| /Zephyr-latest/boards/others/candlelightfd/doc/ |
| D | index.rst | 12 The candleLight FD board is equipped with a STM32G0B1CBT6 microcontroller and features an USB-C con…
13 a DB-9M connector for the CAN bus, and two user LEDs. Schematics and component placement drawings
24 The STM32G0B1CBT6 PLL is driven by an external crystal oscillator (HSE) running at 8 MHz and
25 configured to provide a system clock of 60 MHz. This allows generating a FDCAN1 and FDCAN2 core
28 Programming and Debugging
31 Build and flash applications as usual (see :ref:`build_an_application` and
|
| /Zephyr-latest/boards/raspberrypi/rpi_pico2/doc/ |
| D | index.rst | 17 - 520KB of SRAM, and 4MB of on-board flash memory
18 - USB 1.1 with device and host support
19 - Low-power sleep and dormant modes
20 - Drag-and-drop programming using mass storage over USB
28 - Can emulate interfaces such as SD Card and VGA
35 Connections and IOs
40 Programming and Debugging
43 As with the Pico 1, the SWD interface can be used to program and debug the
|
| /Zephyr-latest/samples/sensor/adt7420/ |
| D | README.rst | 5 Get temperature data from an ADT7420 sensor using polling and window mode.
13 When configured in trigger mode the update interval is 5 s, and the
16 interrupt causes the application to display an event and update the
17 upper and lower window boundaries.
28 Connect Supply: **VDD**, **GND** and Interface: **SDA**, **SCL**
29 and optionally connect the **INT** to a interrupt capable GPIO.
31 Depending on the baseboard used, the **SDA** and **SCL** lines require Pull-Up
34 Building and Running
|
| /Zephyr-latest/samples/sensor/lsm6dsl/ |
| D | README.rst | 5 Get accelerometer and gyroscope data from an LSM6DSL sensor (polling & trigger
11 This sample sets the LSM6DSL accelerometer and gyroscope to 104Hz
12 and enable a trigger on data ready. It displays on the console the
13 values for accelerometer and gyroscope, plus optionally the values of
21 It has been tested on both :ref:`96b_argonkey` and disco_l475_iot1 board.
26 - LSM6DSL https://www.st.com/en/mems-and-sensors/lsm6dsl.html
28 Building and Running
32 sensor, which is present on both the :ref:`96b_argonkey` and disco_l475_iot1 board.
|
| /Zephyr-latest/doc/project/ |
| D | project_roles.rst | 9 TSC projects generally will involve *Maintainers*, *Collaborators*, and
22 by approval of the existing Collaborators and Maintainers of the
34 Contributors are granted the following rights and responsibilities:
37 * Right to report defects (bugs) and suggestions for enhancement.
39 * Right to initiate and participate in discussions in any communication
46 * Responsibility for issues and bugs introduced by one’s own contributions.
49 discussions and in the review of contributions.
61 Contributors who show dedication and skill are granted the Triage permission
69 to a pull request and can be added as a reviewer by other GitHub users.
71 respect to accepting and merging a pull request. However, Contributors comments
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| /Zephyr-latest/boards/bcdevices/plt_demo_v2/doc/ |
| D | index.rst | 8 and several useful external peripherals.
31 - 512 KB flash memory and 64 KB of SRAM
33 - Sensiron SHT30 Humidity and Temperature sensor
35 - Battery connector and charger for 3.7 V lithium polymer batteries
46 Connections and IOs
72 Programming and Debugging
76 can be built and flashed in the usual way (see :ref:`build_an_application`
77 and :ref:`application_run` for more details).
85 Build the Zephyr kernel and the :zephyr:code-sample:`led-strip` sample application.
112 .. _Schematic, layout, and gerbers:
|
| /Zephyr-latest/samples/drivers/ipm/ipm_esp32/ |
| D | README.rst | 5 Implement inter-processor mailbox (IPM) between ESP32 APP and PRO CPUs.
9 This simple example can be used with multicore ESP32 Soc, and demonstrates
12 ESP32 has two CPU named APP and PRO, in this simple example PRO send a
13 message to the APP using the IPM driver, and waits for the APP response
14 message and prints its contents on console.
16 ESP32 intercore messaging has up two four channels, the 0 and 1 are
17 reserved for BT and WIFI messages, and channels 2 and 3 is free to
22 Building and Running the Zephyr Code
|
| /Zephyr-latest/samples/sensor/mcux_lpcmp/ |
| D | README.rst | 19 manual and board schematic to confirm which specific port is used and can
20 connect an external voltage to that port and change the input voltage to
25 Building and Running
28 Building and Running for NXP FRDM-MCXN947
30 Build the application for the :zephyr:board:`frdm_mcxn947` board, and adjust the
39 Building and Running for NXP FRDM-MCXN236
41 Build the application for the :zephyr:board:`frdm_mcxn236` board, and adjust the
50 Building and Running for NXP FRDM-MCXA156
52 Build the application for the :zephyr:board:`frdm_mcxa156` board, and adjust the
|
| /Zephyr-latest/doc/contribute/ |
| D | index.rst | 8 lists useful resources and guidelines to help you in your contribution journey.
27 Learn about the overall process and guidelines for contributing to the Zephyr project.
30 how to ensure your contribution can be considered for inclusion in the project and potentially
42 Code contributions are expected to follow a set of coding guidelines to ensure consistency and
46 Code contributions are expected to follow a set of style guidelines to ensure consistency and
50 Learn when and how to submit RFCs (Request for Comments) for new features and changes to the
54 Guidelines for modifying contributions made by other developers and how to deal with stale pull
72 (reST) markup language and Sphinx documentation generator.
92 available in other open source projects, and it is recommended and encouraged to reuse such code.
93 This page describes in more details when and how to import external source code into Zephyr.
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| /Zephyr-latest/boards/adafruit/feather_m0_basic_proto/doc/ |
| D | index.rst | 7 board with an onboard battery connector and charger for 3.7 V lithium
8 polymer batteries, charging status indicator and user LEDs, native USB
9 connector, 20 I/O pins, and a small prototyping area.
16 - 256 KiB flash memory and 32 KiB of RAM
17 - Battery connector and charger for 3.7 V lithium polymer batteries
28 Connections and IOs
32 information about the board including `pinouts`_ and the `schematic`_.
44 Basic Proto, SERCOM0 is the Zephyr console and is available on pins 0
45 (RX) and 1 (TX).
51 Basic Proto, SERCOM3 is available on pin 20 (SDA) and pin 21 (SCL).
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|
| /Zephyr-latest/boards/shields/nrf7002ek/boards/ |
| D | nrf9160dk_nrf9160_ns.overlay | 7 /* Disabled because of conflicts on P0.00 and P0.01 - Arduino pins D0 and D1
8 * (iovdd-ctrl-gpios and bucken-gpios in nrf7002ek, respectively).
16 * disable LEDs and Button0/1.
|
| /Zephyr-latest/tests/drivers/uart/uart_elementary/ |
| D | README.txt | 6 For single uart configuration - UART0 TX connected to RX and CTS to RTS
7 For dual uart configuratiom - UART0 and UART1 TXs and RXs cross-connected
13 - Dual UART transmission with matched and mismatched configurations
|
| /Zephyr-latest/boards/renesas/ek_ra4e2/doc/ |
| D | index.rst | 7 with 128 KB of code flash memory, 4 KB of data flash memory, and 40 KB of SRAM. RA4E2 MCUs
8 offer high-performance and optimized peripheral functions along with the smallest package
9 options, including space-saving 36-pin BGA and 32-pin QFN packages. The RA4E2
10 Group offers a wide set of peripherals, including USB Full Speed, CANFD, I3C, and ADC.
21 - Native pin access through 2 x 14-pin and 1 x 40-pin male headers
23 - Multiple clock sources - RA MCU oscillator and sub-clock oscillator crystals, providing precision
24 …20.000 MHz and 32,768 Hz reference clock. Additional low-precision clocks are available internal t…
27 **System Control and Ecosystem Access**
33 - External power supply (using surface mount clamp test points and J31 through holes)
41 - User LEDs and buttons
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|
| /Zephyr-latest/boards/renesas/ek_ra4m2/doc/ |
| D | index.rst | 8 functionality. The RA4M2 is built on a highly efficient 40nm process, built on FreeRTOS—and
9 is expandable to use other RTOSes and middleware. The RA4M2 is suitable for IoT applications
10 requiring vast communication options, future proof security, large embedded RAM, and low
24 - Multiple clock sources - RA MCU oscillator and sub-clock oscillator crystals, providing
25 precision 24.000 MHz and 32,768 Hz reference clock. Additional low-precision clocks are
28 **System Control and Ecosystem Access**
30 - USB Full Speed Host and Device (micro AB connector)
34 - External power supply (using surface mount clamp test points and power input vias)
39 - Debug in (ETM, SWD, and JTAG)
42 - User LEDs and buttons
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|
| /Zephyr-latest/boards/renesas/ek_ra6m5/doc/ |
| D | index.rst | 8 proof security, large embedded RAM, and low active power consumption down
18 - Multiple clock sources - RA6M5 MCU oscillator and sub-clock oscillator crystals,
19 providing precision 24.000 MHz and 32,768 Hz reference clock.
22 **System Control and Ecosystem Access**
24 - USB Full Speed Host and Device (micro-AB connector)
28 - External power supply (using surface mount clamp test points and power input vias)
33 - Debug in (ETM, SWD and JTAG)
36 - User LEDs and buttons
48 - Two Digilent Pmod (SPI and UART) connectors
57 - USB High Speed Host and Device (micro-AB connector)
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|
| /Zephyr-latest/boards/renesas/ek_ra6m4/doc/ |
| D | index.rst | 8 performance, unlimited secure key storage, key management, and lower
11 requiring Ethernet, future proof security, large embedded RAM, and low
22 - Multiple clock sources - RA6M4 MCU oscillator and sub-clock oscillator crystals,
23 providing precision 24.000 MHz and 32,768 Hz reference clock.
26 **System Control and Ecosystem Access**
28 - USB Full Speed Host and Device (micro-AB connector)
32 - External power supply (using surface mount clamp test points and power input vias)
37 - Debug in (ETM, SWD and JTAG)
40 - User LEDs and buttons
52 - Two Digilent Pmod (SPI and UART) connectors
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|
| /Zephyr-latest/boards/adafruit/itsybitsy_m4_express/doc/ |
| D | index.rst | 7 board with an onboard RGB LED, USB port, 2 MiB of SPI flash, and range of I/O
14 - 512 KiB of flash memory and 192 KiB of RAM
28 To use the RTC, set :code:`CONFIG_CORTEX_M_SYSTICK=n` and set
32 Connections and IOs
36 the board including `pinouts`_ and the `schematic`_.
48 the Zephyr console and is available on pins 0 (RX) and 1 (TX).
54 into SPI mode and used to connect to devices over the SCK (SCLK), MO (MOSI), and
61 has a resolution of 24 bits and all other generators are 16 bit. :code:`TCC_1`
62 pin 2 is mapped to PA18 (D7) and pin 3 is mapped to PA19 (D9).
72 Programming and Debugging
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|
| /Zephyr-latest/boards/seagate/legend/doc/ |
| D | index.rst | 5 The Legend board family contains three revisions: 25hdd, 25ssd, and 35.
8 Gaming Hard Drive, Gaming Drive for Xbox and Gaming Drive for PlayStation
9 devices. A 2.5" drive and two chips are embedded: an ASMedia ASM1153 USB-to-SATA
10 bridge controller and a STM32F070 MCU. The former is handling the USB to HDD I/Os
15 Drive for Xbox. A Realtek RTS5411S USB hub is embedded and connected to a Phison
19 Hub and Gaming Drive Hub for Xbox devices. A Genesys Logic GL3523-S USB hub is
20 connected to an ASMedia ASM1153 USB-to-SATA bridge controller and a STM32F070
54 Connections and IOs
80 | PA12 | USB | USB DM (25ssd and 35 only) |
82 | PA13 | USB | USB DP (25ssd and 35 only) |
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|
| /Zephyr-latest/boards/native/nrf_bsim/doc/ |
| D | nrf54l15bsim.rst | 18 This uses `BabbleSim`_ to simulate the radio activity, and the
19 :ref:`POSIX architecture<Posix arch>` and the `native simulator`_ to
21 providing native code execution performance and easy debugging using
30 Unlike real nRF54L15 devices, the nrf54l15bsim target has unlimited RAM, and code does not
31 occupy its RRAM. Therefore, as the nRF54L15, nRF54L10 and nRF54L05 SOCs only differ in the amount
32 of available RAM and RRAM either can be simulated using the nrf54l15bsim.
58 and will use the same drivers as the nrf54l15dk targets for these.
72 Building for, and using this board
79 TrustZone, TF-M and other security considerations
84 * There is no differentiation between secure and non secure execution states or bus accesses.
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|
| /Zephyr-latest/samples/modules/tflite-micro/tflm_ethosu/ |
| D | README.rst | 10 framework and the Arm Ethos-U NPU.
17 Vela takes a tflite file as input and produces another tflite file as output,
22 Building and running
25 Add the tflite-micro module to your West manifest and pull it:
32 This application can be built and run on any Arm Ethos-U capable platform, for
35 `MPS3 FPGA prototyping board <https://developer.arm.com/tools-and-software/development-boards/fpga-…
37 `Fixed Virtual Platform <https://developer.arm.com/tools-and-software/open-source-software/arm-plat…
40 Assuming that the Corstone-300 FVP has been downloaded, installed and added to
41 the ``PATH`` variable, then building and testing can be done with following
|
| /Zephyr-latest/boards/nxp/hexiwear/doc/ |
| D | index.rst | 12 user interface consisting of a 1.1" 96px x 96px full color OLED display and six
16 and 6 on-board sensors.
18 OLED screen and onboard sensors such as optical heart rate, accelerometer,
19 magnetometer and gyroscope.
21 temperature, pressure, humidity and ambient light.
35 - 6-axis combo Accelerometer and Magnetometer NXP FXOS8700
40 - Ambient Light sensor, Humidity and Temperature sensor
47 For more information about the K64F SoC and Hexiwear board:
101 Connections and IOs
147 and ``en_3v3b`` regulators in Devicetree.
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|
| /Zephyr-latest/boards/renesas/ek_ra8m1/doc/ |
| D | index.rst | 8 and peripherals set optimized on board allows user to seamlessly evaluate the features
9 of the RA8M1 MCU and develop embedded system application in various field.
16 - Native pin acces througgh 2 x 50-pin, and 2 x 40-pin male headers
18 - Multiple clock sources - RA8M1 MCU oscillator and sub-clock oscillator crystals,
19 providing precision 20.000MHz and 32,768 Hz refeence clocks.
22 **System Control and Ecosystem Access**
24 - USB Full Speed Host and Device (micro-AB connector)
28 - External power supply (using surface mount clamp test points and power input vias)
33 - Debug in (ETM, SWD and JTAG)
36 - User LEDs and buttons
[all …]
|
| /Zephyr-latest/boards/nxp/frdm_k22f/doc/ |
| D | index.rst | 11 accelerometer and magnetometer to create full eCompass capabilities, a
12 tri-colored LED and 2 user push-buttons for direct interaction, a optional
13 microSD card slot, and headers for use with Bluetooth* and 2.4 GHz radio
15 - OpenSDAv2, the NXP open source hardware embedded serial and debug adapter
17 flash programming, and run-control debugging
23 crystal-less USB, and 64 pin Low profile Quad Flat Package (LQFP))
26 - FXOS8700CQ accelerometer and magnetometer
28 - Flexible power supply option - OpenSDAv2 USB, Kinetis K22 USB, and external source
35 run-control debugging and compatibility with IDE tools
41 For more information about the K22F SoC and FRDM-K22F board:
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|
| /Zephyr-latest/boards/st/stm32l562e_dk/doc/ |
| D | index.rst | 6 The STM32L562E-DK Discovery kit is designed as a complete demonstration and
12 - STM32L562QEI6QU microcontroller featuring 512 Kbytes of Flash memory and 256 Kbytes of SRAM in BG…
13 - 1.54" 240 x 240 pixel-262K color TFT LCD module with parallel interface and touch-control panel
20 - iNEMO 3D accelerometer and 3D gyroscope
23 …- STMod+ expansion connector with fan-out expansion board for Wi‑Fi |reg|, Grove and mikroBUS |tra…
41 - User and reset push-buttons
52 - Ultra-low-power with FlexPowerControl (down to 108 nA Standby mode and 62 uA/MHz run mode)
53 - Core: ARM |reg| 32-bit Cortex |reg| -M33 CPU with TrustZone |reg| and FPU.
61 - Arm |reg| TrustZone |reg| and securable I/Os memories and peripherals
63 - Root of trust thanks to unique boot entry and hide protection area (HDP)
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|
| /Zephyr-latest/samples/drivers/i2s/i2s_codec/ |
| D | README.rst | 11 an audio stream. It configures and starts from memory buffer or from DMIC to
12 record i2s data and send to codec with DMA.
19 Building and Running
24 To build and flash the application:
32 To run you can connect earphones to the lineout connect and hear the sound
|
