Demo Kinetis V series enables our customer to get to market quickly using a selection of software and hardware that are targeted at their specific application needs. This electric powered vehicle was developed in a matter of weeks to showcase the model based design tools from Mathworks (MATLAB) and the Motor Control Toolbox from NXP that enables model to code based design rapidly reducing time to market       Features The vehicle has been build using Kinetis V MCUs and FRDM solution hardware to power the vehicle. The software was developed using NXP’s BLDC Reference Design Solution featuring NXPs Embedded Motor Control Libraries. Kinetis V enables customers with little motor control experience or a short time to market with Kinetis Motor Suite. For customer with more focus on model based design Kinetis V enables you with our rMotor Control Development Platform also incorporating NXPs Embedded Software Libraries, or for customers looking for a lower cost, rapid development solution we provide Kinetis Motor Suite. Product Link Kinetis® V Series https://www.nxp.com/products/processors-and-microcontrollers/arm-microcontrollers/general-purpose-mcus/kv-series-cortex-m4-m0-plus-m7:KINETIS_V_SERIES?&cof=0&am=0 Freedom Development Platform for Kinetis® KV1x Family 128 KB, 64 KB, 32 KB and 16 KB Flash MCUs FRDM-KV11Z|Freedom Development Platform|Kinetis MCU | NXP  NXP® Freedom Development Platform for Low-Voltage, 3-Phase PMSM Motor Control FRDM-MC-LVPMSM|Freedom Development Platform | NXP  Low-Voltage, 3-Phase Motor Kit for FRDM platform FRDM-MC-LVMTR|Freedom Development Platform | NXP  High-Voltage Development Platform https://www.nxp.com/products/processors-and-microcontrollers/arm-microcontrollers/general-purpose-mcus/kv-series-cortex-m4-m0-plus-m7/high-voltage-development-platform:HVP-MC3PH?&fsrch=1&sr=1&pageNum=1 Low-Voltage, 3-Phase Motor Control Tower® System Module https://www.nxp.com/design/development-boards/tower-development-boards/peripheral-modules/low-voltage-3-phase-motor-control-tower-system-module:TWR-MC-LV3PH?&lang_cd=en ____________________________________________________________________________________________________________________ Software: Kinetis Designs|NXP ARM Cortex-M0+/M4/M7 Cores|Kinetis V MCUs|NXP 3-Phase AC Induction Motor Control Design|NXP 3-Phase PMSM Motor Control Reference Design|NXP 3-Phase Brushless DC Motor Control Design|NXP ____________________________________________________________________________________________________________________  

Demo This demo shows the abilities of the T4240 processor in Object and NAS storage applications.  Multiple 10G Ethernet ports provides leading edge storage area networking connectivity while the low power and inherent reliability of the T4240 provide a secure and significant cost and performance advantage Vs. competitive solutions.     Features Dual SAS or SSD controllers with up to 24 drives Dual QorIQ T4240 processors with high-performance failover/synchronization path Dual redundant power supplies Featured NXP Products QorIQ T Series T4240/T4160/T4080 24/16/8

For further information visit the complete guide on our NXP Designs: https://community.nxp.com/docs/DOC-344585 

Cellular Freedom Quickly move sensor data to the cloud using the FRDM-K64F End-Device certified Skywire cellular modems provide a path to production Complete mbed code provided This Demo Is Probably of Interest If You: Need a quick proof of concept Have to demonstrate cellular connectivity to a customer or client Don’t want to build your own Thing for your IoT demo Differentiation - This Demo Highlights End-Device certified modems require no Carrier certifications to use on the cellular network XBee R footprint makes your design futureproof Global options for devices deployed or moved anywhere in the world Description The NXP FRDM-K64F is the development board for the NXP Kinetis series, providing an affordable, flexible way to build prototypes. For applications requiring cellular connectivity, the NimbeLink Sensor Shield plugs into the FRDM-K64F development board and, in turn, accepts a plug-in NimbeLink Skywire end-device certified cellular modem, providing quick cellular access. This first-in-the-industry plug-in cellular solution is easier and more compact than USB or other modem connection options, and the pre-certified Skywire embedded modem eliminates the cost and complexity of obtaining carrier certifications. The NimbeLink shield comes with four integrated MEMS sensors for easy proof-of-concept development. Sensors include an accelerometer, a temperature sensor, an atmospheric pressure sensor, light sensor, a humidity sensor, an accelerometer and two pushbutton switches. The shield also provides headers similar to those on an Arduino board. These accept any of hundreds of compatible expansion boards allowing the addition of capabilities like GPS, screens, motor controllers, and more. The NimbeLink Sensor Shield requires 5-12vdc power and accepts a variety of antennas. Full Listing of Products/Components Note: For full listing or additional information for Products/Components used in this demo see "This Demo's IoT Highlights" in Left Column. Note: If you aren't looking at this demo in the IoT Solutions Center, please use below link to access NXP IoT Solutions Center: https://community.freescale.com/community/iot-center/demos/skywire-m2mmanager-demo What this Demo is All About Video Link : 4994 IoT Physical Components Gateways Boards/Modules: FRDM-K64F Software: ARM mbed End User Products: NimbeLink Sensor Shield and Skywire Modem Wireless Connectivity End-Device certified Skywire cellular modem Sensors MEMS accelerometer, temperature, humidity and pressure sensors. Light sensor, potentiometer and pushbutton switches. Cloud Infrastructure/Services Verizon ThingSpace IoT System Capabilities Cloud/App Communications/Interworking See the data from your Sensor Shield in the cloud using the Verizon ThingSpace portal on any connected device. IoT Development Capabilities Embedded Platforms NimbeLink can help you customize your cellular product design to take advantage of the latest NXP advances in technology. IoT Product Type Product/Component Vendor Research or Procure This Product/Component End User Hardware Skywire Sensor Shield Commercial Skywire Sensor Shield End User Hardware Skywire end-device certified cellular modem Commercial Skywire Modem

LS104x DPAA Support PCD in Linux Kernel Products Product Category NXP Part Number URL MPU LS1043A https://www.nxp.com/products/processors-and-microcontrollers/arm-processors/layerscape-communication-process/qoriq-layerscape-1043a-and-1023a-multicore-communications-processors:LS1043A MPU LS1046A https://www.nxp.com/products/processors-and-microcontrollers/arm-processors/layerscape-communication-process/qoriq-layerscape-1046a-and-1026a-multicore-communications-processors:LS1046A LSDK Software Layerscape Software Development Kit https://www.nxp.com/design/software/embedded-software/linux-software-and-development-tools/layerscape-software-development-kit:LAYERSCAPE-SDK Tools NXP Development Board URL LS1043ARDB https://www.nxp.com/design/qoriq-developer-resources/layerscape-ls1043a-reference-design-board:LS1043A-RDB LS1046ARDB https://www.nxp.com/design/qoriq-developer-resources/layerscape-ls1046a-reference-design-board:LS1046A-RDB

Overview This reference design exhibits the suitability and advantages of the NXP® 56F80x and 56F83XX Digital Signal Controllers (DSCs) for torque control applications using a 3-phase PMSM motor with an encoder position sensor. It can also be adapted to 56F81XX Digital Signal Controllers PM synchronous motors are popular in a wide application area The PM synchronous motor lacks a commutator and is, therefore, more reliable than the DC motor The PM synchronous motor also has advantages when compared to an AC induction motor Features Targeted 56F80X, 56F83XX, and 56F81XX Digital Signal Controllers Torque producing current component closed loop Vector current control with position feedback Encoder position feedback Overvoltage, undervoltage and overcurrent fault protection FreeMASTER display interface Manual interface Block Diagram Board

this doc explain how to support high baudrate, such as 3M, 4M in S32G Mcore, even MCAL currently just support 1.8M. and to change uart clock source to avoid the wrongbaudrate value. and after that, still need modify the linux clock tree. 目录 1    背景与资料说明... 2 1.1  背景说明... 2 1.2  所需资料说明... 3 2    S32G波特率设置说明... 4 3    创建UART工程... 7 3.1  打开工程... 7 3.2  修改波特率... 7 3.3  编译与运行... 7 3.4  默认工程说明... 8 4    配置UART更高波特率... 9 4.1  以PERIPH_PLL_PHI3_CLK 100Mhz为LIN_CLK时钟源    9 4.2  以FIRC_CLK 48Mhz为LIN_CLK时钟源... 14 5    Linux的修改... 15 5.1  以PERIPH_PLL_PHI3_CLK 100Mhz为LIN_CLK时钟源    15 5.2  以FIRC_CLK 48Mhz为LIN_CLK时钟源... 19

本文说明在S32G上如何只用QSPI Nor启动一个最小Linux，最主要的作用是：Linux的紧急/升级/测试模式，或快速启动 目录 1    背景与资料说明... 2 1.1  背景说明... 2 1.2  所需资料说明... 2 2    S32G QSPI Nor镜像布局说明... 3 2.1  S32G Linux BSP对QSPI Nor启动的支持情况... 3 2.2  S32G  Yocto fsl-image-flash机制分析... 5 2.3  S32G QSPI Nor启动的镜像布局和修改目标... 7 3    镜像修改与编译... 8 3.1  镜像修改... 8 3.2  Yocto编译方法... 10 3.3  Standalong编译方法... 11 4    如何缩小Linux内核镜像... 12 5    如何制造最小Rootfs. 12 5.1  基于现有rootfs直接缩小... 12 5.2  其它方法... 14 6    测试... 14 6.1  烧写办法... 14 6.2  运行log. 16 7    如何在Rootfs加入应用... 17 7.1  Yocto环境中加入方法... 17 7.2  其它方法... 17 7.3  测试结果... 17 8    附件... 17