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)

Overview During critical processes, an industrial diesel engine management system that includes an electric generator can supply emergency power to all vital and selected loads as desired. Today, most state-of-the-art- hospitals, manufacturing plants, telecommunications organizations, data centers, emergency facilities, large industries, and mining companies require uninterrupted power and have backup diesel engine generators that are reliable. As shown in the block diagram, NXP provides a full range of MCUs, barometric pressure sensors (BAP), and analog/mixed-signal IC drivers for improving diesel vehicle fuel economy, enhancing performance, and meeting emissions requirements in automotive applications. However, the NXP industrial diesel engine management solution is equally applicable in other industrial applications by changing the input sensors and outputs that require control. The NXP Industrial diesel engine management solution incorporates the MPC5777C Power Architecture® MCU that delivers advanced performance, timing systems, security, and functional safety capabilities. This includes a lockstep function that serves as a watchdog function to flag any problems with the MCU, support for advanced timers and ADCs, external memory, fault detection, and handling support, and the highest functional safety standards (ASIL-D) support. Together, this solution provides a reliable and high-performance solution to ensure your customers and their employees are safe. Block Diagram Recommended Products Category Link MCU MPC5777C|Engine Control MCU | NXP  Safety Power Management MC33905 | SBC Gen2 with High-Speed CAN and LIN | NXP  Physical Interface TJA1021 | LIN2.1/SAE J2602 Transceiver | NXP  Output Driver MC33800 | Engine Control Integrated Circuit | NXP  Motor Driver H-Bridge MC33931 | H-Bridge Motor Driver | NXP  MAP Sensor 20 to 105kPa, Absolute, Integrated Pressure Sensor | NXP  BAP Sensor -115 - 115kPa Gauge, Absolute Pressure Sensor | NXP  Injector Driver MC33810 | Automotive Engine Control IC | NXP  Input Signal and Sensor Interface MSDI | NXP 

  Overview Data logger senses parameters such as temperature and processes this data and sends it using UHF/Bluetooth LE. NFC + UHF/Bluetooth LE temperature logging Configuration and logged data read back via NFC Long distance real time data (temperature, total sampling points, out-of-limit points) read back via UHF Our NTAG SmartSensor portfolio offers single-chip solutions that combine NFC connectivity with autonomous sensing, data processing, and logging. These devices can be easily combined with other companion chips, such as radios or sensor solutions. NTAG SmartSensor devices are ideal for Internet of Things (IoT) products. Block Diagram Products Category Smart Sensor Product URL 1 NHS3100: NTAG® SmartSensor with Temperature Sensor and Digital IOs  Product Description 1 The NXP® NHS3100 is an IC optimized for temperature monitoring and logging. With its embedded NFC interface, internal temperature sensor and direct battery connection, it supports an effective system solution with a minimal number of external components. Product URL 2 NHS3100UCODEADK: NHS3100 - UCODE-I2C  Product Description 2 This solution is composed of two NXP ICs, the NHS3100 NTAG SmartSensor and the SL354011FHK; connected via I2C. The NHS3100 is the master of the solution, running the temperature monitor and forwarding the state of the controlled goods to the Rain RfiD (UHF) interface.   Category BLE Product URL 1 QN908x: Ultra-Low-Power Bluetooth Low Energy System on Chip Solution  Product Description QN908x is an ultra-low-power, high-performance and highly integrated Bluetooth Low Energy solution for Bluetooth® Smart applications such as sports and fitness, human interface devices, and app-enabled smart accessories.  

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 MATLAB and Motor Control Development Toolbox. The Motor Control Development Toolbox is a MATLAB plugin to enable complete motor control application simulation within the MATLAB environment, enabling Software and Processor-in-the-Loop (SIL and PIL) simulation. Kinetis V enables customers with little motor control experience or a short time to market with Kinetis Motor Suite. For customer with more application knowledge Kinetis V enables you with our reference design software incorporating NXPs Embedded Software Libraries, or for customers looking for a lower cost, rapid development solution we provide Kinetis Motor Suite ___________________________________________________________________________________________________________ Featured NXP Products: 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 ___________________________________________________________________________________________________________ C61

The purpose of this project is the control of a RGB LED panel using the FlexIO peripheral included in the Kinetis K82 microcontroller. The FlexIO peripheral offers a great advantage, unloading the CPU in the process of refreshing the LED color and brightness information, comparing with other control methods using GPIO bit-banging or PWM + DMA. I will use different method. The panel will use LED stripes with the WS2812B controller. We will also have a simulation platform for developing the applications. Hardware: 30 x16 LED WS2812B Panel Multiplexer board FRDM-K82 Uctronics QVGA display Software: IAR Workbench 7.50.1 SDK 1.3 for the Kinetis K82 FreeRTOS eGUI graphic library You can watch the video with the LED panel working: Video Link : 4707 Part 1: Building the LED Panel Part 2: LED control method using the FlexIO Part 3: Software for LED Panel emulation Part 4: Software for panel control

  Overview Industrial control is a key element in any factory automation process. It may vary from a simple panel-mounted controller to large interconnected and interactive distributed control systems. PLCs are integral to industrial control; their primary function is to control individual machines or stations in real time making low deterministic latency a key factor. The functionality of the PLC include sequential relay control, motion control, process control, distributed control systems, and networking. Multiple interfaces and purpose PLC control card for the system interfaces between host system and daughter modules. Features They can be designed for many arrangements of digital and analog I/O, extended temperature ranges, immunity to electrical noise, and resistance to vibration and impact. Capable for memory extension for various system requirement Use Cases A programmable logic controller (PLC) is an industrial digital computer which has been ruggedized and adapted for the control of manufacturing processes, such as assembly lines, or robotic devices, or any activity that requires high reliability, ease of programming and process fault diagnosis. Block Diagram Products Category MCU Product URL 1 i.MX RT1060 Crossover MCU with Arm® Cortex®-M7 core  Product Description 1 The i.MX RT1060 is the latest addition to the industry's first crossover MCU series and expands the i.MX RT series to three scalable families. Product URL 2 S32K144EVB: S32K144 Evaluation Board  Product Description 2 The S32K144EVB is a low-cost evaluation and development board for general purpose automotive applications.   Category Transceiver Product URL TJA1042: High-speed CAN transceiver with standby mode  Product Description The TJA1042 high-speed CAN transceiver provides an interface between a Controller Area Network (CAN) protocol controller and the physical two-wire CAN bus.

  Overview These shelf-mounted displays can be updated wirelessly, anywhere onsite, so there’s no more need for staff to manually change price labels or print, sort, and replace labels when prices change. Prices can also be set more strategically, with gradual markdowns or in response to competitor offers. RAIN RFID coexists with other onsite technologies, including WiFi, and NFC enables innovative marketing services such as geo-location, customer identification, and targeted offers in real time.   Videos       Recommended Products   Category Name NFC PN7150 | High performance NFC controller for smart devices | NXP  PN7150 is the high-performance version of PN7120, the plug’n play NFC solution for easy integration into any OS environment, reducing Bill of Material (BOM) size and cost. NTAG I2C | NXP  The NTAG I2C plus combines a passive NFC interface with a contact I2C interface.

Demo Owner: b14714 The motor control development toolbox is a comprehensive set of tools that plug into the MATLAB™/Simulink™ model-based design environment for rapid application development on MCUs.  The SFIO Toolbox is a new addition that can control Simulink system models by SFIO algorithms running directly on NXP DSC and Kinetis MCU hardware. NXP FreeMASTER debug monitor and data visualization tool interfaces provide an interface to monitor signals in real time for data logging and signal calibration. Features The motor control development toolbox is a comprehensive set of tools that plug into the MATLAB™/Simulink™ model-based design Auto code generation straight to the Micro. NXP developed a library and embedded target to interface with MATLAB and SimuLink Customers can directly go from the model based environment to the MCU without having to write C code by hand Featured NXP Products Motor Control

Demo The demo session focuses on demonstrating the transport of human voice over the Bluetooth Smart protocol on Kinetis Wireless platforms running the Kinetis Bluetooth Low Energy stack. The intended setup is made up of two Kinetis Wireless KW41Z evaluation boards connected to an audio codec board with a headset (headphones + microphone) connected at each end. The audience can use the headsets for a full duplex voice communication experience. This demo session is aimed at showcasing the performance of the Kinetis KW41Z platform Demo Features Full duplex voice samples transport over Bluetooth LE transport using Kinetis KW41Z enabled with the Kinetis BLE v4.2 stack SGTL5000 audio codec for sample processing and Kinetis K24F for used for compression Interactive component through a pair of headsets for demonstrating the full duplex voice capabilities NXP Recommends Product Link Kinetis® KW41Z-2.4 GHz Dual Mode: Bluetooth® Low Energy and 802.15.4 Wireless Radio Microcontroller (MCU) based on Arm® Cortex®-M0+ Core https://www.nxp.com/products/wireless/thread/kinetis-kw41z-2.4-ghz-dual-mode-bluetooth-low-energy-and-802.15.4-wireless-radio-microcontroller-mcu-based-on-arm-cortex-m0-plus-core:KW41Z?&fsrch=1&sr=1&pageNum=1 Ultra-Low-Power Audio Codec https://www.nxp.com/products/audio/audio-converters/ultra-low-power-audio-codec:SGTL5000?&fsrch=1&sr=1&pageNum=1 Kinetis® K24 120 MHz MCU Tower® System Module TWR-K24F120M|Tower System Board|Kinetis® MCUs | NXP 

S32G Host Secure debug methods with Lauterbach tool after LC is updated, and some details about secure debug knowledge in S32G. 本文主要描述S32G在演进生命后如何使用lauterbach工具来进行调试，涉及到S32G HSE相关知识点。

       YAFFS是第一个在GPL协议下发布的、基于日志的、专门为NAND Flash存储器设计的、适用于大容量的存储设备的嵌入式文件系统。一般MCU系统使用YAFFS系统要求的性能及资源比较多，高性能的i.MXRT系列正好能够满足此要求。     本文基于野火i.MXRT 1052核心板及其上的NandFlash探讨Nand文件系统的原理及实现方式，并探讨了在此基础上如何建立Yaffs文件系统。 Products Product Category NXP Part Number URL MCU MIMXRT1050 https://www.nxp.com/products/processors-and-microcontrollers/arm-microcontrollers/i-mx-rt-crossover-mcus/i-mx-rt1050-crossover-mcu-with-arm-cortex-m7-core:i.MX-RT1050   Tools NXP Development Board URL 野火i.MXRT核心板/开发板 https://ebf-products.readthedocs.io/zh_CN/latest/i.mx-rt/ebf_i.mx-rt1052.html   SDK SDK Version URL Yaffs file system https://yaffs.net/ MCUXpresso SDK mcuxpresso.nxp.com  

Overview The NXP® Home Energy Manager (HEM) reference platform features an i.MX283 application processor, MC13224V ZigBee® module, 9S08QE32 MCU and MC34726 DC/DC buck. The reference platform is aimed at jumpstarting customer developments around the HAN (Home Area Network). Comprises a control board based on the low-power, yet powerful i.MX283 running connectivity interfaces to the: Smart meter Home automation system Broadband IP network User interface Micro-grid generation unit In order to accommodate a fast-paced changing connectivity landscape, the control board features extension connectors ready for: Powerline modems GPRS/3G data modem U-SNAP connectivity peripherals Mass storage cards Features Low-power Based on the latest low-power NXP ®  Arm9™ i.MX283  processor including integrated power management and supporting advanced voltage and frequency scaling techniques for optimized power consumption Running Our low-power ZigBee radio 1.5W max at full operating speed Low-cost Unique integration on the i.MX283 eliminates external components, enables 4-layer PCB Complete solution available Source code Hardware schematics Gerbers Bill of materials Complimentary software available through 3rd party partners Linux based frameworks Windows Embedded Compact 7 based framework Java-based framework Remote In-Home Display software Block Diagram Design Resources

Description Modern home appliances use electronics to provide a host of new features consumers expect. NXP MCUs and sensors keep up with the demand for constant improvements in reliability, cost, and energy efficiency. NXP helps to simplify consumers’ lives with sensor and MCU technology for home appliances. NXP technologies power the latest smart washing machine designs—from user interface, to motor control, to system management, to connectivity. Features Capacitive touch integrated in MCU and I2C devices TFT driving RF remote control NFC-based programming Display drivers, RTC, LED drivers Mux/Demux ESD protection AC power monitoring Fabric and detergent detection NFC-based maintenance Secure device identify Smart sensors Block Diagram Products Category Name 1: MCU Product URL 1 Arm® Cortex®-M4|Kinetis® KV3x Real-time Control MCUs | NXP  Product Description 1 The Kinetis® KV3x family of MCUs delivers a high-performance solution for BLDC, PMSM and ACIM motor control applications. Product URL 2 Arm Cortex-M0+|Kinetis KE1xZ 32-bit 5V MCUs with Touch Interface | NXP  Product Description 2 The robust TSI module provides a high level of stability and accuracy to any HMI system. Product URL 3 i.MX RT1050 MCU/Applications Crossover Processor| Arm® Cortex-M7, 512KB SRAM | NXP  Product Description 3 The i.MX RT1050 provides a Advanced multimedia for GUI and enhanced HMI. Includes a support to Wireless connectivity interface for Wi-Fi®, Bluetooth®, Bluetooth Low Energy, ZigBee® and Thread™ Category Name 2: Real Time Clock Product URL 1 PCF2123 | NXP  Product Description 1 The PCF2123 is a CMOS Real-Time Clock (RTC) and calendar optimized for low power applications. Category Name 3: Drivers Product URL 1 Universal LCD driver for low multiplex rates | NXP  Product Description 1 The PCF85133 is a peripheral device which interfaces to almost any Liquid Crystal Display (LCD) with low multiplex rates. Product URL 2 PCA9955BTW | NXP  Product Description 2 The PCA9955B is an I2C-bus controlled 16-channel constant current LED driver optimized for dimming and blinking 57 mA Red/Green/Blue/Amber (RGBA) LEDs in amusement products. Product URL 3 TEA172x | NXP  Product Description 3 These highly integrated devices enable low no-load power consumption below 10 mW, reduce component count for a cost-effective application design, and provide advanced control modes that deliver exceptional efficiency. Category Name 4: NFC Product URL 1 NTAG I2C | NXP  Product Description 1 The NTAG I2C plus has been designed to be the perfect enabler for NFC in home-automation and consumer applications, this connected NFC tag is the fastest, least expensive way to add tap-and-go connectivity to just about any electronic device. Category Name 5: Wireless Product URL 1 Zigbee and IEEE 802.15.4 wireless microcontroller with 512 kB Flash, 32 kB RAM | NXP  Product Description 1 The JN5169 is an ultra-low-power, high-performance wireless MCU suitable for ZigBee® applications. Product URL 2 Low-Power Multi-Channel UHF RF Wireless Platform | NXP  Product Description 2 The OL2385 device is a radio frequency transceiver with an embedded MCU designed for a wide range of industrial and home applications requiring very high link budget for bi-directional RF communication. Product URL 3 QN908x: Ultra-Low-Power Bluetooth Low Energy System on Chip (SoC) Solution | NXP  Product Description 3 QN908x integrates a Bluetooth Low-Energy radio, controller, protocol stack and profile software on a single chip, providing a flexible and easy to use Bluetooth Low Energy SoC solution. Category Name 6: Security Product URL 1  A71CH | Plug and Trust for IoT | NXP  Product Description 1 A71CH is a ready-to-use secure element for IoT devices providing a root of trust at the IC level and delivers, chip-to-cloud security right out of the box, so you can safely connect to IoT clouds and services, including AWS, IBM Watson IoT™ Platform, and Google Cloud™ IoT Core without writing security code or exposing keys. Demos i.MX RT1050 EVK i.MX RT1050 EVK with Storyboard Suite Demo Applications  Tools Product Link TWR-KV31F120M: Kinetis® KV3x Family Tower® System Module TWR-KV31F120M|Tower System Board|Kinetis® MCUs | NXP  FRDM-KE15Z: Freedom Development Platform for Kinetis® KE1xMCUs FRDM-KE15Z Platform|Freedom Development Board | NXP  MIMXRT1050-EVK: i.MX RT1050 Evaluation Kit i.MX RT1050 Evaluation Kit | NXP  OM13512: Demoboard for the SPI-bus RTC PCF2123 Demoboard for the SPI-bus RTC PCF2123 | NXP  NTAG I2C plus Explorer Kit with NFC Reader OM5569-NT322ER | NTAG I2C plus Explorer Kit + reader | NXP  OM15020: JN5169 USB Dongle for ZigBee JN5169 USB Dongle for ZigBee | NXP  TEA1721BDB1065: TEA1721 universal mains white goods flyback SMPS demo board TEA1721 universal mains white goods flyback SMPS demo board | NXP 

This in home energy display  and Solar Panel demo illustrates a very low-cost  solution for real-time energy monitoring . A DSC-based dedicated control PV inverter from Future supports the MPPT algorithm for optimal power delivery from the solar panel.   Features This Solar Panel demo illustrates a very low-cost connectivity solution for real-time energy monitoring A DSC-based dedicated control PV inverter from Future supports the MPPT algorithm for optimal power delivery from the solar panel    

Overview This reference design deals with the average current mode control of Power Factor Correction (PFC) on the NXP® MC56F8013 digital signal controller (DSC). The application is written for MC56F8013, but can be easy ported into the other members of the MC56F80xx family according to application requirements Both fast current and slow voltage loops are implemented digitally using the DSC and the PFC power switch is controlled directly by the DSC Using direct PFC, we can achieve much better dynamics of the system so the solution is cost-effective The example of such PFC implementation into 3-phase single shunt ACIM vector control is described in this reference design Features Inner current loop Outer voltage loop Direct PFC algorithm Average current control mode 230VAC Input voltage FreeMASTER control interface Part of the system together with HV AC/BLDC Power Stage dedicated for Motor Control Applications Maximal output power 750W Fault protection: Input over-current fault protection Input under-voltage fault protection Input over-voltage fault protection DC-Bus under-voltage fault protection DC-Bus over-voltage fault protection Block Diagram Board Design Resources

Demo Owner AngelC This demo shows the ability to control various wireless devices within a home network with a smart phone / Tablet. This is done by having a so-called gateway system consisting in Tower System TWR K60 Kinetis development module connected via Ethernet/Wi-Fi with a wireless router,  plus a Kinetis KW2x MCU device controls a ZigBee-based home automation 1.2 and a TCP/IP network using a single radio (Dual PAN) . In brief, the Android application running in the tablet connects via Wi-Fi to the gateway, which translates every command to both ZigBee HA 1.2 and TCP/IP networks, thus enabling any Wi-Fi enabled device to control several devices even if using different communication protocols. Features ZigBee and TCP/IP connection Android application Featured NXP Products Product Link Kinetis® K60-100 MHz, Mixed-Signal Integration Microcontrollers based on Arm® Cortex®-M4 Core Arm® Cortex®-M4|Kinetis K60 100 MHz 32-bit Microcontrollers|NXP | NXP  Kinetis K60 100 MHz MCU Tower System Module TWR-K60D100M|Tower System Board|Kinetis MCUs | NXP 

This doc explain how to install S32G design studio& RTD SDK. contributed by Tony.Zhang

Demo HomeKit accessory example and development system implementing a HomeKit controlled chicken coop door with NFC chicken identification, based on the Kinetis K64 microcontroller (MCU), HomeKit SDK, and Arcturus Networks IoT system Features: The Arcturus Networks uCMK64-IoT board is a 60x60mm module for developing secure IoT devices that require a combination of connectivity and control. Includes Ethernet and Wi-Fi connectivity. HomeKit Software Development Kit (SDK) from NXP offers support for home automation applications using Apple HomeKit technology, delivering exceptional performance and advanced security. NXP Kinetis K64 120MHz MCU based on the ARM® Cortex®-M4 core, 256 KB SRAM, 1 MB Flash, and with a rich suite of analog, communication, timing and control peripherals. NXP NFC Controller PN7120, full NFC solution for easy integration into any OS environment, with integrated firmware and NCI interface designed for contactless communication at 13.56 MHz. ________________________________________________________________________________________________________ Featured NXP Products: HomeKit Software Development Kit (SDK)|NXP Arcturus Networks Inc. | uCMK64-IoT ARM Cortex-M4 Cores|Kinetis K6x MCUs|NXP Full NFC Forum-compliant controller with integrated|NXP ________________________________________________________________________________________________________

Overview This reference design describes the design of a 3-phase sensorless brushless DC (BLDC) motor control with back-EMF (electromotive force) zero-crossing sensing using an AD converter for the NXP® 56F80X and 56F83XX Digital Signal Controller (DSCs) dedicated for motor control applications. It can also be adapted to Our 56F81XX Digital Signal Controllers The system is designed as a motor drive for three-phase BLDC motors and is targeted for applications in both industrial and appliance fields (e.g. compressors, air conditioning units, pumps or simple industrial drives) The reference design incorporates both hardware and software parts of the system including hardware schematic Features BLDC sensorless motor 115 or 230V AC Supply Targeted for 56F80x, 56F83XX, and 56F81XX Digital Signal Controllers Running on 3-phase BLDC Motor EVM at 12V, 3-Phase BLDC Low-Voltage Power Stage Speed control loop Motor mode in both direction of rotation Manual interface (RUN/STOP switch, UP/DOWN push buttons control, LED indication) Overvoltage, undervoltage, overcurrent and overheating fault protection PC remote control interface (speed set-up) FreeMASTER software remote monitor Block Diagram Design Resources

The demo from Code is an ultra-compact Sub-GHz to Wi-Fi Border Router solution for use in Home Automation Wireless Sensor Nodes, Smart Lighting, Smart City, Smart Meters, Smart Parking and IoT. The demo consists of an NXP SCM-i.MX 6SoloX V-Link device (i.MX6SoloX/PF0100/512MB LPDDR2) + Code V-Link Top board with 802.11a/b/g/n/ac module + Code Carrier board with the Phalanx Border Router. The Phalanx Border Router provides an optimized mesh network for sensing applications SCM V-Link technology is ideal for space-constrained applications allowing customers to integrate vertically. Features: Top board: Broadcom 2.4 GHz & 5 GHz Wi-Fi, 802.11 a/b/g/n/ac , up to 390 Mbps. U.FL standard antenna connector. SCM-i.MX6 SX V-Link Top board form factor, 15.5mm x 15.5mm. Optimized mesh network for sensing applications. Thousands of nodes, minimizing deployment costs. 900 MHz Wireless. A new, clever routing algorithm which reduces routing overhead. IPv6 capable __________________________________________________________________________________________________________________ Featured NXP Products: Single Chip System Modules (SCM)|NXP Partner CODE Ing __________________________________________________________________________________________________________________