Demo Summary An autonomous vehicle platform leveraging NXP’s new BlueBox engine, and deploying NXP silicon and software solutions at each ADAS node. The system demonstration incorporates the BlueBox central computing engine, together with radar, lidar, and vision sensing, as well as an on-board secure V2X system     Local Motors 3D Printed Car and NXP V2X Tech Showcase - YouTube      Demo / product features   BlueBox—a unique solution designed to help meet the stringent automotive safety, power and processing performance requirements of autonomous vehicle platforms S32V automotive vision and sensor fusion processor LS2085A embedded compute processor Up to 90,000 DMIPS at < 40 W, ISO 26262 supported   NXP Recommends   Product Link NXP BlueBox https://www.nxp.com/design/development-boards/automotive-development-platforms/nxp-bluebox-autonomous-driving-development-platform:BLBX?&tid=vanBlueBox S32V234 S32V234 Vision Processor | NXP        Document Number: https://community.nxp.com/docs/DOC-330366       A20

Demo This solution showcases the i.MX 6QuadPlus along with the MMPF0100 Power Management to enable the 2D/3D cluster, infotainment and rear view camera.      Features: High performance smooth 3D graphics based on the i.MX 6QuadPlus applications processor running on Linux. On the fly rendering of the infotainment menu. Seamlessly integrate extremely responsive instruments and highly complex 3D content Optimal usage of the CPU and GPU to achieve high-end graphics on the power effective and system cost effective i.MX Switch between HD video playback and the rear view camera on the secondary display Menu can be blended over the map (BG layer) using transparency   _______________________________________________________________________________________________________________________ Featured NXP Products: Product Link i.MX 6QuadPlus Processor i.MX 6QuadPlus Applications Processors | Quad Arm® Cortex®-A9 with extreme graphics performance and enhanced power manag…  i.MX 6DualPlus Processor i.MX 6DualPlus Applications Processors | Dual Arm Cortex-A9 for extreme graphics performance| 1.2 GHz | NXP  14-Channel Configurable Power Management IC 14-Channel Configurable Power Management IC | NXP  SABRE for Automotive Infotainment Based on the i.MX 6 Series SABRE|Automotive-Infotainment|i.MX6 | NXP    _________________________________________________________________________________________________________________________   Screen shot 1: Cluster with 3D maps Real-Time 3D map (created in Blender): 640 abstract buildings. 20 different building types. 3 “special” buildings. One building type. 5x5 map grid. Dynamic, directional lighting. Calculating and updating car chase camera every frame. Smooth 3D animations even at 30 Hz. This is no video!     Screen shot 2: Secondary Display playing Video or RearView Camera

Overview   The RDS12VR is a solution engineered for window lift, power windows, and sun roof systems. Developed in partnership with Tongji University and based on the 16-bit S12 MagniV® S12VR mixed-signal microcontrollers, the RDS12VR offers control by multiple LIN salve nodes or LIN master node, through the easy-to-control Graphics User Interface (GUI). The RDS12VR reduces unnecessary external components, lowers the total bill of material (BoM), improves system quality, and saves space in automotive applications through a smaller PCB. The RDS12VR solution includes hardware for real door/window in-vehicle applications, as well as software including anti-pinch algorithms and low-level S12VR drivers for reducing time to market. Block Diagram   Products Product Features S12VR  16-bit S12 MagniV® S12VR mixed-signal microcontrollers, efficient and scalable relay driven DC motor control solution   Features Features   Window manual/automatic up/down, automatic up/down with stop function Anti-pinch in both manual/automatic mode, anti-pinch region and force can be adjusted Stuck detection out of anti-pinch region, motor overload protection Soft stop when window is close to the top/bottom Self learning, calibration by updating the window/motor parameters stored in EEPROM Use hall sensor as well as current sense to judge anti-pinch in algorithm Power   Fault diagnosis, indicating low voltage, over voltage/current/temperature etc. Low power mode (leveraging S12VR low power mode) to reduce power consumption GUI Easy-to-control GUI, set the parameters and get the status Window lift can be controlled either by multiple LIN salve nodes or LIN master node, through GUI Functional Safety Able to comply with relevant content in US Federal Motor Vehicle Safety FMVSS No. 118 standard Document DRM160, Window Lift and Relay Based DC Motor Control Reference Design Using the S12VR Microcontrollers     

Demo We will present Ethernet AVB System Solution Demo running on Vybrid VF6XX or Calypso 6M/3M MPC574XG. Application will show audio playback of multi-channel audio streams received via Ethernet/Broadcom BroadRReach physical interface/, audio data streaming capability from external source or memory, audio sample rate conversion (Vybrid specific), Virtual Autosar Ethernet driver (cross core implementation) and cross core communication module capabilities.   Audio over AVB network—multi-channel audio streaming Syntonized audio playback over multiple audio end nodes Complex AVB solution supporting Power Architecture® and ARM® architecture   Product Link Vybrid Controller Solutions Tower System Module Vybrid VF6xx Tower System Kit with Arm DS-5 | NXP  Evaluation System for MPC574xB/C/G Family Evaluation System for MPC574xB/C/G Family | NXP 

Demo Owner Mark Middleton Processor Expert Software is a development system to create, configure, optimize, migrate, and deliver software components that generate source code for NXP silicon.       Features Processor expert software for Vybrid and i.MX processors Each component encapsulates a discrete set of functionality designed to accomplish the component's design objectives. When used, it may generate configuration files, header files, and/or source code depending on the type of component. A component may represent a hardware abstraction, a peripheral driver, a software algorithm (such as data encryption), or any logical collection of software function. Featured NXP Products Vybrid i.MX Applications Processors based on ARM® Cores Development Software Used Processor Expert Software and Embedded Components Links Vybrid Controller Solutions based on ARM® Technology ARM® Cortex®-A9 Cores: i.MX 6 Series Multicore Processors  

  From GUI to prototype to Product - Fast The evolution of Embedded GUI Design   Products ARM Cortex-A9|i.MX 6 Multicore Processors   Links NXP Partner Program - Crank Software Partner Profile   Other Demo Videos Storyboard Demo Launcher on Freescale's iMX6 Sabre Lite From Photoshop to Crank Storyboard Suite to i.MX Series Hardware in Minutes

Watch this demonstration that shows designing made easy with NXP's MMPF0100 and MMPF0200. These devices are optimized for i.MX 6 applications processors. Power-sensitive applications include portable medical devices, gateways, routers, home security systems, e-readers, tablets, and home energy management solutions.   Features MMPF0100 and MMPF0200 (PMIC) evaluation kit PMICs are optimized for i.MX 6 applications processors Light-Load Efficiency Exceptional Quiescent current Large amount of One-Time Programmable memory on board Flexibility: Programming kit connects the device via USB port and user can set up the start-up frequency, voltage levels, current limit and the timing of each regulator on the device Featured NXP Products MMPF0100 MMPF0200https://community.nxp.com/external-link.jspa?url=http%3A%2F%2Fwww.nxp.com%2Fproducts%2Fpower-management%2Fpmics%2Fpmics-for-i.mx-processors%2F12-channel-configurable-power-management-ic%3AMMPF0200 Block Diagrams

Demo Implementation of CarPlay on an NXP Processor highlighting Siri control, with Linux OS Features: CarPlay head unit implementation developed and available from NXP Professional Services, just one of many available functions for auto infotainment. Available for several NXP processors running Linux, including the i.MX6D and i.MX6Q, and the SABRE for Automotive Infotainment Development system. _______________________________________________________________________________________________________ Featured NXP Products: NXP Software for Apple Carplay|NXPhttp://www.nxp.com/products/software-and-tools/run-time-software/professional-services-software-technology/nxp-software-technology-for-carplay:SOFTWARE-APPLE-CARPLAY Professional Services Software Technology|NXP i.MX6Q|i.MX 6Quad Processors|Quad Core|NXP SABRE-2|Automotive-Infotainment|i.MX6|NXP _______________________________________________________________________________________________________

QGroundControl mission planner optimized by Qt Company to run on a Technexion TEP-15 industrial panel computer. QGroundControl is part of the Dronecode Platform. ======= Please see www.hovergames.com and www.nxp.com/hovergamesdrones for more drone hardware. ======= Features: A low power, rugged, fa n-less, cost effective reference solution NXP i.MX6 Quad core processor QGroundControl is an intuitive and powerful ground control station, is part of the Dronecode Platform and supports MAVLink enabled UAVs such as those based on the PX4 Pro Autopilot and ArduPilot. Technexion TEP-15 industrial panel computer running Ubuntu or Yocto Linux  The Qt Company optimized HMI & app Communicates with the NXP RDDRONE-FMUK66 Drone Flight management unit and KIT-HGDRONEK66 www.HoverGames.com drone kit Partner Information: Technexion offers both SBCs SOMs and Panel computers using NXP i.MX family processors Qt Company provides optimized solutions and consulting services for Qt framework    See NXP UAV landing page for solutions for Rovers and Drones and the HoverGames Drone reference design, and software coding challenge. ##

Demo This demo showcases the MAC57D5xx microcontroller rendering on a LVDS 1280x480 display for a full digital graphic instrument cluster and a Head-up Display on a secondary panel showcasing the warping capabilities of the microcontroller.       Single-chip instrument cluster solution with powerful graphics subsystem, including inline Head-Up Display warping functionality Dual-core ARM® Cortex®-A5/M4 for real-time and application processing and additional Cortex-M0+IOP core Cryptographic Services Engine, tamper detection and password protection for Flash memory and JTAG   Links Ultra-Reliable Multi-Core ARM-based MCU

MCAT is a graphical tool for automatic calculation and real-time tuning of selected motor control structure parameters. MCAT can be used with fixed or floating point 16- or 32-bit data so can be used for MPC5xxx Microcontrollers, Kinetis Microcontrollers, Digital Signal Controllers, and The specified item was not found.. It also acts as a plug-in tool for Freemaster which allows real-time monitoring, tuning and parameter updating in a target application. This Tool is a HMTL-based user-friendly graphical plug-in tool for NXP's FreeMASTER. It is intended for the development of PMSM FOC applications, real-time control structure parameter tuning, and will aid motor control users in adapting our MC solutions to their motors without a detailed knowledge of PI controller constant calculations. https://community.nxp.com/players.brightcove.net/4089003392001/default_default/index.html?videoId=4282488626001" style="color: #05afc3; background-color: #ffffff; font-size: 14.4px;" target="_blankFeatures Up to three motor application support with independent access to each motor Utilizing a pole placement method for control parameter estimation Real-time tuning and updating of control parameters Preview of the static configuration of tuned parameters Generic output file with static configuration of tuned parameters Plug-in tool for FreeMASTER, not available as a standalone tool Offers basic and expert tuning mode Modular S/W concept, easy configurable Featured NXP Products MC56F84XXX Qorivva MPC56xx ARM® Cortex®-M4 High Performance MCUs: Kinetis K  Series ARM® Cortex®-M0+/M4 Motor Control MCUs: Kinetis V Series

This doc explain how to use S32G design studio and SDK, contributed by Gary.Yuan yuan.yuan@nxp.com.

本文说明S32G LLCE CAN Linux驱动的 快速测试方法。 目录 1 参考资料 .................................................................... 2 1.1 参考资料 ................................................................. 2 1.2 版本匹配说明 .......................................................... 2 2 环境搭建 .................................................................... 3 2.1 使用Yocto编译 ........................................................ 3 2.2 使用Standalone编译 ............................................... 4 3 测试 ........................................................................... 5 3.1 硬件连接 ................................................................. 5 3.2 测试方法 ................................................................. 6 4 LLCE CAN Linux驱动说明 ......................................... 7 4.1 DTS ........................................................................ 7 4.2 源代码 .................................................................... 9  

Demo This demo combines Multi-standard Digital Radio by means of Software Defined Radio and combining broadcast radio with internet radio to get the best audio listening experience for the end user. By downloading a different FW start-up of the device this HW platform can service as a global digital radio receiver for the whole world, supporting DAB+, HD-Radio and the DRM standards. This demo can also demonstrate that the internet/IP (which is making its way into more and more cars these days) can also be used as an alternative to broadcast radio. By aligning the two streams (IP-FM), the radio can seamlessly switch between IP and FM to create a continuous audio stream for the listener, especially in the car where radio reception condition change every second     Demo / product features Digital radio and processing system-on-chip (SAF360x) Car radio Digital Signal Processor (SAF775x)   NXP Recommends Multi Standard Digital Radio features and benefits Software defined radio Technology   Links  Software-Defined Radio: One Global Platform for Car Entertainment     A06

Demo Low-cost evaluation board running a PMSM motor Products Links S32K144 Evaluation Board https://www.nxp.com/design/development-boards/automotive-development-platforms/s32k-mcu-platforms/s32k144-evaluation-board:S32K144EVB?&fsrch=1&sr=1&pageNum=1 Low-Cost Motor Control Solution for DEVKIT Platform https://www.nxp.com/design/development-boards/automotive-development-platforms/hardware-tools-accessories/low-cost-motor-control-solution-for-devkit-platform:DEVKIT-MOTORGD?&fsrch=1&sr=1&pageNum=1 FreeMASTER Run-Time Debugging Tool FreeMASTER Run-Time Debugging Tool | NXP  Model-Based Design Toolbox https://www.nxp.com/design/automotive-software-and-tools/model-based-design-toolbox:MC_TOOLBOX?&&&code=MC_TOOLBOX&nodeId=0152109D3F12B8F6F8 Model-Based Design Toolbox for S32K14x Automotive MCU rev2.0  Model-Based Design Toolbox For Panther (MPC574xP) Family of Processors 2.0  Learning Model-Based Design Toolbox Motor Control Example Motor Control Class: Motor Control System Motor Control Class with Model-Based Design

See the capabilities of our latest dual core, ARM-based instrument cluster solution, showing a high-end cluster with premium quality graphics on a WVGA TFT display.     Features Dual core, ARM-based instrument cluster solution, showing a high-end cluster with premium quality graphics on a WVGA TFT display. 32 bit MCU controlling Instrument clusters with GPU, 2D graphics processing unit (with raster and vector operations) Links MAC57D5xx: Automotive DIS MCUs for Instrument Clusters Block Diagram  

Demo Neural network classification method based on SqueezeNet. Images are captured by the camera processed and classified by the S32V processor and then displayed on the TV monitor with a confidence percentage calculated for each object visualized. Based on SqueezeNet, 501x fewer parameters than AlexNet Low power consumption - Less than 10 watts total Average top 1 accuracy of 58% and top 5 accuracies of 92% CNN built with APEX-DNN library Product Link S32V Vision and Sensor Fusion Evaluation Board https://www.nxp.com/design/development-boards/automotive-development-platforms/s32v-mpu-platforms/s32v-vision-and-sensor-fusion-evaluation-board:SBC-S32V234  S32V234 S32V234 Vision Processor | NXP 

Complete NXP solution for Airbag systems including System Basis Chip, squib drivers, sensors, and MCUs.      Features System created by NXP as a reference design Speed time to market solution of airbag system Reduce design risk and low BOM material cost Complete turnkey solution Product Link Airbag Evaluation Platform (PSI5) Airbag Evaluation Platform (PSI5) | NXP  Links Software and hardware documentation Block Diagram  

本文为如下G2版本的升级篇，使用G3+更新的软件 目录 1    需要的软件与工具... 2 1.1  软件工具与文档... 2 1.2  开发说明... 3 2    测试软件安装编译说明... 3 2.1  安装LLCE Logger驱动... 3 2.2  编译LLCE驱动测试程序(以CAN Logger 为例) 4 2.3  Logger Demo功能说明... 5 2.4  M7 BootLoader ATF镜像冲突检查... 7 2.5  LLCE Logger Demo去掉CLOCK INIT. 9 2.6  LLCE Logger Demo去掉MCU 相关INIT. 10 2.7  LLCE Logger Demo程序去掉PORT INIT. 10 2.8  中断冲突说明... 10 2.9  去掉其它无用初始化... 11 3    Bootloader工程说明... 11 3.1  关掉XRDC支持... 12 3.2  关掉eMMC/SD支持(可选) 13 3.3  关掉secure boot(可选) 14 3.4  增加LLCE 驱动所需要的PORT 的初始化... 15 3.5  解决Bootloader,MCAL 与Linux 的clock 冲突... 16 3.6  配置A53 Boot sources: 34 3.7  配置M7 Boot sources: 36 3.8  关闭调试软断点... 37 3.9  编译Bootloader工程... 38 3.10 制造Bootloader的带IVT的镜像... 39 3.11 烧写镜像... 41 4    Linux LLCE logger功能修改... 42 4.1 ATF的修改... 42 4.2 Linux中关于LLCE配置... 44 4.3 LLCE相关初始化冲突说明... 45 5    测试... 46 5.1  硬件连接... 46 5.2  LLCE logger 测试过程... 46 S32G Boot customization doc how to run bootloader to run mcal&linux https://community.nxp.com/t5/NXP-Designs-Knowledge-Base/S32G-Bootloader-Customzition/ta-p/1519838

this doc explain the HSE crypto driver and how to develop new feature 目录 1 参考资料 .................................................................... 2 1.1 参考资料 ................................................................. 2 1.2 版本匹配说明 .......................................................... 3 2 HSE FW服务 ............................................................. 3 2.1 服务描述符 ............................................................. 3 2.2 服务编号 ................................................................. 4 2.3 服务请求和响应 ...................................................... 6 2.4 服务执行 ................................................................. 9 2.5 Crypto驱动AES示例使用到的服务 ........................ 18 3 环境搭建 .................................................................. 19 3.1 安装与编译 ........................................................... 19 3.2 运行Demo ............................................................ 21 4 Crypto驱动代码与功能说明 ...................................... 23 5 定制1：增加GetAttribute功能 .................................. 28 6 CmacCtr Demo简介 ................................................. 31 7 SymmetricPrimitive Demo简介 ................................ 32 8 总结 ......................................................................... 34 9 其它注意事项 ........................................................... 34