Description   Industry 4.0 applications demand superior performance and reliable communications for network synchronization, on-time data delivery, and energy efficiency—even under the most extreme operating conditions. Current manufacturing challenges require flexible platforms capable of uniting trustworthy networking protocols with modern and reliable machine-to-machine communications. A remote access unit works as an interface for machinery that can’t be accessed. This tool displays parameters, measurements and can control any features of the linked machine. This remote access unit application is based in an i.MX 6 applications processor that can be programmed with a Linux distribution and Built-in 2G/3G/GPS/Glonass.   Features GPU 3D GPU 2D (Vector Graphics) Camera Interface Cryptographic cipher engines Tamper detection Ethernet Four USB2.0   Block Diagram     Products   Category Name 1: MPU Product URL 1 i.MX 6Dual Applications Processors | Dual Arm® Cortex®-A9 @1.2GHz | NXP  Product Description 1 The i.MX 6 series of applications processors combines broad levels of integration and power-efficient processing capabilities all the way up to bleeding edge 3D and 2D graphics, as well as high-definition video, to provide a new level of multimedia performance for an unbounded next-generation user experience.   Category Name 2: Transceiver Product URL 1 TJA1057 | High speed CAN transceiver | NXP  Product Description 1 The TJA1057 is part of the Mantis family of high-speed CAN transceivers. It provides an interface between a Controller Area Network (CAN) protocol controller and the physical two-wire CAN bus Product URL 2 TJA1101 | 2nd generation PHY Transceiver | NXP  Product Description 2 TJA1101 is a high-performance single port, IEEE 100BASE-T1 compliant Ethernet PHY Transceiver. Product URL 3 Logic controlled high-side power switch | NXP  Product Description The NX5P1100 is an advanced power switch and ESD-protection device for USB OTG applications. It includes under voltage and over voltage lockout, over-current, over-temperature, reverse bias and in-rush current protection circuits.   Category Name 3: Power Management Product URL 1 14-Channel Configurable Power Management IC | NXP  Product Description 1 The PF0100 SMARTMOS Power Management Integrated Circuit (PMIC) provides a highly programmable/configurable architecture, with fully integrated power devices and minimal external components.   Category Name 4: Memory Product URL 1 NXH5104UK: 4 Mbit Serial EEPROM | NXP  Product Description 1 The NXP NXH5104 is a 4 Mbit serial electrically erasable and programmable read-only memory (EEPROM). It provides byte level and page level serial EEPROM functions, sector level protection and power-down functions.   Category Name 5: Sensor Product URL 1 Ultra-low-power, 1.8 V, 1 deg. C accuracy, digital temperature sensor with I2C bus interface | NXP  Product Description 1 The PCT2202 is an I2C bus, serial output temperature sensor available in a tiny WLCSP6 package. It requires no external components.   Category Name 6: RTC Product URL 1 PCF2123 | NXP  Product Description 1 The PCF2123 is a CMOS Real-Time Clock (RTC) and calendar optimized for low power applications. Data is transferred serially via a Serial Peripheral Interface (SPI-bus) with a maximum data rate of 6.25 Mbit/s.   Documentation i.MX 6 Temperature Sensor Module:  https://www.nxp.com/docs/en/application-note/AN5215.pdf    Tools Product Link RD-IMX6Q-SABRE: SABRE Board for Smart Devices Based on the i.MX 6Quad Applications Processors i.MX 6Quad SABRE Development Board | NXP  KITPF0100EPEVBE: Evaluation Kit - MMPF0100, 14 Channel Configurable PMIC EVB- MMPF0100, 14 Channel Configurable PMIC | NXP  OM13512: Demoboard for the SPI-bus RTC PCF2123 Demoboard for the SPI-bus RTC PCF2123 | NXP  NXH5104ADB: NXH5104A Demo Board NXH5104A Demo Board | NXP  OM13257: Universal Temperature Sensor Daughter Card for the Fm+ Development Kit Universal Temperature Sensor Daughter Card for the Fm+ Development Kit | NXP  TJA1100HN: Evaluation Board, TJA1100HN 100BASE-T1 PHY Transceiver TJA1100 Customer Evaluation Board | NXP 

Overview This reference design shows the simplicity of a soft modem design, how few resources of the processor it takes, and how well it performs on USA average lines. This design omits the standard telecommunications Codec, instead of using PWM for output and ADC for input. Since both peripherals are readily available on one 56F8300/100 series device, along with more processing power than required from the single core, the design is a true one-chip, one-core system that includes telecommunications ability with room for even more system functionality. Ideal for advanced motion control, home appliances, medical monitoring, fire and security systems, power management, smart relays, and POS terminals. Features Hybrid architecture facilitates implementation of V.21 and V.22bis modem, control, and signal processing functions in one chip Consumes only 7.5 MIPS for the modem function - Only 15K words of Flash for the complete modem application and test harness High-performance, secured Flash memory eliminates the need for external storage devices Extended temperature range allows for operation of non-volatile memory in harsh environments Flash memory emulation of EEPROM eliminates the need for external non-volatile memory 32-bit performance with 16-bit code density On-chip voltage regulator and power management reduces overall system cost Off-chip memory expansion capabilities allow for glueless interfacing with the additional memory of external devices, without sacrificing performance Boots directly from Flash, providing additional application flexibility High-performance PWM with programmable fault capability simplifies design and promotes compliance with safety regulations PWM and ADC modules are tightly coupled to reduce processing overhead; only one of each is used by the modem General purpose input/output (GPIO) pins support application-specific needs Simple in-application Flash memory programming via Enhanced OnCE or serial communication Block Diagram Board Design Resources

  Overview NXP ® 's wireless charging reference design uses inductive charging technology to charge high-capacity, multi-cell Li-Ion battery packs. The reference design is capable of charging four battery packs simultaneously, using a single NXP digital signal controller. The reference design consists of two main components: a transmitter that sends the requested power level to the battery packs, and a receiver embedded in the battery packs. The receiver provides a controlled charge to the battery by implementing a charging algorithm. Each transmitter channel adjusts its energy transfer independently by responding to commands from the receiver embedded in the battery pack. The intelligent charging method is software-controlled and has the ability to dynamically adjust the power transfer. Archived content is no longer updated and is made available for historical reference only.   Features 80% transfer efficiency Four charging stations to charge four battery packs simultaneously Supports Qi communications protocol Overtemp, overcurrent and overvoltage protection    

Overview To improve performance in industrial drives, Field Oriented Control (FOC) is an advanced technique used for Permanent Magnetic Synchronous and other motor types. This reference design jump-starts your ability to leverage the NXP® DSCs' advanced feature sets via complete software, tools and hardware platform. Features Bi-directional rotation Application speed ranges from 0 to 100 percent of nominal speed (no field weakening) Four state machine Fault protection for driver DC-bus overcurrent, SW overcurrent, overvoltage and over speed Current control loop execution time: 17 us @ 100 MHz MCU speed PMSM vector control using the quadrature encoder Block Diagram Design Resources

Smart Sensor Demo Kit Highlighted Features Multi-protocol bi-directional data stream support from/to any IP-enabled remote system Data parsing and abstraction mapping layer for normalizing data from heterogeneous devices Drag-and-drop business and analytics processing logic (akin to using Visio and Excel fused together) Report and web page builder that assembles Table reports (including data for exposure to the secure API) Time-series graphs Pie, line, spark and other chart types Uploaded visuals such as photos, CAD/CAM drawings, diagrams, schematics, etc. Full location-based services incorporating Google Maps, NOKIA here, CloudMade and Open Street Maps Business Forms assembly system so you can deploy workflow for Firmware push Remote command and control (on/off, settings, reboot, etc.) Device inventory tracking and control Asset management Financial transactions from machines Many other possibilities   Description The SeeControl Cloud Service allows embedded systems engineers to quickly assemble scalable 3-tier web applications that collect, analyze and display systems data. The service is drag and drop so you don't have to script or code to create a web app. The Service natively supports the following IoT/M2M communication protocols: UDP TCP MQTT HTTP MODBUS CoAP There is additional support for vendor-specific communication stacks such as GE, CalAmp, Sierra Wireless, etc. Customers can also create their own device adapter using protocol and language of choice. You can stream data to these data adapters at http://com2.seecontrol.com. We will give you a specific port range for each protocol/device type. You can also send your data through a device API. Guidance is here. Once the data has been received by our system. You will use a data abstraction tool to define fields that are in the packets you are sending. For example, if you send a variable field called tmp_123 from a temperature sensor you will tell the SeeControl service that tmp_123 is a a number and specifically a unit of measure called "Temperature" and then select whether Celsius or Fahrenheit. Once that is done, you can use the rest of the system to build a scalable web app, typically in 1-2 days depending on how complex our solution needs to be. To see the full range of interfaces available for visualizaing IoT data and managing devices/process, you can log in to: http://cloudx.seecontrol.com user:                fslcommunity1 password:        fslcomms1 This account only shows the visualization output, not the tools used to collect and process data. To try out the whole toolset, please acquire a full demo kit. The demo kit includes a cloud account that you can connect to the sample connectivity and sensor items listed below (or any hardware/system you would like to try out). Full Bill of Materials See bottom of this page for BOM Table Basic Data (To be filled out by FSL) Demo Number: Current Version: Current Demo Reproducibility: Intended to be Modified By: Current Demo Operation: BOM: See bottom of this page Demo Video   Freescale IoT Cloud Demo Kit     System Block Diagram   Hardware Kit & Data Flow Diagram     IoT Physical Components Gateways SOC's: i.MX6 Dual Boards/Modules: Utilite Standard Box Software: https://community.nxp.com/docs/DOC-103268 Utilite Linux BSP Connectivity Software: USB Local TCP/IP over Ethernet HTTP to Cloud Sensors End User Products: Commercial Temperature and Electric Current Sensors (See below for list) Cloud Infrastructure/Services https://community.nxp.com/docs/DOC-103268 IoT System Capabilities Device Management Add Device Remove Device Device Inventory Management Check Online/Offline Status View real time and historical messages Communications/Interworking HTTP (other protocols such as CoAP, MQTT, etc. optional) Security HTTPs (secured HTTP) Middleware / Analytics / Data SeeControl Cloud Communications & Data Mapping Tool SeeControl No Coding Analytic Engine SeeControl No Coding Visualizer Note: For additional Products/Components used in this demo see bottom of this page. IoT Product Type Product/Component Vendor Research or Procure This Product/Component Gateway NXP Utilite Standard Box NXP Contact NXP IoT Center Temperature Sensor Lascar USB Temperature Logger MicroDAQ Visit MicroDAQ Website Electrical Meter eGauge eg3000 Electric Meter eGauge Visit eGauge Website In online or phone order, please ask for SeeControl Turnkey Part Number Current Transformer(s) eGauge Current Transformers eGauge Visit eGauge Website Connectivity / Messaging Middleware SeeControl No Coding IoT Cloud Service    SeeControl Get a live demo Analytics SeeControl No Coding IoT Cloud Service SeeControl Get a live demo Data Visualization SeeControl No Coding IoT Cloud Service SeeControl Get a live demo

uCP1020 IoT Gateway Module and Mbarx IoT Middleware uCP1020 IoT Gateway Module hardware Mbarx IoT Gateway Middleware TLS secure remote site connectivity Data aggregation and proxy of remote IoT devices Seamless switching between local and remote IoT sites   Mbarx System Manager GUI IoT site management tool uCP1020 IoT Gateway System-On-Module Hardware This Demo Is Probably of Interest If You: Have various remote site locations that need to be centrally connected Require remote site data aggregation and secure connectivity, across public networks Need to implement a private cloud service architecture (e.g. develop your own device interactions/workflow) Require a versatile Linux platform to deploy various gateway services Are evaluating options for RYO or commercial IoT gateway hardware Differentiation This Demo Highlights Modular, off-the-shelf IoT gateway hardware Eco-system of Mbarx IoT solutions and tools Simple, GUI driven management of remote sites Complete system-level solution for private or public cloud IoT deployments   What this Demo is All About Video Link : 4542 uCP1020 IoT Gateway Demo - Using Mbarx IoT Gateway Middleware, End-points and System Manager Tool. Demo Diagram(s) IoT Physical Components Gateways SOC: QorIQ P1020 Dual-Core Communication Processor Boards/Modules: uCP1020 IoT Gateway Module hardware Software: Arcturus Mbarx IoT Gateway middleware Arcturus management middleware  Arcturus PBX/Communications software package Arcturus Mbarx-Operations Controller work-flow management middleware Open source Linux software (Kernel mainline branch) Edge Devices SOC:2x 10/100/1000BaseT networking supported natively by the P1020 processor and on board network PHYs Modules:Various PCIe and miniPCIe based connectivity options (see wireless below) Software:Linux Wireless Connectivity Modules:GSM/LTE/HSPA/UMTS/EVDO data (depending on providers, regions and certifications).  As tested using Telit HE910 family (HEPCHGPS204T701) Modules:Wi-Fi (depending on regions and certifications).  As tested using Atheros AR9390 family. Software:Linux Sensors SOC: Peripheral connectivity supported by SPI, I2C, UART, USB, SDHC, PCIe, miniPCIe Cloud Infrastructure/Services Software/Services: Arcturus Mbarx IoT Gateway middleware is fully compatible with Mbarx IoT end-nodes such as uCMK60 based on K60, K64. Mbarx IoT protocol supports TCP/IP sockets with TLS security and simple character driven protocol Mbarx IoT Gateway middleware supports remote-site aggregation, secure connectivity and device management proxy. Optional plugs-ins for MQTT, CoAP and other popular IoT/M2M protocols. Smart Devices/Apps Software: Mbarx-Operations Controller supports cross-platform work-flow driven, operational control using a responsive HTML5 architecture. Mbarx-System Manager site-wide IoT device/node management tool is available for PCs. IoT System Capabilities Device Management Secure remote site connectivity Remote site IoT node/device aggregation Bulk device firmware updates, bulk configuration, site wide-provisioning Secure IoT node/device management and configuration Cloud/App Communications/Interworking Wi-Fi Access Point (Host AP mode), cellular data Security SSL/TLS 1.1,1.2 server and client with X.509 IoT Development Capabilities Embedded Platforms Kinetis MCUs, QorIQ 32-bit Power Architecture processors Embedded Tools Linux - kernel, driver, middleware and user space application development U-boot development and customization MQX - KSDK Services Customization and system solutions available through direct engagement - contact Arcturus Hardware and software services available - contact Arcturus IoT Product Type Product/Component Vendor Research or Procure This Product/Component End User Hardware Laptop PC Win7, Win8, Win10 or Mac Commercial Laptop PC End User Software Arcturus Mbarx System Manager Tool Commercial Arcturus Mbarx IoT and M2M Solutions End User Smart Device Arcturus uCMK60 - VoIP / IoT Board/Modules Arcturus uCMK64 - IoT Board/Modules Commercial Arcturus uCMK60 - VoIP / IoT Boards/Modules End User Edge Device TP-Link TL-SF1008P 802.3af PoE Switch Commercial TP Link TL-SF1008P End User Edge Device Linksys EA6100 Dual Band Smart Wi-Fi Router Commercial Linksys EA6100 Dual Band Smart Wi-Fi Router

Demo NXP’s new MRF13750H transistor delivers 750 W CW for 915 MHz applications. Based on 50 V silicon LDMOS, the MRF13750H is an attractive alternative to vacuum tubes for very high power industrial systems. Applications range from industrial heating/drying, curing, and material welding, as well as particle accelerators Product MRF13750H 750 W CW 915 MHz Applications Industry’s highest power for 915 and 1300 MHz 50 V LDMOS 915 MHz reference circuit 750 W CW Gain 19.5 dB Efficiency 63%

  Description Faced with limited resources and booming demand, the energy industry seeks greater efficiencies within complex energy management and distribution processes, all while providing the best consumer experience. To achieve better service and smarter, streamlined processes, energy providers require reliable, real-time access to data.   A smart plug controls the energy supply of devices connected to it. Using a ZigBee® interface this device connects to a gateway where you can send commands to turn on/off or see the power consumption of the device connected to it.   Features   Tamper detection with time stamping USB battery charging (CC/CV) and Energy Star 2.0 compliant Very low current solution for long battery life System BOM is low in component count and cost 6 LED drivers Integrated power amplifier for long range and robust communication   Block Diagram     Products   Category Name 1:  MCU Product URL 1 Arm® Cortex®-M0+|Kinetis® KM1x 50 MHz 32-bit MCUs | NXP  Product Description 1 The KM1x include a high-accuracy, real-time clock delivers less than 5 PPM drift over temperature. Metrology firmware for calculating active, reactive and apparent power using a variety of algorithms is provided free of charge.   Category Name 2: Power management Product URL 1 HV start-up flyback controller with integrated MOSFET for 5 W applications, f~burst = 1270 Hz | NXP  Product Description 1 The TEA1721 is a small and low cost module Switched Mode Power Supply (SMPS) controller IC for low power applications (up to 5 W) and operates directly from the rectified universal mains input. Product URL 2 PCA9410/9410A | NXP  Product Description 2 The PCA9410 and PCA9410A DC-to-DC converters are optimized for battery-powered applications. High efficiency of up to 94% enables an extended battery life in all portable designs.   Category Name 3: 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.   Category Name 4: Peripherals Product URL 1 PCA9955BTW | NXP  Product Description 1 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. Product link 2  PCF2129 | NXP  Product Description 2 The PCF2129 is a CMOS Real Time Clock (RTC) and calendar with an integrated Temperature Compensated Crystal (Xtal) Oscillator (TCXO) and a 32.768 kHz quartz crystal optimized for very high accuracy and very low power consumption.   Documentation Power Management for Kinetis:  https://www.nxp.com/docs/en/application-note/AN4503.pdf   Tools   Product Link TWR-KM34Z50M: Kinetis M Series Tower System Module TWR-KM34Z50M|Tower System Board|Kinetis MCUs | NXP  TEA1721BDB1065: TEA1721 universal mains white goods flyback SMPS demo board TEA1721 universal mains white goods flyback SMPS demo board | NXP  OM15020: JN5169 USB Dongle for ZigBee JN5169 USB Dongle for ZigBee | NXP 

Demo NXP has a full range of high power LDMOS drivers and finals for cellular base stations. Our cellular LDMOS portfolio delivers industry leading performance with powerful and efficient products targeting rapidly growing frequencies and regions in the world. This demo wall features new devices that cover all cellular bands from 575 to 2400 MHz Products A2V09H300-04N 48 V LDMOS Solution • Frequency 720-960 MHz • Final Doherty performance at 8 dB OBO • Gain 19.5 dB • Efficiency 53% • Peak power 56 dBm • OM-780-4 package A2V07/09H400-04N 48 V LDMOS Solution • Frequency 575–960 MHz • Final Doherty performance at 8 dB OBO o Gain 18 dB o Efficiency 53% • Peak power 57.5 dBm • OM-780-4 package A2V07/08/09H525-04N 48 V LDMOS Solution • Frequency 575–960 MHz • Final Doherty performance at 8 dB OBO o Gain 18.7 dB o Efficiency 53% • Peak power 58.5 dBm • OM-1230-4L package A2T23H200W23S 28 V LDMOS Solution • Frequency 2300–2400 MHz • Final Doherty performance at 8 dB OBO o Gain 15.5 dB o Efficiency 50% • Peak power 55 dBm • ACP-1230-4L2S package A3T18H360W23S 28 V LDMOS Solution • Frequency 1805–1880 MHz • Final Doherty performance at 8 dB OBO o Gain 17.5 dB o Efficiency 53% • Peak power 55.5 dBm • ACP-1230-4L2S package A3T21H450W23S 28 V LDMOS Solution • Frequency 2110-2200 MHz • Final Doherty performance at 8 dB OBO o Gain 15.5 dB o Efficiency 49.5% • Peak power 57.4 dBm • ACP-1230-4L2S package

Demo These state-of-the-art devices are single-chip solutions for contact, contactless, and NFC operation, and can be loaded with fully-custom applications. Optimized antenna operation and low-power modes enable best-in-class performance. This NFC & BLE hospitality demo showcases a physical access scenario in hospitality with ultimate contactless connectivity through NXP NFC and BLE solutions and superior security with MIFARE DESFire on cards, mobile and wearables Product Features • Total interoperability with smart devices – NFC/BLE • Ultimate contactless connectivity through NXP NFC and BLE solutions • Superior contactless experience and security with MIFARE DESFire on cards, mobile and wearables NXP Recommends PN746X_736X_SERIES|NXP  Ultra low power Bluetooth LE system-on-chip solutio|NXP 

This video shows a part of the LS1046A demonstration of capabilities in different high-demandant computing tasks.

Description With the development of new technologies in today’s world, the automotive industry is now capable of implementing new devices that allow drivers to have wider control of their automobiles. These devices could offer remote diagnostic services for vehicle monitoring, car security, GPS to optimize driving paths, and many other services. T-Box provides a remote communication interface for the vehicle as a wireless gateway. It can provide: Traffic data acquisition Travel track record Information and entertainment services such as navigation, news, weather and other information push Vehicle fault monitoring Vehicle remote control (open lock, air conditioning control, window control, transmitter torque limit, engine start and stop) Driving behavior analysis 4G wireless hotspot sharing and other services Features EMC controller support SDRAM CAN controller (from more than 2 CH to more than 3 CH) Small package (from LQFP to BGA) More I/O pins (more UART, SPI, I2C). Low power (GPIO wakeup and RTC wakeup) Cost effective Block Diagram Products Category Name 1: MCU Product URL 1 LPC1778FET208|Arm Cortex-M3|32-bit MCU | NXP  Product Description 1 The LPC1778FET208 is a low-power, cost-effective MCU featuring up to 512 KB Flash, 96 KB SRAM, 4 KB EEPROM and a wide assortment of connectivity peripherals, including up to five UARTs, three SPI/SSP, and three I²C. Product URL 2 LPC540XX Family of Microcontrollers (MCUs) | NXP  Product Description 2 The LPC54S016 offers power-efficiency and unique architecture, advanced HMI and flexible communication peripherals for real-time performance for the next-generation IoT. Category Name 2: Transceiver Product URL 1 TJA1041A | High-Speed CAN transceiver | NXP  Product Description 1 The TJA1041A is primarily intended for automotive high-speed CAN applications (up to 1 Mbit/s). Product URL 2 TJA1043 | High Speed CAN transceiver | NXP  Product Description 2 The TJA1043 transceiver is designed for high-speed CAN applications in the automotive industry, providing differential transmit and receive capability to (a microcontroller with) a CAN protocol controller. Product URL 3 TJA1051 | High-speed CAN Transceiver | NXP  Product Description 3 The TJA1051 transceiver is designed for high-speed CAN applications in the automotive industry, providing differential transmit and receive capability to (a microcontroller with) a CAN protocol controller. Category Name 3: Peripherals Product URL 1 MC33972 | MSDI with Suppressed Wakeup | NXP  Product Description 1 The 33972 Multiple Switch Detection Interface (MSDI) with suppressed wake-up is designed to detect the closing and opening of up to 22 switch contacts. This device also features a 22-to-1 analog multiplexer for reading inputs as analog. Product URL 2 Tiny Real-Time Clock/calendar | NXP  Product Description 2 The PCF85063TP is a CMOS Real-Time Clock (RTC) and calendar optimized for low power consumption. An offset register allows fine-tuning of the clock. Product URL 3 ±2g/±4g/±8g, Low g, 14-Bit Accelerometer | NXP  Product Description 3 The FXLS8471Q accelerometer is highly versatile and ideal for industrial, consumer and automotive high-performance, low-g applications that offer noise density, board mount offset, temperature performance, and sensitivity. Product URL 4 High-speed CAN core system basis chip | NXP  Product Description 4 The UJA1076A supports the networking applications used to control power and sensor peripherals by using a high-speed CAN as the main network interface. Tools Product Link OM13001: EA LPC1788 Evaluation Board EA LPC1788 Evaluation Board | NXP  LPC54S018M-EVK: LPCXpresso54S018M Development Board LPCXpresso54S018M Development Board | NXP  OM11059A: Demoboard for the I²C RTC PCF85063TP and PCF85063ATL Demoboard for the I²C RTC PCF85063TP and PCF85063ATL | NXP  Sensor Toolbox Development Boards for FXLS8471Q 3-Axis Linear Accelerometer FXLS8471Q 3-Axis Accelerometer Development Boards | NXP 

NXP Thread Commissioning Demo with Arrayent’s Cloud Control Thread devices can be monitored and controlled from anywhere in the world using Arrayent Connect Cloud Devices are easily commissioned onto a Thread network using NXP Thread App & QR code Devices are secure using Arrayent Unique ID (whitelisting) and AES-128 bit encryption. This Demo Is Probably of Interest If You: Want to monitor and control Thread devices that sit behind a consumer grade firewall from anywhere in the world. Want to commission Thread devices in a easy way. Differentiation This Demo Highlights Control and monitor Thread devices that sit behind a consumer grade firewall from anywhere in the world. Commission Thread devices using QR code Description The Thread network is managed by a LS1021A  IT Gateway with FRDM-KW24 Thread Border border reference design. The board supports Thread, Wi-Fi, BlueTooth and NFC too. NXP’s Thread commissioning android App discovers the Thread border router. NXP powered Thread “device” is a card with a NXP Kinetis® KW2xD 802.15.4 Wireless chip with an ARM Cortex M4 MCU board running the Thread protocol and the lightweight Arrayent Connect Agent. The Thread device boards are commissioned (or “paired”) on to the Thread network by using the NXP Thread commissioning Android App takes the device’s unique ID from the  QR code on the  device and pushes Thread network credentials into the device. This is shown again with a second card. Arrayent’s Connect Agent has been pre-loaded into the device boards.  And once the board is connected to the Thread network, the device board starts communicates directly to the Arrayent Cloud. Essentially key attributes on the board are presented up to the Arrayent Connect Cloud web services APIs. The final step is to use the Arrayent devkit app to monitor and control the device board from anywhere in the world.  In this case the we can demonstrate three monitor/control use cases: 1.     Turn on and off the device LED from the mobile app. 2.     Press a button three times to update the Apps button press counter (in this case three times.) 3.     Push the board temperature to the mobile app. What this Demo is All About Video Link : 5310 Find more information Press release: Read on The Business Journals Blog posts to read: NXP and Arrayent Collaborate to Connect Thread Devices at Embedded World, Nuremberg, Germany Thread-Enabled Smart Home Powered by Arrayent Demo Diagram IoT Physical Components Gateways SOC: NXP i.MX6 Applications Processor, NXP Kinetis®KW24D SoC Software: Embedded Linux, NXP Thread Stack for border router End User Products: LS1021A IT Gateway with FRDM-KW24 Thread Border border reference design Edge Devices SOC: NXP Kinetis®KW24D (802.15.4 Wireless chip with an ARM Cortex M4 MCU) Boards/Modules: NXP FRDM-KW24D  Development Board Software: Arrayent Connect Agent ported to the KW2xD, NXP Thread Stack for router end devices Wireless Connectivity SOC: NXP Kinetis®KW24D (802.15.4 Wireless chip with an ARM Cortex M4 MCU) Sensors SOC: KW24D On-chip Temperature, MMA8451Q 3-axis accelerometer Cloud Infrastructure/Services Software/Services: Arrayent Connect Cloud Smart Devices/Apps Software: Arrayent Android DevKit sample app and SDK Software: NXP Android Thread provisioning app IoT System Capabilities Device Management Each device is flashed at time of manufacturing a unique Arrayent Device ID and AES key.  The device ID is bound to a specific customer account at time of device commissioning. Cloud/App Communications/Interworking Arrayent devkit app talks to the Arrayent Connect Cloud’s device services interface through the Arrayent Connect Agent embedded software to connect to the device boards. The App is used to monitor and control the device board from anywhere in the world.  In this case the we can demonstrate three monitor/control use cases: Turn on and off the device LED from the mobile app. Press a button three times to update the Apps button press counter (in this case three times.) Push the board temperature to the mobile app. Security Arrayent uses device ID Whitelisting, that is Arrayent issued device ID is flashed into endpoint MCU memory at time of manufacturing.  The per device unique ID is reserved in the cloud. Arrayent ACA embedded agent and ACC cloud services support AES-128 bit end-to-end encryption with dynamic temporal key refresh. Analytics/Data The Arrayent Connect Cloud support IoT Product Type Product/Component Vendor Research or Procure This Product/Component End User Hardware USB Wireless Keyboard and Touchpad Commercial Logitech Wireless Touch Keyboard K400 with Built-in Multi-Touch Touchpad, Black End User Hardware Dell 22" HDMI Monitor Commercial Dell 22" Monitor End User Smart Device Motorola XT1032 Moto G Android Smart Phone Commercial Motorola Android Smart Phone End User Edge Device Xfinity XR2 Remote Control Unit Commercial Comcast Remote Control End User Edge Device Philips HUE Bulb ZigBee Lightlink (HA 1.2) Commercial Hue, Professional Wireless LED Lighting | Philips Lighting End User Edge Device CentraLite 3-Series Appliance Module (4257050-RZHAC) (Zigbee HA 1.2) Commercial SmartPlug End User Edge Device Axis 0301004 M1011-W camera (WiFi g) Commercial AXIS M1011-W Network Camera, a small wireless IP camera | Axis Communications End User Edge Device Maxxima Style Night Light w/ sensor Commercial Night Light End User Edge Device TP-LINK TL-MR3020 3G/4G Wireless N 150 Portable Router Commercial WiFi Router

The attached document describes how to optimize LCD display performance on RT10xx platform. The content include RT10xx configuration and Emwin setting with LCD parameters. Products Product Category NXP Part Number URL MCU i.MX RT1060 i.MX RT1060 MCU/Applications Crossover MCU | Arm® Cortex®-M7, 1MB SRAM | NXP  MCU i.MX RT1050 i.MX RT1050 MCU/Applications Crossover MCU| Arm® Cortex-M7, 512KB SRAM | NXP  SDK Software Software Development Kit https://mcuxpresso.nxp.com/en/select    Tools NXP Development Board URL MIMXRT1060-EVK i.MX RT1060 Evaluation Kit | NXP  MIMXRT1050-EVK i.MX RT1050 Evaluation Kit | NXP  Was this helpful to you?

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

Introduction The FRWY LS1046A comes with the mikroBUS connector that enables the capability to connect different peripheral depending on the application's requirements. The mikroBUS intends to be used for prototyping purposes that facilitate the interconnection of several peripherals. The PN7120 I2C connection delivers a secure and trustworthy connection between both NXP products. Overview The following demo belongs to examples of different usages of the LS1046A MPU, these demonstrations will soon be part of the LSDK. This document showcase the NFC capability to provide an additional layer of security to any access area. NFC access points authorize people with a registered RFID tag to grant access to a particular area. In case the RFID tag isn’t registered or authorized, the access is restricted. The system should alert the denied access to a supervisor in order to take action. The video below shows two NFC applications that can be implemented in the LS1046A, by connecting the Mikroe-2395 module based on the NXP PN7120. This demonstration allows registering new users by entering sensitive data into a local database. The second application validates an NFC tag by comparing the tag ID, with the ones previously registered in the database. The user can access the applications using the LAN with another device like a tablet, this allows the database to be in a non-easy access location for security purposes. Block Diagram Video Products NXP Product Link FRWY LS1046A TP https://www.nxp.com/design/qoriq-developer-resources/ls1046a-freeway-board:FRWY-LS1046A Mikroe-2395 https://www.mikroe.com/nfc-click NXP NTAG 213/215/216 https://www.nxp.com/products/rfid-nfc/nfc-hf/ntag/ntag-for-tags-labels/ntag-213-215-216-nfc-forum-type-2-tag-compliant-ic-with-144-504-888-bytes-user-memory:NTAG213_215_216

Overview This reference design is based on 32-bit DSC MC56F84789, to demo a 3in1 Air-Conditioner Outdoor Unit. This reference design jump-starts your ability to leverage the NXP ®  DSCs' advanced feature sets via complete software, tools and hardware platform. High performance, low cost all DC VF air-conditioner outdoor unit control system Three control objectives (interleaved single-phase PFC converter, fan and compressor) with one MCU device Input voltage range of 85 – 265VAC/40 – 70H Single-phase two channels interleaved PFC converter compatible with global mains input, 99.9% power factor, 8% input current THDi Sensorless FOC algorithm for both compressor and fan Anti-typhoon startup for fan, and on-line load torque compensation control for compressor to reduce system vibration and noise Reliable startup performance under full load and input voltage range Extreme low/high speed (from 1Hz to 150Hz) performance with extended flux observer Over-/under-voltage, over-current, over-temperature, over-input power protection and lock of rotor detection FreeMASTER GUI for easy debugging Features MC56F84789 3in1 Air-Conditioner Outdoor Unit Block Diagram Board Design Resources

Description Application demo uses a model trained off the MNIST dataset to recognize individual handwritten digits written on the touch sensitive LCD screen. Thie model conversion can be found here: https://community.nxp.com/docs/DOC-344227. Software The RT1060 SDK should already be installed in MCUXpresso IDE. Drag-and-drop the .zip file into the Project Explorer view, and then compile and flash. NXP Products Link i.MX RT1060 Evaluation Kit i.MX RT1060 Evaluation Kit | NXP  4.3" LCD Panel 4.3" LCD Panel RK043FN02H-CT | NXP 

Overview NXP brings a broad portfolio of proven PowerQUICC ®  network communications products, firmware and reference designs that support multiple network interfaces. These reference designs have the flexibility to integrate new features and are adaptable across product lines to protect your investment and maintain an edge over the competition. The NXP ®  MPC8323E-RDB is a turnkey hardware/software reference platform designed to rapidly provide the core elements of tomorrow's multiservice gateway products. Built on Power Architecture technology, the MPC8323E-RDB leverages the processing power of the MPC8323E PowerQUICC II Pro integrated communications processor. Features MPC8323E Integrated Multiservice Gateway features: Flexible WAN interfaces RJ45 100BT Ethernet and connectors for ADSL2+/VDSL2, WiMAX IPv4 Router with VPN capability RJ45 100BT Ethernet and connectors for ADSL2+/VDSL2, WiMAX Up to 640 DMIPS e300 CPU QUICC Engine ®  technology acceleration, 200 MHz Bridging/Routing with NAP/NAPT Firewall support (ACL) QoS for IPTV, VoIP and high-speed data VPN termination and pass-through Board Interfaces: Flexible network interfaces 10/100 Ethernet ADSL2+/VDSL2 WiMAX FXS ports (2) for analog phones 4-port 10/100 Ethernet LAN Two USB 2.0 host (480 Mbps) type A MiniPCI slots (2) Development Environment Our well established vertical ecosystem provides customers with the exact development flow they desire. The MPC8323E-RDB is kitted with: Encased CPE form factor board Linux ®  2.6 (LTIB) Design Resources