TS-TPC-7990: Difference between revisions

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{{Infobox
{{Infobox
|title        = TS-TPC-7990
|title        = TS-TPC-7990
|image        = https://www.embeddedarm.com/images/boards/medium/ts-tpc-7990.gif
|image        = https://www.embeddedTS.com/images/boards/medium/ts-tpc-7990.gif
|titlestyle  =   
|titlestyle  =   
|headerstyle  = background:#ccf;
|headerstyle  = background:#ccf;
|labelstyle  = width:33%
|labelstyle  = width:33%
|datastyle    =  
|datastyle    =  
|data2        = [http://www.embeddedarm.com/products/board-detail.php?product=TS-TPC-7990 Product Page]
|data2        = [http://www.embeddedTS.com/products/board-detail.php?product=TS-TPC-7990 Product Page]
|data3        = [https://www.embeddedarm.com/product-images/TS-TPC-7990 Product Images]
|data3        = [https://www.embeddedTS.com/product-images/TS-TPC-7990 Product Images]
|data4        = [https://www.embeddedarm.com/products/TS-TPC-7990?tab=specs Specifications]
|data4        = [https://www.embeddedTS.com/products/TS-TPC-7990?tab=specs Specifications]
|header4      = Documentation
|header4      = Documentation
|data5        = [https://www.embeddedarm.com/documentation/ts-tpc-7990-schematic.pdf Schematic]
|data5        = [https://www.embeddedTS.com/documentation/ts-tpc-7990-schematic.pdf Schematic]
|data6        = [https://www.embeddedarm.com/documentation/ts-tpc-7990-mechanical-drawing.pdf Mechanical Drawing]
|data6        = [https://www.embeddedTS.com/documentation/ts-tpc-7990-mechanical-drawing.pdf Mechanical Drawing]
|data7        = [https://www.embeddedarm.com/documentation/ts-tpc-7990-mounting-clearance-drawing.pdf Bezel Mechanical Drawing]
|data7        = [https://www.embeddedTS.com/documentation/ts-tpc-7990-mounting-clearance-drawing.pdf Bezel Mechanical Drawing]
|data8        = [https://www.embeddedarm.com/documentation/ts-tpc-7990-mounting-cutout-pattern.pdf Panel Cutout Drawing]
|data8        = [https://www.embeddedTS.com/documentation/ts-tpc-7990-mounting-cutout-pattern.pdf Panel Cutout Drawing]
|data9        = [ftp://ftp.embeddedarm.com/ts-arm-sbc/ts-7990-linux/ FTP Path]
|data9        = [https://files.embeddedTS.com/ts-arm-sbc/ts-7990-linux/ FTP Path]
|header10    = Processor
|header10    = Processor
|data11      = NXP i.MX6 Quad core, or Solo
|data11      = NXP i.MX6 Quad core, or Solo
|data12      = [http://www.nxp.com/products/microcontrollers-and-processors/arm-processors/i.mx-applications-processors/i.mx-6-processors/i.mx-6quad-processors-high-performance-3d-graphics-hd-video-arm-cortex-a9-core:i.MX6Q i.MX6 Quad Product Page]
|data12      = [http://www.nxp.com/products/microcontrollers-and-processors/arm-processors/i.mx-applications-processors/i.mx-6-processors/i.mx-6quad-processors-high-performance-3d-graphics-hd-video-arm-cortex-a9-core:i.MX6Q i.MX6 Quad Product Page]
|data13      = [http://www.nxp.com/products/microcontrollers-and-processors/arm-processors/i.mx-applications-processors/i.mx-6-processors/i.mx-6solo-processors-single-core-multimedia-3d-graphics-arm-cortex-a9-core:i.MX6S i.MX6 Solo Product Page]
|data13      = [http://www.nxp.com/products/microcontrollers-and-processors/arm-processors/i.mx-applications-processors/i.mx-6-processors/i.mx-6solo-processors-single-core-multimedia-3d-graphics-arm-cortex-a9-core:i.MX6S i.MX6 Solo Product Page]
|data14      = [http://cache.freescale.com/files/32bit/doc/ref_manual/IMX6DQRM.pdf?fpsp=1&WT_TYPE=Reference%20Manuals&WT_VENDOR=FREESCALE&WT_FILE_FORMAT=pdf&WT_ASSET=Documentation IMX6Q Reference Manual]
|data14      = [https://www.nxp.com/webapp/Download?colCode=IMX6DQRM IMX6Q Reference Manual]
|data15      = [http://cache.freescale.com/files/32bit/doc/ref_manual/IMX6SDLRM.pdf?fpsp=1&WT_TYPE=Reference%20Manuals&WT_VENDOR=FREESCALE&WT_FILE_FORMAT=pdf&WT_ASSET=Documentation IMX6S Reference Manual]
|data15      = [https://www.nxp.com/webapp/Download?colCode=IMX6SDLRM IMX6S Reference Manual]
}}
}}


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Most Linux distributions include the cp210x driver and will register this as /dev/ttyUSB0.  For other operating systems:
Most Linux distributions include the cp210x driver and will register this as /dev/ttyUSB0.  For other operating systems:
* [http://www.silabs.com/products/mcu/Pages/USBtoUARTBridgeVCPDrivers.aspx Silabs USB-to-UART drivers]
* [https://www.silabs.com/developers/usb-to-uart-bridge-vcp-drivers Silabs USB-to-UART drivers]
The serial console is provided through this port at 115200 baud, 8n1, with no flow control.  Picocom is the recommended client which can connect with:
The serial console is provided through this port at 115200 baud, 8n1, with no flow control.  Picocom is the recommended client which can connect with:
<source lang=bash>
<source lang=bash>
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</source>
</source>


This will output some serial settings and then "Terminal ready".  Any messages after this will be from the unit itself.  Now that the terminal is ready, power can be applied.  The power input for the TS-TPC-7990 uses a removable terminal block which accepts 5 VDC, or 8-28 VDC input.  Only one should be connected at a time.
This will output some serial settings and then "Terminal ready".  Any messages after this will be from the unit itself.  Now that the terminal is ready, power can be applied.  The power input for the TS-TPC-7990 uses a removable terminal block which accepts 5 VDC, or 8-36 VDC input.  Only one should be connected at a time.


A power supply should be prepared to provide 20 W, but the device power consumption will typically be around 8 W on an idle quad core.  See the [[#Specifications|Specifications section]] for further details on power requirements, differences between build options, and options to reduce power.
A power supply should be prepared to provide 20 W, but the device power consumption will typically be around 8 W on an idle quad core.  See the [[#Specifications|Specifications section]] for further details on power requirements, differences between build options, and options to reduce power.
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= Debian =
= Debian =
{{:TS-TPC-7990 Debian Sections}}
{{:TS-4900 Debian Sections}}


= Ubuntu =
= Ubuntu =
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= Backup / Restore =
= Backup / Restore =
While all of our products ship with images pre-loaded in to any supplied media, there are many situations where new images may need to be written. For example, to restore a device to its factory settings or apply a customized image/filesytem for application deployment. Additionally, specific units may be used for development and that unit's disk images need to be replicated to other units to be deployed in the field.
We offer a number of different ways to accomplish both capturing images to be written to other units, and the actual writing process itself. See the sections below for details on our USB Image Replicator tool to capture and/or write images, as well as details on manual processes to capture and write images on each of this device's media.
== Image Replicator ==
{{:Image_replicator_intro}}
=== Creating a USB Image Replicator Disk ===
Image Replicator USB disk images can be found below:
Disk image: [https://files.embeddedts.com/ts-socket-macrocontrollers/ts-4900-linux/usb-blaster/tsimx6-usb-image-replicator.dd.xz tsimx6-usb-image-replicator.dd.xz]
Tarball: [https://files.embeddedts.com/ts-socket-macrocontrollers/ts-4900-linux/usb-blaster/tsimx6-usb-image-replicator-rootfs.tar.xz tsimx6-usb-image-replicator-rootfs.tar.xz]
On startup if SW1 is depressed before power is applied and held for a few moments after, then TS-7970's U-Boot will attempt to located a file called <source inline>/tsinit.ub</source> on a USB drive. If found, it will copy this file to memory at <source inline>${loadaddr}</source> and then execute <source inline>source ${loadaddr}</source> to run this U-Boot script. This is the mechanism used to boot either of the two disk images on the TS-7970.
{{:Image_replicator_make}}
=== Running the Image Replicator Tool ===
On startup, if the "U Boot" [[#Jumpers|jumper]] is set when power is applied, then U-Boot will attempt to load a file from a USB drive called <source inline>/tsinit.ub</source>. If found, it will copy this to <source inline>${loadaddr}</source> and execute <source inline>source ${loadaddr}</source> to run it as a U-Boot script. This is the mechanism used to boot either of the two disk images on the TS-TPC-7990.
{{:Image_replicator_generic}}
{{:Image_replicator_media_sd}}
{{:Image_replicator_media_emmc}}
{{:Image_replicator_media_sata}}
{{:Image_replicator_media_uboot_imx6}}
{{Note|SATA is only present on models with Dual/Quad CPUs}}
=== Building the Image Replicator from Source ===
{{:Image_replicator_building}}
== MicroSD Card ==
== MicroSD Card ==
{{Note|Our [[#Image_Replicator|Image Replicator tool]] can be used to automate this process.}}
{{:TS-TPC-7990 MicroSD Backup/restore}}
{{:TS-TPC-7990 MicroSD Backup/restore}}


== eMMC ==
== eMMC ==
{{Note|Our [[#Image_Replicator|Image Replicator tool]] can be used to automate this process.}}
{{:TS-TPC-7990 eMMC Backup/restore}}
{{:TS-TPC-7990 eMMC Backup/restore}}


= Compile the Kernel =
= Compile the Kernel =
{{:TS-TPC-7990 Kernel Compile Guide}}
{{:TS-TPC-7990 Kernel Compile Guide}}
= Production Mechanism =
On startup, if the "U Boot" [[#Jumpers|jumper]] is set when power is applied, then U-Boot will attempt to load a file from a USB drive called /tsinit.ub.  If found, it will copy this to ${loadaddr} and "source ${loadaddr}" to run it as a U-Boot script.  This is intended for the initial production of boards and allows mass programming boards with a USB thumbdrive.
{{:Tsimx6_usb_production}}


= Features =
= Features =
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== Graphics ==
== Graphics ==
=== Rotate the Display ===
=== Rotate the Display ===
Under Yocto xrandr can be used to rotate the screen at any time:
{{:TS-4900 display rotation}}
<source lang=bash>
export DISPLAY=:0
xrandr --rotate left
xrandr --rotate right
xrandr --rotate normal
xrandr --rotate inverted
</source>
 
Under Debian or Ubuntu the rotation is configured via Xorg.conf.  Edit the file /etc/X11/xorg.conf and append this to the end:
<source lang=bash>
Section "Device"
    Identifier      "fbdev display"
    Driver          "fbdev"
    Option "Rotate" "CCW"
EndSection
</source>
 
If the display is rotated, the touchscreen needs to be as well.  The following example matches the CCW rotation, but swapaxes or the invertx/y options will need to be adjusted for other rotations.
 
<source lang=bash>
Section "InputClass"
      Identifier "axis inversion"
      MatchIsTouchscreen "true"
      # swap x/y axes on the device. i.e. rotate by 90 degrees
      Option "SwapAxes" "on"
      # Invert the respective axis.
      Option "InvertX" "on"
      Option "InvertY" "off"
EndSection
</source>


== GPIO ==
== GPIO ==
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|-
|-
| 4
| 4
| [[#CAN|CAN_2_H (can1 interface)]]
| [[#CAN|CAN_2_H (can0 interface)]]<ref name=permterm>This can bus includes 120ohm termination</ref>
|-
|-
| 5
| 5
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|-
|-
| 9
| 9
| [[#CAN|CAN_2_L (can1 interface)]]
| [[#CAN|CAN_2_L (can0 interface)]] <ref name=permterm />
|-
|-
| 10
| 10
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|-
|-
| 4
| 4
| [[#CAN|CAN_3_H (can0 interface)]]
| [[#CAN|CAN_3_H (can1 interface)]] <ref name=optterm>Has optional termination 120ohm termination if DIO header pins 21/22 are shorted.</ref>
|-
|-
| 5
| 5
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|-
|-
| 9
| 9
| [[#CAN|CAN_3_L (can0 interface)]]
| [[#CAN|CAN_3_L (can1 interface)]] <ref name=optterm />
|-
|-
| 10
| 10
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== Mini PCIe ==
== Mini PCIe ==
The Mini PCIe socket provides USB, mSATA, and a PCIe lane.  The TS-TPC-7990 can support a SIM card socket connected to the Mini PCIe interface, but it is not populated by default. [https://www.embeddedarm.com/support/ Contact us for more information on supporting this header].
The Mini PCIe socket provides USB, mSATA, and a PCIe lane.  The TS-TPC-7990 can support a SIM card socket connected to the Mini PCIe interface, but it is not populated by default. [https://www.embeddedTS.com/support/ Contact us for more information on supporting this header].


== Power Connector ==
== Power Connector ==
The TS-TPC-7990 includes a removable terminal block which accepts 8-28 V, or 5 V DC for the power input.  Only one power input may be connected at a time.  A typical power supply for this platform should provide 25 W; see the [[#Power Consumption|power consumption]] section for more information on power requirements based on specific CPU and peripheral configurations.
The TS-TPC-7990 includes a removable terminal block (Eurocomp ETB205/3A) which accepts 8-36 V, or 5 V DC for the power input.  Only one power input may be connected at a time.  A typical power supply for this platform should provide 25 W; see the [[#Power Consumption|power consumption]] section for more information on power requirements based on specific CPU and peripheral configurations.


{| class=wikitable
{| class=wikitable
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| Description
| Description
|-
|-
| 1 <ref> Near 8-28 V label</ref>
| 1 <ref> Near 8-36 V label</ref>
| 8-28 VDC
| 8-36 VDC
|-
|-
| 2
| 2
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[[File:TS-TPC-7990 removable power connector.png|500px]]
[[File:TS-TPC-7990 removable power connector.png|500px]]


{{Warning|Connecting both 8-28 V and 5 V inputs can damage the device and power sources.}}
{{Warning|Connecting both 8-36 V and 5 V inputs can damage the device and power sources.}}


== DIO Header ==
== DIO Header ==
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|-
|-
| 7
| 7
| GPIO 244 [[#FPGA GPIO Table|(FPGA DIO_1_SEL0)]]
| GPIO 244 [[#FPGA GPIO Table|(FPGA DIO_1_SEL0)]] <ref>If this pin is low on u-boot's startup, u-boot will assume the TS-SILO daughtercard is present and this may prevent boot.</ref>
|-
|-
| 8
| 8
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|-
|-
| 23
| 23
| [[#Jumpers|JP_OPTION#]] <ref>If this pin reads low on startup it will stop in U-Boot.  After the initial read this pin can be reused as a GPIO. </ref>, GPIO 231 [[#FPGA GPIO Table|(FPGA DIO_9)]]
| [[#Jumpers|JP_OPTION#]] <ref>If this pin reads low on startup it will stop in U-Boot.  After the initial read this pin can be reused as a GPIO. </ref>, GPIO 231 [[#FPGA GPIO Table|(FPGA DIO_9)]], DC_SPI_CS#
|-
|-
| 24
| 24
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== XBee Header ==
== XBee Header ==
For using this header to connect a standard XBee peripheral, contact us [https://support.embeddedarm.com/support/tickets/new here]; by default the TS-TPC-7990 only supports Nimblelink radios on this header.
For using this header to connect a standard XBee peripheral, contact us [https://support.embeddedTS.com/support/tickets/new here]; by default the TS-TPC-7990 only supports Nimblelink radios on this header.


Some basic commands to manipulate pins on this interface:
Some basic commands to manipulate pins on this interface:
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== TS-DC799-SILO ==
== TS-DC799-SILO ==
[[File:TS-7990_DC799-SILO.jpg|500px|right|TS-DC799-SILO]]
[[File:TS-7990_DC799-SILO.jpg|500px|right|TS-DC799-SILO]]
The TS-TPC-7990 supports [https://www.embeddedarm.com/about/resource/unveiling-the-ts-silo-super-capacitor-technology TS-SILO] via the TS-DC799-SILO daughter card. TS-SILO technology is a UPS-like system that uses supercapacitors to deliver up to 60 seconds of backup power.  Providing protection against short power glitches as well as backup power to perform a safe shutdown in the event of a long power loss. A safe shutdown is critical in applications using writable storage media in order to prevent filesystem damage.
The TS-TPC-7990 supports [https://www.embeddedTS.com/about/resource/unveiling-the-ts-silo-super-capacitor-technology TS-SILO] via the TS-DC799-SILO daughter card. TS-SILO technology is a UPS-like system that uses supercapacitors to deliver up to 100 seconds of backup power.  Providing protection against short power glitches as well as backup power to perform a safe shutdown in the event of a long power loss. A safe shutdown is critical in applications using writable storage media in order to prevent filesystem damage.


A boot cycle with the TS-DC799-SILO daughter card will typically go through these steps:
A boot cycle with the TS-DC799-SILO daughter card will typically go through these steps:
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|}
|}


Once booted to Linux, the [https://github.com/embeddedarm/ts4900-utils/blob/master/script/tssilomon tssilomon] service is started.  This script monitors for input power failure. If a power failure is detected, the daemon will sample the charge level of the supercapacitors. If the charge level falls below 90% then a reboot is initiated. The supercapacitors can provide roughly 35 to 85 seconds of backup power to the TS-TPC-7990 when at a 90% charge level.
Once booted to Linux, the [https://github.com/embeddedTS/ts4900-utils/blob/master/script/tssilomon tssilomon] service is started.  This script monitors for input power failure. If a power failure is detected, the daemon will sample the charge level of the supercapacitors. If the charge level falls below 90% then a reboot is initiated. The supercapacitors can provide roughly 35 to 85 seconds of backup power to the TS-TPC-7990 when at a 90% charge level.


U-Boot the next boot until the supercapacitors have finished charging again, or the power runs out and the power rails collapse.  The on-board supervisory microcontroller will power down the main power rails and ARM CPU so all power and signals available on headers will collapse cleanly rather than fluctuating.
U-Boot the next boot until the supercapacitors have finished charging again, or the power runs out and the power rails collapse.  The on-board supervisory microcontroller will power down the main power rails and ARM CPU so all power and signals available on headers will collapse cleanly rather than fluctuating.


== TS-DC799-POE ==
== TS-DC799-POE ==
This daughterboard provides PoE+ support for the TS-TPC-7990.  This allows the board to be fully powered by J1, the Ethernet connector near the RTC battery and mini pcie connector.   
This daughter card provides PoE+ support for the TS-TPC-7990.  This allows the whole platform to be fully powered via PoE+ on J1, the Ethernet connector near the RTC battery and Mini PCIe connector.   
{|
{|
| https://www.embeddedarm.com/images/boards/medium/ts-dc799-poe-a1.gif
| https://cdn.embeddedTS.com/media/part-images/929/conversions/ts-dc799-poe-a1-thumb.jpg
|}
|}
This board can be detected by the POE_DETECT# signal which can be read on the EIM_DA11 GPIO.
This daughter card can be detected by the POE_DETECT# signal which can be read on the EIM_DA11 [[#GPIO|GPIO]].


= Specifications =
= Specifications =
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{{:TS-TPC-7990 FPGA Changelog}}
{{:TS-TPC-7990 FPGA Changelog}}


== Silabs Changelog ==
== Microcontroller Changelog ==
{{:TS-7990 Silabs Changelog}}
{{:TS-7990 Silabs Changelog}}


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=== SPI Flash Vendor Change ===
=== SPI Flash Vendor Change ===
{{:imx6-newuboot SPI flash change}}
{{:imx6-newuboot SPI flash change}}
=== New eMMC chip ===
{{:imx6 new emmc}}


= Product Notes =
= Product Notes =

Revision as of 17:11, 9 May 2022

TS-TPC-7990
ts-tpc-7990.gif
Product Page
Product Images
Documentation
Schematic
Mechanical Drawing
Bezel Mechanical Drawing
Panel Cutout Drawing
FTP Path
Processor
NXP i.MX6 Quad core, or Solo
i.MX6 Quad Product Page
i.MX6 Solo Product Page
IMX6Q Reference Manual
IMX6S Reference Manual

Overview

The TS-TPC-7990 is a touch panel computer supporting either capacitive or resistive touch using the i.MX6 800 MHz Solo or 1 GHz Quad core CPU.

Getting Started

A Linux PC is recommended for development, and will be assumed for this documentation. For users in Windows or OSX we recommend virtualizing a Linux PC. Most of our platforms run Debian and if there is no personal distribution preference this is what we recommend for ease of use.

Virtualization

Suggested Linux Distributions

It may be possible to develop using a Windows or OSX system, but this is not supported. Development will include accessing drives formatted for Linux and often Linux based tools.

Getting Console and Powering up

WARNING: Be sure to take appropriate Electrostatic Discharge (ESD) precautions. Disconnect the power source before moving, cabling, or performing any set up procedures. Inappropriate handling may cause damage to the unit.

To get the initial console first connect a USB micro cable to the Console/P2 header near the bottom of the board, and connect the host cable to your workstation. This can be done before or after power is applied, but bringing up a serial connection before applying power will allow viewing of the first few console messages.

Most Linux distributions include the cp210x driver and will register this as /dev/ttyUSB0. For other operating systems:

The serial console is provided through this port at 115200 baud, 8n1, with no flow control. Picocom is the recommended client which can connect with:

sudo picocom -b 115200 /dev/ttyUSB0

This will output some serial settings and then "Terminal ready". Any messages after this will be from the unit itself. Now that the terminal is ready, power can be applied. The power input for the TS-TPC-7990 uses a removable terminal block which accepts 5 VDC, or 8-36 VDC input. Only one should be connected at a time.

A power supply should be prepared to provide 20 W, but the device power consumption will typically be around 8 W on an idle quad core. See the Specifications section for further details on power requirements, differences between build options, and options to reduce power.

Power connector

Console output should appear immediately after power input is applied. The first output is from U-Boot:

U-Boot 2015.04-07904-g87ba17a (Jan 23 2017 - 11:56:50)

CPU:   Freescale i.MX6Q rev1.2 at 792 MHz
CPU:   Temperature 42 C
Reset cause: POR
Board: TS-TPC-7990 REV B
I2C:   ready
DRAM:  1 GiB
MMC:   FSL_SDHC: 0, FSL_SDHC: 1
SF: Detected N25Q64 with page size 256 Bytes, erase size 4 KiB, total 8 MiB
auto-detected panel LXD-WSVGA
Display: LXD-WSVGA (1024x600)
In:    serial
Out:   serial
Err:   serial
FPGA Rev: 8
SilabRev: 2
Net:   using phy at 1
FEC [PRIME]
SF: Detected N25Q64 with page size 256 Bytes, erase size 4 KiB, total 8 MiB
SF: 7655 bytes @ 0x200000 Read: OK

Jumpers on the DIO header are used to influence where and how the system boots. When set, the "SD Boot" jumper will cause the unit to boot to SD, otherwise boot to eMMC. Setting the "U-Boot" jumper will cause the unit to check for USB updates on startup, and then stop at a U-Boot console. If it is not set then U-Boot will quickly boot to the selected boot media as fast as possible.

Note: The "*** Warning - bad CRC, using default environment" message is expected if the U-Boot scripts and/or environment variables have not been modified from factory defaults, and can be safely ignored. Using the U-Boot command 'env save' will save the current environment to flash, and cause this message to be removed.

First Linux Boot

U-Boot is loaded from the onboard SPI flash, which is the CPU boot source. U-Boot can boot to to Linux, Android, or other operating systems, from a variety of source mediums (most commonly SD or eMMC). The eMMC and SD cards shipped with the unit will be programmed with Debian Jessie. Other OS sections on this wiki can provide further guidance on switching to Yocto, Ubuntu, Android, or others.

[  OK  ] Started Serial Getty on ttymxc0.
[  OK  ] Reached target Login Prompts.
[  OK  ] Started SLiM Simple Login Manager.
[  OK  ] Created slice user-0.slice.
         Starting LSB: RPC portmapper replacement...
         Starting User Manager for UID 0...
[  OK  ] Started User Manager for UID 0.
[  OK  ] Started LSB: RPC portmapper replacement.
[  OK  ] Reached target RPC Port Mapper.
         Starting Authenticate and Authorize Users to Run Privileged Tasks...

Debian GNU/Linux 8 ts-imx6 ttymxc0

ts-imx6 login: 

By default, the boot output is fairly verbose and includes kernel messages and Debian's startup messages from systemd. On the touch panel, Debian will boot to a minimal XFCE desktop. This is intended as an example to try out the display. In an actual shipping application this is typically disabled and only the applications specifically intended to run are given access to draw on the screen. See Starting automatically in Debian for more details.

Note: During development it is recommended to leave the verbose boot output on as these can help with debugging. The messages can be disabled by modifying the kernel cmdline for a quiet boot which will only print error messages.

The login prompt will ask for a username/password. Under Debian this is just "root" with no password which will allow the initial login. From here, development can continue as suggested in the Debian section of the manual.

Comparison of Distributions

We currently offer a Debian, Ubuntu, Yocto, and Android OS for the TS-TPC-7990. Each of these have their pros and cons. We typically recommend Debian if the user does not require GPU support, or Yocto if the goal is to use QT with remote debug support.

Distribution Pros Cons
Debian
  • Cross compiler requires running the same Debian release
  • Not conveniently patched for hardware support
    • No OpenGL or 2D acceleration from GPU, though framebuffer access is typically fast enough for most applications
Ubuntu
  • Cross compilation requires running the same Ubuntu release on a host PC
  • Not conveniently patched for hardware support
    • No OpenGL or 2D acceleration from GPU, though framebuffer access is typically fast enough for most applications
Yocto
  • Large focus on up-to-date packages
  • Allows rebuilding all packages with custom modifications
  • Supports fairly portable toolchain packages that integrate with QtCreator and Eclipse
  • Includes all patches needed for graphics support.
  • Distribution can be rebuilt to include specific needs.
  • Short life cycles
  • Does not support any online repository of pre-built applications. Adding packages requires rebuilding Yocto or building the required package manually.
  • Less examples and documentation available online
Android
  • Simple well defined API using well documented tools.
  • Allows existing apps to be run without huge customization
  • Under Android it is difficult to access hardware that is not typically on an Android tablet/phone such as UARTs, GPIO, ADC, etc. Often users write a standard application that communicates over a localhost socket to an Android application.
  • Slow boot time
  • Poor documentation for OS customization

U-Boot

This platform uses U-Boot as the bootloader to launch the full operating system. The i.MX6 processor loads U-Boot from the on-board 8 MiB SPI flash. U-Boot provides support for loading data from various mediums; this allows booting a kernel from SD, eMMC, SATA, NFS, or USB. U-Boot is a general purpose bootloader that is capable of booting into common Linux distributions, Android, Windows, or custom software OSes.

On a normal boot the output should be similar to the output below:

U-Boot 2015.04-07932-g68f7575230 (Apr 12 2017 - 10:16:39)

CPU:   Freescale i.MX6SOLO rev1.1 at 792 MHz
CPU:   Temperature 59 C
Reset cause: WDOG
Board: TS-TPC-7990 REV B
I2C:   ready
DRAM:  1 GiB
MMC:   FSL_SDHC: 0, FSL_SDHC: 1
SF: Detected N25Q64 with page size 256 Bytes, erase size 4 KiB, total 8 MiB
auto-detected panel LXD-WSVGA
Display: LXD-WSVGA (1024x600)
In:    serial
Out:   serial
Err:   serial
FPGA Rev: 8
SilabRev: 6
Net:   using phy at 1
FEC [PRIME]
SF: Detected N25Q64 with page size 256 Bytes, erase size 4 KiB, total 8 MiB
SF: 7655 bytes @ 0x200000 Read: OK
Booting from eMMC ...

By default the unit will boot to SD or eMMC depending on the status of the "SD boot" jumper on startup. If the jumper is set it boots to SD, otherwise the unit will boot to eMMC. Other boot options like SATA, Network, USB, will require customizing the U-Boot environment.

U-Boot Environment

The eMMC flash contains both the U-Boot executable binary and U-Boot environment. Our default build has 2 MiB of environment space which can be used for variables and boot scripts. The following commands are examples of how to manipulate the U-Boot environment:

# Print all environment variables
env print -a

# Sets the variable bootdelay to 5 seconds
env set bootdelay 5;

# Variables can also contain commands
env set hellocmd 'led red on; echo Hello world; led green on;'

# Execute commands saved in a variable
env run hellocmd;

# Commit environment changes to the SPI flash
# Otherwise changes are lost
env save

# Restore environment to default
env default -a

# Remove a variable
env delete emmcboot

U-Boot Commands

# The most important command is 
help
# This can also be used to see more information on a specific command
help i2c

# This is a command added to U-Boot by TS to read the baseboard ID on our 
# System on Module devices
bbdetect
echo ${baseboard} ${baseboardid} 
# The echo will return something similar to:
# TS-8390 2

# Boots into the binary at $loadaddr.  The loaded file needs to have
# the U-Boot header from mkimage.  A uImage already contains this.
bootm
# Boots into the binary at $loadaddr, skips the initrd, specifies
# the FDT addrress so Linux knows where to find the device tree
bootm ${loadaddr} - ${fdtaddr}

# Boot a Linux zImage loaded at $loadaddr
bootz
# Boot in to a Linux zImage at $loadaddr, skip initrd, specifies
# the FDT address to Linux knows where to find the device tree
bootz ${loadaddr} - ${fdtaddr}

# Get a DHCP address
dhcp
# This sets ${ipaddr}, ${dnsip}, ${gatewayip}, ${netmask}
# and ${ip_dyn} which can be used to check if the dhcp was successful

# These commands are used for scripting:
false # do nothing, unsuccessfully
true # do nothing, successfully

# This command can set fuses in the processor
# Setting fuses can brick the unit, will void the warranty,
# and should not be done in most cases
fuse

# GPIO can be manipulated from U-Boot.  Keep in mind that the IOMUX 
# in U-Boot is only setup enough to boot the device, so not all pins will
# be set to GPIO mode out of the box.  Boot to the full operating system
# for more GPIO support.
# GPIO are specified in bank and IO in this manual.  U-Boot uses a flat numberspace,
# so for bank 2 DIO 25, this would be number (32*1)+25=89
# The formula thus being (32*(bank-1)+dio)=flattened_dio
# Note that on some products, bank 1 is the first bank
# Set 2_25 low
gpio clear 83
# Set 2_25 high
gpio set 83
# Read 2_25
gpio input 83

# Control LEDs
led red on
led green on
led all off
led red toggle

# This command is used to copy a file from most devices
# Load kernel from SD
load mmc 0:1 ${loadaddr} /boot/uImage
# Load Kernel from eMMC
load mmc 1:1 ${loadaddr} /boot/uImage
# Load kernel from USB
usb start
load usb 0:1 ${loadaddr} /boot/uImage
# Load kernel from SATA
sata init
load sata 0:1 ${loadaddr} /boot/uImage

# View the FDT from U-Boot
load mmc 0:1 ${fdtaddr} /boot/imx6q-ts4900.dtb
fdt addr ${fdtaddr}
fdt print

# It is possible to blindly jump to any memory location
# This is similar to bootm, but it does not require
# the use of the U-Boot header
load mmc 0:1 ${loadaddr} /boot/custombinary
go ${loadaddr}

# Browse fat, ext2, ext3, or ext4 filesystems:
ls mmc 0:1 /

# Access memory like devmem in Linux, read/write arbitrary memory
# using mw and md
# write
mw 0x10000000 0xc0ffee00 1
# read
md 0x10000000 1

# Test memory.
mtest

# Check for new SD card
mmc rescan
# Read SD card size
mmc dev 0
mmcinfo
# Read eMMC Size
mmc dev 1
mmcinfo

# The NFS command is like 'load', but used over the network
dhcp
env set serverip 192.168.0.11
nfs ${loadaddr} 192.168.0.11:/path/to/somefile

# Test ICMP
dhcp
ping 192.168.0.11

# Reboot
reset

# SPI access is through the SF command
# Be careful with sf commands since
# this is where U-Boot and the FPGA bitstream exist
# Improper use can render the board unbootable
sf probe

# Delay in seconds
sleep 10

# Load HUSH scripts that have been created with mkimage
load mmc 0:1 ${loadaddr} /boot/ubootscript
source ${loadaddr}

# Most commands have return values that can be used to test
# success, and HUSH scripting supports comparisons like
# test in Bash, but much more minimal
if load mmc 1:1 ${fdtaddr} /boot/uImage;
	then echo Loaded Kernel
else
	echo Could not find kernel
fi

# Commands can be timed with "time"
time sf probe

# Print U-Boot version/build information
version

Modify Linux Kernel cmdline

The Linux kernel cmdline can be customized by modifying the cmdline_append variable. The variable contents are clobbered when set, so be sure to specify the full desired cmdline string.

env set cmdline_append console=ttymxc0,115200 init=/sbin/init quiet
env save

The kernel command line can also be modified from from the on-board Linux. Debian (and other distributions) provide a U-Boot utilities package that contains the tools necessary to create a U-Boot script:

apt-get update && apt-get install u-boot-tools -y
echo "env set cmdline_append console=ttymxc0,115200 init=/sbin/init quiet" > /boot/boot.scr
mkimage -A arm -T script -C none -n 'tsimx6 boot script' -d /boot/boot.scr /boot/boot.ub

The boot.scr includes the plain text commands to be run in U-Boot on startup. The mkimage tool adds a checksum and header to this file which can be loaded by U-Boot. The .ub file should not be edited directly.

Booting From NFS

U-Boot includes support for NFS client which can be used to load the kernel, device tree binary, and root filesystem across the network. Our default environment contains the nfsboot command which can be updated to boot NFS on a custom network:

# Set this to your NFS server IP
env set nfsroot 192.168.0.36:/mnt/storage/imx6/
env save
# Boot to NFS once
run nfsboot;

# To make the NFS boot the persistent default
env set bootcmd run nfsboot;
env save

Booting From USB

On startup, U-Boot will attempt to load a script from USB if the U-Boot jumper is on. This can be used for reprogramming the board, or for booting to a kernel and/or filesystem on a USB drive. To make a bootable drive, create a single ext3 partition on a USB drive and copy over a rootfs (in the same manner as is done for an SD card. This is described in depth in the Debian and Yocto sections. Create the /tsinit.ub file in the root of the USB drive. Below is an example of booting to the filesystem on the USB drive:

# Prepare with:
# mkimage -A arm -T script -C none -n 'mx6 usb' -d tsinit.scr tsinit.ub

# DO NOT MANUALLY EDIT THE .UB FILE

if test ${model} = '7990'; then
	if load usb ${bootpart} ${loadaddr} /boot/ts7990-fpga.vme; then
		fpga load 0 ${loadaddr} ${filesize};
	fi;

	if test ${pcbrev} != 'a'; then
		load usb ${bootpart} ${fdtaddr} /boot/imx6${cpu}-ts7990-${lcd}-revb.dtb;
	else
		load usb ${bootpart} ${fdtaddr} /boot/imx6${cpu}-ts7990-${lcd}.dtb;
	fi;

	load usb 0:1 ${loadaddr} ${uimage};
	setenv bootargs root=/dev/sda1 rootwait rw ${cmdline_append};
	bootm ${loadaddr} - ${fdtaddr};
fi

load usb 0:1 ${loadaddr} /boot/uImage;
setenv bootargs root=/dev/sda1 rootwait rw ${cmdline_append};
bootm ${loadaddr} - ${fdtaddr};

Generate the tsinit.ub file in the same directory, note that u-boot-tools or the equivalent package for a specific distribution will need to be installed:

mkimage -A arm -T script -C none -n 'mx6 usb' -d tsinit.scr tsinit.ub

Set the "U Boot" jumper, insert the USB drive to the device, and apply power.

Update U-Boot

WARNING: Installing a customer U-Boot binary is not recommended and may cause the unit to fail to boot.

U-Boot requires a different build for Quad/Dual and Solo/Duallite. Flashing the wrong U-Boot image will cause the board to fail to properly boot. Recovery in this case would require submitting an RMA request.

On a booted unit at the U-Boot console, type "env print ${imx_type}" and this will return the U-Boot build that should be used. Copy the correct u-boot.imx file to the SD card, boot to the U-Boot shell, and run:

mmc dev 0
load mmc 0:1 ${loadaddr} /u-boot.imx
sf probe
sf erase 0 0x80000
sf write ${loadaddr} 0x400 $filesize

U-Boot Development

We do provide our U-Boot sources but we do not recommend rebuilding a custom U-Boot if it can be avoided. Custom built U-Boot binaries will not have the latest up to date settings. Specifically, the largest concern is with RAM timing settings. Memory technology is expanding rapidly and we may need to use different parts through the shipping lifetime of the device itself. If RAM timings change, then we update our factory shipped U-Boot to have the proper settings. A custom U-Boot would need to be re-built if any of these settings change.

Our U-Boot includes a variable "imx_type". If loading a custom U-Boot binary, make sure to check the value of this before writing. If we are forced to update the RAM configuration we will change this variable. We will also send out a product change to anyone who is subscribed to our PCS system.

If you still need to proceed with building a custom U-Boot, use the imx_v2015.04_3.14.52_1.1.0_ga branch from the github here: https://github.com/embeddedTS/u-boot-imx/

On a booted unit at the U-Boot console, type "env print ${imx_type}" and this will return the U-Boot build that should be used and the correct RAM timing.

After that, adjust the following commands to match the build configuration; these commands will build the u-boot.imx binary.

export ARCH=arm
export CROSS_COMPILE=arm-linux-gnueabihf-
export DATE=$(date +"%b-%d-%Y")

make ts7990-s-1g-800mhz-i_defconfig
make -j9 u-boot.imx

This will output a u-boot.imx file that can be written to the SPI flash following the instructions in the update U-Boot section.

U-Boot Recovery

We have several variations of the TS-TPC-7990's u-boot which include different RAM configurations for the Quad core, solo commercial, solo industrial, and a few older variants. On a functional board if you run "ech o ${imx_type}" this will show which variant you are running. To recover the system you must get it booting over the USB OTG port.

On startup, the i.MX6 checks the SPI flash for a valid boot header in SPI flash. If it is unable to locate a valid boot header, the CPU falls back to the "serial downloader" which allows the CPU to execute code sent via USB. If the unit has a valid but damaged or incorrect U-Boot binary programmed in to SPI flash, an RMA return will be required in order to properly recover it. Please contact us for assistance with this.

1) Download the U-Boot binary for the correct imx_type variant from the list here: https://files.embeddedTS.com/ts-arm-sbc/ts-7970-linux/u-boot/. See the U-Boot Changelog for information on the changes between released versions.

2) Download and build/install the "imx_usb" loader

3) Apply power to the device.

4) Plug a USB type B cable into the "Device" USB Micro connector on the device and connect it to a host PC.

5) Check 'dmesg' or 'lsusb' on the host PC for a new USB connection. This should show a HID device listing NXP or Freescale as the manufacturer. For example:

hid-generic 0003:15A2:0054.0006: hiddev0,hidraw3: USB HID v1.10 Device [Freescale SemiConductor Inc  SE Blank ARIK] on usb-0000:00:14.0-6.4.2/input0

If it does not show the above output, an RMA return will be required in order to properly recover the unit. Please contact us for assistance with this.

6) Plug a USB type B cable into the "Console" USB Micro connector on the device and connect it to a host PC, and open your terminal emulator

7) Install the UBOOT jumper on the 7990 to stop at the u-boot prompt

8) Run 'imx_usb path/to/u-boot.imx' on the host PC

At this point, the USB serial device should show up on the host, opening it will reveal that the unit is stopped at the U-Boot prompt. Follow the steps in Update U-Boot to reinstall U-Boot on the SPI flash.

Yocto

Yocto is our recommended distribution for graphics packages as the software includes patches to support the GPU. X11 in Yocto includes drivers for providing 2D support as well. Support is also provided for OpenGLES 1&2, as well as GStreamer acceleration, included standalone or with Qt. Yocto also provides cross toolchains that include the rootfs. This toolchain allows integration with the Qt Creator IDE and Eclipse.

Yocto does not provide binary security updates. This distribution also does not have any remote repository of pre-built applications. For either of these we features we recommend using Debian.

Our current Yocto support is based off of Yocto 3.0 "Zeus".

Getting Started with Yocto

Yocto itself is a set of scripts and tools used to build a custom distribution. In our default images we try to include all the common utilities requested by users. Rebuilding Yocto should not be necessary for many users, but is possible if needed. See the Custom Build Yocto section for information on this process.


Our Yocto rootfs tarball is available here:

Yocto Download Links
Yocto Image Download Link
ts-x11-image (Yocto Zeus) Download

To write this to an SD card, first partition the SD card to have one large ext3 partition. Most SD cards include one MBR partition by default. Cards can also be partitioned with fdisk, cfdisk, or the graphical gparted utility. This should be an MBR partition table, not GPT. Once it is partitioned, format the SD and extract this tar with:

# Assuming your SD card is /dev/sdc with one partition
mkfs.ext3 /dev/sdc1
mkdir /mnt/sd/
sudo mount /dev/sdc1 /mnt/sd/
sudo tar --numeric-owner -jxf ts-x11-image-tsimx6-latest.rootfs.tar.bz2 -C /mnt/sd
sudo umount /mnt/sd
sync
Note: The ext4 filesystem can be used instead of ext3, but it may require additional options. U-Boot does not support the 64bit addressing added as the default behavior in recent revisions of mkfs.ext4. If using e2fsprogs 1.43 or newer, the options "-O ^64bit,^metadata_csum" must be used with ext4 for proper compatibility. Older versions of e2fsprogs do not need these options passed nor are they needed for ext3.

To rewrite the eMMC, boot to the SD card. You cannot rewrite the eMMC while it is mounted elsewhere, or used to currently boot the system. Once booted to the SD, run:

mkfs.ext3 /dev/mmcblk2p1
mkdir /mnt/emmc
mount /dev/mmcblk2p1 /mnt/emmc
wget -qO- https://files.embeddedTS.com/ts-socket-macrocontrollers/ts-4900-linux/distributions/yocto/zeus/ts-x11-image-tsimx6-latest.rootfs.tar.bz2 | tar --numeric-owner xj -C /mnt/emmc/
umount /mnt/emmc
sync

The same commands can be used to write SATA by substituting /dev/mmcblk2p1 with /dev/sda1.

First Boot

The stock Yocto image provides a single login of root with no password. With Zeus, the wired ethernet interface will attempt to acquire an IP address via DHCP automatically. However, it is not possible to log in via the network at this time due to security of the device requiring a password for SSH access. Initial login to the device must first be done on the serial console.

Yocto Networking

Our Yocto image uses systemd which stores its network files in /etc/systemd/network/. Yocto will automatically enable DHCP on its wired interfaces. This can be overridden to set a static IP or enable other options for DHCP. The only requirement is that this file is named /etc/systemd/network/XX-wired.network Where "XX" is a number smaller than 80, e.g. /etc/systemd/network/79-wired.network This format must be used for all eth* and en* named network interfaces. The lower file names will take priority.

An example of a static configuration would be:

/etc/systemd/network/42-wired.network

[Match]
Name=eth0

[Network]
Address=192.168.0.50/24
Gateway=192.168.0.1
DNS=192.168.0.1

DNS will be loaded from /etc/resolv.conf. To make this use a static DNS:

rm /etc/resolv.conf
echo "nameserver 8.8.8.8" > /etc/resolv.conf
echo "nameserver 8.8.4.4" >> /etc/resolv.conf

To use the DNS assigned by DHCP, run:

ln -s /run/systemd/resolve/resolv.conf /etc/resolv.conf

For more information on what options are available to configure the network, see the systemd network documentation.

Yocto Wireless

The Atmel driver needs to be loaded manually on units that include wifi. Run 'modprobe wilc3000' to manually load the driver once, or edit /etc/modules and add "wilc3000" on a new line to have the module automatically load on startup.

Yocto uses systemd to start wpa_supplicant, and systemd-networkd to set an IP address via a static setting or DHCP.

Scan for a network

ifconfig wlan0 up

# Scan for available networks
iwlist wlan0 scan

An example of connecting to an open network with an SSID of "default":

          Cell 03 - Address: c0:ff:ee:c0:ff:ee
                    Mode:Managed
                    ESSID:"default"
                    Channel:2
                    Encryption key:off
                    Bit Rates:9 Mb/s

To connect to this open network manually for just this boot:

iwconfig wlan0 essid "default"

Use the 'iwconfig' command to determine authentication to an access point. Before connecting it will show something like this:

# iwconfig wlan0
wlan0     IEEE 802.11bgn  ESSID:"default"  
          Mode:Managed  Frequency:2.417 GHz  Access Point: c0:ff:ee:c0:ff:ee   
          Bit Rate=1 Mb/s   Tx-Power=20 dBm   
          Retry  long limit:7   RTS thr:off   Fragment thr:off
          Encryption key:off
          Power Management:off
          Link Quality=70/70  Signal level=-34 dBm  
          Rx invalid nwid:0  Rx invalid crypt:0  Rx invalid frag:0
          Tx excessive retries:0  Invalid misc:0   Missed beacon:0

If connecting using WEP, also specify a network key:

iwconfig wlan0 essid "default" key "yourpassword"

If connecting to a WPA network use wpa_passphrase and wpa_supplicant:

mkdir /etc/wpa_supplicant/
wpa_passphrase "ssid name" "full passphrase" >> /etc/wpa_supplicant/wpa_supplicant-wlan0.conf

After generating the configuration file the wpa_supplicant daemon can be started.

wpa_supplicant -iwlan0 -c/etc/wpa_supplicant/wpa_supplicant-wlan0.conf -B

This will return:

 Successfully initialized wpa_supplicant
 root@ts-imx6-q:~# [  306.924691] wlan0: authenticate with 28:cf:da:b0:f5:bb
 [  306.959415] wlan0: send auth to 28:cf:da:b0:f5:bb (try 1/3)
 [  306.968137] wlan0: authenticated
 [  306.978477] wlan0: associate with 28:cf:da:b0:f5:bb (try 1/3)
 [  306.988577] wlan0: RX AssocResp from 28:cf:da:b0:f5:bb (capab=0x1431 status=0 aid=9)
 [  307.009751] wlan0: associated
 [  307.012768] IPv6: ADDRCONF(NETDEV_CHANGE): wlan0: link becomes ready
 [  307.047989] wlcore: Association completed.

Use 'iwconfig wlan0' to verify an "Access Point" is specified to verify a connection. This will also report the link quality to the AP.

Wireless may be associated, but this does not get an IP on the network. To connect to the internet or talk to the internal network first configure the interface. See configuring the network, but on many networks only a DHCP client is needed:

udhcpc -i wlan0

Systemd can also be configured to start wpa_supplicant on boot up.

# Assuming the same path for the wpa conf file as shown above
systemctl enable wpa_supplicant@wlan0
systemctl start wpa_supplicant@wlan0

Once this service is started it will bring up the wlan0 interface and associate it to the SSID that is noted in the wpa_supplicant.conf file. Configure the IP settings the same way as a wired network.

In /etc/systemd/network/wlan0.network

[Match]
Name=wlan0

[Network]
DHCP=yes

For a static configuration create a config file for that specific interface. /etc/systemd/network/wlan0.network

[Match]
Name=wlan0

[Network]
Address=192.168.0.50/24
Gateway=192.168.0.1
DNS=192.168.0.1

For more information on what options are available to configure the network, see the systemd network documentation.

Yocto Application Development

Yocto provides a cross toolchain including the native tools and required ARM libraries. The cross toolchain is only available for 64bit Linux host PCs. Download the toolchain by saving the following link:

In order to install the toolchain, use the following commands to run the installation script:

chmod a+x poky-*.sh
sudo ./poky-*.sh

In order to use the toolchain, the environment for it must be sourced to the current terminal before it can be used to build applications: To build an application first source the environment for the toolchain:

source /opt/poky/3.0.2/environment-setup-cortexa9t2hf-neon-poky-linux-gnueabi

# This command sets up paths for the shell along with a number of other
# environment variable. For example:
$ echo $CC
arm-poky-linux-gnueabi-gcc -march=armv7-a -marm -mthumb-interwork -mfloat-abi=hard -mfpu=neon -mtune=cortex-a9 --sysroot=/opt/poky/2.2.2/sysroots/cortexa9hf-vfp-neon-poky-linux-gnueabi

# Cross compiling a simple hello world program:
$CC hello.c -o hello

It is also possible to develop applications directly on the device via serial console or ssh. Yocto includes development tools such as vim, gcc, g++, gdb, make, autoconf, binutils, etc. See the next sections for using the cross toolchain with IDEs.

Configure Qt Creator IDE

Note: This guide is intended for our stock Yocto image using systemd. On custom images, the same instructions should apply if a cross toolchain is built. This can be built through Yocto with bitbake meta-toolchain-qt5. Be sure to update the paths if using a different distribution.


Install the qtcreator tool on a host Linux PC. Any recent version from a modern Linux distribution should be sufficient and work without issue. On a Debian/Ubuntu desktop, run:

sudo apt-get update && sudo apt-get install qtcreator -y

The SDK which includes the Qt support will also need to be downloaded. The cross toolchain is only available for 64-bit Linux host PCs:

In order to install the toolchain, use the following commands to run the installation script:

chmod a+x poky-*.sh
sudo ./poky-*.sh

These instructions assume the installation path will be the default at /opt/poky/3.0.2/


Note: An environment script has to be sourced before every execution of qtcreator. Without this, builds will fail.
source /opt/poky/3.0.2/environment-setup-cortexa9t2hf-neon-poky-linux-gnueabi
qtcreator


Qt Creator needs to be configured to build using this toolchain. Once Qt Creator is launched, select Tools->Options->Devices Click Add, select Generic Linux Device, and then click Start Wizard

Qt Device Configuration

On the next page specify the IP address or hostname of the device running Yocto. In this example, the unit has an IP address of 192.168.2.45 obtained via DHCP. The default Yocto image will use the user root with no password to connect. Set the name to TSIMX6

Qt Device Configuration

It will then verify connectivity. Click close and continue.

Qt Device Test
Note: The paths given in the images below may not match the latest toolchain, but are meant to show where these values would go. Follow the text appropriate to the architecture of your host PC for the correct values


In the left column of the Options menu, select Build & Run. On the Qt Versions tab, click Add in the upper right to configure the TS Kit. Qt Creator may see the qmake binary added to your path from the sourced environment script. If this is detected, add in the string TSIMX6 to the title as shown in the photo below. If it is not autodetected, add the full path and ensure the version name is set to TSIMX6 Qt 5.13.2. This will allow it to be recognized when setting the right binary for the kit.

/opt/poky/3.0.2/sysroots/x86_64-pokysdk-linux/usr/bin/qmake
Qt Versions tab


On the Compilers tab click Add, select GCC then C. Set the Name to TSIMX6 GCC. For the Compiler Path use the following:

/opt/poky/3.0.2/sysroots/x86_64-pokysdk-linux/usr/bin/arm-poky-linux-gnueabi/arm-poky-linux-gnueabi-gcc

Repeat the above steps for the g++ compiler; click Add, select GCC then C++. Set the name to TSIMX6 G++. And for the Compiler Path use the following:

/opt/poky/3.0.2/sysroots/x86_64-pokysdk-linux/usr/bin/arm-poky-linux-gnueabi/arm-poky-linux-gnueabi-g++
Qt Compiler tab

On the Debuggers tab click Add. For name, specify TSIMX6 GDB. For the path, specify the location of gdb with the following:

/opt/poky/3.0.2/sysroots/x86_64-pokysdk-linux/usr/bin/arm-poky-linux-gnueabi/arm-poky-linux-gnueabi-gdb
Qt Debugger tab

On the Kits tab click Add. For Name, enter TSIMX6. Set device type to Generic Linux Device. Set the device to TSIMX6 (default for Generic Linux). Set Qt mkspec to the following (make sure there is no space at the end):

/opt/poky/3.0.2/sysroots/cortexa9t2hf-neon-poky-linux-gnueabi/usr/lib/mkspecs/linux-oe-g++


Set C Compiler to TSIMX6 GCC and C++ Compiler to TSIMX6 G++. Set Debugger to TSIMX6 GDB. Set the Qt version to TSIMX6 QT 5.13.2. Finally, click Apply.

Qt Kit tab
Note: If there is a red exclamation point over the kits icon, it indicates that the compiler ABI does not match. In this case, you will need to revisit the "Compiler", "Debugger", and "Qt Versions" tabs, and browse the host PC for these files manually rather than copy/pasting the paths from these instructions. This is a bug in Ubuntu 16.04's Qt Creator, and may be in later versions as well.

At this point Qt Creator is set up to begin a hello world project.

Qt Creator Hello World

Open the Qt Creator IDE and click New Project.

Qt New Project

Qt provides multiple templates for application development. For this example select the default Qt Widgets Application.

Qt Widgets App

Specify the location for your project. Keep in mind that the compile process will create more build paths in the Create In: path.

Qt Location

Next, select the kit. The TSIMX6 is the kit we set up in the last section, but you may have other kits pre-installed on your system. These can be used for testing graphical development on your PC. Keep in mind distribution versions may contain different functionality.

Qt Select Kit

Next select the class and filename information. This example will use the defaults.

Qt Select Classes

Select any version control for the project. The example will use none and finish the wizard. This will generate the new project.

Qt Project Management

Click the button under Help on the left column, and select TSIMX6 debug. If there is only one kit selected, this will be default.

Qt Select build

Now return to edit, and open the Qt project file, qt5-helloworld.pro. Add in these lines anywhere after the target is specified:

linux-* {
    target.path = /home/root
    INSTALLS += target
}
Qt pro file

Last, the DISPLAY must be selected. This is done by setting a run environment variable that will be set when the application is run on the board.

Qt run environment settings

At this point click the green allow in the bottom left to run the application. This can also be launched from the menu at Build->Run.

Qt Build and Deploy

From here, you can begin customizing your application. Refer to the official Qt documentation for more information

Yocto Hide Cursor

The default image includes the xcursor-transparent icon theme. This can hide the mouse pointer. To enable this, run these commands:

mkdir -p ~/.icons/default/

echo "[Icon Theme]" > ~/.icons/default/index.theme
echo "Inherits=xcursor-transparent" >> ~/.icons/default/index.theme

# Now reset x, or reset the unit and the cursor will be invisible.

Yocto Startup Scripts

To have a custom headless application start up at boot a systemd service needs to be created. Create the file /etc/systemd/system/yourapp.service with contents similar to below:

[Unit]
Description=Run an application on the i.MX6

[Service]
Type=simple
ExecStart=/usr/local/bin/your_app_or_script

[Install]
WantedBy=multi-user.target

If an application depends on networking, the systemd script will want to have After=network.target in the Unit section. Once this file is in place, it can be added to automatic startup with the following:

# Enable the application to be started on boot up
systemctl enable yourapp.service

# Start the application now, but will not affect automatic startup
systemctl start yourapp.service
Note: See the systemd documentation for in depth documentation on services.

To set up a graphical application startup, modify the /usr/bin/mini-x-session file

At the end of the script replace matchbox-terminal with the desired application (absolute path may need to be specified):

matchbox-terminal &
exec matchbox-window-manager

The exec statement must be last in the script in order to take over this script's PID for correct operation.

Custom Build Yocto

If our stock Yocto distribution does not meet all of your needs, it is possible to re-build it with a custom set of features. Including less options for a smaller footprint, or more packages to add more features.

While we may provide guidance, our free support does not include every situation that can cause a build failure in generating custom images.

Debian

Debian is a community run Linux distribution. Debian provides tens of thousands of precompiled applications and services. This distribution is known for stability and large community providing support and documentation.

Debian 12 - Bookworm

Debian 12 - Getting Started

This Debian release is available in 3 flavors with various packages.

Image Estimated Size Description
debian-armhf-bookworm-x11-latest.tar.bz2 1021 MiB
  • Includes 5.10 kernel with tsimx6_defconfig that includes broad driver support
  • Base Debian with common utils
  • Common embedded tools (i2c, can, gpio, iio, serial tools, etc)
  • Includes hardware support
  • Networking tools (ethernet, wifi, bluetooth)
  • Includes Development tools
  • Includes X11 that launches matchbox and xterm on startup
  • Includes touchscreen support
debian-armhf-bookworm-headless-latest.tar.bz2 777 MiB
  • Includes 5.10 kernel with tsimx6_defconfig that includes broad driver support
  • Base Debian with common utils
  • Common embedded tools (i2c, can, gpio, iio, serial tools, etc)
  • Includes hardware support
  • Networking tools (ethernet, wifi, bluetooth)
  • Includes Development tools
debian-armhf-bookworm-minimal-latest.tar.bz2 263 MiB
  • Includes 5.10 kernel with tsimx6_minimal_defconfig that includes bare minimum driver support and kernel options required by Debian.
  • Includes base Debian rootfs adding only what is required for Ethernet support.

The default login is root with no password.

To write this to an SD card, first partition the SD card to have one large ext3, or ext4 partition. See the guide here for more information. Once it is formatted, extract this tar with:

# Assuming your SD card is /dev/sdc with one partition
mkfs.ext3 /dev/sdc1
mkdir /mnt/sd/
sudo mount /dev/sdc1 /mnt/sd/
sudo tar --numeric-owner -xjf debian-armhf-bookworm-x11-latest.tar.bz2 -C /mnt/sd
sudo umount /mnt/sd
sync

To rewrite the eMMC, boot to the SD card. You cannot rewrite the emmc while it is mounted elsewhere, or used to currently boot the system. Once booted to the SD, run:

mkfs.ext3 /dev/mmcblk2p1
mkdir /mnt/emmc
mount /dev/mmcblk2p1 /mnt/emmc
wget -qO- https://files.embeddedts.com/ts-arm-sbc/ts-7970-linux/distributions/debian/debian-armhf-bookworm-x11-latest.tar.bz2 | tar --numeric-owner -xj -C /mnt/emmc/
umount /mnt/emmc
sync


Note: The ext4 filesystem can be used instead of ext3, but it may require additional options. U-Boot does not support the 64bit addressing added as the default behavior in recent revisions of mkfs.ext4. If using e2fsprogs 1.43 or newer, the options "-O ^64bit,^metadata_csum" must be used with ext4 for proper compatibility. Older versions of e2fsprogs do not need these options passed nor are they needed for ext3.

Debian 12 - Networking

The network in Debian is configured with /etc/network/interfaces. For complete documentation, see Debian's documentation here

Some common examples are shown below. On this release network interfaces follow the predictible network interface names. Run ip addr show to get a list of the network interfaces.

Most commonly:

  • end0 - Ethernet device 0 (CPU Ethernet)
  • enp1s0 - Ethernet PCIe port 1 slot 0 ethernet
  • usb<mac> - USB ethernet
  • wlan0 - WIFI

DHCP on end0. Edit the file /etc/network/interfaces and add:

auto end0
allow-hotplug end0
iface end0 inet dhcp

Static IP on end0. Edit the file /etc/network/interfaces and add:

auto end0
iface end0 inet static
    address 192.0.2.7/24
    gateway 192.0.2.254

These will take effect on the next boot, or by restarting the networking service:

service networking restart

Debian 12 - WIFI Client

Wireless interfaces are also managed with configuration files in "/etc/network/interfaces.d/". For example, to connect as a client to a WPA network with DHCP. Note some or all of this software may already be installed on the target SBC.

Install wpa_supplicant:

apt-get update && apt-get install wpasupplicant -y

Run:

wpa_passphrase youressid yourpassword

This command will output information similar to:

 network={
 	ssid="youressid"
 	#psk="yourpassword"
 	psk=151790fab3bf3a1751a269618491b54984e192aa19319fc667397d45ec8dee5b
 }

Use the hashed PSK in the specific network interfaces file for added security. Create the file:

/etc/network/interfaces.d/wlan0

allow-hotplug wlan0
iface wlan0 inet dhcp
    wpa-ssid youressid
    wpa-psk 151790fab3bf3a1751a269618491b54984e192aa19319fc667397d45ec8dee5b

To have this take effect immediately:

service networking restart

For more information on configuring Wi-Fi, see Debian's guide here.

Debian 12 - WIFI Access Point

First, hostapd needs to be installed in order to manage the access point on the device:

apt-get update && apt-get install hostapd -y


Note: The install process will start an unconfigured hostapd process. This process must be killed and restarted before a new hostapd.conf will take effect.

Edit /etc/hostapd/hostapd.conf to include the following lines:

interface=wlan0
driver=nl80211
ssid=YourAPName
channel=1
Note: Refer to the kernel's hostapd documentation for more wireless configuration options.


To start the access point launch hostapd:

hostapd /etc/hostapd/hostapd.conf &

This will start up an access point that can be detected by WIFI clients. A DHCP server will likely be desired to assign IP addresses. Refer to Debian's documentation for more details on DHCP configuration.

Debian 12 - Installing New Software

Debian provides the apt-get system which allows management of pre-built applications. The apt tools require a network connection to the internet in order to automatically download and install new software. The update command will download a list of the current versions of pre-built packages.

apt-get update

A common example is installing Java runtime support for a system. Find the package name first with search, and then install it.

root@tsa38x:~# apt-cache search openjdk
default-jdk - Standard Java or Java compatible Development Kit
default-jdk-doc - Standard Java or Java compatible Development Kit (documentation)
default-jdk-headless - Standard Java or Java compatible Development Kit (headless)
default-jre - Standard Java or Java compatible Runtime
default-jre-headless - Standard Java or Java compatible Runtime (headless)
jtreg - Regression Test Harness for the OpenJDK platform
libreoffice - office productivity suite (metapackage)
openjdk-11-dbg - Java runtime based on OpenJDK (debugging symbols)
openjdk-11-demo - Java runtime based on OpenJDK (demos and examples)
openjdk-11-doc - OpenJDK Development Kit (JDK) documentation
openjdk-11-jdk - OpenJDK Development Kit (JDK)
openjdk-11-jdk-headless - OpenJDK Development Kit (JDK) (headless)
openjdk-11-jre - OpenJDK Java runtime, using Hotspot JIT
openjdk-11-jre-headless - OpenJDK Java runtime, using Hotspot JIT (headless)
openjdk-11-jre-zero - Alternative JVM for OpenJDK, using Zero
openjdk-11-source - OpenJDK Development Kit (JDK) source files
uwsgi-app-integration-plugins - plugins for integration of uWSGI and application
uwsgi-plugin-jvm-openjdk-11 - Java plugin for uWSGI (OpenJDK 11)
uwsgi-plugin-jwsgi-openjdk-11 - JWSGI plugin for uWSGI (OpenJDK 11)
uwsgi-plugin-ring-openjdk-11 - Closure/Ring plugin for uWSGI (OpenJDK 11)
uwsgi-plugin-servlet-openjdk-11 - JWSGI plugin for uWSGI (OpenJDK 11)
java-package - Utility for creating Java Debian packages

In this case, the wanted package will likely be the "openjdk-11-jre" package. Names of packages can be found on Debian's wiki pages or the packages site.

With the package name apt-get install can be used to install the prebuilt packages.

apt-get install openjdk-11-jre
# More than one package can be installed at a time.
apt-get install openjdk-11-jre nano vim mplayer

For more information on using apt-get refer to Debian's documentation here.

Debian 12 - Setting up SSH

Openssh is installed in our default Debian image, but by default openssh does not permit root logins, and requires a password to be set. Additionally, a host key is required if one hasn't already been created on the target board. To allow remote root login:

sed --in-place 's/#PermitRootLogin prohibit-password/PermitRootLogin yes/' /etc/ssh/sshd_config
systemctl restart ssh.service
passwd root # Set any password

If you ssh to this system it will now support ssh as root.

Debian 12 - Starting Automatically

Bookwoorm Startup Scripts

Debian 12 - Cross Compiling

Debian provides cross toolchains within their distribution for different architectures.

For best portability we recommend using a container like docker to run a Debian 12 rootfs for the toolchain. This will allow a consistent toolchain to run from almost any Linux system that can run Docker. Keep in mind that while docker does run under OSX and Windows, these are run under a case insensitive filesystem which will cause problems with complex builds like the Linux kernel so a Linux host is still recommended.

  • Ubuntu/Debian:
sudo apt-get install docker.io -y
  • Fedora
sudo dnf install docker -y

After installing docker on any distribution make sure your user is in the docker group:

# Add your user to the docker group.  You may need to logout/log back in.
sudo usermod -aG docker $USER

Make sure you can run docker's hello world image as your user to verify it is working:

docker run hello-world

Now create a file Dockerfile:

sudo mkdir -p /opt/docker-toolchain/docker-debian-bookworm-armhf
# Use any preferred editor, vim/emacs/nano/etc
sudo nano /opt/docker-toolchain/docker-debian-bookworm-armhf/Dockerfile
# syntax = docker/dockerfile:1.2

FROM debian:bookworm

RUN dpkg --add-architecture armhf

RUN apt-get update && apt-get install -y \
    autogen \
    automake \
    bash \
    bc \
    bison \
    build-essential \
    bzip2 \
    ca-certificates \
    ccache \
    chrpath \
    cpio \
    curl \
    diffstat \
    fakeroot \
    file \
    flex \
    gawk \
    gcc-arm-linux-gnueabihf \
    git \
    gzip \
    kmod \
    libgpiod-dev:armhf \
    libncursesw5-dev \
    libssl-dev \
    libtool \
    libyaml-dev \
    locales \
    lz4 \
    lzop \
    make \
    multistrap \
    ncurses-dev \
    pkg-config \
    python3 \
    python3-cbor \
    python3-pexpect \
    python3-pip \
    qemu-user-static \
    rsync \
    runit \
    socat \
    srecord \
    swig \ 
    texinfo \
    u-boot-tools \
    zstd \
    unzip \
    vim \
    wget \
    xz-utils

# Provide a more friendly name
ENV debian_chroot debian_bookworm
RUN echo "PS1='\${debian_chroot}\\[\033[01;32m\\]@\\H\[\\033[00m\\]:\\[\\033[01;34m\\]\\w\\[\\033[00m\\]\\$ '" >> /etc/bash.bashrc

# Set up locales
RUN sed -i -e 's/# en_US.UTF-8 UTF-8/en_US.UTF-8 UTF-8/' /etc/locale.gen && \
        echo 'LANG="en_US.UTF-8"'>/etc/default/locale && \
        dpkg-reconfigure --frontend=noninteractive locales && \
        update-locale LANG=en_US.UTF-8
ENV LC_ALL en_US.UTF-8
ENV LANG en_US.UTF-8
ENV LANGUAGE en_US.UTF-8

Next make a shell script to enter into this docker container. Create /usr/local/bin/docker-debian-bookworm:

# Use any preferred editor, vim/emacs/nano/etc
sudo nano /usr/local/bin/docker-debian-bookworm
#!/bin/bash -e

# Enters a docker running Debian 12 Bookworm
# Any arguments are run in the docker, or if no arguments it runs a shell

export TAG=debian-bookworm-armdev
SCRIPTPATH=$(readlink -f "$0")
DOCKERPATH=/opt/docker-toolchain/docker-debian-bookworm-armhf/

DOCKER_BUILDKIT=1 docker build --tag "$TAG" "$DOCKERPATH" --quiet

exec docker run --rm \
	-it \
	--volume "$(pwd)":/work \
	--user $(id -g):$(id -u) \
	-w /work \
	-e HOME=/tmp \
	"$TAG" \
	$@;

Make this executable, and call it:

sudo chmod a+x /usr/local/bin/docker-debian-bookworm

# dont run as root
docker-debian-bookworm

The first time this runs it will download a base Debian image, and run the above apt-get commands which may take around 10 or so minutes depending on your internet connection and disk speed. After it has run once, it will stay cached and adds almost no overhead to run.

This docker can be thought of as a very low overhead virtual machine that only has access to the directory where it is run.

For example, to build a simple c project, create a ~/Desktop/hello-world/hello.c:

mkdir -p ~/Desktop/hello-world/

In ~/Desktop/hello-world/hello.c:

#include <stdio.h>

int main() {
    printf("Hello world!\n");
    return 0;
}

We can now use the docker in that directory to use Debian's cross compiler to create a binary that targets armhf:

user@hostname:~$ cd ~/Desktop/hello-world/
user@hostname:~/Desktop/hello-world$ docker-debian-bookworm
sha256:a92e70c3d7346654b34c0442da20ae634901fd25d1a89dd26517e7d1c1d00c47
debian_bookworm@a8ddfa54989f:/work$ ls
hello.c
debian_bookworm@a8ddfa54989f:/work$ arm-linux-gnueabihf-gcc hello.c -o hello
debian_bookworm@a8ddfa54989f:/work$ arm-linux-gnueabihf-strip hello
debian_bookworm@a8ddfa54989f:/work$ file hello
hello: ELF 32-bit LSB pie executable, ARM, EABI5 version 1 (SYSV), dynamically linked, interpreter /lib/ld-linux-armhf.so.3, BuildID[sha1]=ffda981721a1531418ed1da27238707851ae0126, for GNU/Linux 3.2.0, stripped

Debian 11 - Bullseye

Debian 11 - Getting Started

The Debian images apply to the TS-4900, TS-7970, and TS-TPC-7990.

Image Size Kernel config Description
debian-armhf-bullseye-latest.tar.bz2 1346 MB ts4900_defconfig Contains gcc, vim, X11, slim, and will autologin to an xfce4 desktop.

Once installed the default user on either image is "root" with no password.

To prepare an SD card, use partitioning tools such as 'fdisk' 'cfdisk' or 'gparted' in linux to create a single linux partition on the SD card. Once the partition is created and formatted, extract the above tarball with:

# Assuming your SD card is /dev/sdc with one partition
mkfs.ext3 /dev/sdc1
mkdir /mnt/sd/
sudo mount /dev/sdc1 /mnt/sd/
sudo tar --numeric-owner -xjf debian-armhf-bullseye-latest.tar.bz2 -C /mnt/sd
sudo umount /mnt/sd
sync
Note: The ext4 filesystem can be used instead of ext3, but it may require additional options. U-Boot does not support the 64bit addressing added as the default behavior in recent revisions of mkfs.ext4. If using e2fsprogs 1.43 or newer, the options "-O ^64bit,^metadata_csum" must be used with ext4 for proper compatibility. Older versions of e2fsprogs do not need these options passed nor are they needed for ext3.

To rewrite the eMMC the unit must be booted to SD or any other media that is not eMMC. Once booted, run the following commands.:

mkfs.ext3 /dev/mmcblk2p1
mkdir /mnt/emmc
mount /dev/mmcblk2p1 /mnt/emmc
wget -qO- https://files.embeddedTS.com/ts-socket-macrocontrollers/ts-4900-linux/distributions/debian/debian-armhf-bullseye-latest.tar.bz2 | tar xj -C /mnt/emmc/
umount /mnt/emmc
sync

The same commands can be used to write a SATA drive by substituting /dev/mmcblk2p1 with /dev/sda1.

Debian 11 - Networking

The network in Debian is configured /etc/network/interfaces.d/. For complete documentation, see Debian's documentation here

Some common examples are shown below.

DHCP on eth0. Create the file: /etc/network/interfaces.d/eth0

auto eth0
allow-hotplug eth0
iface eth0 inet dhcp

Static IP on eth0. Create the file /etc/network/interfaces.d/eth0

auto eth0
iface eth0 inet static
    address 192.0.2.7/24
    gateway 192.0.2.254

These will take effect on the next boot, or by restarting the networking service:

service networking restart

Debian 11 - WIFI Client

Wireless interfaces are also managed with configuration files in "/etc/network/interfaces.d/". For example, to connect as a client to a WPA network with DHCP. Note some or all of this software may already be installed on the target SBC.

Install wpa_supplicant:

apt-get update && apt-get install wpasupplicant -y

Run:

wpa_passphrase youressid yourpassword

This command will output information similar to:

 network={
 	ssid="youressid"
 	#psk="yourpassword"
 	psk=151790fab3bf3a1751a269618491b54984e192aa19319fc667397d45ec8dee5b
 }

Use the hashed PSK in the specific network interfaces file for added security. Create the file:

/etc/network/interfaces.d/wlan0

allow-hotplug wlan0
iface wlan0 inet dhcp
    wpa-ssid youressid
    wpa-psk 151790fab3bf3a1751a269618491b54984e192aa19319fc667397d45ec8dee5b

To have this take effect immediately:

service networking restart

For more information on configuring Wi-Fi, see Debian's guide here.

Debian 11 - WIFI Access Point

First, hostapd needs to be installed in order to manage the access point on the device:

apt-get update && apt-get install hostapd -y


Note: The install process will start an unconfigured hostapd process. This process must be killed and restarted before a new hostapd.conf will take effect.

Edit /etc/hostapd/hostapd.conf to include the following lines:

interface=wlan0
driver=nl80211
ssid=YourAPName
channel=1
Note: Refer to the kernel's hostapd documentation for more wireless configuration options.


To start the access point launch hostapd:

hostapd /etc/hostapd/hostapd.conf &

This will start up an access point that can be detected by WIFI clients. A DHCP server will likely be desired to assign IP addresses. Refer to Debian's documentation for more details on DHCP configuration.

Debian 11 - Installing New Software

Debian provides the apt-get system which allows management of pre-built applications. The apt tools require a network connection to the internet in order to automatically download and install new software. The update command will download a list of the current versions of pre-built packages.

apt-get update

A common example is installing Java runtime support for a system. Find the package name first with search, and then install it.

root@tsa38x:~# apt-cache search openjdk
default-jdk - Standard Java or Java compatible Development Kit
default-jdk-doc - Standard Java or Java compatible Development Kit (documentation)
default-jdk-headless - Standard Java or Java compatible Development Kit (headless)
default-jre - Standard Java or Java compatible Runtime
default-jre-headless - Standard Java or Java compatible Runtime (headless)
jtreg - Regression Test Harness for the OpenJDK platform
libreoffice - office productivity suite (metapackage)
openjdk-11-dbg - Java runtime based on OpenJDK (debugging symbols)
openjdk-11-demo - Java runtime based on OpenJDK (demos and examples)
openjdk-11-doc - OpenJDK Development Kit (JDK) documentation
openjdk-11-jdk - OpenJDK Development Kit (JDK)
openjdk-11-jdk-headless - OpenJDK Development Kit (JDK) (headless)
openjdk-11-jre - OpenJDK Java runtime, using Hotspot JIT
openjdk-11-jre-headless - OpenJDK Java runtime, using Hotspot JIT (headless)
openjdk-11-jre-zero - Alternative JVM for OpenJDK, using Zero
openjdk-11-source - OpenJDK Development Kit (JDK) source files
uwsgi-app-integration-plugins - plugins for integration of uWSGI and application
uwsgi-plugin-jvm-openjdk-11 - Java plugin for uWSGI (OpenJDK 11)
uwsgi-plugin-jwsgi-openjdk-11 - JWSGI plugin for uWSGI (OpenJDK 11)
uwsgi-plugin-ring-openjdk-11 - Closure/Ring plugin for uWSGI (OpenJDK 11)
uwsgi-plugin-servlet-openjdk-11 - JWSGI plugin for uWSGI (OpenJDK 11)
java-package - Utility for creating Java Debian packages

In this case, the wanted package will likely be the "openjdk-11-jre" package. Names of packages can be found on Debian's wiki pages or the packages site.

With the package name apt-get install can be used to install the prebuilt packages.

apt-get install openjdk-11-jre
# More than one package can be installed at a time.
apt-get install openjdk-11-jre nano vim mplayer

For more information on using apt-get refer to Debian's documentation here.

Debian 11 - Setting up SSH

Openssh is installed in our default Debian image, but by default openssh does not permit root logins, and requires a password to be set. Additionally, a host key is required if one hasn't already been created on the target board. To allow remote root login:

sed --in-place 's/#PermitRootLogin prohibit-password/PermitRootLogin yes/' /etc/ssh/sshd_config
systemctl restart ssh.service
/bin/ls /etc/ssh/ssh_host*key >/dev/null 2>&1  || ssh-keygen -A
passwd root # Set any password

If you ssh to this system it will now support ssh as root.

Debian 11 - Starting Automatically

A systemd service can be created to start up headless applications. Create a file in /etc/systemd/system/yourapp.service

[Unit]
Description=Run an application on startup

[Service]
Type=simple
ExecStart=/usr/local/bin/your_app_or_script

[Install]
WantedBy=multi-user.target

If networking is a dependency add "After=network.target" in the Unit section. Once you have this file in place add it to startup with:

# Start the app on startup, but will not start it now
systemctl enable yourapp.service

# Start the app now, but doesn't change auto startup
systemctl start yourapp.service
Note: See the systemd documentation for in depth documentation on services.

Debian 11 - Cross Compiling

Debian only provides their cross compiler for their distribution. Our examples will set up a Docker for Debian to use for development. If using Debian 11 Bullseye directly, or through a VM then the docker usage can be skipped.

Create a file called "Dockerfile" with these contents:

FROM debian:bullseye

RUN dpkg --add-architecture armhf

RUN apt-get update && apt-get install -y \
    autogen \
    automake \
    bash \
    bc \
    bison \
    build-essential \
    bzip2 \
    ca-certificates \
    ccache \
    chrpath \
    cpio \
    curl \
    diffstat \
    fakeroot \
    file \
    flex \
    gawk \
    gcc-arm-linux-gnueabihf \
    git \
    gzip \
    kmod \
    libgpiod-dev:armhf \
    libncursesw5-dev \
    libssl-dev \
    libtool \
    locales \
    lzop \
    make \
    multistrap \
    ncurses-dev \
    pkg-config \
    python \
    python3 \
    python3-pip \
    python3-pexpect \
    qemu-user-static \
    rsync \
    socat \
    runit \
    texinfo \
    u-boot-tools \
    unzip \
    vim \
    wget \
    xz-utils

# To make a more readable PS1 to show we are in the Docker
ENV debian_chroot debian_bullseye
RUN echo "PS1='\${debian_chroot}\\[\033[01;32m\\]@\\H\[\\033[00m\\]:\\[\\033[01;34m\\]\\w\\[\\033[00m\\]\\$ '" >> /etc/bash.bashrc

# Set up locales.  Needed by yocto.
RUN sed -i -e 's/# en_US.UTF-8 UTF-8/en_US.UTF-8 UTF-8/' /etc/locale.gen && \
        echo 'LANG="en_US.UTF-8"'>/etc/default/locale && \
        dpkg-reconfigure --frontend=noninteractive locales && \
        update-locale LANG=en_US.UTF-8

ENV LC_ALL en_US.UTF-8
ENV LANG en_US.UTF-8
ENV LANGUAGE en_US.UTF-8

In the same directory as the file named "Dockerfile" run:

docker build --tag armhf-bullseye-toolchain .

When this has finished the docker can be used with:

docker run --rm -it --volume $(pwd):/work armhf-bullseye-toolchain bash

This will map the current directory to /work.

At this point the Debian Docker is ready to compile armhf binaries. For example, create a hello world in your home folder at ~/hello.c

#include <stdio.h>
int main(){
    printf("Hello World\n");
}

To compile this enter the docker with:

docker run -it --volume $(pwd):/work armhf-bullseye-toolchain bash
# Then from the docker:
cd /work/
arm-linux-gnueabihf-gcc hello.c -o hello

Check "file hello" to verify the binary type:

debian_bullseye@b720b8ba6c1e:/work# file hello
hello: ELF 32-bit LSB pie executable, ARM, EABI5 version 1 (SYSV), dynamically linked, interpreter /lib/ld-linux-armhf.so.3, BuildID[sha1]=fc6389ca8da310bb5d0b87e5998b59894c078d9f, for GNU/Linux 3.2.0, not stripped

This can also be used to develop against dynamic libraries from Debian. The armhf packages can be installed in the Docker. For example, to link against curl:

# Enter the Docker:
docker run -it --volume $(pwd):/work armhf-bullseye-toolchain bash
cd /work/

apt-get install libcurl4-openssl-dev:armhf
# Download curl's simple.c example
wget https://raw.githubusercontent.com/bagder/curl/master/docs/examples/simple.c
arm-linux-gnueabihf-gcc simple.c -o simple -lcurl

The "simple" binary is now built for armhf and links dynamically to curl.

This will only retain the armhf libcurl package until the docker is exited. To make the changes permanent, add the package to the Dockerfile and rerun:

docker build --tag armhf-bullseye-toolchain .

Debian 10 - Buster

Debian 10 - Getting Started

The Debian images apply to the TS-4900, TS-7970, and TS-TPC-7990.

Image Size Kernel config Description
debian-armhf-buster-latest.tar.bz2 1113 MB ts4900_defconfig Contains gcc, vim, X11, slim, and will autologin to an xfce4 desktop.

Once installed the default user on either image is "root" with no password.

To prepare an SD card, use partitioning tools such as 'fdisk' 'cfdisk' or 'gparted' in linux to create a single linux partition on the SD card. Once the partition is created and formatted, extract the above tarball with:

# Assuming your SD card is /dev/sdc with one partition
mkfs.ext3 /dev/sdc1
mkdir /mnt/sd/
sudo mount /dev/sdc1 /mnt/sd/
sudo tar --numeric-owner -xjf debian-armhf-buster-latest.tar.bz2 -C /mnt/sd
sudo umount /mnt/sd
sync
Note: The ext4 filesystem can be used instead of ext3, but it may require additional options. U-Boot does not support the 64bit addressing added as the default behavior in recent revisions of mkfs.ext4. If using e2fsprogs 1.43 or newer, the options "-O ^64bit,^metadata_csum" must be used with ext4 for proper compatibility. Older versions of e2fsprogs do not need these options passed nor are they needed for ext3.

To rewrite the eMMC the unit must be booted to SD or any other media that is not eMMC. Once booted, run the following commands.:

mkfs.ext3 /dev/mmcblk2p1
mkdir /mnt/emmc
mount /dev/mmcblk2p1 /mnt/emmc
wget -qO- ftp://ftp.embeddedTS.com/ts-socket-macrocontrollers/ts-4900-linux/distributions/debian/debian-armhf-buster-latest.tar.bz2 | tar xj -C /mnt/emmc/
umount /mnt/emmc
sync

The same commands can be used to write a SATA drive by substituting /dev/mmcblk2p1 with /dev/sda1.

Debian 10 - Networking

The network in Debian is configured /etc/network/interfaces.d/. For complete documentation, see Debian's documentation here

Some common examples are shown below.

DHCP on eth0. Create the file: /etc/network/interfaces.d/eth0

auto eth0
allow-hotplug eth0
iface eth0 inet dhcp

Static IP on eth0. Create the file /etc/network/interfaces.d/eth0

auto eth0
iface eth0 inet static
    address 192.0.2.7/24
    gateway 192.0.2.254

These will take effect on the next boot, or by restarting the networking service:

service networking restart

Debian 10 - WIFI Client

Wireless interfaces are also managed with configuration files in "/etc/network/interfaces.d/". For example, to connect as a client to a WPA network with DHCP. Note some or all of this software may already be installed on the target SBC.

Install wpa_supplicant:

apt-get update && apt-get install wpasupplicant -y

Run:

wpa_passphrase youressid yourpassword

This command will output information similar to:

 network={
 	ssid="youressid"
 	#psk="yourpassword"
 	psk=151790fab3bf3a1751a269618491b54984e192aa19319fc667397d45ec8dee5b
 }

Use the hashed PSK in the specific network interfaces file for added security. Create the file:

/etc/network/interfaces.d/wlan0

allow-hotplug wlan0
iface wlan0 inet dhcp
    wpa-ssid youressid
    wpa-psk 151790fab3bf3a1751a269618491b54984e192aa19319fc667397d45ec8dee5b

To have this take effect immediately:

service networking restart

For more information on configuring Wi-Fi, see Debian's guide here.

Debian 10 - WIFI Access Point

First, hostapd needs to be installed in order to manage the access point on the device:

apt-get update && apt-get install hostapd -y


Note: The install process will start an unconfigured hostapd process. This process must be killed and restarted before a new hostapd.conf will take effect.

Edit /etc/hostapd/hostapd.conf to include the following lines:

interface=wlan0
driver=nl80211
ssid=YourAPName
channel=1
Note: Refer to the kernel's hostapd documentation for more wireless configuration options.


To start the access point launch hostapd:

hostapd /etc/hostapd/hostapd.conf &

This will start up an access point that can be detected by WIFI clients. A DHCP server will likely be desired to assign IP addresses. Refer to Debian's documentation for more details on DHCP configuration.

Debian 10 - Installing New Software

Debian provides the apt-get system which allows management of pre-built applications. The apt tools require a network connection to the internet in order to automatically download and install new software. The update command will download a list of the current versions of pre-built packages.

apt-get update

A common example is installing Java runtime support for a system. Find the package name first with search, and then install it.

root@tsa38x:~# apt-cache search openjdk
default-jdk - Standard Java or Java compatible Development Kit
default-jdk-doc - Standard Java or Java compatible Development Kit (documentation)
default-jdk-headless - Standard Java or Java compatible Development Kit (headless)
default-jre - Standard Java or Java compatible Runtime
default-jre-headless - Standard Java or Java compatible Runtime (headless)
jtreg - Regression Test Harness for the OpenJDK platform
libreoffice - office productivity suite (metapackage)
openjdk-11-dbg - Java runtime based on OpenJDK (debugging symbols)
openjdk-11-demo - Java runtime based on OpenJDK (demos and examples)
openjdk-11-doc - OpenJDK Development Kit (JDK) documentation
openjdk-11-jdk - OpenJDK Development Kit (JDK)
openjdk-11-jdk-headless - OpenJDK Development Kit (JDK) (headless)
openjdk-11-jre - OpenJDK Java runtime, using Hotspot JIT
openjdk-11-jre-headless - OpenJDK Java runtime, using Hotspot JIT (headless)
openjdk-11-jre-zero - Alternative JVM for OpenJDK, using Zero
openjdk-11-source - OpenJDK Development Kit (JDK) source files
uwsgi-app-integration-plugins - plugins for integration of uWSGI and application
uwsgi-plugin-jvm-openjdk-11 - Java plugin for uWSGI (OpenJDK 11)
uwsgi-plugin-jwsgi-openjdk-11 - JWSGI plugin for uWSGI (OpenJDK 11)
uwsgi-plugin-ring-openjdk-11 - Closure/Ring plugin for uWSGI (OpenJDK 11)
uwsgi-plugin-servlet-openjdk-11 - JWSGI plugin for uWSGI (OpenJDK 11)
java-package - Utility for creating Java Debian packages

In this case, the wanted package will likely be the "openjdk-11-jre" package. Names of packages can be found on Debian's wiki pages or the packages site.

With the package name apt-get install can be used to install the prebuilt packages.

apt-get install openjdk-11-jre
# More than one package can be installed at a time.
apt-get install openjdk-11-jre nano vim mplayer

For more information on using apt-get refer to Debian's documentation here.

Debian 10 - Setting up SSH

Openssh is installed in our default Debian image, but by default openssh does not permit root logins, and requires a password to be set. Additionally, a host key is required if one hasn't already been created on the target board. To allow remote root login:

sed --in-place 's/#PermitRootLogin prohibit-password/PermitRootLogin yes/' /etc/ssh/sshd_config
systemctl restart ssh.service
/bin/ls /etc/ssh/ssh_host*key >/dev/null 2>&1  || ssh-keygen -A
passwd root # Set any password

If you ssh to this system it will now support ssh as root.

Debian 10 - Starting Automatically

A systemd service can be created to start up headless applications. Create a file in /etc/systemd/system/yourapp.service

[Unit]
Description=Run an application on startup

[Service]
Type=simple
ExecStart=/usr/local/bin/your_app_or_script

[Install]
WantedBy=multi-user.target

If networking is a dependency add "After=network.target" in the Unit section. Once you have this file in place add it to startup with:

# Start the app on startup, but will not start it now
systemctl enable yourapp.service

# Start the app now, but doesn't change auto startup
systemctl start yourapp.service
Note: See the systemd documentation for in depth documentation on services.

Debian 10 - Cross Compiling

Debian only provides their cross compiler for their distribution. Our examples will set up a Docker for Debian to use for development. If using Debian 10 Buster directly, or through a VM then the docker usage can be skipped.

Create a file called "Dockerfile" with these contents:

FROM debian:buster

RUN dpkg --add-architecture armhf

RUN apt-get update && apt-get install -y \
    autogen \
    automake \
    bash \
    bc \
    bison \
    build-essential \
    bzip2 \
    ca-certificates \
    ccache \
    chrpath \
    cpio \
    curl \
    diffstat \
    fakeroot \
    file \
    flex \
    gawk \
    gcc-arm-linux-gnueabihf \
    git \
    gzip \
    kmod \
    libgpiod-dev:armhf \
    libncursesw5-dev \
    libssl-dev \
    libtool \
    locales \
    lzop \
    make \
    multistrap \
    ncurses-dev \
    pkg-config \
    python \
    python3 \
    python3-pip \
    python3-pexpect \
    qemu-user-static \
    rsync \
    socat \
    runit \
    texinfo \
    u-boot-tools \
    unzip \
    vim \
    wget \
    xz-utils

# To make a more readable PS1 to show we are in the Docker
ENV debian_chroot debian_buster
RUN echo "PS1='\${debian_chroot}\\[\033[01;32m\\]@\\H\[\\033[00m\\]:\\[\\033[01;34m\\]\\w\\[\\033[00m\\]\\$ '" >> /etc/bash.bashrc

# Set up locales.  Needed by yocto.
RUN sed -i -e 's/# en_US.UTF-8 UTF-8/en_US.UTF-8 UTF-8/' /etc/locale.gen && \
        echo 'LANG="en_US.UTF-8"'>/etc/default/locale && \
        dpkg-reconfigure --frontend=noninteractive locales && \
        update-locale LANG=en_US.UTF-8

ENV LC_ALL en_US.UTF-8
ENV LANG en_US.UTF-8
ENV LANGUAGE en_US.UTF-8

In the same directory as the file named "Dockerfile" run:

docker build --tag armhf-buster-toolchain .

When this has finished the docker can be used with:

docker run --rm -it --volume $(pwd):/work armhf-buster-toolchain bash

This will map the current directory to /work.

At this point the Debian Docker is ready to compile armhf binaries. For example, create a hello world in your home folder at ~/hello.c

#include <stdio.h>
int main(){
    printf("Hello World\n");
}

To compile this enter the docker with:

docker run -it --volume $(pwd):/work armhf-buster-toolchain bash
# Then from the docker:
cd /work/
arm-linux-gnueabihf-gcc hello.c -o hello

Check "file hello" to verify the binary type:

user@host:~/$ file hello
hello: ELF 32-bit LSB pie executable, ARM, EABI5 version 1 (SYSV), dynamically linked, interpreter /lib/ld-linux-armhf.so.3, for GNU/Linux 3.2.0, BuildID[sha1]=8a8cee3341d3ef76ef6796f72d5722ae9d77c8ea, not stripped

This can also be used to develop against dynamic libraries from Debian. The armhf packages can be installed in the Docker. For example, to link against curl:

# Enter the Docker:
docker run -it --volume $(pwd):/work armhf-buster-toolchain bash
cd /work/

apt-get install libcurl4-openssl-dev:armhf
# Download curl's simple.c example
wget https://raw.githubusercontent.com/bagder/curl/master/docs/examples/simple.c
arm-linux-gnueabihf-gcc simple.c -o simple -lcurl

The "simple" binary is now built for armhf and links dynamically to curl.

This will only retain the armhf libcurl package until the docker is exited. To make the changes permanent, add the package to the Dockerfile and rerun:

docker build --tag armhf-buster-toolchain .

Debian 9 - Stretch

Debian 9 - Getting Started

We provide two images for Debian Stretch which apply to our TS-4900, TS-7970, and TS-TPC-7990. If you are unsure which image to pick, use the larger image which contains more development tools and drivers.

Image Size Kernel config Description
debian-armhf-stretch-latest.tar.bz2 1279MB ts4900_defconfig Contains gcc, vim, X11, slim, and will autologin to an xfce4 desktop.
debian-armhf-stretch-minimal-latest.tar.bz2 184MB ts4900_tiny_defconfig Stripped down Debian containing bare minimal hardware support, very limited peripheral support, and only the core debian packages.

Once installed the default user on either image is "root" with no password.

To prepare an SD card, use partitioning tools such as 'fdisk' 'cfdisk' or 'gparted' in linux to create a single linux partition on the SD card. Once the partition is created and formatted, extract the above tarball with:

# Assuming your SD card is /dev/sdc with one partition
mkfs.ext3 /dev/sdc1
mkdir /mnt/sd/
sudo mount /dev/sdc1 /mnt/sd/
sudo tar --numeric-owner -xjf debian-armhf-stretch-latest.tar.bz2 -C /mnt/sd
sudo umount /mnt/sd
sync
Note: The ext4 filesystem can be used instead of ext3, but it may require additional options. U-Boot does not support the 64bit addressing added as the default behavior in recent revisions of mkfs.ext4. If using e2fsprogs 1.43 or newer, the options "-O ^64bit,^metadata_csum" must be used with ext4 for proper compatibility. Older versions of e2fsprogs do not need these options passed nor are they needed for ext3.

To rewrite the eMMC the unit must be booted to SD or any other media that is not eMMC. Once booted, run the following commands.:

mkfs.ext3 /dev/mmcblk2p1
mkdir /mnt/emmc
mount /dev/mmcblk2p1 /mnt/emmc
wget -qO- ftp://ftp.embeddedTS.com/ts-socket-macrocontrollers/ts-4900-linux/distributions/debian/debian-armhf-stretch-latest.tar.bz2 | tar xj -C /mnt/emmc/
umount /mnt/emmc
sync


The same commands can be used to write a SATA drive by substituting /dev/mmcblk2p1 with /dev/sda1.

Debian 9 - Networking

Debian can automatically set up the networking based on the contents of "/etc/network/interfaces.d/" files. For example, to enable DHCP for "eth0" by default on startup:

echo "auto eth0
iface eth0 inet dhcp" > /etc/network/interfaces.d/eth0

To set up a static IP:

echo "auto eth0
iface eth0 inet static
    address 192.168.0.50
    netmask 255.255.255.0
    gateway 192.168.0.1" > /etc/network/interfaces.d/eth0
echo "nameserver 1.1.1.1" > /etc/resolv.conf

To make this take effect immediately for either option:

service networking restart

To configure other interfaces, replace "eth0" with the other network device name. Some interfaces may use predictable interface names. For example, the traditional name for an ethernet port might be "eth1", but some devices may use "enp1s0" for PCIe, or "enx00D069C0FFEE" (the MAC address appended) for USB ethernet interfaces. Run 'ifconfig -a' or 'ip a' to get a complete list of interfaces, including the ones that are not configured.

Debian 9 - WIFI Client

Wireless interfaces are also managed with configuration files in "/etc/network/interfaces.d/". For example, to connect as a client to a WPA network with DHCP. Note some or all of this software may already be installed on the target SBC.

Install wpa_supplicant:

apt-get update && apt-get install wpasupplicant -y

Run:

wpa_passphrase youressid yourpassword

This command will output information similar to:

 network={
 	ssid="youressid"
 	#psk="yourpassword"
 	psk=151790fab3bf3a1751a269618491b54984e192aa19319fc667397d45ec8dee5b
 }

Use the hashed PSK in the specific network interfaces file for added security. Create the file:

/etc/network/interfaces.d/wlan0

allow-hotplug wlan0
iface wlan0 inet dhcp
    wpa-ssid youressid
    wpa-psk 151790fab3bf3a1751a269618491b54984e192aa19319fc667397d45ec8dee5b

To have this take effect immediately:

service networking restart

For more information on configuring Wi-Fi, see Debian's guide here.

Debian 9 - WIFI Access Point

First, hostapd needs to be installed in order to manage the access point on the device:

apt-get update && apt-get install hostapd -y


Note: The install process will start an unconfigured hostapd process. This process must be killed and restarted before a new hostapd.conf will take effect.

Edit /etc/hostapd/hostapd.conf to include the following lines:

interface=wlan0
driver=nl80211
ssid=YourAPName
channel=1
Note: Refer to the kernel's hostapd documentation for more wireless configuration options.


To start the access point launch hostapd:

hostapd /etc/hostapd/hostapd.conf &

This will start up an access point that can be detected by WIFI clients. A DHCP server will likely be desired to assign IP addresses. Refer to Debian's documentation for more details on DHCP configuration.

Debian 9 - Application Development

Debian 9 - Stretch Cross Compiling

Debian Stretch provides cross compilers from the Debian apt repository archive for Debian Stretch. An install on a workstation can build for the same release on other architectures. A Linux desktop or laptop PC, virtual machine, or chroot will need to be used for this. Debian Stretch for a workstation can be downloaded from here.

From a Debian workstation (not the target), run these commands to set up the cross compiler:

# Run "lsb_release -a" and verify Debian 9.X is returned.  These instructions are not
# expected to work on any other version or distribution.
su root
# Not needed for the immediate apt-get install, but used
# so we can install package:armhf for cross compiling
dpkg --add-architecture armhf
apt-get update
apt-get install curl build-essential crossbuild-essential-armhf -y

This will install a toolchain that can be used with the prefix "arm-linux-gnueabihf-". The standard GCC tools will start with that name, eg "arm-linux-gnueabihf-gcc".

The toolchain can now compile a simple hello world application. Create hello-world.c on the Debian workstation:

#include <stdio.h>
int main(){
    printf("Hello World\n");
}

To compile this:

arm-linux-gnueabihf-gcc hello-world.c -o hello-world
file hello-world

This will return that the binary created is for ARM. Copy this to the target platform to run it there.

Debian Stretch supports multiarch which can install packages designed for other architectures. On workstations this is how 32-bit and 64-bit support is provided. This can also be used to install armhf packages on an x86 based workstation.

This cross compile environment can link to a shared library from the Debian root. The package would be installed in Debian on the workstation to provide headers and libraries. This is included in most "-dev" packages. When run on the arm target it will also need a copy of the library installed, but it does not need the -dev package.

apt-get install libcurl4-openssl-dev:armhf

# Download the simple.c example from curl:
wget https://raw.githubusercontent.com/bagder/curl/master/docs/examples/simple.c
# After installing the supporting library, curl will link as compiling on the unit.
arm-linux-gnueabihf-gcc simple.c -o simple -lcurl

Copy the binary to the target platform and run on the target. This can be accomplished with network protocols like NFS, SCP, FTP, etc.

If any created binaries do not rely on hardware support like GPIO or CAN, they can be run using 'qemu'.

# using the hello world example from before:
./hello-world
# Returns Exec format error
apt-get install qemu-user-static
./hello-world

Debian 9 - Installing New Software

Debian provides the apt-get system which allows management of pre-built applications. The apt tools require a network connection to the internet in order to automatically download and install new software. The update command will download a list of the current versions of pre-built packages.

apt-get update

A common example is installing Java runtime support for a system. Find the package name first with search, and then install it.

root@ts:~# apt-cache search openjdk
default-jdk - Standard Java or Java compatible Development Kit
default-jdk-doc - Standard Java or Java compatible Development Kit (documentation)
default-jdk-headless - Standard Java or Java compatible Development Kit (headless)
default-jre - Standard Java or Java compatible Runtime
default-jre-headless - Standard Java or Java compatible Runtime (headless)
jtreg - Regression Test Harness for the OpenJDK platform
libreoffice - office productivity suite (metapackage)
openjdk-8-dbg - Java runtime based on OpenJDK (debugging symbols)
openjdk-8-demo - Java runtime based on OpenJDK (demos and examples)
openjdk-8-doc - OpenJDK Development Kit (JDK) documentation
openjdk-8-jdk - OpenJDK Development Kit (JDK)
openjdk-8-jdk-headless - OpenJDK Development Kit (JDK) (headless)
openjdk-8-jre - OpenJDK Java runtime, using Hotspot JIT
openjdk-8-jre-headless - OpenJDK Java runtime, using Hotspot JIT (headless)
openjdk-8-jre-zero - Alternative JVM for OpenJDK, using Zero/Shark
openjdk-8-source - OpenJDK Development Kit (JDK) source files
uwsgi-app-integration-plugins - plugins for integration of uWSGI and application
uwsgi-plugin-jvm-openjdk-8 - Java plugin for uWSGI (OpenJDK 8)
uwsgi-plugin-jwsgi-openjdk-8 - JWSGI plugin for uWSGI (OpenJDK 8)
uwsgi-plugin-ring-openjdk-8 - Closure/Ring plugin for uWSGI (OpenJDK 8)
uwsgi-plugin-servlet-openjdk-8 - JWSGI plugin for uWSGI (OpenJDK 8)
java-package - Utility for creating Java Debian packages

In this case, the wanted package will likely be the "openjdk-8-jre" package. Names of packages can be found on Debian's wiki pages or the packages site.

With the package name apt-get install can be used to install the prebuilt packages.

apt-get install openjdk-8-jre
# More than one package can be installed at a time.
apt-get install openjdk-8-jre nano vim mplayer

For more information on using apt-get refer to Debian's documentation here.

Debian 9 - Setting up SSH

To install the SSH server, install the package with apt-get:

apt-get install openssh-server


Debian Stretch by default disallows logins directly from the user "root". Additionally, SSH will not allow remote connections without a password or valid SSH key pair. This means in order to SSH to the device, a user account must first be created, and a password set:

useradd --create-home --shell /bin/bash newuser
passwd newuser


After this setup it is now possible to connect to the device as user "newuser" from a remote PC supporting SSH. On Linux/OS X this is the "ssh" command, or from Windows using a client such as PuTTY.

Debian 9 - Starting Automatically

A systemd service can be created to start up headless applications. Create a file in /etc/systemd/system/yourapp.service

[Unit]
Description=Run an application on startup

[Service]
Type=simple
ExecStart=/usr/local/bin/your_app_or_script

[Install]
WantedBy=multi-user.target

If networking is a dependency add "After=network.target" in the Unit section. Once you have this file in place add it to startup with:

# Start the app on startup, but will not start it now
systemctl enable yourapp.service

# Start the app now, but doesn't change auto startup
systemctl start yourapp.service
Note: See the systemd documentation for in depth documentation on services.

To start an application on bootup with X11 instead change the x-session-manager. By default the system starts xfce:

root@ts:~# ls -lah /usr/bin/x-session-manager 
lrwxrwxrwx 1 root root 35 May 26  2015 /usr/bin/x-session-manager -> /etc/alternatives/x-session-manager
root@ts:~# ls -lah /etc/alternatives/x-session-manager
lrwxrwxrwx 1 root root 19 May 26  2015 /etc/alternatives/x-session-manager -> /usr/bin/startxfce4

The x-session can be modified to only start specified processes. Create the file /usr/bin/mini-x-session with these contents:

#!/bin/bash
matchbox-window-manager -use_titlebar no &

exec xfce4-terminal

You may need to "apt-get install matchbox-window-manager." first. This is a tiny window manager which also has a few flags that simplify embedded use. Now enable this session manager and restart slim to restart x11 and show it now.

chmod a+x /usr/bin/mini-x-session
rm /etc/alternatives/x-session-manager
ln -s /usr/bin/mini-x-session /etc/alternatives/x-session-manager
service slim restart

If the x-session-manager process ever closes x11 will restart. The exec command allows a new process to take over the existing PID. In the above example xfce4-terminal takes over the PID of x-session-manager. If the terminal is closed with commands like exit the slim/x11 processes will restart.

Debian 8 - Jessie

Debian 8 - Getting Started

Once installed, the default user is "root" with no password.

Note: This is a shared image that supports the TS-4900, TS-7970, and TS-TPC-7990.


To prepare an SD card, use partitioning tools such as 'fdisk' 'cfdisk' or 'gparted' in linux to create a single linux partition on the SD card. Once the partition is set up and formatted, extract the above tarball with:

# Assuming your SD card is /dev/sdc with one partition
mkfs.ext3 /dev/sdc1
mkdir /mnt/sd/
sudo mount /dev/sdc1 /mnt/sd/
sudo tar --numeric-owner -xjf debian-armhf-jessie-latest.tar.bz2 -C /mnt/sd
sudo umount /mnt/sd
sync
Note: The ext4 filesystem can be used instead of ext3, but it may require additional options. U-Boot does not support the 64bit addressing added as the default behavior in recent revisions of mkfs.ext4. If using e2fsprogs 1.43 or newer, the options "-O ^64bit,^metadata_csum" must be used with ext4 for proper compatibility. Older versions of e2fsprogs do not need these options passed nor are they needed for ext3.

To rewrite the eMMC the unit must be booted to SD or any other media that is not eMMC. Once booted, run the following commands.:

mkfs.ext3 /dev/mmcblk2p1
mkdir /mnt/emmc
mount /dev/mmcblk2p1 /mnt/emmc
wget -qO- https://files.embeddedTS.com/ts-socket-macrocontrollers/ts-4900-linux/distributions/debian/debian-armhf-jessie-latest.tar.bz2 | tar xj -C /mnt/emmc/
umount /mnt/emmc
sync


The same commands can be used to write a SATA drive by substituting /dev/mmcblk2p1 with /dev/sda1.

Debian 8 - Networking

From almost any Linux system you can use 'ip' command or the 'ifconfig' and 'route' commands to initially set up the network.

# Bring up the CPU network interface
ifconfig eth0 up

# Or if you're on a baseboard with a second ethernet port, you can use that as:
ifconfig eth1 up

# Set an ip address (assumes 255.255.255.0 subnet mask)
ifconfig eth0 192.168.0.50

# Set a specific subnet
ifconfig eth0 192.168.0.50 netmask 255.255.0.0

# Configure your route.  This is the server that provides your internet connection.
route add default gw 192.168.0.1

# Edit /etc/resolv.conf for your DNS server
echo "nameserver 192.168.0.1" > /etc/resolv.conf

Most networks will offer a DHCP server, an IP address can be obtained from a server with a single command in linux:

Configure DHCP in Debian:

# To setup the default CPU ethernet port
dhclient eth0
# Or if you're on a baseboard with a second ethernet port, you can use that as:
dhclient eth1
# You can configure all ethernet ports for a dhcp response with
dhclient


Systemd provides a networking configuration option to allow for automatic configuration on startup. Systemd-networkd has a number of different configuration files, some of the default examples and setup steps are outlined below.

/etc/systemd/network/eth.network

[Match]
Name=eth*

[Network]
DHCP=yes

To use DHCP to configure DNS via systemd, start and enable the network name resolver service, systemd-resolved:

systemctl start systemd-resolved.service 
systemctl enable systemd-resolved.service
ln -s /run/systemd/resolve/resolv.conf /etc/resolv.conf


For a static config create a network configuration for that specific interface.

/etc/systemd/network/eth0.network

[Match]
Name=eth0

[Network]
Address=192.168.0.50/24
Gateway=192.168.0.1
DNS=192.168.0.1

For more information on networking, see Debian and systemd's documentation:

Debian 8 - WIFI Client

If connecting to a WPA/WPA2 network, a wpa_supplicant config file must first be created:

wpa_passphrase yournetwork yournetworkpassphrase > /etc/wpa_supplicant/wpa_supplicant-wlan0.conf


Create the file /lib/systemd/system/wpa_supplicant@.service with these contents

[Unit]
Description=WPA supplicant daemon (interface-specific version)
Requires=sys-subsystem-net-devices-%i.device
After=sys-subsystem-net-devices-%i.device

[Service]
Type=simple
ExecStart=/sbin/wpa_supplicant -c/etc/wpa_supplicant/wpa_supplicant-%I.conf -i%I

[Install]
Alias=multi-user.target.wants/wpa_supplicant@%i.service


Create the file /etc/systemd/network/wlan0.network with:

[Match]
Name=wlan0

[Network]
DHCP=yes

See the systemctl-networkd example for setting a static IP for a network interface. The wlan0.network can be configured the same way as an eth.network.


To enable all of the changes that have been made, run the following commands:

systemctl enable wpa_supplicant@wlan0
systemctl start wpa_supplicant@wlan0
systemctl restart systemd-networkd

Debian 8 - WIFI Access Point

First, hostapd needs to be installed in order to manage the access point on the device:

apt-get update && apt-get install hostapd -y


Note: The install process will start an unconfigured hostapd process. This process must be killed and restarted before a new hostapd.conf will take effect.

Edit /etc/hostapd/hostapd.conf to include the following lines:

interface=wlan0
driver=nl80211
ssid=YourAPName
channel=1
Note: Refer to the kernel's hostapd documentation for more wireless configuration options.


To start the access point launch hostapd:

hostapd /etc/hostapd/hostapd.conf &

This will start up an access point that can be detected by WIFI clients. A DHCP server will likely be desired to assign IP addresses. Refer to Debian's documentation for more details on DHCP configuration.

Debian 8 - Application Development

Debian 8 - Jessie Cross Compiling

Debian Jessie previously provided cross compilers via the Emdebian project. However, Emdebian has been unmaintained for a number of years and is no longer able to provide a viable install package. In order to cross compile from a Debian Jessie workstation, a third party cross compiler is required.

A Debian Jessie install on a workstation has the ability to build for the same release on other architectures using Debian binary libraries. A PC, virtual machine, or chroot will need to be used for this. Install Debian Jessie for your workstation here.

From a Debian workstation (not the target), run the following commands to set up the cross compiler. Note that this expects a 64-bit Debian Jessie install on the workstation. 32-bit installations are not supported at this time.

# Run "lsb_release -a" and verify Debian 8.X is returned.  These instructions are not
# expected to work on any other version or distribution.

cd ~
wget http://ftp.embeddedTS.com/ftp/ts-arm-sbc/ts-7553-V2-linux/cross-toolchains/gcc-linaro-4.9-2016.02-x86_64_arm-linux-gnueabihf.tar.xz
# The above toolchain is from Linaro. Other cross compilers can be used but have not been tested.
mkdir cross_compiler
tar xvf gcc-linaro-4.9-2016.02-x86_64_arm-linux-gnueabihf.tar.xz -C ~/cross_compiler
export PATH=$PATH:~/cross_compiler/gcc-linaro-4.9-2016.02-x86_64_arm-linux-gnueabihf/bin/
# The 'export' command needs to be run every time the user logs in. It is possible to add this command to the user's ".bashrc" file
# in their home directory to ensure it is automatically run every time the user is logged in.
su root
dpkg --add-architecture armhf
apt-get update
apt-get install build-essential

This will install a toolchain that can be used with the prefix "arm-linux-gnueabihf-". The standard GCC tools will start with that name, eg "arm-linux-gnueabihf-gcc".

The toolchain can now compile a simple hello world application. Create hello-world.c on the Debian workstation:

#include <stdio.h>
int main(){
    printf("Hello World\n");
}

To compile this:

arm-linux-gnueabihf-gcc hello-world.c -o hello-world
file hello-world

This will return that the binary created is for ARM. Copy this to the target platform to run it there.

Debian Jessie supports multiarch which can install packages designed for other architectures. On workstations this is how 32-bit and 64-bit support is provided. This can also be used to install armhf packages on an x86 based workstation.

This cross compile environment can link to a shared library from the Debian root. The package would be installed in Debian on the workstation to provide headers and ".so" files. This is included in most "-dev" packages. When run on the arm target it will also need a copy of the library installed, but it does not need the -dev package. Note that since the cross compiler used is 3rd party and not directly from Debian, some compile commands that include libraries will need additional arguments to tell the compiler and linker where on the workstation to find the necessary headers and libraries. Usually, the additional arguments will look like the following string, however adjustments may need to be made depending on the application.

 -I/usr/include -L/usr/lib/arm-linux-gnueabihf -L/lib/arm-linux-gnueabihf -Wl,-rpath=/usr/lib/arm-linux-gnueabihf,-rpath=/lib/arm-linux-gnueabihf


apt-get install libcurl4-openssl-dev:armhf

# Download the simple.c example from curl:
wget https://raw.githubusercontent.com/bagder/curl/master/docs/examples/simple.c
# After installing the supporting library, curl will link as compiling on the unit.
arm-linux-gnueabihf-gcc -I/usr/include -L/usr/lib/arm-linux-gnueabihf -L/lib/arm-linux-gnueabihf -Wl,-rpath=/usr/lib/arm-linux-gnueabihf,-rpath=/lib/arm-linux-gnueabihf simple.c -o simple -lcurl

Copy the binary to the target platform and run on the target. This can be accomplished with network protocols like NFS, SCP, FTP, etc.

If any created binaries do not rely on hardware support like GPIO or CAN, they can be run using qemu.

# using the hello world example from before:
./hello-world
# Returns Exec format error
apt-get install qemu-user-static
./hello-world

Debian 8 - Installing New Software

Debian provides the apt-get system which allows management of pre-built applications. The apt tools require a network connection to the internet in order to automatically download and install new software. The update command will download a list of the current versions of pre-built packages.

Older Debian releases are moved to a different server to indicate it is no longer getting security updates. To download packages for these older distributions, edit /etc/apt/sources.list to only have the following lines:

Jessie:

deb http://archive.debian.org/debian/ jessie main
deb-src http://archive.debian.org/debian/ jessie main

Wheezy:

deb http://archive.debian.org/debian/ wheezy main
deb-src http://archive.debian.org/debian/ wheezy main

After modifying that file, be sure to update the package list:

apt-get update

A common example is installing Java runtime support for a system. Find the package name first with search, and then install it.

root@ts:~# apt-cache search openjdk
jvm-7-avian-jre - lightweight virtual machine using the OpenJDK class library
freemind - Java Program for creating and viewing Mindmaps
icedtea-7-plugin - web browser plugin based on OpenJDK and IcedTea to execute Java applets
default-jdk - Standard Java or Java compatible Development Kit
default-jdk-doc - Standard Java or Java compatible Development Kit (documentation)
default-jre - Standard Java or Java compatible Runtime
default-jre-headless - Standard Java or Java compatible Runtime (headless)
jtreg - Regression Test Harness for the OpenJDK platform
libreoffice - office productivity suite (metapackage)
icedtea-7-jre-jamvm - Alternative JVM for OpenJDK, using JamVM
openjdk-7-dbg - Java runtime based on OpenJDK (debugging symbols)
openjdk-7-demo - Java runtime based on OpenJDK (demos and examples)
openjdk-7-doc - OpenJDK Development Kit (JDK) documentation
openjdk-7-jdk - OpenJDK Development Kit (JDK)
openjdk-7-jre - OpenJDK Java runtime, using Hotspot Zero
openjdk-7-jre-headless - OpenJDK Java runtime, using Hotspot Zero (headless)
openjdk-7-jre-lib - OpenJDK Java runtime (architecture independent libraries)
openjdk-7-source - OpenJDK Development Kit (JDK) source files
uwsgi-app-integration-plugins - plugins for integration of uWSGI and application
uwsgi-plugin-jvm-openjdk-7 - Java plugin for uWSGI (OpenJDK 7)
uwsgi-plugin-jwsgi-openjdk-7 - JWSGI plugin for uWSGI (OpenJDK 7)
                                                       

In this case you will want the openjdk-7-jre package. Names of packages are on Debian's wiki or the packages site.

With the package name apt-get install can be used to install the prebuilt packages.

apt-get install openjdk-7-jre
# More than one package can be installed at a time.
apt-get install openjdk-7-jre nano vim mplayer

For more information on using apt-get refer to Debian's documentation here.

Debian 8 - Setting up SSH

To install ssh, install the package as normal with apt-get:

apt-get install openssh-server


Make sure the device is configured on the network and set a password for the remote user. SSH will not allow remote connections without a password or a valid SSH key pair.

passwd root
Note: The default OpenSSH server will not permit root to login via SSH as a security precaution. To allow root to log in via ssh anyway, edit the /etc/ssh/sshd_config file and add the line PermitRootLogin yes in the authentication section. This change will take effect after reboot or after sshd service restart.

After this setup it is now possible to connect from a remote PC supporting SSH. On Linux/OS X this is the "ssh" command, or from Windows using a client such as PuTTY.

Note: If a DNS server is not present on the target network, it is possible to save time at login by adding "UseDNS no" in /etc/ssh/sshd_config.

Debian 8 - Starting Automatically

A systemd service can be created to start up headless applications. Create a file in /etc/systemd/system/yourapp.service

[Unit]
Description=Run an application on startup

[Service]
Type=simple
ExecStart=/usr/local/bin/your_app_or_script

[Install]
WantedBy=multi-user.target

If networking is a dependency add "After=network.target" in the Unit section. Once you have this file in place add it to startup with:

# Start the app on startup, but will not start it now
systemctl enable yourapp.service

# Start the app now, but doesn't change auto startup
systemctl start yourapp.service
Note: See the systemd documentation for in depth documentation on services.

To start an application on bootup with X11 instead change the x-session-manager. By default the system starts xfce:

root@ts:~# ls -lah /usr/bin/x-session-manager 
lrwxrwxrwx 1 root root 35 May 26  2015 /usr/bin/x-session-manager -> /etc/alternatives/x-session-manager
root@ts:~# ls -lah /etc/alternatives/x-session-manager
lrwxrwxrwx 1 root root 19 May 26  2015 /etc/alternatives/x-session-manager -> /usr/bin/startxfce4

The x-session can be modified to only start specified processes. Create the file /usr/bin/mini-x-session with these contents:

#!/bin/bash
matchbox-window-manager -use_titlebar no &

exec xfce4-terminal

You may need to "apt-get install matchbox-window-manager." first. This is a tiny window manager which also has a few flags that simplify embedded use. Now enable this session manager and restart slim to restart x11 and show it now.

chmod a+x /usr/bin/mini-x-session
rm /etc/alternatives/x-session-manager
ln -s /usr/bin/mini-x-session /etc/alternatives/x-session-manager
service slim restart

If the x-session-manager process ever closes x11 will restart. The exec command allows a new process to take over the existing PID. In the above example xfce4-terminal takes over the PID of x-session-manager. If the terminal is closed with commands like exit the slim/x11 processes will restart.

Ubuntu

Ubuntu is a distribution provided by Canonical which is based on Debian. Ubuntu often has more recent packages but follows a shorter release cycle. The image we provide is based on Ubuntu. We use the root filesystem, but the kernel is not provided by Ubuntu or in any way associated with Canonical.

This image includes support for the TS-4900, TS-7970, and TS-TPC-7990.

Ubuntu 23.04 - Lunar

Ubuntu 23.04 - Getting Started

This Ubuntu release is available in 3 flavors with various packages.

Image Estimated Size Description
ubuntu-armhf-23.04-x11-latest.tar.bz2 1151 MiB
  • Includes 5.10 kernel with tsimx6_defconfig that includes broad driver support
  • Base Ubuntu with common utils
  • Common embedded tools (i2c, can, gpio, iio, serial tools, etc)
  • Includes hardware support
  • Networking tools (ethernet, wifi, bluetooth)
  • Includes Development tools
  • Includes X11 that launches matchbox and xterm on startup
  • Includes touchscreen support
ubuntu-armhf-23.04-headless-latest.tar.bz2 929 MiB
  • Includes 5.10 kernel with tsimx6_defconfig that includes broad driver support
  • Base Ubuntu with common utils
  • Common embedded tools (i2c, can, gpio, iio, serial tools, etc)
  • Includes hardware support
  • Networking tools (ethernet, wifi, bluetooth)
  • Includes Development tools
ubuntu-armhf-23.04-minimal-latest.tar.bz2 198 MiB
  • Includes 5.10 kernel with tsimx6_minimal_defconfig that includes bare minimum driver support and kernel options required by Ubuntu.
  • Includes base Ubuntu rootfs adding only what is required for Ethernet support.

The default login is "user/user" which includes sudo permissions.

To write this to an SD card, first partition the SD card to have one large ext3, or ext4 partition. See the guide here for more information. Once it is formatted, extract this tar with:

# Assuming your SD card is /dev/sdc with one partition
mkfs.ext3 /dev/sdc1
mkdir /mnt/sd/
sudo mount /dev/sdc1 /mnt/sd/
sudo tar --numeric-owner -xjf ubuntu-armhf-23.04-latest.tar.bz2 -C /mnt/sd
sudo umount /mnt/sd
sync

To rewrite the eMMC, boot to the SD card. You cannot rewrite the emmc while it is mounted elsewhere, or used to currently boot the system. Once booted to the SD, run:

mkfs.ext3 /dev/mmcblk2p1
mkdir /mnt/emmc
mount /dev/mmcblk2p1 /mnt/emmc
wget -qO- https://files.embeddedTS.com/ts-socket-macrocontrollers/ts-4900-linux/distributions/ubuntu/ubuntu-armhf-23.04-x11-latest.tar.bz2 | tar --numeric-owner -xj -C /mnt/emmc/
umount /mnt/emmc
sync


Note: The ext4 filesystem can be used instead of ext3, but it may require additional options. U-Boot does not support the 64bit addressing added as the default behavior in recent revisions of mkfs.ext4. If using e2fsprogs 1.43 or newer, the options "-O ^64bit,^metadata_csum" must be used with ext4 for proper compatibility. Older versions of e2fsprogs do not need these options passed nor are they needed for ext3.

Ubuntu 23.04 - Networking

The network in Ubuntu is configured netplan. For complete documentation, see Netplan's documentation here

Some common examples are shown below. On this release network interfaces follow the predictible network interface names. Run ip addr show to get a list of the network interfaces.

Most commonly:

  • end0 - Ethernet device 0 (CPU Ethernet)
  • enp1s0 - Ethernet PCIe port 1 slot 0 ethernet
  • usb<mac> - USB ethernet
  • wlan0 - WIFI

DHCP on end0. Edit the file /etc/netplan/ethernet.yaml and add:

network:
  version: 2
  renderer: networkd
  ethernets:
    end0:
      dhcp4: true
      dhcp6: true

Static IP on end0. Edit the file /etc/netplan/ethernet.yaml and add:

network:
  version: 2
  renderer: networkd
  ethernets:
    end0:
     dhcp4: no
     addresses: [192.168.0.50/24]
     gateway4: 192.168.0.1
     nameservers:
       addresses: [8.8.8.8,8.8.4.4]

After creating the yaml file, set the appropriate permissions and apply the netplan:

sudo chmod 600 /etc/netplan/*.yaml
sudo netplan apply

Ubuntu 23.04 - WIFI Client

Wireless configuration under Ubuntu, similar to Ethernet, also uses netplan for configuration. For example, create /etc/netplan/wifi.yaml:

network:
  version: 2
  renderer: networkd
  wifis:
    wlan0:
      dhcp4: yes
      dhcp6: yes
      access-points:
        "yourssid":
          password: yourpassphrase"

After creating the yaml file, set the appropriate permissions and apply the netplan:

sudo chmod 600 /etc/netplan/*.yaml
sudo netplan apply

Ubuntu 23.04 - WIFI Access Point

First, hostapd needs to be installed in order to manage the access point on the device:

apt-get update && apt-get install hostapd -y


Note: The install process will start an unconfigured hostapd process. This process must be killed and restarted before a new hostapd.conf will take effect.

Edit /etc/hostapd/hostapd.conf to include the following lines:

interface=wlan0
driver=nl80211
ssid=YourAPName
channel=1
Note: Refer to the kernel's hostapd documentation for more wireless configuration options.


To start the access point launch hostapd:

hostapd /etc/hostapd/hostapd.conf &

This will start up an access point that can be detected by WIFI clients. A DHCP server will likely be desired to assign IP addresses. Refer to Debian's documentation for more details on DHCP configuration.

Ubuntu 23.04 - Installing New Software

Ubuntu provides the apt-get system which lets you manage pre-built applications. Before you do this you need to update Ubuntu's list of package versions and locations. This assumes you have a valid network connection to the internet.

apt-get update

For example, lets say you wanted to install openjdk for Java support. You can use the apt-cache command to search the local cache of Debian's packages.

root@ts-imx6:~# apt-cache search openjdk
jvm-7-avian-jre - lightweight virtual machine using the OpenJDK class library
freemind - Java Program for creating and viewing Mindmaps
icedtea-7-plugin - web browser plugin based on OpenJDK and IcedTea to execute Java applets
default-jdk - Standard Java or Java compatible Development Kit
default-jdk-doc - Standard Java or Java compatible Development Kit (documentation)
default-jre - Standard Java or Java compatible Runtime
default-jre-headless - Standard Java or Java compatible Runtime (headless)
jtreg - Regression Test Harness for the OpenJDK platform
libreoffice - office productivity suite (metapackage)
icedtea-7-jre-jamvm - Alternative JVM for OpenJDK, using JamVM
openjdk-7-dbg - Java runtime based on OpenJDK (debugging symbols)
openjdk-7-demo - Java runtime based on OpenJDK (demos and examples)
openjdk-7-doc - OpenJDK Development Kit (JDK) documentation
openjdk-7-jdk - OpenJDK Development Kit (JDK)
openjdk-7-jre - OpenJDK Java runtime, using Hotspot Zero
openjdk-7-jre-headless - OpenJDK Java runtime, using Hotspot Zero (headless)
openjdk-7-jre-lib - OpenJDK Java runtime (architecture independent libraries)
openjdk-7-source - OpenJDK Development Kit (JDK) source files
uwsgi-app-integration-plugins - plugins for integration of uWSGI and application
uwsgi-plugin-jvm-openjdk-7 - Java plugin for uWSGI (OpenJDK 7)
uwsgi-plugin-jwsgi-openjdk-7 - JWSGI plugin for uWSGI (OpenJDK 7)                                              

In this case you will likely want openjdk-7-jre to provide a runtime environment, and possibly openjdk-7-jdk to provide a development environment.

Once you have the package name you can use apt-get to install the package and any dependencies. This assumes you have a network connection to the internet.

apt-get install openjdk-7-jre
# You can also chain packages to be installed
apt-get install openjdk-7-jre nano vim mplayer

For more information on using apt-get refer to Ubuntu's documentation here.

Ubuntu 23.04 - Setting up SSH

To install ssh, install the package as normal with apt-get:

apt-get install openssh-server


Make sure the device is configured on the network and set a password for the remote user. SSH will not allow remote connections without a password or a valid SSH key pair.

passwd root
Note: The default OpenSSH server will not permit root to login via SSH as a security precaution. To allow root to log in via ssh anyway, edit the /etc/ssh/sshd_config file and add the line PermitRootLogin yes in the authentication section. This change will take effect after reboot or after sshd service restart.

After this setup it is now possible to connect from a remote PC supporting SSH. On Linux/OS X this is the "ssh" command, or from Windows using a client such as PuTTY.

Note: If a DNS server is not present on the target network, it is possible to save time at login by adding "UseDNS no" in /etc/ssh/sshd_config.

Ubuntu 23.04 - Starting Automatically

A systemd service can be created to start up headless applications. Create a file in /etc/systemd/system/yourapp.service

[Unit]
Description=Run an application on startup

[Service]
Type=simple
ExecStart=/usr/local/bin/your_app_or_script

[Install]
WantedBy=multi-user.target

If networking is a dependency add "After=network.target" in the Unit section. Once you have this file in place add it to startup with:

# Start the app on startup, but will not start it now
systemctl enable yourapp.service

# Start the app now, but doesn't change auto startup
systemctl start yourapp.service
Note: See the systemd documentation for in depth documentation on services.

Ubuntu 20.04 - Focal

Ubuntu 20.04 - Getting Started

The latest release is available here:

The login is either "root" with no password, or username "ubuntu" with the password "ubuntu". The ubuntu user is allowed to run sudo.

To write this to an SD card, first partition the SD card to have one large ext3, or ext4 partition. See the guide here for more information. Once it is formatted, extract this tar with:

# Assuming your SD card is /dev/sdc with one partition
mkfs.ext3 /dev/sdc1
mkdir /mnt/sd/
sudo mount /dev/sdc1 /mnt/sd/
sudo tar --numeric-owner -xjf ubuntu-armhf-20.04-latest.tar.bz2 -C /mnt/sd
sudo umount /mnt/sd
sync

To rewrite the eMMC, boot to the SD card. You cannot rewrite the emmc while it is mounted elsewhere, or used to currently boot the system. Once booted to the SD, run:

mkfs.ext3 /dev/mmcblk2p1
mkdir /mnt/emmc
mount /dev/mmcblk2p1 /mnt/emmc
wget -qO- https://files.embeddedTS.com/ts-socket-macrocontrollers/ts-4900-linux/distributions/ubuntu/ubuntu-armhf-20.04-latest.tar.bz2 | tar --numeric-owner -xj -C /mnt/emmc/
umount /mnt/emmc
sync


Note: The ext4 filesystem can be used instead of ext3, but it may require additional options. U-Boot does not support the 64bit addressing added as the default behavior in recent revisions of mkfs.ext4. If using e2fsprogs 1.43 or newer, the options "-O ^64bit,^metadata_csum" must be used with ext4 for proper compatibility. Older versions of e2fsprogs do not need these options passed nor are they needed for ext3.

Ubuntu 20.04 - Networking

The network in Ubuntu is configured netplan. For complete documentation, see Netplan's documentation here

Some common examples are shown below. On this release network interfaces follow the predictible network interface names. Run ip addr show to get a list of the network interfaces.

Most commonly:

  • end0 - Ethernet device 0 (CPU Ethernet)
  • enp1s0 - Ethernet PCIe port 1 slot 0 ethernet
  • usb<mac> - USB ethernet
  • wlan0 - WIFI

DHCP on end0. Edit the file /etc/netplan/ethernet.yaml and add:

network:
  version: 2
  renderer: networkd
  ethernets:
    end0:
      dhcp4: true
      dhcp6: true

Static IP on end0. Edit the file /etc/netplan/ethernet.yaml and add:

network:
  version: 2
  renderer: networkd
  ethernets:
    end0:
     dhcp4: no
     addresses: [192.168.0.50/24]
     gateway4: 192.168.0.1
     nameservers:
       addresses: [8.8.8.8,8.8.4.4]

After creating the yaml file, set the appropriate permissions and apply the netplan:

sudo chmod 600 /etc/netplan/*.yaml
sudo netplan apply

Ubuntu 20.04 - WIFI Client

If connecting to a WPA/WPA2 network, a wpa_supplicant config file must first be created:

wpa_passphrase yournetwork yournetworkpassphrase > /etc/wpa_supplicant/wpa_supplicant-wlan0.conf


Create the file /lib/systemd/system/wpa_supplicant@.service with these contents

[Unit]
Description=WPA supplicant daemon (interface-specific version)
Requires=sys-subsystem-net-devices-%i.device
After=sys-subsystem-net-devices-%i.device

[Service]
Type=simple
ExecStart=/sbin/wpa_supplicant -c/etc/wpa_supplicant/wpa_supplicant-%I.conf -i%I

[Install]
Alias=multi-user.target.wants/wpa_supplicant@%i.service

Next, enable the service to start up on boot:

systemctl enable wpa_supplicant@wlan0

Create the file /etc/systemd/network/wlan0.network with:

[Match]
Name=wlan0

[Network]
DHCP=yes

Enable networkd to run dhcp on startup:

systemctl enable systemd-networkd

See the systemctl-networkd example for setting a static IP for a network interface. The wlan0.network can be configured the same way as an eth.network. To enable all of the changes that have been made, run the following commands:

systemctl enable wpa_supplicant@wlan0
systemctl start wpa_supplicant@wlan0
systemctl restart systemd-networkd

Ubuntu 20.04 - WIFI Access Point

First, hostapd needs to be installed in order to manage the access point on the device:

apt-get update && apt-get install hostapd -y


Note: The install process will start an unconfigured hostapd process. This process must be killed and restarted before a new hostapd.conf will take effect.

Edit /etc/hostapd/hostapd.conf to include the following lines:

interface=wlan0
driver=nl80211
ssid=YourAPName
channel=1
Note: Refer to the kernel's hostapd documentation for more wireless configuration options.


To start the access point launch hostapd:

hostapd /etc/hostapd/hostapd.conf &

This will start up an access point that can be detected by WIFI clients. A DHCP server will likely be desired to assign IP addresses. Refer to Debian's documentation for more details on DHCP configuration.

Ubuntu 20.04 - Installing New Software

Ubuntu provides the apt-get system which lets you manage pre-built applications. Before you do this you need to update Ubuntu's list of package versions and locations. This assumes you have a valid network connection to the internet.

apt-get update

For example, lets say you wanted to install openjdk for Java support. You can use the apt-cache command to search the local cache of Debian's packages.

root@ts-imx6:~# apt-cache search openjdk
jvm-7-avian-jre - lightweight virtual machine using the OpenJDK class library
freemind - Java Program for creating and viewing Mindmaps
icedtea-7-plugin - web browser plugin based on OpenJDK and IcedTea to execute Java applets
default-jdk - Standard Java or Java compatible Development Kit
default-jdk-doc - Standard Java or Java compatible Development Kit (documentation)
default-jre - Standard Java or Java compatible Runtime
default-jre-headless - Standard Java or Java compatible Runtime (headless)
jtreg - Regression Test Harness for the OpenJDK platform
libreoffice - office productivity suite (metapackage)
icedtea-7-jre-jamvm - Alternative JVM for OpenJDK, using JamVM
openjdk-7-dbg - Java runtime based on OpenJDK (debugging symbols)
openjdk-7-demo - Java runtime based on OpenJDK (demos and examples)
openjdk-7-doc - OpenJDK Development Kit (JDK) documentation
openjdk-7-jdk - OpenJDK Development Kit (JDK)
openjdk-7-jre - OpenJDK Java runtime, using Hotspot Zero
openjdk-7-jre-headless - OpenJDK Java runtime, using Hotspot Zero (headless)
openjdk-7-jre-lib - OpenJDK Java runtime (architecture independent libraries)
openjdk-7-source - OpenJDK Development Kit (JDK) source files
uwsgi-app-integration-plugins - plugins for integration of uWSGI and application
uwsgi-plugin-jvm-openjdk-7 - Java plugin for uWSGI (OpenJDK 7)
uwsgi-plugin-jwsgi-openjdk-7 - JWSGI plugin for uWSGI (OpenJDK 7)                                              

In this case you will likely want openjdk-7-jre to provide a runtime environment, and possibly openjdk-7-jdk to provide a development environment.

Once you have the package name you can use apt-get to install the package and any dependencies. This assumes you have a network connection to the internet.

apt-get install openjdk-7-jre
# You can also chain packages to be installed
apt-get install openjdk-7-jre nano vim mplayer

For more information on using apt-get refer to Ubuntu's documentation here.

Ubuntu 20.04 - Setting up SSH

To install ssh, install the package as normal with apt-get:

apt-get install openssh-server


Make sure the device is configured on the network and set a password for the remote user. SSH will not allow remote connections without a password or a valid SSH key pair.

passwd root
Note: The default OpenSSH server will not permit root to login via SSH as a security precaution. To allow root to log in via ssh anyway, edit the /etc/ssh/sshd_config file and add the line PermitRootLogin yes in the authentication section. This change will take effect after reboot or after sshd service restart.

After this setup it is now possible to connect from a remote PC supporting SSH. On Linux/OS X this is the "ssh" command, or from Windows using a client such as PuTTY.

Note: If a DNS server is not present on the target network, it is possible to save time at login by adding "UseDNS no" in /etc/ssh/sshd_config.

Ubuntu 20.04 - Starting Automatically

A systemd service can be created to start up headless applications. Create a file in /etc/systemd/system/yourapp.service

[Unit]
Description=Run an application on startup

[Service]
Type=simple
ExecStart=/usr/local/bin/your_app_or_script

[Install]
WantedBy=multi-user.target

If networking is a dependency add "After=network.target" in the Unit section. Once you have this file in place add it to startup with:

# Start the app on startup, but will not start it now
systemctl enable yourapp.service

# Start the app now, but doesn't change auto startup
systemctl start yourapp.service
Note: See the systemd documentation for in depth documentation on services.

Ubuntu 18.04 - Xenial

Ubuntu 18.04 - Getting Started

The latest release is available here:

The login is either "root" with no password, or username "ubuntu" with the password "ubuntu". The ubuntu user is allowed to run sudo.

To write this to an SD card, first partition the SD card to have one large ext3, or ext4 partition. See the guide here for more information. Once it is formatted, extract this tar with:

# Assuming your SD card is /dev/sdc with one partition
mkfs.ext3 /dev/sdc1
mkdir /mnt/sd/
sudo mount /dev/sdc1 /mnt/sd/
sudo tar --numeric-owner -xjf ubuntu-armhf-18.04-latest.tar.bz2 -C /mnt/sd
sudo umount /mnt/sd
sync

To rewrite the eMMC, boot to the SD card. You cannot rewrite the emmc while it is mounted elsewhere, or used to currently boot the system. Once booted to the SD, run:

mkfs.ext3 /dev/mmcblk2p1
mkdir /mnt/emmc
mount /dev/mmcblk2p1 /mnt/emmc
wget -qO- https://files.embeddedTS.com/ts-socket-macrocontrollers/ts-4900-linux/distributions/ubuntu/ubuntu-armhf-18.04-latest.tar.bz2 | tar --numeric-owner -xj -C /mnt/emmc/
umount /mnt/emmc
sync


Note: The ext4 filesystem can be used instead of ext3, but it may require additional options. U-Boot does not support the 64bit addressing added as the default behavior in recent revisions of mkfs.ext4. If using e2fsprogs 1.43 or newer, the options "-O ^64bit,^metadata_csum" must be used with ext4 for proper compatibility. Older versions of e2fsprogs do not need these options passed nor are they needed for ext3.

Ubuntu 18.04 - Networking

From almost any Linux system you can use "ip" or the ifconfig/route commands to set up the network.

# Bring up the CPU network interface
ifconfig eth0 up

# Or if you're on a baseboard with a second ethernet port, you can use that as:
ifconfig eth1 up

# Set an ip address (assumes 255.255.255.0 subnet mask)
ifconfig eth0 192.168.0.50

# Set a specific subnet
ifconfig eth0 192.168.0.50 netmask 255.255.0.0

# Configure your route.  This is the server that provides your internet connection.
route add default gw 192.168.0.1

# Edit /etc/resolv.conf for your DNS server
echo "nameserver 192.168.0.1" > /etc/resolv.conf

Most networks will offer DHCP which can be set up with one command:

# To setup the default CPU ethernet port
dhclient eth0
# Or if you're on a baseboard with a second ethernet port, you can use that as:
dhclient eth1
# You can configure all ethernet ports for a dhcp response with
dhclient

To make DHCP run on startup systemd's networking will need to be configured.

In /etc/systemd/network/eth.network

[Match]
Name=eth*

[Network]
DHCP=yes

Then, if you intend to use DHCP to configure your DNS, start and enable the network name resolver service:

systemctl start systemd-resolved.service 
systemctl enable systemd-resolved.service
ln -s /run/systemd/resolve/resolv.conf /etc/resolv.conf

For a static configuration create a config file for that specific interface. /etc/systemd/network/eth0.network

[Match]
Name=eth0

[Network]
Address=192.168.0.50/24
Gateway=192.168.0.1
DNS=192.168.0.1

For more information on networking, see Ubuntu and systemd's documentation:

Ubuntu 18.04 - WIFI Client

If connecting to a WPA/WPA2 network, a wpa_supplicant config file must first be created:

wpa_passphrase yournetwork yournetworkpassphrase > /etc/wpa_supplicant/wpa_supplicant-wlan0.conf


Create the file /lib/systemd/system/wpa_supplicant@.service with these contents

[Unit]
Description=WPA supplicant daemon (interface-specific version)
Requires=sys-subsystem-net-devices-%i.device
After=sys-subsystem-net-devices-%i.device

[Service]
Type=simple
ExecStart=/sbin/wpa_supplicant -c/etc/wpa_supplicant/wpa_supplicant-%I.conf -i%I

[Install]
Alias=multi-user.target.wants/wpa_supplicant@%i.service

Next, enable the service to start up on boot:

systemctl enable wpa_supplicant@wlan0

Create the file /etc/systemd/network/wlan0.network with:

[Match]
Name=wlan0

[Network]
DHCP=yes

Enable networkd to run dhcp on startup:

systemctl enable systemd-networkd

See the systemctl-networkd example for setting a static IP for a network interface. The wlan0.network can be configured the same way as an eth.network. To enable all of the changes that have been made, run the following commands:

systemctl enable wpa_supplicant@wlan0
systemctl start wpa_supplicant@wlan0
systemctl restart systemd-networkd

Ubuntu 18.04 - WIFI Access Point

First, hostapd needs to be installed in order to manage the access point on the device:

apt-get update && apt-get install hostapd -y


Note: The install process will start an unconfigured hostapd process. This process must be killed and restarted before a new hostapd.conf will take effect.

Edit /etc/hostapd/hostapd.conf to include the following lines:

interface=wlan0
driver=nl80211
ssid=YourAPName
channel=1
Note: Refer to the kernel's hostapd documentation for more wireless configuration options.


To start the access point launch hostapd:

hostapd /etc/hostapd/hostapd.conf &

This will start up an access point that can be detected by WIFI clients. A DHCP server will likely be desired to assign IP addresses. Refer to Debian's documentation for more details on DHCP configuration.

Ubuntu 18.04 - Installing New Software

Ubuntu provides the apt-get system which lets you manage pre-built applications. Before you do this you need to update Ubuntu's list of package versions and locations. This assumes you have a valid network connection to the internet.

apt-get update

For example, lets say you wanted to install openjdk for Java support. You can use the apt-cache command to search the local cache of Debian's packages.

root@ts-imx6:~# apt-cache search openjdk
jvm-7-avian-jre - lightweight virtual machine using the OpenJDK class library
freemind - Java Program for creating and viewing Mindmaps
icedtea-7-plugin - web browser plugin based on OpenJDK and IcedTea to execute Java applets
default-jdk - Standard Java or Java compatible Development Kit
default-jdk-doc - Standard Java or Java compatible Development Kit (documentation)
default-jre - Standard Java or Java compatible Runtime
default-jre-headless - Standard Java or Java compatible Runtime (headless)
jtreg - Regression Test Harness for the OpenJDK platform
libreoffice - office productivity suite (metapackage)
icedtea-7-jre-jamvm - Alternative JVM for OpenJDK, using JamVM
openjdk-7-dbg - Java runtime based on OpenJDK (debugging symbols)
openjdk-7-demo - Java runtime based on OpenJDK (demos and examples)
openjdk-7-doc - OpenJDK Development Kit (JDK) documentation
openjdk-7-jdk - OpenJDK Development Kit (JDK)
openjdk-7-jre - OpenJDK Java runtime, using Hotspot Zero
openjdk-7-jre-headless - OpenJDK Java runtime, using Hotspot Zero (headless)
openjdk-7-jre-lib - OpenJDK Java runtime (architecture independent libraries)
openjdk-7-source - OpenJDK Development Kit (JDK) source files
uwsgi-app-integration-plugins - plugins for integration of uWSGI and application
uwsgi-plugin-jvm-openjdk-7 - Java plugin for uWSGI (OpenJDK 7)
uwsgi-plugin-jwsgi-openjdk-7 - JWSGI plugin for uWSGI (OpenJDK 7)                                              

In this case you will likely want openjdk-7-jre to provide a runtime environment, and possibly openjdk-7-jdk to provide a development environment.

Once you have the package name you can use apt-get to install the package and any dependencies. This assumes you have a network connection to the internet.

apt-get install openjdk-7-jre
# You can also chain packages to be installed
apt-get install openjdk-7-jre nano vim mplayer

For more information on using apt-get refer to Ubuntu's documentation here.

Ubuntu 18.04 - Setting up SSH

To install ssh, install the package as normal with apt-get:

apt-get install openssh-server


Make sure the device is configured on the network and set a password for the remote user. SSH will not allow remote connections without a password or a valid SSH key pair.

passwd root
Note: The default OpenSSH server will not permit root to login via SSH as a security precaution. To allow root to log in via ssh anyway, edit the /etc/ssh/sshd_config file and add the line PermitRootLogin yes in the authentication section. This change will take effect after reboot or after sshd service restart.

After this setup it is now possible to connect from a remote PC supporting SSH. On Linux/OS X this is the "ssh" command, or from Windows using a client such as PuTTY.

Note: If a DNS server is not present on the target network, it is possible to save time at login by adding "UseDNS no" in /etc/ssh/sshd_config.

Ubuntu 18.04 - Starting Automatically

A systemd service can be created to start up headless applications. Create a file in /etc/systemd/system/yourapp.service

[Unit]
Description=Run an application on startup

[Service]
Type=simple
ExecStart=/usr/local/bin/your_app_or_script

[Install]
WantedBy=multi-user.target

If networking is a dependency add "After=network.target" in the Unit section. Once you have this file in place add it to startup with:

# Start the app on startup, but will not start it now
systemctl enable yourapp.service

# Start the app now, but doesn't change auto startup
systemctl start yourapp.service
Note: See the systemd documentation for in depth documentation on services.

To start an application on bootup with X11 instead change the x-session-manager. By default the system starts xfce:

root@ts:~# ls -lah /usr/bin/x-session-manager 
lrwxrwxrwx 1 root root 35 May 26  2015 /usr/bin/x-session-manager -> /etc/alternatives/x-session-manager
root@ts:~# ls -lah /etc/alternatives/x-session-manager
lrwxrwxrwx 1 root root 19 May 26  2015 /etc/alternatives/x-session-manager -> /usr/bin/startxfce4

The x-session can be modified to only start specified processes. Create the file /usr/bin/mini-x-session with these contents:

#!/bin/bash
matchbox-window-manager -use_titlebar no &

exec xfce4-terminal

You may need to "apt-get install matchbox-window-manager." first. This is a tiny window manager which also has a few flags that simplify embedded use. Now enable this session manager and restart slim to restart x11 and show it now.

chmod a+x /usr/bin/mini-x-session
rm /etc/alternatives/x-session-manager
ln -s /usr/bin/mini-x-session /etc/alternatives/x-session-manager
service slim restart

If the x-session-manager process ever closes x11 will restart. The exec command allows a new process to take over the existing PID. In the above example xfce4-terminal takes over the PID of x-session-manager. If the terminal is closed with commands like exit the slim/x11 processes will restart.

Android

This Android distribution is based off of Freescale's port of AOSP to the i.MX6 platform. This allows users to run existing APKs to use this platform with no modifications, or develop new projects using Android Studio.

Getting Started with Android

Android must be run from the eMMC. This can be written with the USB production tool, or from the SD card. To use the USB drive, follow the instructions here, and download the image and copy it to the USB drive as emmcimage.dd.bz2.

Download the Android image here:

To load from the SD card, boot up to any Linux distribution from the SD card such as the default Debian. Once booted here, run:

wget -qO- ftp://ftp.embeddedTS.com/ts-arm-sbc/ts-7990-linux\
/distributions/android/android-7.1.1-tsimx6-atmelwifi-\
latest.dd.bz2 | bzcat | dd bs=4M of=/dev/mmcblk2 conv=fsync

This will download it, decompress it, and write it to the eMMC drive. Remove the SD boot jumper, reboot, and boot into Android.

Android Networking

Android supports networking through the integrated Atmel WIFI chipset, or through the ethernet port on the left side of the screen (eth0). This Ethernet interface will always grab DHCP by default if connected.

Android Software Development

AOSP development works exactly the same as on an Android phone, except the Google APIs associated with the store are not available. See The android documentation for getting started on development: http://developer.android.com/training/basics/firstapp/index.html

Android Install APK

Connect to the ADB USB on the TS-TPC-7990 by pluging a MicroUSB into P1/OTG.

APKs can be installed just like on any other Android device. On the device go to settings->About Tablet and press the "build number" until the text states "You are now a developer". Go back to Settings and there is now a "Developer Options" menu. Under Debugging enable USB Debugging. You should now be able to run adb commands to install apk files.

adb install </path/to/app.apk>

Backup / Restore

While all of our products ship with images pre-loaded in to any supplied media, there are many situations where new images may need to be written. For example, to restore a device to its factory settings or apply a customized image/filesytem for application deployment. Additionally, specific units may be used for development and that unit's disk images need to be replicated to other units to be deployed in the field.

We offer a number of different ways to accomplish both capturing images to be written to other units, and the actual writing process itself. See the sections below for details on our USB Image Replicator tool to capture and/or write images, as well as details on manual processes to capture and write images on each of this device's media.


Image Replicator

This platform supports our Image Replicator tool. The Image Replicator tool is intended for use by developers as a means to write bootable images or filesystems on to a device's media (SD / eMMC / SATA / etc.) as part of their production or preparation process. In addition to writing media, the Image Replicator tool is capable of capturing images from a device's media and preparing them to be written to other devices.

The Image Replicator tool is a USB disk image that can be booted on a target device to capture or write its media directly without the need for a host workstation. The USB disk image is based on Buildroot and contains a set of scripts which handle the capture and write process. The process and its scripts are flexible and can be used as-is or adapted in to larger production processes to format and load data on to devices. The single USB drive can be used to capture images from a device, and then can be inserted in to other devices to write those same images on to other devices. The capture process is not necessary if it is not needed. Images for the target device can be copied to the USB drive, booted on compatible units, and have the target images written to that unit's media.


Image Capture Process

The image capture process performs the following steps. For more detailed information, see the Image Capture section below.

  1. If no valid images exist on the disk, image capture starts.
  2. For each valid media present on the unit, a bit for bit copy of the source is made.
  3. This image is mounted, sanitized (to remove unneeded files and allow safe copying of the image to other units), and saved as either a disk image or a tarball depending on the partition layout of the source disk.
  4. All images and tarballs are compressed, with both the output files having their MD5 hash saved as well as all of the files contained in the root partition having their MD5 hashes saved to a file for later verification.

The captured images and tarballs are named such that the USB Image Replicator disk can be immediately used to boot another unit and have it perform the Image Write process to write that unit's media with the captured images.

Note: When using this process, the USB drive used for the Image Replicator must be sized large enough to handle multiple compressed images as well as the uncompressed copy of the media image actively being worked with. If the image capture process runs out of space, the process will indicate a failure.


Image Write Process

The image write process performs the following steps. For more details information see the Image Write section below.

  1. For each valid media present on the unit, find the first valid source image file for it.
  2. If a source image exists for a media that is not present on the unit, then the process indicates a failure.
  3. If the source image is a tarball, format the target disk with an appropriate filesystem, and unpack it to the target disk, verifying all files against the MD5 hash file list after they are written.
  4. If the source image is a disk image, write that to the target disk. If an MD5 file for the disk image exists, read back the written disk and compare it to the hash.


Creating a USB Image Replicator Disk

Image Replicator USB disk images can be found below:

Disk image: tsimx6-usb-image-replicator.dd.xz

Tarball: tsimx6-usb-image-replicator-rootfs.tar.xz

On startup if SW1 is depressed before power is applied and held for a few moments after, then TS-7970's U-Boot will attempt to located a file called /tsinit.ub on a USB drive. If found, it will copy this file to memory at ${loadaddr} and then execute source ${loadaddr} to run this U-Boot script. This is the mechanism used to boot either of the two disk images on the TS-7970.

Two types of USB Image Replicator images are available for this platform, a tarball and an actual disk image. They both have the same contents and are intended to provide different methods to write the Image Replicator tool to a USB disk.

Disk Image (.dd.xz)
The disk image is easier to write from different workstation OSs, will auto-expand to the full disk length on its first boot, and is intended to be used for image capture (and later image writing) due to its small size and auto-expansion process. We recommend this route for users who may not have access to a Linux workstation or need to capture images from a golden unit first.
Tarball Image (.tar.xz)
The tarball image is easiest to write from a Linux workstation, but requires creating a partition table on the USB disk (if one does not already exist), formatting the filesystem, and unpacking the tarball. It can readily be used for for both image capture and writing, but is the easiest route when image capture is not needed due to the auto-expansion process.


Note: It is recommended to use USB drives with solid-state media for this process. Slower USB drives, especially those with spinning media, may take too long to enumerate and the bootloader will not boot the Image Replicator disk. Additionally, the use of low quality, damaged, and/or worn out USB drives may cause unexpected errors that appear unrelated to the USB drive itself. If there are issues using the Image Replicator, we recommend first trying a new, fresh, high-quality USB drive from a trusted named brand.


Disk Image

This process uses a small disk image that can be written to a USB device. This disk image uses an ext3 filesystem which expands on its first boot to the full length of the disk before beginning the image capture process. This disk is recommended for users who may not have access to a Linux workstation or who need to capture images from a golden unit.

It is possible to use the disk image for just image writing, however, in order to ensure full disk space is available it is recommended to write the disk image to a USB drive, boot it on a unit, let the image capture process complete, insert the USB drive in to a workstation, and then remove the captured image files before copying in the desired image files for the target unit from the workstation.


Writing Disk Image From a Linux Workstation

The disk image can be written via the command line with the dd command (replace /dev/sdX with the correct USB device node):

xzcat <platform>-usb-image-replicator.dd.xz | dd of=/dev/sdX bs=1M conv=fsync

Graphical tools also exist for this purpose, for example balenaEtcher[1] offers this functionality.


Writing Disk Image From a Windows Workstation

A number of tools exist for writing an image to a USB drive, including (but not limited to) balenaEtcher[1] and Win32DiskImager[2]


Writing Disk Image From a MacOS Workstation

We recommend using a tool such as balenaEtcher[1] to write disk images.


  1. 1.0 1.1 1.2 embeddedTS is not affiliated with this tool. balenaEtcher version 1.5.101 tested in Windows 10 on 20220216
  2. embeddedTS is not affiliated with this tool. Win32DiskImager 1.0.0 tested in Windows 10 on 20220216. Cannot handle compressed images, must first decompress disk image.


Tarball

This process is easiest on a Linux workstation, but can be performs on other operating systems as well so long as they can support a compatible filesystem, the xz compression algorithm, as well as the tarball archive format. Note that in many cases, one of our computing platforms running our stock Linux image can be used if a Linux workstation is not available. After writing the tarball to a USB disk, the full length of the USB disk would be available to copy source images to in order to write them to other units.

The image replicator and scripts require a minimum of 50 MB; this plus the size of any target disk images or tarballs to be used dictates the minimum USB disk size required. The USB drive should have only a single partition, which is formatted ext2[1] / 3 / 4[2] or FAT32/vfat[3] Note that other filesystems are not compatible with U-Boot and therefore cannot be used.


Writing Tarball From a Linux Workstation

# This assumes USB drive is /dev/sdc:
sudo mkfs.ext3 /dev/sdc1
sudo mkdir /mnt/usb/
sudo mount /dev/sdc1 /mnt/usb/
sudo tar --numeric-owner -xf /path/to/<platform>-usb-image-replicator-rootfs.tar.xz -C /mnt/usb/
sudo umount /mnt/usb/


Writing Tarball From a Windows Workstation

It is recommended to use a third party tool, as native Windows archive tools have been observed to not work correctly. Tools such as 7-Zip[4] or PeaZip[5] are known working. It may also be possible to use Windows Subsystem for Linux following the Linux Workstation instructions above, but this has not been tested.

Note that some Windows tools may attempt to use the whole disk, rather than create a partition table. A partition table with a single partition is required for U-Boot support.

With a formatted USB disk, the archive can be unpacked to the root folder of the USB disk. Be sure to not unpack the tarball contents in to a new folder on the drive as this will not be bootable.


  1. The ext2 filesystem has a max file size limit as low at 16 GiB. This may cause issues for Image Capture.
  2. Use of ext4 may require additional options. U-Boot on some platforms does not support the 64-bit addressing added as the default behavior in recent revisions of mkfs.ext4. If using e2fsprogs 1.43 or newer, the options -O ^64bit,^metadata_csum may need to be used with ext4 for proper compatibility. Older versions of e2fsprogs do not need these options passed, nor are they needed for ext2 / 3.
  3. The FAT32 (supported by vfat in Linux) filesystem has a max file size limit of 4 GiB. This may cause issues for Image Capture.
  4. embeddedTS is not affiliated with this tool. 7-Zip 21.07 tested in Windows 10 on 20220222
  5. embeddedTS is not affiliated with this tool. PeaZip 7.2.0 tested in Windows 10 on 20220222


Running the Image Replicator Tool

On startup, if the "U Boot" jumper is set when power is applied, then U-Boot will attempt to load a file from a USB drive called /tsinit.ub. If found, it will copy this to ${loadaddr} and execute source ${loadaddr} to run it as a U-Boot script. This is the mechanism used to boot either of the two disk images on the TS-TPC-7990.

Once a USB drive is formatted with the Image Replicator tool (see Creating a USB Image Replicator Disk for the correct files and process), boot to this USB drive (note that the Image Replicator already sets up the correct U-Boot boot scripts to boot to the USB drive, see the aforementioned section for details on how to make U-Boot call the scripts on the USB drive). This will start either image capture if no disk images/tarballs are present on the USB drive, or image write if there are disk images/tarballs present on the USB drive.

The Image Replicator tool, while in progress, will flash the green LED once per second while the red LED remains solidly lit. Upon completion, the red LED turns off and the green LED will slowly blink to indicate success, while a blinking red LED with the green LED off indicates a failure.

On each boot, startup scripts will check if the single partition of the USB drive can be expanded and do so if possible. If this process fails, then any further operations will not be run and the LEDs will blink to indicate a failure.


Image Capture

If no valid images to write exist on the booted USB Image Replicator drive, the image capture process starts automatically.

Note that while in progress, the USB Image Replicator drive is mounted read-write. It is not advised to remove power or disconnect the USB Image Replicator drive until the whole process has completed.

To help diagnose failures, files in /tmp/logs/ contain output from each capture process.

For each media present on the unit (SD / eMMC / SATA / etc.), the image capture process will do the following:

  1. Copy the entire media image to an appropriately named file on the USB Image Replicator drive, e.g. sdimage.dd. No data is written to the source media and it is never mounted. The source disk can follow the stock partition layout, or implement a customized one.
  2. Perform an fsck on the Linux rootfs partition in the image file. Note that, if deviating from the standard partition layout, it may be necessary to modify the scripts handling the capture process.
  3. Mount the Linux rootfs partition from the image file and sanitize the filesystem. The sanitization process removes temporary files (e.g. /log/ files), unique files (e.g. ssh private key files, machine ID files), adds a file to indicate that it is a custom image with the date as its contents, etc. The full list of operations can be found in this script. It may be necessary to modify this file for unique situations.
  4. If the media's partition layout uses only a single partition, the filesystem is packed in to a tarball on the USB Image Replicator drive which is appropriately named and compressed, e.g. sdimage.tar.xz. The image file is then unmounted and removed from the USB Image Replicator drive.
  5. If the media's partition layout uses multiple partitions, the image file is then unmounted, an md5sum of the image file taken, it is compressed and appropriately named on the USB Image Replicator drive, e.g. emmcimage.dd.xz, and then an md5sum of the compressed image is taken.

Note that when using this process, the USB Image Replicator drive that is used must be sized large enough to handle multiple compressed images as well as the uncompressed copy of the media image actively being worked with. If the image capture process runs out of space, the process will indicate a failure via the LEDs.

The images files captured are saved to the root folder of the USB Image Replicator drive. Upon completion, it is safe to remove power or unplug the USB drive.

For more details on the image capture process, see this script.


Image Write

This process is used to write existing images to media on a target unit. If appropriately named disk images or tarballs (see table below) are present in the root folder of the USB Image Replicator drive when booted, then the startup scripts will start the image writing process. The latest disk images we provide for our platforms can be downloaded from our FTP site, see the backup and restore section for links to these files.

Note that the USB Image Replicator drive remains read-only through the entire process but target devices may be mounted or actively written. It is not advised to remove power or disconnect the USB Image Replicator drive until the whole process has completed.

To help diagnose failures, files in /tmp/logs/ contain output from each writing process.

The Image Replicator script expects disk images or tarballs to have specific names to match the target media. The script will attempt to match tarball and then disk image names (in the order they are listed in the table below) for each target media, using the first file that is found to write to the target media. Note that symlinks can be used on the USB Image Replicator disk if formatted with a filesystem that supports symlinks. This can be used, for example, to write the same tarball to both SD and eMMC from only a single copy of the source tarball.

Upon completion, it is safe to remove power or unplug the USB drive.

For more details on the image write process, see this script.

The following table is the list of valid file names and how they are processed:

Target media Accepted filenames Description
SD Card

/sdimage.tar.xz /sdimage.tar.bz2 /sdimage.tar.gz /sdimage.tar

Tar of the filesystem. This will repartition the SD card to a single partition and extract this tarball to the filesystem. If present, a file named /md5sums.txt in the tarball will have its contents checked against the whole filesystem after the tarball is extracted. This md5sums.txt file is optional and can be omitted, but it must not be blank if present. This file is present in our official images and is created during image capture with the Image Replicator tool.

/sdimage.dd.xz /sdimage.dd.bz2 /sdimage.dd.gz /sdimage.dd

Disk image of the media. This will be written to the SD card block device directly. If present on the USB Image Replicator drive, a file named /sdimage.dd.md5 will be used to verify the data written to the SD card against this checksum. This file is provided with our official images and is created during image capture with the Image Replicator tool.
eMMC

/emmcimage.tar.xz /emmcimage.tar.bz2 /emmcimage.tar.gz /emmcimage.tar

Tar of the filesystem. This will repartition the eMMC to a single partition and extract this tarball to the filesystem. If present, a file named /md5sums.txt in the tarball will have its contents checked against the whole filesystem after the tarball is extracted. This md5sums.txt file is optional and can be omitted, but it must not be blank if present. This file is present in our official images and is created during image capture with the Image Replicator tool.

/emmcimage.dd.xz /emmcimage.dd.bz2 /emmcimage.dd.gz /emmcimage.dd

Disk image of the media. This will be written to the eMMC block device directly. If present on the USB Image Replicator drive, a file named /emmcimage.dd.md5 will be used to verify the data written to the SD card against this checksum. This file is provided with our official images and is created during image capture with the Image Replicator tool.
SATA

/sataimage.tar.xz /sataimage.tar.bz2 /sataimage.tar.gz /sataimage.tar

Tar of the filesystem. This will repartition the first SATA drive with a single partition and extract this tarball to the filesystem. If present, a file named /md5sums.txt in the tarball will have its contents checked against the whole filesystem after the tarball is extracted. This md5sums.txt file is optional and can be omitted, but it must not be blank if present. This file is present in our official images and is created during image capture with the Image Replicator tool.

/sataimage.dd.xz /sataimage.dd.bz2 /sataimage.dd.gz /sataimage.dd

Disk image of the media. This will be written to the first SATA block device directly. If present on the USB Image Replicator drive, a file named /sataimage.dd.md5 will be used to verify the data written to the SD card against this checksum. This file is provided with our official images and is created during image capture with the Image Replicator tool.
U-Boot

/u-boot.imx

U-Boot binary blob. This will be written to the SPI flash. The imx_type variable of the new file and the existing U-Boot installation on SPI flash will be checked to ensure the file being written is compatible with the current CPU. If the file /u-boot.imx.md5 is present on the USB drive, this will be used to verify the data written to SPI flash.
Note: SATA is only present on models with Dual/Quad CPUs


Building the Image Replicator from Source

The Image Replicator tool uses Buildroot to create the bootable USB disk image and tarball. See the project repository on github for information on compatibility and instructions on building: https://github.com/embeddedTS/buildroot-ts

MicroSD Card

Note: Our Image Replicator tool can be used to automate this process.


These instructions assume you have an SD card with one partition. Most SD cards ship this way by default. If the card has had its partition table modified this can be corrected with a tool like 'gparted' or 'fdisk'.

Plug the SD card into a USB reader and connect it to a linux workstation PC. Newer distributions include a utility called 'lsblk' which lists all block devices like a USB SD card reader:

lsblk
 NAME   MAJ:MIN RM   SIZE RO TYPE MOUNTPOINT
 sdY      8:0    0   400G  0 disk 
 ├─sdY1   8:1    0   398G  0 part /
 ├─sdY2   8:2    0     1K  0 part 
 └─sdY5   8:5    0     2G  0 part [SWAP]
 sr0     11:0    1  1024M  0 rom  
 sdX      8:32   1   3.9G  0 disk 
 ├─sdX1   8:33   1   7.9M  0 part 
 ├─sdX2   8:34   1     2M  0 part 
 ├─sdX3   8:35   1     2M  0 part 
 └─sdX4   8:36   1   3.8G  0 part  

In this case the SD card is 4GB, so sdX is the target device. Note that on your system, sdX will not be a real device, it could be sda, sdb, mmcblk0, etc. Technologic Systems is not responsible for any damages cause by using the improper device node for imaging an SD card.

After plugging in the device after Linux has booted you can use dmesg to print out the kernel log. When the USB drive is added it will append to the end of that file. Try running:

dmesg | tail -n 100
 scsi 54:0:0:0: Direct-Access     Generic  Storage Device   0.00 PQ: 0 ANSI: 2
 sd 54:0:0:0: Attached scsi generic sg2 type 0
 sd 54:0:0:0: [sdX] 3862528 512-byte logical blocks: (3.97 GB/3.84 GiB)

In this case, sdXc is shown as a 3.97GB card. Note that on your system, sdX will not be a real device, it could be sda, sdb, mmcblk0, etc. Technologic Systems is not responsible for any damages cause by using the improper device node for imaging an SD card.

The following commands will reformat the first partition of the SD card, and unpack the latest filesystem on there:

# Verify nothing else has this mounted
sudo umount /dev/sdX1

sudo mkfs.ext3 /dev/sdX1
sudo mkdir /mnt/sd
sudo mount /dev/sdX1 /mnt/sd/
wget ftp://ftp.embeddedTS.com/ts-arm-sbc/ts-7990-linux/distributions/yocto/morty/ts-x11-image-tsimx6-latest.rootfs.tar.bz2

sudo tar -xf ts-x11-image-tsimx6-latest.rootfs.tar.bz2 -C /mnt/sd
sudo umount /mnt/sd
sync
Note: The ext4 filesystem can be used instead of ext3, but it may require additional options. U-Boot does not support the 64bit addressing added as the default behavior in recent revisions of mkfs.ext4. If using e2fsprogs 1.43 or newer, the options "-O ^64bit,^metadata_csum" must be used with ext4 for proper compatibility. Older versions of e2fsprogs do not need these options passed nor are they needed for ext3.

Once written, the files on disk can be verified to ensure they are the same as the source files in the archive. Reinsert the disk to flush the block cache completely, then run the following commands:

mount /dev/sdX1 /mnt/sd
cd /mnt/sd/
sudo md5sum --quiet -c md5sums.txt
cd -
umount /mnt/sd
sync

The md5sum command will report what differences there are, if any, and return if it passed or failed.

eMMC

Note: Our Image Replicator tool can be used to automate this process.


Pick the latest image to restore to here:

The simplest way to backup/restore the eMMC is through u-boot. If you boot up with JP2 connected and stop in u-boot you can run this command:

ums 0 mmc 1

Now plug in the P1 USB port and this will make the board act as a USB mass storage device with direct access to the eMMC disk. On a linux workstation, to backup the image:

dmesg | tail -n 30
# Look for the last /dev/sd* device connected.  This should also match the eMMC
# size of around 3.78GiB.  On my system, this is /dev/sdd.
sudo mkdir /mnt/emmc/
sudo mount /dev/mmcblk1p1 /mnt/emmc/
cd /mnt/emmc/
sudo tar -cjf /path/to/ts-backup-image.tar.bz2 .
cd ../
sudo umount /mnt/emmc/
sync

To write a new filesystem:

dmesg | tail -n 30
# Look for the last /dev/sd* device connected.  This should also match the eMMC
# size of around 3.78GiB.  On my system, this is /dev/sdd.
sudo mkdir /mnt/emmc/
sudo mkfs.ext3 /dev/mmcblk1p1
# If the above command fails, use fdisk or gparted to repartition the emmc
# to have one large partition.
sudo mount /dev/mmcblk1p1 /mnt/emmc/
sudo tar -xjf /path/to/ts-new-image.tar.bz2 -C /mnt/emmc
sudo umount /mnt/emmc/
sync

Note that this interface is limited to about 1MB/s. You can write the eMMC disk faster by booting to SD with access to the image and using the native SD linux install to rewrite eMMC.

Compile the Kernel

To add additional driver support, reduce the size of our stock kernel kernel, or to write custom kernel drivers the kernel can be compiled from our sources. The following steps walk through the kernel build process; they are compatible with most of our Linux distributions.

This device has multiple kernels released and available in our git repository:

Newer kernels are released on the linux-tsimx repository:

  • embeddedTS/linux-tsimx
  • The "ts-imx_4.9.11_1.0.0_ga" branch is the only one that should be used with our i.MX6 series.

For legacy kernels:

  • embeddedTS/linux-3.10.17-imx6
  • The "master" branch is 3.10.17 and is largely outdated and replaced with later kernels. This is used with the old Yocto Dora builds.
  • The "imx_3.10.53_1.1.0_ga" kernel is a stable branch. Use this with Yocto Dizzy, Fido, or compatible with Debian Jessie.
  • The "imx_3.14.52_1.1.0_ga" branch is compatible with Yocto Jethro, and Debian.
  • The "imx_4.1.15_1.0.0_ga" branch is compatible with Yocto Jethro, Yocto Morty and Debian. Includes recent fixes not in older branches. This is recommended for most users.

The kernel can be rebuilt by cross compiling from an x86 or x86_64 Linux workstation. Our stock kernels are built with the toolchains built by Yocto. The appropriate cross toolchain for your Linux workstation can be downloaded here:

Note: Older kernels will require older toolchains. For older Yocto kernels use a matching Yocto toolchain. For Debian, the latest toolchain and kernel is recommended.
chmod a+x poky*.sh
sudo ./poky*.sh

This will ask for the install directory for the toolchain. A custom location can be chosen, however the following instructions will assume the default installation location.

This process will also require several applications for the install/build process. These can be installed on an Ubuntu/Debian workstation with the following command:

sudo apt-get install git build-essential lzop u-boot-tools libncursesw5-dev fakeroot bc

Once those are installed:

git clone https://github.com/embeddedTS/linux-tsimx.git -b ts-imx_4.9.11_1.0.0_ga linux-tsimx6 --depth 1

# For legacy kernels instead:
# git clone https://github.com/embeddedTS/linux-3.10.17-imx6.git -b imx_4.1.15_1.0.0_ga linux-tsimx6 --depth 1
# If it is already cloned, the "git pull" command will download and merge the latest changes

# For WiFi support, download qcacld-2.0:
# This is only compatible with 4.1.15 or 4.9.11 kernels
git clone https://github.com/embeddedTS/qcacld-2.0.git -b caf-wlan/CNSS.LEA.NRT_3.1

cd linux-tsimx6
# These export commands must be run every time before any make commands
export ARCH=arm
# For 64-bit
export CROSS_COMPILE=/opt/poky/2.2.2/sysroots/x86_64-pokysdk-linux/usr/bin/arm-poky-linux-gnueabi/arm-poky-linux-gnueabi-
# For 32-bit
#export CROSS_COMPILE=/opt/poky/2.2.2/sysroots/i686-pokysdk-linux/usr/bin/arm-poky-linux-gnueabi/arm-poky-linux-gnueabi-
export LOADADDR=0x10008000
export TEMPDIR=$(mktemp -d)

make ts4900_defconfig

## Make any changes in "make menuconfig" or driver modifications, then compile
make -j8 all uImage zImage

mkdir "$TEMPDIR"/boot/
cp arch/arm/boot/uImage  "$TEMPDIR"/boot/uImage
cp arch/arm/boot/zImage  "$TEMPDIR"/boot/zImage
cp arch/arm/boot/dts/imx6*-ts*.dtb "$TEMPDIR"/boot/
INSTALL_MOD_PATH="$TEMPDIR" make modules_install
make headers_install INSTALL_HDR_PATH="$TEMPDIR"

# Compile wifi driver:
cd ../qcacld-2.0/
export KERNEL_SRC="../linux-tsimx6/"
make clean
CONFIG_CLD_HL_SDIO_CORE=y make -j8
INSTALL_MOD_PATH="$TEMPDIR" make modules_install 

fakeroot sh -c "chmod 755 $TEMPDIR;
	chown -R root:root $TEMPDIR;
	tar cjvf kernel.tar.bz2 -C $TEMPDIR .;
	rm -rvf $TEMPDIR"

This will generate "kernel.tar.bz2" which contains the kernel and necessary modules. It can be installed to the device by copying it to a running unit and executing:

# Only run this on a device! Not on a workstation!
tar -xf kernel.tar.bz2 -C /

This can also be extracted over existing images from a workstation, or removable media like SD cards. For example, assuming the SD card on a workstation is "/dev/sdc":

mkdir /mnt/sd/
mount /dev/sdc1 /mnt/sd/
tar -xf kernel.tar.bz2 -C /mnt/sd/
umount /mnt/sd/

Change Kernel Splash Screen

The TS-7990 uses two splash screens. By default they display the same image. U-Boot draws the very first splash screen, and the kernel the second. U-Boot's is only present for about a second while the kernel, device tree, and optionally the FPGA are loaded. The U-Boot splash can be disabled allowing only the kernel's splash screen to show up during boot. This change can be made with:

# This tells the splash command to just run "true" which returns immediately instead of
# drawing a splash screen
env set splash true
env save

To use a custom logo or splash screen in U-Boot, convert the file to a .bmp, and compress it with gz. The logo should be as small and simple as possible to compress well and load fast.

The imagemagick tool can be used on a host system to convert to the correct format.

convert yoursplash.png -colors 256 -depth 8 -compress none splash.bmp3
gzip splash.bmp3
# Write to SPI flash
dd if=splash.bmp3.gz of=/dev/mtdblock0 bs=1024 seek=2048

This is provided in U-Boot primarily for applications that may want to give some feedback to the user. For example, a developer may want to use this U-Boot splash as failed to boot screen or to show the user a message while updating from custom U-Boot scripts. In the default configuration when booting off of eMMC or SD the splash screen from U-Boot will only be shown for about 1-3 seconds until the OS kernel is started.

After U-Boot runs, the Linux kernel is typically started which will set up the clock tree and reinitialize hardware. It is not possible for the U-Boot splash to persist through this, but the kernel can redraw the splash a second later which will appear as a short flicker.

The kernel splash screen allows 224 colors. It also allows up to the full screen resolution, but for fastest boot speed it should be kept as small as possible. The image will be centered around a black background.

To convert an image to be compatible with the Linux splash screen, for example, "mylogo.png":

convert mylogo.png mylogo.ppm
ppmquant 224 mylogo.ppm > mylogo-224.ppm
pnmnoraw mylogo-224.ppm > logo_user_clut224.ppm
cp logo_user_clut224.ppm <kernel build sources>/drivers/video/logo/

In order for this to take effect on boot, the kernel must be re-compiled.

As another option the Linux kernel logo can be disabled completely with "logo.nologo" in the kernel cmdline.

Features

Accelerometer

This SBC contains an NXP MMA8451 3-axis accelerometer. It is connected to the kernel as an input device and can be accessed through the input event layers. The kernel driver is only polling and the accelerometer's IRQs are not supported. The accelerometer supports a ±2, ±4, and ±8 g dynamically selectable scale.

On a stock system with no other peripherals attached, the accelerometer will show up as

 /dev/input/event0

If other peripherals, such as mice, keyboards, or other HID devices are attached at boot, then this device may change.

In order to read from the accelerometer it must first be enabled:

echo 1 > /sys/devices/virtual/input/input0/enable

The scale mode can be changed by writing a 0 (±2 g), 1 (±4 g), or 2 (±8 g) to the scalemode sys file:

#Set the scale mode to 8 g
echo 2 > /sys/devices/virtual/input/input0/scalemode

Note that the input0 above may change if other input devices are present in the system.


From here, a tool such as 'evtest' can be installed and run to verify output:

apt-get update
apt-get install evtest
evtest /dev/input/event0

The 'evtest' command will have output similar to the following:

 Event: time 1466445467.909559, -------------- EV_SYN ------------
 Event: time 1466445468.029557, type 3 (EV_ABS), code 0 (ABS_X), value -123
 Event: time 1466445468.029557, type 3 (EV_ABS), code 1 (ABS_Y), value -35
 Event: time 1466445468.029557, type 3 (EV_ABS), code 2 (ABS_Z), value 16294
 Event: time 1466445468.029557, -------------- EV_SYN ------------
 Event: time 1466445468.149557, type 3 (EV_ABS), code 1 (ABS_Y), value -17
 Event: time 1466445468.149557, type 3 (EV_ABS), code 2 (ABS_Z), value 16224
 Event: time 1466445468.149557, -------------- EV_SYN ------------
 Event: time 1466445468.269598, type 3 (EV_ABS), code 0 (ABS_X), value -149
 Event: time 1466445468.269598, -------------- EV_SYN ------------
 Event: time 1466445468.389560, type 3 (EV_ABS), code 1 (ABS_Y), value -48
 Event: time 1466445468.389560, type 3 (EV_ABS), code 2 (ABS_Z), value 16416
 

Readings from the accelerometer are read from the kernel input event interface. The linux documentation for the input system as well as event types are the best resource for creating an application to read from the device:

https://www.kernel.org/doc/Documentation/input/input.txt

https://www.kernel.org/doc/Documentation/input/event-codes.txt

Additionally, the Openmoko documentation has a great breakdown of the input event data:

http://wiki.openmoko.org/wiki/Accelerometer_data_retrieval#Data_structure

Backlight

The backlight is controlled through the sysfs in /sys/class/backlight/backlight0/brightness. This allows brightness to be specified from 0 (off), to 8 (max brightness).

# Turn off backlight
echo 0 > /sys/class/backlight/backlight0/brightness

# Backlight on low intensity
echo 1 > /sys/class/backlight/backlight0/brightness

# Backlight on medium intensity
echo 4 > /sys/class/backlight/backlight0/brightness

# Backlight on full intensity
echo 8 > /sys/class/backlight/backlight0/brightness

Bluetooth

The WIFI option on the board also includes a bluetooth 4.0 LE module. This is supported in Linux using the Bluez stack.

# First bring up wifi.  This loads the firwmare for
# both WIFI and Bluetooth
modprobe wilc3000
ifconfig wlan0 up
# WIFI can optionally be brought back down
# ifconfig wlan0 down

hciattach /dev/ttymxc1 any 115200 noflow
hciconfig hci0 up
hcitool cmd 0x3F 0x0053 00 10 0E 00 01
stty -F /dev/ttymxc1 921600 crtscts

# If your board is REV A use this setup instead:
echo 237 > /sys/class/gpio/export
echo low > /sys/class/gpio/gpio237/direction
echo high > /sys/class/gpio/gpio237/direction
sleep .1
hciattach /dev/ttymxc1 texas 3000000
hciconfig hci0 up

Now you may scan for available devices with:

hcitool scan

This will return a list of devices such as:

14:74:11:AB:12:34	SAMSUNG-SM-G900A

You may request more information from a detected device like so:

hcitool info 14:74:11:AB:12:34

This will produce lots of details about the device, for example:

Requesting information ...                                                      
        BD Address:  14:74:11:AB:12:34                                          
        OUI Company: Samsung Electronics Co.,Ltd (4C-A5-6D)                     
        Device Name: SAMSUNG-SM-G900A                                           
        LMP Version: 4.1 (0x7) LMP Subversion: 0x610c                           
        Manufacturer: Broadcom Corporation (15)                                 
        Features page 0: 0xbf 0xfe 0xcf 0xfe 0xdb 0xff 0x7b 0x87        
        .
        .
        .

Bluez has support for many different profiles for HID, A2DP, and many more. Refer to the Bluez documentation for more information.

CAN

The TS-7990 CAN bus is located on COM2 and COM3 headers. A jumper can be shorted between DIO header pins 21/22 to add 120ohm termination to the can0 on the COM3 header. The CAN bus on COM2 always has 120ohm termination present.

The i.MX6 includes 2 CAN controllers which support the SocketCAN interface. Before proceeding with the examples, see the Kernel's CAN documentation here.

This board comes preinstalled with can-utils. These can be used to communicate over a CAN network without writing any code. The candump utility can be used to dump all data on the network

## First, set the baud rate and bring up the device:
ip link set can0 type can bitrate 250000
ip link set can0 up

## Dump data & errors:
candump can0 &

## Send the packet with:
#can_id = 0x7df
#data 0 = 0x3
#data 1 = 0x1
#data 2 = 0x0c
cansend can0 -i 0x7Df 0x3 0x1 0x0c
## Some versions of cansend use a different syntax.  If the above
## commands gives an error, try this instead:
#cansend can0 7DF#03010C

The above example packet is designed to work with the Ozen Elektronik myOByDic 1610 ECU simulator to read the RPM speed. In this case, the ECU simulator would return data from candump with:

 <0x7e8> [8] 04 41 0c 60 40 00 00 00 
 <0x7e9> [8] 04 41 0c 60 40 00 00 00 

In the output above, columns 6 and 7 are the current RPM value. This shows a simple way to prove out the communication before moving to another language.

The following example sends the same packet and parses the same response in C:

#include <stdio.h>
#include <pthread.h>
#include <net/if.h>
#include <string.h>
#include <unistd.h>
#include <net/if.h>
#include <sys/ioctl.h>
#include <assert.h>
#include <linux/can.h>
#include <linux/can/raw.h>

int main(void)
{
	int s;
	int nbytes;
	struct sockaddr_can addr;
	struct can_frame frame;
	struct ifreq ifr;
	struct iovec iov;
	struct msghdr msg;
	char ctrlmsg[CMSG_SPACE(sizeof(struct timeval)) + CMSG_SPACE(sizeof(__u32))];
	char *ifname = "can0";
 
	if((s = socket(PF_CAN, SOCK_RAW, CAN_RAW)) < 0) {
		perror("Error while opening socket");
		return -1;
	}
 
	strcpy(ifr.ifr_name, ifname);
	ioctl(s, SIOCGIFINDEX, &ifr);
	addr.can_family  = AF_CAN;
	addr.can_ifindex = ifr.ifr_ifindex;
 
	if(bind(s, (struct sockaddr *)&addr, sizeof(addr)) < 0) {
		perror("socket");
		return -2;
	}
 
 	/* For the ozen myOByDic 1610 this requests the RPM guage */
	frame.can_id  = 0x7df;
	frame.can_dlc = 3;
	frame.data[0] = 3;
	frame.data[1] = 1;
	frame.data[2] = 0x0c;
 
	nbytes = write(s, &frame, sizeof(struct can_frame));
	if(nbytes < 0) {
		perror("write");
		return -3;
	}

	iov.iov_base = &frame;
	msg.msg_name = &addr;
	msg.msg_iov = &iov;
	msg.msg_iovlen = 1;
	msg.msg_control = &ctrlmsg;
	iov.iov_len = sizeof(frame);
	msg.msg_namelen = sizeof(struct sockaddr_can);
	msg.msg_controllen = sizeof(ctrlmsg);  
	msg.msg_flags = 0;

	do {
		nbytes = recvmsg(s, &msg, 0);
		if (nbytes < 0) {
			perror("read");
			return -4;
		}

		if (nbytes < (int)sizeof(struct can_frame)) {
			fprintf(stderr, "read: incomplete CAN frame\n");
		}
	} while(nbytes == 0);

	if(frame.data[0] == 0x4)
		printf("RPM at %d of 255\n", frame.data[3]);
 
	return 0;
}

See the Kernel's CAN documentation here. Other languages have bindings to access CAN such as Python, Java using JNI.

In production use of CAN we also recommend setting a restart-ms for each active CAN port.

ip link set can0 type can restart-ms 100

This allows the CAN bus to automatically recover in the event of a bus-off condition.

CPU

The i.MX6 is an armv7a Cortex-A9 by NXP. The CPU itself is available in 792MHz, 996MHz, and 1.2GHz with a solo, dual, or quad core processor.

Refer to NXP's documentation for in depth documentation on these CPU cores:

eMMC

This board includes a Micron eMMC. Our default builds are 4 GiB, but up to 64 GiB devices are available for custom builds. The eMMC flash appears to Linux as an SD card at /dev/mmcblk2. Our default programming will include one partition programmed with our Yocto image.

The eMMC devices are like SD cards in that they should not be powered down during a write/erase cycle. This eMMC device includes support for setting a fuse for a "Write Reliability" mode, and a "psuedo SLC" mode. When both of these are enabled all writes will be atomic to 512 B. If a sector is being written during a power loss, a block is guaranteed to have either the old or new data. This scheme is far more resilient to power loss than more traditional flash media. In cases of old 512 B data, fsck will likely be able to recover a mountable filesystem. In cases where the corrupted file is a database it may still require a separate mechanism for recovery.

When the pSLC mode is turned on it will reduce the available space to under half, and reduce the write speed.

See our post on preventing filesystem corruption.

The mmc-utils package is used to enable these modes. First determine the exact size of the flash you're using:

mmc extcsd read /dev/mmcblk2 | grep MAX_ENH_SIZE_MULT -A 1
Max Enhanced Area Size [MAX_ENH_SIZE_MULT]: 0x0001cd
 i.e. 1888256 KiB

So in this case, 1888256 KiB is the max size of the enhanced partition. This number should be used for the enh_area command:

mmc write_reliability set -n 0 /dev/mmcblk2
mmc enh_area set -y 0 1888256 /dev/mmcblk2
WARNING: Setting either of those modes is permanent. Using the wrong value it is possible to brick eMMC which will not be covered by the warranty. Evaluation units with fuses set will not be accepted through returns.

After this is run, reboot the whole unit. On all future boots the eMMC will be detected at the smaller size. Changing the enhanced area will erase the drive. After these mmc commands the disk will need to be rewritten.

Ethernet Port

The i.MX6 includes a 10/100/1000 Ethernet port which is located near the speaker. In Linux this is the eth0 interface. The TS-TPC-7990 includes second Ethernet located near the USB socket that is based on the SMSC LAN9514 chipset. This is a 10/100 Ethernet port.

The MAC address uses the Technologic Systems 00:d0:69:00:00:00 OUI, and the last 3 octets are assigned from our pool. The MAC address is burned into the CPU's fuses during production, and will be read back automatically by software in Linux or U-Boot. The eth1 port will use the next mac address after eth0.

Note: NXP has a published erratum regarding the maximum Ethernet speed. The max achievable speed for the 10/100/1000 ethernet port is ~400 Mb/s.

FPGA

The Lattice MachXO2 FPGA provides auto TX enable for RS-485 half duplex, additional DIO, a crossbar MUX, and it can generate four preset clocks. Most of these registers are controlled using the 'tshwctl' utility. The source for 'tshwctl' and other utilities we provide can be found in the ts4900-utils repository. The DIO can be manipulated using the sysfs GPIO interface. See the GPIO section for more information on the recommended GPIO access patterns.

Usage: tshwctl [OPTIONS] ...
Technologic Systems i.mx6 FPGA Utility
     -m, --addr <address>   Sets up the address for a peek/poke
     -v, --poke <value>     Writes the value to the specified address
     -t, --peek             Reads from the specified address
     -i, --mode <8n1>       Used with -a, sets mode like '8n1', '7e2', etc
     -x, --baud <speed>     Used with -a, sets baud rate for auto485
     -a, --autotxen <uart>  Enables autotxen for supported CPU UARTs
                              Uses baud/mode if set or reads the current
                              configuration of that uart
     -c, --dump             Prints out the crossbar configuration
     -g, --get              Print crossbar for use in eval
     -s, --set              Read environment for crossbar changes
     -q, --showall          Print all possible FPGA inputs and outputs.
     -h, --help             This message

The GPIO registers below include a crossbar, output enable, and data bit. The crossbar selects between GPIO and all other modes described in the FPGA Crossbar table. When a pin MUX is set to GPIO, bit 0 is used as an output enable and bit 1 is used as a value. When bit 0 is set to 0 (output disabled), bit 1 reflects the input value. When bit 0 is set to 1 (output enabled), bit 1 reflects the value that will be output on the pin.

Addr Bits Function
00 7:2 TTYMXC2_RXD Crossbar
1 TTYMXC2_RXD Output Data
0 Reserved (Output only)
01 7:2 TTYMXC4_RXD Crossbar
1 TTYMXC4_RXD Output Data
0 Reserved (Output only)
02 7:2 TTYMXC2_CTS Crossbar
1 TTYMXC2_CTS Data
0 TTYMXC2_CTS Output Enable
03 7:2 TTYMXC3_RXD Crossbar
1 TTYMXC3_RXD Output Data
0 Reserved (Output Only)
04 7:2 TTYMXC1_CTS Crossbar
1 TTYMXC1_CTS Output Data
0 Reserved (Output Only)
05 7:2 TTYMXC2_RTS Crossbar
1 TTYMXC2_RTS Data
0 TTYMXC2_RTS Output Enable
06 7:2 DIO_8 Crossbar
1 DIO_8 Data
0 DIO_8 Output Enable
07 7:2 DIO_9 Crossbar
1 DIO_9 Data
0 DIO_9 Output Enable
08 7:2 TXD1_485 Crossbar
1 TXD1_485 Output Data
0 Reserved (Output Only)
09 7:2 TXD2_485 Crossbar
1 TXD2_485 Output Data
0 Reserved (Output Only)
10 7:2 TXD3_485 Crossbar
1 TXD3_485 Output Data
0 Reserved (Output Only)
11 7:2 TXEN1_485 (ttymxc1) Crossbar
1 TXEN1_485 (ttymxc1) Output Data
0 Reserved (Output Only)
12 7:2 TXEN2_485 (ttymxc3) Crossbar
1 TXEN2_485 (ttymxc3) Output Data
0 Reserved (Output Only)
13 7:2 Reserved
1 WIFI_RESET# Output data
0 Reserved
14 7:2 Reserved
1 EN_WIFI_PWR Output data
0 Reserved
15 7:2 BT_RTS Crossbar
1 BT_RTS Data
0 BT_RTS Output Enable
16 7:2 BT_CTS Crossbar
1 BT_CTS Data
0 BT_CTS Output Enable
17 7:2 BT_TXD Crossbar
1 BT_TXD Output Data
0 Reserved (Output Only)
18 7:2 TTYMXC1_RXD Crossbar
1 Reserved
0 Reserved (Output Only)
19 7:2 DIO_0 Crossbar
1 DIO_0 Data
0 DIO_0 Output Enable
20 7:2 DIO_1 Crossbar
1 DIO_1 Data
0 DIO_1 Output Enable
21 7:2 DIO_2 Crossbar
1 DIO_2 Data
0 DIO_2 Output Enable
22 7:2 DIO_3 Crossbar
1 DIO_3 Data
0 DIO_3 Output Enable
23 7:2 DIO_4 Crossbar
1 DIO_4 Data
0 DIO_4 Output Enable
24 7:2 DIO_5 Crossbar
1 DIO_5 Data
0 DIO_5 Output Enable
25 7:2 DIO_6 Crossbar
1 DIO_6 Data
0 DIO_6 Output Enable
26 7:2 DIO_7 Crossbar
1 DIO_7 Data
0 DIO_7 Output Enable
27 7:2 FPGA_IRQ_1 Crossbar Value
1 FGPA_IRQ_1 Output Data
0 Reserved (Output Only)
28 7:0 Reserved
29 7:0 Reserved
30 7:2 Reserved
1 Reboot (on 1) [1]
0 Reserved
31 7:0 Reserved
32 7:0 RS485_CNT0 [23:16]
33 7:0 RS485_CNT0 [15:8]
34 7:0 RS485_CNT0 [7:0]
35 7:0 RS485_CNT1 [23:16]
36 7:0 RS485_CNT1 [15:8]
37 7:0 RS485_CNT1 [7:0]
38 7:0 RS485_CNT2 [23:16]
39 7:0 RS485_CNT2 [15:8]
40 7:0 RS485_CNT2 [7:0]
41 7:0 RS485_CNT3 [23:16]
42 7:0 RS485_CNT3 [15:8]
43 7:0 RS485_CNT3 [7:0]
44 7:2 TTYMAX0_RXD Crossbar
1 TTYMAX0_RXD Output Data
0 Reserved (Output Only)
45 7:2 TTYMAX1_RXD Crossbar
1 TTYMAX1_RXD Output Data
0 Reserved (Output Only)
46 7:2 TTYMAX2_RXD Crossbar
1 TTYMAX2_RXD Output Data
0 Reserved (Output Only)
47 7:2 TXEN3_485 Crossbar
1 TXEN3_485 Output Data
0 Reserved (Output Only)
48 7:2 COM1_TXD_232_3V Crossbar
1 COM1_TXD_232_3V
0 Reserved (Output Only)
49 7:2 COM2_TXD_232_3V Crossbar
1 COM2_TXD_232_3V Output Data
0 Reserved (Output Only)
50 7:2 COM3_TXD_232_3V Crossbar
1 COM3_TXD_232_3V Output Data
0 Reserved (Output Only)
51 7:4 FPGA Revision
3 P13 Input Value
2 L14 Input Value
1 G12 Input Value
0 H12 Input Value
52 7:2 COM1_RTS_3V Crossbar
1 COM1_RTS_3V Output Data
0 Reserved (Output Only)
53 7:2 TTYMAX0_CTS Crossbar
1 TTYMAX0_CTS Output Data
0 Reserved (Output Only)
54 7:2 TTYMAX1_CTS Crossbar
1 TTYMAX1_CTS Output Data
0 Reserved (Output Only)
55 7:2 TTYMAX2_CTS Crossbar
1 TTYMAX2_CTS Output Data
0 Reserved (Output Only)
56 7:0 DIO 7:0 Input Data
57 7:5 Reserved
4 LXD_PRESENT
3 OKAYA_PRESENT
2:1 DIO 9:8 Input Data
0 CN99_BOOT_SEL_PAD [2]
58 7:2 Reserved
1 XBEE Power Enable (1 = on)
0 XBEE Power select (3.3V = 0, 4V = 1) [3]
59 7:6 Reserved
5 XBEE_RESET#
4 EN_LCD_POWER
3 LCD_RESET#
2 EN_LCD_11V#
1 EN_LCD_NEG_7V
0 EN_LCD_20V
60 7:2 Reserved
1 MT_LCD_PRESENT
0 Reserved
61 7:2 Reserved
1 EN_SPKR Output Data
0 Reserved
62 7:2 XBEE_TXD Crossbar
1 XBEE_TXD Output Data
0 Reserved (Output Only)
  1. This power cycles all rails rather than a CPU watchdog reset
  2. This is used to select the offboard SPI primarily just used for production purposes.
  3. The XBEE requires 3.3V, and the Nimbelink requires 4V.

FPGA Crossbar

The FPGA crossbar allows almost any of the FPGA pins to be rerouted. All of the FPGA registers that have a crossbar mux value can be written with these values to change the output value. When using the crossbar pins that are outputs, bit 1 should also be set to allow output enables.

Crossbar Value Selected Function
0 Do not change
1 BT_RTS
2 BT_RXD
3 TTYMXC4_TXD
4 TTYMXC2_TXD
5 TTYMXC2_CTS
6 TTYMXC1_RTS
7 TTYMXC2_RTS
8 RXD1_485_3V
9 RXD2_485_3V
10 RXD3_485_3V
11 COM1_RXD_232_3V
12 COM2_RXD_232_3V
13 COM3_RXD_232_3V
14 TTYMXC3_TXD
15 TTYMXC1_TXD
16 TTYMAX0_TXD
17 TTYMAX0_TXEN
18 TTYMAX0_RTS
19 TTYMAX1_TXD
20 TTYMAX1_TXEN
21 TTYMAX1_RTS
22 TTYMAX2_TXD
23 TTYMAX2_TXEN
24 TTYMAX2_RTS
25 TTYMXC1_TXEN
26 TTYMXC3_TXEN
27 CLK_12MHZ
28 CLK_14MHZ
29 FPGA_24MHZ_CLK
30 CLK_28MHZ
31 GPIO [1]
32 DIO_0
33 DIO_1
34 DIO_2
35 DIO_3
36 DIO_4
37 DIO_5
38 DIO_6
39 DIO_7
40 DIO_8
41 DIO_9
42 XBEE_RXD
  1. This mode enables the use of the GPIO bits in the register, Data and Output Enable

For example, we can remap three ttyMAX ports to the HD1 GPIO.

Pin Function
HD1_DIO_1 ttyMAX0 txd
HD1_DIO_2 ttyMAX0 rxd
HD1_DIO_3 ttyMAX1 txd
HD1_DIO_4 ttyMAX1 rxd
HD1_DIO_5 ttyMAX2 txd
HD1_DIO_6 ttyMAX2 rxd
tshwctl --dump

This will return the mapping of all of the pins as they are currently set. These are the relevant pins:

     FPGA Pad (DIR) (VAL) FPGA Output
       MB_TXD ( in) (  0) TTYMAX1_TXD
  STC_TXD_485 ( in) (  0) TTYMAX0_TXD
  RTS_232_COM ( in) (  0) TTYMAX2_TXD
    HD1_DIO_1 ( in) (  0) GPIO
    HD1_DIO_2 ( in) (  0) GPIO
    HD1_DIO_3 ( in) (  0) GPIO
    HD1_DIO_4 ( in) (  0) GPIO
    HD1_DIO_5 ( in) (  0) GPIO
    HD1_DIO_6 ( in) (  0) GPIO
  TTYMAX0_RXD ( in) (  0) STC_RXD_485_3V
  TTYMAX1_RXD ( in) (  0) MB_RXD_485
  TTYMAX2_RXD ( in) (  0) CTS_232_COM

...

The tshwctl tool uses the bash environment to set/get pin status. To remap these pins:

eval $(tshwctl --get)
export HD1_DIO_1=TTYMAX0_TXD
export HD1_DIO_3=TTYMAX1_TXD
export HD1_DIO_5=TTYMAX2_TXD
export TTYMAX0_RXD=HD1_DIO_2
export TTYMAX1_RXD=HD1_DIO_4
export TTYMAX2_RXD=HD1_DIO_6

# These last 3 aren't required, but this will disable ttyMAX pins on
# their default locations.  Without this, writes to /dev/ttyMAX0 
# would go to both STC_TXD_485 and to HD1_DIO_1.
export MB_TXD=GPIO
export STC_TXD_485=GPIO
export RTS_232_COM=GPIO

# This will read the environment and look for the PAD names 
# for any changes and apply them.
tshwctl --set

# The TTY_MAX*_TXD lines will only output data
# if they pins are outputs, so set these pins 
echo 243 > /sys/class/gpio/export # HD1_DIO_1
echo high > /sys/class/gpio/gpio243/direction
echo 245 > /sys/class/gpio/export # HD1_DIO_3
echo high > /sys/class/gpio/gpio245/direction
echo 247 > /sys/class/gpio/export # HD1_DIO_5
echo high > /sys/class/gpio/gpio247/direction

Graphics

Rotate the Display

Under Yocto you can use xrandr to rotate the screen:

export DISPLAY=:0 
xrandr --rotate left
xrandr --rotate right
xrandr --rotate normal
xrandr --rotate inverted

Under Debian or Ubuntu you can rotate the screen in the Xorg.conf. Edit the file /etc/X11/xorg.conf and append this to the end:

Section "Device"
    Identifier      "fbdev display"
    Driver          "fbdev"
    Option "Rotate" "CCW"
EndSection

After the display is rotated you will also need to rotate a touchscreen if this is being used. This example matches the CCW rotation, but swapaxes or the invertx/y options will need to be adjusted for other rotations.

Section "InputClass"
       Identifier "axis inversion"
       MatchIsTouchscreen "true"
       # swap x/y axes on the device. i.e. rotate by 90 degrees
       Option "SwapAxes" "on"
       # Invert the respective axis.
       Option "InvertX" "on"
       Option "InvertY" "off"
EndSection

On newer X11 releases libinput is used instead of the evdev driver. To rotate with Debian 10 and above this will require changing the coordinate transormation matrix. Edit /etc/X11/Xsession.d/10x11-ts-calibration and add the transformation matrix for your rotation to the end of the script. Eg, for clockwise rotations add:

xinput set-prop "ADS7846 Touchscreen" 'Coordinate Transformation Matrix' 0 -1 1 1 0 0 0 0 1

GPIO

The i.MX6 and FPGA GPIO are accessed using the kernel's sysfs GPIO interface. See the kernel's documentation here for more detail. This interface provides a set of files and directories for interacting with GPIO which can be used from any language that can write files.

To interact with a pin, first export it to userspace:

echo "48" > /sys/class/gpio/export

If you receive a permission denied on a pin that means it is claimed by another kernel driver. In this case, you can "cat /sys/kernel/debug/gpio" to see what driver has claimed it. If it succeeds you will have a /sys/class/gpio/gpio48/ directory. The relevant files in this directory are:

 direction - "in", "out" (out = low), "low", "high"
 value - write "1" or "0", or read "1" or "0" if direction is in
 edge - write with "rising", "falling", or "none"

With direction you can set it as an output and set the direction at the same time with high/low. If you just specify out this is the same as low.

# Set as a low output
echo "out" > /sys/class/gpio/gpio48/direction
# Set GPIO 48 high
echo "1" > /sys/class/gpio/gpio48/value
# Set GPIO 48 low
echo "0" > /sys/class/gpio/gpio48/value

# Read the value of GPIO 48
echo "in" > /sys/class/gpio/gpio48/direction
cat /sys/class/gpio/gpio48/value

# You can set it as a high output by setting the direction:
echo "high" > /sys/class/gpio/gpio48/direction

As an output, the in can be written to 0 for low (GND), or 1 for high (3.3V). The GPIO pins directly off of the i.MX6 processor support an absolute maximum of -0.5 to 3.6V. It is also possible to use any processor GPIO as an interrupt by writing the edge value, and then using select() or poll() on the value file for changes.

CPU GPIO Table

The GPIO numbers in the table below are relevant to how the Linux references these numbers. The CPU documentation refers to bank and IO while Linux flattens this out to one number space.

Schematic Name CPU PAD [1] GPIO Number Common Functions [2] Location
SD1_CMD SD1_CMD 18 #WIFI Onboard WIFI
SD1_CLK SD1_CLK 20 #WIFI Onboard WIFI
SD1_D0 SD1_DAT0 16 #WIFI Onboard WIFI
SD1_D1 SD1_DAT1 17 #WIFI Onboard WIFI
SD1_D2 SD1_DAT2 19 #WIFI Onboard WIFI
SD1_D3 SD1_DAT3 21 #WIFI Onboard WIFI
SD2_CMD SD2_CMD 11 #SD Card MicroSD socket
SD2_CLK SD2_CLK 10 #SD Card MicroSD socket
SD2_D0 SD2_DAT0 15 #SD Card MicroSD socket
SD2_D1 SD2_DAT1 14 #SD Card MicroSD socket
SD2_D2 SD2_DAT2 13 #SD Card MicroSD socket
SD2_D3 SD2_DAT3 12 #SD Card MicroSD socket
SD3_CMD SD3_CMD 194 #eMMC Onboard eMMC
SD3_CLK SD3_CLK 195 #eMMC Onboard eMMC
SD3_D0 SD3_DAT0 196 #eMMC Onboard eMMC
SD3_D1 SD3_DAT1 197 #eMMC Onboard eMMC
SD3_D2 SD3_DAT2 198 #eMMC Onboard eMMC
SD3_D3 SD3_DAT3 199 #eMMC Onboard eMMC
UART1_RXD SD3_DAT6 178 #Getting a Console Onboard Silabs
UART1_TXD SD3_DAT7 117 #Getting a Console Onboard Silabs
SPI_REM_CS# SD3_RST 200 #SPI HD6 pin 10
PWM_LOCAL_LCD SD4_DAT1 41 #Backlight Onboard backlight regulator
USB_HUB_RESET# SD4_DAT3 43 #USB Onboard USB hub
UART2_RTS# SD4_DAT5 45 ttymxc1 RTS #FPGA Crossbar
UART2_CTS# SD4_DAT6 46 ttymxc1 CTS #FPGA Crossbar
SPI_REM_MOSI SD4_DAT7 47 #SPI HD6 pin 6
WIFI_IRQ ENET_RXD1 26 #WIFI Onboard WIFI
UART4_TXD KEY_COL0 102 ttymxc3 TXD #FPGA Crossbar
UART4_RXD KEY_ROW0 103 ttymxc3 RXD #FPGA Crossbar
UART5_TXD KEY_COL1 104 ttymxc4 TXD #FPGA Crossbar
UART5_RXD KEY_ROW1 105 ttymxc4 RXD #FPGA Crossbar
TXD_CAN1 KEY_COL2 106 #CAN Onboard xceiver, COM2 header pins 4(h) and 9(l)
RXD_CAN1_3V KEY_ROW2 107 #CAN Onboard xceiver, COM2 header pins 4(h) and 9(l)
DC_I2C_CLK KEY_COL3 108 #I2C HD8 pin 3
DC_I2C_DAT KEY_ROW3 109 #I2C HD8 pin 1
TXD_CAN0 KEY_COL4 110 #CAN Onboard xceiver, COM3 header pins 4(h) and 9(l)
RXD_CAN0_3V KEY_ROW4 111 #CAN Onboard xceiver, COM3 header pins 4(h) and 9(l)
AUD_MCLK GPIO_0 0 #Audio Onboard SGTL5000
USB_OTG_ID GPIO_1 1 #USB OTG Onboard pullup only
RED_LED GPIO_2 2 #LEDs Onboard RED LED
FPGA_24MHZ_CLK GPIO_3 3 #FPGA Onboard FPGA Clock
FPGA_IRQ_1 GPIO_4 4 #Interrupts #FPGA Crossbar
JTAG_FPGA_TMS GPIO_5 5 #FPGA Onboard FPGA JTAG
FPGA_SPI_CS1# GPIO_6 6 #SPI Onboard FPGA (Unused)
UART2_TXD GPIO_7 7 ttymxc1 TXD #FPGA Crossbar
UART2_RXD GPIO_8 8 ttymxc1 RXD #FPGA Crossbar
PWM_REM_LCD GPIO_9 9 #PWM HD6 pin 14
JTAG_FPGA_TCK GPIO_16 203 #FPGA Onboard FPGA JTAG
JTAG_FPGA_TDI GPIO_17 204 #FPGA Onboard FPGA JTAG
JTAG_FPGA_TDO CSI0_MCLK 147 #FPGA Onboard FPGA JTAG
DC_SPI_CS# CSI0_PIXCLK 146 #SPI HD8 pin 15, #FPGA Crossbar
GREEN_LED CSI0_VSYNC 149 #LEDs Onboard Green LED
FPGA_IRQ_0 CSI0_DATA_EN 148 FPGA MAX3100 IRQ Onboard FPGA
AUD_CLK CSI0_DAT4 150 #Audio Onboard SGTL5000
AUD_TXD CSI0_DAT5 151 #Audio Onboard SGTL5000
AUD_FRM CSI0_DAT6 152 #Audio Onboard SGTL5000
AUD_RXD CSI0_DAT7 153 #Audio Onboard SGTL5000
FPGA_SPI_CLK CSI0_DAT8 154 FPGA MAX3100 UART Onboard FPGA
FPGA_SPI_MOSI CSI0_DAT9 155 FPGA MAX3100 UART Onboard FPGA
FPGA_SPI_MISO CSI0_DAT10 FPGA MAX3100 UART Onboard FPGA
FPGA_SPI_CS0# CSI0_DAT13 156 FPGA MAX3100 UART Onboard FPGA
LCD_PIX_CLK DI0_DISP_CLK 112 #LCD Interface CN4 pin 38, CN8 pin 37
EN_232_TRANS DI0_PIN2 114 Onboard 232 enable Onboard RS232 transceiver
ETH_PHY_RESET DI0_PIN4 116 Ethernet PHY reset Onboard Ethernet PHY
LCD_DE DI0_PIN15 113 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D02 DISP0_DAT2 119 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D03 DISP0_DAT3 120 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D04 DISP0_DAT4 121 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D05 DISP0_DAT5 122 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D06 DISP0_DAT6 123 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D07 DISP0_DAT7 124 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D10 DISP0_DAT10 127 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D11 DISP0_DAT11 133 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D12 DISP0_DAT12 134 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D13 DISP0_DAT13 135 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D14 DISP0_DAT14 136 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D15 DISP0_DAT15 137 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D18 DISP0_DAT18 140 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D19 DISP0_DAT19 141 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D20 DISP0_DAT20 142 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D21 DISP0_DAT21 143 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D22 DISP0_DAT22 144 #LCD Interface CN4 and CN8 LCD FPCs
LCD_D23 DISP0_DAT23 145 #LCD Interface CN4 and CN8 LCD FPCs
JP_OPTION# EIM_OE 57 Jumper, GPIO HD8 pin 23
JP_SD_BOOT# EIM_RW 58 Boot jumper HD8 pin 25
ACCEL_INT EIM_CS0 55 #Accelerometer Accelerometer IRQ
EN_USB_5V EIM_A16 54 #USB Onboard USB power FET
TOUCH_SPI_CLK EIM_A18 52 #Touch Controller Onboard Resistive Touch Controller
TOUCH_SPI_CS# EIM_A19 51 #Touch Controller Onboard Resistive Touch Controller
TOUCH_SPI_MOSI EIM_A20 50 #Touch Controller Onboard Resistive Touch Controller
TOUCH_SPI_MISO EIM_A21 49 #Touch Controller Onboard Resistive Touch Controller
BOOT_SPI_1_CLK EIM_D16 80 #SPI Flash Onboard SPI flash
BOOT_SPI_1_MISO EIM_D17 81 #SPI Flash Onboard SPI flash
BOOT_SPI_1_MOSI EIM_D18 82 #SPI Flash Onboard SPI flash
BOOT_SPI_1_CS1# EIM_D19 83 #SPI Flash Onboard SPI flash
I2C_1_CLK EIM_D21 85 #I2C Onboard I2C Peripherals
UART3_TXD EIM_D24 88 ttymxc2 TXD #FPGA Crossbar
UART3_RXD EIM_D25 89 ttymxc2 RXD #FPGA Crossbar
I2C_1_DAT EIM_D28 92 #I2C Onboard I2C Peripherals
UART3_HS2 EIM_D30 94 ttymxc2 RTS #FPGA Crossbar
UART3_HS1 EIM_D31 95 ttymxc2 CTS #FPGA Crossbar
EN_CAN# EIM_BCLK 191 CAN Xceiver enable Onboard CAN transceivers
FPGA_RESET EIM_EB0 60 #FPGA reset pin Onboard FPGA
TOUCH_REM_IRQ EIM_DA0 64 GPIO HD6 pin 12
SPI_REM_CLK EIM_DA2 66 #SPI HD6 pin 4
5V_REG_PWM_MODE EIM_DA4 68 Onboard Regulator Option [3] Onboard Regulator
EN_HUB_3.3V EIM_DA5 69 #USB Onboard USB HUB
PUSH_SW_1# EIM_DA9 73 Button SW1 Home Button
PUSH_SW_2# EIM_DA10 74 Button SW2 Back Button
SPI_REM_MISO EIM_DA11 75 #SPI HD6 pin 8
TOUCH_LOCAL_IRQ EIM_DA12 76 Touch Interrupt Onboard Touch controllers
ACCEL_2_INT EIM_DA15 79 #Accelerometer Accelerometer IRQ
  1. The pad name does not often correspond with the functionality of the IO we use, but can be used to reference the pad in the CPU manual.
  2. This does not contain all of the functions possible for a pin, but the common functions as they are used on our off the shelf basebords. Consult the i.MX6 CPU Reference manual for a complete list.
  3. Can change to PWM mode on the onboard regulator. This will lower efficiency of the regulator raising power consumption, but it reduces the audible noise heard on lower current consumption.

FPGA GPIO Table

The FPGA GPIO can also be accessed through the sysfs API. These are available at GPIOs 224 to 255. Not all of the reserved pins are used on this design, but they will be reserved by the kernel.

Name GPIO Number Default Crossbar Mode Location
UART3_RXD (TTYMXC2_RXD) 224 COM3_RXD_232_3V (13) CPU pin EIM_D25 (89)
UART5_RXD (TTYMXC4_RXD) 225 COM3_RXD_232_3V (12) CPU pin KEY_ROW1 (105)
UART3_CTS (TTYMXC2_CTS) 226 GPIO (31) CPU pin EIM_D31 (95)
UART4_RXD (TTYMXC3_RXD) 227 RXD3_485_3V (10) CPU pin KEY_ROW0 (103)
UART2_CTS (TTYMXC1_CTS) 228 BT_RTS (1) CPU pin SD4_DAT6 (46)
UART3_RTS (TTYMXC2_RTS) 229 GPIO (31) CPU pin EIM_D30 (94)
DIO_8 230 GPIO (31) HD8 pin 25
DIO_9 231 GPIO (31) HD8 pin 23
TXD1_485 232 TTYMAX1_TXD (19) HD1 pin 1/6 (RS485+-)
TXD2_485 233 TTYMAX0_TXD (16) HD2 pin 1/6 (RS485+-)
TXD3_485 234 TTYMXC3_TXD (14) HD3 pin 1/6 (RS485+-)
TXEN1_485 235 TTYMAX1_TXEN (20) HD1 RS485 TX enable
TXEN2_485 236 TTYMAX0_TXEN (17) HD2 RS485 TX enable
BT_EN 237 GPIO Only Register
WL_EN 238 GPIO Only Register
BT_CTS 240 TTYMXC1_RTS (6) Onboard Bluetooth CTS
BT_RXD 241 TTYMXC1_TXD (15) Onboard Bluetooth RXD
UART2_RXD (TTYMXC1_RXD) 242 BT_TXD (2) Onboard Bluetooth TXD
DIO_0 243 GPIO (31) HD8 pin 5
DIO_1 244 GPIO (31) HD8 pin 7
DIO_2 245 GPIO (31) HD8 pin 9
DIO_3 246 GPIO (31) HD8 pin 11
DIO_4 247 GPIO (31) HD8 pin 10
DIO_5 248 GPIO (31) HD8 pin 12
DIO_6 249 GPIO (31) HD8 pin 14
DIO_7 250 GPIO (31) HD8 pin 16
FPGA_IRQ_1 251 GPIO (31) CPU pin GPIO_4 (4)
Reboot 254 N/A (GPIO only) Register
TTYMAX0_RXD 268 RXD2_485_3V (9) FPGA Generated UART
TTYMAX1_RXD 269 RXD1_485_3V (8) FPGA Generated UART
TTYMAX2_RXD 270 COM1_RXD_232_3V (11) FPGA Generated UART
TXEN3_485 271 TTYMXC3_TXEN (26) HD3 RS485 TX enable
COM1_TXD_232_3V 272 TTYMAX2_TXD (22) HD1 pin 3
COM2_TXD_232_3V 273 TTYMXC4_TXD (3) HD2 pin 3
COM3_TXD_232_3V 274 TTYMXC2_TXD (4) HD3 pin 3
COM1_RTS_3V 276 TTYMAX2_RTS (24) HD1 pin 8
TTYMAX0_CTS 277 GPIO (29) FPGA Generated UART
TTYMAX1_CTS 278 GPIO (29) FPGA Generated UART
TTYMAX2_CTS 279 GPIO (29) FPGA Generated UART
MT_LCD_PRESENT 284 GPIO Only Register
EN_SPKR 285 GPIO Only Regulator AMP enable

I2C

The i.MX6 CPU implements a standard I2C interface at 100khz that is compatible with fast mode for 400khz operation. The CPU has 2 I2C buses used on the TS-7990.

I2C 0 is used for many onboard peripherals only, but I2C 1 is unused and brought out to the DIO header pins 1 (DAT) and 3 (CLK).

/dev/i2c-0
Address Device
0x0A SGTL5000 audio codec
0x1C Accelerometer
0x28-0x2F FPGA
0x4A Supervisory Microcontroller
0x5C [1] Capacitive Touch Controller
0x68 RTC
  1. LXD option only

The kernel I2C device node is available at /dev/i2c-<bus number>. The i2c-tools (i2cdetect, i2cget, i2cset) suite can be used to manipulate the bus. It is also possible to create a custom application using the I2C device interface API.

Interrupts

The i.MX6 CPU GPIO are also able to function as interrupts on rising and falling edges. This is accessible from the kernel as well as userspace. Userspace IRQs are exposed through the sysfs gpio mechanism. This example will trigger on a falling edge for GPIO 48:

echo "48" > /sys/class/gpio/export
echo "in" > /sys/class/gpio/gpio48/direction
echo "falling" > /sys/class/gpio/gpio48/edge

From here, an application can poll() or select() on the "/sys/class/gpio/gpio48/value" file and will return when the edge setting has been triggered:

#include <stdio.h>
#include <stdlib.h>
#include <fcntl.h>
#include <sys/select.h>
#include <sys/stat.h>
#include <unistd.h>
 
int main(int argc, char **argv)
{
	char gpio_irq[64];
	int ret, irqfd = 0, i = 0;
	fd_set fds;
	FD_ZERO(&fds);
	int buf;
 
	if(argc < 2) {
		printf("Usage: %s <gpio number>\n", argv[0]);
		return 1;
	}
 
	snprintf(gpio_irq, sizeof(gpio_irq), "/sys/class/gpio/gpio%d/value", atoi(argv[1]));
	irqfd = open(gpio_irq, O_RDONLY, S_IREAD);
 
	if(irqfd == -1) {
		printf("Could not open IRQ %s\n", argv[1]);
		printf("Make sure the GPIO is already exported", argv[1]);
		return 1;
	}

	// Read first since there is always an initial status
	ret = read(irqfd, &buf, sizeof(buf));

	while(1) {
		FD_SET(irqfd, &fds);
		// See if the IRQ has any data available to read
		ret = select(irqfd + 1, NULL, NULL, &fds, NULL);
 
		if(FD_ISSET(irqfd, &fds))
		{
			FD_CLR(irqfd, &fds);  //Remove the filedes from set
			printf("IRQ detected %d\n", i);
			fflush(stdout);
			i++;
			
			/* The return value includes the actual GPIO register value */
			read(irqfd, &buf, sizeof(buf));
			lseek(irqfd, 0, SEEK_SET);
		}
 
		//Sleep, or do any other processing here
		usleep(100000);
	}
 
	return 0;
}

This example can be run as "./irqtest 48" which will echo every time the pin changes but not consume any CPU time while waiting for an edge to occur.

Jumpers

The TS-TPC-7990 has a set of jumpers located on the DIO Header near the edge of the SBC. These jumpers control a number of aspects of the TS-7990's behavior. The jumpers are labeled on the silkscreen rather than numbered:

Label Description
SD Boot When jumper is set, boot kernel and Debian from the SD card. Otherwise boot kernel and Debian from eMMC. This jumper influences U-Boot behavior.
U Boot When jumper is set, pause booting in U-Boot and drop to a U-Boot shell. Otherwise boot straight to Debian.
CAN When jumper is set, adds a 120 ohm termination resistor across CAN0 H and L pins.

LEDs

The kernel provides access to control the LEDs using the sysfs:

# Set Red led on
echo 1 > /sys/class/leds/red-led/brightness
# Set Red led off
echo 0 > /sys/class/leds/red-led/brightness

# Set Green led on
echo 1 > /sys/class/leds/green-led/brightness
# Set Green led off
echo 0 > /sys/class/leds/green-led/brightness

The kernel provides various triggers that can be useful for debugging purposes. The trigger for a given LED is in its directory:

echo "heartbeat" > /sys/class/leds/red-led/trigger
Trigger value LED toggles on
none Default, no action
mmc0 MicroSD card activity
mmc1 eMMC activity
mmc2 WIFI SDIO activity
timer 2hz blink
oneshot Blinks after delay. [1]
heartbeat Similar to timer, but varies the period based on system load
backlight Toggles on FB_BLANK
gpio Toggle based on a specified gpio. [2]
cpu0 Blink on CPU core 0 activity
cpu1 Blink on CPU core 1 activity
cpu2 Blink on CPU core 2 activity
cpu3 Blink on CPU core 3 activity
default-on Only turns on by default. Only useful for device tree.
transient Specify on/off with time to turn off. [3]
flash/torch Toggle on Camera activation. Not currently used.
  1. See the Kernel documentation for more details
  2. When this trigger is set, a "gpio" file appears in the same directory which can be used to specify what GPIO to follow when it blinks
  3. See the Kernel documentation for more details

MicroSD Card Interface

The i.MX6 SDHCI driver supports MicroSD (0-2GB), MicroSDHC (4-32GB), and MicroSDXC(64GB-2TB). The cards available on our website on average support up to 16MB/s read, and 22MB/s write using this interface. The linux driver provides access to this socket at /dev/mmcblk1 as a standard Linux block device.

This graph shows our SD write endurance test for 40x TS-7553 boards. These boards are running a doublestore stress test on 4GB Sandisk MicroSD cards. A failure is marked on the graph for a card once a single bit of corruption is found.

See chapter 67 of the i.MX6 reference manual for the specific CPU variant for more information on the mmc controller.

We have performed compatibility testing on the Sandisk MicroSD cards we provide. We do not suggest switching brands/models without your own qualification testing. While SD cards specifications are standardized, in practice cards behave very differently. We do not recommend ATP or Transcend MicroSD cards due to known compatibility issues.

Our testing has shown that on average microSD cards will last between 6-12TB. After this cards can begin to experience corruption, or stop being recognized by the host PC. This may be enough storage for many applications to write for years without problems. For more reliable storage consider using the eMMC. Our endurance testing showed a write lifetime on average of about 123 TiB.

MicroSD cards should not have power removed during a write or they will have disk corruption. Keep the filesystem mounted read only if this is a possibility. It is not always possible for fsck to recover from the types of failures that will be seen with SD power loss. Consider using the eMMC for storage instead which is far more resilient to power loss.

RTC

This board uses a M41T00S STMicro Battery Backed RTC using an external and replaceable coin cell battery. This RTC is connected to the CPU via I2C and is handled by the kernel and is presented as a standard RTC device in linux.

With the provided battery this is expected to last 6 years. The RTCs are tested by the manufacturer to +-35ppm at 25C, which is about 1.53 minutes per month.

SATA

Note: SATA is functional on Rev. B or newer PCBs.

SATA is located on the mini PCIe header on the TS-7990. This is intended to be used with mSATA style drives to provide fast embedded storage.

The i.MX6 Quad and Dual include integrated SATA II support. This interface has been tested to provide 135MiB/s write, and 170MiB/s read in sequential accesses. In linux this is accessed through the /dev/sda device:

[    1.768036] ata1: SATA link up 3.0 Gbps (SStatus 123 SControl 300)
[    1.785377] ata1.00: ATA-8: MKNSSDAT30GB-DX, 507ABBF0, max UDMA/133
[    1.791716] ata1.00: 58626288 sectors, multi 16: LBA48 NCQ (depth 31/32)
[    1.805380] ata1.00: configured for UDMA/133
[    1.810320] scsi 0:0:0:0: Direct-Access     ATA      MKNSSDAT30GB-DX  507A PQ: 0 ANSI: 5
[    1.819459] sd 0:0:0:0: [sda] 58626288 512-byte logical blocks: (30.0 GB/27.9 GiB)
[    1.827427] sd 0:0:0:0: [sda] Write Protect is off
[    1.832812] sd 0:0:0:0: [sda] Write cache: enabled, read cache: enabled, doesn't support DPO or FUA
[    1.843621]  sda: sda1
[    1.847381] sd 0:0:0:0: [sda] Attached SCSI dis

U-Boot includes a script to boot off of a SATA drive. The SATA drive should be formatted just like the SD card examples. In U-Boot run:

env set bootcmd 'run sataboot;'
env save

This will ignore the SD boot jumper and boot directly to SATA.

Sleep Mode

The TS-TPC-7990 implements a very low power sleep mode using the onboard supervisory microcontroller. This allows powering off the i.MX6 CPU entirely. While in this mode the entire board will use about 6 mW for resistive or 26 mW for capacitive touch screens.

The board can be woken 2 ways:

  • Timer - sleep mode requires specifying an amount of seconds to sleep (up to 16777215).
  • Touch - The touch controllers are kept powered on while in sleep mode.

The sleep mode can be entered at a low level calling "tshwctl --sleep 60" to sleep for 60 seconds, but this typically should not be called directly. This would be equivalent to disconnecting power while booted which can cause data loss.

The Yocto, Debian, or Ubuntu distributions use systemd to manage shutdown. When systemd shuts down it will call all executables in /lib/systemd/system-shutdown/. Create a script silabs-sleep in this directory with these contents:

#!/bin/bash

tsmicroctl --sleep 60

And make it executable:

chmod a+x /lib/systemd/system-shutdown/silabs-sleep

Now the board will sleep immediately following a shutdown. It is safe during the sleep mode to disconnect power.

SPI

SPI is located on the DIO header and is available in software via /dev/spidev1.2

This platform includes one SPI interface which is accessible through either kernel drivers or userspace using the /dev/spi interface.

Developing or implementing kernel SPI drivers are beyond the scope of this document, but the build environment is described in the kernel compile guide.

The /dev/spidev1.2 interface can be accessed using the userspace API. For more information see the documentation and sample code:

Onboard SPI Flash

This board includes 8 MiB of SPI flash using a Micron N25Q064A13ESE40F. The CPU uses this for the initial boot to load U-Boot, as well as the U-Boot environment. In Linux this is accessed with the /dev/mtdblock devices.

Bytes Size Description
0x000000-0x0003FF 1 KB Unused
0x000400-0x0FFFFF 0.999 MiB U-Boot
0x100000-0x101FFF 8 KiB U-Boot environment #1
0x102000-0x17FFFF 504 KiB Unused
0x180000-0x181FFF 8 KiB U-boot environment #2
0x182000-0x1FFFFF 504 KiB Unused
0x200000-0x201DE7 7655 B Splash Screen
0x201DE8-0x700000 4.993 MiB Unused

UARTs

This board uses UARTs from both the CPU and the FPGA. The CPU UART 0 (/dev/ttymxc0) is a dedicated console for Linux and U-Boot and not suggested to be reused. The other CPU UARTs for ttymxc1 through ttymxc4 are usable for end applications. These support up to 5Mb/s UART data with DMA.

The FPGA also emulates a MAX3100 UART interface accessible at /dev/ttyMAX0-2. These UARTs support a total throughput of about 115200[1]. These UARTs include hardware that makes implementing RS-485 half duplex software extremely simple. If higher throughput is needed, the FPGA crossbar can be adjusted to use a CPU UART with TXEN support instead.

Note: Our SPI interface matches the max3100 almost entirely, except optionally a single 8-bit transaction can be sent to act as a chip select between the three uarts supported on our interface. The default FPGA supports 3 UARTs on this interface. This is handled automatically by our driver (max3100-ts).

The RS-485 half duplex direction control is built into the ttyMAX UARTs. By default, they are connected to the RS-485 ports and no code is required for the transmit enable to toggle. The CPU UARTs however do not have transmit enable built in. The FPGA provides support for transmit enable on ttymxc1/ttymxc3, but additional setup steps are required so the FPGA can properly time the transmit enable output. The FPGA needs to know the baud rate, and symbol size (data bits, parity, stop bits) that the UART will be run at

For example:

# Configure ttymxc1 and ttymxc3 as 115200, 8n1

stty -F /dev/ttymxc1 115200 cs8 -cstopb
tshwctl --autotxen 1

stty -F /dev/ttymxc3 115200 cs8 -cstopb
tshwctl --autotxen 3

The 'tshwctl' tool will read the UART settings and set up the FPGA timing for TXEN automatically. The baud rate and mode settings must be set before running the 'tshwctl' command!

When using the FPGA for either the ttyMAX UARTs or the CPU UARTs, the TXEN timing will happen well under a single bit time [2] of any baud rate possible by the hardware.

All of these UARTs are accessed using the standard /dev/ interfaces. See these resources for information on programming with UARTs in Linux.

  1. Idle periods do not count towards the total throughput limitation.
  2. This is a requirement for half duplex MODBUS

All of the CPU UARTs are routed through the FPGA Crossbar MUX to allow rerouting, or to enable flow control for a UART. These mappings can be changed by adjusting the crossbar, but these are the default mappings:

UART Type TX (or 485 +) RX (or 485 -) CTS RTS
ttymxc0 USB [1] Onboard Silabs Onboard Silabs N/A N/A
ttymxc1 TTL 1.8 Onboard Bluetooth Onboard Bluetooth Onboard Bluetooth Onboard Bluetooth
ttymxc2 RS232 COM3_TXD_232_3V / COM3 header pin 3 COM3_RXD_232_3V / COM3 header pin 2 N/A N/A
ttymxc3 RS485 TXD3_485_3V / COM3 header pin 1 RXD3_485_3V / COM3 header pin 6 N/A N/A
ttymxc4 RS232 COM2_TXD_232_3V / COM2 header pin 3 COM2_RXD_232_3V / COM2 header pin 2 N/A N/A
ttyMAX0 RS485 TXD2_485_3V / COM2 header pin 1 RXD2_485_3V / COM2 header pin 6 N/A N/A
ttyMAX1 RS485 TXD1_485_3V / COM1 header pin 1 RXD1_485_3V / COM1 header pin 6 N/A N/A
ttyMAX2 RS232 COM1_TXD_232_3V / COM1 header pin 3 COM1_RXD_232_3V / COM1 header pin 2 N/A COM1_RTS_232_3V / COM1 header pin 7
  1. This is connected to the onboard microcontroller which presents the USB as a cp210x USB serial device on P2. This is not intended for application use.

USB

USB OTG

The TS-7990 brings out a USB device port on P1 which can allow the board to act as a USB device. Several gadget device drivers are compiled into the default kernel. Additional devices can be compiled into the kernel by following the section here.

USB Serial

modprobe g_serial use_acm=1

This will create a /dev/ttyGS0 immediately after this modprobe is run. When this USB is connected to another Linux system this will show up as /dev/ttyACM0. See the kernel documentation for more information:

USB Ethernet

modprobe g_ether

This provides a usb0 network interface which simulates an ethernet network connection between the host pc and the i.MX6. This uses the Ethernet CDC driver on the host system where it is connected. Under Windows the inf file will be needed:

USB Host

The TS-7990 provides 4 standard USB 2.0 host supporting 480Mb/s. Two are on the Type A connector, one is on the XBEE module for use with cellular MODEM modules, and one is on the mini PCIe header. Most commonly USB drivers built into Linux handle the USB communication but low level USB communication is possible using libusb.

A GPIO is available to toggle power to USB devices. This can be used to save power, or to reset USB devices that get stuck in a bad state.

# Power disabled
echo 0 > /sys/class/leds/en-usb-5v/brightness
sleep 2 # let any devices reset
# Enable power
echo 1 > /sys/class/leds/en-usb-5v/brightness

Watchdog

The kernel provides an interface to the watchdog driver at /dev/watchdog. Refer to the kernel documentation for more information:

WIFI

This board uses an ATWILC3000-MR110CA IEEE 802.11 b/g/n Link Controller Module With Integrated Bluetooth® 4.0. Linux provides support for this module using the wilc3000 driver.

Summary features:

  • IEEE 802.11 b/g/n RF/PHY/MAC SOC
  • IEEE 802.11 b/g/n (1x1) for up to 72 Mbps PHY rate
  • Single spatial stream in 2.4GHz ISM band
  • Integrated PA and T/R Switch Integrated Chip Antenna
  • Superior Sensitivity and Range via advanced PHY signal processing
  • Advanced Equalization and Channel Estimation
  • Advanced Carrier and Timing Synchronization
  • Wi-Fi Direct and Soft-AP support
  • Supports IEEE 802.11 WEP, WPA, and WPA2 Security
  • Supports China WAPI security
  • Operating temperature range of -40°C to +85°C

External Interfaces

Buttons

The back of the unit includes two buttons for general use. These can be sampled with:

echo 73 > /sys/class/gpio/export # Home
echo 74 > /sys/class/gpio/export # Back

echo in > /sys/class/gpio/gpio73/direction
echo in > /sys/class/gpio/gpio74/direction

# These will read 1 when not pressed, and 0 when pressed
cat /sys/class/gpio/gpio73/value
cat /sys/class/gpio/gpio74/value

Displays

The TS-TPC-7990 includes support for three different displays. U-boot will print out the detected display during startup:

 Display: LXD-WSVGA (1024x600)

LXD Display

The LXD is a 1024x600 7" 800 nit display with capacitive touch. The capacitive touch is using a pixcir tango c series controller providing 5 points of touch simultaneously.

Okaya Display

The Okaya is a 800x480 7" 800 nit display with resistive touch. This uses the onboard resistive touch controller the TSC2046. This provides one point of touch.

Microtips Display

The Microtips display is a 800x480 7" 400 nit display with resistive touch. This uses the onboard resistive touch controller the TSC2046. This provides one point of touch.

Audio

The TS-TPC-7990 provides audio output to an AC'97 audio header and an on-board piezo speaker. The piezo speaker can be disabled to force audio output from only the AC97 header:

echo 0 > /sys/class/leds/en-speaker/brightness

The utility 'aplay' can be used to play WAV files as a simple test of audio functionality. The 'arecord' utility will take input from the microphone and create a WAV file:

arecord -d 5 recording.wav
aplay recording.wav

Audio Header

The TS-TPC-7990 includes a 2x5 0.1" pitch header which includes speaker and headphone output, as well as microphone input. This header is compatible with AC'97 which is commonly found on desktop motherboards. Third party cabling can be used to break out the interface to 3.5 mm jacks.

Pin Description
1 MIC
2 GND
3 MIC Bias
4 GND
5 HP_R
6 NC
7 SPKR+
8 SPKR-
9 HP_L
10 NC

TS-7990-Audio.png

Speaker

Audio Frequency Response

The TS-TPC-7990 includes an on-board piezo speaker for basic audio. It can produce 81 dB of sound pressure with a 4 kHz square wave. This speaker is ideal for implementing alarm and siren type of noises.

amixer sset 'PCM' 100%
amixer sset 'Headphone' 100%

# This will produce a 1 second 4 kHz beep from the speaker at full volume.
timeout 1s speaker-test -f 4000 --test=sine

# 2 kHz
timeout 1s speaker-test -f 2000 --test=sine

COM Headers

The COM ports all use 0.1" pitch 2x5 headers. You can use the RC-DB9 cable in the accessories section to bring this to a DB9 cable.

COM1 Header
Pin Description
1 COM1_485+ (/dev/ttyMAX1)
2 COM1_232_RXD (dev/ttyMAX2)
3 COM1_232_TXD (/dev/ttyMAX2)
4 NC
5 GND
6 COM1_485- (/dev/ttyMAX1)
7 COM1_232_RTS (/dev/ttyMAX2)
8 COM1_232_CTS (/dev/ttyMAX2)
9 NC
10 NC
COM2 Header
Pin Description
1 COM2_485+ (/dev/ttyMAX0)
2 COM2_232_RXD (/dev/ttymxc4)
3 COM2_232_TXD (/dev/ttymxc4)
4 CAN_2_H (can0 interface)[1]
5 GND
6 COM2_485-
7 NC
8 NC
9 CAN_2_L (can0 interface) [1]
10 NC
COM3 Header
Pin Description
1 COM3_485+ (/dev/ttymxc3) [2]
2 COM3_232_RXD (/dev/ttymxc2)
3 COM3_232_TXD (/dev/ttymxc2)
4 CAN_3_H (can1 interface) [3]
5 GND
6 COM3_485- (/dev/ttymxc3) [2]
7 NC
8 NC
9 CAN_3_L (can1 interface) [3]
10 NC
TS-7990-COM.png
  1. 1.0 1.1 This can bus includes 120ohm termination
  2. 2.0 2.1 This uart must be set up before RS485 will work. See the #COM Ports section for more information.
  3. 3.0 3.1 Has optional termination 120ohm termination if DIO header pins 21/22 are shorted.

Mini PCIe

The Mini PCIe socket provides USB, mSATA, and a PCIe lane. The TS-TPC-7990 can support a SIM card socket connected to the Mini PCIe interface, but it is not populated by default. Contact us for more information on supporting this header.

Power Connector

The TS-TPC-7990 includes a removable terminal block (Eurocomp ETB205/3A) which accepts 8-36 V, or 5 V DC for the power input. Only one power input may be connected at a time. A typical power supply for this platform should provide 25 W; see the power consumption section for more information on power requirements based on specific CPU and peripheral configurations.

Pin Description
1 [1] 8-36 VDC
2 5 VDC
3 GND
  1. Near 8-36 V label

TS-TPC-7990 removable power connector.png

WARNING: Connecting both 8-36 V and 5 V inputs can damage the device and power sources.

DIO Header

The DIO header includes I2C, SPI, GPIO, and jumpers. The TS-DC799-SILO daughter card is also supported on this header. If pin 7 is held low at the start of U-Boot then all of the DIO will be used for managing the TS-DC799-SILO daughter card. However, after the unit is started up and the pins configured, any of the DIO pins can be used as normal GPIO.

Pin Description
1 DC_I2C_DAT (/dev/i2c-1)
2 VIN
3 DC_I2C_CLK (/dev/i2c-1)
4 VIN
5 SUP_CAP_ANALOG
6 SW_5V [1]
7 GPIO 244 (FPGA DIO_1_SEL0) [2]
8 3.3V rail
9 GPIO 245 (FPGA DIO_2_SEL1)
10 GPIO 247 (FPGA DIO_4_PWM)
11 GPIO 246 (FPGA DIO_3_SEL2)
12 GPIO 248 (FPGA DIO_5_SILAB_DATA)
13 DC_SPI_MISO
14 GPIO 249 (FPGA DIO_6_POWER_FAIL)
15 SUP_CAP_4.6V
16 GPIO 250 (FPGA DIO_7)[3]
17 DC_SPI_MOSI
18 USB_OTG_M
19 DC_SPI_CLK
20 USB_OTG_P
21 CAN_3_L [4]
22 CAN_TERM_3
23 JP_OPTION# [5], GPIO 231 (FPGA DIO_9), DC_SPI_CS#
24 Ground
25 JP_SDBOOT [6], GPIO 230 (FPGA DIO_8)
26 Ground

TS-7990-DIO.png

  1. This 5 V rail is switched on/off with power.
  2. If this pin is low on u-boot's startup, u-boot will assume the TS-SILO daughtercard is present and this may prevent boot.
  3. This pin defaults to an RTS signal. To use this as DIO run:
    DIO_7=GPIO tshwctl --set
    
  4. It is not recommended to use this pin as a CAN signal, this is meant to optionally be connected to the CAN termination resistor via a jumper.
  5. If this pin reads low on startup it will stop in U-Boot. After the initial read this pin can be reused as a GPIO.
  6. This pin is latched on startup and sets the "jpsdboot" value. This decides if the default scripts boot to SD or eMMC.

XBee Header

For using this header to connect a standard XBee peripheral, contact us here; by default the TS-TPC-7990 only supports Nimblelink radios on this header.

Some basic commands to manipulate pins on this interface:

# Enable 3.3V to XBee header:
tshwctl --addr 58 --poke 0x2

# Take XBee out of reset:
eval $(tshwctl --addr 59 --peek)
tshwctl --addr 59 --poke $(($addr59 | 0x20))

The Nimbelink modem can use the USB on this header, but still needs power enabled:

# Enable 4 V to Nimbelink
tshwctl --addr 58 --poke 0x3

# The Nimbelink needs to be taken out of reset after being turned on:
eval $(tshwctl --addr 59 --peek)
tshwctl --addr 59 --poke $(($addr59 | 0x20))
# The nimblelink can take ~ 10-15 seconds to show up on USB.
Pin Description
1 VIN (3.3V or 4V based on FPGA reg 58)
2 XBEE_RXD
3 XBEE_TXD
4 GND
5 Not connected
6 VIN
7 USB_DN4_P
8 USB_DN4_M
9 GND (DTR)
10 GND
11 GND
12 (CTS) Not connected
13 Not connected
14 3.3V (VREF)
15 GND
16 GND (RTS)
17 Not connected
18 Not connected
19 Not connected
20 GND (POWER_ON)

TS-7990-XBEEHeader.png

USB Ports

The TS-TPC-7990 includes 2 standard type 'A' USB ports on J8. Two more ports are avaialble on other interfaces such as the Mini PCIe header, and the XBee header for supporting NimbleLink cell modems.

Peripherals

TS-DC799-SILO

TS-DC799-SILO

The TS-TPC-7990 supports TS-SILO via the TS-DC799-SILO daughter card. TS-SILO technology is a UPS-like system that uses supercapacitors to deliver up to 100 seconds of backup power. Providing protection against short power glitches as well as backup power to perform a safe shutdown in the event of a long power loss. A safe shutdown is critical in applications using writable storage media in order to prevent filesystem damage.

A boot cycle with the TS-DC799-SILO daughter card will typically go through these steps:

  • The TS-TPC-7990 will detect the TS-DC799-SILO daughter card on startup and enable charging the supercapacitors.
  • U-Boot will load the kernel, device tree, and optionally the FPGA.
  • U-Boot will then wait until the supercapacitors are charged to a configurable percentage level.
  • Once the supercapacitors are charged and VIN is still valid, U-Boot will then begin booting the kernel.
  • In Linux, a daemon monitors a GPIO pin to detect power failure. If a power failure occurs, the daemon will monitor the charge of the supercapacitors.
  • If the supercapacitor charge falls below a specific threshold, the daemon will start a safe reboot of the TS-TPC-7990.
  • The unit will reboot to U-Boot and wait as it did above.
    • If power does not return, the supervisory microcontroller will remove power from the i.MX6 and slowly allow the caps to fully drain.
    • If power does return, then the caps will be recharged and the unit will boot up again as normal.

If the "No Charge" jumper is set, then U-Boot will not attempt to charge the supercapacitors and will begin booting the kernel as soon as possible. This is beneficial for development and testing without having to wait for the supercapacitors to charge.

On startup, U-Boot evaluates pin 7 on the DIO header. If this pin is low (logic 0) then U-Boot will assume the presence of the TS-DC799-SILO daughter card. Pins 9, 10, 11, and 14 will then also be configured to communicate with the charging circuit on the daughter card.

The percentage of charge that U-Boot will stall booting for is set via the environment variable "silochargpct". The percentage is a linear representation of the charge voltage from 0 to 12 VDC. The default we specify is 90% and can be changed with the following commands in U-Boot:

env set silochargpct 80
env save

The value chosen should be a high enough charge to support power being removed immediately after the kernel begins booting. That is, a high enough charge to fully boot the system and fully reboot all on the supercapacitor support. If the charge is too low and backup power fails before a safe reboot occurs then it is possible for filesystem corruption to occur.

The supercapacitors will charge up to 12 VDC total and are able to sustain the TS-TPC-7990 as long as their voltage remains above 6 VDC. A full charge when completely drained will take approximately 2 minutes. Fully charging the supercapacitors from a partial charge, 6 VDC, will take approximately 1 minute.

Charging Graph

The supercapacitors discharge rate will vary depending on power consumption of the whole platform. The graph below shows a fast charge of a loaded CPU and GPU on the TS-TPC-7990-QMW3E quad core with the PCAP display. The slow discharge shows a TS-TPC-7990-SMN2E solo with the resistive which is using the powersaving CPU governor, LCD off, and an idle CPU.

Discharge Graph

Once booted to Linux, the tssilomon service is started. This script monitors for input power failure. If a power failure is detected, the daemon will sample the charge level of the supercapacitors. If the charge level falls below 90% then a reboot is initiated. The supercapacitors can provide roughly 35 to 85 seconds of backup power to the TS-TPC-7990 when at a 90% charge level.

U-Boot the next boot until the supercapacitors have finished charging again, or the power runs out and the power rails collapse. The on-board supervisory microcontroller will power down the main power rails and ARM CPU so all power and signals available on headers will collapse cleanly rather than fluctuating.

TS-DC799-POE

This daughter card provides PoE+ support for the TS-TPC-7990. This allows the whole platform to be fully powered via PoE+ on J1, the Ethernet connector near the RTC battery and Mini PCIe connector.

ts-dc799-poe-a1-thumb.jpg

This daughter card can be detected by the POE_DETECT# signal which can be read on the EIM_DA11 GPIO.

Specifications

Power Specifications

The TS-TPC-7990 includes 2 methods for powering the device. A 5 VDC input, and a 8-36 VDC input on a single power connector. Only a single power input may be connected at a time, connecting both may cause damage to the device or the power supply.

Input Min voltage Max voltage
5 VDC input 4.75 5.25
8-36 VDC Input 8.00 36.00

Power Consumption

The power consumption of the platform can vary depending on the build configuration and run time application/peripheral use. The majority of power savings occur when the CPU and GPU are idle. It is also possible to disable the Ethernet PHY for additional savings. The backlight intensity can be reduced for significant power savings as well.

# Put ETH PHY in reset
echo 116 > /sys/class/gpio/export
echo high > /sys/class/gpio/gpio116/direction

# Put USB hub in reset
echo 43 > /sys/class/gpio/export
echo low > /sys/class/gpio/gpio43/direction

# Lower backlight to 50%
echo 4 > /sys/class/backlight/backlight_local_lcd/brightness

# Disable backlight
echo 0 > /sys/class/backlight/backlight_local_lcd/brightness

In the measurements below, Ethernet is not connected unless otherwise specified and USB serial is disconnected during the measurement. The CPU test is 5x parallel processes of "openssl speed", and the GPU test is Qt5CinematicExperience in the Yocto image.

These tests are performed powering the unit through 5 VDC.

TS-7990 solo without WIFI
Test Max Watts Average Watts
CPU 100% + GPU loaded (LCD 100%) + IO + Ethernet 12.00 (2.40 A) 8.95 (1.79 A)
CPU 100% (LCD 100%) 8.90 (1.78 A) 7.80 (1.56 A)
CPU Idle (LCD 100%) 8.35 (1.67 A) 7.20 (1.44 A)
CPU Idle (LCD 50%) 8.60 (1.72 A) 6.10 (1.22 A)
CPU Idle (LCD 0%) 4.75 (0.95 A) 3.90 (0.78 A)
CPU Idle (LCD 0%), USB HUB off 4.10 (0.82 A) 3.35 (0.67 A)
CPU Idle (LCD 0%), USB HUB off, Ethernet PHY in reset 4.05 (0.81 A) 2.95 (0.59 A)
CPU Idle (LCD 100%) + CPU Ethernet 9.20 (1.84 A) 5.70 (1.14 A)
CPU Idle (LCD 100%) + USB Ethernet 5.85 (1.70 A) 5.70 (1.14 A)
TS-7990 quad core with WIFI
Test Max Watts Average Watts
CPU 100% + GPU loaded (LCD 100%) + IO + Ethernet 18.85 (3.77 A) 11.25 (2.25 A)
CPU 100% (LCD 100%) 12.20 (2.44 A) 8.65 (1.73 A)
CPU Idle (LCD 100%) 11.50 (2.30 A) 9.70 (1.94 A)
CPU Idle (LCD 50%) 11.40 (2.28 A) 7.90 (1.58 A)
CPU Idle (LCD 0%) 4.65 (0.93 A) 3.90 (0.78 A)
CPU Idle (LCD 0%), USB HUB off 5.55 (1.11 A) 3.50 (0.70 A)
CPU Idle (LCD 0%), USB HUB off, Ethernet PHY in reset 4.90 (0.98 A) 3.05 (0.61 A)
CPU Idle (LCD 100%) + CPU Ethernet 11.20 (2.24 A) 6.60 (1.32 A)
CPU Idle (LCD 100%) + USB Ethernet 11.60 (2.32 A) 6.70 (1.34 A)

The on-board microcontroller is able to disable power to the rest of the platform and restore power after a specified number of seconds or if the touchscreen receives a touch event. The CPU variants will all draw the same amount of power while in sleep mode, however the touchscreen used will impact overall power draw during sleep. These tests are both at 5 VDC.

Sleep modes
Test Max Average
Resistive touch (Okaya or microtips) 90mW 20mW
Capacitive touch (LXD) 125mW 26mW

Temperature Specifications

The stock CPUs on the TS-TPC-7990 are either the solo core rated for industrial temperatures, or the quad core CPU rated for extended temperatures. The TS-TPC-7990 is designed using industrial components that will support -40C to 85C operation, but on this system the LCD will be the limiting factor for temperature.

Model Number Operating Min Operating Max Storage Min Storage Max
TS-TPC-7990-SMN2E -20C 70C -30C 80C
TS-TPC-7990-SMN3E -20C 60C -30C 70C
TS-TPC-7990-QMW2E -20C 70C -30C 80C
TS-TPC-7990-QMW3E -20C 60C -30C 70C

The default Linux includes a thermal driver to help manage temperatures where the CPU may overheat. When heating up it will throttle itself at the passive temperature until it reaches the cooling temperature, or it if it continues to heat up to the critical temperature the system will reboot and wait in u-boot until

Model Number Cooling Temp [1] Passive Temp [2] Critical/Max Junction Temp [3]
TS-TPC-7990-S**** 75C 85C 105C
TS-TPC-7990-Q**** 75C 85C 100C
  1. CPU stops all throttling below this temperature
  2. CPU begins throttling until the cooling temperature
  3. CPU Max temperature. Linux will shut down to cool the CPU at this temperature. The system will boot to U-Boot and wait for the temperature to drop.

For custom builds with different CPUs these are also exposed in /sys/:

# Passive
cat /sys/devices/virtual/thermal/thermal_zone0/trip_point_0_temp
# Critical
cat /sys/devices/virtual/thermal/thermal_zone0/trip_point_1_temp

The current CPU die temperature can be read with:

cat /sys/devices/virtual/thermal/thermal_zone0/temp


Our test data can be used to estimate the temperature rise of the CPU over the ambient temperature. These are tested without an enclosure in open air. The temperature ranges show the CPU at idle at the low end, to a very high system load at the high end.

Configuration Temp rise over ambient
Solo No Heatsink 21-27C
Solo with HS-50x53x13 18-20C
Quad No Heatsink 16-50C
Quad with HS-50x53x13 10-23C

When the CPU heats up past the cooling temp on a first boot, it will take no action. Heating up past the passive temperature the kernel will cool down the CPU by reducing clocks. This will show a kernel message:

[  158.454693] System is too hot. GPU3D will work at 1/64 clock.

When it cools back down below the cooling temperature it will resume normal clock speed.

[  394.082161] Hot alarm is canceled. GPU3D clock will return to 64/64

If the CPU continues heating to the critical temperature it will overheat and reboot. Booting back up U-Boot will block the boot until the temperature has been reduced to the Cooling Temp+5C. This will be shown on boot with:

U-Boot 2015.04-07857-g486fa69 (Jun 03 2016 - 12:04:30)

CPU:   Freescale i.MX6SOLO rev1.1 at 792 MHz
CPU Temperature is 105 C, too hot to boot, waiting...
CPU Temperature is 102 C, too hot to boot, waiting...
CPU Temperature is 99 C, too hot to boot, waiting...
CPU Temperature is 90 C, too hot to boot, waiting...
CPU Temperature is 86 C, too hot to boot, waiting...
CPU Temperature is 84 C, too hot to boot, waiting...
CPU Temperature is 80 C, too hot to boot, waiting...
CPU Temperature is 80 C, too hot to boot, waiting...
CPU Temperature is 80 C, too hot to boot, waiting...
CPU:   Temperature 78 C
Reset cause: WDOG
Board: TS-7990


Stress Test

IO Specifications

The GPIO external to the device are all nominally 3.3V, but will vary depending on if they are CPU/FPGA pins.

The CPU pins can be adjusted in software and will have initial values in the device tree. This allows for adjustment of the drive strength and pull resistor strength of each individual IO pin. See the device tree for further details on a specific IO pin.

The FPGA IO cannot be adjusted further in software.

IO Typical Range Absolute Range Logic Low Logic high Drive strength
External CPU GPIO 0-3.3V -0.5V to 3.3V Rail + 0.3V 0.3 * 3.3V Rail 0.7 * 3.3V Rail 27.5mA
External FPGA GPIO 0.3.3V -0.5-3.75V 0.8 2.0 12mA

Refer to the MachXO Family Datasheet for more detail on the FPGA IO. Refer to the CPU quad or solo datasheet for further details on the CPU IO.

WARNING: Do not drive any IO from an external supply until 3.3V is up on the board. Doing so can violate the power sequencing of the board causing failures or damage.

Rail Specifications

The TS-TPC-7990 generates all rails from either the 8-36 VDC input, or the 5 VDC input. This table does not document every rail. This will only cover those that can provide power to an external header for use in an application.

Rail Current Available Location
3.3V 1A mPCIE/mSATA, HD8 pin 8
5V Quad core 0.5 A, Solo 1.5 A [1] HD8 pin 2/4, USB, mPCIE/mSATA
  1. These limitations are only relevant if 8-36 VDC is supplied into the device.

Revisions and Changes

TS-TPC-7990 PCB Revisions

Revision Changes
A
  • Initial Release
B
  • Changed to Marvell PHY
  • Changed speaker to Piezo to save space, and it is louder for alarm implementations.
  • Added Nimblelink Socket
  • Fixed touch controller to have correct IRQ polarity for sleep mode
  • Changed 5V regulator to provide higher current (2.5 A to 5 A)
  • Fixed SW_5V FET from being held off by offboard RS-232
  • Auto select LCD voltage rails with no specific strapping resistors differentiating build
  • Changed WIFI from TIWI-BLE to equivalent Atmel/Microchip WILC3000 module with 12 year availability.
    • WIFI DOES NOT WORK ON THIS BOARD REVISION
  • Micro USB ports both moved a few mm in to fix interference with daughter cards
  • CN26 modified to support our daughtercards
  • Backlight regulator has GPIO enable allowing backlight to be entirely turned off besides PWM.
  • Removed SIM socket
  • Changed scan on Microtips LCD to rotate 180 degrees to match other LCDs
  • Added SATA/PCIe MUX. Mode is selected in u-boot.
  • Changed 11V regulator
  • Grounded CPU DIO (Ball L21) to identify REV B builds.
  • Additional minor changes for internal production
C
  • WIFI moved to SPI to avoid SDIO bug in wifi chip. WIFI works now with latest kernel.
  • R198 removed means REV C board.
  • Added PCIe reset GPIO. Fixed some devices not working after a software reboot.
  • XBEE_RESET# moved to FPGA GPIO
  • TOUCH_RESET# moved to CPU GPIO so rare i2c bus lockups can be recovered with a reboot.
  • Minor layout fixes
  • Minor changes to CN99 for production

U-Boot Changelog

May-09-2016
  • Initial Release
Nov-16-2016
  • Added support for supercap daughtercard
  • Implemented sleep mode (if silabs rev >= 1)
  • Implemented redundant env
  • Fixed environment being reset when usb initialized on startup
Jan-13-2017
  • Added REV B support
  • Added Marvell Ethernet support
Feb-03-2017
  • Added DC-799-SILO daughtercard support
Feb-17-2017
  • Added check for 64bit ext4 filesystem.
Mar-06-2017
  • Fixed loading correct device tree for REv.A PCBs.
Apr-12-2017
  • Improved supercap support.
    • Draw splash screen before blocking
    • Improved boot time while charging
    • nfsboot/sataboot now support supercap blocking
    • Supercaps are automatically detected and honor the "No Charge" jumper
Jun-07-2017
  • Fixed Rev.A PCBs erroneously detecting silo boards
Jul-28-2017
  • Added support for detecting Rev.C PCBs
Aug-03-2017
  • Fixed regression in TS-SILO support
Nov-14-2018
  • Reduced USB block size to 256B to improve compatibility with USB thumbdrives.
Aug-02-2023
  • Updated to support Rev.E PCBs
  • Updated to support Broadcom Gbit Ethernet PHY

FPGA Changelog

Check the FPGA rev with:

echo $(($(tshwctl --peek --addr 51)>>4))
Rev Changes
1
  • Initial Release
2
  • Added TOUCH_RESET gpio
3
  • Changed FPGA_IRQ_2 into FPGA_RESET
4
  • tristate DC_SPI_CS#
  • ttyMAX uarts use IRQ 0
  • Fixed WIFI clock
  • Fixed default crossbar so all uarts work without regisiter write fixes
  • Fixed DIO_1
5
  • Changed onboard pullup to fix production process.
6
  • Added support for REV B boards.
7
  • Added support for reprogramming Silabs in the field
8
  • Routes DC_SPI_MISO to FPGA_SPI_MISO when the chip select is not asserted. Used to detect silo board automatically.
9
  • Added XBEE_TXD to crossbar at address fpga register 62

You can reload the FPGA during startup for custom FPGAs. If /boot/ts7990-fpga.vme is present during startup you will see u-boot reload this file:

Bytes transferred = 56341 (dc15 hex)
VME file checked: starting downloading to FPGA
Diamond Deployment Tool 3.5
CREATION DATE: Wed Oct 07 11:38:24 2015


Downloading FPGA 53248/56341 completed
FPGA downloaded successfully

Microcontroller Changelog

Revision Changes
0
  • Initial Release
1
  • Added Sleep mode
  • Blinks Silabs LED in low power modes. Sleep mode does this, as well as USB device connected with no power on the main VIN.
6
  • Include support for DC799-SILO daughtercard providing up to 60 seconds of charge when power is lost.

Software Images

Yocto Changelog

Quad/Dual Image Solo/Duallite Image Changes
ts-x11-image-ts4900-quad-20140905235640.rootfs.tar.bz2 ts-x11-image-ts4900-solo-20140908160116.rootfs.tar.bz2
  • Initial Release
ts-x11-image-ts4900-quad-20141119190447.rootfs.tar.bz2 ts-x11-image-ts4900-solo-20141119204157.rootfs.tar.bz2
  • Systemd default
  • Added /usr/lib/openssh/sftp-server (Fixes QtCreator/Eclipse deploy)
  • Added QtQuick
  • Added Sqlite to QT
  • Added early TS-7970 support.
  • Updated kernel with significant fixes, see github for more information.
ts-x11-image-ts4900-quad-20141224171440.rootfs.tar.bz2 ts-x11-image-ts4900-solo-20141224175107.rootfs.tar.bz2
  • Updated Kernel
    • Fixed ISL RTC errors hardware builds that omit the RTC
    • Fixed I2C bus for 8390 ADC
    • Added small pop fix for sgtl5000 on the 8390
  • Updated ts4900-utils
    • New util 8390adc for reading the low speed MCP ADC
    • Fixed tshwctl to support auto TX-EN RS485 on ttymxc1
ts-x11-image-ts4900-quad-20150331224909.rootfs.tar.bz2 ts-x11-image-ts4900-solo-20150401003538.rootfs.tar.bz2
  • Updated to 3.10.53 kernel
    • Significant fixes to GPU, UARTs, CAN and more.
    • Added TS-TPC-8950 support
    • Fixed 7" twinkling pixels on TS-8390 w/solo
    • Included splash screen
  • Updated to Yocto Dizzy for new freescale GPU support
  • Added Chromium to default image (google-chrome)
  • Updated toolchain to match dizzy image
  • Included gstreamer in the image
  • Updated FPGA with crossbar, max3100 based spi uart, bluetooth fixes (REV C only)
ts-x11-image-ts4900-quad-20150527173205.rootfs.tar.bz2 ts-x11-image-ts4900-solo-20150528210615.rootfs.tar.bz2
  • Fixed networkd
  • Enabled PCIe in default kernel
    • Added I210 support for TS-7970
ts-x11-image-ts4900-quad-20150620060219.rootfs.tar.bz2 ts-x11-image-ts4900-solo-20150622150127.rootfs.tar.bz2
  • Added TS-7970 support
ts-x11-image-tsimx6-20150821190815.rootfs.tar.bz2
  • Updated to Yocto Fido
    • Removed GTK3 packages to reduce image size (GTK2 still available)
    • Removed distcc from default environment
    • Includes QT 5.4.3
    • Included qtmultimedia, xcursor-transparent theme
  • Updated Kernel
    • Includes fix for rare screen flip issues
ts-x11-image-tsimx6-20150821190815.rootfs.tar.bz2
  • Included significantly fixed support for the TS-7970
    • I210 support is fixed, but some prototype boards will need to be RMA'd to get MACs assigned.
    • All UARTs are now working
    • Included tsmicroctl for reading the silabs ADC (p10-12 4-20mA included)
    • Included load_fpga for software reloading fpgas later after boot
  • Updated TS-4900 FPGA to have CTS/RTS fixed for bluetooth, and corrected CTS/RTS polarity on the max3100s
ts-x11-image-tsimx6-20151014183028.rootfs.tar.bz2
  • Corrected defconfig used in kernel
    • Fixed WIFI and other modules
  • If used with the u-boot release from 10-14-2015 this fixes the mac address for the smsc95xx
ts-x11-image-tsimx6-20151221232637.rootfs.tar.bz2
  • Fixed MAC address to use device tree as well as parameter for the latest u-boot support.
  • Fixed tsgpio driver which was causing some incorrect DIO sets.
    • The WIFI driver uses tsgpio for toggling the enable which also corrects the behavior of ifdown/ifup wlan0.
  • Added rsync and lighttpd-cgi support
ts-x11-image-tsimx6-20160512161729.rootfs.tar.bz2
  • Added 100kohm pullups to the onboard/offboard SPI chip selects.
ts-x11-image-tsimx6-20161116215413.rootfs.tar.bz2
  • Updated to Yocto Jethro
  • Updates to QT 5.5
  • Updated to 4.1.15 based on Freescale/NXP's imx_4.1.15_1.0.0_ga.
  • Added improved support for TS-TPC-7990
  • New tshwctl with crossbar support.
ts-x11-image-tsimx6-20170301225516.rootfs.tar.bz2
  • Updated to Yocto Morty 2.2.1 with the same imx_4.1.15_1.0.0_ga kernel
  • Includes QT 5.7.1
  • Included additional alsa utilities
ts-x11-image-tsimx6-20170731205110.rootfs.tar.bz2
  • Updated to Morty 2.2.2
  • Included QT Quick 1.x/2.x support
  • Added support for TS-TPC-7990 REV C in kernel and ts4900-utils
  • Updated kernel
    • Fixed issue with ttyMAX* UARTs losing data or requiring the user to transmit before it continues to receive again
    • Fixed issue with ttyMAX* loopbacks dropping the first character
    • Added wilc3000 support for TS-TPC-7990 REV C WIFI
ts-x11-image-tsimx6-20180502184622.rootfs.tar.bz2
  • Updated to Yocto Morty 2.2.3
  • Add support for SST26VF064BA, and IS25LP064A spi flashes
  • Fixed TS-TPC-7990 REV C WIFI
ts-x11-image-tsimx6-20180608232731.rootfs.tar.bz2
  • Added support for accelerated gstreamer playback
ts-x11-image-tsimx6-20200409220332.rootfs.tar.bz2
  • Updated to Yocto Zeus
  • Added support for Silex WIFI driver
ts-x11-image-tsimx6-20211130163916.rootfs.tar.bz2
  • Added WIFI fix for solo TS-4900 on fallback device tree
  • Fixed TS-7970 FPGA GPIOs > 32.
ts-x11-image-tsimx6-20211206183743.rootfs.tar.bz2
  • Added support for Silex Bluetooth

Debian Changelog

Image Changes
debian-armhf-wheezy-20140929.tar.bz2
  • Initial Release
debian-armhf-wheezy-20141125.tar.bz2
  • Updated kernel with significant fixes, see github for more information.
  • Included first TS-7970 FPGA
debian-armhf-jessie-20160825.tar.bz2
  • New kernel - 3.10.53 (from freescale's 3.10.53_1.1.0_ga) instead of 3.10.17.
    • Fixed CAN dropped frames (just under 1% of frames were dropped on 3.10.17)
    • Fixed reported UART RX fifo overflows
    • GPU fixes
    • Kernel includes compiled in splash screen for quick graphical response on boot
  • TS-TPC-8950 support added
  • New FPGA (crossbar added, bluetooth fixed, and max3100 implemented)
  • Added bluez, wireless-tools, usbutils, nfs-common, and pciutils into the image.
  • Added Openssh server (generates on first boot)
debian-armhf-jessie-20150526.tar.bz2
  • First update to Debian Jessie
debian-armhf-jessie-20151008.tar.bz2
  • Included kernel support for TS-7970 REV A
  • Updated to latest TS-4900 FPGA (20150603)
  • Included openssh, generates keys on first boot. Remove /etc/ssh/*key* to regenerate.
  • Included latest ts4900-utils with TS-7970 support.
debian-armhf-jessie-20160512.tar.bz2
  • Fixed TS-7970 ttyMAX uarts (requires FPGA update)
  • Fixed resolv.conf symlink to use resolvd
  • Updated to 3.14.52 kernel
  • Corrected TS-TPC-8950 calibration
debian-armhf-jessie-20160512.tar.bz2
  • Moved to 4.1.15 kernel
  • Updated Debian to latest Jessie changes
  • Added latest ts4900-utils with improved TS-TPC-7990 support.
debian-armhf-jessie-20170123.tar.bz2
  • Added support for TS-7970 REV D hardware
  • Added support for TS-7990 REV B hardware
debian-armhf-jessie-20170306.tar.bz2
  • Fixed resolv.conf symlink
  • Added nfs-common
  • Cleaned up old temporary files
debian-armhf-jessie-20170327.tar.bz2
  • Fixed regression in TS-TPC-8950 support
  • Adds root.version to list image date
debian-armhf-jessie-20170419.tar.bz2
  • Fixed issue of missing U-boot splash screen disabling the backlight on REV B boards.
  • Fixed potential issue with WIFI not being recognized.
  • Added support for #TS-DC799-SILO board.
debian-armhf-jessie-20170731.tar.bz2
  • Added support for TS-TPC-7990 REV C in kernel and ts4900-utils
  • Updated kernel
    • Fixed issue with ttyMAX* UARTs losing data or requiring the user to transmit before it continues to receive again
    • Fixed issue with ttyMAX* loopbacks dropping the first character
    • Added wilc3000 support for TS-TPC-7990 REV C WIFI
debian-armhf-stretch-20180412.tar.bz2
  • Add support for SST26VF064BA, and IS25LP064A spi flashes
  • Initial port to Debian Stretch
debian-armhf-stretch-20180501.tar.bz2
  • Added support for TS-MINI-ADC
debian-armhf-stretch-20181016.tar.bz2
  • Updated kernel to support the offboard SPI Chip select on TS-7990 REV C.
debian-armhf-buster-20200401.tar.bz2
  • Updated to Debian Buster (10)
  • Updated to Linux 4.9.11
  • Added SILEX SDMAC+ support for TS-4900 REV E and TS-7970 REV F
debian-armhf-buster-20210210.tar.bz2
  • Updated to latest kernel revision with less verbose qcacld messages
debian-armhf-buster-20210526.tar.bz2
  • Kernel update to fix imx_thermal support when the board is already heat soaked past the passive cooling temp.
debian-armhf-buster-20211130.tar.bz2
  • Added WIFI fix for solo TS-4900 on fallback device tree
debian-armhf-buster-20230808.tar.bz2
  • add support for TS-TPC-7990 REV E
debian-armhf-bullseye-20211217.tar.bz2
  • Initial release of Debian Bullseye
debian-armhf-bullseye-20230807.tar.bz2
  • Updated bullseye image to add support for TS-TPC-7990 REV E
debian-armhf-bookworm-x11-20230628.tar.bz2
  • Initial release of Debian Bookworm
  • Bumps to kernel 5.10
debian-armhf-bookworm-x11-20230807.tar.bz2
  • Added missing Silex firmware
  • Fixed issue with Micrel phy on the TS-4900 solo
  • add support for TS-TPC-7990 REV E

Arch Linux Changelog

Image Changes
arch-armhf-20180502.tar.bz2 Initial Release

Ubuntu Linux Changelog

Image Changes
ubuntu-armhf-16.04-20160407.tar.bz2
  • Initial Release
ubuntu-armhf-16.04-20160818.tar.bz2
  • Bumped from 3.14.52 to 4.1.15 kernel. This adds support for the TS-TPC-7990.
  • Added more common packages, mmc, can-utils, etc.
ubuntu-armhf-16.04-20170306.tar.bz2
  • Updated ts4900-utils for final TS-7970/TS-TPC-7990
  • Added TS-TPC-7990 REV B support
ubuntu-armhf-16.04-20180221.tar.bz2
  • Fixed TS-TPC-8950 touchscreen
  • Updated to latest packages in apt repository
  • Updated ts4900-utils to latest version, included fix for supercaps.
  • Updated chromium browser's .desktop file to allow starting as root.
ubuntu-armhf-18.04-20190114.tar.bz2
  • Update to Ubuntu 18.04
  • Updated to kernel 4.9
ubuntu-armhf-18.04-20190806.tar.bz2
  • Updated to latest 4.9 kernel in git to add missing bluetooth driver
ubuntu-armhf-20.04-2011130.tar.bz2
  • Updated to Ubuntu 20.04 with Silex wifi support
ubuntu-armhf-23.04-x11-20230807.tar.bz2
  • Initial release with Ubuntu 23.04
  • Updated to kernel 5.10

Product Change Notices

SPI Flash Vendor Change

Due to an EOL the SPI flash on this product is changing. The old part is a Micron N25Q064A13ESE40F. Two new parts were qualified to reduce the impact of any potential EOL in the future. The new parts are the Microchip's SST26VF064BA, and ISSI's IS25LP064A.

Most applications will not be affected by this change unless they are manually accessing /dev/mtdblock0 or creating a custom u-boot. In those cases some updates will be required.

Linux Kernel Changes

Rebuilding the latest kernel in our git will include these changes, but the specific commits for our various kernel branches are:

U-Boot Changes

These two patches are required for the new flash:

Images with support

Any of our Linux images after March 7th, 2018 include support for this new SPI flash.

New eMMC chip

Due to an EOL on the older Micron MTFC4GMDEA-4M IT part, the replacement Micron MTFC4GACAJCN-4M IT has been qualified for use on this board. This new eMMC flash includes write reliability enabled by default. This will improve reliability for power loss events without requiring user intervention. These modes are further detailed in the eMMC section.

This may require a change to production processes for those who were manually set write reliability and enhanced area for the previous chip. The enh_area and write_reliability settings are permanent and these partition settings are locked once any of them are set. This led to scripts verifying write reliability was set and assuming both were set. The eMMC section includes an example shell script for enabling atomic writes on both versions of this chip.

Product Notes

FCC Advisory

This equipment generates, uses, and can radiate radio frequency energy and if not installed and used properly (that is, in strict accordance with the manufacturer's instructions), may cause interference to radio and television reception. It has been type tested and found to comply with the limits for a Class A digital device in accordance with the specifications in Part 15 of FCC Rules, which are designed to provide reasonable protection against such interference when operated in a commercial environment. Operation of this equipment in a residential area is likely to cause interference, in which case the owner will be required to correct the interference at his own expense.

If this equipment does cause interference, which can be determined by turning the unit on and off, the user is encouraged to try the following measures to correct the interference:

Reorient the receiving antenna. Relocate the unit with respect to the receiver. Plug the unit into a different outlet so that the unit and receiver are on different branch circuits. Ensure that mounting screws and connector attachment screws are tightly secured. Ensure that good quality, shielded, and grounded cables are used for all data communications. If necessary, the user should consult the dealer or an experienced radio/television technician for additional suggestions. The following booklets prepared by the Federal Communications Commission (FCC) may also prove helpful:

How to Identify and Resolve Radio-TV Interference Problems (Stock No. 004-000-000345-4) Interface Handbook (Stock No. 004-000-004505-7) These booklets may be purchased from the Superintendent of Documents, U.S. Government Printing Office, Washington, DC 20402.

Limited Warranty

See our Terms and Conditions for more details.