LMIC for MOTE_L152RC

Dependents:   lmic_transmit

LoRa WAN in C for NA-mote 72

Currently version 1.5


LoRaWAN network configuration for end-device

The following three pieces of information uniquely identifies end-device to network to allow over-the-air activation. These are stored in the end-device prior to join procedure.

AppEUI

Uniquely identifies application provider of end-device.

Least-significant byte first, 8 bytes. Use LMIC_reverse_memcpy() for AppEUI to keep same byte order as that on lora server.

example C code

static const u1_t APPEUI[8]  = { 0x01, 0x00, 0x01, 0x00, 0x00, 0x0C, 0x25, 0x00 };

This is copied into LMIC by os_getArtEui() callback function in application.

DevEUI

End-device ID, unique to each end-node.

Least-significant byte first, 8 bytes. Use LMIC_reverse_memcpy() for DevEUI to keep same byte order as that on lora server.

example C code

static const u1_t DEVEUI[8]  = { 0x00, 0x00, 0x00, 0x00, 0x01, 0x0C, 0x25, 0x00 }; 

This is copied into LMIC by os_getDevEui() callback function in application.

AppKey (aka DevKey)

128-bit (16byte) AES key.

example C code

static const u1_t DEVKEY[16] = { 0xe4, 0x72, 0x71, 0xc5, 0xf5, 0x30, 0xa9, 0x9f, 0xcf, 0xc4, 0x0e, 0xab, 0xea, 0xd7, 0x19, 0x42 };

This is copied into LMIC by os_getDevKey() callback function in application.

Using over-the air activation, the end-device (LMIC) performs a join procedure every time it starts for first time, or has lost session context information. When join procedure has successfully completed, the end-device will have a network session key (NwkSKey) and an application session key (AppSKey), which are used for encryption and message integrity check.


configuration with http://us01-iot.semtech.com/

  • log in to server
  • click on Applications
  • find your application and click it
  • go to configure motes
  • to create a mote, you may enter a new DevEUI
    • you may copy-paste the 16byte application key from an already existing mote, if you desire.

Information

DevEUI is entered in reverse order into C-code from that shown on server (unique device ID).

AppEUI is entered in reverse order into C-code from that shown on server.

AppEUI is equivalent to "Application"

transmit power limits

FCC Part 15 rules permit one watt of transmit power when more than 50 channels are used. When received by a 64-channel gateway, the maximum power may be used.

However, if end-device is sending to a 8-channel gateway (single SX1301), the maximum transmit power permitted is +20dBm.

To configure LMIC for use with 8-channel gateway, CHNL_HYBRID should be defined in in config.h, and should be undefined for use with 64-channel gateway.

CHNL_HYBRID125KHz500KHz
defined valuechannelschannel
00 to 764
18 to 1565
216 to 2366
324 to 3167
432 to 3968
540 to 4769
648 to 5570
756 to 6371
undef0 to 6364 to 71
Committer:
dudmuck
Date:
Fri Dec 04 01:05:11 2015 +0000
Revision:
10:6c0830baf10f
Parent:
9:83ae7f34e88c
correct DR4 channel used in 8ch mode.  added JOIN_SINGLE_CHANNEL_BLOCK option for faster joining in 8ch mode.

Who changed what in which revision?

UserRevisionLine numberNew contents of line
dudmuck 0:f2716e543d97 1 /* HAL for MOTE_L152RC */
dudmuck 0:f2716e543d97 2
dudmuck 0:f2716e543d97 3 #include "mbed.h"
dudmuck 0:f2716e543d97 4 #include "oslmic.h"
dudmuck 0:f2716e543d97 5 #include "debug.h"
dudmuck 0:f2716e543d97 6
dudmuck 0:f2716e543d97 7 #define RADIO_MOSI PB_15
dudmuck 0:f2716e543d97 8 #define RADIO_MISO PB_14
dudmuck 0:f2716e543d97 9 #define RADIO_SCLK PB_13
dudmuck 0:f2716e543d97 10 #define RADIO_NSS PB_12
dudmuck 0:f2716e543d97 11 #define RESET_PIN PC_2
dudmuck 0:f2716e543d97 12
dudmuck 0:f2716e543d97 13 #define RFSW1 PC_4 //NorAm_Mote RFSwitch_CNTR_1
dudmuck 0:f2716e543d97 14 #define RFSW2 PC_13 //NorAm_Mote RFSwitch_CNTR_2
dudmuck 0:f2716e543d97 15
dudmuck 0:f2716e543d97 16 static DigitalOut nss(RADIO_NSS);
dudmuck 0:f2716e543d97 17 static SPI spi(RADIO_MOSI, RADIO_MISO, RADIO_SCLK); // (mosi, miso, sclk)
dudmuck 0:f2716e543d97 18
dudmuck 0:f2716e543d97 19 static DigitalInOut rst(RESET_PIN);
dudmuck 0:f2716e543d97 20
dudmuck 0:f2716e543d97 21 DigitalOut rfsw1(RFSW1);
dudmuck 0:f2716e543d97 22 DigitalOut rfsw2(RFSW2);
dudmuck 0:f2716e543d97 23
dudmuck 6:dfc048cda33f 24 DigitalOut hdr_fem_csd(PC_0);
dudmuck 0:f2716e543d97 25
dudmuck 0:f2716e543d97 26 static InterruptIn dio0(PC_6);
dudmuck 0:f2716e543d97 27 static InterruptIn dio1(PC_10);
dudmuck 0:f2716e543d97 28 static InterruptIn dio2(PC_11);
dudmuck 0:f2716e543d97 29
dudmuck 0:f2716e543d97 30 extern RTC_HandleTypeDef RtcHandle;
dudmuck 0:f2716e543d97 31
dudmuck 0:f2716e543d97 32 // HAL state
dudmuck 0:f2716e543d97 33 static struct {
dudmuck 0:f2716e543d97 34 int irqlevel;
dudmuck 0:f2716e543d97 35 } HAL;
dudmuck 0:f2716e543d97 36
dudmuck 0:f2716e543d97 37 void radio_irq_handler (u1_t dio);
dudmuck 0:f2716e543d97 38
dudmuck 0:f2716e543d97 39 static void dio0Irq( void ){
dudmuck 0:f2716e543d97 40 radio_irq_handler( 0 );
dudmuck 0:f2716e543d97 41 }
dudmuck 0:f2716e543d97 42 static void dio1Irq( void ){
dudmuck 0:f2716e543d97 43 radio_irq_handler( 1 );
dudmuck 0:f2716e543d97 44 }
dudmuck 0:f2716e543d97 45 static void dio2Irq( void ){
dudmuck 0:f2716e543d97 46 radio_irq_handler( 2 );
dudmuck 0:f2716e543d97 47 }
dudmuck 0:f2716e543d97 48
dudmuck 0:f2716e543d97 49 void hal_disableIRQs()
dudmuck 0:f2716e543d97 50 {
dudmuck 0:f2716e543d97 51 __disable_irq();
dudmuck 0:f2716e543d97 52 HAL.irqlevel++;
dudmuck 0:f2716e543d97 53 }
dudmuck 0:f2716e543d97 54
dudmuck 0:f2716e543d97 55 void hal_enableIRQs()
dudmuck 0:f2716e543d97 56 {
dudmuck 0:f2716e543d97 57 if (--HAL.irqlevel == 0) {
dudmuck 0:f2716e543d97 58 __enable_irq();
dudmuck 0:f2716e543d97 59 }
dudmuck 0:f2716e543d97 60 }
dudmuck 0:f2716e543d97 61
dudmuck 0:f2716e543d97 62 void hal_failed ()
dudmuck 0:f2716e543d97 63 {
dudmuck 0:f2716e543d97 64 while (1)
dudmuck 0:f2716e543d97 65 asm("nop");
dudmuck 0:f2716e543d97 66 }
dudmuck 0:f2716e543d97 67
dudmuck 0:f2716e543d97 68 static void rtc_wkup_irq(void)
dudmuck 0:f2716e543d97 69 {
dudmuck 0:f2716e543d97 70 HAL_RTCEx_WakeUpTimerIRQHandler(&RtcHandle);
dudmuck 0:f2716e543d97 71 }
dudmuck 0:f2716e543d97 72
dudmuck 0:f2716e543d97 73 void HAL_RTCEx_WakeUpTimerEventCallback(RTC_HandleTypeDef *hrtc)
dudmuck 0:f2716e543d97 74 {
dudmuck 0:f2716e543d97 75 /* Clear Wake Up Flag */
dudmuck 0:f2716e543d97 76 __HAL_PWR_CLEAR_FLAG(PWR_FLAG_WU);
dudmuck 0:f2716e543d97 77 }
dudmuck 0:f2716e543d97 78
dudmuck 0:f2716e543d97 79 /*void HAL_RCC_CCSCallback()
dudmuck 0:f2716e543d97 80 {
dudmuck 0:f2716e543d97 81 for (;;) asm("nop");
dudmuck 0:f2716e543d97 82 }*/
dudmuck 0:f2716e543d97 83
dudmuck 0:f2716e543d97 84
dudmuck 0:f2716e543d97 85 volatile uint32_t /*rcc_cr_a, rcc_cr_b,*/ rcc_cr_c;
dudmuck 0:f2716e543d97 86 void hal_init (void)
dudmuck 0:f2716e543d97 87 {
dudmuck 0:f2716e543d97 88 memset(&HAL, 0x00, sizeof(HAL));
dudmuck 0:f2716e543d97 89 hal_disableIRQs();
dudmuck 0:f2716e543d97 90
dudmuck 0:f2716e543d97 91 #if USE_SMTC_RADIO_DRIVER
dudmuck 0:f2716e543d97 92
dudmuck 0:f2716e543d97 93 #else
dudmuck 0:f2716e543d97 94 // configure input lines
dudmuck 0:f2716e543d97 95 dio0.mode(PullDown);
dudmuck 0:f2716e543d97 96 dio0.rise(dio0Irq);
dudmuck 0:f2716e543d97 97 dio0.enable_irq();
dudmuck 0:f2716e543d97 98 dio1.mode(PullDown);
dudmuck 0:f2716e543d97 99 dio1.rise(dio1Irq);
dudmuck 0:f2716e543d97 100 dio1.enable_irq();
dudmuck 0:f2716e543d97 101 dio2.mode(PullDown);
dudmuck 0:f2716e543d97 102 dio2.rise(dio2Irq);
dudmuck 0:f2716e543d97 103 dio2.enable_irq();
dudmuck 0:f2716e543d97 104 // configure reset line
dudmuck 0:f2716e543d97 105 rst.input();
dudmuck 0:f2716e543d97 106 // configure spi
dudmuck 0:f2716e543d97 107 spi.frequency(8000000);
dudmuck 0:f2716e543d97 108 spi.format(8, 0);
dudmuck 0:f2716e543d97 109 nss = 1;
dudmuck 0:f2716e543d97 110 //RFSwitch_CNTR_2 = 1;
dudmuck 0:f2716e543d97 111 #endif
dudmuck 0:f2716e543d97 112
dudmuck 0:f2716e543d97 113 set_time(0); // initialize RTC
dudmuck 0:f2716e543d97 114
dudmuck 0:f2716e543d97 115 /* Enable Ultra low power mode */
dudmuck 0:f2716e543d97 116 HAL_PWREx_EnableUltraLowPower();
dudmuck 0:f2716e543d97 117
dudmuck 0:f2716e543d97 118 /* Enable the fast wake up from Ultra low power mode */
dudmuck 0:f2716e543d97 119 HAL_PWREx_EnableFastWakeUp();
dudmuck 0:f2716e543d97 120
dudmuck 0:f2716e543d97 121 __HAL_RTC_WAKEUPTIMER_CLEAR_FLAG(&RtcHandle, RTC_FLAG_WUTF);
dudmuck 0:f2716e543d97 122
dudmuck 0:f2716e543d97 123 NVIC_SetVector(RTC_WKUP_IRQn, (uint32_t)rtc_wkup_irq);
dudmuck 0:f2716e543d97 124 NVIC_EnableIRQ(RTC_WKUP_IRQn);
dudmuck 0:f2716e543d97 125
dudmuck 6:dfc048cda33f 126 hdr_fem_csd = 0;
dudmuck 0:f2716e543d97 127
dudmuck 0:f2716e543d97 128 hal_enableIRQs();
dudmuck 0:f2716e543d97 129
dudmuck 0:f2716e543d97 130 GPIOA->MODER |= 0x01415500; // unused pins as outputs: PA4, PA5, PA6, PA7, PA8, (PA11,PA12 USB)
dudmuck 0:f2716e543d97 131 GPIOB->MODER |= 0x00000401; // unused pins as outputs: PB0(HDR_DIO1), PB5 (PB10 pulled hi by LED), PB3-T_SWO
dudmuck 0:f2716e543d97 132 GPIOC->MODER |= 0x00000041; // unused pins as outputs: PC0(HDR_FEM_CSD), PC3(SPI3_enable)
dudmuck 0:f2716e543d97 133
dudmuck 0:f2716e543d97 134
dudmuck 0:f2716e543d97 135 }
dudmuck 0:f2716e543d97 136
dudmuck 0:f2716e543d97 137 u4_t hal_ticks ()
dudmuck 0:f2716e543d97 138 {
dudmuck 0:f2716e543d97 139 RTC_DateTypeDef dateStruct;
dudmuck 0:f2716e543d97 140 RTC_TimeTypeDef timeStruct;
dudmuck 0:f2716e543d97 141 struct tm timeinfo;
dudmuck 0:f2716e543d97 142 uint16_t sub_seconds;
dudmuck 0:f2716e543d97 143
dudmuck 0:f2716e543d97 144 RtcHandle.Instance = RTC;
dudmuck 0:f2716e543d97 145
dudmuck 0:f2716e543d97 146 // Read actual date and time
dudmuck 0:f2716e543d97 147 // Warning: the time must be read first!
dudmuck 0:f2716e543d97 148 HAL_RTC_GetTime(&RtcHandle, &timeStruct, FORMAT_BIN);
dudmuck 0:f2716e543d97 149 HAL_RTC_GetDate(&RtcHandle, &dateStruct, FORMAT_BIN);
dudmuck 0:f2716e543d97 150 sub_seconds = 16384 - timeStruct.SubSeconds; // RTC_SSR counts down
dudmuck 0:f2716e543d97 151
dudmuck 0:f2716e543d97 152 // Setup a tm structure based on the RTC
dudmuck 0:f2716e543d97 153 timeinfo.tm_wday = dateStruct.WeekDay;
dudmuck 0:f2716e543d97 154 timeinfo.tm_mon = dateStruct.Month - 1;
dudmuck 0:f2716e543d97 155 timeinfo.tm_mday = dateStruct.Date;
dudmuck 0:f2716e543d97 156 timeinfo.tm_year = dateStruct.Year + 100;
dudmuck 0:f2716e543d97 157 timeinfo.tm_hour = timeStruct.Hours;
dudmuck 0:f2716e543d97 158 timeinfo.tm_min = timeStruct.Minutes;
dudmuck 0:f2716e543d97 159 timeinfo.tm_sec = timeStruct.Seconds;
dudmuck 0:f2716e543d97 160
dudmuck 0:f2716e543d97 161 // Convert to timestamp
dudmuck 0:f2716e543d97 162 time_t t = mktime(&timeinfo);
dudmuck 0:f2716e543d97 163
dudmuck 0:f2716e543d97 164 // 14: SSR is driven at 16384Hz
dudmuck 1:04fd63382b03 165 t <<= 14;
dudmuck 1:04fd63382b03 166 return t | sub_seconds;
dudmuck 0:f2716e543d97 167 }
dudmuck 0:f2716e543d97 168
dudmuck 0:f2716e543d97 169 void hal_waitUntil (u4_t time)
dudmuck 0:f2716e543d97 170 {
dudmuck 0:f2716e543d97 171 while (hal_ticks() < time)
dudmuck 0:f2716e543d97 172 asm("nop");
dudmuck 0:f2716e543d97 173 }
dudmuck 0:f2716e543d97 174
dudmuck 0:f2716e543d97 175
dudmuck 0:f2716e543d97 176 volatile char deep_sleep;
dudmuck 0:f2716e543d97 177 /* return 1 if target time is soon, return 0 if timer was programmed */
dudmuck 0:f2716e543d97 178 u1_t hal_checkTimer (u4_t time)
dudmuck 0:f2716e543d97 179 {
dudmuck 0:f2716e543d97 180 int d = time - hal_ticks();
dudmuck 0:f2716e543d97 181
dudmuck 0:f2716e543d97 182 HAL_RTCEx_DeactivateWakeUpTimer(&RtcHandle);
dudmuck 0:f2716e543d97 183 __HAL_RTC_WAKEUPTIMER_CLEAR_FLAG(&RtcHandle, RTC_FLAG_WUTF);
dudmuck 0:f2716e543d97 184
dudmuck 0:f2716e543d97 185 if (d < 0x10000) { // less than 4s
dudmuck 0:f2716e543d97 186 deep_sleep = 0;
dudmuck 0:f2716e543d97 187 if (d < 4)
dudmuck 0:f2716e543d97 188 return 1; // very soon
dudmuck 0:f2716e543d97 189 if (d > ms2osticks(100)) {
dudmuck 0:f2716e543d97 190 d -= 13; // HSE_PLL startup time
dudmuck 0:f2716e543d97 191 deep_sleep = 1;
dudmuck 0:f2716e543d97 192 }
dudmuck 0:f2716e543d97 193 // 61.035us steps
dudmuck 0:f2716e543d97 194 HAL_RTCEx_SetWakeUpTimer_IT(&RtcHandle, d, RTC_WAKEUPCLOCK_RTCCLK_DIV2);
dudmuck 0:f2716e543d97 195 } else if (d < 0x20000) { // less than 8s
dudmuck 0:f2716e543d97 196 d -= 6; // HSE_PLL startup time
dudmuck 0:f2716e543d97 197 deep_sleep = 1;
dudmuck 0:f2716e543d97 198 // 122us steps
dudmuck 0:f2716e543d97 199 HAL_RTCEx_SetWakeUpTimer_IT(&RtcHandle, d >> 1, RTC_WAKEUPCLOCK_RTCCLK_DIV4);
dudmuck 0:f2716e543d97 200 } else if (d < 0x40000) { // less than 16s
dudmuck 0:f2716e543d97 201 deep_sleep = 1;
dudmuck 0:f2716e543d97 202 // 244us steps
dudmuck 0:f2716e543d97 203 HAL_RTCEx_SetWakeUpTimer_IT(&RtcHandle, d >> 2, RTC_WAKEUPCLOCK_RTCCLK_DIV8);
dudmuck 0:f2716e543d97 204 } else if (d < 0x80000) { // less than 32s
dudmuck 0:f2716e543d97 205 deep_sleep = 1;
dudmuck 0:f2716e543d97 206 // 488us steps
dudmuck 0:f2716e543d97 207 HAL_RTCEx_SetWakeUpTimer_IT(&RtcHandle, d >> 3, RTC_WAKEUPCLOCK_RTCCLK_DIV16);
dudmuck 0:f2716e543d97 208 } else {
dudmuck 0:f2716e543d97 209 deep_sleep = 1;
dudmuck 0:f2716e543d97 210 // 1s steps to 18hours
dudmuck 0:f2716e543d97 211 HAL_RTCEx_SetWakeUpTimer_IT(&RtcHandle, d >> 14, RTC_WAKEUPCLOCK_CK_SPRE_16BITS);
dudmuck 0:f2716e543d97 212 /* RTC_WAKEUPCLOCK_CK_SPRE_17BITS: 18h to 36h */
dudmuck 0:f2716e543d97 213 /*for (;;)
dudmuck 0:f2716e543d97 214 asm("nop");*/
dudmuck 0:f2716e543d97 215 }
dudmuck 0:f2716e543d97 216
dudmuck 0:f2716e543d97 217 return 0;
dudmuck 0:f2716e543d97 218 }
dudmuck 0:f2716e543d97 219
dudmuck 0:f2716e543d97 220 //#define SLEEP_DEBUG 1
dudmuck 0:f2716e543d97 221
dudmuck 0:f2716e543d97 222 void hal_sleep ()
dudmuck 0:f2716e543d97 223 {
dudmuck 0:f2716e543d97 224 #ifdef SLEEP_DEBUG
dudmuck 0:f2716e543d97 225 u4_t start_tick, end_tick;
dudmuck 0:f2716e543d97 226 volatile uint32_t time_asleep;
dudmuck 0:f2716e543d97 227 #endif /* SLEEP_DEBUG */
dudmuck 0:f2716e543d97 228
dudmuck 0:f2716e543d97 229 #ifdef USE_DEBUGGER
dudmuck 0:f2716e543d97 230 HAL_EnableDBGStopMode();
dudmuck 0:f2716e543d97 231 if (!DBGMCU->CR & DBGMCU_CR_DBG_STOP)
dudmuck 0:f2716e543d97 232 for (;;) asm("nop");
dudmuck 0:f2716e543d97 233 #endif /* USE_DEBUGGER */
dudmuck 0:f2716e543d97 234
dudmuck 1:04fd63382b03 235 //printf("%x cr:%06x isr:%04x %d\r\n", RtcHandle.Instance->WUTR, RtcHandle.Instance->CR, RtcHandle.Instance->ISR, deep_sleep);
dudmuck 1:04fd63382b03 236 //debug_done();
dudmuck 1:04fd63382b03 237
dudmuck 9:83ae7f34e88c 238 if (deep_sleep) {
dudmuck 0:f2716e543d97 239 debug_done(); // wait here if debug still printing
dudmuck 9:83ae7f34e88c 240 }
dudmuck 0:f2716e543d97 241
dudmuck 0:f2716e543d97 242 if (__HAL_RTC_WAKEUPTIMER_GET_FLAG(&RtcHandle, RTC_FLAG_WUTF) == 0) {
dudmuck 0:f2716e543d97 243 // set gpio for sleep
dudmuck 0:f2716e543d97 244 #ifdef SLEEP_DEBUG
dudmuck 0:f2716e543d97 245 start_tick = hal_ticks();
dudmuck 0:f2716e543d97 246 #endif /* SLEEP_DEBUG */
dudmuck 6:dfc048cda33f 247
dudmuck 0:f2716e543d97 248
dudmuck 0:f2716e543d97 249 if (deep_sleep) {
dudmuck 0:f2716e543d97 250 #ifndef USE_DEBUGGER
dudmuck 0:f2716e543d97 251 /* PA13 to undriven JTMS/SWDIO pin (from AF0 to GPIO), and PA2 */
dudmuck 0:f2716e543d97 252 GPIOA->MODER &= 0xf7ffffdf;
dudmuck 0:f2716e543d97 253 GPIOB->MODER &= 0xffffdfff; // PB6 UART_TX to input
dudmuck 0:f2716e543d97 254 #endif
dudmuck 0:f2716e543d97 255 deepsleep(); // blocks until waking
dudmuck 0:f2716e543d97 256 #ifndef USE_DEBUGGER
dudmuck 0:f2716e543d97 257 /* PA13 back to JTMS/SWDIO pin (from GPIO to AF0), and PA2 */
dudmuck 0:f2716e543d97 258 GPIOA->MODER |= 0x08000020;
dudmuck 0:f2716e543d97 259 GPIOB->MODER |= 0x00002000; // PB6 input to UART_TX
dudmuck 0:f2716e543d97 260 #endif
dudmuck 0:f2716e543d97 261 } else
dudmuck 0:f2716e543d97 262 sleep(); // blocks until waking
dudmuck 0:f2716e543d97 263
dudmuck 0:f2716e543d97 264 #ifdef SLEEP_DEBUG
dudmuck 0:f2716e543d97 265 end_tick = hal_ticks();
dudmuck 0:f2716e543d97 266 time_asleep = end_tick - start_tick;
dudmuck 1:04fd63382b03 267 printf("%u = %u - %u\r\n", time_asleep, end_tick, start_tick);
dudmuck 0:f2716e543d97 268 #endif /* SLEEP_DEBUG */
dudmuck 0:f2716e543d97 269 // restore gpio from sleep
dudmuck 0:f2716e543d97 270 }
dudmuck 0:f2716e543d97 271 }
dudmuck 0:f2716e543d97 272
dudmuck 0:f2716e543d97 273 void hal_pin_nss (u1_t val)
dudmuck 0:f2716e543d97 274 {
dudmuck 0:f2716e543d97 275 nss = val;
dudmuck 0:f2716e543d97 276 }
dudmuck 0:f2716e543d97 277
dudmuck 0:f2716e543d97 278 u1_t hal_spi (u1_t out)
dudmuck 0:f2716e543d97 279 {
dudmuck 0:f2716e543d97 280 return spi.write(out);
dudmuck 0:f2716e543d97 281 }
dudmuck 0:f2716e543d97 282
dudmuck 0:f2716e543d97 283 // 0=RX 1=TX
dudmuck 0:f2716e543d97 284 /*void hal_pin_rxtx (u1_t val)
dudmuck 0:f2716e543d97 285 {
dudmuck 0:f2716e543d97 286 rxtx = !val;
dudmuck 0:f2716e543d97 287 }*/
dudmuck 0:f2716e543d97 288 #define OPMODE_LORA 0x80
dudmuck 0:f2716e543d97 289 #define OPMODE_MASK 0x07
dudmuck 0:f2716e543d97 290 #define OPMODE_SLEEP 0x00
dudmuck 0:f2716e543d97 291 #define OPMODE_STANDBY 0x01
dudmuck 0:f2716e543d97 292 #define OPMODE_FSTX 0x02
dudmuck 0:f2716e543d97 293 #define OPMODE_TX 0x03
dudmuck 0:f2716e543d97 294 #define OPMODE_FSRX 0x04
dudmuck 0:f2716e543d97 295 #define OPMODE_RX 0x05
dudmuck 0:f2716e543d97 296 #define OPMODE_RX_SINGLE 0x06
dudmuck 0:f2716e543d97 297 #define OPMODE_CAD 0x07
dudmuck 0:f2716e543d97 298 void hal_opmode(u1_t mode, u1_t pa_boost)
dudmuck 0:f2716e543d97 299 {
dudmuck 0:f2716e543d97 300 if (mode == OPMODE_TX) { // start of transmission
dudmuck 0:f2716e543d97 301 if (pa_boost) {
dudmuck 0:f2716e543d97 302 rfsw2 = 0;
dudmuck 0:f2716e543d97 303 rfsw1 = 1;
dudmuck 0:f2716e543d97 304 } else {
dudmuck 0:f2716e543d97 305 rfsw2 = 1;
dudmuck 0:f2716e543d97 306 rfsw1 = 0;
dudmuck 0:f2716e543d97 307 }
dudmuck 6:dfc048cda33f 308 hdr_fem_csd = 0; // debug
dudmuck 0:f2716e543d97 309 } else if (mode == OPMODE_RX || mode == OPMODE_RX_SINGLE || mode == OPMODE_CAD) { // start of reception
dudmuck 0:f2716e543d97 310 rfsw2 = 1;
dudmuck 4:1a9a62cf220f 311 rfsw1 = 1;
dudmuck 6:dfc048cda33f 312 hdr_fem_csd = 1; // debug
dudmuck 0:f2716e543d97 313 } else { // RF switch shutdown
dudmuck 0:f2716e543d97 314 rfsw2 = 0;
dudmuck 0:f2716e543d97 315 rfsw1 = 0;
dudmuck 6:dfc048cda33f 316 hdr_fem_csd = 0; // debug
dudmuck 0:f2716e543d97 317 }
dudmuck 0:f2716e543d97 318 }
dudmuck 0:f2716e543d97 319
dudmuck 0:f2716e543d97 320 void hal_pin_rst (u1_t val)
dudmuck 0:f2716e543d97 321 {
dudmuck 0:f2716e543d97 322 if (val == 0 || val == 1) { // drive pin
dudmuck 0:f2716e543d97 323 rst.output();
dudmuck 0:f2716e543d97 324 rst = val;
dudmuck 0:f2716e543d97 325 } else { // keep pin floating
dudmuck 0:f2716e543d97 326 rst.input();
dudmuck 0:f2716e543d97 327 }
dudmuck 0:f2716e543d97 328 }
dudmuck 0:f2716e543d97 329