Panda How to kernel 3 4 rel

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Kernel 3.4 has been released

You can download a tarball of the mainline kernel at

or you can clone a copy of mainline kernel with:

git clone
cd linux
git checkout v3.4

Important Note There has been a lot of work done on the HDMI interface and its related driver omapdrm. Between kernel 3.1 and 3.2-rc1 enough changed so that the Testing section on the HDMI interface is no longer correct. The hdmi init functions are no longer in arch/arm/mach_omap2/board-omap4panda.c. When this situation stabilises, the HDMI testing section below will be updated.

The entire 3.4-rcx series was plagued with problems which were only resolved in the final days of the cycle, that's why there were no How-To's on building the intermediate -rcx series. Kernel 3.4 works, although there is considerable work going on in the HDMI/DVI/DSS area as well a sound and power management.

PandaBoard ES

There is now a PandaBoard ES which includes an OMAP 4460 at up to 1.2GHz. Several important differences make it important (at the present time) that the MLO/u-boot be specifically crafted for the 4460. The thermal management is not in the mainline 4430 code as yet and therefore the max clock frequency when running the OMAP4460 on the PandaBoard ES with the mainline kernel is 920MHz(same as the OMAP4430).


wlan12xx patch

This patch is still necessary to resolve the issue noted in 3.0, 3.1 and 3.2, the code was moved to twl_common.c.


Apply it like so: (from inside the kernel sources directory)

patch -p1 < 0001a-omap4-pandaboard-wlan-fix.patch

The latest wlan firmware is available from git: git:// just copy the contents of the ti-connectivity folder to /lib/firmware/ti-connectivity.

The patch is no longer necessary for the PandaBoard ES but does not seem to hurt if applied. In addition, the race issue that required building as a module has returned. As part of the code cleanup, the wl12xx and wl12xx_sdio drivers no longer depend on each other. This creates an issue with systems that do not use udev or mdev (with as somewhat fiddly & slow script) to load MODALIAS drivers. The quick solution is to modprobe both, the order no longer matters. Just modprobing wl12xx_sdio will no longer automatically load wl12xx. It is suggested that these 2 drivers be built as modules.


Building 3.3 is fairly straight forward.

Grab the 3.3 sources and use config.3.3.1 as the .config

The 3.3 .config enables Sound builtin and wl12xx as modules. The builtin sound does not presently work, but the enabled configuration allows USB sound devices, which function properly.

Then compile like so:

make ARCH=arm CROSS_COMPILE=Path_to_your/arm-2010q1/bin/arm-none-linux-gnueabi- uImage


fbtest on DVI Port

After booting run fbtest to see a nice test pattern from the dvi port.


Switching primary display to the HDMI port --> Currently not functional <--

Make sure that a monitor is plugged into the HDMI port before doing the following:

# Enable HDMI
echo "1" > /sys/devices/platform/omapdss/display1/enabled

# Disable overlay0 (an overlay must be disabled before changing its properties)
echo "0" > /sys/devices/platform/omapdss/overlay0/enabled

# Set the manager of overlay0 to display1 which is HDMI
echo "tv" > /sys/devices/platform/omapdss/overlay0/manager

# Enable overlay0
echo "1" > /sys/devices/platform/omapdss/overlay0/enabled

And content on overlay 0 of primary lcd would be transferred to HDMI. It works similarly for all other overlay's.

Switching primary display to the DVI port

See: for lots of useful info on the display subsystem. Be aware that the display, manager and overlay numbers don't match the panda configuration.

Make sure that a monitor is plugged into the DVI port before doing the following:

# Disable HDMI
echo "0" > /sys/devices/platform/omapdss/display1/enabled

# Disable overlay0 (an overlay must be disabled before changing its properties)
echo "0" > /sys/devices/platform/omapdss/overlay0/enabled

# Set the manager of overlay0 to display0 which is DVI
echo "lcd2" > /sys/devices/platform/omapdss/overlay0/manager

# Enable overlay0
echo "1" > /sys/devices/platform/omapdss/overlay0/enabled

The above commands should be run from the serial console and the cable should be in the destination port before running the commands.

fbtest on HDMI Port --> Currently not functional <--

Run fbtest to see a nice test pattern from the HDMI port.



You can run i2cdetect and the results should look like this:

# i2cdetect -y -r 1
    0  1  2  3  4  5  6  7  8  9  a  b  c  d  e  f
00:          -- -- -- -- -- -- -- -- -- -- -- -- -- 
10: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 
20: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 
30: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 
40: -- -- -- -- -- -- -- -- UU UU UU UU -- -- -- -- 
50: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 
60: -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- -- 
70: -- -- -- -- -- -- -- --


Run the following commands after the PandaBoard is booted:

modprobe wl12xx    ** only if you built the wl12xx drivers as modules
modprobe wl12xx_sdio    ** only if you built the wl12xx drivers as module
ifconfig wlan0 up
iwconfig wlan0 essid "Your AccessPoint Name"
udhcpc -i wlan0

If your network is set up to provide DHCP services, the PandaBoard will get all the "right stuff(tm)" and you will be able to access the Internet.

# ping
PING ( 56 data bytes
64 bytes from seq=0 ttl=43 time=62.683 ms
64 bytes from seq=1 ttl=43 time=54.077 ms
64 bytes from seq=2 ttl=43 time=51.484 ms
64 bytes from seq=3 ttl=43 time=54.108 ms

USB Performance

Insert a USB memory stick into one of the usb ports

Run dmesg to see what sdx the stick was recognised as, then:

hdparam -tT /dev/sdx

If you run the same command on a desktop Linux system, with the same USB memory stick, the PandaBoard's speed should roughly be the same.