BeagleBoardUbuntu

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Revision as of 16:48, 12 February 2016 by RobertCNelson (talk | contribs) (Method 1: Download a Complete Pre-Configured Image: 2016-02-11)
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(For BeagleBoardAngstrom, click here.) (Should Beagleboard:Ubuntu On BeagleBone Black be merged into this page?)

This page is about running a Linux distribution (ARM EABI) Ubuntu on the BeagleBoard. BeagleBoard will boot the (ARM EABI) Ubuntu distribution from the SD card. Since much of this page is generic, it has also been extended to help support devices such as the PandaBoard and BeagleBone.

  • For the best experience, make sure you have an LCD/HDMI monitor attached to the BeagleBoard's HDMI port, 2 GB/4 GB/8 GB SD card, and a known good USB 2.0 hub with mouse and keyboard.

Help

If you need any help:

  • Ubuntu related help:
    • #ubuntu-arm: Ubuntu's ARM IRC on Freenode (logs -> year -> month -> day -> #ubuntu-arm.html)
  • When requesting help, please provide some debugging information:
    • U-Boot Version installed on board
    • Kernel Version: uname -a
    • pastebin dmesg
      • Copy from serial port or use "dmesg | pastebinit" (sudo apt-get install pastebinit)

Required Beagle Software

Mainline U-Boot:

  • All older BeagleBoard (classic) Ax, Bx, Cx and Dx boards are required to upgrade to at least these U-Boot versions
  • XM Boards have no NAND, so MLO/u-boot.img is always required on the first partition
  • Directions: Upgrade X-loader and U-Boot

Omap Serial Changes

boot.scr/boot.cmd changes:

With 2.6.35:

console=ttyS2,115200n8

With 2.6.36/37+:

console=ttyO2,115200n8

Serial console login: /etc/init/ttyO2.conf

start on stopped rc RUNLEVEL=[2345]
stop on runlevel [!2345]

respawn
exec /sbin/getty 115200 ttyO2

Method 1: Download a Complete Pre-Configured Image

Demo Image

git clone https://github.com/RobertCNelson/armv7-multiplatform.git
cd armv7-multiplatform
git checkout origin/v4.4.x -b tmp
./build_kernel.sh
git clone https://github.com/RobertCNelson/ti-linux-kernel-dev.git
cd ti-linux-kernel-dev
git checkout origin/ti-linux-rt-4.1.y -b tmp
./build_kernel.sh

Ubuntu (14.04.3)

Default username/password:

  • username: ubuntu
  • password: temppwd

Image Updated:

  • 2016-02-11
    • BeagleBoard xM: v4.4.1-armv7-x5 kernel
    • BeagleBone White/Black/Green: v4.1.17-ti-rt-r47 kernel
    • OMAP5432 uEVM: v4.1.17-ti-rt-r47 kernel
    • BeagleBoard-X15: v4.1.17-ti-rt-r47 kernel
  • 2016-01-14
    • BeagleBoard xM: v4.4.0-armv7-x3 kernel
    • BeagleBone White/Black/Green: v4.1.15-ti-rt-r40 kernel
    • OMAP5432 uEVM: v4.1.15-ti-rt-r40 kernel
    • BeagleBoard-X15: v4.1.15-ti-rt-r40 kernel
  • 2015-12-11
    • BeagleBoard xM: v4.3.2-armv7-x1 kernel
    • BeagleBone White/Black/Green: v4.1.13-ti-r36 kernel
    • OMAP5432 uEVM: v4.1.13-ti-r36 kernel
    • BeagleBoard-X15: v4.1.13-ti-r36 kernel

Services Active:

Note: Depending on your internal network these may work out of the box
Apache, Port 80: http://arm.local/ (Bone: via usb) http://192.168.7.2
SSH, Port 22: ssh ubuntu@arm.local (Bone: via usb) ubuntu@192.168.7.2
Getty, Serial Port

Default user: ubuntu pass: temppwd

Get prebuilt image:

wget https://rcn-ee.com/rootfs/2016-02-11/elinux/ubuntu-14.04.3-console-armhf-2016-02-11.tar.xz

Verify Image with:

sha256sum ubuntu-14.04.3-console-armhf-2016-02-11.tar.xz
e28b2ef67b45e8e6eb3f02c0be41ab7a68ff2d6aa510581484b736f02749b407  ubuntu-14.04.3-console-armhf-2016-02-11.tar.xz

Unpack Image:

tar xf ubuntu-14.04.3-console-armhf-2016-02-11.tar.xz
cd ubuntu-14.04.3-console-armhf-2016-02-11

If you don't know the location of your SD card:

sudo ./setup_sdcard.sh --probe-mmc

You should see something like:

Are you sure? I don't see [/dev/idontknow], here is what I do see...

fdisk -l:
Disk /dev/sda: 500.1 GB, 500107862016 bytes <- x86 Root Drive
Disk /dev/sdd: 3957 MB, 3957325824 bytes <- MMC/SD card

lsblk:
NAME   MAJ:MIN RM   SIZE RO TYPE MOUNTPOINT
sda      8:0    0 465.8G  0 disk 
├─sda1   8:1    0 446.9G  0 part /  <- x86 Root Partition
├─sda2   8:2    0     1K  0 part 
└─sda5   8:5    0  18.9G  0 part [SWAP]
sdd      8:48   1   3.7G  0 disk 
├─sdd1   8:49   1    64M  0 part 
└─sdd2   8:50   1   3.6G  0 part 
  • In this example, we can see via mount, /dev/sda1 is the x86 rootfs, therefore /dev/sdd is the other drive in the system, which is the MMC/SD card that was inserted and should be used by ./setup_sdcard.sh...

Install Image:

Quick install script for [board]

sudo ./setup_sdcard.sh --mmc /dev/sdX --dtb board

board options:

  • BeagleBoard Ax/Bx/Cx/Dx - omap3-beagle
  • BeagleBoard xM - omap3-beagle-xm
  • BeagleBone White/Black/Green - beaglebone
  • OMAP5432 uEVM - omap5-uevm
  • BeagleBoard-X15 - am57xx-beagle-x15

So for the BeagleBoard xM:

sudo ./setup_sdcard.sh --mmc /dev/sdX --dtb omap3-beagle-xm

Advanced: Build Image:

git clone https://github.com/RobertCNelson/omap-image-builder.git
cd omap-image-builder
git checkout v2016.02 -b tmp

Stable:

./RootStock-NG.sh -c rcn-ee_console_ubuntu_trusty_armhf

Testing:

./RootStock-NG.sh -c rcn-ee_console_ubuntu_xenial_armhf

Ubuntu Testing (xenial)

Image Updated:

  • 2016-02-11
    • BeagleBoard xM: v4.4.1-armv7-x5 kernel
    • BeagleBone White/Black/Green: v4.1.17-ti-rt-r47 kernel
    • OMAP5432 uEVM: v4.1.17-ti-rt-r47 kernel
    • BeagleBoard-X15: v4.1.17-ti-rt-r47 kernel
  • 2016-01-14
    • BeagleBoard xM: v4.4.0-armv7-x3 kernel
    • BeagleBone White/Black/Green: v4.1.15-ti-rt-r40 kernel
    • OMAP5432 uEVM: v4.1.15-ti-rt-r40 kernel
    • BeagleBoard-X15: v4.1.15-ti-rt-r40 kernel
  • 2015-12-11
    • BeagleBoard xM: v4.3.2-armv7-x1 kernel
    • BeagleBone White/Black/Green: v4.1.13-ti-r36 kernel
    • OMAP5432 uEVM: v4.1.13-ti-r36 kernel
    • BeagleBoard-X15: v4.1.13-ti-r36 kernel

Get prebuilt image:

wget https://rcn-ee.com/rootfs/2016-02-11/elinux/ubuntu-xenial-console-armhf-2016-02-11.tar.xz

Verify Image with:

sha256sum ubuntu-xenial-console-armhf-2016-02-11.tar.xz
7b1c463bc6b77404b0548373df0f08dc765bcec57540ab89d91b9ea2ba2c25a7  ubuntu-xenial-console-armhf-2016-02-11.tar.xz

Unpack image:

tar xf ubuntu-xenial-console-armhf-2016-02-11.tar.xz
cd ubuntu-xenial-console-armhf-2016-02-11

Then follow the directions shown above with the other images...

Flasher

eMMC: BeagleBone Black/Green

This image can be written to a 2GB (or larger) microSD card, via 'dd' on linux or on windows: https://wiki.ubuntu.com/Win32DiskImager First press and hold the boot select button (next to the microSD card), then apply power. On bootup the board should indicate it has started the flashing procedure visually via a Cylon Sweep pattern shown on the 4 LED's next to the ethernet jack. Progress is reported on both the serial debug and hdmi connectors, once completed all 4 LED's should be full ON. Simply remove power, remove the microSD card and Ubuntu will now boot directly from eMMC.

Script for reference: (this is the script that writes to the eMMC)

https://github.com/RobertCNelson/boot-scripts/blob/master/tools/eMMC/init-eMMC-flasher-v3.sh

This script will only take about 5-6 Minutes after power on.

Notes:

  • If only two LED's stay lit and nothing happens, the board has crashed due to lack of power. Retry with a 5Volt DC power supply connected.
  • If the 4 LED's blink a constant pattern, the eMMC write has failed. First REMOVE ALL capes, then retry again.

User: ubuntu pass: temppwd

Image Updated:

  • 2016-02-11
    • BeagleBone Black/Green: v4.1.17-ti-rt-r47 kernel
  • 2016-01-14
    • BeagleBone Black/Green: v4.1.15-ti-rt-r40 kernel
  • 2015-12-11
    • BeagleBone Black/Green: v4.1.13-ti-r36 kernel

Get prebuilt image:

wget https://rcn-ee.com/rootfs/2016-02-11/flasher/BBB-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz
wget https://rcn-ee.com/rootfs/2016-02-11/flasher/BBB-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.bmap

Verify Image with:

sha256sum BBB-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb*
74500f1f430296d06841a503de380692602f9def0333698c7ebe588f727a8b49  BBB-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.bmap
ed1ec8b5e33ba80131e8473b52da360769e1888aafbd43784d0bcaf95d4f0b66  BBB-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz

Linux: (bmaptool 3.2)

sudo bmaptool copy --bmap BBB-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.bmap \
BBB-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz /dev/sdX

Linux: (dd)

unxz BBB-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz
sudo dd if=./BBB-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img of=/dev/sdX

eMMC: BeagleBoard-X15

This image can be written to a 2GB (or larger) microSD card, via 'dd' on linux or on windows: https://wiki.ubuntu.com/Win32DiskImager First press and hold the boot select button (next to the microSD card), then apply power. On bootup the board should indicate it has started the flashing procedure visually via a Cylon Sweep pattern shown on the 4 LED's next to the ethernet jack. Progress is reported on both the serial debug and hdmi connectors, once completed all 4 LED's should be full ON. Simply remove power, remove the microSD card and Ubuntu will now boot directly from eMMC.

Script for reference: (this is the script that writes to the eMMC)

https://github.com/RobertCNelson/boot-scripts/blob/master/tools/eMMC/init-eMMC-flasher-v3.sh

This script will only take about 5-6 Minutes after power on.

Notes:

  • If only two LED's stay lit and nothing happens, the board has crashed due to lack of power. Retry with a 5Volt DC power supply connected.
  • If the 4 LED's blink a constant pattern, the eMMC write has failed. First REMOVE ALL capes, then retry again.

User: ubuntu pass: temppwd

Image Updated:

  • 2016-02-11
    • BeagleBoard-X15: v4.1.17-ti-rt-r47 kernel
  • 2016-01-14
    • BeagleBoard-X15: v4.1.15-ti-rt-r40 kernel
  • 2015-12-11
    • BeagleBoard-X15: v4.1.13-ti-r36 kernel

Get prebuilt image:

wget https://rcn-ee.com/rootfs/2016-02-11/flasher/bbx15-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz
wget https://rcn-ee.com/rootfs/2016-02-11/flasher/bbx15-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.bmap

Verify Image with:

sha256sum bbx15-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb*
8f7839dd01ce592fa53dc488f68fdeb4fb0839c8ab96c082ca395f62f95abfd8  bbx15-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.bmap
929b3df00e1e3cfc786ad8fd48a80cfdd612e4e48c02484c6c1d24e420ee726e  bbx15-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz

Linux: (bmaptool 3.2)

sudo bmaptool copy --bmap bbx15-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.bmap \
bbx15-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz /dev/sdX

Linux: (dd)

unxz bbx15-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz
sudo dd if=./bbx15-eMMC-flasher-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img of=/dev/sdX

raw microSD img

BeagleBone White/Black/Green

This image can be written to a 2GB (or larger) microSD card, via 'dd' on linux or on windows: https://wiki.ubuntu.com/Win32DiskImager

User: ubuntu pass: temppwd

Auto partition resize:

cd /opt/scripts/tools
git pull
./grow_partition.sh
sudo reboot

Image Updated:

  • 2016-02-11
    • BeagleBone White/Black/Green: v4.1.17-ti-rt-r47 kernel
  • 2016-01-14
    • BeagleBone White/Black/Green: v4.1.15-ti-rt-r40 kernel
  • 2015-12-11
    • BeagleBone White/Black/Green: v4.1.13-ti-r36 kernel

Get prebuilt image:

wget https://rcn-ee.com/rootfs/2016-02-11/microsd/bone-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz
wget https://rcn-ee.com/rootfs/2016-02-11/microsd/bone-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.bmap

Verify Image with:

sha256sum bone-ubuntu-14.04.3-console-armhf-2016-02-11-2gb*
e77a3e37491941ed45aabb02c0063d10834e34dc14bd47ea535320101cf8f7a7  bone-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.bmap
d3082fe46f9142cd818ee9dd4513a869a4a63d10e84749011b9dd1ac81ce0f67  bone-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz

Linux: (bmaptool 3.2)

sudo bmaptool copy --bmap bone-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.bmap \
bone-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz /dev/sdX

Linux: (dd)

unxz bone-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz
sudo dd if=./bone-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img of=/dev/sdX

OMAP5432 uEVM

This image can be written to a 2GB (or larger) microSD card, via 'dd' on linux or on windows: https://wiki.ubuntu.com/Win32DiskImager

User: ubuntu pass: temppwd

Auto partition resize:

cd /opt/scripts/tools
git pull
./grow_partition.sh
sudo reboot

Image Updated:

  • 2016-02-11
    • OMAP5432 uEVM: v4.1.17-ti-rt-r47 kernel
  • 2016-01-14
    • OMAP5432 uEVM: v4.1.15-ti-rt-r40 kernel
  • 2015-12-11
    • OMAP5432 uEVM: v4.1.13-ti-r36 kernel

Get prebuilt image:

wget https://rcn-ee.com/rootfs/2016-02-11/microsd/omap5-uevm-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz
wget https://rcn-ee.com/rootfs/2016-02-11/microsd/omap5-uevm-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.bmap

Verify Image with:

sha256sum omap5-uevm-ubuntu-14.04.3-console-armhf-2016-02-11-2gb*
238a78e86fb6b32b7bd14b08eca863bc25f7b7158d51b33dadbf49c7d17f3b0e  omap5-uevm-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.bmap
311c5322e59744e993a8187e68ad189b3835d698c86f42d077e3f0820f28014a  omap5-uevm-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz

Linux: (bmaptool 3.2)

sudo bmaptool copy --bmap omap5-uevm-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.bmap \
omap5-uevm-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz /dev/sdX

Linux: (dd)

unxz omap5-uevm-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz
sudo dd if=./omap5-uevm-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img of=/dev/sdX

BeagleBoard-X15

This image can be written to a 2GB (or larger) microSD card, via 'dd' on linux or on windows: https://wiki.ubuntu.com/Win32DiskImager

User: ubuntu pass: temppwd

Auto partition resize:

cd /opt/scripts/tools
git pull
./grow_partition.sh
sudo reboot

Image Updated:

  • 2016-02-11
    • BeagleBoard-X15: v4.1.17-ti-rt-r47 kernel
  • 2016-01-14
    • BeagleBoard-X15: v4.1.15-ti-rt-r40 kernel
  • 2015-12-11
    • BeagleBoard-X15: v4.1.13-ti-r36 kernel

Get prebuilt image:

wget https://rcn-ee.com/rootfs/2016-02-11/microsd/bbx15-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz
wget https://rcn-ee.com/rootfs/2016-02-11/microsd/bbx15-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.bmap

Verify Image with:

sha256sum bbx15-ubuntu-14.04.3-console-armhf-2016-02-11-2gb*
c715b20339f38b6544a8e37d6e1f7ce2e8f3209aba2b04765997ef85e1e657a3  bbx15-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.bmap
d9996c395c030ad00aecc0359d76d3f69060a0eff8c74e03f6d9280f5448b001  bbx15-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz

Linux: (bmaptool 3.2)

sudo bmaptool copy --bmap bbx15-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.bmap \
bbx15-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz /dev/sdX

Linux: (dd)

unxz bbx15-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img.xz
sudo dd if=./bbx15-ubuntu-14.04.3-console-armhf-2016-02-11-2gb.img of=/dev/sdX

Method 2: Use the NetInstall method

You will need a 1GB/2GB/4GB/8GB SD card or greater.

Standard system : ~700 MB

Report Bugs/Issues to: https://github.com/RobertCNelson/netinstall/issues (anywhere else will be ignored..)

Download the netinstall script:

git clone https://github.com/RobertCNelson/netinstall.git
cd netinstall

Currently supported Ubuntu distributions:

--distro oneiric (11.10)
--distro precise-armhf (12.04)
--distro quantal (12.10)
--distro raring (13.04)
--distro saucy (13.10)

Device: <board> selection:

*BeagleBoard Ax/Bx/Cx  - omap3-beagle
*BeagleBoard xMA/B/C   - omap3-beagle-xm
*BeagleBone Ax         - am335x-bone-serial
*BeagleBone (DVI cape) - am335x-bone-video
*BeagleBone Black      - am335x-boneblack
*PandaBoard Ax     - omap4-panda
*PandaBoard A4+    - omap4-panda-a4
*PandaBoard ES     - omap4-panda-es

Installation script for new <board> selection: (slowly migrating all devices to this method)

sudo ./mk_mmc.sh --mmc /dev/sdX --dtb <board> --distro <distro>

So for the xM: with quantal:

sudo ./mk_mmc.sh --mmc /dev/sdX --dtb omap3-beagle-xm --distro quantal
  • Other Options:
    • --firmware : installs firmware
    • --serial-mode : debian-installer uses Serial Port

Place SD card into BeagleBoard and boot:

Configure the network:

usb0: USB net <- (usually the OTG port)
eth0: USB net <- (usually the smsc95xx adapter on the BeagleBoard and PandaBoard)
wlan0: Wifi <- Your USDB-Wi-Fi device.. 

See my notes for my testing procedure: https://github.com/RobertCNelson/netinstall/blob/master/test.Ubuntu

Troubleshooting: If booting fails..

  • Hold the user button down to force booting from MMC
  • Upgrade X-loader and U-boot Upgrade X-loader and U-Boot
  • Clear U-boot's Environment Variables in NAND:
nand erase 260000 20000

NetInstall assumptions:

Assume asll <default>'s... Thanks you preseed.conf!!!

Method 3: Manual Install (no automatic scripts)

Note, this section used to have a lot of details, but maintenance of the two wiki's became a pain, so for now on we will just link to my other pages:

Beagle/Beagle xM

http://eewiki.net/display/linuxonarm/BeagleBoard

BeagleBone

http://eewiki.net/display/linuxonarm/BeagleBone

BeagleBone Black

http://eewiki.net/display/linuxonarm/BeagleBone+Black

Panda/Panda ES

http://eewiki.net/display/linuxonarm/PandaBoard

Advanced

Install Latest Kernel Image

General apt syntax for searching and installing a specific kernel:

sudo apt-get update
sudo apt-cache search linux-image | grep <branch>
sudo apt-get install linux-image-<specific version>
sudo reboot

Latest kernel script

cd /opt/scripts/tools/
git pull
sudo ./update_kernel.sh <OPTIONS>

3.8.x

This is the first beagleboard.org long term kernel tree with capemanager support, it's been the default install for Debian Wheezy

beagleboard.org patchset: https://github.com/beagleboard/linux/tree/3.8
3.8.x BeagleBone/BeagleBone Black FULL Cape Support
--bone-channel --stable
3.8.x BeagleBone/BeagleBone Black FULL Cape Support + Xenomai
--bone-xenomai-channel --stable

4.1.x-ti

This is slated to replace the v3.8.x tree in Debian Jessie, cape manager support is enabled.

beagleboard.org patchset: https://github.com/beagleboard/linux/tree/4.1
Based on: http://git.ti.com/gitweb/?p=ti-linux-kernel/ti-linux-kernel.git;a=shortlog;h=refs/heads/ti-linux-4.1.y
4.1.x-ti BeagleBone/BeagleBone Black/BeagleBoard-X15
--ti-channel --stable
4.1.x-ti BeagleBone/BeagleBone Black/BeagleBoard-X15 + RT
--ti-rt-channel --stable

Mainline (lts)

4.1.x BeagleBone/BeagleBone Black + SGX
--bone-kernel --lts
4.1.x BeagleBone/BeagleBone Black + RT + SGX
--bone-rt-kernel --lts

Mainline

4.3.x BeagleBone/BeagleBone Black
--bone-kernel --testing

Debian 8: jessie

sudo apt-get install linux-image-armmp

Reboot with your new Kernel Image.

Xorg Drivers

Script:

cd /opt/scripts/tools/
git pull

BeagleBoard/PandaBoard:

cd /opt/scripts/tools/graphics/
./ti-omapdrm.sh

BeagleBone/BeagleBone Black:

cd /opt/scripts/tools/graphics/
./ti-tilcdc.sh

SGX Drivers

SGX BeagleBone/BeagleBone Black

Note, these are FBDEV only, no xorg/x11/etc...

Install the "4.1.x" lts/bone kernel: http://elinux.org/BeagleBoardUbuntu#Mainline_.28lts.29

Build SGX userspace for 4.1.x (must be done on an x86, due to the TI 5.01.01.02 blob extractor)

git clone https://github.com/RobertCNelson/bb-kernel.git
cd bb-kernel/
git checkout origin/am33x-v4.1 -b tmp-sgx
./sgx_create_package.sh

Copy ./deploy/GFX_5.01.01.02.tar.gz to BeagleBone/BeagleBone Black and install

sudo tar xfv GFX_5.01.01.02.tar.gz -C /
cd /opt/gfxinstall/
sudo ./sgx-install.sh
sudo reboot

Verify omaplfb & pvrsrvkm loaded

debian@arm:~$ lsmod | grep omaplfb
omaplfb                12065  0 
pvrsrvkm              178782  1 omaplfb

Xorg Drivers

Script:

cd /opt/scripts/tools/
git pull

BeagleBoard/PandaBoard:

cd /opt/scripts/tools/graphics/
./ti-omapdrm.sh

BeagleBone/BeagleBone Black:

cd /opt/scripts/tools/graphics/
./ti-tilcdc.sh

Swapfile

Using a File for Swap Instead of a Partition

On the Beagleboard you should expect to require a swap file given the limitation of how little RAM is available (between 256 MB and 512 MB). Some system programs like apt-get will only run properly when some swap space is present (due to 256 MB not being enough RAM).

Some images (such as those from Linaro.org) do not come with a swap partition or any swap space allocated.

Under Linux, swap space can be either a dedicated partition or a swap file. Both can be mounted as swap which the OS can access.

Creating a Swapfile

The following commands will create a 1 GB file, limit access only to root, format it as swap and then make it available to the OS:

sudo mkdir -p /var/cache/swap/   
sudo dd if=/dev/zero of=/var/cache/swap/swapfile bs=1M count=1024
sudo chmod 0600 /var/cache/swap/swapfile 
sudo mkswap /var/cache/swap/swapfile 
sudo swapon /var/cache/swap/swapfile 

To tell the OS to load this swapfile on each start up, edit the /etc/fstab file to include the following additional line:

/var/cache/swap/swapfile    none    swap    sw    0   0

To verify that the swapfile is accessilble as swap to the OS, run "top" or "htop" at a console.

Ubuntu Software

Wi-Fi Networking (command line)

/etc/network/interfaces

It is relatively easy to configure a Wi-Fi card from the command line.

You will need to edit the /etc/network/interfaces file. There are several guides available via Google.

This is a particularly useful guide https://ubuntuforums.org/showthread.php?t=202834

A sample /etc/network/interfaces file for a WPA2 encrypted access point is:

auto lo
iface lo inet loopback
auto wlan0
iface wlan0 inet dhcp
wpa-driver wext
wpa-ssid <NAME OF AP>
wpa-ap-scan 1
wpa-proto RSN
wpa-pairwise CCMP
wpa-group CCMP
wpa-key-mgmt WPA-PSK
wpa-psk <INSERT KEY XXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXXX>

Your Wi-Fi card will automatically load these settings upon startup and initialize wireless network access.

Lightweight window managers

If you intend to use Ubuntu on the BeagleBoard you can install JWM or IceWM to improve performance.

JWM in particular uses little RAM. On a BeagleBoard with 256 MB, using JWM will leave about 60 MB free in which to run applications.

Web Apps

Midori

Given that the BeagleBoard has fewer resources than a desktop a lightweight browser is more responsive. Midori is a lightweight browser that still supports flash, etc. It is available from the standard repositories: http://en.wikipedia.org/wiki/Midori_%28web_browser%29

Surveillance

Motion

If you have a video source (webcam, IP cam, etc.) which appears as /dev/video0, etc. then you can use the Linux surveillance software "motion" to monitor the video stream and record periods of activity.

Motion is also available from the standard repositories: http://www.debian-administration.org/article/An_Introduction_to_Video_Surveillance_with_%27Motion%27 Using a 960x720 resolution webcam with a 15 fps rate under the UVC driver the Rev C BeagleBoard under Xubuntu reports ~60% CPU utilisation.

To make the BeagleBoard automatically start recording on boot, do the following:

  • Auto Login - run "gdmsetup" from a terminal and select a user to automatically login
  • Sessions - make sure you don't save any previous X Windows sessions so that it doesn't prompt you for which one you want
  • motion.conf - edit /etc/motion/motion.conf to use the settings you want (that is, video output directory, record only video, record in MPEG-4, set frame rate, etc). Do this with "sudo medit /etc/motion/motion.conf" at a prompt.
  • Boot script - create a new script in /etc/rc2.d called "S65motion_client" and set permissions appropriately ("sudo chmod 777 /etc/rc2.d/S65motion_client"). Then edit the file so it contains the following lines:
#! /bin/sh
/usr/bin/motion -c /etc/motion/motion.conf

This will now launch the motion client as root when you boot up.

Also note that unless your BeagleBoard can remember the time (battery backed up clock installed), the timestamps will not be correct until you update the time. If your BeagleBoard has an Internet connection this can be achieved using the ntpdate application.

Robotics

ROS

ROS (Robot Operating System) provides libraries and tools to help software developers create robot applications. It provides hardware abstraction, device drivers, libraries, visualizers, message-passing, package management, and more. ROS is licensed under an open source, BSD license.

There are currently builds of ROS for Ubuntu Trusty armhf. These builds include most but not all packages, and save a considerable amount of time compared to doing a full source-based installation:

http://wiki.ros.org/indigo/Installation/UbuntuARM

Alternatively ROS can be installed from source and is generally easy to do so (although slow).

For more information about ROS, see www.ros.org.