwkSkey and AppSKey.
(note 2): In LoRaWAN-1.0 (both OTA and ABP) SNwkSIntKey, NwkSEncKey. FNwkSIntKey are of same value and are collectively known as NwkSKey.
(note 3): LoRaWAN-1.0 uses single network session key, LoRaWAN-1.1 uses 3 network session keys. Both use a unique application session key.
In LoRaWAN-1.1 OTA: the root NwkKey is used to generate SNwkSIntKey, NwkSEncKey, FNwkSIntKey
In LoRaWAN-1.1 OTA: the root AppKey is used to generate AppSKey
in ABP mode, the DevAddr, and session keys are fixed (never change), and frame counters never reset to zero.
ABP operation has no concept of: root keys, or DevEUI or JoinEUI/AppEUI.
in OTA mode, the DevAddr and session keys are assigned at join procedure, and frame counters reset at join.
eeprom
This library includes eeprom driver to support non-volatile storage required by LoRaWAN specification.
Currently eeprom is implemented for STM32L1 family and STM32L0 family.
Writing of values are wear-leveled to increase endurance; each write operation circulates across several memory locations. A read operation returns the highest value found. This simple method is used for sequence numbers which only increase.
value name | used in | |
---|---|---|
DevNonce | OTA | for Join request (note 1) |
RJcount1 | OTA | for ReJoin Type 1 request |
FCntUp | ABP | uplink frame counter |
NFCntDown | ABP | downlink frame counter |
AFCntDown | ABP | downlink frame counter |
AFCntDown is only used in LoRaWAN-1.1 when application payload is present in downlink and FPort > 0.
NFCntDown is used in LoRaWAN-1.1 when FPort is zero in downlink or application payload not present.
NFCntDown is the only downlink frame counter used in LoRaWAN-1.0
(note 1) OTA DevNonce is random number in LoRaWAN-1.0, therefore not stored in eeprom. DevNonce in LoRaWAN-1.1 is forever increasing (non-volatile) number upon each join request,.
RJcount0 is only stored in RAM because the value resets upon new session from JoinAccept, therefore not stored in eeprom.
Frame counters in OTA mode reset upon new session in join request, therefore are stored in RAM instead of eeprom for OTA.
radio driver support
When SX127x driver is used, both SX1272 and SX1276 are supported without defining at compile time. The chip is detected at start-up.
Supported radio platforms:
Alternately, when SX126x driver is imported, the SX126xDVK1xAS board is used.
low-speed clock oscillator selection
LoRaWAN uses 32768Hz crystal to permit low-power operation.
However, some mbed targets might revert to low-speed internal oscillator, which is not accurate enough for LoRaWAN operation.
An oscillator check is performed at initialization; program will not start if internal oscillator is used.
To force LSE watch crystal, add to mbed_app.json
{ "macros": [ "MBEDTLS_CMAC_C" ], "target_overrides": { "<your-target>": { "target.lse_available": true } } }
mac/region_us915.cpp
- Committer:
- Wayne Roberts
- Date:
- 2018-03-05
- Revision:
- 3:eb174e10afbb
- Parent:
- 0:6b3ac9c5a042
- Child:
- 7:4b6f960dcca2
File content as of revision 3:eb174e10afbb:
#include "board.h" #if defined(USE_BAND_915_HYBRID) || defined(USE_BAND_915) #include <stdint.h> #include "LoRaMacPrivate.h" ChannelParams_t Channels[LORA_MAX_NB_CHANNELS]; uint16_t ChannelsMaskRemaining[6]; const int8_t TxPowers[] = { 30, 28, 26, 24, 22, 20, 18, 16, 14, 12, 10 }; // DR: 0 1 2 3 4 5 6 7 8 9 10 11 12 13 14 15 const uint8_t Datarates[] = { 10, 9, 8, 7, 8, 0, 0, 0, 12, 11, 10, 9, 8, 7, 0, 0}; const uint8_t MaxPayloadOfDatarate[] = { 11, 53, 125, 242, 242, 0, 0, 0, 53, 129, 242, 242, 242, 242, 0, 0 }; bool DisableChannelInMask( uint8_t id, uint16_t* mask ) { uint8_t index = 0; index = id / 16; if( ( index > 4 ) || ( id >= LORA_MAX_NB_CHANNELS ) ) { return false; } // Deactivate channel mask[index] &= ~( 1 << ( id % 16 ) ); return true; } /*! * Up/Down link data rates offset definition */ const int8_t datarateOffsets[5][4] = { { DR_10, DR_9 , DR_8 , DR_8 }, // DR_0 { DR_11, DR_10, DR_9 , DR_8 }, // DR_1 { DR_12, DR_11, DR_10, DR_9 }, // DR_2 { DR_13, DR_12, DR_11, DR_10 }, // DR_3 { DR_13, DR_13, DR_12, DR_11 }, // DR_4 }; uint32_t region_GetRxBandwidth( int8_t datarate ) { if( datarate >= DR_4 ) {// LoRa 500 kHz return 2; } return 0; // LoRa 125 kHz } uint16_t region_GetRxSymbolTimeout( int8_t datarate ) { switch( datarate ) { case DR_0: // SF10 - BW125 return 5; case DR_1: // SF9 - BW125 case DR_2: // SF8 - BW125 case DR_8: // SF12 - BW500 case DR_9: // SF11 - BW500 case DR_10: // SF10 - BW500 return 8; case DR_3: // SF7 - BW125 case DR_11: // SF9 - BW500 return 10; case DR_4: // SF8 - BW500 case DR_12: // SF8 - BW500 return 14; case DR_13: // SF7 - BW500 return 16; default: return 0; // LoRa 125 kHz } } void region_rx1_setup(uint8_t ch) { int8_t datarate = datarateOffsets[LoRaMacParams.ChannelsDatarate][LoRaMacParams.Rx1DrOffset]; if( datarate < 0 ) { datarate = DR_0; } RxWindowSetup( LORAMAC_FIRST_RX1_CHANNEL + ( ch % 8 ) * LORAMAC_STEPWIDTH_RX1_CHANNEL, datarate, region_GetRxBandwidth(datarate), region_GetRxSymbolTimeout(datarate) ); } bool ValidateChannelMask( uint16_t* channelsMask ) { bool chanMaskState = false; uint16_t block1 = 0; uint16_t block2 = 0; uint8_t index = 0; for( uint8_t i = 0; i < 4; i++ ) { block1 = channelsMask[i] & 0x00FF; block2 = channelsMask[i] & 0xFF00; if( ( CountBits( block1, 16 ) > 5 ) && ( chanMaskState == false ) ) { channelsMask[i] &= block1; channelsMask[4] = 1 << ( i * 2 ); chanMaskState = true; index = i; } else if( ( CountBits( block2, 16 ) > 5 ) && ( chanMaskState == false ) ) { channelsMask[i] &= block2; channelsMask[4] = 1 << ( i * 2 + 1 ); chanMaskState = true; index = i; } } // Do only change the channel mask, if we have found a valid block. if( chanMaskState == true ) { for( uint8_t i = 0; i < 4; i++ ) { if( i != index ) { channelsMask[i] = 0; } } } return chanMaskState; } void region_adr_request(adr_t* adr) { if( adr->chMaskCntl == 6 ) { // Enable all 125 kHz channels adr->channelsMask[0] = 0xFFFF; adr->channelsMask[1] = 0xFFFF; adr->channelsMask[2] = 0xFFFF; adr->channelsMask[3] = 0xFFFF; // Apply chMask to channels 64 to 71 adr->channelsMask[4] = adr->chMask; } else if( adr->chMaskCntl == 7 ) { // Disable all 125 kHz channels adr->channelsMask[0] = 0x0000; adr->channelsMask[1] = 0x0000; adr->channelsMask[2] = 0x0000; adr->channelsMask[3] = 0x0000; // Apply chMask to channels 64 to 71 adr->channelsMask[4] = adr->chMask; } else if( adr->chMaskCntl == 5 ) { // RFU adr->status &= 0xFE; // Channel mask KO } else { adr->channelsMask[adr->chMaskCntl] = adr->chMask; // FCC 15.247 paragraph F mandates to hop on at least 2 125 kHz channels if( ( adr->datarate < DR_4 ) && ( CountNbEnabled125kHzChannels( adr->channelsMask ) < 2 ) ) { adr->status &= 0xFE; // Channel mask KO } #if defined( USE_BAND_915_HYBRID ) if( ValidateChannelMask( adr->channelsMask ) == false ) { adr->status &= 0xFE; // Channel mask KO } #endif } if ((adr->status & 0x07) == 0x07) { // Reset ChannelsMaskRemaining to the new ChannelsMask ChannelsMaskRemaining[0] &= adr->channelsMask[0]; ChannelsMaskRemaining[1] &= adr->channelsMask[1]; ChannelsMaskRemaining[2] &= adr->channelsMask[2]; ChannelsMaskRemaining[3] &= adr->channelsMask[3]; ChannelsMaskRemaining[4] = adr->channelsMask[4]; ChannelsMaskRemaining[5] = adr->channelsMask[5]; } } uint8_t region_CountNbEnabledChannels() { return CountNbEnabled125kHzChannels(LoRaMacParams.ChannelsMask) + CountBits(LoRaMacParams.ChannelsMask[4], 16); } uint8_t CountNbEnabled125kHzChannels( uint16_t *channelsMask ) { uint8_t nb125kHzChannels = 0; for( uint8_t i = 0, k = 0; i < LORA_MAX_NB_CHANNELS - 8; i += 16, k++ ) { nb125kHzChannels += CountBits( channelsMask[k], 16 ); } return nb125kHzChannels; } static bool SetNextChannel( ) { uint8_t nbEnabledChannels = 0; uint8_t enabledChannels[LORA_MAX_NB_CHANNELS]; memset( enabledChannels, 0, LORA_MAX_NB_CHANNELS ); if( CountNbEnabled125kHzChannels( ChannelsMaskRemaining ) == 0 ) { // Restore default channels memcpy( ( uint8_t* ) ChannelsMaskRemaining, ( uint8_t* ) LoRaMacParams.ChannelsMask, 8 ); } if( ( LoRaMacParams.ChannelsDatarate >= DR_4 ) && ( ( ChannelsMaskRemaining[4] & 0x00FF ) == 0 ) ) { // Make sure, that the channels are activated ChannelsMaskRemaining[4] = LoRaMacParams.ChannelsMask[4]; } // Search how many channels are enabled for( uint8_t i = 0, k = 0; i < LORA_MAX_NB_CHANNELS; i += 16, k++ ) { for( uint8_t j = 0; j < 16; j++ ) { if( ( ChannelsMaskRemaining[k] & ( 1 << j ) ) != 0 ) { if( Channels[i + j].FreqHz == 0 ) { // Check if the channel is enabled continue; } if( ( ( Channels[i + j].DrRange.Fields.Min <= LoRaMacParams.ChannelsDatarate ) && ( LoRaMacParams.ChannelsDatarate <= Channels[i + j].DrRange.Fields.Max ) ) == false ) { // Check if the current channel selection supports the given datarate continue; } enabledChannels[nbEnabledChannels++] = i + j; } } } if( nbEnabledChannels > 0 ) { Channel = enabledChannels[random_at_most( nbEnabledChannels - 1 )]; if( Channel < ( LORA_MAX_NB_CHANNELS - 8 ) ) { DisableChannelInMask( Channel, ChannelsMaskRemaining ); } return true; } else { // Datarate not supported by any channel return false; } } void region_ScheduleTx( ) { // Select channel while( SetNextChannel() == false ) { // Set the default datarate LoRaMacParams.ChannelsDatarate = LoRaMacParamsDefaults.ChannelsDatarate; } //MAC_PRINTF("ch%u ", Channel); SendFrameOnChannel( Channel ); } void region_tx_setup(int8_t dbm, uint8_t pktLen) { int8_t datarate = Datarates[LoRaMacParams.ChannelsDatarate]; //MAC_PRINTF("txsetup sf%d dr%u ", datarate, LoRaMacParams.ChannelsDatarate); if( LoRaMacParams.ChannelsDatarate >= DR_4 ) { // High speed LoRa channel BW500 kHz Radio::SetTxConfig( MODEM_LORA, dbm, 0, 2, datarate, 1, 8, false, true, false); //TxTimeOnAir_us = Radio.TimeOnAir_us( MODEM_LORA, pktLen ); } else { // Normal LoRa channel Radio::SetTxConfig( MODEM_LORA, dbm, 0, 0, datarate, 1, 8, false, true, false); //TxTimeOnAir_us = Radio.TimeOnAir_us( MODEM_LORA, pktLen ); } } #define RECEIVE_DELAY2_us 2000000 #define JOIN_ACCEPT_DELAY1_us 5000000 #define JOIN_ACCEPT_DELAY2_us 6000000 const LoRaMacParams_t LoRaMacParamsDefaults = { /* int8_t ChannelsTxPower; */ LORAMAC_DEFAULT_TX_POWER, /* int8_t ChannelsDatarate;*/ LORAMAC_DEFAULT_DATARATE, /* uint32_t MaxRxWindow_us;*/ MAX_RX_WINDOW_us, /* uint32_t ReceiveDelay1_us;*/ RECEIVE_DELAY1_us, /* uint32_t ReceiveDelay2_us;*/ RECEIVE_DELAY2_us, #ifdef LORAWAN_JOIN_EUI /* uint32_t JoinAcceptDelay1_us;*/ JOIN_ACCEPT_DELAY1_us, /* uint32_t JoinAcceptDelay2_us;*/ JOIN_ACCEPT_DELAY2_us, #endif /* LORAWAN_JOIN_EUI */ /* uint8_t NbTrans;*/ 1, /* uint8_t Rx1DrOffset;*/ 0, /* Rx2ChannelParams_t Rx2Channel;*/ RX_WND_2_CHANNEL, #if defined( USE_BAND_915 ) /* uint16_t ChannelsMask[6];*/ { 0xffff, 0xffff, 0xffff, 0xffff, 0x00ff, 0x0000}, /* uint8_t NbEnabledChannels;*/ 72, #elif defined( USE_BAND_915_HYBRID ) /* uint16_t ChannelsMask[6];*/ { 0x00ff, 0x0000, 0x0000, 0x0000, 0x0001, 0x0000}, /* uint8_t NbEnabledChannels;*/ 9 #endif }; void region_mac_init() { // 125 kHz channels for( uint8_t i = 0; i < LORA_MAX_NB_CHANNELS - 8; i++ ) { Channels[i].FreqHz = 902.3e6 + i * 200e3; Channels[i].DrRange.Value = ( DR_3 << 4 ) | DR_0; Channels[i].Band = 0; } // 500 kHz channels for( uint8_t i = LORA_MAX_NB_CHANNELS - 8; i < LORA_MAX_NB_CHANNELS; i++ ) { Channels[i].FreqHz = 903.0e6 + ( i - ( LORA_MAX_NB_CHANNELS - 8 ) ) * 1.6e6; Channels[i].DrRange.Value = ( DR_4 << 4 ) | DR_4; Channels[i].Band = 0; } } int8_t region_LimitTxPower( int8_t txPower ) { int8_t resultTxPower = txPower; if( ( LoRaMacParams.ChannelsDatarate == DR_4 ) || ( ( LoRaMacParams.ChannelsDatarate >= DR_8 ) && ( LoRaMacParams.ChannelsDatarate <= DR_13 ) ) ) {// Limit tx power to max 26dBm resultTxPower = MAX( txPower, TX_POWER_26_DBM ); } else { if( CountNbEnabled125kHzChannels( LoRaMacParams.ChannelsMask ) < 50 ) {// Limit tx power to max 21dBm resultTxPower = MAX( txPower, TX_POWER_20_DBM ); } } return resultTxPower; } #ifdef LORAWAN_JOIN_EUI int8_t region_AlternateDatarate( uint16_t nbTrials ) { if (region_CountNbEnabledChannels() < LoRaMacParamsDefaults.NbEnabledChannels) { memcpy(LoRaMacParams.ChannelsMask, LoRaMacParamsDefaults.ChannelsMask, sizeof(LoRaMacParams.ChannelsMask)); LoRaMacParams.NbEnabledChannels = LoRaMacParamsDefaults.NbEnabledChannels; } if( ( nbTrials & 0x01 ) == 0x01 ) { return DR_4; } else { return DR_0; } } #endif /* LORAWAN_JOIN_EUI */ void region_session_start(LoRaMacEventInfoStatus_t status) { } #endif /* USE_BAND_915_HYBRID || USE_BAND_915 */