What is an IoT Gateway? An IoT Gateway is essential part of a Trust enabled, power-efficient IoT deployment in buildings, homes, street and industrial sites. The low-power foot-print is achieved by having low-power, low-cost sensor nodes connecting over low-power, shorter range radio networks. The IoT Gateway bridges between these wireless sensor networks and the enterprise or carrier networks.   Furthermore, the IoT gateway also provides a platform for local data filtering and decision making. This is context aware computing. In near future, the cost of processing data will be less than the cost of moving data across a network and less than the cost of data storage. It makes sense to distribute the intelligence and process/filer data close to the data source. In this session, one of the first public demo’s of LS1021A, NXP will demonstrate an ready-to-use IoT gateway platform together with sensor and cloud connectivity. Value Propositions    Coupling IoT to SDN and Big Data. LS10121A IoT Gateway   Customer-premise IoT Gateways – Industrial, Enterprise, Home, Street-side     Distributed/Local Intelligence for real-time decision making and management (context aware computing)                                                                     High-availability, Trust Enabled networking, highly power efficient      NXP Recommends: Product Link LS1021A-IoT Gateway Reference Design LS1021A-IoT Gateway Reference Design | 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 4000 MHz Products http://www.nxp.com/products/rf/rf-power-transistors/rf-cellular-infrastructure/2300-2690-mhz/100-3600-mhz-3.2-w-avg.-28-v-airfast-rf-ldmos-wideband-integrated-amplifiers:A2I25D025N A2I25D025N 5 W IC Final Small Cell Solution • Frequency 2100–2900 MHz • Doherty performance at 8 dB OBO 2300-2700 MHz    Gain 29.2 dB    Efficiency 42%    Peak 46 dBm • TO-270WB-17 plastic package A2I20D040N 5 W IC Final Small Cell Solution • Frequency 1400–2300 MHz • Doherty performance at 8 dB OBO 1800-2200 MHz    Gain 29.2 dB    Efficiency 46.5%    Peak 47.6 dBm • TO-270WB-17 plastic package A2I35H060N 5 W IC Final Small Cell Solution • Frequency 3400–3800 MHz • Doherty performance at 8 dB OBO 3400-3600 MHz    Gain 24 dB    Efficiency 32%    Peak 48 dBm • TO-270WB-17 plastic package A3I35D025N 5 W IC Final Small Cell Solution • Frequency 3200–4000 MHz • Doherty performance at 8 dB OBO 3400-3600 MHz    Gain 25 dB    Efficiency 35%    Peak 42.8 dBm • TO-270WB-17 plastic package A2T08VD020N 48 V LDMOS Solution • Frequency 720–960 MHz • Class AB performance at 10 dB OBO    Gain 19.3 dB    Efficiency 21.5% • Peak power 43.4 dBm • PQFN 8x8 package A2I09VD030N 48 V LDMOS Solution • Frequency 575–960 MHz • Doherty performance at 10 dB OBO    Gain 34.4 dB    Efficiency 20% • Peak power 46 dBm • TO-270WB-15 package

Overview This application creates a vector control PMSM drive with optional speed closed-loop using a quadrature encoder, and serves as an example of a PMSM vector control system design based on the cost-effective 32-MIPS NXP® digital signal controller MC56F80XX. Dedicated algorithms such as transformations, PI controllers and space vector modulation, are implemented using NXP’s Motor Control Library This cost-effective and highly reliable solution minimizes system cost, as the algorithm implements a single shunt current sensing, reducing 3 current sensors to one The reference manual provides a detailed description of the application, including the design of the hardware and the software Features Designed to fit into consumer and industrial applications Uses 56F8013 or 56F8023 32 MIPS Digital Signal Controller Running on a 3-phase High Voltage Power Stage Vector control of PMSM using theQuadrature Encoder as a position sensor Control technique incorporates: Vector control with speed closed-loop with position encoder Rotation in both direction Start from any motor position with rotor alignment 4-quadrant operation Reconstruction of three-phase motor currents from DC-Bus shunt resistor Wide speed range FreeMASTER Control Interface Fault protection - overcurrent, overvoltage, undervoltage Block Diagram Board Design Resources

Overview The Occupancy Sensor Node reference design is a compact form factor, open source design. It enables low power nodes based on IEEE 802.15.4 protocols such as Thread and ZigBee to communicate data to a wireless sensor network. NXP supplements the Kinetis KW2xD with tools and software that include hardware evaluation and development boards, software development IDE and demo applications and drivers. Features MKW24D512 802.15.4 Kinetis MCU Full IEEE 802.15.4 compliant wireless node for Thread network Integrated PCB meander horizontal antenna 2 Interrupt push button switches (LLWU) 1 FXOS87000CQ Combo sensor 1 Coin cell battery holder 1 EEPROM 1 Battery charger Block Diagram Board Design Resources

Introduction Overview The following demo is part of a bundle of examples that shortly will be available in the LSDK. As can be seen in the video, there is a menu for the user to select the desired demo and start testing the different approaches the FRWY LS1046A TPU is capable of executing. These examples aim to demonstrate AI/ML capability through multiple “dockerized” demos including face recognition, Industrial safety & security -MPU and TPU versions-, People counter using the CPU and a pose detection demonstration. By using the native PCIe 3.0 of the LS1046A MPU, is possible to showcase the ML frameworks offload and acceleration via Coral Tensor Processing Unit. The below video shows one of the ML examples for pose detection of a person by using a simple USB camera plugged into the LS1046A FRWY board. Using the ML frameworks from Coral Tensor, the body movements and positions are detected by using the joints as the reference for movement detection of the body. As in the video is mentioned, the performance enhancement by using the TPU versus the CPU, improves significantly the frames per second from ~5 fps to ~30 fps. Block Diagram Video Products Product Link FRWY LS1046A TP LS1046A Freeway Board | NXP  Coral M.2 Accelerator M.2 Accelerator A+E key | Coral  HD Webcam https://www.amazon.com/gp/product/B07K95WFWM/ref=ppx_yo_dt_b_search_asin_title?ie=UTF8&psc=1

Overview This reference design describes a 3-phase sensorless brushless DC (BLDC) motor control with back-EMF (electromotive force) zero-crossing detection, supporting the NXP® 56F80X and 56F83XX Digital Signal Controllers (DSCs) for motor control applications. It can also be applied to Our 56F81XX DSCs The system is designed as a motor drive system 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 schematics 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 Hardware autodetection FreeMASTER control interface (speed set-up) FreeMASTER software remote monitor Block Diagram Board Design Resources

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

  JN-5189 SoC的多功能Timer外设支持Pulse Counter脉冲计数功能。可以参考附件文档实现这个功能。 Products Product Category NXP Part Number URL MCU JN5189 JN5189/88 (T): High Performance and Ultra-low power MCUs for Zigbee®   Tools NXP Development Board URL JN5189 Evaluation Kit for ZigBee and Thread mesh network with NFC Commissioning Advanced Development Kit for JN5189/88   SDK Development Software and ANs URL MCUXpresso SDK Software Welcome | MCUXpresso SDK Builder  Application Note Zigbee 3.0 IoT Control Bridge    

This video shows how to control the QN9080 PWM using NXP's Toolbox Android app via simple commands.

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

This video shows how to get GPS coordinates and send them to the internet by using the Sigfox OL2385 board

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

Description NXP’s enterprise storage server solution is focused on our new I²C Fast-mode Plus (Fm+) devices which go from zero to 1 MHz so you can go to the next design level with higher data rates and up to 540 pF bus loading. In computing, telecom and networking systems architecture the trend is for greater use of I²C-bus as a maintenance and control bus, so more bandwidth and more devices on the bus are required.   Block Diagram Products Category Name 1: Microprocessor Product URL 1 QorIQ® Layerscape 1043A | NXP  Product Description 1 The QorIQ® LS1043A processor is NXP's first quad-core, 64-bit Arm®-based processor for embedded networking, it delivers greater than 10 Gbps of performance in a flexible I/O package supporting fanless designs. The new 0.9V LS1043A delivers additional power savings for applications such as Wireless LAN and to Power over Ethernet systems.   Category Name 2: I²C-bus Level Translator Product URL 1 PCA9509P | NXP  Product Description 1 The PCA9509P is a level translating I²C-bus/SMBus repeater with two voltage supplies that enable processor low voltage 2-wire serial bus to interface with standard I²C-bus or SMBus I/O. While retaining all the operating modes and features of the I²C-bus system during the level shifts, it also permits extension of the I²C-bus by providing bidirectional buffering for both lines. Product URL 2 PCA9617A | NXP  Product Description 2 The PCA9617A is an IC that provides level shifting between low voltage (0.8 V to 5.5 V) and higher voltage (2.2 V to 5.5 V) Fast-mode Plus (Fm+) I²C-bus or SMBus applications. The static offset design of the port B PCA9617A I/O drivers prevents them from being connected to the static or incremented offset of other bus buffers. Product URL 3 PCA9306 | NXP  Product Description 3 The PCA9306 is a dual bidirectional I²C-bus and SMBus voltage-level translator with an enable (EN) input, and is operational from 1.0 V to 3.6 V and 1.8 V to 5.5 V. The PCA9306 features a 2-bit bidirectional translator for SDA and SCL lines in mixed-mode I²C-bus applications and also provides bidirectional voltage translation with no direction pin.   Category Name 4: PCIe Switch Product URL 1 CBTL04083A; CBTL04083B | NXP  Product Description 1 The  CBTL04083A/B has minimized the impedance of the switch such that the attenuation observed through the switch is negligible, and also minimized the channel-to-channel skew as well as channel-to-channel crosstalk, as required by the high-speed serial interface.   Category Name 5: GTL Level Translator Product URL 1 4-bit LVTTL to GTL transceiver | NXP  Product Description 1 The GTL2014 is a 4-bit translating transceiver designed for 3.3 V LVTTL system interface with a GTL-/GTL/GTL+ bus, where GTL-/GTL/GTL+ refers to the reference voltage of the GTL bus and the input/output voltage thresholds associated with it.   Category Name 6: Memory Switch Product URL 1 CBTW28DD14 | NXP  Product Description 1 The CBTW28DD14 is a 14-bit bus switch/multiplexer (MUX) is designed for 1.5 V or 1.8 V supply voltage operation designed for operation in DDR2, DDR3 or DDR4 memory bus systems. The CBTW28DD14 uses NXP proprietary high-speed switch architecture providing high bandwidth, very little insertion loss at low frequency, and very low propagation delay, allowing use in many applications requiring switching or multiplexing of high-speed signals.   Category Name 7: I2C Mux Product URL 1 PCA9846 | NXP  Product Description 1 The PCA9846 is an ultra-low voltage, quad bidirectional translating switch controlled via the I²C-bus. The SCL/SDA upstream pair fans out to four downstream pairs, or channels. Any or all SCx/SDx channels can be selected, determined by the programmable control register.   Category Name 8: Load Switch Product URL 1 Logic controlled high-side power switch | NXP  Product Description 1 The NX5P2924 is a high-side load switch that features a low ON resistance N-channel MOSFET with a controlled slew rate that supports 2.5 A of continuous current.   Category Name 9: I2C Expander Product URL 1 PCAL6416A | NXP  Product Description 1 The PCAL6416A is a 16-bit general-purpose I/O expander that provides remote I/O expansion for most microcontroller families via the I2C-bus interface. The PCAL6416A has built-in level shifting feature that makes these devices extremely flexible in mixed-signal environments where communication between incompatible I/O voltages is required.   Category Name 10: Dip switch Product URL 1 PCA8550 | NXP  Product Description 1 The primary function of the 4-bit 2-to-1 I²C multiplexer is to select either a 4-bit input or data from a non-volatile register and drive this value onto the output pins.   Category Name 11: LED Dimmer Product URL 1 PCA9532 | NXP  Product Description 1 The PCA9532 is a 16-bit I²C-bus and SMBus I/O expander optimized for dimming LEDs in 256 discrete steps for Red/Green/Blue (RGB) color mixing and backlight applications.   Category Name 12: VGA Switch Product URL 1 Low power DisplayPort to VGA adapter with integrated 1 : 2 VGA switch | NXP  Product Description 1 PTN3355 is a DisplayPort to VGA adapter with an integrated 1: 2 VGA switch optimized primarily for motherboard applications, it also integrates a DisplayPort receiver. The PTN3355 supports I²C-bus over AUX per DisplayPort standard and bridges the VESA DDC channel to the DisplayPort Interface.   Category Name 13: LDC Driver Product URL 1 32 x 4 automotive LCD driver for low multiplex rates | NXP  Product Description 1 The PCA85162 is a peripheral device which interfaces to almost any Liquid Crystal Display (LCD) with low multiplex rates. It generates the drive signals for any static or multiplexed LCD containing up to four backplanes and up to 32 segments.       Category Name 14: UART Product URL 1 SC16IS740/750/760 | NXP  Product Description 1 The SC16IS740/750/760 is a slave I²C-bus/SPI interface to a single-channel high-performance UART. It offers data rates up to 5 Mbit/s and guarantees low operating and sleeping current.   Category Name 15: USB 3.0 Pre-Driver Product URL 1 SuperSpeed USB 3.0 redriver | NXP  Product Description 1 PTN36001 is a dual-channel USB 3.0 Pre-Driver that supports data signaling rate of 5 Gbit/s through each channel. The data flow of one channel is facing the USB host, and another channel is facing the USB peripheral or device. Related Documentation   Document URL Title https://www.nxp.com/webapp/Download?colCode=AN5226  AN5226, Common Board Design for LS1046A, LS1043A and LS1088A Processors https://www.nxp.com/docs/en/application-note/AN5125.pdf AN5125, Introduction to Device Trees https://www.nxp.com/webapp/Download?colCode=AN4311 SerDes Reference Clock Interfacing and HSSI Measurements Recommendations https://www.nxp.com/webapp/Download?colCode=AN5097  Hardware and Layout Design Considerations for DDR4 SDRAM Memory Interfaces Tools   Tools URL QorIQ® LS1043A Development Board | NXP  Training Training URL NET-N1886 Tips for Silicon Bring-Up of QorIQ LS1043A Processor  APF-DES-T1853 - QorIQ LS1043A Application Solution Kit (IoT, NAS, RGW)  LS1012A, LS1043A and LS1046A Design Cycle using N…  APF-DES-T1853 - QorIQ LS1043A Application Solution Kit (IoT, NAS, RGW)  Related Demos from Communities Related Demos URL QorIQ Processing Platforms  Layerscape  IoT Solutions Platform based on LS1043 

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 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

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%

Today, mobile network operators make it easy to get your own Smart Home Kit. The complexity often comes with the first setup of devices that are as diverse as the standards in which they operate. NFC promises to make this process as easy as tap and connect. The inforgraphic gives 5 reasons to equip smart homes with NFC, plus benefits for the ecosystem.

Demo   The i.MX 7 series is a highly integrated multi-market applications processor designed to enable secure and portable applications within the Internet of Things. The i.MX 7 series is the first device in the market utilizing both the ARM ® Cortex ® -A7 and Cortex-M4 cores for general purpose programmable processing. Its heterogeneous asymmetric architecture provides the ultimate flexibility for customers by enabling a single-chip solution that can run sophisticated operating systems and provide real-time responsiveness. The i.MX 7 series incorporates four independently controlled resource domains for maximum effectiveness and security when partitioning system resources such as memory and peripherals.   Demo / Product Features Advanced Heterogeneous Architecture Up to Dual Cortex-A7 @ 1GHz Cortex-M4 @ 200MHz Unmatched Power Efficiency for Active and Low Power modes Complete Security Infrastructure Secure Boot Crypto H/W Acceleration Internal and External Tamper Detection Enabling Flexible High Speed Connectivity PCI-e v2.1 Dual Gbit Ethernet  with AVB DDR QuadSPI support eMMC 5.0   NXP recommends the following links for additional information i.MX 7 Series Applications Processors: Multicore, ARM® Cortex®-A7 Core, ARM Cortex-M4 Core     C23

    Features QorIQ Processing Platforms BSC9131 SoC based LTE small cell Zero intrusion by fitting in a lamppost’s existing photocell socket Avoids costly site acquisition and lengthy planning procedures Backhaul agnostic – Fiber, copper, PoE wireless P2P Trust architecture provides secure computing environment Block Diagram