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

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  

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

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 _______________________________________________________________________________________________________

功能需求 RT117X系列MCU在汽车和工业类产品中有广泛应用，有很多客户对LIN通讯有需求，RT1176有12路独立的LPUART接口，最大支持的波特率能支持到20M，而且每一路都支持Break发送和中断接收，可以用来配合定时器实现LIN的主机和从机通讯。但是目前RT117X的EVK板没有放置LIN的收发器，SDK也没有相关LIN的示例代码和LIN协议栈支持，所以本示例目的是移植KW36工程中的LIN 2.1版本的代码到RT1176 EVK板子上，在硬件上通过跳线将LIN Master主节点和 Slave从节点的LPUART TX/RX线连接到FRDM-KW36板载的LIN收发器TJA1027上，分别实现LIN 2.1版本协议栈在Master和Slave节点的通讯功能验证，同时还需支持Auto Baud Rate自动波特率调整。为客户做二次开发或者移植用户自己的LINstack提供底层驱动，提高开发效率。 代码包软件   RT1176 LIN Master节点代码：RT1170_LIN_Porting_Demo_Master.7z RT1176 LIN Slave节点代码(支持自动波特率😞 RT1170_LIN_Porting_Demo_Slave_with_Auto_Baud_Rate.7z 配置FRDM-KW36板载LIN 收发器的代码: KW36_LIN_PHY_Board_Init.7z 硬件Setup   MIMXRT1170-EVK： 2pcs，分别用作LIN Master节点和Slave节点。 FRDM-KW36：2pcs， 分别用作Master节点的收发器，和 Slave节点的收发器 下图是系统连接，2块RT1170 EVK板分别和2块FRDM-KW36板通过Arduino接口连接在一起，然后将两块KW36之间的LIN收发器通过 J13 连接在一起，需要使用外部12V adapter为FRDM-KW36供电，否则板上的LIN收发器无法工作。特别强调的是，如果需要使能自动波特率检测的话，还需要将Slave节点RT1176 Arduino接口的J9-Pin2引脚连接到RT1176 Arduino接口的J9-Pin12引脚，作为Timer 脉冲捕捉的输入，即可完成系统硬件的setup。   软件Setup：   在以上硬件连接完成后，按照如下步骤下载对应软件： - Step1: 下载KW36_LIN_PHY_Board_Init.7z代码到两块FRDM-KW36板子上；  该代码中主要实现两个功能：第1个拉高板子的PTC5引脚，唤醒LIN收发器TJA1027。第2个将PTA18引脚配置成disable高阻状态。如果该引脚作为GPIO输出或者LPUART TX功能，会导致LIN slave回应数据出错(bit位丢失或者错误)。究其原因猜测应该是短路导致，当这个引脚作为GPIO输出或者LPUART TX功能，内部会有上拉，当RX1176 TX引脚输出Low时，由于电路上没有串联电阻(板子上使用的0Ω)，会导致引脚上出现大电流。尤其是第2个点，花费了很多时间去查这个问题，从波形去看，是有数据输出的，但只是数据不对，很具有迷惑性。当然如果客户是自己打的板子，板子上已经有LIN收发器就不需要这一步，直接跳到Step2即可。 - Step2: 下载RT1170_LIN_Porting_Demo_Master.7z代码到作为Master节点的IMRT1176-EVK板； - Step3: 下载RT1170_LIN_Porting_Demo_Slave_with_Auto_Baud_Rate.7z代码到作为Slave节点的IMRT1176-EVK板，如果需要使能自动波特率调整，需要配置宏linUserConfigSlave.autobaudEnable = true; 代码中默认是打开的。 实验结果   打开两个IMRT1176-EVK板串口，波特率配置115200，单击RT1176 Master节点上的按键SW7，便可以启动Master节点开始发送数据，通讯波形和串口打印信息如下两张图所示。   代码移植的几个难点   1. LIN通讯协议栈的调度流程的理解，包括Wakeup段，Break段，Sync段，PID段，Data段的状态切换和跳转，每个段的超时监测和错误处理，其核心思想有两个：一个在于LIN的RX引脚要不断去monitor TX引脚的状态，然后去切换状态机，具体调度的流程在后文会详细介绍，这里不展开。第二个是准确获取在每个段的定时器时间，尤其是超时超过一个overflow周期的情况，需要对timerGetTimeIntervalCallback0函数有理解。 2. 自动波特率调整功能的支持，该功能的原理是测量SYNC段的8个脉冲的脉宽，如果每个脉宽差异在2%范围内，再根据脉冲宽度去判断对应的波特率。在原来KW36的代码中是使用TPM的Overflow中断来作为计时，Edge中断来触发，而RT1176没有TPM，只能使用Qtimer (Qtimer功能上要更强于TPM)，但是不巧的是Qtimer不支持Overflow中断(参见芯片ERRATA 050194)，所以只能使用compare中断来实现类似的功能，而原有的计时定时计算都是基于overflow的，因此就需要对定时器部分的代码做大范围的更改。 应用中考虑到timerGetTimeIntervalCallback0函数在自动波特率调整时和超时监测处理时的一致性，最好使用同一个Timer的同一个channel，这就需要这个Timer既支持普通的定时中断模式，又支持input capture功能。对于TPM来说，是无法实现的因为两次在寄存器配置上时互斥的, 参见下图。幸运的是Qtimer支持这个feature，只是需要根据SDK代码做些配置 前面提到，需要QTimer支持input capture功能, 触发信号是LPUART_RX引脚的信号，需要硬件loop到Qtimer支持的硬件引脚上，对于KW36来说，只需要把这两个物理引脚连接在一起即可，但对RT1176来说, 只有这一步还不行，还需要对XBAR进行配置，将Qtimer的TIMER 1的触发引脚(合计有4个物理引脚)Link到QTIMER对应的Channel上，因为RT1176有4个QTimer，每个Qtimer有4个通道，标称的Qtimer trigger pin有4个，那具体哪个pin触发哪个QTimer的哪个通道，是需要配置的。如果客户没有使用过XBAR配置起来有难度，还好MCUXpresso config tool支持配置，可以简便的完成配置。示例代码和触发关系如下，如果实际硬件使用的物理引脚有区别，需要对应修改。 RT的XBAR功能非常强大，或许可以不使用外部的物理连线，直接将Qtimer的出发引脚的信号直接在内部Loop到LPUART_RX引脚，这样就更加灵活，此处只提供一个思路，不再进一步延伸。 IOMUXC_GPR->GPR15 = ((IOMUXC_GPR->GPR15 & (~(IOMUXC_GPR_GPR15_QTIMER4_TRM1_INPUT_SEL_MASK | IOMUXC_GPR_GPR15_QTIMER4_TRM2_INPUT_SEL_MASK)))/*Mask bits to zero which are setting*/ | IOMUXC_GPR_GPR15_QTIMER4_TRM1_INPUT_SEL(0x00U) /*QTIMER4 TMR1 input select: 0x00U*/ | IOMUXC_GPR_GPR15_QTIMER4_TRM2_INPUT_SEL(0x00U) /*QTIMER4 TMR2 input select: 0x00U*/ ); 4. 在状态机切换和超时以及错误处理过程中，经常会看到两种模式Sleep模式和Idle模式，区别是什么呢？ LIN_LPUART_GoToSleepMode: 函数会关闭Break中断，RX接收中断，帧错误中断，保留RX边沿 中断; LIN_LPUART_GotoIdleState 函数会打开Break中断，RX接收中断，帧错误中断，关闭RX边沿中 断; 实际通讯波形   Master作为Subscribe角色时，发送Header，由Slave发送Respone Master作为PUBLIC角色时，同时发送Header，以及Respone 按照调度表依次发送LI0_lin_configuration_RAM数组定义的PID数据 static uint8_t LI0_lin_configuration_RAM[LI0_LIN_SIZE_OF_CFG]= {0x00, 0x30, 0x33, 0x36, 0x2D, 0x3C, 0x3D ,0xFF}; Qtimer准确读取wake up信号的脉冲宽度 Slave使能Auto baud rate后读取到的每个脉冲宽度数据 免责声明： THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS "AS IS" AND *ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED *WARRANTIES OF MERCHANTABILITY AND FITNESS FOR A PARTICULAR PURPOSE ARE DISCLAIMED.* IN NO EVENT SHALL THE COPYRIGHT HOLDER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, *INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, * BUTNOT LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, * DATA, ORPROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF * LIABILITY,WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE * OR OTHERWISE)

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

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     

This doc explain bootloader secure boot feature and how to re-develop it to support: .FW update .OTP attribute access .IVT protect: 目录 1 参考资料 .................................................................... 2 2 S32G Secure Boot说明 ............................................. 2 2.1 IVT头格式与Secure Boot相关 ................................ 3 2.2 Secure Boot流程 .................................................... 3 2.3 Secure Boot配置 .................................................... 4 2.4 Secure Boot涉及到的HSE内容 ............................... 6 3 环境搭建 .................................................................... 7 3.1 搭建编译环境 .......................................................... 7 3.2 IVT镜像制造 ........................................................... 7 3.3 镜像烧写 ................................................................. 8 3.4 Bootloader Secure Boot测试 .................................. 8 4 Bootloader Secure Boot代码与功能说明 ................... 9 4.1 EB配置说明： ........................................................ 9 4.2 EB生成代码说明： ............................................... 15 5 定制1：HSE FW update .......................................... 22 5.1 代码开发 ............................................................... 22 5.2 测试 ...................................................................... 25 6 定制2：HSE OTP Attribute设置 ............................... 26 6.1 代码开发 ............................................................... 26 6.2 模拟测试 ............................................................... 33 7 定制3：IVT签名 ....................................................... 35 7.1 代码开发 ............................................................... 35 7.2 模拟测试 ............................................................... 40 Contents 1 Reference Materials .................................................. 2 2 S32G Secure Boot ..................................................... 3 2.1 IVT header format for the Secure Boot part .......... 3 2.2 Secure Boot Flow ................................................... 3 2.3 Secure Boot Configuration ..................................... 4 2.4 HSE background of Secure Boot ........................... 6 3 Build the Project ........................................................ 7 3.1 Build the Compiling Environment ........................... 7 3.2 Create IVT Image ................................................... 7 3.3 Burning Image ........................................................ 8 3.4 Bootloader Secure Boot Testing ............................ 9 4 Bootloader Secure Boot Codes and Function Description 9 4.1 EB Configuration .................................................... 9 4.2 EB output codes ................................................... 15 5 Customization 1：HSE FW update ......................... 22 5.1 Codes development ............................................. 23 5.2 Testing ................................................................. 26 6 Customization 2：HSE OTP Attribute Setting ......... 26 6.1 Code Development .............................................. 27 6.2 Simulation test ...................................................... 34 7 Customization 3：IVT Signature ............................. 36 7.1 Codes Development ............................................. 36 7.2 Simulation Testing ................................................ 40  

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

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

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 

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 e-Cockpit Demo featuring cluster plus infotainment display. Infotainment display created using Crank Storyboard Suite. Cluster developed using CGI Studio   Cluster plus infotainment system with CAN communication Infotainment done with Crank Storyboard™ Suite; cluster done with CGI Studio Working hands-free profile with BlueZ and oFono open source libraries   Featured NXP Products i.MX6 i.MX6QP|i.MX 6QuadPlus Processors|Quad Core|NXP   Links Crank Demo - GUI / Software

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  

Radar-detected Emergency Break via V2X to following traffic. RoadLink V2X platform, Ethernet Switch & 77GHz Radar Dolphin transceiver Features enabled by NXP Disrupting the market with an RFCMOS Radar-solution: •Highly integrated, minimal-footprint •Low Power Consumption •Sophisticated Functional Safety Features •Fully invisible mounting •Attractive System Cost Recommended Products •RoadLink Chipset •RF Transceiver (TEF5x00) •Baseband IC (SAF5x00) •Security IC (SXF1700) •Dolphin 77GHz Radar Chip •Ethernet Switch Resources Website http://www.nxp.com/products/rf/millimeter-wave-solutions/radar-technology:RADAR-TECH Video https://www.youtube.com/watch?v=H5eLhER9jZ4

Demo This demonstration features an Unmanned Aerial Vehicle (UAV) using the powerful Kinetis KV46 MCU controlling four GD3000 Brushless DC pre-drivers to spin the four motors which drive the propellers.   Features KV5x 240MHz ARM Cortex-M7 MCU with high speed ADCs & timers controlling all 4 BLDC motors GD3000 BDLC motor pre-driver featuring fast switching to drive low Q MOSFETs Single MCU solution unique in the market – reduced component count and BOM cost with superior performance   Featured NXP Products KV5x|Kinetis KV5x Connected Control MCUs|NXP 3-Phase Brushless Motor Pre-Driver|NXP   Links Quadcopter Demonstrating UAV Speed Control Using Kinetis KV5x MCUs and GD3000 Motor Pre-Drivers

Demo Owner David Lopez Explore this SafeAssure solution for ASIL D applications. This highly optimized Qorivva MCU and system basis chip (SBC) solution offers independent fail-safe monitoring for power management. It also features MCU external assessment of SBC architecture and concept to fit for ISO 26262 within an optimized ecosystem.   Features Safe Assure solution to fit for ASIL D applications Highly optimized SBC + MCU solution inside a new EVM ecosystem Independent fail-safe monitoring unit for power management and MCU External assessment of SBC (System Based Chip) architecture and concept fit for ISO 26262 MC33907 independent from physical and electrical stand point. It is Monitoring MCU and Power Management Presenting different components for the safe assure program Featured NXP Products Qoriva MCU MPC5643L MC33907 MC33908 Development Hardware Used KIT33908MBEVBE: Evaluation mother board - MC33908, Safe System Basis Chip with Buck and Boost DC/DC up to 1.5 A on Vcore