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.buildinfo

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+# Sphinx build info version 1
+# This file hashes the configuration used when building these files. When it is not found, a full rebuild will be done.
+config: 74d2714be0ea7a9cb870136f56bf4a23
+tags: 645f666f9bcd5a90fca523b33c5a78b7

_sources/board_overview.md.txt

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+# Board overview
+
+Jetson Orin Baseboard is an open hardware board design supporting NVIDIA Jetson Orin NX and Orin Nano family of SoMs.
+The board design files were created in KiCad 7x.
+The board is a versatile development kit which can be easily adopted in order to make it usable in commercial applications for autonomous vehicles, industry, agriculture, medicine or space.
+You can find out more about the Jetson Orin Baseboard in this [blog article](https://antmicro.com/blog/2023/05/jetson-orin-baseboard-1-1-with-orin-nano/), or by visiting Antmicro's portals listed below:
+
+* [Open Hardware Portal](https://openhardware.antmicro.com/boards/jetson-orin-baseboard/)
+* [System Designer](https://designer.antmicro.com/hardware/devices/jetson-orin-baseboard)
+* [Open Source Portal](https://opensource.antmicro.com/projects/jetson-orin-baseboard/)
+
+They provide 3D renders and the board [stackup definition](https://openhardware.antmicro.com/boards/jetson-orin-baseboard/?view=top-ortho&tab=stackup), as well as [an interactive preview](https://openhardware.antmicro.com/boards/jetson-orin-baseboard/?view=top-ortho&tab=preview) of the board schematic.
+A [PDF schematic](./jetson-orin-baseboard-schematic.pdf) of the board is also available.
+
+## IO map 
+
+A map of on-board connectors, status LEDs, control buttons and I/O interfaces is provided below.
+
+:::{figure-md}
+![](img/job_io_map.png)
+
+Jetson Orin Baseboard interface map
+:::
+
+## Power
+
+The board can be powered with the following sources:
+
+### 1. DC Connector
+
+Jetson Orin Baseboard can be powered with a stable DC voltage via the on-board locking DC connector ([`J12`](#J12)) with Molex Nano-Fit plug (see the [Power Supply](getting_started.md#power-supply) section for details related to Nano-Fit power harness assembly).
+You can use an external DC adapter for powering the board or a battery pack with chargeable or non-rechargeable batteries, as long as the provided voltage fits within the accepted range (9-15VDC).
+Please note that Jetson Orin Baseboard does not support battery recharging.
+
+### 2. Power over Ethernet
+
+Jetson Orin Baseboard supports PoE++ Type 3 (IEEE 802.3bt) and negotiates Power Delivery (PD) Class 5 with a maximum power budget of 40W.
+The board includes an isolated PoE DC/DC converter.
+You can power the board via the Gigabit Ethernet port ([`J6`](#J6)) using a PoE injector or a PoE-capable Ethernet switch.
+
+### 3. USB-C Power Delivery
+
+* USB Power Delivery PD, available on two USB-C ports:
+    * USB-C0 ([`J4`](#J4)) general purpose USB port 
+    * USB-C3 ([`J3`](#J3)) debug console interface port
+
+Those ports are maintained by the on-board USB-C Power Delivery controller (Texas Instruments/[TPS65988](https://www.ti.com/product/TPS65988/part-details/TPS65988DHRSHR)).
+This controller needs to be configured in order to make it implement one of the desired power source/sink negotiation scenarios.
+
+:::{note}
+The recommended power supply voltage negotiated with USB-C PD controller for power sink mode is 15VDC.
+If you plan to power up the Jetson Orin Baseboard through the USB PD source, make sure it provides at least 45W of power for stable operation.
+:::
+
+## Configuring the USB-C Power Delivery controller
+
+The on-board USB-C Power Delivery controller (Texas Instruments/[TPS65988](https://www.ti.com/product/TPS65988/part-details/TPS65988DHRSHR)) can be configured for a specific power profile by writing a binary configuration file to an SPI flash.
+You can generate your own configuration file with the [TPS6598X-CONFIG](https://www.ti.com/tool/TPS6598X-CONFIG) utility provided by Texas Instruments.
+Please refer to the Jetson Orin Baseboard [schematics](./jetson-orin-baseboard-schematic.pdf) to identify the USB port and power supply rail associated with it to generate a valid power profile setting while using the `TPS6598X-CONFIG` tool.
+Also please refer to the [TPS65987DDH and TPS65988DH Host Interface Technical Reference Manual](https://www.ti.com/lit/ug/slvubh2b/slvubh2b.pdf) for further details.
+
+In order to make the USB-C Power Delivery configuration permanent, upload the configuration file generated with `TPS6598X-CONFIG` to the configuration SPI Flash [`U7`](#U7) via an external SPI Flash programmer connected to the ``J9`` configuration port located on the bottom side of the Jetson Orin Baseboard.
+
+### 1. Collect the hardware
+
+You will need the following pieces of hardware to proceed with writing the USB-C PD configuration file to a SPI Flash:
+
+* USB dongle based on FTDI/(FT4232H-56Q)[FTDI4232](https://ftdichip.com/products/ft4232hq/).
+  We suggest using Antmicro's open hardware [Debug Toolkit](https://github.com/antmicro/ftdi-toolkit)
+* A computer running Linux - the following procedure was tested with Ubuntu 23 and Debian 11 distributions
+* 10 Pin Tag-Connect [TC2050-IDC-NL](https://www.tag-connect.com/product/tc2050-idc-nl-10-pin-no-legs-cable-with-ribbon-connector) cable
+  This cable should be connected to the signals from FTDI FT4232 with respect to the following mapping:
+
+| Tag-Connect TC2050-IDC-NL-050 [(pinout)](https://www.tag-connect.com/wp-content/uploads/bsk-pdf-manager/TC2050-IDC-NL_Datasheet_8.pdf) | FTDI 4232 [(pinout)](https://ftdichip.com/wp-content/uploads/2024/05/DS_FT4232H.pdf) |
+|----------------------------------------------------------------------------------------------------------------------------------------|--------------------------------------------------------------------------------------|
+| 1                                                                                                                                      | 3V3                                                                                  |
+| 2                                                                                                                                      | GND                                                                                  |
+| 3                                                                                                                                      | NC                                                                                   |
+| 4                                                                                                                                      | NC                                                                                   |
+| 5                                                                                                                                      | NC                                                                                   |
+| 6                                                                                                                                      | NC                                                                                   |
+| 7                                                                                                                                      | ADBUS1 (TDI/MOSI)                                                                    |
+| 8                                                                                                                                      | ADBUS2(TDO/MISO)                                                                     |
+| 9                                                                                                                                      | ADBUS0 (TCK/SCLK)                                                                    |
+| 10                                                                                                                                     | ADBUS3 (TMS/CS)                                                                      |
+
+### 2. Prepare the FT4232 dongle
+
+  *  Set the [Debug Toolkit](https://github.com/antmicro/ftdi-toolkit) Channel A to 3.3V logic with a jumper.
+  *  Enable JTAG VCC with a jumper.
+  *  Select `SPI/SWD` interface mode for channel A with a jumper.
+  *  Connect a 10 Pin Tag-Connect cable with the Deubg Toolkit assuming the connection mapping specified in the table above.
+
+:::{figure-md}
+![](img/debug_toolkit_jumper_configuration.png)
+
+Debug Toolkit Jumper configuration for writing the USB-C PD configuration file.
+:::
+
+### 3. Prepare the PC for flashing
+
+  * Install the [flashrom](https://github.com/flashrom/flashrom) utility on your host PC.
+    On Debian-based distributions you can use a package manager for that.
+```
+sudo apt install flashrom
+```
+  * Adjust the size of the TPS6598 binary configuration file (we named it `config.bin`) to match the SPI flash size:
+```
+truncate -s 1048576 config.bin
+```
+
+### 4. Write the configuration
+
+  * Connect [Tag-Connect Plug-of-Nails](https://www.tag-connect.com/product/tc2050-idc-nl-050) to the ``J9`` connector on board. 
+   Hold plug in place firmly during flashing process.
+   The SPI flash will be powered via the programming cable during the flashing process - you do not have to provide your Jetson Orin Baseboard with power.
+
+:::{figure-md}
+![](img/job_tag_connect_plugged.png)
+
+Jetson Orin Baseboard with Tag-Connect plugged for PD controller flashing.
+:::
+
+ * Check if SPI Flash can be detected via Debug Toolkit:
+```
+flashrom -p ft2232_spi:type=4232H,port=A,divisor=64 | grep "W25Q80.V"
+```
+Expected outcome:
+```
+Found Winbond flash chip "W25Q80.V" (1024 kB, SPI) on ft2232_spi.
+```
+
+ * Write the configuration file to an SPI Flash:
+```
+flashrom -p ft2232_spi:type=4232H,port=A,divisor=64 -w config.bin
+```
+Expected outcome:
+```
+(...)
+Reading old flash chip contents... done.
+Erasing and writing flash chip... Erase/write done.
+Verifying flash... VERIFIED.
+```
+
+ *  You can repeat the previous set to ensure that binary file has been written successfully:
+
+Expected outcome:
+```
+(...)
+Warning: Chip content is identical to the requested image.
+Erase/write done.
+```
+
+## Mechanics
+
+The Jetson Orin Baseboard PCB is 120x60 millimeters (WxL) which translates into 4.72x2.36 inch.
+The overall height of the set depends on the cooling module attached.
+The base setup with a default cooling module is 37 mm or 1.45 inch tall. 
+The KiCad PCB design files include mechanical layers with dimensions specified for the fastening holes and notable components. 
+The board with the Jetson Module, M.2 storage and cooling module weighs 164g (5.78oz). 
+The mechanical STEP model of the Jetson Orin Baseboard is provided in the [1.1.6 design release](https://github.com/antmicro/jetson-orin-baseboard/releases/tag/rev.1.1.6-ch) available on GitHub.
+