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  

iMXRT eLCDIF 时钟参数计算工具，能够根据用户输入的RGB接口LCD Panel的规格书时序数据，快速计算eLCDIF模块和相应的PLL时钟配置参数，并直接用于RT105x和RT106x的SDK代码中，用于方便用户在iMXRT平台上快速适配新的LCD屏幕。 Products Product Category NXP Part Number URL MCU MIMXRT1050 MIMXRT1060 https://www.nxp.com/products/processors-and-microcontrollers/arm-microcontrollers/i-mx-rt-crossover-... https://www.nxp.com/products/processors-and-microcontrollers/arm-microcontrollers/i-mx-rt-crossover-mcus/i-mx-rt1060-crossover-mcu-with-arm-cortex-m7-core:i.MX-RT1060   SDK SDK Version URL MCUXpresso SDK mcuxpresso.nxp.com

Overview The NXP® 800 MHz MPC8377E PowerQUICC® II Pro processor built on Power Architecture® technology features integrated hardware acceleration for wireless security, MiniPCI or MiniPCI Express®-based interfaces for 802.11N radio modules, dual-band concurrent operation, Gigabit Ethernet (GbE) LAN and WAN interfaces, USB 2.0 host/device interface and IEEE® 802.3af PoE-compliant solution for dual-concurrent MIMO operation. Features 800 MHz MPC8377E PowerQUICC ®  II Pro processor built on Power Architecture technology Integrated hardware acceleration for wireless security MiniPCI or MiniPCI Express based interfaces for 802.11N radio modules Dual-band concurrent operation with 3 x 3 MIMO (GbE) LAN and WAN interfaces USB 2.0 host/device interface IEEE ®  802.3af PoE-compliant solution for dual-concurrent MIMO operation Block Diagram Board Design Resources

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

Overview With this application we create a proposal to automate the click and collect service in the wholesale warehouses, taking into account the operation as a large vending machine. Working as a vending machine, it has the characteristic of managing inventories, modules for secure connection to a server to receive orders and at the same time make re-stock orders, nfc reader modules to read wholesale customer cards. All this driven internally by a system of conveyor belts managed by motors. With current technologies we can present the evolution of wineries to Industry 4.0 powered by NXP.   We have a control by sections managed by a main controller, we have the following sections: Inventory reception: It consists of a reader of an NFC tag or a QR code to read the product and be able to move it to its corresponding storage section Inventory management: Connection to the cloud to be monitoring in real time to use algorithms handling orders, inputs and outputs Internal logistics: It consists of motor control by section for the mobility and arrangement of articles. It uses sensors for safety in mobility and accident prevention. Customer interface: NFC or QR code reader for package pickup reading indicator, touch screen to display data and customer confirmation. Block Diagram     Products MCU Link i.MX RT1060 i.MX RT1060 Crossover MCU with Arm® Cortex®-M7 Core   Wireless Link Wi-Fi 88W8801: 2.4 GHz Single-Band 1x1 Wi-Fi® 4 (802.11n) Solution NFC Reader PN7462: NFC Cortex®-M0 All-in-One Microcontroller with Optional Contact Interface for Access Control NFC Tag NTAG213F, NTAG216F: NFC Forum Type 2 Tag Compliant IC with 144/888 B User Memory and Field Detection   Secure Element Link EdgeLock™ SE051 EdgeLock™ SE051: Proven, Easy-to-Use IoT Security Solution with Support for Updatability and Custom Applets   Power Management Link PMIC PCA9420: PMIC for Low Power Applications AC-DC Controller TEA19161T: Resonant Power Supply Control IC   Sensors Link Accelerometer MMA8450Q: ±2g/±4g/±8g, Low g, Digital Accelerometer Temperature sensor PCT2075: I2C-Bus Fm+, 1 Degree C Accuracy, Digital Temperature Sensor And Thermal Watchdog   Motor Driver Link HB2001 HB2001: SPI Programmable 10 A H-Bridge Brushed DC Motor Driver   Demo Motor control: Download the software AN12214SW Unzip and install   Open MCUXpresso Import project   Look in the AN12214SW software installation folder   Click on finish Build project Open the freemaster folder in the software installation folder and open the pmsm_ref_sol   Change mode expert a basic   Click on app control and run   Extra links PN710 reader demo Getting Started with NXP Wi-Fi® modules using i.MX RT platform NXP Tech Session - Implementing Graphics in Real-time Industrial HMI Systems with NXP MCUs and Embedded Wizard

Overview Bluetooth® and WiFi are popular technologies in wireless headphones and speakers. These technologies require the smartphone to be paired with the audio devices to enable the connection, and NFC is a simple and reliable solution for this. Tap your phone to a Bluetooth speaker or headphone, and the two are securely paired automatically, without searching for a connection or typing a code. NFC is also an excellent choice for easy pairing wireless speakers together and creating a multispeakers audio system.   Block Diagram     Product Description PN7150  High performance NFC controller with integrated firmware for smart devices PN7120  NFC controller with integrated firmware and NCI interface for Home appliances   Documents NXP-NCI MCUXpresso example   Bluetooth & Wi-Fi pairing with NFC  

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 See what FlexIO Does _______________________________________________________________________________________________________ KL28Z FlexIO Camera Demo FRDM-KL28Z board connects with a camera device module via FLexIO interface. The FlexIO peripheral emulates camera interface to capture raw image data. And the real-time images are displayed on a TFT LCD. Features: The FlexIO peripheral emulates camera interface. Captures 320x240 QVGA images via 8-bit width data bus. Displays real-time images on a TFT LCD. The sample rate is up to 15fps. _______________________________________________________________________________________________________ KL28Z FlexIO LCD Demo TWR-KL28Z board drives a TFT LCD panel via FlexIO emulated 8080 interface. Features: The FlexIO peripheral emulates 8080 parallel interface with full writing and reading functions. Drives a 320x240 resolution TFT LCD via the interface. Bus width could be 8 bits or 16 bits. The refresh rate is up to 128 fps with 16-bit width data bus and 48MHz core clock. Featured NXP Products: Flex Your Mind with Kinetis FlexIO projects - Hackster.io ARM Cortex-M4 Cores|Kinetis K8x MCUs|NXP K8X Freedom Development Platform|NXP  QRDEMOUG.pdf _______________________________________________________________________________________ USB Video Camera This demo shows how the FRDM-K82F board along with an OV7670 Camera module can be utilized to create a USB web camera application. The demo application software is delivered as part of the KSDK software enablement. The FS USB video class demonstration can deliver images to PCs or tablets. Demo / product features USB Video device class demonstration application included in Kinetis SDK Easy connection to PC or tablet  display and process video captured from the device     FlexIO camera driver utilized to interface to OV7670 camera module NXP Recommends http://www.nxp.com/products/microcontrollers-and-processors/arm-processors/kinetis-cortex-m-mcus/k-series/k8x-scalable-secure-mcus:K8X-SCALABLE-SECURE-MCU?cof=0&am=0 AN5275: Using FlexIO for parallel Camera Interfacehttp://cache.nxp.com/files/microcontrollers/doc/app_note/AN5275.pdf?fsrch=1&sr=1&pageNum=1 AN5280: Using Kinetis FlexIO to drive a Graphical LCD Training C25

This doc explain how to support RGMII/RMII/MII 100Mbps device in Mcal, and also the debug suggestion. in Chinese version. 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    RGMII RMII MII区别说明... 2 2.1  IO管脚与信号方向... 2 2.2  时钟说明... 7 2.3  注意事项... 7 3    RGMII MCAL配置... 8 3.1  MCAL配置... 8 3.2  注意事项... 10 4    RMII MCAL配置... 11 4.1  MCAL配置... 11 4.2  注意事项... 13 5    MII MCAL配置... 14 5.1  MCAL配置... 14 5.2  注意事项... 15 6    其它建议... 16 6.1  Debug. 16 6.2  EMI 16  

The label printer requires some means of regulating the flow of data to and from the system to which they are attached. The suspension and resumption of data flow is necessary in a variety of circumstances. The attached PPT introduces a simple and effective flow control method running upon lwIP stack.  

KW36 - 32kHz RTC外部振荡器的微调调节 USL：https://community.nxp.com/docs/DOC-342672     引言 FRDM-KW36包含带有32 kHz晶体振荡器的RTC模块。RTC模块以极低功耗模式运行并为MCU提供32 kHz时钟源。该振荡器包括一组可编程调节的负载电容C LOAD ，改变这些负载电容的值可以调整振荡器提供的频率。 此可配置电容的范围为0 pF（禁用电容器组）至30 pF，步长为2 pF。 这些值是通过组合启用的电容器获得的。可用值为2 pF，4 pF，8 pF和16 pF。这四个数值可以任意组合。如果外部电容可用，建议禁用这些内部电容器（将RTC控制寄存器SFR中的SC2P，SC4P，SCS8和SC16位设置为0）。 要调整振荡器提供的频率，必须首先能够测量该频率。最好使用频率计数器测了频率，因为它提供了比示波器更精确的测量。另外还需要KW36通过IO输出振荡器频率。要输出振荡器频率，以任意一个低功耗蓝牙演示应用程序为例，执行以下操作： 调整频率示例 本示例将利用低功耗蓝牙演示应用程序的心率传感器演示（freertos版本），并假定开发人员具有从SDK到IDE导入或打开项目的知识。 从SDK中打开或克隆“心率传感器”项目。       在工作区的board文件夹中找到board.c和board.h文件。 如下图所示在board.h文件中声明一个void函数。该函数将是为了把RTC时钟多路复用到PTB3，以使其能够输出32kHz频率用于测量。 /* Function to mux PTB3 to RTC_CLKOUT */void BOARD_EnableRtcClkOut (void); 如下所示在board.c文件中添加BOARD_EnableRtcClkOut函数。    void BOARD_EnableRtcClkOut(void){/* Enable PORTB clock gating */CLOCK_EnableClock(kCLOCK_PortB);/* Mux the RTC_CLKOUT to PTB3 */PORT_SetPinMux(PORTB, 3u, kPORT_MuxAlt7);/* Select the 32kHz reference for RTC_CLKOUT signal */ SIM->SOPT1 |= SIM_SOPT1_OSC32KOUT(1); } 在hardware_init函数中（board.c文件），在调用BOARD_BootClockRUN函数之后立即调用BOARD_EnableRtcClkOut函数。       在工作区的board文件夹中找到clock_config.c文件。 在文件顶部添加以下定义。 #define RTC_OSC_CAP_LOAD_0 0x0U /*!< RTC oscillator, capacitance 0pF */#define RTC_OSC_CAP_LOAD_2 0x2000U /*!< RTC oscillator, capacitance 2pF */#define RTC_OSC_CAP_LOAD_4 0x1000U /*!< RTC oscillator, capacitance 4pF */#define RTC_OSC_CAP_LOAD_6 0x3000U /*!< RTC oscillator, capacitance 6pF */#define RTC_OSC_CAP_LOAD_8 0x800U /*!< RTC oscillator, capacitance 8pF */#define RTC_OSC_CAP_LOAD_10 0x2800U /*!< RTC oscillator, capacitance 10pF */#define RTC_OSC_CAP_LOAD_12 0x1800U /*!< RTC oscillator, capacitance 12pF */#define RTC_OSC_CAP_LOAD_14 0x3800U /*!< RTC oscillator, capacitance 14pF */#define RTC_OSC_CAP_LOAD_16 0x400U /*!< RTC oscillator, capacitance 16pF */#define RTC_OSC_CAP_LOAD_18 0x2400U /*!< RTC oscillator, capacitance 18pF */#define RTC_OSC_CAP_LOAD_20 0x1400U /*!< RTC oscillator, capacitance 20pF */#define RTC_OSC_CAP_LOAD_22 0x3400U /*!< RTC oscillator, capacitance 22pF */#define RTC_OSC_CAP_LOAD_24 0xC00U /*!< RTC oscillator, capacitance 24pF */#define RTC_OSC_CAP_LOAD_26 0x2C00U /*!< RTC oscillator, capacitance 26pF */#define RTC_OSC_CAP_LOAD_28 0x1C00U /*!< RTC oscillator, capacitance 28pF */#define RTC_OSC_CAP_LOAD_30 0x3C00U /*!< RTC oscillator, capacitance 30pF */ 在BOARD_BootClockRUN函数内（也在clock_config.c文件中）找到对函数CLOCK_CONFIG_EnableRtcOsc的调用，然后通过上述任意定义来设置函数入参。 最后，在项目源文件夹中的“app_preinclude.h”文件中禁用低功耗选项和LED Support： #define cPWR_UsePowerDownMode 0#define gLEDSupported_d 0     此时，可以用频率计数器测量PTB3输出的频率，并进行频率调整。每次对电路板进行编程时，都需要执行POR以获得正确的测量值。下表是从FRDM-KW36板rev B获得的，可用作调整频率的参考。 请注意，电容不仅由启用的内部电容组成，还包括封装、焊线、焊垫和 PCB 走线中的寄生电容。因此，尽管下面给出的参考测量值应接近实际值，但您还应该在电路板上进行测量，以确保频率是专门针对您的电路板和布局进行调整的。 启用的电容器 CLOAD 电容定义 频率 - 0pF RTC_OSC_CAP_LOAD_0 (bank disabled) 32772.980Hz SC2P 2pF RTC_OSC_CAP_LOAD_2 32771.330Hz SC4P 4pF RTC_OSC_CAP_LOAD_4 32770.050Hz SC2P, SC4P 6pF RTC_OSC_CAP_LOAD_6 32769.122Hz SC8P 8pF RTC_OSC_CAP_LOAD_8 32768.289Hz SC2P, SC8P 10pF RTC_OSC_CAP_LOAD_10 32767.701Hz SC4P, SC8P 12pF RTC_OSC_CAP_LOAD_12 32767.182Hz SC2P, SC4P, SC8P 14pF RTC_OSC_CAP_LOAD_14 32766.766Hz SC16P 16pF RTC_OSC_CAP_LOAD_16 32766.338Hz SC2P, SC16P 18pF RTC_OSC_CAP_LOAD_18 32766.038Hz SC4P, SC16P 20pF RTC_OSC_CAP_LOAD_20 32765.762Hz SC2P, SC4P, SC16P 22pF RTC_OSC_CAP_LOAD_22 32765.532Hz SC8P, SC16P 24pF RTC_OSC_CAP_LOAD_24 32765.297Hz SC2P, SC8P, SC16P 26pF RTC_OSC_CAP_LOAD_26 32765.117Hz SC4P, SC8P, SC16P 28pF RTC_OSC_CAP_LOAD_28 32764.940Hz SC2P, SC4P, SC8P, SC16P 30pF RTC_OSC_CAP_LOAD_30 32764.764Hz  

Description Governing motion and speed, this domain is what makes an automobile move. Movement is based on inputs from the driver or the driver-substitute and can be modified based on personal preferences and environmental constraints, such as road conditions. The vehicle dynamics portion of this domain is where supporting subsystems, such as suspension and steering, ensure stability and a smooth ride. Our angular sensors include magnetic field sensors, integrated amplifiers and programmable sensors. NXP’s 16- and 32-bit single and dual-core automotive MCUs provide enhanced computing power and specialized peripherals for complex electric motor control functions. Integrated power supply solutions are also important elements of a power steering control unit. Features BLDC motor commutation Electronic Power Steering (EPS) Steering angle measurement Window wiper position detection Contactless angle measurement Quick response High accuracy over wider temperature range Block Diagram Products Category Name 1: MCU Product URL 1 32-bit Automotive General Purpose MCUs | NXP  Product Description 1 S32K MCUs combine multiple low power operating modes with autonomous, low power peripherals providing complete control over the dynamic and static power profiles. Category Name 2: CAN Product URL 1 CAN/LIN SBC w/<Gen2 | NXP  Product Description 1 The MC33903 works as an advanced power management unit for the MCU and additional integrated circuits such as sensors and CAN transceivers Product URL 2 UJA1169LTK | Mini High-Speed CAN SBC | NXP  Product Description 2 The UJA1169L is designed to be used in applications that require more than one transceiver or additional power supply resources. Category Name 3: Sensor Product URL 1 KMZ60 | Angle sensor with integrated amplifier | NXP  Product Description 1 The MagnetoResistive (MR) sensor with integrated amplifier is designed for angular control applications and Brushless DC (BLDC) motors with even-numbered pole pairs. Demos Automotive Magnetic Sensors  Training Vehicle Dynamics &amp; Safety: Next-Generation Automotive Security Solutions  Tools Product Link S32K144EVB: S32K144 Evaluation Board S32K144 Evaluation Board | NXP  KIT33903BD3EVBE: Evaluation Kit - MC33903BD3, SBC Gen2 with CAN and LIN EVK - MC33903BD3, SBC Gen2 with CAN and LIN | NXP 

Connecting the Streets of Austin with Live V2X Demonstration – NXP FTF 2016 “Together with Siemens and Electric Cab of Austin NXP is showing how V2X and other connected technologies are going to change the face of our cities as we know them – making them more efficient, cleaner and less congested” Demo / product features V2X technology warns drivers of traffic hazards, increasing the safety for the driver, while taking people or objects into account, essentially “seeing around corners”. V2X technology warns drivers of traffic hazards even one mile ahead, increasing the safety for the driver, while taking people or objects into account, essentially “seeing around corners”. The strength of V2X comes from its ability to take control of traffic. V2X technology helps make roads safer and eases traffic by warning drivers and presenting alternatives when problems occur. For example, when only one lane is open, the V2X system controls on-coming vehicles with traffic lights to safely share the single lane. V2X will also advise drivers on optimal speed to pass the traffic light during a green phase and the remaining time of the green signal. V2X-enabled traffic lights detect pedestrians, cyclists and other vulnerable road users and signal for crossing vehicles to stop to allow the pedestrians to cross Transparent truck with IoT truck V2X – V2V Drone-to-car communication Emergency vehicle approaching Security – hacker use case Pedestrian crossing Real-time camera video streaming over 802.11p from IoT truck Vulnerable road user detection based on RFID tags and broadcast VRU warning via V2X NXP Recommends V2X comms RoadLink Chipset RF Transceiver (TEF5x00) Baseband IC (SAF5x00) Security IC (SXF1700) Dolphin 77GHz Radar Chip Ethernet Switch Videos

Demo Needs for insuring availability of Electrical Power is increasing. Batteries are spreading into automotive, electrical storage systems. This demo will demonstrate the Battery Management Product Family from NXP.   Most scalable and comprehensive battery management solutions Automotive robustness and in-house manufacturing process Designed for Functional Safety   Featured NXP Product 14-Channel Li-ion Battery Cell Controller IC|NXP   Target Applications Automotive Battery Chargers and Management 48V battery applications High-voltage battery management systems (> 800 V) Industrial Energy Storage Systems Uninterrupted power supply (UPS) E-bikes, E-scooters   Block Diagram

Winners! NXP received a number of creative submissions over the course of the MRFX Design Challenge. We appreciate the enthusiasm from the community as designers were hard at work on their RF projects. Now is the moment everyone's been waiting for as NXP proclaims the MRFX Design Challenge winners. First Place Winner  Russell Kendrick | Bio + Full Project Description Project Video: MRFX1K80H 50 MHz Project Brief This amplifier is intended to be driven with a modern transceiver with 100 watts output on 50 MHz. To protect the MRFX1K80H from overdrive a series of RF pads are used to reduce the input to the proper level. The input matching is accomplished by using a 9:1 conventional RF transformer formed on an Amidon BN 61-202 core. An 82 nH inductance is in series with the high impedance winding of the transformer. This arrangement yielded an input match of 1.3:1 SWR over the entire 6-meter Amateur band when measured without the pads. Shunt gate resistance is used to prevent oscillation at low frequencies. This is the same approach used in the 27 MHz test circuit from NXP. Bias will be supplied by a DAC driven by the microcontroller that will manage the finished amplifier Second Place Winner        Floris Roosen | Bio                                                                         Project Video: Roosen Single-Ended Broadband (87-110 MHz) RF Design         Third Place Winner Mike Mysliwiec | Bio Project Video: 2xMRFX1K80H 1.8-54 MHz HF Amplifier   Overview  NXP is hosting an RF power amplifier design contest. Applicants will record a video of their power amplifier/demo using NXP’s new 65V LDMOS 1800 W RF Power transistor, MRFX1K80H The contest is open to students, professional engineers, companies or individuals Key Dates Contest kick-off: October 30, 2017 Submit a video (3-5 minutes in length) no later than Friday, January 26, 2018, by sending a link to any video website, such as YouTube, YouKu or others to rfindustrial@nxp.com Results will be announced on Monday, February 12, 2018 Prizes • 1st prize: $3,000 cash award + 15 MRFX1K80H samples. Showcase designer bio and video in an NXP blog • 2nd prize: $1,000 cash award + 10 MRFX1K80H samples • 3rd prize: $500 cash award + 10 MRFX1K80H samples The prize amounts are before tax All accepted videos will be posted on www.nxp.com/videos  Judging Criteria How to enter the competition Please click on the link below for the latest details and to access the MRFX Design Challenge page www.nxp.com/MRFXdesign 

Overview NXP® and Tongji University jointly developed the anti-pinch window lift reference design featuring the MagniV® S12VR MCU, ideal for the development of power windows and sun roof systems. Includes hardware for real door/window in-vehicle applications, as well as software including anti-pinch algorithms and low-level S12VR drivers Aimed at reducing time to market, this design leverages unique features of the MagniV S12VR MCU Reduces unnecessary external components, lowers the total bill of material (BOM), improves system quality and saves space in automotive applications through a smaller PCB 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 Fault diagnosis, indicating low voltage, over voltage/current/temperature etc. Low power mode (leveraging S12VR low power mode) to reduce power consumption 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 Easy-to-control Graphics User Interface (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) Able to comply with relevant content in US Federal Motor Vehicle Safety Standard (FMVSS No. 118) Block Diagram Design Resources

Overview The very rapid adoption of digital media such as downloadable music, video games, and movies has created a strong demand for converged network platforms to distribute media content throughout the home. Consumers need a unified platform that connects all digital networked devices within the home and provides content and services management from anywhere in the world. The MPC8349E-mITX is a turnkey hardware/ software reference platform ideal as a "location-free control access" residential gateway solution. This reference platform is based on the MPC8349E PowerQUICC® II™ Pro processor, containing a Power Architecture® core and HipServ™ software platform from Axentra, a leading provider of personal digital content and services software platform for the Digital Home. Features MPC8349E mITX Digital Home Center Reference Platform features: MPC8349-mITX reference platform helps you manage your digital devices remotely from just about anywhere on the globe. These include: Internet gateway Router Wi-Fi access point Digital content/media server Home automation PC Home-bound content remote access and sharing Backup Server The MPC8349E-mITX integrates the enhanced e300 Power Architecture core and advanced features such as DDR memory, dual PCI, Gigabit Ethernet, and high-speed USB controllers. The platform supports dual 10/100/1000 Mbit/s Ethernet controllers, dual 32-bit/single 64-bit PCI controllers, integrated security engines, USB 2.0 host and devices controllers, 4-channel DMA, DUART, serial peripherals, general-purpose I/O and system timers. The high level of integration in the MPC8349E helps lower system costs, improves performance, and simplifies board design. The MPC8349E also integrates a hardware encryption block that supports different algorithms for high-performance data authentication as required for secure communications in the residential market. It supports DES, 3DES, MD-5, SHA-1, AES, PKEU, RNG, and RC-4 encryption algorithms in hardware. In addition to the highly integrated MPC8349E processor, the reference platform leverages external components to support these additional features: 5-port Gigabit Ethernet switch Four high-speed USB ports Four Serial ATA ports PCI slot MiniPCI slot Compact FLASH memory slot Axentra's Location-Free Access and Control Software: The HipServ software platform is a comprehensive and unified environment that allows home users to easily use various content on different devices within the home or access the content from anywhere, anytime. Home users are increasingly creating more digital content and need a single environment to better manage, access, share, and backup their critical home-created content. This innovative software platform also allows users to access and share their home content using mobile devices. Key Features: Content remote access, sharing and publishing (home-based content) Unified operating environment and interface for central access to any content Auto back-up from PC/Mac to central storage or remote storage Media management and server (UpnP-AV) Home surveillance (internet camera) Remote desktop access (PC/Mac) Easy management of photographs, music, and videos Block Diagram Board Design Resources

Demo Go to your local bicycle store and you will see just how popular Ebike are becoming. To help power this revolution further Kinetis Motor Suite will enable your motor control solution quickly. KMS is used to tune and control the motor with FOC torque control, with the startup control modified to uses the hall effect inputs to improve start-up power.     Features: A sensorless FOC Brushless DC (BLDC) motor control application with torque control, using a Kinetis V Series KV3x ARM Cortex-M4 MCU and the Kinetis Motor Suite solution.  KMS supports the development of sensored and sensorless velocity control, and sensored position control applications for PMSM and BLDC motors ____________________________________________________________________________________________________________________________ Featured NXP Products: Product Link Kinetis® KV3x-100–120 MHz, Advanced 3ph FOC / Sensorless Motor Control MCUs based on Arm® Cortex®-M4 Arm® Cortex®-M4|Kinetis® KV3x Real-time Control MCUs | NXP  Kinetis® KV3x Family Tower® System Module https://www.nxp.com/design/development-boards/tower-development-boards/mcu-and-processor-modules/kinetis-modules/kinetis-kv3x-family-tower-system-module:TWR-KV31F120M?&lang_cd=en 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 Freedom Development Platform for Kinetis® KV3x Family MCUs FRDM-KV31F|Freedom Development Platform|Kinetis® MCU | NXP  NXP® Freedom Development Platform for Low-Voltage, 3-Phase PMSM Motor Control https://www.nxp.com/design/development-boards/freedom-development-boards/mcu-boards/nxp-freedom-development-platform-for-low-voltage-3-phase-pmsm-motor-control:FRDM-MC-LVPMSM?&fsrch=1&sr=1&pageNum=1 ____________________________________________________________________________________________________________________________ Online Training: Kinetis V Series MCU Online Training|NXP ____________________________________________________________________________________________________________________________     C63

Demo NXP’s new Doherty amplifier-optimized power transistors provide high power, small footprints, and higher frequencies required for use in current and next-generation cellular base stations. The four new transistors collectively cover cellular bands from 1805 to 3600 MHz, meeting the needs of wireless carriers for superior performance at higher frequencies     Demo / product features A2G35S160-01S / A2G35S200-01S 48 V GaN Doherty Power Amplifier Solution Frequency 3400–3500 MHz Asymmetrical Doherty performance at 8 dB OBO Gain 13.8 Db Efficiency 45.8% Peak power 55.2 dBm NI-400S-2S package   A2G26H281-04S 48 V GaN Doherty Power Amplifier In-package Solution Frequency 2496–2690 MHz Doherty performance at 8 dB OBO Gain 15.3 dB Efficiency 57% Peak power 54.6 dBm NI-780S-4L package   A2G22S251-01S 48 V GaN Single-ended Transistor Frequency 1805–2200 MHz Class AB performance at 7 dB OBO Gain 18 dB Efficiency 35% Peak power 53.8 dBm NI-400S-2S package   NXP Recommends A2G22S251-01S – Single-ended GaN for 1805-2200 MHz cellular base stations A2G26H281-04S – In-package asymmetric Doherty GaN for 2496-2690 MHz cellular base stations A2G35S160-01S – Single-ended GaN for 3400-3600 MHz cellular base stations A2G35S200-01S – Single-ended GaN for 3400-3600 MHz cellular base stations   Fast Track 5G with NXP

      虽然目前NXP的很多MCU都带了丰富的UART资源，但是在某些特地的情况下或个别芯片，UART数量还是有一定的局限性。现在NXP很多的MCU也携带有FlexIO模块，那么我们就可以利用FlexIO来扩展更多的UART，SDK中有相应的代码，这些代码是支持全双工的，需要使用至少两个timer和两个shifter设计一个UART, 在实际使用中很多时候是使用半双工通信的，本文是基于SDK FlexIO的例程来设计基于一个timer和一个shifter的半双工UART，最大限度扩展UART数量，设计4个半双工的UART，本文设计验证平台为FRDEM-KE15Z和SDK_2.6.0_MKE15Z256xxx7。     希望能给需要的使用者提供种扩展尽可能多UART的方法。 Best Regards, Fred Fu