EU 868Mhz configured version of LMiC 1.5
Dependents: STM32F103C8T6_LoRaWAN-lmic-app
Fork of LMiC by
radio.cpp@3:519c71d29a06, 2015-11-26 (annotated)
- Committer:
- mluis
- Date:
- Thu Nov 26 12:46:56 2015 +0000
- Revision:
- 3:519c71d29a06
- Parent:
- 1:d3b7bde3995c
- Child:
- 4:85b2b647cb64
Adapted radio.cpp to new version of SX1276Lib radio driver; Small corrections on lmic.c/lmic.h
Who changed what in which revision?
User | Revision | Line number | New contents of line |
---|---|---|---|
mluis | 0:62d1edcc13d1 | 1 | /******************************************************************************* |
mluis | 1:d3b7bde3995c | 2 | * Copyright (c) 2014-2015 IBM Corporation. |
mluis | 0:62d1edcc13d1 | 3 | * All rights reserved. This program and the accompanying materials |
mluis | 0:62d1edcc13d1 | 4 | * are made available under the terms of the Eclipse Public License v1.0 |
mluis | 0:62d1edcc13d1 | 5 | * which accompanies this distribution, and is available at |
mluis | 0:62d1edcc13d1 | 6 | * http://www.eclipse.org/legal/epl-v10.html |
mluis | 0:62d1edcc13d1 | 7 | * |
mluis | 0:62d1edcc13d1 | 8 | * Contributors: |
mluis | 0:62d1edcc13d1 | 9 | * IBM Zurich Research Lab - initial API, implementation and documentation |
mluis | 0:62d1edcc13d1 | 10 | * Semtech Apps Team - Modified to support the MBED sx1276 driver |
mluis | 0:62d1edcc13d1 | 11 | * library. |
mluis | 0:62d1edcc13d1 | 12 | * Possibility to use original or Semtech's MBED |
mluis | 0:62d1edcc13d1 | 13 | * radio driver. The selection is done by setting |
mluis | 0:62d1edcc13d1 | 14 | * USE_SMTC_RADIO_DRIVER preprocessing directive |
mluis | 0:62d1edcc13d1 | 15 | * in lmic.h |
mluis | 0:62d1edcc13d1 | 16 | *******************************************************************************/ |
mluis | 1:d3b7bde3995c | 17 | |
mluis | 0:62d1edcc13d1 | 18 | #include "lmic.h" |
mluis | 0:62d1edcc13d1 | 19 | |
mluis | 0:62d1edcc13d1 | 20 | #if USE_SMTC_RADIO_DRIVER |
mluis | 0:62d1edcc13d1 | 21 | #include "sx1276-hal.h" |
mluis | 0:62d1edcc13d1 | 22 | |
mluis | 0:62d1edcc13d1 | 23 | /*! |
mluis | 1:d3b7bde3995c | 24 | * Syncword for lora networks |
mluis | 0:62d1edcc13d1 | 25 | */ |
mluis | 1:d3b7bde3995c | 26 | #define LORA_MAC_SYNCWORD 0x34 |
mluis | 0:62d1edcc13d1 | 27 | |
mluis | 0:62d1edcc13d1 | 28 | /* |
mluis | 0:62d1edcc13d1 | 29 | * Callback functions prototypes |
mluis | 0:62d1edcc13d1 | 30 | */ |
mluis | 0:62d1edcc13d1 | 31 | /*! |
mluis | 0:62d1edcc13d1 | 32 | * @brief Function to be executed on Radio Tx Done event |
mluis | 0:62d1edcc13d1 | 33 | */ |
mluis | 0:62d1edcc13d1 | 34 | void OnTxDone( void ); |
mluis | 0:62d1edcc13d1 | 35 | |
mluis | 0:62d1edcc13d1 | 36 | /*! |
mluis | 0:62d1edcc13d1 | 37 | * @brief Function to be executed on Radio Rx Done event |
mluis | 0:62d1edcc13d1 | 38 | */ |
mluis | 0:62d1edcc13d1 | 39 | void OnRxDone( uint8_t *payload, uint16_t size, int16_t rssi, int8_t snr ); |
mluis | 0:62d1edcc13d1 | 40 | |
mluis | 0:62d1edcc13d1 | 41 | /*! |
mluis | 0:62d1edcc13d1 | 42 | * @brief Function executed on Radio Tx Timeout event |
mluis | 0:62d1edcc13d1 | 43 | */ |
mluis | 0:62d1edcc13d1 | 44 | void OnTxTimeout( void ); |
mluis | 0:62d1edcc13d1 | 45 | |
mluis | 0:62d1edcc13d1 | 46 | /*! |
mluis | 0:62d1edcc13d1 | 47 | * @brief Function executed on Radio Rx Timeout event |
mluis | 0:62d1edcc13d1 | 48 | */ |
mluis | 0:62d1edcc13d1 | 49 | void OnRxTimeout( void ); |
mluis | 0:62d1edcc13d1 | 50 | |
mluis | 0:62d1edcc13d1 | 51 | /*! |
mluis | 0:62d1edcc13d1 | 52 | * @brief Function executed on Radio Rx Error event |
mluis | 0:62d1edcc13d1 | 53 | */ |
mluis | 0:62d1edcc13d1 | 54 | void OnRxError( void ); |
mluis | 0:62d1edcc13d1 | 55 | |
mluis | 0:62d1edcc13d1 | 56 | /*! |
mluis | 0:62d1edcc13d1 | 57 | * @brief Function executed on Radio Fhss Change Channel event |
mluis | 0:62d1edcc13d1 | 58 | */ |
mluis | 0:62d1edcc13d1 | 59 | void OnFhssChangeChannel( uint8_t channelIndex ); |
mluis | 0:62d1edcc13d1 | 60 | |
mluis | 0:62d1edcc13d1 | 61 | /*! |
mluis | 0:62d1edcc13d1 | 62 | * @brief Function executed on CAD Done event |
mluis | 0:62d1edcc13d1 | 63 | */ |
mluis | 0:62d1edcc13d1 | 64 | void OnCadDone( void ); |
mluis | 0:62d1edcc13d1 | 65 | |
mluis | 3:519c71d29a06 | 66 | /*! |
mluis | 3:519c71d29a06 | 67 | * Radio events function pointer |
mluis | 3:519c71d29a06 | 68 | */ |
mluis | 3:519c71d29a06 | 69 | static RadioEvents_t RadioEvents; |
mluis | 3:519c71d29a06 | 70 | |
mluis | 0:62d1edcc13d1 | 71 | /* |
mluis | 0:62d1edcc13d1 | 72 | * Radio object declraration |
mluis | 0:62d1edcc13d1 | 73 | */ |
mluis | 3:519c71d29a06 | 74 | SX1276MB1xAS Radio( NULL ); |
mluis | 0:62d1edcc13d1 | 75 | |
mluis | 0:62d1edcc13d1 | 76 | static const u2_t LORA_RXDONE_FIXUP[] = { |
mluis | 0:62d1edcc13d1 | 77 | [FSK] = us2osticks(0), // ( 0 ticks) |
mluis | 0:62d1edcc13d1 | 78 | [SF7] = us2osticks(0), // ( 0 ticks) |
mluis | 0:62d1edcc13d1 | 79 | [SF8] = us2osticks(1648), // ( 54 ticks) |
mluis | 0:62d1edcc13d1 | 80 | [SF9] = us2osticks(3265), // ( 107 ticks) |
mluis | 0:62d1edcc13d1 | 81 | [SF10] = us2osticks(7049), // ( 231 ticks) |
mluis | 0:62d1edcc13d1 | 82 | [SF11] = us2osticks(13641), // ( 447 ticks) |
mluis | 0:62d1edcc13d1 | 83 | [SF12] = us2osticks(31189), // (1022 ticks) |
mluis | 0:62d1edcc13d1 | 84 | }; |
mluis | 0:62d1edcc13d1 | 85 | |
mluis | 0:62d1edcc13d1 | 86 | void OnTxDone( void ) |
mluis | 0:62d1edcc13d1 | 87 | { |
mluis | 0:62d1edcc13d1 | 88 | ostime_t now = os_getTime( ); |
mluis | 0:62d1edcc13d1 | 89 | // save exact tx time |
mluis | 1:d3b7bde3995c | 90 | LMIC.txend = now - us2osticks( RADIO_WAKEUP_TIME ); // TXDONE FIXUP |
mluis | 0:62d1edcc13d1 | 91 | |
mluis | 0:62d1edcc13d1 | 92 | // go from stanby to sleep |
mluis | 0:62d1edcc13d1 | 93 | Radio.Sleep( ); |
mluis | 0:62d1edcc13d1 | 94 | // run os job (use preset func ptr) |
mluis | 0:62d1edcc13d1 | 95 | os_setCallback( &LMIC.osjob, LMIC.osjob.func ); |
mluis | 0:62d1edcc13d1 | 96 | } |
mluis | 0:62d1edcc13d1 | 97 | |
mluis | 0:62d1edcc13d1 | 98 | void OnRxDone( uint8_t *payload, uint16_t size, int16_t rssi, int8_t snr ) |
mluis | 0:62d1edcc13d1 | 99 | { |
mluis | 0:62d1edcc13d1 | 100 | ostime_t now = os_getTime( ); |
mluis | 0:62d1edcc13d1 | 101 | // save exact rx time |
mluis | 1:d3b7bde3995c | 102 | if( getBw( LMIC.rps ) == BW125 ) |
mluis | 1:d3b7bde3995c | 103 | { |
mluis | 1:d3b7bde3995c | 104 | now -= LORA_RXDONE_FIXUP[getSf( LMIC.rps )]; |
mluis | 1:d3b7bde3995c | 105 | } |
mluis | 1:d3b7bde3995c | 106 | LMIC.rxtime = now; |
mluis | 0:62d1edcc13d1 | 107 | // read the PDU and inform the MAC that we received something |
mluis | 0:62d1edcc13d1 | 108 | LMIC.dataLen = size; |
mluis | 0:62d1edcc13d1 | 109 | // now read the FIFO |
mluis | 0:62d1edcc13d1 | 110 | memcpy( LMIC.frame, payload, size ); |
mluis | 0:62d1edcc13d1 | 111 | // read rx quality parameters |
mluis | 1:d3b7bde3995c | 112 | LMIC.snr = snr; // SNR [dB] * 4 |
mluis | 1:d3b7bde3995c | 113 | LMIC.rssi = rssi; // RSSI [dBm] (-196...+63) |
mluis | 0:62d1edcc13d1 | 114 | |
mluis | 0:62d1edcc13d1 | 115 | // go from stanby to sleep |
mluis | 0:62d1edcc13d1 | 116 | Radio.Sleep( ); |
mluis | 0:62d1edcc13d1 | 117 | // run os job (use preset func ptr) |
mluis | 0:62d1edcc13d1 | 118 | os_setCallback( &LMIC.osjob, LMIC.osjob.func ); |
mluis | 0:62d1edcc13d1 | 119 | } |
mluis | 0:62d1edcc13d1 | 120 | |
mluis | 0:62d1edcc13d1 | 121 | void OnTxTimeout( void ) |
mluis | 0:62d1edcc13d1 | 122 | { |
mluis | 0:62d1edcc13d1 | 123 | ostime_t now = os_getTime( ); |
mluis | 0:62d1edcc13d1 | 124 | |
mluis | 0:62d1edcc13d1 | 125 | // indicate error |
mluis | 1:d3b7bde3995c | 126 | LMIC.dataLen = 0; |
mluis | 1:d3b7bde3995c | 127 | |
mluis | 0:62d1edcc13d1 | 128 | // go from stanby to sleep |
mluis | 0:62d1edcc13d1 | 129 | Radio.Sleep( ); |
mluis | 0:62d1edcc13d1 | 130 | // run os job (use preset func ptr) |
mluis | 0:62d1edcc13d1 | 131 | os_setCallback( &LMIC.osjob, LMIC.osjob.func ); |
mluis | 0:62d1edcc13d1 | 132 | } |
mluis | 0:62d1edcc13d1 | 133 | |
mluis | 0:62d1edcc13d1 | 134 | void OnRxTimeout( void ) |
mluis | 0:62d1edcc13d1 | 135 | { |
mluis | 0:62d1edcc13d1 | 136 | ostime_t now = os_getTime( ); |
mluis | 0:62d1edcc13d1 | 137 | // indicate timeout |
mluis | 0:62d1edcc13d1 | 138 | LMIC.dataLen = 0; |
mluis | 0:62d1edcc13d1 | 139 | |
mluis | 0:62d1edcc13d1 | 140 | // go from stanby to sleep |
mluis | 0:62d1edcc13d1 | 141 | Radio.Sleep( ); |
mluis | 0:62d1edcc13d1 | 142 | // run os job (use preset func ptr) |
mluis | 0:62d1edcc13d1 | 143 | os_setCallback( &LMIC.osjob, LMIC.osjob.func ); |
mluis | 0:62d1edcc13d1 | 144 | } |
mluis | 0:62d1edcc13d1 | 145 | |
mluis | 0:62d1edcc13d1 | 146 | void OnRxError( void ) |
mluis | 0:62d1edcc13d1 | 147 | { |
mluis | 0:62d1edcc13d1 | 148 | ostime_t now = os_getTime( ); |
mluis | 0:62d1edcc13d1 | 149 | |
mluis | 0:62d1edcc13d1 | 150 | // indicate error |
mluis | 0:62d1edcc13d1 | 151 | LMIC.dataLen = 0; |
mluis | 0:62d1edcc13d1 | 152 | |
mluis | 0:62d1edcc13d1 | 153 | // go from stanby to sleep |
mluis | 0:62d1edcc13d1 | 154 | Radio.Sleep( ); |
mluis | 0:62d1edcc13d1 | 155 | // run os job (use preset func ptr) |
mluis | 0:62d1edcc13d1 | 156 | os_setCallback( &LMIC.osjob, LMIC.osjob.func ); |
mluis | 0:62d1edcc13d1 | 157 | } |
mluis | 0:62d1edcc13d1 | 158 | |
mluis | 0:62d1edcc13d1 | 159 | /*! |
mluis | 0:62d1edcc13d1 | 160 | * LMIC API implementation |
mluis | 0:62d1edcc13d1 | 161 | */ |
mluis | 0:62d1edcc13d1 | 162 | // RADIO STATE |
mluis | 0:62d1edcc13d1 | 163 | // (initialized by radio_init( ), used by radio_rand1( )) |
mluis | 0:62d1edcc13d1 | 164 | static u1_t randbuf[16]; |
mluis | 0:62d1edcc13d1 | 165 | |
mluis | 0:62d1edcc13d1 | 166 | // get random seed from wideband noise rssi |
mluis | 0:62d1edcc13d1 | 167 | void radio_init( void ) |
mluis | 0:62d1edcc13d1 | 168 | { |
mluis | 0:62d1edcc13d1 | 169 | hal_disableIRQs( ); |
mluis | 3:519c71d29a06 | 170 | |
mluis | 3:519c71d29a06 | 171 | // Initialize Radio driver |
mluis | 3:519c71d29a06 | 172 | RadioEvents.TxDone = OnTxDone; |
mluis | 3:519c71d29a06 | 173 | RadioEvents.RxDone = OnRxDone; |
mluis | 3:519c71d29a06 | 174 | RadioEvents.RxError = OnRxError; |
mluis | 3:519c71d29a06 | 175 | RadioEvents.TxTimeout = OnTxTimeout; |
mluis | 3:519c71d29a06 | 176 | RadioEvents.RxTimeout = OnRxTimeout; |
mluis | 3:519c71d29a06 | 177 | Radio.Init( &RadioEvents ); |
mluis | 0:62d1edcc13d1 | 178 | |
mluis | 0:62d1edcc13d1 | 179 | // seed 15-byte randomness via noise rssi |
mluis | 0:62d1edcc13d1 | 180 | // Set LoRa modem ON |
mluis | 0:62d1edcc13d1 | 181 | Radio.SetModem( MODEM_LORA ); |
mluis | 0:62d1edcc13d1 | 182 | // Disable LoRa modem interrupts |
mluis | 0:62d1edcc13d1 | 183 | Radio.Write( REG_LR_IRQFLAGSMASK, RFLR_IRQFLAGS_RXTIMEOUT | |
mluis | 0:62d1edcc13d1 | 184 | RFLR_IRQFLAGS_RXDONE | |
mluis | 0:62d1edcc13d1 | 185 | RFLR_IRQFLAGS_PAYLOADCRCERROR | |
mluis | 0:62d1edcc13d1 | 186 | RFLR_IRQFLAGS_VALIDHEADER | |
mluis | 0:62d1edcc13d1 | 187 | RFLR_IRQFLAGS_TXDONE | |
mluis | 0:62d1edcc13d1 | 188 | RFLR_IRQFLAGS_CADDONE | |
mluis | 0:62d1edcc13d1 | 189 | RFLR_IRQFLAGS_FHSSCHANGEDCHANNEL | |
mluis | 0:62d1edcc13d1 | 190 | RFLR_IRQFLAGS_CADDETECTED ); |
mluis | 0:62d1edcc13d1 | 191 | |
mluis | 0:62d1edcc13d1 | 192 | // Set radio in continuous reception |
mluis | 0:62d1edcc13d1 | 193 | Radio.Rx( 0 ); |
mluis | 0:62d1edcc13d1 | 194 | |
mluis | 0:62d1edcc13d1 | 195 | for( int i = 1; i < 16; i++ ) |
mluis | 0:62d1edcc13d1 | 196 | { |
mluis | 0:62d1edcc13d1 | 197 | for( int j = 0; j < 8; j++ ) |
mluis | 0:62d1edcc13d1 | 198 | { |
mluis | 0:62d1edcc13d1 | 199 | u1_t b; // wait for two non-identical subsequent least-significant bits |
mluis | 0:62d1edcc13d1 | 200 | while( ( b = Radio.Read( REG_LR_RSSIWIDEBAND ) & 0x01 ) == ( Radio.Read( REG_LR_RSSIWIDEBAND ) & 0x01 ) ); |
mluis | 0:62d1edcc13d1 | 201 | randbuf[i] = ( randbuf[i] << 1 ) | b; |
mluis | 0:62d1edcc13d1 | 202 | } |
mluis | 0:62d1edcc13d1 | 203 | } |
mluis | 0:62d1edcc13d1 | 204 | randbuf[0] = 16; // set initial index |
mluis | 0:62d1edcc13d1 | 205 | |
mluis | 0:62d1edcc13d1 | 206 | // Change LoRa modem SyncWord |
mluis | 0:62d1edcc13d1 | 207 | Radio.Write( REG_LR_SYNCWORD, LORA_MAC_SYNCWORD ); |
mluis | 0:62d1edcc13d1 | 208 | |
mluis | 0:62d1edcc13d1 | 209 | Radio.Sleep( ); |
mluis | 0:62d1edcc13d1 | 210 | |
mluis | 0:62d1edcc13d1 | 211 | hal_enableIRQs( ); |
mluis | 0:62d1edcc13d1 | 212 | } |
mluis | 0:62d1edcc13d1 | 213 | |
mluis | 0:62d1edcc13d1 | 214 | // return next random byte derived from seed buffer |
mluis | 0:62d1edcc13d1 | 215 | // (buf[0] holds index of next byte to be returned) |
mluis | 0:62d1edcc13d1 | 216 | u1_t radio_rand1( void ) |
mluis | 0:62d1edcc13d1 | 217 | { |
mluis | 0:62d1edcc13d1 | 218 | u1_t i = randbuf[0]; |
mluis | 0:62d1edcc13d1 | 219 | ASSERT( i != 0 ); |
mluis | 0:62d1edcc13d1 | 220 | if( i == 16 ) |
mluis | 0:62d1edcc13d1 | 221 | { |
mluis | 0:62d1edcc13d1 | 222 | os_aes( AES_ENC, randbuf, 16 ); // encrypt seed with any key |
mluis | 0:62d1edcc13d1 | 223 | i = 0; |
mluis | 0:62d1edcc13d1 | 224 | } |
mluis | 0:62d1edcc13d1 | 225 | u1_t v = randbuf[i++]; |
mluis | 0:62d1edcc13d1 | 226 | randbuf[0] = i; |
mluis | 0:62d1edcc13d1 | 227 | return v; |
mluis | 0:62d1edcc13d1 | 228 | } |
mluis | 0:62d1edcc13d1 | 229 | |
mluis | 0:62d1edcc13d1 | 230 | void os_radio( u1_t mode ) |
mluis | 0:62d1edcc13d1 | 231 | { |
mluis | 0:62d1edcc13d1 | 232 | hal_disableIRQs( ); |
mluis | 0:62d1edcc13d1 | 233 | switch( mode ) |
mluis | 0:62d1edcc13d1 | 234 | { |
mluis | 0:62d1edcc13d1 | 235 | case RADIO_RST: |
mluis | 0:62d1edcc13d1 | 236 | // put radio to sleep |
mluis | 0:62d1edcc13d1 | 237 | Radio.Sleep( ); |
mluis | 0:62d1edcc13d1 | 238 | break; |
mluis | 0:62d1edcc13d1 | 239 | |
mluis | 0:62d1edcc13d1 | 240 | case RADIO_TX: |
mluis | 0:62d1edcc13d1 | 241 | // transmit frame now |
mluis | 0:62d1edcc13d1 | 242 | //ASSERT( Radio.GetState( ) == IDLE ); |
mluis | 0:62d1edcc13d1 | 243 | |
mluis | 0:62d1edcc13d1 | 244 | Radio.SetChannel( LMIC.freq ); |
mluis | 0:62d1edcc13d1 | 245 | if( getSf( LMIC.rps ) == FSK ) |
mluis | 0:62d1edcc13d1 | 246 | { // FSK modem |
mluis | 0:62d1edcc13d1 | 247 | Radio.SetTxConfig( MODEM_FSK, LMIC.txpow, 25e3, 0, 50e3, 0, 5, false, true, 0, 0, false, 3e6 ); |
mluis | 0:62d1edcc13d1 | 248 | } |
mluis | 0:62d1edcc13d1 | 249 | else |
mluis | 0:62d1edcc13d1 | 250 | { // LoRa modem |
mluis | 0:62d1edcc13d1 | 251 | |
mluis | 1:d3b7bde3995c | 252 | Radio.SetTxConfig( MODEM_LORA, LMIC.txpow, 0, getBw( LMIC.rps ), getSf( LMIC.rps ) + 6, getCr( LMIC.rps ) + 1, 8, getIh( LMIC.rps ) ? true : false, ( getNocrc( LMIC.rps ) == 0 ) ? true : false, 0, 0, false, 3e6 ); |
mluis | 0:62d1edcc13d1 | 253 | } |
mluis | 0:62d1edcc13d1 | 254 | |
mluis | 0:62d1edcc13d1 | 255 | //starttx( ); // buf=LMIC.frame, len=LMIC.dataLen |
mluis | 0:62d1edcc13d1 | 256 | Radio.Send( LMIC.frame, LMIC.dataLen ); |
mluis | 0:62d1edcc13d1 | 257 | break; |
mluis | 0:62d1edcc13d1 | 258 | |
mluis | 0:62d1edcc13d1 | 259 | case RADIO_RX: |
mluis | 0:62d1edcc13d1 | 260 | // receive frame now (exactly at rxtime) |
mluis | 0:62d1edcc13d1 | 261 | //ASSERT( Radio.GetState( ) == IDLE ); |
mluis | 0:62d1edcc13d1 | 262 | |
mluis | 0:62d1edcc13d1 | 263 | Radio.SetChannel( LMIC.freq ); |
mluis | 0:62d1edcc13d1 | 264 | if( getSf( LMIC.rps ) == FSK ) |
mluis | 0:62d1edcc13d1 | 265 | { // FSK modem |
mluis | 0:62d1edcc13d1 | 266 | //Radio.SetRxConfig( MODEM_FSK, 50e3, 50e3, 0, 83.333e3, 5, 0, false, 0, true, 0, 0, false, false ); |
mluis | 0:62d1edcc13d1 | 267 | Radio.SetRxConfig( MODEM_FSK, 50e3, 50e3, 0, 83.333e3, 5, 0, false, 0, true, 0, 0, false, true ); |
mluis | 0:62d1edcc13d1 | 268 | } |
mluis | 0:62d1edcc13d1 | 269 | else |
mluis | 0:62d1edcc13d1 | 270 | { // LoRa modem |
mluis | 1:d3b7bde3995c | 271 | if( ( getSf( LMIC.rps ) <= SF9 ) && ( LMIC.rxsyms < 8 ) ) |
mluis | 1:d3b7bde3995c | 272 | { |
mluis | 1:d3b7bde3995c | 273 | Radio.SetRxConfig( MODEM_LORA, getBw( LMIC.rps ), getSf( LMIC.rps ) + 6, getCr( LMIC.rps ) + 1, 0, 8, LMIC.rxsyms + 3, getIh( LMIC.rps ) ? true : false, getIh( LMIC.rps ), ( getNocrc( LMIC.rps ) == 0 ) ? true : false, 0, 0, true, false ); |
mluis | 1:d3b7bde3995c | 274 | } |
mluis | 1:d3b7bde3995c | 275 | else |
mluis | 1:d3b7bde3995c | 276 | { |
mluis | 1:d3b7bde3995c | 277 | Radio.SetRxConfig( MODEM_LORA, getBw( LMIC.rps ), getSf( LMIC.rps ) + 6, getCr( LMIC.rps ) + 1, 0, 8, LMIC.rxsyms, getIh( LMIC.rps ) ? true : false, getIh( LMIC.rps ), ( getNocrc( LMIC.rps ) == 0 ) ? true : false, 0, 0, true, false ); |
mluis | 1:d3b7bde3995c | 278 | } |
mluis | 0:62d1edcc13d1 | 279 | } |
mluis | 0:62d1edcc13d1 | 280 | |
mluis | 0:62d1edcc13d1 | 281 | // now instruct the radio to receive |
mluis | 0:62d1edcc13d1 | 282 | hal_waitUntil( LMIC.rxtime ); // busy wait until exact rx time |
mluis | 0:62d1edcc13d1 | 283 | |
mluis | 0:62d1edcc13d1 | 284 | //startrx( RXMODE_SINGLE ); // buf = LMIC.frame, time = LMIC.rxtime, timeout=LMIC.rxsyms |
mluis | 0:62d1edcc13d1 | 285 | if( getSf( LMIC.rps ) == FSK ) |
mluis | 0:62d1edcc13d1 | 286 | { // FSK modem |
mluis | 0:62d1edcc13d1 | 287 | Radio.Rx( 50e3 ); // Max Rx window 50 ms |
mluis | 0:62d1edcc13d1 | 288 | } |
mluis | 0:62d1edcc13d1 | 289 | else |
mluis | 0:62d1edcc13d1 | 290 | { // LoRa modem |
mluis | 0:62d1edcc13d1 | 291 | Radio.Rx( 3e6 ); // Max Rx window 3 seconds |
mluis | 0:62d1edcc13d1 | 292 | } |
mluis | 0:62d1edcc13d1 | 293 | break; |
mluis | 0:62d1edcc13d1 | 294 | |
mluis | 0:62d1edcc13d1 | 295 | case RADIO_RXON: |
mluis | 0:62d1edcc13d1 | 296 | // start scanning for beacon now |
mluis | 0:62d1edcc13d1 | 297 | |
mluis | 0:62d1edcc13d1 | 298 | //ASSERT( Radio.GetState( ) == IDLE ); |
mluis | 0:62d1edcc13d1 | 299 | |
mluis | 0:62d1edcc13d1 | 300 | Radio.SetChannel( LMIC.freq ); |
mluis | 0:62d1edcc13d1 | 301 | if( getSf( LMIC.rps ) == FSK ) |
mluis | 0:62d1edcc13d1 | 302 | { // FSK modem |
mluis | 0:62d1edcc13d1 | 303 | Radio.SetRxConfig( MODEM_FSK, 50e3, 50e3, 0, 83.333e3, 5, 0, false, 0, true, 0, 0, false, true ); |
mluis | 0:62d1edcc13d1 | 304 | } |
mluis | 0:62d1edcc13d1 | 305 | else |
mluis | 0:62d1edcc13d1 | 306 | { // LoRa modem |
mluis | 1:d3b7bde3995c | 307 | Radio.SetRxConfig( MODEM_LORA, getBw( LMIC.rps ), getSf( LMIC.rps ) + 6, getCr( LMIC.rps ) + 1, 0, 8, LMIC.rxsyms, getIh( LMIC.rps ) ? true : false, getIh( LMIC.rps ), ( getNocrc( LMIC.rps ) == 0 ) ? true : false, 0, 0, true, true ); |
mluis | 0:62d1edcc13d1 | 308 | } |
mluis | 0:62d1edcc13d1 | 309 | |
mluis | 1:d3b7bde3995c | 310 | //startrx( RXMODE_SCAN ); // buf = LMIC.frame |
mluis | 0:62d1edcc13d1 | 311 | Radio.Rx( 0 ); |
mluis | 0:62d1edcc13d1 | 312 | break; |
mluis | 0:62d1edcc13d1 | 313 | } |
mluis | 0:62d1edcc13d1 | 314 | hal_enableIRQs( ); |
mluis | 0:62d1edcc13d1 | 315 | } |
mluis | 0:62d1edcc13d1 | 316 | |
mluis | 0:62d1edcc13d1 | 317 | #else |
mluis | 0:62d1edcc13d1 | 318 | |
mluis | 0:62d1edcc13d1 | 319 | // ---------------------------------------- |
mluis | 0:62d1edcc13d1 | 320 | // Registers Mapping |
mluis | 0:62d1edcc13d1 | 321 | #define RegFifo 0x00 // common |
mluis | 0:62d1edcc13d1 | 322 | #define RegOpMode 0x01 // common |
mluis | 0:62d1edcc13d1 | 323 | #define FSKRegBitrateMsb 0x02 |
mluis | 0:62d1edcc13d1 | 324 | #define FSKRegBitrateLsb 0x03 |
mluis | 0:62d1edcc13d1 | 325 | #define FSKRegFdevMsb 0x04 |
mluis | 0:62d1edcc13d1 | 326 | #define FSKRegFdevLsb 0x05 |
mluis | 0:62d1edcc13d1 | 327 | #define RegFrfMsb 0x06 // common |
mluis | 0:62d1edcc13d1 | 328 | #define RegFrfMid 0x07 // common |
mluis | 0:62d1edcc13d1 | 329 | #define RegFrfLsb 0x08 // common |
mluis | 0:62d1edcc13d1 | 330 | #define RegPaConfig 0x09 // common |
mluis | 0:62d1edcc13d1 | 331 | #define RegPaRamp 0x0A // common |
mluis | 0:62d1edcc13d1 | 332 | #define RegOcp 0x0B // common |
mluis | 0:62d1edcc13d1 | 333 | #define RegLna 0x0C // common |
mluis | 0:62d1edcc13d1 | 334 | #define FSKRegRxConfig 0x0D |
mluis | 0:62d1edcc13d1 | 335 | #define LORARegFifoAddrPtr 0x0D |
mluis | 0:62d1edcc13d1 | 336 | #define FSKRegRssiConfig 0x0E |
mluis | 0:62d1edcc13d1 | 337 | #define LORARegFifoTxBaseAddr 0x0E |
mluis | 0:62d1edcc13d1 | 338 | #define FSKRegRssiCollision 0x0F |
mluis | 0:62d1edcc13d1 | 339 | #define LORARegFifoRxBaseAddr 0x0F |
mluis | 0:62d1edcc13d1 | 340 | #define FSKRegRssiThresh 0x10 |
mluis | 0:62d1edcc13d1 | 341 | #define LORARegFifoRxCurrentAddr 0x10 |
mluis | 0:62d1edcc13d1 | 342 | #define FSKRegRssiValue 0x11 |
mluis | 0:62d1edcc13d1 | 343 | #define LORARegIrqFlagsMask 0x11 |
mluis | 0:62d1edcc13d1 | 344 | #define FSKRegRxBw 0x12 |
mluis | 0:62d1edcc13d1 | 345 | #define LORARegIrqFlags 0x12 |
mluis | 0:62d1edcc13d1 | 346 | #define FSKRegAfcBw 0x13 |
mluis | 0:62d1edcc13d1 | 347 | #define LORARegRxNbBytes 0x13 |
mluis | 0:62d1edcc13d1 | 348 | #define FSKRegOokPeak 0x14 |
mluis | 0:62d1edcc13d1 | 349 | #define LORARegRxHeaderCntValueMsb 0x14 |
mluis | 0:62d1edcc13d1 | 350 | #define FSKRegOokFix 0x15 |
mluis | 0:62d1edcc13d1 | 351 | #define LORARegRxHeaderCntValueLsb 0x15 |
mluis | 0:62d1edcc13d1 | 352 | #define FSKRegOokAvg 0x16 |
mluis | 0:62d1edcc13d1 | 353 | #define LORARegRxPacketCntValueMsb 0x16 |
mluis | 0:62d1edcc13d1 | 354 | #define LORARegRxpacketCntValueLsb 0x17 |
mluis | 0:62d1edcc13d1 | 355 | #define LORARegModemStat 0x18 |
mluis | 0:62d1edcc13d1 | 356 | #define LORARegPktSnrValue 0x19 |
mluis | 0:62d1edcc13d1 | 357 | #define FSKRegAfcFei 0x1A |
mluis | 0:62d1edcc13d1 | 358 | #define LORARegPktRssiValue 0x1A |
mluis | 0:62d1edcc13d1 | 359 | #define FSKRegAfcMsb 0x1B |
mluis | 0:62d1edcc13d1 | 360 | #define LORARegRssiValue 0x1B |
mluis | 0:62d1edcc13d1 | 361 | #define FSKRegAfcLsb 0x1C |
mluis | 0:62d1edcc13d1 | 362 | #define LORARegHopChannel 0x1C |
mluis | 0:62d1edcc13d1 | 363 | #define FSKRegFeiMsb 0x1D |
mluis | 0:62d1edcc13d1 | 364 | #define LORARegModemConfig1 0x1D |
mluis | 0:62d1edcc13d1 | 365 | #define FSKRegFeiLsb 0x1E |
mluis | 0:62d1edcc13d1 | 366 | #define LORARegModemConfig2 0x1E |
mluis | 0:62d1edcc13d1 | 367 | #define FSKRegPreambleDetect 0x1F |
mluis | 0:62d1edcc13d1 | 368 | #define LORARegSymbTimeoutLsb 0x1F |
mluis | 0:62d1edcc13d1 | 369 | #define FSKRegRxTimeout1 0x20 |
mluis | 0:62d1edcc13d1 | 370 | #define LORARegPreambleMsb 0x20 |
mluis | 0:62d1edcc13d1 | 371 | #define FSKRegRxTimeout2 0x21 |
mluis | 0:62d1edcc13d1 | 372 | #define LORARegPreambleLsb 0x21 |
mluis | 0:62d1edcc13d1 | 373 | #define FSKRegRxTimeout3 0x22 |
mluis | 0:62d1edcc13d1 | 374 | #define LORARegPayloadLength 0x22 |
mluis | 0:62d1edcc13d1 | 375 | #define FSKRegRxDelay 0x23 |
mluis | 0:62d1edcc13d1 | 376 | #define LORARegPayloadMaxLength 0x23 |
mluis | 0:62d1edcc13d1 | 377 | #define FSKRegOsc 0x24 |
mluis | 0:62d1edcc13d1 | 378 | #define LORARegHopPeriod 0x24 |
mluis | 0:62d1edcc13d1 | 379 | #define FSKRegPreambleMsb 0x25 |
mluis | 0:62d1edcc13d1 | 380 | #define LORARegFifoRxByteAddr 0x25 |
mluis | 0:62d1edcc13d1 | 381 | #define LORARegModemConfig3 0x26 |
mluis | 0:62d1edcc13d1 | 382 | #define FSKRegPreambleLsb 0x26 |
mluis | 0:62d1edcc13d1 | 383 | #define FSKRegSyncConfig 0x27 |
mluis | 0:62d1edcc13d1 | 384 | #define LORARegFeiMsb 0x28 |
mluis | 0:62d1edcc13d1 | 385 | #define FSKRegSyncValue1 0x28 |
mluis | 0:62d1edcc13d1 | 386 | #define LORAFeiMib 0x29 |
mluis | 0:62d1edcc13d1 | 387 | #define FSKRegSyncValue2 0x29 |
mluis | 0:62d1edcc13d1 | 388 | #define LORARegFeiLsb 0x2A |
mluis | 0:62d1edcc13d1 | 389 | #define FSKRegSyncValue3 0x2A |
mluis | 0:62d1edcc13d1 | 390 | #define FSKRegSyncValue4 0x2B |
mluis | 0:62d1edcc13d1 | 391 | #define LORARegRssiWideband 0x2C |
mluis | 0:62d1edcc13d1 | 392 | #define FSKRegSyncValue5 0x2C |
mluis | 0:62d1edcc13d1 | 393 | #define FSKRegSyncValue6 0x2D |
mluis | 0:62d1edcc13d1 | 394 | #define FSKRegSyncValue7 0x2E |
mluis | 0:62d1edcc13d1 | 395 | #define FSKRegSyncValue8 0x2F |
mluis | 0:62d1edcc13d1 | 396 | #define FSKRegPacketConfig1 0x30 |
mluis | 0:62d1edcc13d1 | 397 | #define FSKRegPacketConfig2 0x31 |
mluis | 0:62d1edcc13d1 | 398 | #define LORARegDetectOptimize 0x31 |
mluis | 0:62d1edcc13d1 | 399 | #define FSKRegPayloadLength 0x32 |
mluis | 0:62d1edcc13d1 | 400 | #define FSKRegNodeAdrs 0x33 |
mluis | 0:62d1edcc13d1 | 401 | #define LORARegInvertIQ 0x33 |
mluis | 0:62d1edcc13d1 | 402 | #define FSKRegBroadcastAdrs 0x34 |
mluis | 0:62d1edcc13d1 | 403 | #define FSKRegFifoThresh 0x35 |
mluis | 0:62d1edcc13d1 | 404 | #define FSKRegSeqConfig1 0x36 |
mluis | 0:62d1edcc13d1 | 405 | #define FSKRegSeqConfig2 0x37 |
mluis | 0:62d1edcc13d1 | 406 | #define LORARegDetectionThreshold 0x37 |
mluis | 0:62d1edcc13d1 | 407 | #define FSKRegTimerResol 0x38 |
mluis | 0:62d1edcc13d1 | 408 | #define FSKRegTimer1Coef 0x39 |
mluis | 0:62d1edcc13d1 | 409 | #define LORARegSyncWord 0x39 |
mluis | 0:62d1edcc13d1 | 410 | #define FSKRegTimer2Coef 0x3A |
mluis | 0:62d1edcc13d1 | 411 | #define FSKRegImageCal 0x3B |
mluis | 0:62d1edcc13d1 | 412 | #define FSKRegTemp 0x3C |
mluis | 0:62d1edcc13d1 | 413 | #define FSKRegLowBat 0x3D |
mluis | 0:62d1edcc13d1 | 414 | #define FSKRegIrqFlags1 0x3E |
mluis | 0:62d1edcc13d1 | 415 | #define FSKRegIrqFlags2 0x3F |
mluis | 0:62d1edcc13d1 | 416 | #define RegDioMapping1 0x40 // common |
mluis | 0:62d1edcc13d1 | 417 | #define RegDioMapping2 0x41 // common |
mluis | 0:62d1edcc13d1 | 418 | #define RegVersion 0x42 // common |
mluis | 0:62d1edcc13d1 | 419 | // #define RegAgcRef 0x43 // common |
mluis | 0:62d1edcc13d1 | 420 | // #define RegAgcThresh1 0x44 // common |
mluis | 0:62d1edcc13d1 | 421 | // #define RegAgcThresh2 0x45 // common |
mluis | 0:62d1edcc13d1 | 422 | // #define RegAgcThresh3 0x46 // common |
mluis | 0:62d1edcc13d1 | 423 | // #define RegPllHop 0x4B // common |
mluis | 0:62d1edcc13d1 | 424 | // #define RegTcxo 0x58 // common |
mluis | 0:62d1edcc13d1 | 425 | #define RegPaDac 0x5A // common |
mluis | 0:62d1edcc13d1 | 426 | // #define RegPll 0x5C // common |
mluis | 0:62d1edcc13d1 | 427 | // #define RegPllLowPn 0x5E // common |
mluis | 0:62d1edcc13d1 | 428 | // #define RegFormerTemp 0x6C // common |
mluis | 0:62d1edcc13d1 | 429 | // #define RegBitRateFrac 0x70 // common |
mluis | 0:62d1edcc13d1 | 430 | |
mluis | 0:62d1edcc13d1 | 431 | // ---------------------------------------- |
mluis | 0:62d1edcc13d1 | 432 | // spread factors and mode for RegModemConfig2 |
mluis | 0:62d1edcc13d1 | 433 | #define SX1272_MC2_FSK 0x00 |
mluis | 0:62d1edcc13d1 | 434 | #define SX1272_MC2_SF7 0x70 |
mluis | 0:62d1edcc13d1 | 435 | #define SX1272_MC2_SF8 0x80 |
mluis | 0:62d1edcc13d1 | 436 | #define SX1272_MC2_SF9 0x90 |
mluis | 0:62d1edcc13d1 | 437 | #define SX1272_MC2_SF10 0xA0 |
mluis | 0:62d1edcc13d1 | 438 | #define SX1272_MC2_SF11 0xB0 |
mluis | 0:62d1edcc13d1 | 439 | #define SX1272_MC2_SF12 0xC0 |
mluis | 0:62d1edcc13d1 | 440 | // bandwidth for RegModemConfig1 |
mluis | 0:62d1edcc13d1 | 441 | #define SX1272_MC1_BW_125 0x00 |
mluis | 0:62d1edcc13d1 | 442 | #define SX1272_MC1_BW_250 0x40 |
mluis | 0:62d1edcc13d1 | 443 | #define SX1272_MC1_BW_500 0x80 |
mluis | 0:62d1edcc13d1 | 444 | // coding rate for RegModemConfig1 |
mluis | 0:62d1edcc13d1 | 445 | #define SX1272_MC1_CR_4_5 0x08 |
mluis | 0:62d1edcc13d1 | 446 | #define SX1272_MC1_CR_4_6 0x10 |
mluis | 0:62d1edcc13d1 | 447 | #define SX1272_MC1_CR_4_7 0x18 |
mluis | 0:62d1edcc13d1 | 448 | #define SX1272_MC1_CR_4_8 0x20 |
mluis | 0:62d1edcc13d1 | 449 | #define SX1272_MC1_IMPLICIT_HEADER_MODE_ON 0x04 // required for receive |
mluis | 0:62d1edcc13d1 | 450 | #define SX1272_MC1_RX_PAYLOAD_CRCON 0x02 |
mluis | 0:62d1edcc13d1 | 451 | #define SX1272_MC1_LOW_DATA_RATE_OPTIMIZE 0x01 // mandated for SF11 and SF12 |
mluis | 0:62d1edcc13d1 | 452 | // transmit power configuration for RegPaConfig |
mluis | 0:62d1edcc13d1 | 453 | #define SX1272_PAC_PA_SELECT_PA_BOOST 0x80 |
mluis | 0:62d1edcc13d1 | 454 | #define SX1272_PAC_PA_SELECT_RFIO_PIN 0x00 |
mluis | 0:62d1edcc13d1 | 455 | |
mluis | 0:62d1edcc13d1 | 456 | |
mluis | 0:62d1edcc13d1 | 457 | // sx1276 RegModemConfig1 |
mluis | 0:62d1edcc13d1 | 458 | #define SX1276_MC1_BW_125 0x70 |
mluis | 0:62d1edcc13d1 | 459 | #define SX1276_MC1_BW_250 0x80 |
mluis | 0:62d1edcc13d1 | 460 | #define SX1276_MC1_BW_500 0x90 |
mluis | 0:62d1edcc13d1 | 461 | #define SX1276_MC1_CR_4_5 0x02 |
mluis | 0:62d1edcc13d1 | 462 | #define SX1276_MC1_CR_4_6 0x04 |
mluis | 0:62d1edcc13d1 | 463 | #define SX1276_MC1_CR_4_7 0x06 |
mluis | 0:62d1edcc13d1 | 464 | #define SX1276_MC1_CR_4_8 0x08 |
mluis | 0:62d1edcc13d1 | 465 | |
mluis | 0:62d1edcc13d1 | 466 | #define SX1276_MC1_IMPLICIT_HEADER_MODE_ON 0x01 |
mluis | 0:62d1edcc13d1 | 467 | |
mluis | 0:62d1edcc13d1 | 468 | // sx1276 RegModemConfig2 |
mluis | 0:62d1edcc13d1 | 469 | #define SX1276_MC2_RX_PAYLOAD_CRCON 0x04 |
mluis | 0:62d1edcc13d1 | 470 | |
mluis | 0:62d1edcc13d1 | 471 | // sx1276 RegModemConfig3 |
mluis | 0:62d1edcc13d1 | 472 | #define SX1276_MC3_LOW_DATA_RATE_OPTIMIZE 0x08 |
mluis | 0:62d1edcc13d1 | 473 | #define SX1276_MC3_AGCAUTO 0x04 |
mluis | 0:62d1edcc13d1 | 474 | |
mluis | 0:62d1edcc13d1 | 475 | // preamble for lora networks (nibbles swapped) |
mluis | 1:d3b7bde3995c | 476 | #define LORA_MAC_PREAMBLE 0x34 |
mluis | 0:62d1edcc13d1 | 477 | |
mluis | 0:62d1edcc13d1 | 478 | #define RXLORA_RXMODE_RSSI_REG_MODEM_CONFIG1 0x0A |
mluis | 0:62d1edcc13d1 | 479 | #ifdef CFG_sx1276_radio |
mluis | 0:62d1edcc13d1 | 480 | #define RXLORA_RXMODE_RSSI_REG_MODEM_CONFIG2 0x70 |
mluis | 0:62d1edcc13d1 | 481 | #elif CFG_sx1272_radio |
mluis | 0:62d1edcc13d1 | 482 | #define RXLORA_RXMODE_RSSI_REG_MODEM_CONFIG2 0x74 |
mluis | 0:62d1edcc13d1 | 483 | #endif |
mluis | 0:62d1edcc13d1 | 484 | |
mluis | 0:62d1edcc13d1 | 485 | |
mluis | 0:62d1edcc13d1 | 486 | |
mluis | 0:62d1edcc13d1 | 487 | // ---------------------------------------- |
mluis | 0:62d1edcc13d1 | 488 | // Constants for radio registers |
mluis | 0:62d1edcc13d1 | 489 | #define OPMODE_LORA 0x80 |
mluis | 0:62d1edcc13d1 | 490 | #define OPMODE_MASK 0x07 |
mluis | 0:62d1edcc13d1 | 491 | #define OPMODE_SLEEP 0x00 |
mluis | 0:62d1edcc13d1 | 492 | #define OPMODE_STANDBY 0x01 |
mluis | 0:62d1edcc13d1 | 493 | #define OPMODE_FSTX 0x02 |
mluis | 0:62d1edcc13d1 | 494 | #define OPMODE_TX 0x03 |
mluis | 0:62d1edcc13d1 | 495 | #define OPMODE_FSRX 0x04 |
mluis | 0:62d1edcc13d1 | 496 | #define OPMODE_RX 0x05 |
mluis | 0:62d1edcc13d1 | 497 | #define OPMODE_RX_SINGLE 0x06 |
mluis | 0:62d1edcc13d1 | 498 | #define OPMODE_CAD 0x07 |
mluis | 0:62d1edcc13d1 | 499 | |
mluis | 0:62d1edcc13d1 | 500 | // ---------------------------------------- |
mluis | 0:62d1edcc13d1 | 501 | // Bits masking the corresponding IRQs from the radio |
mluis | 0:62d1edcc13d1 | 502 | #define IRQ_LORA_RXTOUT_MASK 0x80 |
mluis | 0:62d1edcc13d1 | 503 | #define IRQ_LORA_RXDONE_MASK 0x40 |
mluis | 0:62d1edcc13d1 | 504 | #define IRQ_LORA_CRCERR_MASK 0x20 |
mluis | 0:62d1edcc13d1 | 505 | #define IRQ_LORA_HEADER_MASK 0x10 |
mluis | 0:62d1edcc13d1 | 506 | #define IRQ_LORA_TXDONE_MASK 0x08 |
mluis | 0:62d1edcc13d1 | 507 | #define IRQ_LORA_CDDONE_MASK 0x04 |
mluis | 0:62d1edcc13d1 | 508 | #define IRQ_LORA_FHSSCH_MASK 0x02 |
mluis | 0:62d1edcc13d1 | 509 | #define IRQ_LORA_CDDETD_MASK 0x01 |
mluis | 0:62d1edcc13d1 | 510 | |
mluis | 0:62d1edcc13d1 | 511 | #define IRQ_FSK1_MODEREADY_MASK 0x80 |
mluis | 0:62d1edcc13d1 | 512 | #define IRQ_FSK1_RXREADY_MASK 0x40 |
mluis | 0:62d1edcc13d1 | 513 | #define IRQ_FSK1_TXREADY_MASK 0x20 |
mluis | 0:62d1edcc13d1 | 514 | #define IRQ_FSK1_PLLLOCK_MASK 0x10 |
mluis | 0:62d1edcc13d1 | 515 | #define IRQ_FSK1_RSSI_MASK 0x08 |
mluis | 0:62d1edcc13d1 | 516 | #define IRQ_FSK1_TIMEOUT_MASK 0x04 |
mluis | 0:62d1edcc13d1 | 517 | #define IRQ_FSK1_PREAMBLEDETECT_MASK 0x02 |
mluis | 0:62d1edcc13d1 | 518 | #define IRQ_FSK1_SYNCADDRESSMATCH_MASK 0x01 |
mluis | 0:62d1edcc13d1 | 519 | #define IRQ_FSK2_FIFOFULL_MASK 0x80 |
mluis | 0:62d1edcc13d1 | 520 | #define IRQ_FSK2_FIFOEMPTY_MASK 0x40 |
mluis | 0:62d1edcc13d1 | 521 | #define IRQ_FSK2_FIFOLEVEL_MASK 0x20 |
mluis | 0:62d1edcc13d1 | 522 | #define IRQ_FSK2_FIFOOVERRUN_MASK 0x10 |
mluis | 0:62d1edcc13d1 | 523 | #define IRQ_FSK2_PACKETSENT_MASK 0x08 |
mluis | 0:62d1edcc13d1 | 524 | #define IRQ_FSK2_PAYLOADREADY_MASK 0x04 |
mluis | 0:62d1edcc13d1 | 525 | #define IRQ_FSK2_CRCOK_MASK 0x02 |
mluis | 0:62d1edcc13d1 | 526 | #define IRQ_FSK2_LOWBAT_MASK 0x01 |
mluis | 0:62d1edcc13d1 | 527 | |
mluis | 0:62d1edcc13d1 | 528 | // ---------------------------------------- |
mluis | 0:62d1edcc13d1 | 529 | // DIO function mappings D0D1D2D3 |
mluis | 0:62d1edcc13d1 | 530 | #define MAP_DIO0_LORA_RXDONE 0x00 // 00------ |
mluis | 0:62d1edcc13d1 | 531 | #define MAP_DIO0_LORA_TXDONE 0x40 // 01------ |
mluis | 0:62d1edcc13d1 | 532 | #define MAP_DIO1_LORA_RXTOUT 0x00 // --00---- |
mluis | 0:62d1edcc13d1 | 533 | #define MAP_DIO1_LORA_NOP 0x30 // --11---- |
mluis | 0:62d1edcc13d1 | 534 | #define MAP_DIO2_LORA_NOP 0xC0 // ----11-- |
mluis | 0:62d1edcc13d1 | 535 | |
mluis | 0:62d1edcc13d1 | 536 | #define MAP_DIO0_FSK_READY 0x00 // 00------ (packet sent / payload ready) |
mluis | 0:62d1edcc13d1 | 537 | #define MAP_DIO1_FSK_NOP 0x30 // --11---- |
mluis | 0:62d1edcc13d1 | 538 | #define MAP_DIO2_FSK_TXNOP 0x04 // ----01-- |
mluis | 0:62d1edcc13d1 | 539 | #define MAP_DIO2_FSK_TIMEOUT 0x08 // ----10-- |
mluis | 0:62d1edcc13d1 | 540 | |
mluis | 0:62d1edcc13d1 | 541 | |
mluis | 0:62d1edcc13d1 | 542 | // FSK IMAGECAL defines |
mluis | 0:62d1edcc13d1 | 543 | #define RF_IMAGECAL_AUTOIMAGECAL_MASK 0x7F |
mluis | 0:62d1edcc13d1 | 544 | #define RF_IMAGECAL_AUTOIMAGECAL_ON 0x80 |
mluis | 0:62d1edcc13d1 | 545 | #define RF_IMAGECAL_AUTOIMAGECAL_OFF 0x00 // Default |
mluis | 0:62d1edcc13d1 | 546 | |
mluis | 0:62d1edcc13d1 | 547 | #define RF_IMAGECAL_IMAGECAL_MASK 0xBF |
mluis | 0:62d1edcc13d1 | 548 | #define RF_IMAGECAL_IMAGECAL_START 0x40 |
mluis | 0:62d1edcc13d1 | 549 | |
mluis | 0:62d1edcc13d1 | 550 | #define RF_IMAGECAL_IMAGECAL_RUNNING 0x20 |
mluis | 0:62d1edcc13d1 | 551 | #define RF_IMAGECAL_IMAGECAL_DONE 0x00 // Default |
mluis | 0:62d1edcc13d1 | 552 | |
mluis | 0:62d1edcc13d1 | 553 | |
mluis | 0:62d1edcc13d1 | 554 | // RADIO STATE |
mluis | 0:62d1edcc13d1 | 555 | // (initialized by radio_init(), used by radio_rand1()) |
mluis | 0:62d1edcc13d1 | 556 | static u1_t randbuf[16]; |
mluis | 0:62d1edcc13d1 | 557 | |
mluis | 0:62d1edcc13d1 | 558 | |
mluis | 0:62d1edcc13d1 | 559 | #ifdef CFG_sx1276_radio |
mluis | 0:62d1edcc13d1 | 560 | #define LNA_RX_GAIN (0x20|0x1) |
mluis | 0:62d1edcc13d1 | 561 | #elif CFG_sx1272_radio |
mluis | 0:62d1edcc13d1 | 562 | #define LNA_RX_GAIN (0x20|0x03) |
mluis | 0:62d1edcc13d1 | 563 | #else |
mluis | 0:62d1edcc13d1 | 564 | #error Missing CFG_sx1272_radio/CFG_sx1276_radio |
mluis | 0:62d1edcc13d1 | 565 | #endif |
mluis | 0:62d1edcc13d1 | 566 | |
mluis | 1:d3b7bde3995c | 567 | #define RADIO_DBG |
mluis | 1:d3b7bde3995c | 568 | #if defined(RADIO_DBG) |
mluis | 1:d3b7bde3995c | 569 | DigitalOut txStateIo( PB_8 ); |
mluis | 1:d3b7bde3995c | 570 | DigitalOut rxStateIo( PB_9 ); |
mluis | 1:d3b7bde3995c | 571 | #endif |
mluis | 1:d3b7bde3995c | 572 | |
mluis | 0:62d1edcc13d1 | 573 | static void writeReg (u1_t addr, u1_t data ) { |
mluis | 0:62d1edcc13d1 | 574 | hal_pin_nss(0); |
mluis | 0:62d1edcc13d1 | 575 | hal_spi(addr | 0x80); |
mluis | 0:62d1edcc13d1 | 576 | hal_spi(data); |
mluis | 0:62d1edcc13d1 | 577 | hal_pin_nss(1); |
mluis | 0:62d1edcc13d1 | 578 | } |
mluis | 0:62d1edcc13d1 | 579 | |
mluis | 0:62d1edcc13d1 | 580 | static u1_t readReg (u1_t addr) { |
mluis | 0:62d1edcc13d1 | 581 | hal_pin_nss(0); |
mluis | 0:62d1edcc13d1 | 582 | hal_spi(addr & 0x7F); |
mluis | 0:62d1edcc13d1 | 583 | u1_t val = hal_spi(0x00); |
mluis | 0:62d1edcc13d1 | 584 | hal_pin_nss(1); |
mluis | 0:62d1edcc13d1 | 585 | return val; |
mluis | 0:62d1edcc13d1 | 586 | } |
mluis | 0:62d1edcc13d1 | 587 | |
mluis | 0:62d1edcc13d1 | 588 | static void writeBuf (u1_t addr, xref2u1_t buf, u1_t len) { |
mluis | 0:62d1edcc13d1 | 589 | hal_pin_nss(0); |
mluis | 0:62d1edcc13d1 | 590 | hal_spi(addr | 0x80); |
mluis | 0:62d1edcc13d1 | 591 | for (u1_t i=0; i<len; i++) { |
mluis | 0:62d1edcc13d1 | 592 | hal_spi(buf[i]); |
mluis | 0:62d1edcc13d1 | 593 | } |
mluis | 0:62d1edcc13d1 | 594 | hal_pin_nss(1); |
mluis | 0:62d1edcc13d1 | 595 | } |
mluis | 0:62d1edcc13d1 | 596 | |
mluis | 0:62d1edcc13d1 | 597 | static void readBuf (u1_t addr, xref2u1_t buf, u1_t len) { |
mluis | 0:62d1edcc13d1 | 598 | hal_pin_nss(0); |
mluis | 0:62d1edcc13d1 | 599 | hal_spi(addr & 0x7F); |
mluis | 0:62d1edcc13d1 | 600 | for (u1_t i=0; i<len; i++) { |
mluis | 0:62d1edcc13d1 | 601 | buf[i] = hal_spi(0x00); |
mluis | 0:62d1edcc13d1 | 602 | } |
mluis | 0:62d1edcc13d1 | 603 | hal_pin_nss(1); |
mluis | 0:62d1edcc13d1 | 604 | } |
mluis | 0:62d1edcc13d1 | 605 | |
mluis | 0:62d1edcc13d1 | 606 | static void opmode (u1_t mode) { |
mluis | 0:62d1edcc13d1 | 607 | writeReg(RegOpMode, (readReg(RegOpMode) & ~OPMODE_MASK) | mode); |
mluis | 0:62d1edcc13d1 | 608 | } |
mluis | 0:62d1edcc13d1 | 609 | |
mluis | 1:d3b7bde3995c | 610 | static void opmodeLora() { |
mluis | 0:62d1edcc13d1 | 611 | u1_t u = OPMODE_LORA; |
mluis | 0:62d1edcc13d1 | 612 | #ifdef CFG_sx1276_radio |
mluis | 0:62d1edcc13d1 | 613 | u |= 0x8; // TBD: sx1276 high freq |
mluis | 0:62d1edcc13d1 | 614 | #endif |
mluis | 0:62d1edcc13d1 | 615 | writeReg(RegOpMode, u); |
mluis | 0:62d1edcc13d1 | 616 | } |
mluis | 0:62d1edcc13d1 | 617 | |
mluis | 1:d3b7bde3995c | 618 | static void opmodeFSK() { |
mluis | 0:62d1edcc13d1 | 619 | u1_t u = 0; |
mluis | 0:62d1edcc13d1 | 620 | #ifdef CFG_sx1276_radio |
mluis | 0:62d1edcc13d1 | 621 | u |= 0x8; // TBD: sx1276 high freq |
mluis | 0:62d1edcc13d1 | 622 | #endif |
mluis | 0:62d1edcc13d1 | 623 | writeReg(RegOpMode, u); |
mluis | 0:62d1edcc13d1 | 624 | } |
mluis | 0:62d1edcc13d1 | 625 | |
mluis | 0:62d1edcc13d1 | 626 | // configure LoRa modem (cfg1, cfg2) |
mluis | 1:d3b7bde3995c | 627 | static void configLoraModem () { |
mluis | 0:62d1edcc13d1 | 628 | sf_t sf = getSf(LMIC.rps); |
mluis | 0:62d1edcc13d1 | 629 | |
mluis | 0:62d1edcc13d1 | 630 | #ifdef CFG_sx1276_radio |
mluis | 1:d3b7bde3995c | 631 | u1_t mc1 = 0, mc2 = 0, mc3 = 0; |
mluis | 0:62d1edcc13d1 | 632 | |
mluis | 1:d3b7bde3995c | 633 | switch (getBw(LMIC.rps)) { |
mluis | 1:d3b7bde3995c | 634 | case BW125: mc1 |= SX1276_MC1_BW_125; break; |
mluis | 1:d3b7bde3995c | 635 | case BW250: mc1 |= SX1276_MC1_BW_250; break; |
mluis | 1:d3b7bde3995c | 636 | case BW500: mc1 |= SX1276_MC1_BW_500; break; |
mluis | 1:d3b7bde3995c | 637 | default: |
mluis | 1:d3b7bde3995c | 638 | ASSERT(0); |
mluis | 1:d3b7bde3995c | 639 | } |
mluis | 1:d3b7bde3995c | 640 | switch( getCr(LMIC.rps) ) { |
mluis | 1:d3b7bde3995c | 641 | case CR_4_5: mc1 |= SX1276_MC1_CR_4_5; break; |
mluis | 1:d3b7bde3995c | 642 | case CR_4_6: mc1 |= SX1276_MC1_CR_4_6; break; |
mluis | 1:d3b7bde3995c | 643 | case CR_4_7: mc1 |= SX1276_MC1_CR_4_7; break; |
mluis | 1:d3b7bde3995c | 644 | case CR_4_8: mc1 |= SX1276_MC1_CR_4_8; break; |
mluis | 1:d3b7bde3995c | 645 | default: |
mluis | 1:d3b7bde3995c | 646 | ASSERT(0); |
mluis | 1:d3b7bde3995c | 647 | } |
mluis | 0:62d1edcc13d1 | 648 | |
mluis | 1:d3b7bde3995c | 649 | if (getIh(LMIC.rps)) { |
mluis | 1:d3b7bde3995c | 650 | mc1 |= SX1276_MC1_IMPLICIT_HEADER_MODE_ON; |
mluis | 1:d3b7bde3995c | 651 | writeReg(LORARegPayloadLength, getIh(LMIC.rps)); // required length |
mluis | 1:d3b7bde3995c | 652 | } |
mluis | 1:d3b7bde3995c | 653 | // set ModemConfig1 |
mluis | 1:d3b7bde3995c | 654 | writeReg(LORARegModemConfig1, mc1); |
mluis | 0:62d1edcc13d1 | 655 | |
mluis | 1:d3b7bde3995c | 656 | mc2 = (SX1272_MC2_SF7 + ((sf-1)<<4)); |
mluis | 1:d3b7bde3995c | 657 | if (getNocrc(LMIC.rps) == 0) { |
mluis | 1:d3b7bde3995c | 658 | mc2 |= SX1276_MC2_RX_PAYLOAD_CRCON; |
mluis | 1:d3b7bde3995c | 659 | } |
mluis | 1:d3b7bde3995c | 660 | writeReg(LORARegModemConfig2, mc2); |
mluis | 1:d3b7bde3995c | 661 | |
mluis | 1:d3b7bde3995c | 662 | mc3 = SX1276_MC3_AGCAUTO; |
mluis | 1:d3b7bde3995c | 663 | if ((sf == SF11 || sf == SF12) && getBw(LMIC.rps) == BW125) { |
mluis | 1:d3b7bde3995c | 664 | mc3 |= SX1276_MC3_LOW_DATA_RATE_OPTIMIZE; |
mluis | 1:d3b7bde3995c | 665 | } |
mluis | 1:d3b7bde3995c | 666 | writeReg(LORARegModemConfig3, mc3); |
mluis | 0:62d1edcc13d1 | 667 | #elif CFG_sx1272_radio |
mluis | 1:d3b7bde3995c | 668 | u1_t mc1 = (getBw(LMIC.rps)<<6); |
mluis | 0:62d1edcc13d1 | 669 | |
mluis | 1:d3b7bde3995c | 670 | switch( getCr(LMIC.rps) ) { |
mluis | 1:d3b7bde3995c | 671 | case CR_4_5: mc1 |= SX1272_MC1_CR_4_5; break; |
mluis | 1:d3b7bde3995c | 672 | case CR_4_6: mc1 |= SX1272_MC1_CR_4_6; break; |
mluis | 1:d3b7bde3995c | 673 | case CR_4_7: mc1 |= SX1272_MC1_CR_4_7; break; |
mluis | 1:d3b7bde3995c | 674 | case CR_4_8: mc1 |= SX1272_MC1_CR_4_8; break; |
mluis | 1:d3b7bde3995c | 675 | } |
mluis | 1:d3b7bde3995c | 676 | |
mluis | 1:d3b7bde3995c | 677 | if ((sf == SF11 || sf == SF12) && getBw(LMIC.rps) == BW125) { |
mluis | 1:d3b7bde3995c | 678 | mc1 |= SX1272_MC1_LOW_DATA_RATE_OPTIMIZE; |
mluis | 1:d3b7bde3995c | 679 | } |
mluis | 1:d3b7bde3995c | 680 | |
mluis | 1:d3b7bde3995c | 681 | if (getNocrc(LMIC.rps) == 0) { |
mluis | 1:d3b7bde3995c | 682 | mc1 |= SX1272_MC1_RX_PAYLOAD_CRCON; |
mluis | 1:d3b7bde3995c | 683 | } |
mluis | 1:d3b7bde3995c | 684 | |
mluis | 1:d3b7bde3995c | 685 | if (getIh(LMIC.rps)) { |
mluis | 1:d3b7bde3995c | 686 | mc1 |= SX1272_MC1_IMPLICIT_HEADER_MODE_ON; |
mluis | 1:d3b7bde3995c | 687 | writeReg(LORARegPayloadLength, getIh(LMIC.rps)); // required length |
mluis | 1:d3b7bde3995c | 688 | } |
mluis | 1:d3b7bde3995c | 689 | // set ModemConfig1 |
mluis | 1:d3b7bde3995c | 690 | writeReg(LORARegModemConfig1, mc1); |
mluis | 1:d3b7bde3995c | 691 | |
mluis | 1:d3b7bde3995c | 692 | // set ModemConfig2 (sf, AgcAutoOn=1 SymbTimeoutHi=00) |
mluis | 1:d3b7bde3995c | 693 | writeReg(LORARegModemConfig2, (SX1272_MC2_SF7 + ((sf-1)<<4)) | 0x04); |
mluis | 0:62d1edcc13d1 | 694 | #else |
mluis | 0:62d1edcc13d1 | 695 | #error Missing CFG_sx1272_radio/CFG_sx1276_radio |
mluis | 0:62d1edcc13d1 | 696 | #endif /* CFG_sx1272_radio */ |
mluis | 0:62d1edcc13d1 | 697 | } |
mluis | 0:62d1edcc13d1 | 698 | |
mluis | 1:d3b7bde3995c | 699 | static void configChannel () { |
mluis | 0:62d1edcc13d1 | 700 | // set frequency: FQ = (FRF * 32 Mhz) / (2 ^ 19) |
mluis | 0:62d1edcc13d1 | 701 | u8_t frf = ((u8_t)LMIC.freq << 19) / 32000000; |
mluis | 0:62d1edcc13d1 | 702 | writeReg(RegFrfMsb, (u1_t)(frf>>16)); |
mluis | 0:62d1edcc13d1 | 703 | writeReg(RegFrfMid, (u1_t)(frf>> 8)); |
mluis | 0:62d1edcc13d1 | 704 | writeReg(RegFrfLsb, (u1_t)(frf>> 0)); |
mluis | 0:62d1edcc13d1 | 705 | } |
mluis | 0:62d1edcc13d1 | 706 | |
mluis | 0:62d1edcc13d1 | 707 | |
mluis | 0:62d1edcc13d1 | 708 | |
mluis | 1:d3b7bde3995c | 709 | static void configPower () { |
mluis | 0:62d1edcc13d1 | 710 | #ifdef CFG_sx1276_radio |
mluis | 0:62d1edcc13d1 | 711 | // no boost used for now |
mluis | 0:62d1edcc13d1 | 712 | s1_t pw = (s1_t)LMIC.txpow; |
mluis | 1:d3b7bde3995c | 713 | if(pw >= 17) { |
mluis | 1:d3b7bde3995c | 714 | pw = 15; |
mluis | 1:d3b7bde3995c | 715 | } else if(pw < 2) { |
mluis | 1:d3b7bde3995c | 716 | pw = 2; |
mluis | 0:62d1edcc13d1 | 717 | } |
mluis | 0:62d1edcc13d1 | 718 | // check board type for BOOST pin |
mluis | 1:d3b7bde3995c | 719 | writeReg(RegPaConfig, (u1_t)(0x80|(pw&0xf))); |
mluis | 0:62d1edcc13d1 | 720 | writeReg(RegPaDac, readReg(RegPaDac)|0x4); |
mluis | 0:62d1edcc13d1 | 721 | |
mluis | 0:62d1edcc13d1 | 722 | #elif CFG_sx1272_radio |
mluis | 0:62d1edcc13d1 | 723 | // set PA config (2-17 dBm using PA_BOOST) |
mluis | 0:62d1edcc13d1 | 724 | s1_t pw = (s1_t)LMIC.txpow; |
mluis | 0:62d1edcc13d1 | 725 | if(pw > 17) { |
mluis | 1:d3b7bde3995c | 726 | pw = 17; |
mluis | 0:62d1edcc13d1 | 727 | } else if(pw < 2) { |
mluis | 1:d3b7bde3995c | 728 | pw = 2; |
mluis | 0:62d1edcc13d1 | 729 | } |
mluis | 0:62d1edcc13d1 | 730 | writeReg(RegPaConfig, (u1_t)(0x80|(pw-2))); |
mluis | 0:62d1edcc13d1 | 731 | #else |
mluis | 0:62d1edcc13d1 | 732 | #error Missing CFG_sx1272_radio/CFG_sx1276_radio |
mluis | 0:62d1edcc13d1 | 733 | #endif /* CFG_sx1272_radio */ |
mluis | 0:62d1edcc13d1 | 734 | } |
mluis | 0:62d1edcc13d1 | 735 | |
mluis | 1:d3b7bde3995c | 736 | static void txfsk () { |
mluis | 0:62d1edcc13d1 | 737 | // select FSK modem (from sleep mode) |
mluis | 0:62d1edcc13d1 | 738 | writeReg(RegOpMode, 0x10); // FSK, BT=0.5 |
mluis | 0:62d1edcc13d1 | 739 | ASSERT(readReg(RegOpMode) == 0x10); |
mluis | 0:62d1edcc13d1 | 740 | // enter standby mode (required for FIFO loading)) |
mluis | 0:62d1edcc13d1 | 741 | opmode(OPMODE_STANDBY); |
mluis | 1:d3b7bde3995c | 742 | #if defined(RADIO_DBG) |
mluis | 1:d3b7bde3995c | 743 | txStateIo = 0; |
mluis | 1:d3b7bde3995c | 744 | rxStateIo = 0; |
mluis | 1:d3b7bde3995c | 745 | #endif |
mluis | 0:62d1edcc13d1 | 746 | // set bitrate |
mluis | 0:62d1edcc13d1 | 747 | writeReg(FSKRegBitrateMsb, 0x02); // 50kbps |
mluis | 0:62d1edcc13d1 | 748 | writeReg(FSKRegBitrateLsb, 0x80); |
mluis | 0:62d1edcc13d1 | 749 | // set frequency deviation |
mluis | 0:62d1edcc13d1 | 750 | writeReg(FSKRegFdevMsb, 0x01); // +/- 25kHz |
mluis | 0:62d1edcc13d1 | 751 | writeReg(FSKRegFdevLsb, 0x99); |
mluis | 0:62d1edcc13d1 | 752 | // frame and packet handler settings |
mluis | 0:62d1edcc13d1 | 753 | writeReg(FSKRegPreambleMsb, 0x00); |
mluis | 0:62d1edcc13d1 | 754 | writeReg(FSKRegPreambleLsb, 0x05); |
mluis | 0:62d1edcc13d1 | 755 | writeReg(FSKRegSyncConfig, 0x12); |
mluis | 0:62d1edcc13d1 | 756 | writeReg(FSKRegPacketConfig1, 0xD0); |
mluis | 0:62d1edcc13d1 | 757 | writeReg(FSKRegPacketConfig2, 0x40); |
mluis | 0:62d1edcc13d1 | 758 | writeReg(FSKRegSyncValue1, 0xC1); |
mluis | 0:62d1edcc13d1 | 759 | writeReg(FSKRegSyncValue2, 0x94); |
mluis | 0:62d1edcc13d1 | 760 | writeReg(FSKRegSyncValue3, 0xC1); |
mluis | 0:62d1edcc13d1 | 761 | // configure frequency |
mluis | 0:62d1edcc13d1 | 762 | configChannel(); |
mluis | 0:62d1edcc13d1 | 763 | // configure output power |
mluis | 0:62d1edcc13d1 | 764 | configPower(); |
mluis | 0:62d1edcc13d1 | 765 | |
mluis | 0:62d1edcc13d1 | 766 | // set the IRQ mapping DIO0=PacketSent DIO1=NOP DIO2=NOP |
mluis | 0:62d1edcc13d1 | 767 | writeReg(RegDioMapping1, MAP_DIO0_FSK_READY|MAP_DIO1_FSK_NOP|MAP_DIO2_FSK_TXNOP); |
mluis | 0:62d1edcc13d1 | 768 | |
mluis | 0:62d1edcc13d1 | 769 | // initialize the payload size and address pointers |
mluis | 0:62d1edcc13d1 | 770 | writeReg(FSKRegPayloadLength, LMIC.dataLen+1); // (insert length byte into payload)) |
mluis | 0:62d1edcc13d1 | 771 | |
mluis | 0:62d1edcc13d1 | 772 | // download length byte and buffer to the radio FIFO |
mluis | 0:62d1edcc13d1 | 773 | writeReg(RegFifo, LMIC.dataLen); |
mluis | 0:62d1edcc13d1 | 774 | writeBuf(RegFifo, LMIC.frame, LMIC.dataLen); |
mluis | 0:62d1edcc13d1 | 775 | |
mluis | 0:62d1edcc13d1 | 776 | // enable antenna switch for TX |
mluis | 0:62d1edcc13d1 | 777 | hal_pin_rxtx(1); |
mluis | 0:62d1edcc13d1 | 778 | |
mluis | 0:62d1edcc13d1 | 779 | // now we actually start the transmission |
mluis | 0:62d1edcc13d1 | 780 | opmode(OPMODE_TX); |
mluis | 1:d3b7bde3995c | 781 | #if defined(RADIO_DBG) |
mluis | 1:d3b7bde3995c | 782 | txStateIo = 1; |
mluis | 1:d3b7bde3995c | 783 | #endif |
mluis | 0:62d1edcc13d1 | 784 | } |
mluis | 0:62d1edcc13d1 | 785 | |
mluis | 1:d3b7bde3995c | 786 | static void txlora () { |
mluis | 0:62d1edcc13d1 | 787 | // select LoRa modem (from sleep mode) |
mluis | 0:62d1edcc13d1 | 788 | //writeReg(RegOpMode, OPMODE_LORA); |
mluis | 0:62d1edcc13d1 | 789 | opmodeLora(); |
mluis | 0:62d1edcc13d1 | 790 | ASSERT((readReg(RegOpMode) & OPMODE_LORA) != 0); |
mluis | 0:62d1edcc13d1 | 791 | |
mluis | 0:62d1edcc13d1 | 792 | // enter standby mode (required for FIFO loading)) |
mluis | 0:62d1edcc13d1 | 793 | opmode(OPMODE_STANDBY); |
mluis | 1:d3b7bde3995c | 794 | #if defined(RADIO_DBG) |
mluis | 1:d3b7bde3995c | 795 | txStateIo = 0; |
mluis | 1:d3b7bde3995c | 796 | rxStateIo = 0; |
mluis | 1:d3b7bde3995c | 797 | #endif |
mluis | 0:62d1edcc13d1 | 798 | // configure LoRa modem (cfg1, cfg2) |
mluis | 0:62d1edcc13d1 | 799 | configLoraModem(); |
mluis | 0:62d1edcc13d1 | 800 | // configure frequency |
mluis | 0:62d1edcc13d1 | 801 | configChannel(); |
mluis | 0:62d1edcc13d1 | 802 | // configure output power |
mluis | 0:62d1edcc13d1 | 803 | writeReg(RegPaRamp, (readReg(RegPaRamp) & 0xF0) | 0x08); // set PA ramp-up time 50 uSec |
mluis | 0:62d1edcc13d1 | 804 | configPower(); |
mluis | 0:62d1edcc13d1 | 805 | // set sync word |
mluis | 0:62d1edcc13d1 | 806 | writeReg(LORARegSyncWord, LORA_MAC_PREAMBLE); |
mluis | 0:62d1edcc13d1 | 807 | |
mluis | 0:62d1edcc13d1 | 808 | // set the IRQ mapping DIO0=TxDone DIO1=NOP DIO2=NOP |
mluis | 0:62d1edcc13d1 | 809 | writeReg(RegDioMapping1, MAP_DIO0_LORA_TXDONE|MAP_DIO1_LORA_NOP|MAP_DIO2_LORA_NOP); |
mluis | 0:62d1edcc13d1 | 810 | // clear all radio IRQ flags |
mluis | 0:62d1edcc13d1 | 811 | writeReg(LORARegIrqFlags, 0xFF); |
mluis | 0:62d1edcc13d1 | 812 | // mask all IRQs but TxDone |
mluis | 0:62d1edcc13d1 | 813 | writeReg(LORARegIrqFlagsMask, ~IRQ_LORA_TXDONE_MASK); |
mluis | 0:62d1edcc13d1 | 814 | |
mluis | 0:62d1edcc13d1 | 815 | // initialize the payload size and address pointers |
mluis | 0:62d1edcc13d1 | 816 | writeReg(LORARegFifoTxBaseAddr, 0x00); |
mluis | 0:62d1edcc13d1 | 817 | writeReg(LORARegFifoAddrPtr, 0x00); |
mluis | 0:62d1edcc13d1 | 818 | writeReg(LORARegPayloadLength, LMIC.dataLen); |
mluis | 0:62d1edcc13d1 | 819 | |
mluis | 0:62d1edcc13d1 | 820 | // download buffer to the radio FIFO |
mluis | 0:62d1edcc13d1 | 821 | writeBuf(RegFifo, LMIC.frame, LMIC.dataLen); |
mluis | 0:62d1edcc13d1 | 822 | |
mluis | 0:62d1edcc13d1 | 823 | // enable antenna switch for TX |
mluis | 0:62d1edcc13d1 | 824 | hal_pin_rxtx(1); |
mluis | 0:62d1edcc13d1 | 825 | |
mluis | 0:62d1edcc13d1 | 826 | // now we actually start the transmission |
mluis | 0:62d1edcc13d1 | 827 | opmode(OPMODE_TX); |
mluis | 0:62d1edcc13d1 | 828 | } |
mluis | 0:62d1edcc13d1 | 829 | |
mluis | 0:62d1edcc13d1 | 830 | // start transmitter (buf=LMIC.frame, len=LMIC.dataLen) |
mluis | 1:d3b7bde3995c | 831 | static void starttx () { |
mluis | 0:62d1edcc13d1 | 832 | ASSERT( (readReg(RegOpMode) & OPMODE_MASK) == OPMODE_SLEEP ); |
mluis | 0:62d1edcc13d1 | 833 | if(getSf(LMIC.rps) == FSK) { // FSK modem |
mluis | 0:62d1edcc13d1 | 834 | txfsk(); |
mluis | 0:62d1edcc13d1 | 835 | } else { // LoRa modem |
mluis | 0:62d1edcc13d1 | 836 | txlora(); |
mluis | 0:62d1edcc13d1 | 837 | } |
mluis | 0:62d1edcc13d1 | 838 | // the radio will go back to STANDBY mode as soon as the TX is finished |
mluis | 0:62d1edcc13d1 | 839 | // the corresponding IRQ will inform us about completion. |
mluis | 0:62d1edcc13d1 | 840 | } |
mluis | 0:62d1edcc13d1 | 841 | |
mluis | 0:62d1edcc13d1 | 842 | enum { RXMODE_SINGLE, RXMODE_SCAN, RXMODE_RSSI }; |
mluis | 0:62d1edcc13d1 | 843 | |
mluis | 0:62d1edcc13d1 | 844 | static const u1_t rxlorairqmask[] = { |
mluis | 0:62d1edcc13d1 | 845 | [RXMODE_SINGLE] = IRQ_LORA_RXDONE_MASK|IRQ_LORA_RXTOUT_MASK, |
mluis | 0:62d1edcc13d1 | 846 | [RXMODE_SCAN] = IRQ_LORA_RXDONE_MASK, |
mluis | 0:62d1edcc13d1 | 847 | [RXMODE_RSSI] = 0x00, |
mluis | 0:62d1edcc13d1 | 848 | }; |
mluis | 0:62d1edcc13d1 | 849 | |
mluis | 0:62d1edcc13d1 | 850 | // start LoRa receiver (time=LMIC.rxtime, timeout=LMIC.rxsyms, result=LMIC.frame[LMIC.dataLen]) |
mluis | 0:62d1edcc13d1 | 851 | static void rxlora (u1_t rxmode) { |
mluis | 0:62d1edcc13d1 | 852 | // select LoRa modem (from sleep mode) |
mluis | 0:62d1edcc13d1 | 853 | opmodeLora(); |
mluis | 0:62d1edcc13d1 | 854 | ASSERT((readReg(RegOpMode) & OPMODE_LORA) != 0); |
mluis | 0:62d1edcc13d1 | 855 | // enter standby mode (warm up)) |
mluis | 0:62d1edcc13d1 | 856 | opmode(OPMODE_STANDBY); |
mluis | 1:d3b7bde3995c | 857 | #if defined(RADIO_DBG) |
mluis | 1:d3b7bde3995c | 858 | txStateIo = 0; |
mluis | 1:d3b7bde3995c | 859 | rxStateIo = 0; |
mluis | 1:d3b7bde3995c | 860 | #endif |
mluis | 0:62d1edcc13d1 | 861 | // don't use MAC settings at startup |
mluis | 0:62d1edcc13d1 | 862 | if(rxmode == RXMODE_RSSI) { // use fixed settings for rssi scan |
mluis | 0:62d1edcc13d1 | 863 | writeReg(LORARegModemConfig1, RXLORA_RXMODE_RSSI_REG_MODEM_CONFIG1); |
mluis | 0:62d1edcc13d1 | 864 | writeReg(LORARegModemConfig2, RXLORA_RXMODE_RSSI_REG_MODEM_CONFIG2); |
mluis | 0:62d1edcc13d1 | 865 | } else { // single or continuous rx mode |
mluis | 0:62d1edcc13d1 | 866 | // configure LoRa modem (cfg1, cfg2) |
mluis | 0:62d1edcc13d1 | 867 | configLoraModem(); |
mluis | 0:62d1edcc13d1 | 868 | // configure frequency |
mluis | 0:62d1edcc13d1 | 869 | configChannel(); |
mluis | 0:62d1edcc13d1 | 870 | } |
mluis | 0:62d1edcc13d1 | 871 | // set LNA gain |
mluis | 0:62d1edcc13d1 | 872 | writeReg(RegLna, LNA_RX_GAIN); |
mluis | 0:62d1edcc13d1 | 873 | // set max payload size |
mluis | 0:62d1edcc13d1 | 874 | writeReg(LORARegPayloadMaxLength, 64); |
mluis | 0:62d1edcc13d1 | 875 | // use inverted I/Q signal (prevent mote-to-mote communication) |
mluis | 0:62d1edcc13d1 | 876 | writeReg(LORARegInvertIQ, readReg(LORARegInvertIQ)|(1<<6)); |
mluis | 0:62d1edcc13d1 | 877 | // set symbol timeout (for single rx) |
mluis | 0:62d1edcc13d1 | 878 | writeReg(LORARegSymbTimeoutLsb, LMIC.rxsyms); |
mluis | 0:62d1edcc13d1 | 879 | // set sync word |
mluis | 0:62d1edcc13d1 | 880 | writeReg(LORARegSyncWord, LORA_MAC_PREAMBLE); |
mluis | 0:62d1edcc13d1 | 881 | |
mluis | 0:62d1edcc13d1 | 882 | // configure DIO mapping DIO0=RxDone DIO1=RxTout DIO2=NOP |
mluis | 0:62d1edcc13d1 | 883 | writeReg(RegDioMapping1, MAP_DIO0_LORA_RXDONE|MAP_DIO1_LORA_RXTOUT|MAP_DIO2_LORA_NOP); |
mluis | 0:62d1edcc13d1 | 884 | // clear all radio IRQ flags |
mluis | 0:62d1edcc13d1 | 885 | writeReg(LORARegIrqFlags, 0xFF); |
mluis | 0:62d1edcc13d1 | 886 | // enable required radio IRQs |
mluis | 0:62d1edcc13d1 | 887 | writeReg(LORARegIrqFlagsMask, ~rxlorairqmask[rxmode]); |
mluis | 0:62d1edcc13d1 | 888 | |
mluis | 0:62d1edcc13d1 | 889 | // enable antenna switch for RX |
mluis | 0:62d1edcc13d1 | 890 | hal_pin_rxtx(0); |
mluis | 0:62d1edcc13d1 | 891 | |
mluis | 0:62d1edcc13d1 | 892 | // now instruct the radio to receive |
mluis | 0:62d1edcc13d1 | 893 | if (rxmode == RXMODE_SINGLE) { // single rx |
mluis | 0:62d1edcc13d1 | 894 | hal_waitUntil(LMIC.rxtime); // busy wait until exact rx time |
mluis | 1:d3b7bde3995c | 895 | opmode(OPMODE_RX_SINGLE); |
mluis | 1:d3b7bde3995c | 896 | #if defined(RADIO_DBG) |
mluis | 1:d3b7bde3995c | 897 | rxStateIo = 1; |
mluis | 1:d3b7bde3995c | 898 | #endif |
mluis | 0:62d1edcc13d1 | 899 | } else { // continous rx (scan or rssi) |
mluis | 1:d3b7bde3995c | 900 | opmode(OPMODE_RX); |
mluis | 1:d3b7bde3995c | 901 | #if defined(RADIO_DBG) |
mluis | 1:d3b7bde3995c | 902 | rxStateIo = 1; |
mluis | 1:d3b7bde3995c | 903 | #endif |
mluis | 0:62d1edcc13d1 | 904 | } |
mluis | 0:62d1edcc13d1 | 905 | } |
mluis | 0:62d1edcc13d1 | 906 | |
mluis | 0:62d1edcc13d1 | 907 | static void rxfsk (u1_t rxmode) { |
mluis | 0:62d1edcc13d1 | 908 | // only single rx (no continuous scanning, no noise sampling) |
mluis | 0:62d1edcc13d1 | 909 | ASSERT( rxmode == RXMODE_SINGLE ); |
mluis | 0:62d1edcc13d1 | 910 | // select FSK modem (from sleep mode) |
mluis | 0:62d1edcc13d1 | 911 | //writeReg(RegOpMode, 0x00); // (not LoRa) |
mluis | 0:62d1edcc13d1 | 912 | opmodeFSK(); |
mluis | 0:62d1edcc13d1 | 913 | ASSERT((readReg(RegOpMode) & OPMODE_LORA) == 0); |
mluis | 0:62d1edcc13d1 | 914 | // enter standby mode (warm up)) |
mluis | 0:62d1edcc13d1 | 915 | opmode(OPMODE_STANDBY); |
mluis | 1:d3b7bde3995c | 916 | #if defined(RADIO_DBG) |
mluis | 1:d3b7bde3995c | 917 | txStateIo = 0; |
mluis | 1:d3b7bde3995c | 918 | rxStateIo = 0; |
mluis | 1:d3b7bde3995c | 919 | #endif |
mluis | 0:62d1edcc13d1 | 920 | // configure frequency |
mluis | 0:62d1edcc13d1 | 921 | configChannel(); |
mluis | 0:62d1edcc13d1 | 922 | // set LNA gain |
mluis | 0:62d1edcc13d1 | 923 | //writeReg(RegLna, 0x20|0x03); // max gain, boost enable |
mluis | 0:62d1edcc13d1 | 924 | writeReg(RegLna, LNA_RX_GAIN); |
mluis | 0:62d1edcc13d1 | 925 | // configure receiver |
mluis | 0:62d1edcc13d1 | 926 | writeReg(FSKRegRxConfig, 0x1E); // AFC auto, AGC, trigger on preamble?!? |
mluis | 0:62d1edcc13d1 | 927 | // set receiver bandwidth |
mluis | 0:62d1edcc13d1 | 928 | writeReg(FSKRegRxBw, 0x0B); // 50kHz SSb |
mluis | 0:62d1edcc13d1 | 929 | // set AFC bandwidth |
mluis | 0:62d1edcc13d1 | 930 | writeReg(FSKRegAfcBw, 0x12); // 83.3kHz SSB |
mluis | 0:62d1edcc13d1 | 931 | // set preamble detection |
mluis | 0:62d1edcc13d1 | 932 | writeReg(FSKRegPreambleDetect, 0xAA); // enable, 2 bytes, 10 chip errors |
mluis | 0:62d1edcc13d1 | 933 | // set sync config |
mluis | 0:62d1edcc13d1 | 934 | writeReg(FSKRegSyncConfig, 0x12); // no auto restart, preamble 0xAA, enable, fill FIFO, 3 bytes sync |
mluis | 0:62d1edcc13d1 | 935 | // set packet config |
mluis | 0:62d1edcc13d1 | 936 | writeReg(FSKRegPacketConfig1, 0xD8); // var-length, whitening, crc, no auto-clear, no adr filter |
mluis | 0:62d1edcc13d1 | 937 | writeReg(FSKRegPacketConfig2, 0x40); // packet mode |
mluis | 0:62d1edcc13d1 | 938 | // set sync value |
mluis | 0:62d1edcc13d1 | 939 | writeReg(FSKRegSyncValue1, 0xC1); |
mluis | 0:62d1edcc13d1 | 940 | writeReg(FSKRegSyncValue2, 0x94); |
mluis | 0:62d1edcc13d1 | 941 | writeReg(FSKRegSyncValue3, 0xC1); |
mluis | 0:62d1edcc13d1 | 942 | // set preamble timeout |
mluis | 0:62d1edcc13d1 | 943 | writeReg(FSKRegRxTimeout2, 0xFF);//(LMIC.rxsyms+1)/2); |
mluis | 0:62d1edcc13d1 | 944 | // set bitrate |
mluis | 0:62d1edcc13d1 | 945 | writeReg(FSKRegBitrateMsb, 0x02); // 50kbps |
mluis | 0:62d1edcc13d1 | 946 | writeReg(FSKRegBitrateLsb, 0x80); |
mluis | 0:62d1edcc13d1 | 947 | // set frequency deviation |
mluis | 0:62d1edcc13d1 | 948 | writeReg(FSKRegFdevMsb, 0x01); // +/- 25kHz |
mluis | 0:62d1edcc13d1 | 949 | writeReg(FSKRegFdevLsb, 0x99); |
mluis | 0:62d1edcc13d1 | 950 | |
mluis | 0:62d1edcc13d1 | 951 | // configure DIO mapping DIO0=PayloadReady DIO1=NOP DIO2=TimeOut |
mluis | 0:62d1edcc13d1 | 952 | writeReg(RegDioMapping1, MAP_DIO0_FSK_READY|MAP_DIO1_FSK_NOP|MAP_DIO2_FSK_TIMEOUT); |
mluis | 0:62d1edcc13d1 | 953 | |
mluis | 0:62d1edcc13d1 | 954 | // enable antenna switch for RX |
mluis | 0:62d1edcc13d1 | 955 | hal_pin_rxtx(0); |
mluis | 0:62d1edcc13d1 | 956 | |
mluis | 0:62d1edcc13d1 | 957 | // now instruct the radio to receive |
mluis | 0:62d1edcc13d1 | 958 | hal_waitUntil(LMIC.rxtime); // busy wait until exact rx time |
mluis | 0:62d1edcc13d1 | 959 | opmode(OPMODE_RX); // no single rx mode available in FSK |
mluis | 1:d3b7bde3995c | 960 | #if defined(RADIO_DBG) |
mluis | 1:d3b7bde3995c | 961 | rxStateIo = 1; |
mluis | 1:d3b7bde3995c | 962 | #endif |
mluis | 0:62d1edcc13d1 | 963 | } |
mluis | 0:62d1edcc13d1 | 964 | |
mluis | 0:62d1edcc13d1 | 965 | static void startrx (u1_t rxmode) { |
mluis | 0:62d1edcc13d1 | 966 | ASSERT( (readReg(RegOpMode) & OPMODE_MASK) == OPMODE_SLEEP ); |
mluis | 0:62d1edcc13d1 | 967 | if(getSf(LMIC.rps) == FSK) { // FSK modem |
mluis | 0:62d1edcc13d1 | 968 | rxfsk(rxmode); |
mluis | 0:62d1edcc13d1 | 969 | } else { // LoRa modem |
mluis | 0:62d1edcc13d1 | 970 | rxlora(rxmode); |
mluis | 0:62d1edcc13d1 | 971 | } |
mluis | 0:62d1edcc13d1 | 972 | // the radio will go back to STANDBY mode as soon as the RX is finished |
mluis | 0:62d1edcc13d1 | 973 | // or timed out, and the corresponding IRQ will inform us about completion. |
mluis | 0:62d1edcc13d1 | 974 | } |
mluis | 0:62d1edcc13d1 | 975 | |
mluis | 0:62d1edcc13d1 | 976 | // get random seed from wideband noise rssi |
mluis | 1:d3b7bde3995c | 977 | void radio_init () { |
mluis | 0:62d1edcc13d1 | 978 | hal_disableIRQs(); |
mluis | 0:62d1edcc13d1 | 979 | |
mluis | 0:62d1edcc13d1 | 980 | // manually reset radio |
mluis | 0:62d1edcc13d1 | 981 | #ifdef CFG_sx1276_radio |
mluis | 0:62d1edcc13d1 | 982 | hal_pin_rst(0); // drive RST pin low |
mluis | 0:62d1edcc13d1 | 983 | #else |
mluis | 0:62d1edcc13d1 | 984 | hal_pin_rst(1); // drive RST pin high |
mluis | 0:62d1edcc13d1 | 985 | #endif |
mluis | 0:62d1edcc13d1 | 986 | hal_waitUntil(os_getTime()+ms2osticks(1)); // wait >100us |
mluis | 0:62d1edcc13d1 | 987 | hal_pin_rst(2); // configure RST pin floating! |
mluis | 0:62d1edcc13d1 | 988 | hal_waitUntil(os_getTime()+ms2osticks(5)); // wait 5ms |
mluis | 0:62d1edcc13d1 | 989 | |
mluis | 0:62d1edcc13d1 | 990 | opmode(OPMODE_SLEEP); |
mluis | 1:d3b7bde3995c | 991 | #if defined(RADIO_DBG) |
mluis | 1:d3b7bde3995c | 992 | txStateIo = 0; |
mluis | 1:d3b7bde3995c | 993 | rxStateIo = 0; |
mluis | 1:d3b7bde3995c | 994 | #endif |
mluis | 0:62d1edcc13d1 | 995 | // some sanity checks, e.g., read version number |
mluis | 0:62d1edcc13d1 | 996 | u1_t v = readReg(RegVersion); |
mluis | 0:62d1edcc13d1 | 997 | #ifdef CFG_sx1276_radio |
mluis | 0:62d1edcc13d1 | 998 | ASSERT(v == 0x12 ); |
mluis | 0:62d1edcc13d1 | 999 | #elif CFG_sx1272_radio |
mluis | 0:62d1edcc13d1 | 1000 | ASSERT(v == 0x22); |
mluis | 0:62d1edcc13d1 | 1001 | #else |
mluis | 0:62d1edcc13d1 | 1002 | #error Missing CFG_sx1272_radio/CFG_sx1276_radio |
mluis | 0:62d1edcc13d1 | 1003 | #endif |
mluis | 0:62d1edcc13d1 | 1004 | // seed 15-byte randomness via noise rssi |
mluis | 0:62d1edcc13d1 | 1005 | rxlora(RXMODE_RSSI); |
mluis | 0:62d1edcc13d1 | 1006 | while( (readReg(RegOpMode) & OPMODE_MASK) != OPMODE_RX ); // continuous rx |
mluis | 0:62d1edcc13d1 | 1007 | for(int i=1; i<16; i++) { |
mluis | 0:62d1edcc13d1 | 1008 | for(int j=0; j<8; j++) { |
mluis | 0:62d1edcc13d1 | 1009 | u1_t b; // wait for two non-identical subsequent least-significant bits |
mluis | 0:62d1edcc13d1 | 1010 | while( (b = readReg(LORARegRssiWideband) & 0x01) == (readReg(LORARegRssiWideband) & 0x01) ); |
mluis | 0:62d1edcc13d1 | 1011 | randbuf[i] = (randbuf[i] << 1) | b; |
mluis | 0:62d1edcc13d1 | 1012 | } |
mluis | 0:62d1edcc13d1 | 1013 | } |
mluis | 0:62d1edcc13d1 | 1014 | randbuf[0] = 16; // set initial index |
mluis | 0:62d1edcc13d1 | 1015 | |
mluis | 1:d3b7bde3995c | 1016 | #ifdef CFG_sx1276mb1_board |
mluis | 0:62d1edcc13d1 | 1017 | // chain calibration |
mluis | 0:62d1edcc13d1 | 1018 | writeReg(RegPaConfig, 0); |
mluis | 0:62d1edcc13d1 | 1019 | |
mluis | 0:62d1edcc13d1 | 1020 | // Launch Rx chain calibration for LF band |
mluis | 0:62d1edcc13d1 | 1021 | writeReg(FSKRegImageCal, (readReg(FSKRegImageCal) & RF_IMAGECAL_IMAGECAL_MASK)|RF_IMAGECAL_IMAGECAL_START); |
mluis | 0:62d1edcc13d1 | 1022 | while((readReg(FSKRegImageCal)&RF_IMAGECAL_IMAGECAL_RUNNING) == RF_IMAGECAL_IMAGECAL_RUNNING){ ; } |
mluis | 0:62d1edcc13d1 | 1023 | |
mluis | 0:62d1edcc13d1 | 1024 | // Sets a Frequency in HF band |
mluis | 0:62d1edcc13d1 | 1025 | u4_t frf = 868000000; |
mluis | 0:62d1edcc13d1 | 1026 | writeReg(RegFrfMsb, (u1_t)(frf>>16)); |
mluis | 0:62d1edcc13d1 | 1027 | writeReg(RegFrfMid, (u1_t)(frf>> 8)); |
mluis | 0:62d1edcc13d1 | 1028 | writeReg(RegFrfLsb, (u1_t)(frf>> 0)); |
mluis | 0:62d1edcc13d1 | 1029 | |
mluis | 0:62d1edcc13d1 | 1030 | // Launch Rx chain calibration for HF band |
mluis | 0:62d1edcc13d1 | 1031 | writeReg(FSKRegImageCal, (readReg(FSKRegImageCal) & RF_IMAGECAL_IMAGECAL_MASK)|RF_IMAGECAL_IMAGECAL_START); |
mluis | 0:62d1edcc13d1 | 1032 | while((readReg(FSKRegImageCal) & RF_IMAGECAL_IMAGECAL_RUNNING) == RF_IMAGECAL_IMAGECAL_RUNNING) { ; } |
mluis | 1:d3b7bde3995c | 1033 | #endif /* CFG_sx1276mb1_board */ |
mluis | 0:62d1edcc13d1 | 1034 | |
mluis | 0:62d1edcc13d1 | 1035 | opmode(OPMODE_SLEEP); |
mluis | 1:d3b7bde3995c | 1036 | #if defined(RADIO_DBG) |
mluis | 1:d3b7bde3995c | 1037 | txStateIo = 0; |
mluis | 1:d3b7bde3995c | 1038 | rxStateIo = 0; |
mluis | 1:d3b7bde3995c | 1039 | #endif |
mluis | 0:62d1edcc13d1 | 1040 | hal_enableIRQs(); |
mluis | 0:62d1edcc13d1 | 1041 | } |
mluis | 0:62d1edcc13d1 | 1042 | |
mluis | 0:62d1edcc13d1 | 1043 | // return next random byte derived from seed buffer |
mluis | 0:62d1edcc13d1 | 1044 | // (buf[0] holds index of next byte to be returned) |
mluis | 1:d3b7bde3995c | 1045 | u1_t radio_rand1 () { |
mluis | 0:62d1edcc13d1 | 1046 | u1_t i = randbuf[0]; |
mluis | 0:62d1edcc13d1 | 1047 | ASSERT( i != 0 ); |
mluis | 0:62d1edcc13d1 | 1048 | if( i==16 ) { |
mluis | 0:62d1edcc13d1 | 1049 | os_aes(AES_ENC, randbuf, 16); // encrypt seed with any key |
mluis | 0:62d1edcc13d1 | 1050 | i = 0; |
mluis | 0:62d1edcc13d1 | 1051 | } |
mluis | 0:62d1edcc13d1 | 1052 | u1_t v = randbuf[i++]; |
mluis | 0:62d1edcc13d1 | 1053 | randbuf[0] = i; |
mluis | 0:62d1edcc13d1 | 1054 | return v; |
mluis | 0:62d1edcc13d1 | 1055 | } |
mluis | 0:62d1edcc13d1 | 1056 | |
mluis | 1:d3b7bde3995c | 1057 | u1_t radio_rssi () { |
mluis | 0:62d1edcc13d1 | 1058 | hal_disableIRQs(); |
mluis | 0:62d1edcc13d1 | 1059 | u1_t r = readReg(LORARegRssiValue); |
mluis | 0:62d1edcc13d1 | 1060 | hal_enableIRQs(); |
mluis | 0:62d1edcc13d1 | 1061 | return r; |
mluis | 0:62d1edcc13d1 | 1062 | } |
mluis | 0:62d1edcc13d1 | 1063 | |
mluis | 0:62d1edcc13d1 | 1064 | static const u2_t LORA_RXDONE_FIXUP[] = { |
mluis | 0:62d1edcc13d1 | 1065 | [FSK] = us2osticks(0), // ( 0 ticks) |
mluis | 0:62d1edcc13d1 | 1066 | [SF7] = us2osticks(0), // ( 0 ticks) |
mluis | 0:62d1edcc13d1 | 1067 | [SF8] = us2osticks(1648), // ( 54 ticks) |
mluis | 0:62d1edcc13d1 | 1068 | [SF9] = us2osticks(3265), // ( 107 ticks) |
mluis | 0:62d1edcc13d1 | 1069 | [SF10] = us2osticks(7049), // ( 231 ticks) |
mluis | 0:62d1edcc13d1 | 1070 | [SF11] = us2osticks(13641), // ( 447 ticks) |
mluis | 0:62d1edcc13d1 | 1071 | [SF12] = us2osticks(31189), // (1022 ticks) |
mluis | 0:62d1edcc13d1 | 1072 | }; |
mluis | 0:62d1edcc13d1 | 1073 | |
mluis | 0:62d1edcc13d1 | 1074 | // called by hal ext IRQ handler |
mluis | 0:62d1edcc13d1 | 1075 | // (radio goes to stanby mode after tx/rx operations) |
mluis | 0:62d1edcc13d1 | 1076 | void radio_irq_handler (u1_t dio) { |
mluis | 0:62d1edcc13d1 | 1077 | ostime_t now = os_getTime(); |
mluis | 0:62d1edcc13d1 | 1078 | if( (readReg(RegOpMode) & OPMODE_LORA) != 0) { // LORA modem |
mluis | 1:d3b7bde3995c | 1079 | u1_t flags = readReg(LORARegIrqFlags); |
mluis | 1:d3b7bde3995c | 1080 | if( flags & IRQ_LORA_TXDONE_MASK ) { |
mluis | 1:d3b7bde3995c | 1081 | // save exact tx time |
mluis | 1:d3b7bde3995c | 1082 | LMIC.txend = now - us2osticks(43); // TXDONE FIXUP |
mluis | 1:d3b7bde3995c | 1083 | } else if( flags & IRQ_LORA_RXDONE_MASK ) { |
mluis | 1:d3b7bde3995c | 1084 | // save exact rx time |
mluis | 1:d3b7bde3995c | 1085 | if(getBw(LMIC.rps) == BW125) { |
mluis | 1:d3b7bde3995c | 1086 | now -= LORA_RXDONE_FIXUP[getSf(LMIC.rps)]; |
mluis | 1:d3b7bde3995c | 1087 | } |
mluis | 1:d3b7bde3995c | 1088 | LMIC.rxtime = now; |
mluis | 1:d3b7bde3995c | 1089 | // read the PDU and inform the MAC that we received something |
mluis | 1:d3b7bde3995c | 1090 | LMIC.dataLen = (readReg(LORARegModemConfig1) & SX1272_MC1_IMPLICIT_HEADER_MODE_ON) ? |
mluis | 1:d3b7bde3995c | 1091 | readReg(LORARegPayloadLength) : readReg(LORARegRxNbBytes); |
mluis | 1:d3b7bde3995c | 1092 | // set FIFO read address pointer |
mluis | 1:d3b7bde3995c | 1093 | writeReg(LORARegFifoAddrPtr, readReg(LORARegFifoRxCurrentAddr)); |
mluis | 1:d3b7bde3995c | 1094 | // now read the FIFO |
mluis | 1:d3b7bde3995c | 1095 | readBuf(RegFifo, LMIC.frame, LMIC.dataLen); |
mluis | 1:d3b7bde3995c | 1096 | // read rx quality parameters |
mluis | 1:d3b7bde3995c | 1097 | LMIC.snr = readReg(LORARegPktSnrValue); // SNR [dB] * 4 |
mluis | 1:d3b7bde3995c | 1098 | LMIC.rssi = readReg(LORARegPktRssiValue) - 125 + 64; // RSSI [dBm] (-196...+63) |
mluis | 1:d3b7bde3995c | 1099 | } else if( flags & IRQ_LORA_RXTOUT_MASK ) { |
mluis | 1:d3b7bde3995c | 1100 | // indicate timeout |
mluis | 1:d3b7bde3995c | 1101 | LMIC.dataLen = 0; |
mluis | 1:d3b7bde3995c | 1102 | } |
mluis | 0:62d1edcc13d1 | 1103 | // mask all radio IRQs |
mluis | 0:62d1edcc13d1 | 1104 | writeReg(LORARegIrqFlagsMask, 0xFF); |
mluis | 0:62d1edcc13d1 | 1105 | // clear radio IRQ flags |
mluis | 0:62d1edcc13d1 | 1106 | writeReg(LORARegIrqFlags, 0xFF); |
mluis | 0:62d1edcc13d1 | 1107 | } else { // FSK modem |
mluis | 1:d3b7bde3995c | 1108 | u1_t flags1 = readReg(FSKRegIrqFlags1); |
mluis | 1:d3b7bde3995c | 1109 | u1_t flags2 = readReg(FSKRegIrqFlags2); |
mluis | 1:d3b7bde3995c | 1110 | if( flags2 & IRQ_FSK2_PACKETSENT_MASK ) { |
mluis | 1:d3b7bde3995c | 1111 | // save exact tx time |
mluis | 1:d3b7bde3995c | 1112 | LMIC.txend = now; |
mluis | 0:62d1edcc13d1 | 1113 | } else if( flags2 & IRQ_FSK2_PAYLOADREADY_MASK ) { |
mluis | 1:d3b7bde3995c | 1114 | // save exact rx time |
mluis | 1:d3b7bde3995c | 1115 | LMIC.rxtime = now; |
mluis | 1:d3b7bde3995c | 1116 | // read the PDU and inform the MAC that we received something |
mluis | 1:d3b7bde3995c | 1117 | LMIC.dataLen = readReg(FSKRegPayloadLength); |
mluis | 1:d3b7bde3995c | 1118 | // now read the FIFO |
mluis | 1:d3b7bde3995c | 1119 | readBuf(RegFifo, LMIC.frame, LMIC.dataLen); |
mluis | 1:d3b7bde3995c | 1120 | // read rx quality parameters |
mluis | 1:d3b7bde3995c | 1121 | LMIC.snr = 0; // determine snr |
mluis | 1:d3b7bde3995c | 1122 | LMIC.rssi = 0; // determine rssi |
mluis | 1:d3b7bde3995c | 1123 | } else if( flags1 & IRQ_FSK1_TIMEOUT_MASK ) { |
mluis | 1:d3b7bde3995c | 1124 | // indicate timeout |
mluis | 1:d3b7bde3995c | 1125 | LMIC.dataLen = 0; |
mluis | 1:d3b7bde3995c | 1126 | } else { |
mluis | 0:62d1edcc13d1 | 1127 | while(1); |
mluis | 0:62d1edcc13d1 | 1128 | } |
mluis | 0:62d1edcc13d1 | 1129 | } |
mluis | 0:62d1edcc13d1 | 1130 | // go from stanby to sleep |
mluis | 0:62d1edcc13d1 | 1131 | opmode(OPMODE_SLEEP); |
mluis | 1:d3b7bde3995c | 1132 | #if defined(RADIO_DBG) |
mluis | 1:d3b7bde3995c | 1133 | txStateIo = 0; |
mluis | 1:d3b7bde3995c | 1134 | rxStateIo = 0; |
mluis | 1:d3b7bde3995c | 1135 | #endif |
mluis | 0:62d1edcc13d1 | 1136 | // run os job (use preset func ptr) |
mluis | 0:62d1edcc13d1 | 1137 | os_setCallback(&LMIC.osjob, LMIC.osjob.func); |
mluis | 0:62d1edcc13d1 | 1138 | } |
mluis | 0:62d1edcc13d1 | 1139 | |
mluis | 0:62d1edcc13d1 | 1140 | void os_radio (u1_t mode) { |
mluis | 0:62d1edcc13d1 | 1141 | hal_disableIRQs(); |
mluis | 0:62d1edcc13d1 | 1142 | switch (mode) { |
mluis | 0:62d1edcc13d1 | 1143 | case RADIO_RST: |
mluis | 0:62d1edcc13d1 | 1144 | // put radio to sleep |
mluis | 0:62d1edcc13d1 | 1145 | opmode(OPMODE_SLEEP); |
mluis | 1:d3b7bde3995c | 1146 | #if defined(RADIO_DBG) |
mluis | 1:d3b7bde3995c | 1147 | txStateIo = 0; |
mluis | 1:d3b7bde3995c | 1148 | rxStateIo = 0; |
mluis | 1:d3b7bde3995c | 1149 | #endif |
mluis | 0:62d1edcc13d1 | 1150 | break; |
mluis | 0:62d1edcc13d1 | 1151 | |
mluis | 0:62d1edcc13d1 | 1152 | case RADIO_TX: |
mluis | 1:d3b7bde3995c | 1153 | // transmit frame now |
mluis | 0:62d1edcc13d1 | 1154 | starttx(); // buf=LMIC.frame, len=LMIC.dataLen |
mluis | 1:d3b7bde3995c | 1155 | #if defined(RADIO_DBG) |
mluis | 1:d3b7bde3995c | 1156 | txStateIo = 1; |
mluis | 1:d3b7bde3995c | 1157 | #endif |
mluis | 0:62d1edcc13d1 | 1158 | break; |
mluis | 0:62d1edcc13d1 | 1159 | |
mluis | 0:62d1edcc13d1 | 1160 | case RADIO_RX: |
mluis | 1:d3b7bde3995c | 1161 | // receive frame now (exactly at rxtime) |
mluis | 0:62d1edcc13d1 | 1162 | startrx(RXMODE_SINGLE); // buf=LMIC.frame, time=LMIC.rxtime, timeout=LMIC.rxsyms |
mluis | 1:d3b7bde3995c | 1163 | #if defined(RADIO_DBG) |
mluis | 1:d3b7bde3995c | 1164 | rxStateIo = 1; |
mluis | 1:d3b7bde3995c | 1165 | #endif |
mluis | 0:62d1edcc13d1 | 1166 | break; |
mluis | 0:62d1edcc13d1 | 1167 | |
mluis | 0:62d1edcc13d1 | 1168 | case RADIO_RXON: |
mluis | 0:62d1edcc13d1 | 1169 | // start scanning for beacon now |
mluis | 0:62d1edcc13d1 | 1170 | startrx(RXMODE_SCAN); // buf=LMIC.frame |
mluis | 1:d3b7bde3995c | 1171 | #if defined(RADIO_DBG) |
mluis | 1:d3b7bde3995c | 1172 | rxStateIo = 1; |
mluis | 1:d3b7bde3995c | 1173 | #endif |
mluis | 0:62d1edcc13d1 | 1174 | break; |
mluis | 0:62d1edcc13d1 | 1175 | } |
mluis | 0:62d1edcc13d1 | 1176 | hal_enableIRQs(); |
mluis | 0:62d1edcc13d1 | 1177 | } |
mluis | 0:62d1edcc13d1 | 1178 | |
mluis | 0:62d1edcc13d1 | 1179 | #endif // USE_SMTC_RADIO_DRIVER |