# hw definition file for processing by chibios_hwdef.py # MCU class and specific type MCU STM32F7xx STM32F777xx # board ID for firmware load APJ_BOARD_ID 141 # crystal frequency OSCILLATOR_HZ 24000000 define STM32_LSECLK 32768U define STM32_LSEDRV (3U << 3U) define STM32_PLLSRC STM32_PLLSRC_HSE define STM32_PLLM_VALUE 24 define STM32_PLLN_VALUE 432 define STM32_PLLP_VALUE 2 define STM32_PLLQ_VALUE 9 # board voltage STM32_VDD 330U FLASH_SIZE_KB 2048 # with 2M flash we can afford to optimize for speed env OPTIMIZE -O2 # start on 4th sector (1st sector for bootloader, 2 for extra storage) FLASH_RESERVE_START_KB 96 # fallback storage in case FRAM is not populated define STORAGE_FLASH_PAGE 1 # this is the STM32 timer that ChibiOS will use for the low level # driver. This must be a 32 bit timer, so Timers 2 or 5 on the STM32F777. # See hal_st_lld.c in ChibiOS for details # ChibiOS system timer STM32_ST_USE_TIMER 5 define HAL_STORAGE_SIZE 16384 # USB setup USB_VENDOR 0x0483 # ST USB_PRODUCT 0x5740 USB_STRING_MANUFACTURER "mRo" # RC Input set for Interrupt not DMA PC7 TIM3_CH2 TIM3 RCININT FLOAT LOW # also USART6_RX for serial RC # Control of Spektrum power pin PE4 SPEKTRUM_PWR OUTPUT LOW GPIO(70) define HAL_GPIO_SPEKTRUM_PWR 70 # Spektrum Power is Active Low define HAL_SPEKTRUM_PWR_ENABLED 0 # Spektrum RC Input pin, used as GPIO for bind for Satellite Receivers PB0 SPEKTRUM_RC INPUT PULLUP GPIO(71) define HAL_GPIO_SPEKTRUM_RC 71 # Order of I2C buses I2C_ORDER I2C1 # this board only has a single I2C bus so make it external define HAL_I2C_INTERNAL_MASK 0 # OEM Only # I2C_ORDER I2C1, I2C2, I2C3 # order of UARTs (and USB) # UART4 GPS # USART2 FC # USART3 FC # UART8 FRSKY Telem # USART6 FC # UART7 DEBUG UART_ORDER OTG1 UART4 USART2 USART3 UART8 USART6 UART7 OTG2 # default the 2nd interface to MAVLink2 until MissionPlanner updates drivers define HAL_OTG2_PROTOCOL SerialProtocol_MAVLink2 # Another USART, this one for telem1. This one has RTS and CTS lines. # USART2 telem1 PD3 USART2_CTS USART2 PD4 USART2_RTS USART2 PD5 USART2_TX USART2 PD6 USART2_RX USART2 # The telem2 USART, this one for telem2. This one has RTS and CTS lines. # USART3 telem2 PD8 USART3_TX USART3 PD9 USART3_RX USART3 PD11 USART3_CTS USART3 PD12 USART3_RTS USART3 # UART4 GPS PA0 UART4_TX UART4 PA1 UART4_RX UART4 NODMA # USART6 Spare or can be configured as SPI6 PG14 USART6_TX USART6 NODMA PG9 USART6_RX USART6 NODMA # UART7 maps to uartF in the HAL (serial5 in SERIALn_ parameters). Debug Console PE7 UART7_RX UART7 NODMA PE8 UART7_TX UART7 NODMA # UART8 FrSky Telemetry PE0 UART8_RX UART8 NODMA PE1 UART8_TX UART8 NODMA # RSSI Analog Input PC1 RSSI_IN ADC1 # Safety Switch Input PC4 SAFETY_IN INPUT PULLDOWN PA2 BATT_VOLTAGE_SENS ADC1 SCALE(1) PA3 BATT_CURRENT_SENS ADC1 SCALE(1) # Now the VDD sense pin. This is used to sense primary board voltage. PA4 VDD_5V_SENS ADC1 SCALE(2) #SPI1 ICM_20602 / ICM_20948 PA5 SPI1_SCK SPI1 PA6 SPI1_MISO SPI1 PA7 SPI1_MOSI SPI1 #SPI2 FRAM / DPS310 PB10 SPI2_SCK SPI2 PB14 SPI2_MISO SPI2 PB15 SPI2_MOSI SPI2 #SPI5 BMI088 PF7 SPI5_SCK SPI5 PF8 SPI5_MISO SPI5 PF9 SPI5_MOSI SPI5 # This is the pin that senses USB being connected. It is an input pin # setup as OPENDRAIN. PA9 VBUS INPUT OPENDRAIN # This input pin is used to detect that power is valid on USB. PC0 VBUS_VALID INPUT # Now we define the pins that USB is connected on. PA11 OTG_FS_DM OTG1 PA12 OTG_FS_DP OTG1 # These are the pins for SWD debugging with a STlinkv2 or black-magic probe. PA13 JTMS-SWDIO SWD PA14 JTCK-SWCLK SWD # PWM output for buzzer PA15 TIM2_CH1 TIM2 GPIO(77) ALARM # Now the first I2C bus. The pin speeds are automatically setup # correctly, but can be overridden here if needed. PB8 I2C1_SCL I2C1 PB9 I2C1_SDA I2C1 # the 2nd I2C bus, OEM Only # PB10 I2C2_SCL I2C2 # PB11 I2C2_SDA I2C2 # the 3nd I2C bus, OEM Only # PB6 I2C4_SCL I2C4 # PB7 I2C4_SDA I2C4 # Now setup the pins for the microSD card, if available. PC8 SDMMC_D0 SDMMC1 PC9 SDMMC_D1 SDMMC1 PC10 SDMMC_D2 SDMMC1 PC11 SDMMC_D3 SDMMC1 PC12 SDMMC_CK SDMMC1 PD2 SDMMC_CMD SDMMC1 # More CS pins for more sensors. The labels for all CS pins need to # match the SPI device table later in this file. PC2 ICM_20602_CS CS PD7 BARO_CS CS # The CS pin for FRAM (ramtron). This one is marked as using # SPEED_VERYLOW, which matches the HAL_PX4 setup. PD10 FRAM_CS CS SPEED_VERYLOW NODMA PE15 ICM_20948_CS CS PF10 BMI088_GYRO_CS CS PF6 BMI088_ACCEL_CS CS # the first CAN bus PD0 CAN1_RX CAN1 PD1 CAN1_TX CAN1 PF5 GPIO_CAN1_SILENT OUTPUT PUSHPULL SPEED_LOW LOW GPIO(72) # This defines the pins for the 2nd CAN interface, OEM Only. # PB6 CAN2_TX CAN2 # PB4 CAN2_RX CAN2 # Now we start defining some PWM pins. We also map these pins to GPIO # values, so users can set BRD_PWM_COUNT to choose how many of the PWM # outputs on the primary MCU are setup as PWM and how many as # GPIOs. To match HAL_PX4 we number the GPIOs for the PWM outputs # starting at 50. PE14 TIM1_CH4 TIM1 PWM(1) GPIO(50) PE13 TIM1_CH3 TIM1 PWM(2) GPIO(51) PE11 TIM1_CH2 TIM1 PWM(3) GPIO(52) PE9 TIM1_CH1 TIM1 PWM(4) GPIO(53) PD13 TIM4_CH2 TIM4 PWM(5) GPIO(54) PD14 TIM4_CH3 TIM4 PWM(6) GPIO(55) PI5 TIM8_CH1 TIM8 PWM(7) GPIO(56) PI6 TIM8_CH2 TIM8 PWM(8) GPIO(57) define BOARD_PWM_COUNT_DEFAULT 8 # This is the invensense data-ready pin. We don't use it in the # default driver. PD15 MPU_DRDY INPUT # This is the pin to enable the sensors rail. It can be used to power # cycle sensors to recover them in case there are problems with power on # timing affecting sensor stability. We pull it high by default. PE3 VDD_3V3_SENSORS_EN OUTPUT HIGH # Power flag pins: these tell the MCU the status of the various power # supplies that are available. The pin names need to exactly match the # names used in AnalogIn.cpp. PB5 VDD_BRICK_VALID INPUT PULLUP SPIDEV dps280 SPI2 DEVID3 BARO_CS MODE3 10*MHZ 10*MHZ SPIDEV ramtron SPI2 DEVID10 FRAM_CS MODE3 8*MHZ 8*MHZ SPIDEV icm20948 SPI1 DEVID1 ICM_20948_CS MODE3 2*MHZ 4*MHZ SPIDEV icm20608 SPI1 DEVID2 ICM_20602_CS MODE3 2*MHZ 8*MHZ SPIDEV bmi088_g SPI5 DEVID1 BMI088_GYRO_CS MODE3 10*MHZ 10*MHZ SPIDEV bmi088_a SPI5 DEVID2 BMI088_ACCEL_CS MODE3 10*MHZ 10*MHZ # Now some defines for logging and terrain data files. define HAL_BOARD_LOG_DIRECTORY "/APM/LOGS" define HAL_BOARD_TERRAIN_DIRECTORY "/APM/TERRAIN" # allow to have have a dedicated safety switch pin define HAL_HAVE_SAFETY_SWITCH 1 # Enable RAMTROM parameter storage. define HAL_WITH_RAMTRON 1 # Enable FAT filesystem support (needs a microSD defined via SDMMC). define HAL_OS_FATFS_IO 1 # Enable RTSCTS support. You should define this if you have any UARTs with RTS/CTS pins. define AP_FEATURE_RTSCTS 1 # Now setup the default battery pins driver analog pins and default # scaling for the power brick. define HAL_BATT_VOLT_PIN 2 define HAL_BATT_CURR_PIN 3 define HAL_BATT_VOLT_SCALE 10.1 define HAL_BATT_CURR_SCALE 17.0 # Control Zero has a TriColor LED, Red, Green, Blue define HAL_HAVE_PIXRACER_LED define HAL_GPIO_LED_ON 0 define HAL_GPIO_LED_OFF 1 # LED setup for PixracerLED driver PB11 LED_R OUTPUT HIGH GPIO(0) PB1 LED_G OUTPUT HIGH GPIO(1) PB3 LED_B OUTPUT HIGH GPIO(2) define HAL_GPIO_A_LED_PIN 0 define HAL_GPIO_B_LED_PIN 1 define HAL_GPIO_C_LED_PIN 2 DMA_PRIORITY SDMMC* #DMA_NOSHARE SPI1* * #DMA_NOSHARE SPI5* * # 3 IMUs IMU Invensensev2 SPI:icm20948 ROTATION_ROLL_180_YAW_90 IMU Invensense SPI:icm20608 ROTATION_ROLL_180_YAW_90 IMU BMI088 SPI:bmi088_a SPI:bmi088_g ROTATION_NONE # 1 baro BARO DPS280 SPI:dps280 # 1 compass COMPASS AK09916:probe_ICM20948 0 ROTATION_ROLL_180 define HAL_PROBE_EXTERNAL_I2C_COMPASSES