/** ****************************************************************************** * * @file main.c * @author The OpenPilot Team, http://www.openpilot.org Copyright (C) 2010. * @brief Main modem functions * @see The GNU Public License (GPL) Version 3 * *****************************************************************************/ /* * This program is free software; you can redistribute it and/or modify * it under the terms of the GNU General Public License as published by * the Free Software Foundation; either version 3 of the License, or * (at your option) any later version. * * This program is distributed in the hope that it will be useful, but * WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY * or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License * for more details. * * You should have received a copy of the GNU General Public License along * with this program; if not, write to the Free Software Foundation, Inc., * 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA */ // ***************************************************************************** #define USE_WATCHDOG // comment this out if you don't want to use the watchdog // ***************************************************************************** // OpenPilot Includes #include #include "crc.h" #include "aes.h" #include "rfm22b.h" #include "packet_handler.h" #include "transparent_comms.h" #include "uavtalk_comms.h" #include "gpio_in.h" #include "stopwatch.h" #include "watchdog.h" #include "saved_settings.h" #include "main.h" // ***************************************************************************** // ADC data #define ADC_REF 3.3f // ADC reference voltage #define ADC_FULL_RANGE 4096 // 12 bit ADC #define ADC_PSU_RESISTOR_TOP 10000.0f // 10k upper resistor #define ADC_PSU_RESISTOR_BOTTOM 2700.0f // 2k7 lower resistor #define ADC_PSU_RATIO (ADC_PSU_RESISTOR_BOTTOM / (ADC_PSU_RESISTOR_TOP + ADC_PSU_RESISTOR_BOTTOM)) #define ADC_PSU_mV_SCALE ((ADC_REF * 1000) / (ADC_FULL_RANGE * ADC_PSU_RATIO)) // ***************************************************************************** // Global Variables uint32_t flash_size; char serial_number_str[25]; uint32_t serial_number_crc32; uint32_t reset_addr; bool API_Mode; bool booting; volatile uint32_t random32; // ***************************************************************************** // Local Variables #if defined(USE_WATCHDOG) volatile uint16_t watchdog_timer; uint16_t watchdog_delay; #endif volatile bool inside_timer_int; volatile uint32_t uptime_ms; volatile uint16_t second_tick_timer; volatile bool second_tick; //volatile int32_t temp_adc; //volatile int32_t psu_adc; // ***************************************************************************** #if defined(USE_WATCHDOG) void processWatchdog(void) { // random32 = UpdateCRC32(random32, IWDG->SR); if (watchdog_timer < watchdog_delay) return; // the watchdog needs resetting watchdog_timer = 0; watchdog_Clear(); } void enableWatchdog(void) { // enable a watchdog watchdog_timer = 0; watchdog_delay = watchdog_Init(1000); // 1 second watchdog timeout } #endif // ***************************************************************************** /* void WWDG_IRQHandler(void) { // Update WWDG counter WWDG_SetCounter(0x7F); // Clear EWI flag WWDG_ClearFlag(); } void enableWatchdog(void) { // Enable WWDG clock RCC_APB1PeriphClockCmd(RCC_APB1Periph_WWDG, ENABLE); // On Value line devices, WWDG clock counter = (PCLK1 (24MHz)/4096)/8 = 732 Hz (~1366 ęs) // On other devices, WWDG clock counter = (PCLK1(36MHz)/4096)/8 = 1099 Hz (~910 ęs) WWDG_SetPrescaler(WWDG_Prescaler_8); // Set Window value to 65 WWDG_SetWindowValue(65); // On Value line devices, Enable WWDG and set counter value to 127, WWDG timeout = ~1366 ęs * 64 = 87.42 ms // On other devices, Enable WWDG and set counter value to 127, WWDG timeout = ~910 ęs * 64 = 58.25 ms WWDG_Enable(127); // Clear EWI flag WWDG_ClearFlag(); // Enable EW interrupt WWDG_EnableIT(); } */ // ***************************************************************************** void sequenceLEDs(void) { for (int i = 0; i < 2; i++) { USB_LED_ON; PIOS_DELAY_WaitmS(80); USB_LED_OFF; LINK_LED_ON; PIOS_DELAY_WaitmS(80); LINK_LED_OFF; RX_LED_ON; PIOS_DELAY_WaitmS(80); RX_LED_OFF; TX_LED_ON; PIOS_DELAY_WaitmS(80); TX_LED_OFF; #if defined(USE_WATCHDOG) processWatchdog(); // process the watchdog #endif } } // ***************************************************************************** /* void setup_SPI(void) { SPI_InitTypeDef SPI_InitStructure; SPI_InitStructure.SPI_Mode = SPI_Mode_Master, // SPI_InitStructure.SPI_Mode = SPI_Mode_Slave, SPI_InitStructure.SPI_Direction = SPI_Direction_2Lines_FullDuplex, // SPI_InitStructure.SPI_Direction = SPI_Direction_2Lines_RxOnly, // SPI_InitStructure.SPI_Direction = SPI_Direction_1Line_Rx, // SPI_InitStructure.SPI_Direction = SPI_Direction_1Line_Tx, // SPI_InitStructure.SPI_DataSize = SPI_DataSize_16b, SPI_InitStructure.SPI_DataSize = SPI_DataSize_8b, SPI_InitStructure.SPI_NSS = SPI_NSS_Soft, // SPI_InitStructure.SPI_NSS = SPI_NSS_Hard, SPI_InitStructure.SPI_FirstBit = SPI_FirstBit_MSB, // SPI_InitStructure.SPI_FirstBit = SPI_FirstBit_LSB, SPI_InitStructure.SPI_CRCPolynomial = 7, // SPI_InitStructure.SPI_CPOL = SPI_CPOL_Low, SPI_InitStructure.SPI_CPOL = SPI_CPOL_High, // SPI_InitStructure.SPI_CPHA = SPI_CPHA_1Edge, SPI_InitStructure.SPI_CPHA = SPI_CPHA_2Edge, // SPI_InitStructure.SPI_BaudRatePrescaler = SPI_BaudRatePrescaler_2, // fastest SCLK // SPI_InitStructure.SPI_BaudRatePrescaler = SPI_BaudRatePrescaler_4, // SPI_InitStructure.SPI_BaudRatePrescaler = SPI_BaudRatePrescaler_8, // SPI_InitStructure.SPI_BaudRatePrescaler = SPI_BaudRatePrescaler_16, // SPI_InitStructure.SPI_BaudRatePrescaler = SPI_BaudRatePrescaler_32, // SPI_InitStructure.SPI_BaudRatePrescaler = SPI_BaudRatePrescaler_64, // SPI_InitStructure.SPI_BaudRatePrescaler = SPI_BaudRatePrescaler_128, SPI_InitStructure.SPI_BaudRatePrescaler = SPI_BaudRatePrescaler_256, // slowest SCLK SPI_Init(SPI1, &SPI_InitStructure); SPI_Cmd(SPI1, ENABLE); } */ // ***************************************************************************** // timer interrupt void TIMER_INT_FUNC(void) { inside_timer_int = TRUE; if (TIM_GetITStatus(TIMER_INT_TIMER, TIM_IT_Update) != RESET) { // Clear timer interrupt pending bit TIM_ClearITPendingBit(TIMER_INT_TIMER, TIM_IT_Update); // random32 = UpdateCRC32(random32, PIOS_DELAY_TIMER->CNT >> 8); // random32 = UpdateCRC32(random32, PIOS_DELAY_TIMER->CNT); uptime_ms++; #if defined(USE_WATCHDOG) watchdog_timer++; #endif // *********** if (!booting) { // *********** if (++second_tick_timer >= 1000) { second_tick_timer -= 1000; second_tick = TRUE; } // *********** // read the chip temperature // temp_adc = PIOS_ADC_PinGet(0); // read the psu voltage // psu_adc = PIOS_ADC_PinGet(1); // *********** rfm22_1ms_tick(); // rf module tick ph_1ms_tick(); // packet handler tick if (!API_Mode) trans_1ms_tick(); // transparent communications tick else uavtalk_1ms_tick(); // uavtalk communications tick // *********** } } inside_timer_int = FALSE; } void setup_TimerInt(uint16_t Hz) { // setup the timer interrupt // enable timer clock switch ((uint32_t)TIMER_INT_TIMER) { case (uint32_t)TIM1: RCC_APB2PeriphClockCmd(RCC_APB2Periph_TIM1, ENABLE); break; case (uint32_t)TIM2: RCC_APB1PeriphClockCmd(RCC_APB1Periph_TIM2, ENABLE); break; case (uint32_t)TIM3: RCC_APB1PeriphClockCmd(RCC_APB1Periph_TIM3, ENABLE); break; case (uint32_t)TIM4: RCC_APB1PeriphClockCmd(RCC_APB1Periph_TIM4, ENABLE); break; #ifdef STM32F10X_HD case (uint32_t)TIM5: RCC_APB1PeriphClockCmd(RCC_APB1Periph_TIM5, ENABLE); break; case (uint32_t)TIM6: RCC_APB1PeriphClockCmd(RCC_APB1Periph_TIM6, ENABLE); break; case (uint32_t)TIM7: RCC_APB1PeriphClockCmd(RCC_APB1Periph_TIM7, ENABLE); break; case (uint32_t)TIM8: RCC_APB2PeriphClockCmd(RCC_APB2Periph_TIM8, ENABLE); break; #endif } // enable timer interrupt NVIC_InitTypeDef NVIC_InitStructure; switch ((uint32_t)TIMER_INT_TIMER) { // case (uint32_t)TIM1: NVIC_InitStructure.NVIC_IRQChannel = TIM1_IRQn; break; case (uint32_t)TIM2: NVIC_InitStructure.NVIC_IRQChannel = TIM2_IRQn; break; case (uint32_t)TIM3: NVIC_InitStructure.NVIC_IRQChannel = TIM3_IRQn; break; case (uint32_t)TIM4: NVIC_InitStructure.NVIC_IRQChannel = TIM4_IRQn; break; #ifdef STM32F10X_HD case (uint32_t)TIM5: NVIC_InitStructure.NVIC_IRQChannel = TIM5_IRQn; break; case (uint32_t)TIM6: NVIC_InitStructure.NVIC_IRQChannel = TIM6_IRQn; break; case (uint32_t)TIM7: NVIC_InitStructure.NVIC_IRQChannel = TIM7_IRQn; break; // case (uint32_t)TIM8: NVIC_InitStructure.NVIC_IRQChannel = TIM8_IRQn; break; #endif } NVIC_InitStructure.NVIC_IRQChannelPreemptionPriority = TIMER_INT_PRIORITY; NVIC_InitStructure.NVIC_IRQChannelSubPriority = 0; NVIC_InitStructure.NVIC_IRQChannelCmd = ENABLE; NVIC_Init(&NVIC_InitStructure); // Time base configuration TIM_TimeBaseInitTypeDef TIM_TimeBaseStructure; TIM_TimeBaseStructInit(&TIM_TimeBaseStructure); TIM_TimeBaseStructure.TIM_Period = ((1000000 / Hz) - 1); TIM_TimeBaseStructure.TIM_Prescaler = (PIOS_MASTER_CLOCK / 1000000) - 1; // For 1 uS accuracy TIM_TimeBaseStructure.TIM_ClockDivision = TIM_CKD_DIV1; TIM_TimeBaseStructure.TIM_CounterMode = TIM_CounterMode_Up; TIM_TimeBaseInit(TIMER_INT_TIMER, &TIM_TimeBaseStructure); // Enable the CC2 Interrupt Request TIM_ITConfig(TIMER_INT_TIMER, TIM_IT_Update, ENABLE); // Clear update pending flag TIM_ClearFlag(TIMER_INT_TIMER, TIM_FLAG_Update); // Enable counter TIM_Cmd(TIMER_INT_TIMER, ENABLE); } // ***************************************************************************** // read the CPU's flash and ram sizes void get_CPUDetails(void) { // read the flash size flash_size = (uint32_t)mem16(0x1FFFF7E0) * 1024; int j = 0; // read the CPU electronic signature (12-bytes) serial_number_str[j] = 0; for (int i = 0; i < 12; i++) { uint8_t ms_nibble = mem8(0x1ffff7e8 + i) >> 4; uint8_t ls_nibble = mem8(0x1ffff7e8 + i) & 0x0f; if (j > sizeof(serial_number_str) - 3) break; serial_number_str[j++] = ((ms_nibble > 9) ? ('A' - 10) : '0') + ms_nibble; serial_number_str[j++] = ((ls_nibble > 9) ? ('A' - 10) : '0') + ls_nibble; serial_number_str[j] = 0; } // create a 32-bit crc from the serial number hex string serial_number_crc32 = UpdateCRC32Data(0xffffffff, serial_number_str, j); serial_number_crc32 = UpdateCRC32(serial_number_crc32, j); // reset_addr = (uint32_t)&Reset_Handler; } // ***************************************************************************** void init_RF_module(void) { int i = -100; switch (saved_settings.frequency_band) { case freqBand_434MHz: case freqBand_868MHz: case freqBand_915MHz: i = rfm22_init(saved_settings.min_frequency_Hz, saved_settings.max_frequency_Hz, 50000); break; default: #if defined(PIOS_COM_DEBUG) DEBUG_PRINTF("UNKNOWN BAND ERROR\r\n", i); #endif for (int j = 0; j < 8; j++) { USB_LED_ON; LINK_LED_OFF; RX_LED_ON; TX_LED_OFF; PIOS_DELAY_WaitmS(200); USB_LED_OFF; LINK_LED_ON; RX_LED_OFF; TX_LED_ON; PIOS_DELAY_WaitmS(200); #if defined(USE_WATCHDOG) processWatchdog(); #endif } PIOS_DELAY_WaitmS(1000); PIOS_SYS_Reset(); while (1); break; } if (i < 0) { // RF module error .. flash the LED's #if defined(PIOS_COM_DEBUG) DEBUG_PRINTF("RF ERROR res: %d\r\n", i); #endif for (int j = 0; j < 6; j++) { USB_LED_ON; LINK_LED_ON; RX_LED_OFF; TX_LED_OFF; PIOS_DELAY_WaitmS(200); USB_LED_OFF; LINK_LED_OFF; RX_LED_ON; TX_LED_ON; PIOS_DELAY_WaitmS(200); #if defined(USE_WATCHDOG) processWatchdog(); #endif } PIOS_DELAY_WaitmS(1000); PIOS_SYS_Reset(); while (1); } // set carrier frequency rfm22_setNominalCarrierFrequency(saved_settings.frequency_Hz); ph_setDatarate(saved_settings.max_rf_bandwidth); ph_setTxPower(saved_settings.max_tx_power); } // ***************************************************************************** // find out what caused our reset and act on it void processReset(void) { if (RCC_GetFlagStatus(RCC_FLAG_IWDGRST) != RESET) { // Independant Watchdog Reset #if defined(PIOS_COM_DEBUG) DEBUG_PRINTF("\r\nINDEPENDANT WATCHDOG CAUSED A RESET\r\n"); #endif // all led's ON USB_LED_ON; LINK_LED_ON; RX_LED_ON; TX_LED_ON; PIOS_DELAY_WaitmS(500); // delay a bit // all led's OFF USB_LED_OFF; LINK_LED_OFF; RX_LED_OFF; TX_LED_OFF; } /* if (RCC_GetFlagStatus(RCC_FLAG_WWDGRST) != RESET) { // Window Watchdog Reset DEBUG_PRINTF("\r\nWINDOW WATCHDOG CAUSED A REBOOT\r\n"); // all led's ON USB_LED_ON; LINK_LED_ON; RX_LED_ON; TX_LED_ON; PIOS_DELAY_WaitmS(500); // delay a bit // all led's OFF USB_LED_OFF; LINK_LED_OFF; RX_LED_OFF; TX_LED_OFF; } */ if (RCC_GetFlagStatus(RCC_FLAG_PORRST) != RESET) { // Power-On Reset #if defined(PIOS_COM_DEBUG) DEBUG_PRINTF("\r\nPOWER-ON-RESET\r\n"); #endif } if (RCC_GetFlagStatus(RCC_FLAG_SFTRST) != RESET) { // Software Reset #if defined(PIOS_COM_DEBUG) DEBUG_PRINTF("\r\nSOFTWARE RESET\r\n"); #endif } if (RCC_GetFlagStatus(RCC_FLAG_LPWRRST) != RESET) { // Low-Power Reset #if defined(PIOS_COM_DEBUG) DEBUG_PRINTF("\r\nLOW POWER RESET\r\n"); #endif } if (RCC_GetFlagStatus(RCC_FLAG_PINRST) != RESET) { // Pin Reset #if defined(PIOS_COM_DEBUG) DEBUG_PRINTF("\r\nPIN RESET\r\n"); #endif } // Clear reset flags RCC_ClearFlag(); } // ***************************************************************************** // Main function int main() { // ************* // init various variables booting = TRUE; inside_timer_int = FALSE; uptime_ms = 0; flash_size = 0; serial_number_str[0] = 0; serial_number_crc32 = 0; reset_addr = 0; // temp_adc = -1; // psu_adc = -1; API_Mode = FALSE; // API_Mode = TRUE; // TEST ONLY second_tick_timer = 0; second_tick = FALSE; saved_settings.frequency_band = freqBand_UNKNOWN; // ************* // Bring up System using CMSIS functions, enables the LEDs. PIOS_SYS_Init(); // turn all the leds on USB_LED_ON; LINK_LED_ON; RX_LED_ON; TX_LED_ON; CRC_init(); // read the CPU details get_CPUDetails(); // Delay system PIOS_DELAY_Init(); // UART communication system PIOS_COM_Init(); // ADC system // PIOS_ADC_Init(); // SPI link to master PIOS_SPI_Init(); // setup the GPIO input pins GPIO_IN_Init(); // ************* // set various GPIO pin states // uart serial RTS line high SERIAL_RTS_ENABLE; SERIAL_RTS_SET; // RF module chip-select line high RF_CS_ENABLE; RF_CS_HIGH; // EEPROM chip-select line high EE_CS_ENABLE; EE_CS_HIGH; // ************* random32 ^= serial_number_crc32; // try to randomize the random number // random32 ^= serial_number_crc32 ^ CRC_IDR; // try to randomize the random number ph_init(serial_number_crc32, 128000, 0); // initialise the packet handler trans_init(); // initialise the tranparent communications module uavtalk_init(); // initialise the UAVTalk communications module setup_TimerInt(1000); // setup a 1kHz timer interrupt #if defined(USE_WATCHDOG) enableWatchdog(); // enable the watchdog #endif // ************* // do a simple LED flash test sequence so the user knows all the led's are working and that we have booted PIOS_DELAY_WaitmS(100); // turn all the leds off USB_LED_OFF; LINK_LED_OFF; RX_LED_OFF; TX_LED_OFF; PIOS_DELAY_WaitmS(200); sequenceLEDs(); // turn all the leds off USB_LED_OFF; LINK_LED_OFF; RX_LED_OFF; TX_LED_OFF; // ************* // debug stuff #if defined(PIOS_COM_DEBUG) DEBUG_PRINTF("\r\n"); DEBUG_PRINTF("PipXtreme v%u.%u rebooted\r\n", version_major, version_minor); #endif // ************* // initialize the saved settings module saved_settings_init(); // ************* // read the API mode pin if (!GPIO_IN(API_MODE_PIN)) API_Mode = TRUE; // ************* // read the 434/868/915 jumper options if (!GPIO_IN(_868MHz_PIN) && !GPIO_IN(_915MHz_PIN)) saved_settings.frequency_band = freqBand_434MHz; // 434MHz band else if (!GPIO_IN(_868MHz_PIN) && GPIO_IN(_915MHz_PIN)) saved_settings.frequency_band = freqBand_868MHz; // 868MHz band else if ( GPIO_IN(_868MHz_PIN) && !GPIO_IN(_915MHz_PIN)) saved_settings.frequency_band = freqBand_915MHz; // 915MHz band switch (saved_settings.frequency_band) { case freqBand_434MHz: // if (saved_settings.frequency_Hz == 0xffffffff) { saved_settings.frequency_Hz = 434000000; saved_settings.min_frequency_Hz = 434000000 - 2000000; saved_settings.max_frequency_Hz = 434000000 + 2000000; } // if (saved_settings.max_rf_bandwidth == 0xffffffff) { // saved_settings.max_rf_bandwidth = 500; // saved_settings.max_rf_bandwidth = 1000; // saved_settings.max_rf_bandwidth = 2000; // saved_settings.max_rf_bandwidth = 4000; // saved_settings.max_rf_bandwidth = 8000; // saved_settings.max_rf_bandwidth = 9600; // saved_settings.max_rf_bandwidth = 16000; // saved_settings.max_rf_bandwidth = 19200; // saved_settings.max_rf_bandwidth = 24000; // saved_settings.max_rf_bandwidth = 32000; // saved_settings.max_rf_bandwidth = 64000; saved_settings.max_rf_bandwidth = 128000; // saved_settings.max_rf_bandwidth = 192000; } // if (saved_settings.max_tx_power == 0xff) { // saved_settings.max_tx_power = 0; // +1dBm ... 1.25mW // saved_settings.max_tx_power = 1; // +2dBm ... 1.6mW // saved_settings.max_tx_power = 2; // +5dBm ... 3.16mW // saved_settings.max_tx_power = 3; // +8dBm ... 6.3mW saved_settings.max_tx_power = 4; // +11dBm .. 12.6mW // saved_settings.max_tx_power = 5; // +14dBm .. 25mW // saved_settings.max_tx_power = 6; // +17dBm .. 50mW // saved_settings.max_tx_power = 7; // +20dBm .. 100mW } break; case freqBand_868MHz: // if (saved_settings.frequency_Hz == 0xffffffff) { saved_settings.frequency_Hz = 868000000; saved_settings.min_frequency_Hz = 868000000 - 10000000; saved_settings.max_frequency_Hz = 868000000 + 10000000; } // if (saved_settings.max_rf_bandwidth == 0xffffffff) { // saved_settings.max_rf_bandwidth = 500; // saved_settings.max_rf_bandwidth = 1000; // saved_settings.max_rf_bandwidth = 2000; // saved_settings.max_rf_bandwidth = 4000; // saved_settings.max_rf_bandwidth = 8000; // saved_settings.max_rf_bandwidth = 9600; // saved_settings.max_rf_bandwidth = 16000; // saved_settings.max_rf_bandwidth = 19200; // saved_settings.max_rf_bandwidth = 24000; // saved_settings.max_rf_bandwidth = 32000; // saved_settings.max_rf_bandwidth = 64000; saved_settings.max_rf_bandwidth = 128000; // saved_settings.max_rf_bandwidth = 192000; } // if (saved_settings.max_tx_power == 0xff) { // saved_settings.max_tx_power = 0; // +1dBm ... 1.25mW // saved_settings.max_tx_power = 1; // +2dBm ... 1.6mW // saved_settings.max_tx_power = 2; // +5dBm ... 3.16mW // saved_settings.max_tx_power = 3; // +8dBm ... 6.3mW saved_settings.max_tx_power = 4; // +11dBm .. 12.6mW // saved_settings.max_tx_power = 5; // +14dBm .. 25mW // saved_settings.max_tx_power = 6; // +17dBm .. 50mW // saved_settings.max_tx_power = 7; // +20dBm .. 100mW } break; case freqBand_915MHz: // if (saved_settings.frequency_Hz == 0xffffffff) { saved_settings.frequency_Hz = 915000000; saved_settings.min_frequency_Hz = 915000000 - 13000000; saved_settings.max_frequency_Hz = 915000000 + 13000000; } // if (saved_settings.max_rf_bandwidth == 0xffffffff) { // saved_settings.max_rf_bandwidth = 500; // saved_settings.max_rf_bandwidth = 1000; // saved_settings.max_rf_bandwidth = 2000; // saved_settings.max_rf_bandwidth = 4000; // saved_settings.max_rf_bandwidth = 8000; // saved_settings.max_rf_bandwidth = 9600; // saved_settings.max_rf_bandwidth = 16000; // saved_settings.max_rf_bandwidth = 19200; // saved_settings.max_rf_bandwidth = 24000; // saved_settings.max_rf_bandwidth = 32000; // saved_settings.max_rf_bandwidth = 64000; saved_settings.max_rf_bandwidth = 128000; // saved_settings.max_rf_bandwidth = 192000; } // if (saved_settings.max_tx_power == 0xff) { // saved_settings.max_tx_power = 0; // +1dBm ... 1.25mW // saved_settings.max_tx_power = 1; // +2dBm ... 1.6mW // saved_settings.max_tx_power = 2; // +5dBm ... 3.16mW // saved_settings.max_tx_power = 3; // +8dBm ... 6.3mW saved_settings.max_tx_power = 4; // +11dBm .. 12.6mW // saved_settings.max_tx_power = 5; // +14dBm .. 25mW // saved_settings.max_tx_power = 6; // +17dBm .. 50mW // saved_settings.max_tx_power = 7; // +20dBm .. 100mW } break; default: break; } if (serial_number_crc32 == 0x176C1EC6) saved_settings.destination_id = 0xA524A3B0; // modem 1, open a connection to modem 2 else if (serial_number_crc32 == 0xA524A3B0) saved_settings.destination_id = 0x176C1EC6; // modem 2, open a connection to modem 1 // ************* processReset(); // Determine what caused the reset/reboot // ************* // debug stuff #if defined(PIOS_COM_DEBUG) DEBUG_PRINTF("\r\n"); DEBUG_PRINTF("CPU flash size: %u\r\n", flash_size); DEBUG_PRINTF("CPU serial number: %s %08X\r\n", serial_number_str, serial_number_crc32); // DEBUG_PRINTF("Reset address: %08X\r\n", reset_addr); if (!API_Mode) DEBUG_PRINTF("TRANSPARENT mode\r\n"); else DEBUG_PRINTF("API mode\r\n"); switch (saved_settings.frequency_band) { case freqBand_UNKNOWN: DEBUG_PRINTF("UNKNOWN band\r\n"); break; case freqBand_434MHz: DEBUG_PRINTF("434MHz band\r\n"); break; case freqBand_868MHz: DEBUG_PRINTF("868MHz band\r\n"); break; case freqBand_915MHz: DEBUG_PRINTF("915MHz band\r\n"); break; } #endif // ************* // initialize the RF module init_RF_module(); // ************* // initialize the USB interface #if defined(PIOS_INCLUDE_USB_HID) // PIOS_USB_HID_Init(0); // this is not needed as it gets called by the com init routine .. thank you Ed! #endif // ************* saved_settings_save(); booting = FALSE; // ************* ph_set_remote_serial_number(0, saved_settings.destination_id); #if defined(PIOS_COM_DEBUG) DEBUG_PRINTF("\r\n"); DEBUG_PRINTF("RF datarate: %dbps\r\n", ph_getDatarate()); DEBUG_PRINTF("RF frequency: %dHz\r\n", rfm22_getNominalCarrierFrequency()); DEBUG_PRINTF("RF TX power: %d\r\n", ph_getTxPower()); #endif // ************* // Main executive loop for (;;) { random32 = UpdateCRC32(random32, PIOS_DELAY_TIMER->CNT >> 8); random32 = UpdateCRC32(random32, PIOS_DELAY_TIMER->CNT); if (second_tick) { second_tick = FALSE; // ************************* // display the up-time .. HH:MM:SS // #if defined(PIOS_COM_DEBUG) // int32_t _uptime_ms = uptime_ms; // uint32_t _uptime_sec = _uptime_ms / 1000; // DEBUG_PRINTF("Uptime: %02d:%02d:%02d.%03d\r\n", _uptime_sec / 3600, (_uptime_sec / 60) % 60, _uptime_sec % 60, _uptime_ms % 1000); // #endif // ************************* // process the Temperature // if (temp_adc >= 0) // { // int32_t degress_C = temp_adc; // // #if defined(PIOS_COM_DEBUG) // DEBUG_PRINTF("TEMP: %d %d\r\n", temp_adc, degress_C); // #endif // } // ************************* // process the PSU voltage level // if (psu_adc >= 0) // { // int32_t psu_mV = psu_adc * ADC_PSU_mV_SCALE; // // #if defined(PIOS_COM_DEBUG) // DEBUG_PRINTF("PSU: %d, %dmV\r\n", psu_adc, psu_mV); // #endif // } // ************************* // rfm22_setTxCarrierMode(); // TEST ONLY } rfm22_process(); // rf hardware layer processing ph_process(); // packet handler processing if (!API_Mode) trans_process(); // tranparent local communication processing (serial port and usb port) else uavtalk_process(); // UAVTalk local communication processing (serial port and usb port) // ****************** // TEST ONLY ... get/put data over the radio link .. speed testing .. comment out trans_process() and uavtalk_process() if testing with this /* int connection_index = 0; if (ph_connected(connection_index)) { // we have a connection to a remote modem uint8_t buffer[128]; uint16_t num = ph_getData_used(connection_index); // number of bytes waiting for us to get if (num > 0) { // their is data in the received buffer - fetch it if (num > sizeof(buffer)) num = sizeof(buffer); num = ph_getData(connection_index, buffer, num); // fetch the received data } // keep the tx buffer topped up num = ph_putData_free(connection_index); if (num > 0) { // their is space available in the transmit buffer - top it up if (num > sizeof(buffer)) num = sizeof(buffer); for (int16_t i = 0; i < num; i++) buffer[i] = i; num = ph_putData(connection_index, buffer, num); } } */ // ****************** #if defined(USE_WATCHDOG) processWatchdog(); // process the watchdog #endif } // ************* // we should never arrive here // disable all interrupts PIOS_IRQ_Disable(); // turn off all leds USB_LED_OFF; LINK_LED_OFF; RX_LED_OFF; TX_LED_OFF; PIOS_SYS_Reset(); while (1); return 0; } // *****************************************************************************