About the demo components For this demo, we are using the Sigfox kit, which includes the FRDM-KL43Z and the OM2385 board. Sigfox is an inexpensive, reliable, low-power solution to connect sensors and devices.  With our dedicated radio-based network, we are committed to giving a voice to the physical world and making the Internet of Things truly happen.  The Sigfox protocol focuses on:  Autonomy. Extremely low energy consumption allows years of battery life. Simplicity. No configuration, connection request or signaling. Your device is up and running within minutes! Cost efficiency. From the hardware used in the devices on our network, we optimized every step to be as cost-effective as possible. Small messages. there are no large assets or media allowed on the network.  Only small notifications up to 12 bytes are allowed. Complementarity. Thanks to its low cost and ease of configuration, you can also use Sigfox as a secondary solution to any other type of network, e.g.: Wi-Fi, Bluetooth, GPRS, etc. You can read more about Sigfox in What is Sigfox? | Sigfox build.     The OM2385/SF001 is a development platform dedicated to SIGFOX Wide Area Networking applications. It includes an OL2385 wireless sub-GHz transceiver running the preprogrammed SIGFOX library and is mounted on an FRDM-KL43Z development platform that serves as a host processor for the user's application. The FRDM-KL43Z is an ultra-low-cost development platform for Kinetis L families KL43, KL33, KL27, KL17, and KL13 MCUs built on Arm Cortex-M0+ processor running at 48 MHz.   Video     Limitations: Sigfox is only able to send a small amount of data every day for free, so if your application requires more data to be sent, you need to get a connectivity plan from Sigfox Buy .   Useful Links FRDM-KL43Z and NXP Sigfox OL2385 Board : OM2385/SF001 - SIGFOX Development Kit | NXP  Sigfox Backend Account: Sigfox Buy  Download MCUXpresso: MCUXpresso IDE|Eclipse-based Integrated Development Environment (IDE) | NXP  Download SDK: https://mcuxpresso.nxp.com/en/builder    NXP Product Link FRDM-KL43Z and NXP Sigfox OL2385 Board OM2385/SF001 - SIGFOX Development Kit | NXP  Sigfox Backend Account Sigfox Buy  Download MCUXpresso MCUXpresso IDE|Eclipse-based Integrated Development Environment (IDE) | NXP  Download SDK https://mcuxpresso.nxp.com/en/builder    Required Items:     OL2385 Arduino Shield Board FRDM-KL43Z hardware USB A-to-MiniB cable Sub-GHz Antenna GPS UART module   Hardware Diagram:    SPI OL2585 KL43Z FRDM UART GPS MOSI ---------- MISO ---------- SCK ----------- ACK ----------- CS ------------- PTD07 PTD06 PTD05 PTD02 PTD04 PTE23 PTE22           ----------- TX ----------- RX         This picture shows the board connections made for the project     Step-by-Step Guide After we get the Required items, we need to activate the Sigfox account and register our board: Sigfox Buy  If you are having trouble registering your Sigfox device, don't hesitate to write your question in our NXP community. We register the board in our backend account, and we should see the device on our device list. When we have our board registered, we will start building the application on MCUXpresso. Download the project attached at the end of this document and import it into MCUXpresso IDE.  In the video, how to import the sigfox_console example from the SDK is shown, and a brief explanation of the modifications is given. If you want to download the SDK example to start your project from scratch, you need to add the Sigfox software component to the SDK. After importing the project to our workspace, the only thing left is to make the respective hardware connections and flash the device. Then try your new project in a building-clear area. To be sure your new project will function properly, you should avoid tall buildings to get a stronger signal. The data sent should be seen in your Sigfox backend session. Teraterm console prints the data obtained from the GPS module for your viewing purposes.   Results:       This is the data sent from the Sigfox transceiver to the user backend account. The sent frames are floating-point coordinates converted to four byte-hexadecimal strings.     After the attached project is flashed to the KL43Z, this should be the results seen in the Teraterm console.

Demo Ricardo Anguiano describes a memory game demo built by Mentor Graphics for their Embedded Systems Division's 20th Anniversary. The game uses 36 FRDM-K64F boards with Adafruit 2.8" capacitive touchscreens in a 6 x 6 grid. The FRDM-K64F boards run the Nucleus RTOS from Mentor Graphics. The FRDM-K64F boards are connected over Ethernet to a touchscreen-driven Boundary Devices BD-SL-i.MX6 (formerly the SABRE Lite board) game controller which also runs the Nucleus RTOS. Players start the game by viewing and studying the position of all 36 digital cards, the cards are flipped and the player must touch matching pairs for points before time expires. The memory game generated lots of interest with players coming back multiple times. It was a great way to introduce the ARM TechCon crowd to the Nucleus RTOS, which enjoys wide success in a number of vertical markets and product categories like industrial, medical, IoT, wearables and automotive. The safety-certified version, Nucleus SafetyCert has been verified and documented to meet the certification requirements for device manufacturers developing safety related software for avionics requiring DO-178C Level A, industrial requiring IEC 61508 SIL 3, medical requiring IEC 62304 Class C, and automotive requiring ISO 26262 ASIL B. Features • A fun memory game built on Mentor Graphics' Nucleus RTOS, deployed on over 3 billion devices worldwide. • NXP FRDM-K64F and i.MX6 based hardware NXP products ARM Cortex-M4|Kinetis K64 120 MHz 32-bit MCUs i.MX6Q|i.MX 6Quad Processors|Quad Core Tools FRDM-K64F|Freedom Development Platform|Kinetis MCUs https://boundarydevices.com/product/sabre-lite-imx6-sbc/  Mentor Graphics Links https://www.mentor.com/embedded-software/nucleus/ https://www.mentor.com/embedded-software/nucleus/safety https://blogs.mentor.com/embedded/blog/2016/10/31/testing-your-memory-at-arm-techcon/ 

  Overview The USB Type-C allows multi-function signaling over the same connector. Our active cable application supports the connectivity of data, video, security, and power over a single connector. The active cables system for Type-C supports up to 10 Gbps. The MCU provides fundamental signal processing and management duties. It communicates with both the signal conditioner and USB PD PHY to organize signal traffic and power flow. Interactive Block Diagram Recommended Products Category Products MCU Kinetis® K Series: High-Performance Microcontrollers (MCUs) based on Arm® Cortex®-M4 Core | NXP    LPC800 Series: Low-Cost Microcontrollers (MCUs) based on Arm® Cortex®-M0+ Cores | NXP  Authentication A1006 | Secure Authenticator IC: Embedded Security Platform | NXP  Signal Conditioners SuperSpeed USB 3.0 redriver | NXP    PTN36043A: USB Type-C SuperSpeed active switch | NXP  USB PD PHY PTN5100 | NXP    PTN5100D | NXP    PTN5150 | NXP    Featured Videos Link NXP USB Type C | NXP  USB Type C Shield Board | NXP  NXP® End to End Secure USB Type-C Solution | NXP  Documentation Link Features Paving The Way for USB Type-C Connectors  Delivering data, video, security, and power in one small, easy-to-insert connector, the new USB Type-C connector. PTN5110N PD PHY application programming guide  PTN5110N is a 1-port TCPC (Type-C Port controller) compliant USB Power Delivery (PD) PHY IC   Training Link USB Type-C Overview - Part 1| Introduction to USB Type-C | NXP  Authentication for USB Type-C - Part 1 | Introduction to NXP Identification & Security | NXP  NXP USB Type-C Solution - Part 1| Overview of NXP Secure Interfaces & Power Solutions | NXP    Community Links Link Other NXP Products  Secure Authentication  Introduction to USB Type-C and Type-C Solutions from NXP  USB Type-C Overview  MHW-N1910 Authentication for USB Type-C 

this doc explain the S32G PCIe HW design checkpoints and How to debug HW issue with SW. 主要包括：         1：S32G PCIe硬件设计说明。         2：如何根据硬件设计配置软件。         3：如何根据软件现象debug硬件连接问题。         4：一个连接PCIe外设的demo. 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    PCIe硬件设计说明... 2 2.1  S32G PCIe能力... 2 2.2  S32G PCIe原理图设计... 4 2.3  S32G PCIe设计说明... 8 2.4  S32G PCIe硬件bring up. 9 3    PCIe 软件说明... 9 3.1  软件配置说明... 9 3.2  PCIe uboot初始化流程... 12 3.3  PCIe Linux初始化流程... 19 4    硬件连接错误的软件表现示例... 21 4.1  时钟配置错误... 21 4.2  硬件连接错误... 23 5    RDB3连接PCIe设置Demo. 25 5.1  硬件说明... 25 5.2  Uboot配置... 26 5.3  内核打印... 27 5.4  内核sys文件夹... 36  

Demo Owner: Nicholas Sargologos Demonstration of the IoTgateway reference design based on QorIQ Processor LS1021A multicore - utilizing the Freedom board, the Node Red network configuration tool and IBM Cloud Services   Features Multi-protocol support for IoT devices and high speed WAN / LAN for cloud connectivity The demo supports two data flows using Open source MQTT messaging protocol. There are two nodes powered by Kinetis micro-controllers and IoT Gateway. Node 1 is equipped with a sensor cluster serves as a publisher Node 2 is connected to as small fan and serves as a subscriber MQTT flows are carried from the nodes and the Iot gateway via Wi-Fi Java based environment is used to establish connectivity between nodes   Featured NXP Products LS1021A Links Product Link LS1021A-IoT Gateway Reference Design LS1021A-IoT Gateway Reference Design | NXP  Freedom Development Platform for Kinetis® KL14, KL15, KL24, KL25 MCUs FRDM-KL25Z|Freedom Development Platform|Kinetis® MCU | NXP  Block Diagram   News Buzz IoT designs need to start in the right direction - Embedded Computing Design

Demo i.MX RT1050 from NXP showing three different Storyboard Suite demo applications; Washing Machine, Home Automation and Medical demos. Based on the Arm ®  Cortex ® -M7, the i.MX RT series bridges the gap between the performance of applications processors and the usability of MCUs, without compromising low-power or low cost. Video Overview (Click here) NXP Products Product Link i.MX RT1050 Evaluation Kit i.MX RT1050 Evaluation Kit | NXP  4.3" LCD Panel 4.3" LCD Panel RK043FN02H-CT | NXP 

Video   NXP’s Touch Sense Interface (TSI) offers a complete solution to help easily integrate this growing ‘touch’ requirement on your next design. NXP’s touch software, offered as a middleware as part of the MCUXpresso SDK, is optimized to work with the Kinetis KE15Z MCU to deliver an easy-to-implement solution. Product features Advanced EMC robustness, pass IEC61000-4-6 standard test Support both of Self-cap sensor and Mutual-cap sensor, up to 36 touch keys Low BOM cost per touch key, no need for external devices Adjustable touch sensing resolution and sensitivity, high performance for waterproof Low power support NXP recommends the following links for additional information Product Link NXP Touch Solution for Kinetis KE15Z MCU Family NXP Touch-Based User Interface Solutions for Kinetis KE15Z MCU Family | NXP  Touch Module for Freedom Board FRDM-TOUCH|Touch Module for Freedom Board | NXP  Freedom Development Platform for Kinetis® KE1xMCUs FRDM-KE15Z Platform|Freedom Development Board | NXP 

KW36-创建保留存储器内容的OTAP镜像 简介 当OTAP客户端（接收软件更新的设备，通常为Bluetooth LEPeripheral）从OTAP服务器（发送软件更新的设备，通常为Bluetooth LE Central）请求软件更新时，用户可能希望保留以前获取的一些数据，例如绑定信息，系统振荡器的调整值或者应用程序的NVM数据。 本文档将介绍在执行OTAP更新时，保留需要的指定数据内容。 本文档适用于熟悉OTAP自定义Bluetooth LE服务的开发人员。相关更多信息，可以阅读以下文章：使用OTAP客户端软件对KW36设备进行重新编程。 OTAP Header和子元素 OTAP协议为软件更新实现了一种数据格式，该格式由Header和指定数量的子元素组成。 OTAP Header描述了关于软件更新的普通信息，其格式定义如下图所示。 有关Header字段的更多信息，请转至SDK中的<SDK_2.2.X_FRDM-KW36_Download_Path> \ docs \ wireless \ Bluetooth中的《 Bluetooth Low Energy Application Developer's Guide》文档的11.4.1 Bluetooth Low Energy OTAP Header一章。   每个子元素都包含用于特定目的的信息。 用户可以为其应用程序实现专有字段（有关子元素字段的更多信息，请转至SDK中的<SDK_2.2.X_FRDM-KW36_Download_Path> \ docs \ wireless \ Bluetooth中的《 Bluetooth Low Energy Application Developer's Guide》文档的11.4.1 Bluetooth Low Energy OTAP Header一章。 OTAP包含以下子元素： 镜像文件子元素 值字段长度 （字节） 描述 升级镜像 n 该子元素包含实际的二进制可执行镜像，该镜像已复制到OTAP客户端设备的闪存中。 该子元素的最大字节长度取决于目标硬件。 扇区位图 32 该子元素包含目标设备闪存的扇区位图，该位图告诉引导加载程序哪些扇区应被覆盖，哪些扇区保持完整。 该字段的格式是首先使用每个字节的最低有效位，且最低有效字节和位代表闪存的最低存储扇区。 镜像文件CRC 2 这是在镜像文件的所有元素（此字段本身除外）上计算的16位CRC。 该元素必须是通过空中发送的镜像文件中的最后一个子元素。 OTAP扇区位图子元素字段 KW36闪存分为： 一个256 KB程序闪存（P-Flash）阵列，每个扇区大小2KB，闪存地址范围为0x0000_0000至0x0003_FFFF。 一个256 KB FlexNVM阵列，每个扇区大小2KB，闪存地址范围为0x1000_0000至0x1003_FFFF，别名存储器的地址范围为0x0004_0000至0x0007_FFFF。   位图子元素的长度为256位，就KW36闪存而言，每个位代表2KB扇区，覆盖从0x0-0x0007_FFFF的地址范围（P-Flash到FlexNVM Alias地址范围），其中1表示该扇区应被擦除，0表示应保留该扇区。 OTAP引导加载程序使用位图字段来获取在使用软件更新对KW36进行编程之前应擦除的地址范围，因此必须在发送软件更新之前对其进行配置，使得包含保留数据的内存地址范围内其内容保持不变，仅擦除将被软件更新覆盖的地址范围的数据。   例如：假设开发人员想要保留0x7D800-0x7FFFF之间的地址范围和0x0-0x1FFF之间的地址范围的数据，并且必须擦除其余数据。 0x7D800-0x7FFFF之间的地址范围对应于高地址5个闪存扇区，0x0-0x1FFF之间的地址范围是低地址4个扇区。   因此，这意味着应将256和252之间的位（256、255、254、253和252）以及4和1之间的位（4、3、2和1）设置为0，则OTAP位图为 ： 0x07FFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF0 使用NXP测试工具配置OTAP位图以保护指定地址范围的数据 在恩智浦网站上下载并安装用于连接产品的测试工具   在PC上打开NXP Test Tool 12软件。 转到“ OTA更新-> OTAP蓝牙LE”，然后单击“浏览...”按钮加载用于软件更新的映像文件（NXP测试工具仅接受.bin和.srec文件）。 选择“覆盖扇区位图”复选框，配置OTAP位图，并更改默认值为新的位图值。 配置完位图后，选择“保存...”。   然后，弹出一个窗口，用于选择保存.bleota文件的目录。 填写文件名，点击保存。 在Android和iOS上，该文件可以使用IoT Toolbox中的OTAP进行软件升级。 这个新的.bleota文件所包含位图告诉OTAP引导加载程序哪些扇区将被擦除，哪些扇区将被保留。    

这篇文章通过覆盖与GFSK （通用频移键控）通信并行的 低功耗蓝牙 多节点连接，提供了混 合应用程序（ W ireless UART + GFSK Advertising ）的示例。这是 SDK 的另一个示例，其中我 们定义了 混合应用程序，用于与 GFSK 通信并行进行蓝牙 LE 广告和扫描。 Products Product Category NXP Part Number URL MCU KW36/35/34 https://www.nxp.com/products/wireless/bluetooth-low-energy/kw36-35-34-arm-cortex-m0-pluskinetis-kw36-35-34-bluetooth-low-energy-32-bit-mcus-nxp:KW36-35 MCU KW39/38/37 https://www.nxp.com/products/wireless/bluetooth-low-energy/kw39-38-37-32-bit-bluetooth-5-0-long-range-mcus-with-can-fd-and-lin-bus-options-arm-cortex-m0-plus-core:KW39-38-37   Tools NXP Development Board URL FRDM-KW36 Freedom Development Kit https://www.nxp.com/design/development-boards/freedom-development-boards/mcu-boards/frdm-kw36-freedom-development-kit-for-kinetis-kw36-35-34-mcus:FRDM-KW36 FRDM-KW38 Freedom Development Kit https://www.nxp.com/design/designs/freedom-development-kit-for-kw39-38-37-mcus:FRDM-KW38   SDK SDK Version URL MCUXpresso SDK Builder https://mcuxpresso.nxp.com/en/welcome

Demo Owner Clark Jarvis   The following demo will show a comprehensive enablement in software. Next-gen Kinetis K series MCUs, new FRDM-K64F development platform, software development kit* and Kinetis Design Studio IDE*, paired with Processor Expert software, MQX RTOS and PEG graphics studio to provide powerful and rapid prototyping. *In beta release now     Features Comprehensive, all in one development software Featured NXP Products Product Link Freedom Development Platform for Kinetis® K64, K63, and K24 MCUs FRDM-K64F Platform|Freedom Development Board|Kinetis MCUs | NXP  Supporting Hardware Dialog Auto Shield Arduino Display

Demo Industry 4.0 connectivity or Industrial IoT  combines the existing high Level network based on Ethernet type Protocols and the access  to a single sensor data.  IO Link protocol helps in that convergence by providing an easy migration of current of non-connected sensors to networked one. The demonstration show a typical Industrial Network using ModBus and IO Link sensors Features Modbus TCP Slave based on LS1021A Open source stack & Support for Industrial Strength Security Master IOLink Modem  node based on Kinetis KL17 + transceiver Device Node IOlink based on Kinetis KE02 + transceiver NXP Recommends Product Link QorIQ® Layerscape 1021A Dual-Core Communications Processor with LCD Controller https://www.nxp.com/products/processors-and-microcontrollers/arm-processors/layerscape-communication-process/qoriq-layerscape-1021a-dual-core-communications-processor-with-lcd-controller:LS1021A?&lang_cd=en Freedom® Development Platform for Kinetis® KL17 and KL27 MCUs FRDM-KL27Z|Freedom Development Platform|Kinetis® MCU | NXP  Freedom Development Platform for Kinetis KE02 MCUs https://www.nxp.com/design/development-boards/freedom-development-boards/mcu-boards/freedom-development-platform-for-kinetis-ke02-mcus:FRDM-KE02Z40M?&lang_cd=en QorIQ® LS1021A Tower® System Module QorIQ® LS1021A Tower® System Module | NXP 

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

Demo This demo showcases the Bluetooth Low Energy Mesh solution on Kinetis KW41Z devices, leveraging the Kinetis Bluetooth LE v4.2 stack. The audience will be able to interact with remote nodes of the mesh via a single laptop console. The remote nodes offer feedback via a RGB LED array.     Features: Bluetooth® LE Mesh software implementation over the Kinetis BLE stack v4.2 Mesh nodes made up of FRDM-KW41Z evaluation boards with Adafruit NeoPixel LED shields Interactive configuration and control of the mesh nodes with feedback on the LED arrays Sensor data sent via the Mesh to the cloud _______________________________________________________________________________________________________   Featured NXP Products: KW41ZlKinetis BLE & 802.15.4 Wireless MCU|NXP _______________________________________________________________________________________________________    

Overview This reference design describes the design of a 3-phase BLDC (Brushless DC) motor drive, which supports the NXP® 56F801X Digital Signal Controllers (DSCs). The speed-closed loop and torque control BLDC drive using a Hall sensor is implemented The system is targeted for applications in both industrial and appliance fields (e.g. washing machines, compressors, air conditioning units, pumps or simple industrial drives required high reliability and efficiency) Features Voltage control of BLDC motor using Hall sensor Targeted for 56F801X Digital Signal Controllers Running on 3-phase Motor Board Control technique incorporates: Voltage BLDC motor control with speed-closed loop Current feedback loop Manual interface DCBus undervoltage fault protection Block Diagram Board Design Resources

doc&patch explain how to decrease the qspi init clock to avoid the spi read qspi id error in linux S32G Linux BSP初始化QSPI Nor时钟是默认200Mhz，但是JEDEC规范建议读QSPI Nor ID是使用SPI模式，低速时钟，所以默认BSP是有可能读ID不成功的，本文说明如何解决这个问题。 本文采用软件版本为Linux BSP43 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    Linux QSPI Nor驱动说明... 3 2.1  QSPI Nor控制器驱动说明... 3 2.2  QSPI Nor设备驱动说明... 4 2.3  SPI Mem驱动说明... 5 3    代码修改... 6 3.1  将初始化时钟切换成133Mhz. 6 3.2  在初始化后将时钟切换回200Mhz. 7 4    测试... 7 4.1  软件测试... 7 4.2  硬件测量... 7 5    其它注意事项... 8    

Overview Heating, ventilation, and air conditioning (HVAC) systems are based on inputs from a variety of sensors, controlling different types of motors such as stepper motors for flaps and DC/BLDC blower fan motors. NXP broad portfolio of 32-bit, 16-bit S12, and 8-bit S08 families of microcontrollers enables designers to meet the needs of a variety of HVAC applications. System basis chips (SBCs) combine physical network connection with power management. Intelligent eXtreme switches complete the system solution for DC motor blowers. BLDC motor control requires more complex algorithms. NXP’s MagniV products combine MCU with SBC functionality, network connection, and motor control, specific drivers, into a single package, providing a cost-effective small footprint system solution. Interactive Block Diagrams https://www.nxp.com/video/building-automation:BUILDING-AUTOMATION-V02Recommended Products Category Products Features MCU MPC560xB|32-bit MCU|Body-Electronic | NXP  32-bit single-core Power Architecture® MCU. 32-bit Automotive General Purpose MCUs | NXP  Arm Cortex-M0+|Kinetis KEA 32-bit Automotive MCUs | NXP  System Basis Chip (SBC) MC33742 | SBC with Enhanced High-Speed CAN Transceiver | NXP  System basis chip with high-speed CAN Interface. SBC Gen2 with High-speed CAN | NXP  System basis chip with high-speed CAN Interface. MC33905 | SBC Gen2 with High-Speed CAN and LIN | NXP  System basis chip with high-speed CAN Interface. LIN SBC | NXP MC33910  System basis chip with LIN interface (Entry Level). LIN SBC | NXP MC33911 System basis chip with LIN interface (Medium Level). LIN SBC | NXP MC33912 System basis chip with LIN interface (High-end Level). CAN Interface MC33897 | Single-Wire Can Transceiver | NXP  CAN interface with protection features LIN Interface TJA1021 | LIN2.1/SAE J2602 Transceiver | NXP  LIN interface with low emission. MC33662 | LIN 2.1 / SAEJ2602-2, LIN Physical Layer | NXP  LIN 2.1 and SAEJ2602-2 interface. Switch Monitoring MC33972 | MSDI with Suppressed Wakeup | NXP  Multiple switch detection interface with sleep mode. MSDI | NXP  Multiple switch detection interface with sleep mode. Motor Control MagniV® S12ZVM Mixed-Signal MCUs | NXP  Single-chip BLDC motor control solution. MC33937 | Field Effect Transistor | NXP  Three phase field effect transistor (FET) pre-driver. MC33932 | H-Bridge Motor Driver | NXP  Dual 5.0 A throttle control H-bridge. High Side Switches MC33937 | Field Effect Transistor | NXP  Three phase field effect transistor (FET) pre-driver. MC33932 | H-Bridge Motor Driver | NXP  Dual 5.0 A throttle control H-bridge. Tools and Software Link Features Development Kit for sensorless BLDC | NXP  Based on the 32-bit Arm Cortex-M4F S32K144, the MTRDEVKSBNK144 is a development kit engineered for sensorless applications requiring one Brushless Direct Current (BLDC).

This demo shows a demonstration of NXP's wireless charging reference design for a tablet computer.       Features Consumer and Automotive Applications Compliance with wireless power consortium QI standard Transfer efficiency Touch sensing Featured NXP Products WCT1000 Links Link to Wireless Charging Links to document page Block Diagram  

Overview   NXP has a proud heritage of supplying solutions for automotive and aerospace applications. Many of these solutions also apply to the rapidly evolving field of mobile robotics. Whether your system operates on the ground, under the sea or in the sky, NXP offers a complete portfolio of sensors, controllers and communications solutions. NXP® processing solutions for transportation systems communication scale from MCUs to multicore MPUs. The transponder is designed to provide high performance and great reliability. Its user-friendly interface enables an intuitive handling of complex features AIS class A delivers. This solution will cover a wide range of uses for vehicular, marine and flight applications. This solution is based on i.MX RT technology. Use Cases Solutions for connecting functional modules within a vehicle or transportation system and connecting them to external networks. Some applications for this could be: Service-Oriented gateways Transponders V2X Communication Ethernet Chassis Switch Block Diagram Products Category MCU Product URL 1 i.MX RT1050 Crossover MCU with Arm® Cortex®-M7 core  Product Description 1 The i.MX RT1050 is the industry's first crossover MCU and combines the high-performance and high level of integration on an applications processors with the ease of use and real-time functionality of a microcontroller. Product URL 2 K22_120: Kinetis® K22-120 MHz, Cost Effective, Full-Speed USB Microcontrollers (MCUs) based on Arm® Cortex®-M4 Core  Product Description 2 Kinetis® K22 MCUs have been optimized for cost-sensitive applications requiring low power flexibility and processing efficiency.   Category Ethernet PHY Product URL TJA1101: 2nd generation Ethernet PHY Transceivers - IEEE 100BASE-T1 compliant  Product Description TJA1101 is a high-performance single port, IEEE 100BASE-T1 compliant Ethernet PHY Transceiver.

The demo from FirstView Consultants is a wearable medical EKG alert with Wi-Fi connection to enable Cloud reporting and diagnosis. The demo consists of an SCM-i.MX 6SoloX V-Link device (i.MX6SoloX/PF0100/512MB LPDDR2) + Firstview V-Link Top board with 802.11 b/g/n, Bluetooth     SCM V-Link technology is ideal for handheld/space-constrained applications allowing customers to integrate vertically.   Features: AFIB detection with diagnosis and report to Cloud via Wi-Fi. Top board contains: Wi-Fi/BT module (802.11 b/g/n), NXP 6-axis sensor and SPI NOR Flash 1 GB. Base SCM device: 15.5x15.5mm. ____________________________________________________________________________________________________ Featured NXP Products: Single Chip System Modules (SCM)|NXP Partner Firstview Consultants NXP FXOS8700CQ 6-axis Sensor

Demo NXP’s Smart Defrost Solution is the newest way to defrost food. From frozen solid to sliceable food in minutes. Our solution uses RF and a smart tuning unit to evenly defrost food. The NXP Smart Defrost reference design consists of the following:    Defrost Appliance Concept                              Smart Defrost Reference Design Block Diagram Reference Design Features • RF creates the energy used to raise food temperature • Smart Tuning Unit intelligently adjusts operation for properties of the food within the defrost chamber • Electrodes provide the delivery of energy into the defrost cavity • Defrost cavity is a shielded, enclosed space for defrosting frozen food • Host control for main appliance control and user input interface Benefits • Reduced time-to-market • Simple integration into system • Predictable repeatable results • Creates even defrost environment • Reliable • Cost-effective interconnection • Minimum software needed for control Links https://www.nxp.com/pages/defrosting:RF-DEFROSTING-PG   Fact Sheets https://www.nxp.com/docs/en/fact-sheet/SmartDefrostRDFS.pdf  https://www.nxp.com/docs/en/fact-sheet/SDS31300FS.pdf