mirror of https://github.com/ArduPilot/ardupilot
467 lines
18 KiB
Plaintext
467 lines
18 KiB
Plaintext
# hw definition file for processing by chibios_hwdef.py
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# for FMUv3 hardware (ie. for Pixhawk1, Pixhawk2 cube, XUAV2.1 etc)
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# This hwdef.dat file contains a lot of comments so it can act as a
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# reference for developers adding new boards.
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# The hwdef.dat file defines all the hardware peripherals and pins for
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# a port of ArduPilot to a board using the ChibiOS HAL. You should be
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# able to write the hwdef.dat file for a new board with just the
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# schematic for the board.
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# This file is processed by chibios_hwdef.py to create hwdef.h for
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# this board. You may find it useful to run chibios_hwdef.py manually
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# when building this file for a new board. The resulting hwdef.h file
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# is formatted to make it quite readable. It is strongly suggested
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# that you read the resulting hwdef.h file when porting to a new board
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# to make sure it has resulted in what you want.
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# You should read this file in conjunction with the schematic for your
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# board, the datasheet for the MCU for your board and the python
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# tables file that we have extracted from the datasheet for your
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# MCU. The python tables file is particularly important, so if you
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# haven't seen it before go and look at it now. For the STM32F427 it
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# it called STM32F427xx.py and it is in the hwdef/script/ directory
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# inside the HAL_ChibiOS directory. That file tells you what each pin
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# can do (the alternate functions table) and what DMA channels can be
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# used for each peripheral type. The alternative functions table is
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# particularly useful when doing a new hwdef.dat file as you can work
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# out peripheral numbers given a port/pin name.
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# We need to start off by saying what main CPU is on the board. There
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# are two CPU identifiers that you need to specify. The first is the
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# ChibiOS MCU type. So far we only support STM32F4xx for all STM32F4
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# board types. In the future we will add F7 and other MCU types
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# The second string needs to match the name of a config file in the
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# libraries/AP_HAL_ChibiOS/hwdef/script directory. In this case we are
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# using a F427 MCU, so we select STM32F427xx to match the
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# STM32F427xx.py file in the script directory. If you are supporting a
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# board type that doesn't have a python hardware database file yet
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# then you will need to create one. There are scripts in the scripts
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# directory to help with that by parsing the STM32 datasheets to
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# extract the required DMA and alternate function tables.
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# MCU class and specific type
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MCU STM32F4xx STM32F427xx
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# We set a specific HAL_BOARD_SUBTYPE, allowing for custom config in
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# drivers. For this to be used the subtype needs to be added to
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# AP_HAL/AP_HAL_Boards.h as well.
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define CONFIG_HAL_BOARD_SUBTYPE HAL_BOARD_SUBTYPE_CHIBIOS_FMUV3
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# Now we need to specify the APJ_BOARD_ID. This is the ID that the
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# bootloader presents to GCS software so it knows if this firmware is
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# suitable for the board. Please see
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# https://github.com/ArduPilot/Bootloader/blob/master/hw_config.h for
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# a list of current board IDs. If you add a new board type then please
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# get it added to that repository so we don't get conflicts.
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# Note that APJ is "ArduPilot JSON Firmware Format".
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# board ID for firmware load
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APJ_BOARD_ID 9
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# Now you need to say what crystal frequency you have for this
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# board. All of the clocks are scaled against this. Typical values are
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# 24000000 or 8000000.
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# crystal frequency
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OSCILLATOR_HZ 24000000
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# On some boards you will need to also set the various PLL values. See
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# the defaults in common/mcuconf.h, and use the define mechanism
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# explained later in this file to override values suitable for your
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# board. Refer to your MCU datasheet or examples from supported boards
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# in ChibiOS for the right values.
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# Now define the voltage the MCU runs at. This is needed for ChibiOS
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# to set various internal driver limits. It is in 0.01 volt units.
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# This is the STM32 timer that ChibiOS will use for the low level
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# driver. This must be a 32 bit timer. We currently only support
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# timers 2, 3, 4, 5 and 21. See hal_st_lld.c in ChibiOS for details.
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# ChibiOS system timer
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STM32_ST_USE_TIMER 5
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# Now the size of flash in kilobytes, for creating the ld.script.
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# flash size
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FLASH_SIZE_KB 2048
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# Now define which UART is used for printf(). We rarely use printf()
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# in ChibiOS, so this is really only for debugging very early startup
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# in drivers.
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# Serial port for stdout. This is optional. If you leave it out then
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# output from printf() lines will go to the ArduPilot console, which is the
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# first UART in the SERIAL_ORDER list. But note that some startup code
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# runs before USB is set up.
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# The value for STDOUT_SERIAL is a serial device name, and must be for a
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# serial device for which pins are defined in this file. For example, SD7
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# is for UART7 (SD7 == "serial device 7" in ChibiOS).
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#STDOUT_SERIAL SD7
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#STDOUT_BAUDRATE 57600
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# Now the USB setup, if you have USB. All of these settings are
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# option, and the ones below are the defaults. It ends up creating a
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# USB ID on Linux like this:
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# /dev/serial/by-id/usb-ArduPilot_fmuv3_3E0031000B51353233343932-if00
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# If creating a board for a RTF vehicle you may wish to customise these.
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# USB setup
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USB_STRING_MANUFACTURER "ArduPilot"
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# Now define the order that I2C buses are presented in the hal.i2c API
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# in ArduPilot. For historical reasons inherited from HAL_PX4 the
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# 'external' I2C bus should be bus 1 in hal.i2c, and internal I2C bus
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# should be bus 0. On fmuv3 the STM32 I2C1 is our external bus and
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# I2C2 is our internal bus, so we need to setup the order as I2C2
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# followed by I2C1 in order to achieve the conventional order that
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# drivers expect.
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# order of I2C buses
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I2C_ORDER I2C2 I2C1
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# Now the serial ordering. These map to the SERIALn_ parameter numbers
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# If you use a shorter list then HAL_Empty::UARTDriver
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# objects are substituted for later UARTs, or you can leave a gap by
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# listing one or more of the uarts as EMPTY.
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# The normal usage of this ordering is:
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# 1) SERIAL0: console (primary mavlink, usually USB)
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# 2) SERIAL1: telem1
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# 3) SERIAL2: telem2
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# 4) SERIAL3: primary GPS
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# 5) SERIAL4: GPS2
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# 6) SERIAL5: extra UART (usually RTOS debug console)
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# order of UARTs (and USB)
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SERIAL_ORDER OTG1 USART2 USART3 UART4 UART8 UART7
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# If the board has an IOMCU connected via a UART then this defines the
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# UART to talk to that MCU. Leave it out for boards with no IOMCU.
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# UART for IOMCU
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IOMCU_UART USART6
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# Now we start on the pin definitions. Every pin used by ArduPilot
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# needs to be in this file. The pins in this file can be defined in any order.
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# The format is P+port+pin. So PC4 is portC pin4.
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# For every pin the second column is the label. If this is a
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# peripheral that has an alternate function defined in the STM32
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# datasheet then the label must be the name of that alternative
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# function. The names are looked up in the python database for this
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# MCU. Please see STM32F427xx.py for the F427 database. That database
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# is used to automatically fill in the alternative function (and later
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# for the DMA channels).
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# The third column is the peripheral type. This must be one of the
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# following: UARTn, USARTn, OTGn, SPIn, I2Cn, ADCn, TIMn, SWD, SDIO,
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# INPUT, OUTPUT, CS.
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# The fourth and later columns are for modifiers on the pin. The
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# possible modifiers are:
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# pin speed: SPEED_VERYLOW, SPEED_LOW, SPEED_MEDIUM, SPEED_HIGH
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# pullup: PULLUP, PULLDOWN, FLOATING
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# out type: OPENDRAIN, PUSHPULL
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# default value: LOW, HIGH
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# Additionally, each class of pin peripheral can have extra modifiers
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# suitable for that pin type. For example, for an OUTPUT you can map
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# it to a GPIO number in hal.gpio using the GPIO(n) modifier. For ADC
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# inputs you can apply a scaling factor (to bring it to unit volts)
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# using the SCALE(x) modifier. See the examples below for more
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# modifiers, or read the python code in chibios_hwdef.py.
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# Now we define UART4 which is for the GPS. Be careful
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# of the difference between USART and UART. Check the STM32F427xx.py
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# if unsure which it is. For a UART we need to specify at least TX and
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# RX pins.
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# UART4 serial GPS
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PA0 UART4_TX UART4
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PA1 UART4_RX UART4
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# Now define the primary battery connectors. The labels we choose here
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# are used to create defines for pins in the various drivers, so
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# choose names that match existing board setups where possible. Here
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# we define two pins PA2 and PA3 for voltage and current sensing, with
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# a scale factor of 1.0 and connected on ADC1. The pin number this
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# maps to in hal.adc is automatically determined using the datasheet
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# tables in STM32F427xx.py.
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PA2 BATT_VOLTAGE_SENS ADC1 SCALE(1)
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PA3 BATT_CURRENT_SENS ADC1 SCALE(1)
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# Now the VDD sense pin. This is used to sense primary board voltage.
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PA4 VDD_5V_SENS ADC1 SCALE(2)
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# Now the first SPI bus. At minimum you need SCK, MISO and MOSI pin
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definitions. You can add speed modifiers if you want them, otherwise
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the defaults for the peripheral class are used.
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PA5 SPI1_SCK SPI1
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PA6 SPI1_MISO SPI1
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PA7 SPI1_MOSI SPI1
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# This defines an output pin which will default to output LOW. It is a
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# pin that enables peripheral power on this board.
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PA8 nVDD_5V_PERIPH_EN OUTPUT LOW
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# This is the pin that senses USB being connected. It is an input pin
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# setup as OPENDRAIN.
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PA9 VBUS INPUT OPENDRAIN
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# This is a commented out pin for talking to the debug UART on the
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# IOMCU, not used yet, but left as a comment (with a '#' in front) for
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# future reference
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# PA10 IO-debug-console
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# Now we define the pins that USB is connected on.
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PA11 OTG_FS_DM OTG1
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PA12 OTG_FS_DP OTG1
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# These are the pins for SWD debugging with a STlinkv2 or black-magic probe.
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PA13 JTMS-SWDIO SWD
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PA14 JTCK-SWCLK SWD
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# This defines the PWM pin for the buzzer (if there is one). It is
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# also mapped to a GPIO output so you can play with the buzzer via
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# MAVLink relay commands if you want to.
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# PWM output for buzzer
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PA15 TIM2_CH1 TIM2 GPIO(77) ALARM
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# This defines a couple of general purpose outputs, mapped to GPIO
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# numbers 1 and 2 for users.
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PB0 EXTERN_GPIO1 OUTPUT GPIO(1)
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PB1 EXTERN_GPIO2 OUTPUT GPIO(2)
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# This defines some input pins, currently unused.
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PB2 BOOT1 INPUT
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PB3 FMU_SW0 INPUT
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# This defines the pins for the 2nd CAN interface, if available.
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PB6 CAN2_TX CAN2
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PB12 CAN2_RX CAN2
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# Now the first I2C bus. The pin speeds are automatically setup
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# correctly, but can be overridden here if needed.
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PB8 I2C1_SCL I2C1
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PB9 I2C1_SDA I2C1
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# the 2nd I2C bus
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PB10 I2C2_SCL I2C2
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PB11 I2C2_SDA I2C2
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# the 2nd SPI bus
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PB13 SPI2_SCK SPI2
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PB14 SPI2_MISO SPI2
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PB15 SPI2_MOSI SPI2
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# This input pin is used to detect that power is valid on USB.
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PC0 VBUS_nVALID INPUT PULLUP
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# This defines the CS pin for the magnetometer and first IMU. Note
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# that CS pins are software controlled, and are not tied to a particular
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# SPI bus.
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PC1 MAG_CS CS
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PC2 MPU_CS CS
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# This defines more ADC inputs.
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PC3 AUX_POWER ADC1 SCALE(1)
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PC4 AUX_ADC2 ADC1 SCALE(1)
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# And the analog input for airspeed (rarely used these days).
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PC5 PRESSURE_SENS ADC1 SCALE(2)
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# This sets up the UART for talking to the IOMCU. Note that it is
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# vital that this UART has DMA available. See the DMA settings below
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# for more information.
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# USART6 to IO
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PC6 USART6_TX USART6
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PC7 USART6_RX USART6
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# Now setup the pins for the microSD card, if available.
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PC8 SDIO_D0 SDIO
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PC9 SDIO_D1 SDIO
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PC10 SDIO_D2 SDIO
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PC11 SDIO_D3 SDIO
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PC12 SDIO_CK SDIO
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PD2 SDIO_CMD SDIO
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# More CS pins for more sensors. The labels for all CS pins need to
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# match the SPI device table later in this file.
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PC13 GYRO_EXT_CS CS
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PC14 BARO_EXT_CS CS
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PC15 ACCEL_EXT_CS CS
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PD7 BARO_CS CS
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PE4 MPU_EXT_CS CS
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# the first CAN bus
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PD0 CAN1_RX CAN1
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PD1 CAN1_TX CAN1
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# Another USART, this one for telem1. This one has RTS and CTS lines.
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# USART2 serial2 telem1
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PD3 USART2_CTS USART2
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PD4 USART2_RTS USART2
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PD5 USART2_TX USART2
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PD6 USART2_RX USART2
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# The telem2 USART, also with RTS/CTS available.
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# USART3 serial3 telem2
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PD8 USART3_TX USART3
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PD9 USART3_RX USART3
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PD11 USART3_CTS USART3
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PD12 USART3_RTS USART3
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# The CS pin for FRAM (ramtron). This one is marked as using
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# SPEED_VERYLOW, which matches the HAL_PX4 setup.
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PD10 FRAM_CS CS SPEED_VERYLOW
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# Now we start defining some PWM pins. We also map these pins to GPIO
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# values, so users can set BRD_PWM_COUNT to choose how many of the PWM
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# outputs on the primary MCU are setup as PWM and how many as
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# GPIOs. To match HAL_PX4 we number the GPIOs for the PWM outputs
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# starting at 50.
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PE14 TIM1_CH4 TIM1 PWM(1) GPIO(50) # one of these is require by SPI4
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PE13 TIM1_CH3 TIM1 PWM(2) GPIO(51) BIDIR
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PE11 TIM1_CH2 TIM1 PWM(3) GPIO(52) BIDIR
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PE9 TIM1_CH1 TIM1 PWM(4) GPIO(53)
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PD13 TIM4_CH2 TIM4 PWM(5) GPIO(54) NODMA
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PD14 TIM4_CH3 TIM4 PWM(6) GPIO(55) NODMA
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# This is the invensense data-ready pin. We don't use it in the
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# default driver.
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PD15 MPU_DRDY INPUT
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# the 2nd GPS UART
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# UART8 serial4 GPS2
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PE0 UART8_RX UART8
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PE1 UART8_TX UART8
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# Now setup SPI bus4.
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#PE2 SPI4_SCK SPI4
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#PE5 SPI4_MISO SPI4
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#PE6 SPI4_MOSI SPI4
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# This is the pin to enable the sensors rail. It can be used to power
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# cycle sensors to recover them in case there are problems with power on
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# timing affecting sensor stability. We pull it high by default.
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PE3 VDD_3V3_SENSORS_EN OUTPUT HIGH
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# UART7 maps to SERIAL5.
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PE7 UART7_RX UART7
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PE8 UART7_TX UART7
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# Define a LED, mapping it to GPIO(0). LOW will illuminate the LED
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PE12 FMU_LED_AMBER OUTPUT HIGH OPENDRAIN GPIO(0)
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# Power flag pins: these tell the MCU the status of the various power
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# supplies that are available. The pin names need to exactly match the
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# names used in AnalogIn.cpp.
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PB5 VDD_BRICK_nVALID INPUT PULLUP
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PB7 VDD_BRICK2_nVALID INPUT PULLUP
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PE10 VDD_5V_HIPOWER_nOC INPUT PULLUP
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PE15 VDD_5V_PERIPH_nOC INPUT PULLUP
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# Now the SPI device table. This table creates all accessible SPI
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# devices, giving the name of the device (which is used by device
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# drivers to open the device), plus which SPI bus it it on, what
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# device ID will be used (which controls the IDs used in parameters
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# such as COMPASS_DEV_ID, so we can detect when the list of devices
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# changes between reboots for calibration purposes), the SPI mode to
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# use, and the low and high speed settings for the device.
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# You can define more SPI devices than you actually have, to allow for
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# flexibility in board setup, and the driver code can probe to see
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# which are responding.
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# The DEVID values and device names are chosen to match the PX4 port
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# of ArduPilot so users don't need to re-do their accel and compass
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# calibrations when moving to ChibiOS.
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SPIDEV ms5611 SPI1 DEVID3 BARO_CS MODE3 20*MHZ 20*MHZ
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#SPIDEV ms5611_ext SPI4 DEVID2 BARO_EXT_CS MODE3 20*MHZ 20*MHZ
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SPIDEV mpu6000 SPI1 DEVID4 MPU_CS MODE3 2*MHZ 8*MHZ
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SPIDEV icm20608-am SPI1 DEVID2 ACCEL_EXT_CS MODE3 4*MHZ 8*MHZ
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SPIDEV mpu9250 SPI1 DEVID4 MPU_CS MODE3 4*MHZ 8*MHZ
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#SPIDEV mpu9250_ext SPI4 DEVID1 MPU_EXT_CS MODE3 4*MHZ 8*MHZ
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SPIDEV icm20948 SPI1 DEVID4 MPU_CS MODE3 4*MHZ 8*MHZ
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#SPIDEV icm20948_ext SPI4 DEVID1 MPU_EXT_CS MODE3 4*MHZ 8*MHZ
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SPIDEV hmc5843 SPI1 DEVID5 MAG_CS MODE3 11*MHZ 11*MHZ
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SPIDEV lsm9ds0_g SPI1 DEVID1 GYRO_EXT_CS MODE3 11*MHZ 11*MHZ
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SPIDEV lsm9ds0_am SPI1 DEVID2 ACCEL_EXT_CS MODE3 11*MHZ 11*MHZ
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#SPIDEV lsm9ds0_ext_g SPI4 DEVID4 GYRO_EXT_CS MODE3 11*MHZ 11*MHZ
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#SPIDEV lsm9ds0_ext_am SPI4 DEVID3 ACCEL_EXT_CS MODE3 11*MHZ 11*MHZ
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#SPIDEV icm20602_ext SPI4 DEVID4 GYRO_EXT_CS MODE3 4*MHZ 8*MHZ
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SPIDEV ramtron SPI2 DEVID10 FRAM_CS MODE3 8*MHZ 8*MHZ
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#SPIDEV external0m0 SPI4 DEVID5 MPU_EXT_CS MODE0 2*MHZ 2*MHZ
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#SPIDEV external0m1 SPI4 DEVID5 MPU_EXT_CS MODE1 2*MHZ 2*MHZ
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#SPIDEV external0m2 SPI4 DEVID5 MPU_EXT_CS MODE2 2*MHZ 2*MHZ
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#SPIDEV external0m3 SPI4 DEVID5 MPU_EXT_CS MODE3 2*MHZ 2*MHZ
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#SPIDEV pixartPC15 SPI4 DEVID13 ACCEL_EXT_CS MODE3 2*MHZ 2*MHZ
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# Now some commented out SPI device names which can be used by
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# developers to test that the clock calculations are right for a
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# bus. This is used in conjunction with the mavproxy devop module.
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# for SPI clock testing
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#SPIDEV clock500 SPI4 DEVID5 MPU_EXT_CS MODE0 500*KHZ 500*KHZ # gives 329KHz
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#SPIDEV clock1 SPI4 DEVID5 MPU_EXT_CS MODE0 1*MHZ 1*MHZ # gives 657kHz
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#SPIDEV clock2 SPI4 DEVID5 MPU_EXT_CS MODE0 2*MHZ 2*MHZ # gives 1.3MHz
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#SPIDEV clock4 SPI4 DEVID5 MPU_EXT_CS MODE0 4*MHZ 4*MHZ # gives 2.6MHz
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#SPIDEV clock8 SPI4 DEVID5 MPU_EXT_CS MODE0 8*MHZ 8*MHZ # gives 5.5MHz
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#SPIDEV clock16 SPI4 DEVID5 MPU_EXT_CS MODE0 16*MHZ 16*MHZ # gives 10.6MHz
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# This adds a C define which sets up the ArduPilot architecture
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# define. Any line starting with 'define' is copied literally as
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# a #define in the hwdef.h header.
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define HAL_CHIBIOS_ARCH_FMUV3 1
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# We need to tell HAL_ChibiOS/Storage.cpp how much storage is
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# available (in bytes).
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define HAL_STORAGE_SIZE 16384
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# allow to have have a dedicated safety switch pin
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define HAL_HAVE_SAFETY_SWITCH 1
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# This enables the use of a ramtron device for storage, if one is
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# found on SPI. You must have a ramtron entry in the SPI device table.
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# Enable RAMTROM parameter storage.
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define HAL_WITH_RAMTRON 1
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# Setup for the possibility of an IMU heater since the pixhawk2 cube has
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# an IMU heater.
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define HAL_HAVE_IMU_HEATER 1
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# Enable FAT filesystem support (needs a microSD defined via SDIO).
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define HAL_OS_FATFS_IO 1
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# Now setup the default battery pins driver analog pins and default
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# scaling for the power brick.
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define HAL_BATT_VOLT_PIN 2
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define HAL_BATT_CURR_PIN 3
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define HAL_BATT_VOLT_SCALE 10.1
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define HAL_BATT_CURR_SCALE 17.0
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# This defines the default maximum clock on I2C devices.
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define HAL_I2C_MAX_CLOCK 100000
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# We can't share the IO UART (USART6).
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DMA_NOSHARE USART6_TX ADC1
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DMA_PRIORITY TIM1_CH3 TIM1_CH2 TIM1_UP USART6* ADC1* SDIO* SPI*
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# List of files to put in ROMFS. For fmuv3 we need an IO firmware so
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# we can automatically update the IOMCU firmware on boot. The format
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# is "ROMFS ROMFS-filename source-filename". Paths are relative to the
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# ardupilot root.
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ROMFS io_firmware.bin Tools/IO_Firmware/iofirmware_lowpolh.bin
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