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'Multi-core Processor Technology’ will be the key in the development of next generation of advanced computing devices. With major silicon vendor Freescale bringing multi-core application processors for the mainstream embedded devices, there is  need to have the multi-core processing support in the embedded operating systems. Windows Embedded Compact 7(WEC7) will enhance the performance of ARM based multi-core platforms with the addition of Symmetric Multi-Processing (SMP) support. iWave systems has done a SMP support verification on its Freescale’s i.MX6 Quad core processor running WEC7 platform. Symmetric Multi-Processing (SMP) support in WEC7: The most important update in the Windows Embedded Compact 7 is the support for Symmetric Multi-Processing (SMP) which takes the full advantage of multi-core systems providing a performance boost when the multithreaded applications are being used. The multi-core processor platforms such as Freescale’s i.MX6Q which has 4 identical CPU cores, can effectively take advantage of SMP support in WEC7. SMP enabled kernel can use several CPU cores simultaneously and distribute the execution of different processes and threads to them. The number of available cores can be determined by SMP API from the application – the processing and assignment of a thread to a specially selected core is also possible. Read More.. Windows Embedded Compact7 on i.MX6 RainboW-G15D Development Board: iWave Systems, profoundly known for its genuine embedded solution offerings spanning from SOMs to fully integrated systems, offers Windows Embedded Compact 7 (WEC7) reference BSP for iWave’s i.MX6 platform named RainboW G15D besides the existing Linux & Android BSP versions. All the latest features that WEC7 offers such as Silverlight 3.0, MPEG-4 HD, Expression Blend, Active Sync and also Adobe Flash10.1 are made available. About i.MX6 Qseven Development Board: The Development Platform incorporates Qseven compatible i.MX6x SOM which is based on Freescale's iMX 6 Series 1.2GHz multimedia focused processor and Generic Q7 compatible Evaluation Board. This platform can be used for quick prototyping of any high end applications in verticals like Automotive, Industrial & Medical. Being a nano ITX form factor with 120mmx120mm size, the board is highly packed with all necessary on-board connectors to validate complete iMX6 CPU features. About iWave Systems: iWave has been an innovator in the development of “Highly integrated, high-performance, low-power and low-cost i.MX6/i.MX50/i.MX53/i.MX51/i.MX27 SOMs”. iWave helps its customers reduce their time-to-market and development effort with its products ranging from System-On-Module to complete systems. The i.MX6 Pico ITX SBC is brought out by iWave in a record time of just 5 weeks. Furthermore, iWave’s i.MX6/i.MX50/i.MX53/i.MX51/i.MX27 SOMs have been engineered to meet the industry demanding requirements like various Embedded Computing Applications in Industrial, Medical & Automotive verticals. iWave provides full product design engineering and manufacturing services around the i.MX SOMs to help customers quickly develop innovative products and solutions. For more details: WEC7 on i.MX6 Rainbow G15D  | iWave Systems email: mktg@iwavesystems.com
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In this new version, the experts at GuruCE have achieved some major improvements in performance and added quite a lot of new functionality: 4.75x faster than our previous release This is >6x faster than our competitor's BSP... Added full HDMI support, including display auto-detection, hot-plug and dynamic resolution changes in CE This means you can plug in a 1360x768 monitor and have the CE desktop shown in that resolution, then unplug the monitor and plug in a 1920x1080 monitor and CE will dynamically change resolution and show the desktop in 1920x1080 resolution, all this of course without the purple line on the left (a long-standing problem in all the other iMX6 BSPs available). HDMI, LVDS and LCD display output is now configurable in the bootloader This means you can have one kernel image for all. Just go into the bootloader menu and select which display you are using at which resolution and launch the kernel. Simple as that! Added support for DMA on all UARTs Full RX & TX DMA support on UART1, 2, 3, 4 and 5. Upgraded to the latest Vivante GPU GALCORE driver v5.0.11 (25762) And we added all the tutorials and test code as well. Together with the amazing performance increase of this release you can now enjoy 110+ fps in full-screen 1920x1080 (and 350+ fps windowed) for OpenGL-ES 1.1/2.0! The OpenVG spinning tiger sample is now so fast you only see a blur, and we fully support OpenCL on Dual and Quad of course. Now asynchronously loading drivers for faster boot Added free downloadable demo kernel for Congatec-QMX6 (Dual/Quad, 1 GB module) on a QKIT-ARM Maximum CPU temperature at rest: 45°C / 113°F Maximum CPU temperature while running OpenGL-ES 2.0 reflecting ball: 65°C / 149°F This is not nearly as low as we would like, but it's a lot better already. Our next release will focus on power consumption and heat generation reductions. Improved network performance The performance improvements also make Ethernet throughput a lot better. We're only halfway to reaching the theoretical maximum possible on the iMX6 of ~45 Mbyte/s (it's on our list of things to fix), but at least Ethernet speeds are out of the KByte range now (tested using NETIO on WEC7 & WEC2013): NETIO - Network Throughput Benchmark, Version 1.32 (C) 1997-2012 Kai Uwe Rommel TCP connection established. Packet size 1k bytes: 19.11 MByte/s Tx, 19.22 MByte/s Rx. Packet size 2k bytes: 21.22 MByte/s Tx, 20.38 MByte/s Rx. Packet size 4k bytes: 22.44 MByte/s Tx, 20.85 MByte/s Rx. Packet size 8k bytes: 23.06 MByte/s Tx, 22.43 MByte/s Rx. Packet size 16k bytes: 20.67 MByte/s Tx, 19.38 MByte/s Rx. Packet size 32k bytes: 20.79 MByte/s Tx, 20.58 MByte/s Rx. Done. UDP connection established. Packet size 1k bytes: 13.84 MByte/s (0%) Tx, 13.76 MByte/s (0%) Rx. Packet size 2k bytes: 15.97 MByte/s (0%) Tx, 15.97 MByte/s (0%) Rx. Packet size 4k bytes: 20.25 MByte/s (0%) Tx, 19.83 MByte/s (0%) Rx. Packet size 8k bytes: 22.39 MByte/s (0%) Tx, 22.49 MByte/s (0%) Rx. Packet size 16k bytes: 19.34 MByte/s (0%) Tx, 17.95 MByte/s (0%) Rx. Packet size 32k bytes: 21.78 MByte/s (0%) Tx, 21.17 MByte/s (0%) Rx. Done. Further details in the release notes. Don't believe the hype? Try it yourself! We've got free downloadable demo kernels for the RIoTboard, the SABRE-Lite, the Nitrogen6X, the Opal6, the ConnectCore6 and now also the Conga-QMX6. GuruCE website: https://guruce.com iMX6 landing page: https://guruce.com/imx6 Latest iMX6 BSP r474: https://guruce.com/imx6-bsp-releases/imx6-r474
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On the 1st of July 2018, GuruCE released an update of their WEC7/WEC2013 iMX6 BSP now with full support for iMX6 ULL, UL, Solo, DualLite, Dual, DualPlus, Quad and QuadPlus processors! The BSP can be used to build Windows Embedded Compact 7 and Compact 2013 kernels. Some highlights: Support for UL & ULL Display clone CE Updater (update firmware from within CE) Multi-touch Super fast and reliable USB RNDIS and USB Serial for KITL Simplified use of hive-based registry (no need to pre-format disks anymore) Completely verified clock tree code Gigabit Ethernet (on selected boards and with limitations due to NDIS) Easy switch USB function Copy/update firmware from SD to eMMC Keep track of reason of last reset (power-on reset, software reset, watchdog reset, etc) Many improvements to our BSP catalog to make working with our BSP even easier And many more improvements, fixes and new features! Further details in the release notes. Our promise We will keep improving our iMX6 BSP, adding new features and we will be supporting our customers for many years to come, at the very least until the end of Microsoft's extended support end date of 10 October 2023. Even though the GuruCE i.MX6 BSP is already the best performing, 100% OAL stable and most feature-rich i.MX6 BSP on the market today, there are always things to improve or fix and new features to implement. Here's our wishlist: Bring hardware accelerated H.264 video codecs to WEC2013 (not just WEC7) Improve Gigabit network performance Animated GIF bootsplash support Create a solid solution for multi-display touch As always; if you have anything you want us to add to the list or you want us to prioritize an item on the list: contact us and we'll make it happen. Don't forget to check our Testimonials page to see what some of our customers have to say about the GuruCE i.MX6 BSP. Don't believe the hype? Try it yourself! We've got free downloadable evaluation kernels for the Element14 RIoTboard, the Boundary Devices SABRE-Lite, Nitrogen6X and Nitrogen6_VM, the Device Solutions Opal6 (all variants), the Digi ConnectCore6, the NXP SDP (DualLite & Quad), the SDB-QP(QuadPlus), the NXP MCIMX6ULL EVK (ULL), the Toradex Colibri and the Variscite VAR-SOM_MX6 (Dual/Quad) Starter Kit. GuruCE website: https://guruce.com iMX6 landing page: https://guruce.com/imx6 Latest iMX6 BSP release: https://guruce.com/imx6/latest
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i.MX53 SOM at Arm TechCon,2011 Added by iWavesystems on November 17, 2011 at 7:21am    
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Today, technology goes forward and we get some new possibilities in the Online TV viewing. iWave’s i.MX6 Pico-ITX board with Jelly Bean Android provides one such solution. Today we can watch online TV in the Browser that will run in the i.MX6 Pico-ITX Single Board Computer. This uses Real Time Messaging Protocol (RTMP).  RTMP was initially a proprietary protocol developed by Macromedia. It is based on TCP and was specifically designed for streaming video, audio, and data between a media server and clients (Flash player). Currently applications like follows use this protocol: Online multi-player games Text and video chat applications Virtual meeting applications Synchronous and interactive e-learning applications (business simulation games, etc.) In the early days of web video delivery, users had to rely on progressive delivery of video, meaning that the bits of video were delivered to your player one packet at a time “in the blind,” with no communication between the server and player. When a reasonable percentage of the file was downloaded to disk, the player would begin playing the file. However too often the player caught up with the point at which the file was being delivered, and playback halted. As a result streaming was created—a mode through which the video is passed to the player, with increased communication and monitoring in place, and it happens in real time between the player and server. If bandwidth degrades on the player side, it signals the server and “buffers” until it can obtain a suitable amount of packets of video to resume playback. One benefit with RTMP worth mentioning here is its ability to provide multicast support. If you run an enterprise and want to take one stream inside your corporate network and deliver it to many users without initiating a new connection for each user, RTMP is the best technology. Using iMX6 PICO-ITX Android Jelly Bean, one can watch ‘online live iptv broadcasting’ and ‘video on demand’. As shown in the above block diagram, web browser through http requests the web server, then the web server will send the swf file to the web browser over http. Flash player then connects to the media server using RTMP. RTMP server will send the data via RTMP that will be played in the Flash Player. If your favourite online service (IP TV) uses the RTMP protocol for broadcasting, you have a good chance of being able to watch the video stream live using iWave’s i.MX6 SBC.  Its operating principle is simple: you input the address of the video server. It just connects to the server, consuming only the network traffic containing the video, and streams it to your display unit. Online Live IP TV: "Russia Today" is one of the IPTV broadcasting http://rt.com/on-air/rt-america-air/ we can watch this IPTV online in the Jelly Bean's Browser. We can choose the quality either HD, medium and low. Video On Demand: i.MX6 Pico ITX SBC also supports RTMP for Video on demand services. "Deutsche Welle" is one of the Video on demand service provider. We can watch this on demand video in the Android Browser.  http://www.dw-world.de/dw/0,,4756,00.html We can watch Discovery Germany Video By clicking on that. Finally iWave’s i.MX6 Single Board Computer is able to provide Video on demand services and Worldwide IPTV broadcasting over HDMI or LVDS display. For further information or enquiries please write to mktg@iwavesystems.com or visit www.iwavesystems.com. http://http://www.iwavesystems.com/onlinetv-videoondemand-imx6-android
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http://www.youtube.com/watch?feature=player_embedded&v=aED0x7_NptY   Uploaded by emtrion on Aug 24, 2011 processor modul showing parallel two videos using silverlight and vector graphic using Open VG Category: Science & Technology License: Standard YouTube License  
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This post is based on http://boundarydevices.com/using-the-cortex-m4-mcu-on-the-nit6_solox/ The i.MX6 SoloX processor is the first of a kind, coupling a Cortex-A9 with a Cortex-M4 core inside one chip to offer the best of both MPU and MCU worlds. The MCU is perfect for all the real-time tasks whereas the MPU can provide a great UI experience with non real-time OS such as GNU/Linux. This blog post will detail how to build and run source code on the MCU using our Nit6_SoloX. Terminology Before getting any further, here is a list of terms that will be used in this post: MCC: Multi-Core Communication: protocol offered by Freescale for the MCU and MPU to exchange data MCU: Microcontroller Unit such as the ARM Cortex-M series, here referring to the Cortex-M4 MPU: Microprocessor Unit such as the ARM Cortex-A series, here referring to the Cortex-A9 MQX: RTOS provided by Freescale to run their MCUs RTOS: Real-Time Operating System such as MQX or FreeRTOS For the impatient You can download a demo image from here: 20150814-buildroot-nitrogen6x-mcu-demo.img.gz for Nit6_SoloX. As usual, you’ll need to register on our site and agree to the EULA because it contains Freescale content. The image is a 1GB SD card image that can be restored using zcat and dd under Linux. ~$ zcat 20150814-buildroot*.img.gz | sudo dd of=/dev/sdX bs=1M For Windows users, please use Alex Page’s USB Image Tool. This image contains the following components: Linux kernel 3.14.38 from our repo https://github.com/boundarydevices/linux-imx6/tree/boundary-imx_3.14.38_6qp_beta U-Boot v2015.04 from our repo https://github.com/boundarydevices/u-boot-imx6/tree/boundary-imx6sx Development environment setup This section will detail how to set up a Linux machine to be able to build MCU source code. First you need to download the "MQX RTOS for i.MX 6SoloX v4.1.0 releases and patches" file from Freescale website: http://www.freescale.com/webapp/sps/site/prod_summary.jsp?code=MQX Then you need to untar this archive and apply our patch to add support for the Nit6_SoloX board. ~$ cd && mkdir mqx && cd mqx ~/mqx$ tar xf ~/Downloads/Freescale\ MQX\ RTOS\ 4.1.0\ for\ i.MX\ 6SoloX\ Linux\ Base.tar.gz ~/mqx$ wget http://boundarydevices.com.commondatastorage.googleapis.com/0001-Add-Nit6_SoloX-board-support.patch ~/mqx$ patch -p1 < 0001-Add-Nit6_SoloX-board-support.patch ~/mqx$ find . -name "*.sh" -exec chmod +x {} \; Note that this package comes with a good set of documentation which we invite you to read: doc/Freescale_MQX_RTOS_4.1.0_i.MX_6SoloX_Release_Notes.pdf doc/Getting_Started_with_Freescale_MQX_RTOS_on_i.MX_6SoloX.pdf As specified in the documentation, you need to install a specific toolchain (CodeSourcery v2014q1) in order to build the BSP. ~$ cd && mkdir toolchains && cd toolchains ~/toolchains$ wget https://launchpad.net/gcc-arm-embedded/4.8/4.8-2014-q1-update/+download/gcc-arm-none-eabi-4_8-2014q1-20140314-linux.tar.bz2 ~/toolchains$ tar xjf gcc-arm-none-eabi-4_8-2014q1-20140314-linux.tar.bz2 ~/toolchains$ rm gcc-arm-none-eabi-4_8-2014q1-20140314-linux.tar.bz2 Your machine is now ready to build applications for the MCU! Build instructions This section explains how to build the BSP as well as the applications for the MCU only. In order to build the BSP for the MPU, please refer to other blog posts on either Yocto or Buildroot. ~$ cd ~/mqx/ ~/mqx$ export TOP=$PWD ~/mqx$ export TOOLCHAIN_ROOTDIR=$HOME/toolchains/gcc-arm-none-eabi-4_8-2014q1/ ~/mqx$ cd $TOP/build/imx6sx_nit6sx_m4/make ~/mqx$ ./build_gcc_arm.sh As the BSP for our board is now built, we can build any example application provided in the MQX package. In order to have an interaction between the MPU and the MCU, you need to build a MCC application. Below are the instructions to build the pingpong application which sends data back and forth between the cores. ~/mqx$ cd $TOP/mcc/examples/pingpong/build/make/pingpong_example_imx6sx_nit6sx_m4/ ~/mqx$ ./build_gcc_arm.sh ~/mqx$ $TOOLCHAIN_ROOTDIR/bin/arm-none-eabi-objcopy \        ./gcc_arm/ram_release/pingpong_example_imx6sx_nit6sx_m4.elf \        -O binary m4_fw.bin That's it, the binary is ready to be used! Some might be interested in using an IDE to browse/modify/build the source code, note that Freescale provides instructions to use IAR Workbench (Windows only). It seems that there isn't any plan to support the SoloX MQX release inside the KSDK (Kinetis SDK) as explained in a community forum post. Run the demo First you need to copy the image (20150814-buildroot-nitrogen6x-mcu-demo.img.gz) provided at the beginning of this post to an SD Card. Then copy the m4_fw.bin binary to the root directory of the SD Card. The SD Card contains the U-Boot version that enables the use of the Cortex-M4, the bootloader inside your NOR must therefore be upgraded. U-Boot > setenv bootfile u-boot.imx U-Boot > run upgradeu Once the upgrade is complete and the board restarted, make sure to have a clean environment: U-Boot > env default -a ## Resetting to default environment U-Boot > saveenv By default, the M4 must be flashed in NOR memory, a U-Boot command has been added to look for the m4_fw.bin as the root of any external storage (SD, USB, SATA): U-Boot > run m4update This command will download the firmware from external storage to RAM and flash it at the offset 0x1E0000 of the NOR. While debugging on the MCU, you might wish not to write every firmware into NOR so we've added a command that loads the M4 firmware directly from external storage. U-Boot > setenv m4boot 'run m4boot_ext' Before going any further, make sure to hook up the second serial port to your machine as the one marked as "console" will be used for U-Boot and the other one will display data coming from the MCU. In order to start the MCU at boot up, we need to set a variable that will tell the 6x_bootscript to load the firmware into OCRAM. If you wish to start the MCU at every boot, make sure to save this variable. U-Boot > setenv m4enabled 1 U-Boot > boot While the kernel is booting, you should see the following prompt on the MCU serial output: ***** MCC PINGPONG EXAMPLE ***** Please wait :   1) A9 peer is ready   Then press "S" to start the demo ******************************** Press "S" to start the demo : Press the S key as requested above on the MCU serial console and then log into Buildroot on the MPU serial output (login is root, no password). You now need to enable the MPU side of the communication before starting the demo: # echo 1 > /sys/bus/platform/drivers/imx6sx-mcc-test/mcctest.15/pingpong_en & A9 mcc prepares run, MCC version is 002.000 test/mcctest.15/pingpong_en & # Main task received a msg from [1, 0, 2] endpoint Message: Size=0x00000004, data = 0x00000002 Main task received a msg from [1, 0, 2] endpoint Message: Size=0x00000004, data = 0x00000004 ... That's it, you've built a MCU application from scratch and can now start exploring all the examples provided inside the MQX SoloX release.
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     See a connected Android demo on an i.MX53 in action -  http://www.youtube.com/watch?v=1R1kbya77eE   
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Boundary Devices is pleased to announce that its i.MX8M-based SBC Nitrogen8M is available and in stock! https://boundarydevices.com/product/nitrogen8m-imx8/  Nitrogen8M specifications The Nitrogen8M comes pre-populated with the most robust set of connectivity options available to allow for rapid development and validation of your next project. The boards are also be built with Boundary Device’s industry-leading, production-ready standards and include options such as industrial temp and conformal coating. All this allows the Nitrogen8M to be used as an evaluation platform or production-ready solution. Review the full list of the specifications below. More information including pricing and availability can be found on the Nitrogen8M product page: CPU — i.MX 8M Quad Core (x4 Cortex-A53 @ 1.5GHz; Cortex-M4 @ 266MHz) RAM — 2GB LPDDR4 (4GB Optional) Storage — 8GB eMMC (upgradeable to 128GB) GPU — Vivante GC7000Lite Camera — x2 4-lane MIPI-CSI Display — x1 HDMI (w/CEC) and x1 MIPI DSI several MIPI-DSI displays options available Wireless — 802.11 ac and Bluetooth 4.1 BD-SDMAC Module (QCA9377) Networking — Gigabit Ethernet port Other I/O: x3 USB 3.0 Host ports x1 USB 3.0 OTG port x3 I2C x1 SPI x3 RS-232 x1 SD/MMC x1 RTC + battery x2 PCIe (1 Mini-PCIE connector, 1 on expansion connector) x1 JTAG Power — 5V DC input Operating Temperature — 0 to 70°C (Industrial Optional) Operating System — Yocto, Ubuntu/Debian, Buildroot, FreeRTOS (M4 Core), Android Demos As some people say, a video is worth a thousand words, so let's just share what can run on that platform already: Nitrogen8M Crank Storyboard Demo - YouTube  Nitrogen8M Yocto GPU SDK Demo - YouTube  Nitrogen8M Android 8.1 Qt5 + 4k video demo - YouTube  Source code access The bootloader and kernel source code are already available publicly on our GitHub account: GitHub - boundarydevices/u-boot-imx6 at boundary-imx_v2017.03_4.9.51_imx8m_ga  GitHub - boundarydevices/linux-imx6 at boundary-imx_4.9.x_2.0.0_ga  Android has been officially released: https://boundarydevices.com/android-oreo-8-1-0-release-for-nitrogen8m/  Some benchmarking has been done to compare against previous i.MX6 CPUs Yocto BSP is on the way, Boundary Devices is actively contributing to the community BSP: meta-freescale-3rdparty/nitrogen8m.conf at master · Freescale/meta-freescale-3rdparty · GitHub  Ubuntu Bionic Beaver beta image is also available upon request (please contact support@boundarydevices.com). Feel free to contact us for more information: info@boundarydevices.com.
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Added by Johan Dams on June 24, 2010 at 7:07am   http://www.youtube.com/watch?feature=player_embedded&v=pOSluW6vHL8   Uploaded by Charbax on Jun 22, 2010 http://genesiamericas.com is presenting this awesome looking ARM Cortex A8 based Smartbook design, presented by Genesi who designed the hardware in collaboration with Pegatron of this latest generation of this Freescale Powered Smartbook design. For fun, we are running Microsoft Office through a high resolution version of Citrix viewer on the latest version of Ubuntu 10.4 for ARM processors. This could provide a one click online based software as a service solution. Want to run any X86 application on your ARM Laptop? Just click through the Citrix virtualization stuff and you can have it all running and smoothly. In theory, the apps could be processed by a grid and delivered much faster than on a single x86 processor based device.   Genesi are providing the hardware and software integration solution, in combination with Future Electronics, they can provide the whole solution to carriers, distributors, with the full bill of material, setting up the manufacturing and making the whole thing work and be sold to the market.   Genesi's main IP is their Aura firmware solution: http://www.genesi-usa.com/products/firmware   Aura, the Genesi Firmware offering, implements a run-time, re-entrant hardware abstraction layer supporting the industry standard IEEE 1275 (OpenFirmware) and UEFI firmware specifications, with significant added functionality.   These additional features provide cost reduction of systems and faster time-to-market of hardware. Genesi provides board bring-up services and firmware for other Power Architecture and ARM hardware suppliers, up to and including a Linux desktop, based on our firmware.   Genesi is an active Open Source supporter, having donated a lot of hardware over the years to Debian, OpenSuSe, Gentoo, Crux and many other Linux distributions.   Genesi says that they are very active in optimizing software specifically for ARM Cortex by porting libraries to the NEON unit in these devices resulting in large speedups.   Genesi has a developer forum: http://www.powerdeveloper.org Category: Science & Technology License: Standard YouTube License
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This document is an overview file for introducing MYIR's CPU Module MYC-Y6ULX, which is starting at only $18, delivered with shield cover and powered by NXP i.MX 6UltraLite / 6ULL ARM Cortex-A7 processor. It is part of a MYD-Y6ULX development board, capable of running Linux and supports -40 to 85°C working temperature for industrial embedded applications.   The MYC-Y6ULX CPU Module has a compact sizeof 37mm by 39mm, carrying out as many as peripheral signals and IOs through 1.0mm pitch 140-pin stamp hole expansion interface. It is integrated with 528 MHz i.MX 6UltraLite / i.MX 6ULL processor, 256MB DDR3, 256MB Nand Flash (4GB eMMC Flash is optional) and Ethernet PHY. It is populated on MYD-Y6ULX development board base board as the core controller board, thus rich peripherals and interfaces have been extended through connectors and headers to the base board like Serial ports, USB, Ethernet, CAN, Micro SD card, WiFi module, LCD/Touch screen, Camera, Audio as well as a Mini PCIe interface for optional USB based 4G LTE module. The MYD-Y6ULX is a versatile platform and solid reference design delivered with necessary cable accessories and detailed documentations ideal for prototype and evaluation based on i.MX 6UL/6ULL solutions.                                  MYC-Y6ULX CPU Module (delivered with shield cover)   MYIR offers three models with different configurations and features to meet various requirements from customers. MYD-Y6ULX MYD-Y6ULG2-256N256D-50-I MYD-Y6ULY2-256N256D-50-C MYD-Y6ULY2-4E512D-50-C MYC-Y6ULX MYC-Y6ULG2-256N256D-50-I MYC-Y6ULY2-256N256D-50-C MYC-Y6ULY2-4E512D-50-C Processor MCIMX6G2CVM05AB MCIMX6Y2DVM05AA MCIMX6Y2DVM05AA RAM 256MB DDR3 256MB DDR3 512MB DDR3 Flash <span "="" style="font-family: arial, 宋体;">256MB Nand Flash 256MB Nand Flash 4GB eMMC WiFi Support Support Cannot support Reuse SDIO with eMMC Working Temp. -40 to +85 Celsius 0 to +70 Celsius 0 to +70 Celsius WiFi Module can only support -20 to +65 Celsius.                                                                                                        Device Options                                                                  MYD-Y6ULX Development Board The launch of the MYC-Y6ULX CPU Module and MYD-Y6ULX development board provide an expansion solution for development based on NXP’s i.MX 6UltraLite / 6ULL processor after MYIR’s release of the MYS-6ULX Single Board Computer in April.
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In May of 2015, Forlinx Embedded Tech. Co., Ltd launched a new item based on i.MX6 serial microprocessor, both quad-core and dual lite-core are optional. Its features are as below: 1)i.MX6Q CPU module features i.MX6Q base board features: 2) i.MX6DL features: Both i.MX6Q and i.MX6DL share one CPU module and one base board. But SATA interface is only available for the quad-core board. They have excellent performance of OS Android, both multi-screen displaying and displayings are possible on it. Besides, as many companies are now engaged in EV Charger Billing Unit project or solution, i.MX6 will be a best backup option based on its advantages of LVDS and multi-screen For more details pls refer to our homepage www.forlinx.net or send emails to grace@forlinx.com Hardware Interface   S
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REX - Freescale iMX6 Opensource Project Designed by FEDEVEL Academy Based on Freescale i.MX6 CPU. This is an open source project. All documents are free for download, including Schematic and PCB files. The iMX6 Rex Module is also used for teaching about Schematic Design and Advanced PCB Layout at FEDEVEL Academy. Module Specification Freescale iMX6 processor, up to 1.2GHz / 4 cores Soldered down DDR3-1066 (533MHz), up to 4GB 10/100/1000 Mbps Ethernet 1x HDMI (up to QXGA 2048×1536) 1x LVDS (up to WUXGA 1920×1200) 1x PCIE 1x SATA On board SPI Flash up to 32Mb 1x SD, 1x MMC 2x USB 3x UART, 3x I2C, 1x SPI Digital audio JTAG User LED, power LED 2x high speed board to board connectors (only one required) Size: 70 x 40 mm (smaller than a credit card) Input power: 7 to 24 V (DC) Releated posts iMX6 Rex EMC Testing – Pass iMX6 Rex infrared images User friendly GUI + Mouse + Keyboard working ok How long it took to design the iMX6 Rex module prototype? iMX6 Module Total Cost Prototype Developement The iMX6 Rex module design licensing Video from Assembling iMX6 Rex Boards Bringing up i.MX6 Rex Module to Life – from unpacking to booting iMX6 Rex Layout Video
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Connect any Android-based M2M device seamlessly with Device Cloud by Etherios and instantly build solutions for the Internet of Things (IoT). This set of libraries, plug-ins, samples and tools simplifies the development of Device Cloud applications for Android devices (Android version 2.2 and later). Easy and immediate integration of IoT cloud connectivity into applications Supports any Android device version 2.2 and greater Two-way messaging for full cloud-to-device messaging and control Device management and troubleshooting tools including configuration edits, firmware updates and device reboots Application development tools Remote file system management Secure connections Installation via Eclipse Update Manager The download includes:  Eclipse plug-ins that extend the functionality of the IDE, simplifying development Cloud Connector for Android library, including an API that allows Device Cloud communication with just a few lines of code Examples and demos (Android and Web applications), with source code included Comprehensive documentation, including a Getting Started Guide, a General Users Manual and an API reference Visit Cloud Connector for Android and download the free Cloud Connector for Android. For an overview of the Device Cloud by Etherios IoT solution, please also take a look at Device Cloud: Driving the Internet of ANYthing
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QBIT Running Linux - Matchbox Added by Renato Torres Tovar on January 7, 2012 at 8:58pm QBIT embedded system... I.MX23, 128LQFP    
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SBC+TVP_notes Added by Lautaro Carmona on September 26, 2011 at 10:49am Here is our hardware framework. We are using BlueTechnix Single Board Computer SBC-i.MX51 with our TVIN board with TVP5147 TV encoder.   We connect them together through an 80-pin connector, which includes:   CSI1.Data[0:9] CSI1.PIXCLK CSI1.HS CSI1.VS CSI1.MCLK CSI1.PWDN I2C_SDA I2C_SCL  
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An inquisitive visitor viewing i.MX6 Q7 Quad display Added by iWavesystems on June 26, 2012 at 3:49am    
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http://www.youtube.com/watch?v=AxqNOEPFtCk&feature=player_embedded   Uploaded by LinaroOrg on Nov 3, 2011 Orlando, Nov. 2, 2011   I took the opportunity of the Q4.11 edition of Linaro Connect to meet with 3 members of the Freescale Landing team at Linaro: Paul Liu (middleware and graphics acceleration), Haitao Zhang (kernel) and Eric Miao (tech lead, a long time contributor to the ARM Linux community).   In Linaro, a landing team is a engineering team that works on making a hardware platform supported in the upstream open-source projects such as the Linux kernel and distributions like Ubuntu and Android.   Eric, Paul and Haitao explained how they work with the Freescale engineers (they actually are employed by Canonical), and gave details about the technical challenges they face. It was also an opportunity to speak about the Freescale i.MX53 QuickStart board they work on, a low cost yet very powerful board for the community.   This board, together with the kernel and distribution releases made by Linaro, allows community contributors to work always with the latest versions. This is essential to allow the community to contribute.   They also explained how they work together. In particular, they organized a code sprint in Shanghai 1 month before, and had a very productive week together. Category: Science & Technology License: Creative Commons Attribution license (reuse allowed)  
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This overview document gives a brief introduction of MYIR's MYD-Y6ULX development board which is a complete evaluation platform for NXP’s i.MX 6UltraLite / 6ULL processor family, which can operate at 528 MHz and features the most efficient ARM Cortex-A7 core, providing various memory interfaces and enhancing the flexibility and convenience of the board to connect peripheral devices. The board is ready to run Linux and supports industrial operating temperature range from -40 to +85 Celsius. The MYD-Y6ULX development board employs the MYC-Y6ULX CPU Module as the controller board by populating the CPU Module on its base board through 1.0mm pitch 140-pin stamp hole interface. The MYC-Y6ULX CPU Module is mounted with a shield cover and integrated with core components including i.MX 6UltraLite / 6ULL processor, 256MB DDR3, 256MB Nand Flash or optional 4GB eMMC and Ethernet PHY. The base board has extended rich peripherals through connectors and headers like Serial ports, USB, Ethernet, CAN, Micro SD card, WiFi module, LCD/Touch screen, Camera, Audio as well as a Mini PCIe interface for optional USB based 4G LTE module. It is a versatile platform and solid reference design delivered with necessary cable accessories and detailed documentations ideal for prototype and evaluation based on i.MX 6UL/6ULL solutions. MYIR offers three models of MYD-Y6ULX development boards with mainly different features as shown in below table. User can select model according to their own requirement. MYD-Y6ULX MYD-Y6ULG2-256N256D-50-I MYD-Y6ULY2-256N256D-50-C MYD-Y6ULY2-4E512D-50-C MYC-Y6ULX MYC-Y6ULG2-256N256D-50-I MYC-Y6ULY2-256N256D-50-C MYC-Y6ULY2-4E512D-50-C Processor MCIMX6G2CVM05AB MCIMX6Y2DVM05AA MCIMX6Y2DVM05AA RAM 256MB DDR3 256MB DDR3 512MB DDR3 Flash 256MB Nand Flash 256MB Nand Flash 4GB eMMC WiFi Support Support Cannot support Reuse SDIO with eMMC Working Temp. -40 to +85 Celsius 0 to +70 Celsius 0 to +70 Celsius WiFi Module can only support -20 to +65 Celsius.                                                                  Three Models of MYD-Y6ULX (default configurations)                                                              MYD-Y6ULX Development Board                                                                MYC-Y6ULX CPU Module
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