How to connect i.MX51 and Ubuntu using USB cable: i.MX51 Side Plug in USB cable. getprop debug.adb.usb - Shows that debug.adb.usb are not set by default setprop persist.service.adb.enable 0 -> disable adb setprop debug.adb.usb 1 - adb will be through USB (for Ethernet, use setprop debug.adb.usb 0) setprop persist.service.adb.enable 1 -> enable adb Example: # getprop debug.adb.usb  # # # setprop persist.service.adb.enable 0 disabling adb # adb_release android_usb gadget: high speed config #1: android setprop debug.adb.usb 1 # # setprop persist.service.adb.enable 1 enabling adb # adb_open adb_release adb_open android_usb gadget: high speed config #1: android # Ubuntu Side On Ubuntu side, the most important tip is regarding permission. ADB server MUST be started with root right. Example of right mistake: $ sudo <AND_SDK_DIR>/android-sdk-linux_86/tools/adb devices List of devices attached ????????????    no permissions  $ sudo <AND_SDK_DIR>/android-sdk-linux_86/tools/adb shell error: insufficient permissions for device How to proceed to get permission: $ sudo <AND_SDK_DIR>/android-sdk-linux_86/tools/adb kill-server $ sudo <AND_SDK_DIR>/android-sdk-linux_86/tools/adb start-server * daemon not running. starting it now * * daemon started successfully * $ sudo <AND_SDK_DIR>/android-sdk-linux_86/tools/adb devices List of devices attached 0123456789ABCDEF    device  $ sudo <AND_SDK_DIR>/android-sdk-linux_86/tools/adb shell ADB over Ethernet/Wi-Fi To make ADB work in i.MX51 using TCP: In your host machine: - Install Android SDK - export ADBHOST=BOARD_IP (setenv ADBHOST=xxx.xxx.xxx.xxx) - adb kill-server In your board: - make sure that ro.secure property is *not* set when the adbd daemon is launched, so edit the file default.prop - make sure that /dev/android_adb or /dev/android do *not* exist - stop adbd - start adbd Now you will be able to list the device: hamilton@saygon:/opt/work/androidsdk/android-sdk-linux_86/tools$ ./adb kill-server hamilton@saygon:/opt/work/androidsdk/android-sdk-linux_86/tools$ ./adb devices * daemon not running. starting it now * * daemon started successfully * List of devices attached emulator-5554   device

In order to get USB cameras (web cams) working on i.MX 51 EVK board running Ubuntu, a few steps must be followed, and they are: Enable USB Camera's drivers on Kernel Test it using Gstreamer or another compatible software (as Cheese) Kernel Driver USB cameras (web cameras) on Linux work over GSPCA driver, to enable this driver you need to go to: ./ltib -c   [*] Configure the kernel     Device Drivers -->          Multimedia Devices -->               [*] Video Capture Adapters -->                    [*] V4L USB Devices -->                         <*> USB Video Class (UVC)                                      [*] UVC input events device support                         <*> GSPCA Based WebCams --> From this point, you need to choose your specific driver. If you don't know, you can select all of those options as a built-in module "<*>" that will work. GSPCA Drivers USB Camera Detection Connect your USB camera to the USB Host port on i.MX 51 EVK board and then type "dmesg", and also check if there is a video0 device using: ubuntu@ubuntu-desktop:~$ ls /dev/video0 /dev/video0 USB Camera Detection Gstreamer Command Line In order to test your USB camera using Gstreamer plugin, use the following command line to perform it: ubuntu@ubuntu-desktop:~$ gst-launch-0.10 v4l2src ! ffmpegcolorspace ! ximagesink and the results: Hi there !!! EOF !

It is often not easy to use company network to flash application, due to network security (proxy, etc...). We will see in this tutorial, how to flash a Linux application in a SD card with ONLY a SD card reader and simple standard Linux commands. SD card Memory Map A Linux application is divided in 3 parts: the bootloader the Linux Kernel the Linux Rootfs We will flash sequentially these 3 parts Flashing U-boot With the SD card Reader, we will flash the yellow part. In the [...]/ltib/rootfs/boot/ folder $ sudo dd if=u-boot.bin of=/dev/sdb bs=512 skip=2 seek=2 && sudo sync Flashing Linux Kernel With the SD card reader, we will flash the green part. Keep in mind that 1MB=1048576B -> Kernel Offset. $ sudo dd if=uImage of=/dev/sdb bs=1048576 seek=1 && sudo sync Configure U-boot variables To launch the Kernel, you need to configure U-boot. Plug the serial cable on the EVK: 115kbps, 8 bits, 1 stop and no parity EVK switches must be configured as below: DS1 DS2 DS3 DS4 DS5 DS5 DS7 DS8 DS9 DS10 Boot from SD/MMC Card 0 0 0 0 0 0 1 1 0 0 Put the SD card in the EVK (bottom slot) and launch the app. In the hyperterminal type:   BBG U-Boot > printenv To print environnement variables Modify the bootcmd: BBG U-Boot > setenv bootcmd_mmc 'run bootargs_base bootargs_mmc;mmc read 0 ${loadaddr} 0x800 0x1800;bootm' "0x1800" is the size of the kernel. Must be bigger than uImage Kernel file (0x1800x512Byte=3MB) If you want to use the WVGA as display screen (kernel need to be configured with CLAA support), for LTIB1007 and after (before it was 'wvga' option): Script for LTIB1007's u-boot on i.MX51 EVK (copy/paste in the hyperterminal): setenv bootcmd_mmc 'run bootargs_base bootargs_mmc; mmc read 0 ${loadaddr} 800 1800 ; bootm' setenv bootargs_mmc 'setenv bootargs ${bootargs} root=/dev/mmcblk0p1 rootwait rw  init=/init' setenv bootargs_base' setenv bootargs console=ttymxc0,115200 di1_primary console=tty1' setenv bootcmd 'run bootcmd_mmc' saveenv Script for LTIB1007's u-boot on i.MX53 EVK (copy/paste in the hyperterminal): setenv bootcmd_mmc 'run bootargs_base bootargs_mmc; mmc read 0 ${loadaddr} 800 1800 ; bootm' setenv bootargs_mmc 'setenv bootargs ${bootargs} root=/dev/mmcblk0p1 rootwait rw  init=/init' setenv bootargs_base 'setenv bootargs console=ttymxc0,115200 di0_primary console=tty1' setenv bootcmd 'run bootcmd_mmc' saveenv You must have the following printenv: BBG U-Boot > printenv bootdelay=3 baudrate=115200 loadaddr=0x90800000 netdev=eth0 ethprime=FEC0 uboot_addr=0xa0000000 uboot=u-boot.bin kernel=uImage bootargs_nfs=setenv bootargs ${bootargs} root=/dev/nfs ip=dhcp nfsroot=${serveri p}:${nfsroot},v3,tcp bootcmd_net=run bootargs_base bootargs_nfs; tftpboot ${loadaddr} ${kernel}; boot m load_uboot=tftpboot ${loadaddr} ${uboot} ethact=FEC0 bootargs=console=ttymxc0,115200 di1_primary root=/dev/mmcblk0p1 rootwait rw init =/init bootcmd_mmc=run bootargs_base bootargs_mmc; mmc read 0 ${loadaddr} 800 1800 ; bo otm bootargs_mmc=setenv bootargs ${bootargs} root=/dev/mmcblk0p1 rootwait rw init=/i nit bootargs_base=setenv bootargs console=ttymxc0,115200 di1_primary bootcmd=run bootcmd_mmc stdin=serial stdout=serial stderr=serial</br> Environment size: 748/131068 bytes BBG U-Boot > Create ext3 partition With the SD card reader, create an ext3 partition. You can use gparted, a graphical partition manager tool. Launch gparted: $ sudo gparted Create a new ext3 partition, with 20MB of offset: Copying Linux To copy rootfs folder generated by LTIB, type in the shell: $ sudo cp -r /[…]/ltib/rootfs/* /media/FreescaleSD/ && sudo sync Test application Put the SD in the slot slot and launch the application. Password is root.

Changing the storage for U-boot environment variables   U-Boot on Freescale BSP has a compiling option that allows you to choose the storage for environment variables.   1 - Extract the u-boot source using LTIB: ./ltib -m prep -p u-boot   2 - The source will be extracted to <ltib path>/rpm/BUILD/u-boot-2009.08   3 - On u-Boot source locate the i.MXEVK config file, <ltib path>/rpm/BUILD/u-boot-2009.08/include/configs/mx51_bbg.h   4 - To change the storage of variables environment to SD card, on this file, comment out CONFIG_FSL_ENV_IN_SF and define CONFIG_FSL_ENV_IN_MMC:   //#define CONFIG_FSL_ENV_IN_SF   #define CONFIG_FSL_ENV_IN_MMC 5 - Adjust CONFIG_ENV_SECT_SIZE and CONFIG_ENV_OFFSET accordingly. Recall that sd card read block size is 512B.   For example:   #define CONFIG_ENV_SECT_SIZE (256 * 512)   #define CONFIG_ENV_SIZE CONFIG_ENV_SECT_SIZE   #if defined(CONFIG_FSL_ENV_IN_MMC)   #define CONFIG_ENV_IS_IN_MMC 1 #define CONFIG_ENV_OFFSET (1023 * 512)   6 - Save the file.   7 - Recompile u-boot: ./ltib -m scbuild -p u-boot   8 - Your new compiled u-boot image will be saved at: <ltib path>/rpm/BUILD/u-boot-2009.08/u-boot.bin

This tutorial has been done with an i.MX51 EVK. This example can be easily adapted to i.MX35 or i.MX53 that share the same GPU Core (Z160) and the same API (OpenVG 1.1). This tutorial show you how to do a simple image warp deformation with OpenVG 1.1.     Generation of Linux Image with 2D gpu support To support 2D/3D gpu, you need to select gpu driver in LTIB. In LTIB's "package list" select the following packages: [x] amd-gpu-bin-mx51 [x] libz160-bin Build your Linux Image and copy it to your SD card. Building OpenVG simple application Download the application (see attached archive) Untar/unbz2 the application source code. To build the simple OpenVG application, you need to adapt the Makerules file. First you have to indicate where your linux image has been generated withLTIB: ROOTFS = /home/fsl/LTIB_1_7/ltib/rootfs You also need to indicate the compiler path (usualy installed in /opt/freescale/usr/local/....): GNUTOOL_PATH=/opt/freescale/usr/local/gcc-4.1.2-glibc-2.5-nptl-3/arm-none-linux-gnueabi/bin/ After that you have to copy gpu's driver headers files in the include folder of the project. You will find these header in /opt/freescale/pkgs/amd-gpu-bin-mx51-x.x.x.tar.gz archive: extract all the include folders/files in the include folder of the project. Now you can build the application:   fsl@fsl-laptop:~/SW/openVG_sample$ make /opt/freescale/usr/local/gcc-4.1.2-glibc-2.5-nptl-3/arm-none-linux-gnueabi/bin/arm-none-linux-gnueabi-gcc -mfloat-abi=softfp -mfpu=vfp -Wall -O3 -fsigned-char -D_LINUX -I/home/fsl/SW/openVG_sample/include -c warp.c -o warp.o In file included from warp.c:37: roselend_savoie_france_350x350.c:12391:66: warning: trigraph ??) ignored, use -trigraphs to enable roselend_savoie_france_350x350.c:12964:71: warning: trigraph ??/ ignored, use -trigraphs to enable roselend_savoie_france_350x350.c:14518:10: warning: trigraph ??- ignored, use -trigraphs to enable roselend_savoie_france_350x350.c:15118:67: warning: trigraph ??) ignored, use -trigraphs to enable roselend_savoie_france_350x350.c:15327:67: warning: trigraph ??' ignored, use -trigraphs to enable roselend_savoie_france_350x350.c:15795:62: warning: trigraph ??! ignored, use -trigraphs to enable /opt/freescale/usr/local/gcc-4.1.2-glibc-2.5-nptl-3/arm-none-linux-gnueabi/bin/arm-none-linux-gnueabi-gcc -I/home/fsl/SW/openVG_sample/include -lOpenVG -legl13 -Wl,--library-path=/home/fsl/LTIB_1_7/ltib/rootfs/usr/lib,-rpath-link=/home/fsl/LTIB_1_7/ltib/rootfs/usr/lib -o warp warp.o fsl@fsl-laptop:~/SW/openVG_sample$ Copy the application on your SD card Put the SD card in the i.MX51 and run the gpu drivers $ login:root $ modprobe gpu Run the application $ ./warp Modifying the image A simple way to modify the image, is to use The Gimp. When you want to save your image, choose "C source code format": Then choose the prefix name (here "roselend"): Click on "Save". The "C" file of your image is generated: /* GIMP RGBA C-Source image dump (roselend_savoie_france.c) */ static const struct {   guint        width;   guint        height;   guint        bytes_per_pixel; /* 3:RGB, 4:RGBA */   guint8       pixel_data[350 * 350 * 4 + 1]; } roselend = {   350, 350, 4,   "\265\303\357\376\264\304\357\376\262\304\357\376\260\304\356\376\260\303"   "\356\376\257\303\356\376\257\302\355\376\257\301\355\376\257\302\355\376"   "\257\302\355\377\256\302\356\376\256\302\357\376\256\302\356\377\255\302" "\357\376\254\302\360\376\253\302\357\376\254\302\355\376\255\302\357\376" ...

How to load the camera driver modprobe ov3640_camera modprobe mxc_v4l2_capture How to encode audio gst-launch alsasrc ! mfw_mp3encoder ! filesink location= audio.mp3 Encoding an AVI audio only gst-launch alsasrc ! mfw_mp3encoder ! avimux ! filesink location=audio.avi You can use audiotestsrc instead of alsasrc Encoding Audio and Video (testsrc only) Raw video and Raw audio gst-launch videotestsrc num-buffers=250 ! 'video/x-raw-yuv,format=fourcc)I420,width=320,height=240,framerate=(fraction)25/1' ! queue ! mux. audiotestsrc num-buffers=440 ! audioconvert ! 'audio/x-raw-int,rate=44100,channels=2' ! queue ! mux. avimux name=mux ! filesink location=test.avi H.263 video and Raw audio gst-launch videotestsrc num-buffers=250 ! mfw_vpuencoder codec-type=1 ! queue ! mux. audiotestsrc num-buffers=440 ! audioconvert ! 'audio/x-raw-int,rate=44100,channels=2' ! queue ! mux. avimux name=mux ! filesink location=test.avi H.263 video and MP3 audio gst-launch videotestsrc num-buffers=250 ! mfw_vpuencoder codec-type=1 ! queue ! mux. audiotestsrc num-buffers=440 ! audioconvert ! mfw_mp3encoder ! queue ! mux. avimux name=mux ! filesink location=test.avi Real Source gst-launch-0.10 mfw_v4lsrc capture-mode=5 num-buffers=300 capture-width=320 capture-height=240 fps-n=15 blocksize=115200 ! queue2 max-size-buffers=1000 max-size-bytes=0 max-size-time=0 ! mfw_vpuencoder framerate=15 codec-type=2 name=venc  alsasrc num-buffers=300 ! audio/x-raw-int,rate=32000,channels=1,depth=16 ! audioconvert ! queue2 max-size-buffers=1000 max-size-bytes=0 max-size-time=0 ! mfw_mp3encoder name=aenc avimux name=mux ! filesink location=all_in_one.avi aenc. ! mux. venc. ! mux. The movie isn't that good, but you can improve that increasing num-buffers, width and heigh, and even framerate! STAMP If you face synchronization issues, you can try to use a non-standard plugin called stamp. Use the spec file gst-entrans.spec and this command line: gst-launch-0.10 mfw_v4lsrc capture-mode=5 num-buffers=160 capture-width=320 capture-height=240 fps-n=15 blocksize=115200 !  stamp sync-margin=1 sync-interval=1 ! queue2 max-size-buffers=1000 max-size-bytes=0 max-size-time=0  !  mfw_vpuencoder framerate=15 codec-type=2 name=venc  alsasrc num-buffers=160  !  audio/x-raw-int,rate=32000,channels=1,depth=16     !  audioconvert ! queue2 max-size-buffers=1000 max-size-bytes=0 max-size-time=0      !  mfw_mp3encoder name=aenc avimux name=mux ! filesink location=test_ALL.avi aenc. ! mux. venc. ! mux. Donwload the package from here: http://gentrans.sourceforge.net/ (source for stamp topic: http://blog.buberel.org/2008/03/using-a-usb-web.html)

LTIB Creating Uimage Uboot Configuration file for fw_(printenv/saveenv) utility Add new i.MX5x board on LTIB LTIB Creating Uimage Uboot U-boot expects uImage format for the kernel image. In order to LTIB generate a uImage file: $ export SYSCFG_KTARG=uImage $ ./ltib -p kernel Setup in U-Boot the kernel bootargs: u-boot> setenv bootargs noinitrd console=ttymxc0,115200 init=/linuxrc root=/dev/nfs nfsroot=10.29.244.27:/tftpboot/rootfs ip=dhcp Change 10.29.244.27 to your host IP. The procedure above is needed when default bootloader used by ltib was redboot. In some ltib releases (before 2010) default bootloader is u-boot. In this case, ltib will create uImage by default Configuration file for fw_(printenv/saveenv) utility # Configuration file for fw_(printenv/saveenv) utility. # Up to two entries are valid, in this case the redundant # environment sector is assumed present. # Notice, that the "Number of sectors" is ignored on NOR.               # MTD device name Device offset Env. size Flash sector size Number of sectors #/dev/mtd1 0x0000 0x4000 0x4000 #/dev/mtd2 0x0000 0x4000 0x4000 # NAND example /dev/mtd0 0x80000 0x40000 0x20000 2 Add new i.MX5x board on LTIB After porting u-boot to your i.MX5x board you might want add it on LTIB menu, "Choose your board for u-boot" section. For this, edit ltib/config/platform/imx/main.lkc to add your board: Enter board on menu: comment "Choose your board for u-boot" choice prompt "board" default BOARD_MX51_BBG depends on PLATFORM = "imx51" help This menu will let you choose the board you use. ... + config BOARD_MX53_MYBOARD + bool "mx53_myboard" ... endchoice Add the "mx53_myboard_config" that matches your board configuration on the u-boot Makefile to PKG_U_BOOT_CONFIG_TYPE: config PKG_U_BOOT_CONFIG_TYPE   string   ... + default "mx53_myboard_config" if ( PLATFORM = "imx51" && BOARD_MX53_MYBOARD && !PKG_KERNEL_UPDATER )   ...

Changing Freescale's BSP U-boot using LTIB This quick recipe demonstrates how to compile U-boot using Freescale BSP. 0. After installing i.MX51 BSP: 1. Extract u-boot source: ./ltib -m prep -p u-boot 2. (optional) If you wish to apply changes to the code, the source is located at: <ltib path>/rpm/BUILD/u-boot-2009.08 3. Compile u-boot for the i.MX51 EVK ./ltib -m scbuilb -p u-boot 4. Copy the compiled file to a SD card on your host machine, insert the SD card and: $ sudo dd if=rpm/BUILD/u-boot-2009.08/u-boot.bin of=/dev/mmcblk0 bs=512 /dev/mmcblk0 should replaced according to your host, use "dmesg" after inserting the SD to find out where is the SD on your host. Unmount it before issuing the dd command.   5. Insert the SD on the i.MX 51 EVK, set the switches for SD Card boot and power on the board.

Working with mainline U-Boot Freescale BSP provides an i.MX51 EVK U-boot port. However, i.MX51 EVK is also supported on I-boot main tree. This quick "how to" teaches how to use it. 0. Get u-boot code from the imx U-Boot Custodian tree: $ git clone git://git.denx.de/u-boot-imx.git 1. Prepare the environment: $ export PATH="$PATH:/opt/freescale/usr/local/gcc-4.1.2-glibc-2.5-nptl-3/arm-none-linux-gnueabi/bin/" $ export CROSS_COMPILE=arm-none-linux-gnueabi- 2. Configure for i.MX 51 EVK $ cd u-boot-imx $ make mx51evk_config 3. Compile $ make u-boot.imx   iMX may SoCs use its internal ROM to execute some instructions at boot time, using "make u-boot.imx" an image containing the instructions 4. Copy the compiled file to a SD card on your host machine, insert the SD card and: $ sudo dd if=u-boot.imx of=/dev/mmcblk0 bs=512 seek=2 "/dev/mmcblk0" should replaced according to your host, use "dmesg" after inserting the SD to find out where is the SD on your host. Unmount it before issuing the dd command. seek 2, skips the first 1K bytes (2x512) of the SD where the ROM expects the boot image for SD. 5. Insert the SD on the i.MX51 EVK, and set the switches for SD card boot and power on the board.

OpenCV is a computer vision library originally developed by Intel. It is free for commercial and research use under the open source BSD license. The library is cross-platform. It focuses mainly on real-time image processing; as such, if it finds Intel's Integrated Performance Primitives on the system, it will use these commercial optimized routines to accelerate itself. Application OpenCV's application areas include: * 2D and 3D feature toolkits * Egomotion estimation * Face Recognition * Gesture Recognition * Human-Computer Interface (HCI) * Mobile robotics * Motion Understanding * Object Identification * Segmentation and Recognition * Stereopsis Stereo vision: depth perception from 2 cameras * Structure from motion (SFM) * Motion Tracking To support some of the above areas, OpenCV includes a statistical machine learning library that contains: * Boosting * Decision Trees * Expectation Maximization * k-nearest neighbor algorithm * Naive Bayes classifier * Artificial neural networks * Random forest * Support Vector Machine Installing OpenCV on i.MX 51 EVK Board running Ubuntu Linux Assuming that you already have the Ubuntu Linux running on your board, you can use this wiki page to guide you to get your USB camera running on your system in order to use real time image processing features of this library. In a brand new installation of Ubuntu some libraries is not installed by default, so you need to install them by your own hands (use synaptic to do that), here is the list of these libraries: libgtk2.0-dev libjpeg62-dev zlib1g-dev libpng12-dev libtiff4-dev libjasper-dev libgst-dev libgstreamer0.10-dev If you already have some of those libraries installed, make sure that is the DEV version. After installing those libraries you can download the stable OpenCV version here. Install it following the procedure below: 1 - untar the opencv package tar -xvzf opencv-1.1pre1.tar.gz  2 - change to OpenCV folder cd opencv-1.1.0  3 - configure the installation enabling gstreamer and letting to compile demo apps later ./configure --with-gstreamer --disable-apps You will get the following results: General configuration ================================================       Compiler:                         g++       CXXFLAGS:       DEF_CXXFLAGS:             -Wall -fno-rtti -pipe -O3 -fomit-frame-pointer       PY_CXXFLAGS:               -Wall -pipe -O3 -fomit-frame-pointer       OCT_CXXFLAGS:             -fno-strict-aliasing -Wall -Wno-uninitialized -pipe -O3 -fomit-frame-pointer        Install path:                      /usr/local  HighGUI configuration ================================================       Windowing system --------------       Use Carbon / Mac OS X:        no       Use gtk+ 2.x:                        yes       Use gthread:                         yes       Image I/O ---------------------       Use ImageIO / Mac OS X:       no       Use libjpeg:                            yes       Use zlib:                                yes       Use libpng:                             yes       Use libtiff:                               yes       Use libjasper:                          yes       Use libIlmImf:                          no             Video I/O ---------------------       Use QuickTime / Mac OS X:     no       Use xine:                                no       Use gstreamer:                        yes       Use ffmpeg:                             no       Use dc1394 & raw1394:     no       Use v4l:                                   yes       Use v4l2:                                 yes       Use unicap:                             no     Wrappers for other languages =========================================       SWIG Python                          no       Octave                                    no       Additional build settings ============================================       Build demo apps                      no Now run make ... 4 - Build OpenCV ./make 5 - Install OpenCV ./sudo make install if all steps above were executed properly, now you can compile the sample applications: 1 - change to samples/c directory cd samples/c 2 - change the build_all script mode to +x chmod +x build_all.sh 3 - run the script ./build_all.sh Now you can test. The results below were taken from the Laplacian filter sample processing in real-time images grabbed from an USB camera: Laplacian filter with USB Camera capture device Also, you can see how is it performance on a 3 windowed application performing color conversion and canny edge detection at the same time: http://www.youtube.com/watch?v=w9yQgdABT7c EOF !

Using a USB Touchscreen on Ubuntu   This example uses a XENARC 706TSA monitor http://www.xenarc.com/product/706tsa.html To use a USB touchscreen on i.MX51 EVK, disable all touchscreen drivers on menuconfig and build the kernel: Device Drivers  --->        Input device support  --->        [ ]   Touchscreens  ---> Download xserver-xorg-input-evtouch (0.8.8-ubuntu3 version) from http://launchpadlibrarian.net/24760784/xserver-xorg-input-evtouch_0.8.8-0ubuntu3_armel.deb. X crash is found if using latest 0.8.8-ubuntu6.1 version. For the details. See https://bugs.launchpad.net/ubuntu/+source/xf86-inputevtouch/+bug/511491 On MX51 EVK board, run “sudo dpkg –i xserver-xorg-input-evtouch_0.8.8-0ubuntu3_armel.deb” to install debian package. Add fdi file by "sudo vi ./usr/share/hal/fdi/policy/20thirdparty/50-eGalax.fdi": <?xml version="1.0" encoding="UTF-8"?> <deviceinfo version="0.2">    <device>       <match key="info.product" contains="eGalax">          <match key="info.capabilities" contains="input">             <merge key="input.x11_driver" type="string">evtouch</merge>             <merge key="input.x11_options.minx" type="string">130</merge>             <merge key="input.x11_options.miny" type="string">197</merge>             <merge key="input.x11_options.maxx" type="string">3945</merge>             <merge key="input.x11_options.maxy" type="string">3894</merge>             <merge key="input.x11_options.Rotate" type="string">CCW</merge>             <merge key="input.x11_options.Swapy" type="string">true</merge>             <merge key="input.x11_options.taptimer" type="string">30</merge>             <merge key="input.x11_options.longtouchtimer" type="string">750</merge>             <merge key="input.x11_options.longtouched_action" type="string">click</merge>             <merge key="input.x11_options.longtouched_button" type="string">3</merge>             <merge key="input.x11_options.oneandhalftap_button" type="string">2</merge>             <merge key="input.x11_options.movelimit" type="string">10</merge>             <merge key="input.x11_options.touched_drag" type="string">1</merge>             <merge key="input.x11_options.maybetapped_action" type="string">click</merge>             <merge key="input.x11_options.maybetapped_button" type="string">1</merge>          </match>       </match>    </device> </deviceinfo> Save above configuration. Calibrating Calibration in made by clicking on System -> Administration -> Calibrate Touchscreen Follow the on screen instructions and reboot the system. Calibrating using Xinput Calibrator Xinput_calibrator is another option to calibrate touchscreen. It can be downloaded at: http://www.freedesktop.org/wiki/Software/xinput_calibrator On i.MX5x Ubuntu, unpack the source code: tar -xzvf xinput_calibrator-0.7.5.tar.gz Install xorg-dev, it's required to build xinput_calibrator sudo apt-get install xorg-dev Configure, build and install xinput_calibrator ./configure ./make ./make install Execute xinput_calibrator. A four-point calibration screen will be shown. Follow the instructions on screen and after complete xinput_calibrator will return the calibration parameters. Replace the given calibration parameters on file /usr/share/hal/fdi/policy/20thirdparty/50-eGalax.fdi and reboot the system.

This example uses the touchscreen that comes with i.MX51 EVK's parallel LCD Download xserver-xorg-input-evtouch (xserver-xorg-input-evtouch_0.8.8-3build1_armel.deb) from https://launchpad.net/ubuntu/lucid/armel/xserver-xorg-input-evtouch/0.8.8-3build1 On i.MX51 EVK board, run “sudo dpkg –i xserver-xorg-input-evtouch_0.8.8-3build1_armel.deb” to install debian package. Remove evdev config file: sudo rm /usr/lib/X11/xorg.conf.d/05-evdev.conf Change the content of 10-evtouch.conf to: sudo vi /usr/lib/X11/xorg.conf.d/10-evtouch.conf Section "InputClass"            Identifier "touchscreen catchall"            MatchIsTouchscreen "on"            Driver "evtouch"            Option "SwapY" "1"            Option "MinX" "32"            Option "MinY" "46"            Option "MaxX" "1001"            Option "MaxY" "967" EndSection   The MinX, MinY, MaxX and MaxY values can be changed to match the exact configuration of your touchscreen Save above configuration and reboot the system.

When you do long test (days or weeks) test on i.MX board and your test fails, you often wants to know what has happen with a JTAG probe. The problem is when you have 50 boards running in parallel, you don't have the budget to have 50 JTAG debug probe. If you do a "hot plug" of your JTAG probe, you have roughly one chance out 2 to reset your board... so you'll have to wait another couple of hour to resee the problem. Anyway to have a reliable JTAG plug with no reset, it is really simple... cut the RESET line on your cable! then you'll still be able to "attach" to your i.MX. On the MEK board, with a 10-pin JTAG connector, you have the cut the cable line 10 of the ribbon cable: On the cable, cut the reset line like this: With my Lauterbach JTAG  probe, when I do a "hot plug" I never have a reset of my i.MX. BR Vincent

The following document contains a list of document, questions and discussions that are relevant in the community based on amount of views. If you are having a problem, doubt or getting started in i.MX processors, you should check the following links to see if your doubt is in there. Yocto Project Freescale Yocto Project main page‌ Yocto Training - HOME‌ i.MX Yocto Project: Frequently Asked Questions‌ Useful bitbake commands‌ Yocto Project Package Management - smart  How to add a new layer and a new recipe in Yocto  Setting up the Eclipse IDE for Yocto Application Development Guide to the .sdcard format  Yocto NFS &amp; TFTP boot  YOCTO project clean  Yocto with a package manager (ex: apt-get)  Yocto Setting the Default Ethernet address and disable DHCP on boot.  i.MX x Building QT for i.MX6  i.MX6/7 DDR Stress Test Tool V3.00  i.MX6DQSDL DDR3 Script Aid  Installing Ubuntu Rootfs on NXP i.MX6 boards  iMX6DQ MAX9286 MIPI CSI2 720P camera surround view solution for Linux BSP i.MX Design&amp;Tool Lists  Simple GPIO Example - quandry  i.MX6 GStreamer-imx Plugins - Tutorial &amp; Example Pipelines  Streaming USB Webcam over Network  Step-by-step: How to setup TI Wilink (WL18xx) with iMX6 Linux 3.10.53  Linux / Kernel Copying Files Between Windows and Linux using PuTTY  Building Linux Kernel  Patch to support uboot logo keep from uboot to kernel for NXP Linux and Android BSP (HDMI, LCD and LVDS)  load kernel from SD card in U-boot  Changing the Kernel configuration for i.MX6 SABRE  Android  The Android Booting process  What is inside the init.rc and what is it used for.  Others How to use qtmultimedia(QML) with Gstreamer 1.0

The patches are based on iMX53 L2.6.35_ER1109 BSP. In default linux BSP, the followed two pathes were supported in kernel driver mxc_v4l2_capture.c: CSI->IC->MEM CSI->MEM After appied these two patches, it can support the followed path: CSI->VDI->IC->MEM In this mode, the VDI de-interlace will be handled on the fly, so the whole system bandwidth will be reduced. Limitations: 1. Since the IC can only output resolution up to 1024*1024, so this is the limation on output. 2. Only VDI motion mode 2 was supported. mxc_v4l2_tvin_vdi_ic.zip: It is the test aplication, test command: "./mxc_v4l2_tvin.out -ol 0 -ot 0 -ow 800 -oh 480 -i 2" "-i 2" means CSI->VDI->IC->MEM path.

The attached is the document and sample code for iMX5 system 80 interface LCD driver based on IPUV3. It is based on iMX51 2.6.31_09.12 BSP (SDK 1.7), tested on iMX53 3-Stack board. 1. Description This is Smartlcd driver for Freescale MX51 SDK1.7 release. (Kernel: 2.6.31_09.12.00/01)  2. File List -- Smartlcd_giantplus_4_IMX51_Linux_2.6.31_09.12.01.patch: SmartLCD panel support patch, and unit test code. -- Sample.config: the config file for reference. -- readme.txt: this file, please refer to it before use the package. -- SmartLCD Structure.pptx: the basic structure for smartlcd on IPUv3. 3. Requirement - MX51_3DS Green board(TO2.0) - No hardware rework needed, only need plug the giantplus GMA722A0 to J10. - MX51 SDK1.7 release package - L2.6.31_09.12.00_SDK_source.tar.gz                                - redboot_200952.zip 4. How to use 4.1 How to use demo -- Program default redboot.bin to board via ATKtools -- Copy attached zImage to tftp folder (assume /tftpboot) -- extract default rootfs to NFS folder (assume /nfsroot) -- COPY attached imx51_fb_test to ~/unit_test folder. -- Power on the board -- After redboot is boot up, use following command to boot up linux kernel    load -r -b 0x100000 zImage    exec -c "noinitrd console=ttymxc0 root=/dev/nfsroot rootfstype=nfsroot nfsroot=10.192.225.221:/nfsroot/rootfs rw ip=dhcp" -- Once the linux kernel launched, run following commands to test smartlcd panel.    cd /unit_tests    ./imx51_fb_test 4.2 How to use source code -- Current release code is based on L2.6.31_09.12.00_SDK_source.tar.gz. Extract the file to your working folder. -- Entering the working folder and type "./install", select a folder to install ltib. (such as .../ltib) -- Entering ltib folder and type "./ltib" to build Linux platform.  If you are not familiar with this setp, please refer to doc "i.MX_3Stack_SDK_UserGuide.pdf" for detail. -- Entering folder ".../ltib/rpm/BUILD/linux", copy "Smartlcd_giantplus_4_IMX51_Linux_2.6.31_09.12.01.patch" from release package to current folder    Run command "patch -p1 < Smartlcd_giantplus_4_IMX51_Linux_2.6.31_09.12.01.patch" -- When complete, run command "make ARCH=arm menuconfig", and you can refer to attached sample.config for detail.    * enable    Device Drivers ----> Graphics support ----> [*]   Asynchronous Panels                                            ----> [*] GiantPlus 240x320 Panel                                             * disable    Device Drivers ----> Graphics support ----> [ ]   Synchronous Panel Framebuffer                                         ----> Multimedia support    ----> [ ]   Video For Linux                                             -- Run command "make ARCH=arm" to build kernel.  4.3 How to do SMARTLCD driver test -- After Smartlcd_giantplus_4_IMX51_Linux_2.6.31_09.12.01.patch applied, there will be an folder "IMX51_TEST" under linux. -- Go to that folder, and run "make ARCH=arm", imx51_fb_test will be created. -- Copy imx51_fb_test to rootfs/unit_test. and run. 5. History N/A 6. Known Issue -- V4L2 not working yet.

Question: When working with v1.6.0.55 using the standard profile for i.MX35 the tool fails most of the time when transferring the target root file system, on v1.6.0.42 it works just fine. The tags on the internal git don’t clearly mention a tool version, but a BSP. Wwhat are the differences between v1.6.0.55 and v1.6.0.42? Or to which tag(or commit) they correspond on git? Answer: 1.6.042 commit by looking at "Apps/MfgTool.exe/docs/changelog.txt": 1ca2a16df736ac51979a67423fef6a09bed6b7e2 And 1.6.055: "06a4f9190e34297b7273fc4bb4a92737e5bc837f"

Attached patch enable dual display on i.MX51 wince6. It will set DI0 as main display.

In our default release , the eboot logo only can be show on WVGA panel. Attached patch file can let the eboot logo show both on DVI XGA and RGB WVGA panel.

We have a ATK tool which can program image, also it can burn fuse for i.MX51. Since fuse is one time program, so please take care the fuse can't be turn back after programmed.