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

In some use case, when user program size>128K，it will display verify error when download, and the user code can’t run normally. Especially the second time download in IAR, after user modify the FlexRAM allocation. The root cause is IAR default Flash Loader use all the default 128K OCRAM as the download buffer in .ICF, if user changed the FlexRAM allocation in user code, for example: setting OCRAM to 32K, it will lead to error as there is no 128K buffer size, this demo code is used to fix it.

Demo This development board for RF power products is now available from Richardson, one of NXPs distributors Demo / product features This next generation board provides RF design engineers with best efficiency, a range of frequencies and voltage. Richardson has a combined depth of real-world RF technical experience and a solid partnership with NXP that enables us to serve the unique needs of the RF design engineer. Richardson and NXP serve customers across a similar set of vertical markets, including aerospace and defense, military, wireless infrastructure, mobile, broadcast and ISM. Links RF | NXP Richardson RFPD - NXP Semiconductors

Demo How to configure, validate and optimize DDR controller configuration for a QorIQ LS2080A device How to validate the SerDes controller lanes [configured in digital loopback mode] configurations for a QorIQ LS2085A device How to generate a PBL binary ready to be flashed to target for a QorIQ LS device     Features: Configuration and validation of SoC elements [DDR, SerDes, PBL] from QorIQ LS devices with a few mouse clicks _______________________________________________________________________________________________________   Featured NXP Products: QorIQ DDR configuration & QCVS tool|NXP RCW Override for Use in QorIQ Debugge|NXP Configure QorIQ DDR in 3 minutes|NXP _______________________________________________________________________________________________________   N02

This demo will provide three modes to show the CAPWAP offloading capability of QorIQ platform. mode Iis the core-through mode which can be implemented by the CAPWAP stack to send the CAPWAP stack packets; Mode II is the offloading-mode which demonstrates the CAPWAP Encapsulation/De-capsulation capability of the SoC, and can be used in the AC case; Mode III is the net-bridge mode which is the basic usage for EAP which bridge the packets from PCIE to SEC and FM for offloading CAPWAP manipulation, the bridge is zero-memory copy in order to get high performance data. Together with the throughput data, this demo will help the customer to evaluate the EAP design with QorIQ platform.   Features QorIQ T1 processors handle secure WLAN tunnels with offload engines instead of CPU cycles CAPWAP tunneling firmware performs extra tasks (frag/ reassembly) and interfaces to the Linux user Highly efficient bridging to WLAN radios ensures maximum WLAN performance CAPWAP fragmentation and reassembly Featured NXP  Products T1040 Block Diagram

Flomio was able to take our SLN-POS-RDR and develop their first EASyPOS prototype in 2 short months! What is an EASyPOS? EASyPOS is an item level point of sale. A light weight terminal that connects wirelessly to the payment network to securely process transactions and unlock from products for consumers to take. EASyPOS is the first of it’s kind and though placing a POS on every item may seem impractical, it offers several advantages. For one the device is able to monitor it’s location with a high degree of accuracy, guiding shoppers directly to the products they seek and consistently delivering positive purchase experiences. Also, inventory accuracy is all but guaranteed so omnichannel commerce and other popular retail trends are supported. Finally, EASyPOS has lights and sound alerts to enable smart filtering and encourage impulse buys.     How do I use it? Using the EASyPOS is —in fact— “easy”. Follow these steps to complete your purchase: - Grab the product you want to purchase.  - Place your Contactless Payment credential on the surface of the contactless payment logo and wait for 4 LEDs to blink green. EASyPOS is now disarmed. - Slide apart the magnetic halves and remove your from your purchase.     How is it built? The EASyPOS was built by Flomio, an expert in mobile NFC device design. It operates at very low power while actively monitoring for payment engagements, remote notifications, tamper attacks, and location changes throughout the retail environment. Smaller than a deck of cards, the EASyPOS is a payments certifiable device leverages the hardened security and miniaturization advances of NXP Semiconductors. It’s split in two assemblies, the top hosting active components like the freakishly loud 90dB speaker and the bottom containing the wireless recharging power system.   Short Video: https://www.youtube.com/watch?v=FQrnTWPpRHE About Flomio, Inc. Disney’s Magic Band™ technology revolutionized their theme park business. Companies eager to “Disney-fy” their businesses without their own team of imagineers and billions to invest turn to Flomio, imagineers for the rest of us. Flomio creates proximity ID solutions that help enterprise clients and developers cross the chasm to the next web, the Internet of Things (IoT). Funded by TechStars, Flomio is fundamentally changing the way people engage with the spaces around them by making proximity ID simple to integrate, easy to deploy, and fun to use. Soon, 50 billion devices will regularly connect to the internet. Flomio’s platform empowers enterprise customers and developers to create applications that communicate with these devices. The future is ubiquitous connectivity. Flomio makes sure businesses take advantage of it.

Explore MC06XSD200, MC10XSD200, MC16XSD200 and MC50XS4200 eXtreme switch products that are showcased using the Tower System for industrial lighting and motor applications. NXP's family of intelligent, dual high side eXtreme switches for 36 V systems offers devices with current capability ranging from one to 12 A DC that are fully compatible in footprint and software within the PQFN sub family. Each output can be programmed to be used for any kind of loads, including lamps, LEDs, motors or solenoids. This allows customers to design a flexible module which can become specific and optimized for a given application through software. NXP's 36 V eXtreme switch solution provides robust design, intelligence and safety needed for industrial applications up to 36 V supply voltage. With increased integration, the switch drives lighter-weight, smaller systems and a lower component count.       Features Up to 12 A steady-state current per channel Separate bulb and DC motor latched over-current handling Sleep mode with minimal supply current (< 10 µA @ 24 V) Individually programmable internal/external PWM clock signals Overcurrent, short-circuit, and overtemperature protection with programmable auto-retry functions Accurate temperature and current sensing Open-load detection (channel in OFF and ON state), also for LED applications (7.0 mA typ.) Normal operating range: 8.0 - 36 V, extended range: 6.0 - 58 V 3.3 V and 5.0 V compatible 16-bit SPI port for device control, configuration, and diagnostics at rates up to 8.0 MHz Compatible PCB foot print and SPI software driver among the family These products are included in NXP's Product Longevity Program with assured supply for a minimum of 15 years after launch Featured NXP Products MC06XSD200: MC06XSD200, Dual 6.0 mOhm High Side Switch - Data Sheet MC10XSD200: MC10XSD200, Dual 10 mOhm High Side Switch - Data Sheet MC16XSD200: MC16XSD200, Dual 16 mOhm High Side Switch - Data Sheet MC50XS4200  

本文说明如何检查S32DS Flash Tool的默认波特率，以便确认下载相关的失败问题，以及如何解决。 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... 4 2    S32G波特率设置说明... 4 3    检查FlashTool Target image的默认波特率... 6 3.1  运行FlashTool下载Target image. 6 3.2  连接lauterbach检查波特率相关配置... 6 4    G2的检查情况... 8 5    如何解决此问题... 9  

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

Demo NXP has a full range of high power LDMOS ICs for powering outdoor small cell base stations. Our small cell portfolio delivers industry leading performance with powerful, efficient and diverse range of outdoor small cells targeting rapidly growing frequencies and regions in the world. This demo features new devices that cover all cellular bands from 700 to 3800 MHz     Outdoor Small Cells for Cellular Infrastructure - YouTube        Demo / product features A2I08H040N 9 W IC Final Small Cell Solution Frequency 728-960 MHz Gain 30.7 dB Efficiency 46% TO-270WB-15 plastic package   A2I20H060N 5 W IC Final Small Cell Solution Frequency 1800–2200 MHz Doherty performance at 8 dB OBO 1805-1880 MHz Gain 28.5 dB Efficiency 44% Peak 48.5 dBm TO-270WB-15 plastic package   A2I25H060N 5 W IC Final Small Cell Solution Frequency 2300–2690 MHz Doherty performance at 8 dB OBO 2496-2690 MHz Gain 27.5 dB Efficiency 41% Peak 48.2 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 33% Peak 48 dBm TO-270WB-17 plastic package   A2I25D025N 5 W IC Final Small Cell Solution Frequency 2100–2900 MHz Doherty performance at 8 dB OBO 2400-2600 MHz Gain 29.1 dB Efficiency 40% Peak 45.8 dBm TO-270WB-15 plastic package   A2I25D012N 2.2 W IC Final Small Cell Solution Frequency 2100-2900 MHz Gain 27.7 dB Efficiency 40% TO-270WB-15 plastic package   A2I20D040N 5 W IC Final Small Cell Solution Frequency 1400–2300 MHz Doherty performance at 8 dB OBO 1850-1950 MHz Gain 29.7 dB Efficiency 46% Peak 47.6 dBm TO-270WB-17 plastic package   A2I20D020N 2.5 W Final Small Cell Solution Frequency 1400-2300 MHz Gain 29.7 dB Efficiency 43% TO270WB-17 plastic package   NXP Recommends A2I08H040N A2I20H060N A2I25H060N A2I35H060N A2I25D025N A2I25D012N A2I20D040N A2I20D020N   Fast Track 5G with NXP   Fast-Track 5G with NXP - YouTube 

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 

Demo NXP demonstrates the industry’s highest power LDMOS narrowband transistor for IFF and civil transponders     Demo / product features MMRF2010N 250 W Pulse 50 V LDMOS Transistor 250 W Peak, 1030-1090 MHz reference circuit Plastic package TO-270WB-14 50 Ohm Input matching Singe ended   MMRF1317H 1500 W Pulse 50 V LDMOS Transistor Highest power narrowband IFF transistor for defense and civil use Ceramic package NI-1230H-4S 1500 W Peak, 1030-1090 MHz reference circuit > 10:1 VSWR   NXP Recommends MMG3005N MMRF2010N MMRF1317H                                                                                                                         

Description Near Field Communication (NFC) is used for real-time precision marketing based on time, local inventory and the individual when embedded in product displays or the products themselves. NFC is also becoming the preferred method for payment either in smartphones or smart payment cards. NXP secure MCUs and MPUs paired with our contact and contactless readers provide customers with state-of-the-art, comprehensive, pre-certified PCI and EMVCo payment acceptance capabilities that will ease the development process and speed time to market for payment solutions. SmartPOS will be the most important POS in the future. Customers can download authorized third-party software and connect to an acquiring system via cellular communication. It has both the security of traditional POS and the convenience of mPOS. Features Contact card interface (TDA8035) and contactless card interface (CLRC663) Supports the whole system to pass EMV Level 1/2 certification Magnetic Strip Card Reader (MSR) supports 1/2/3 tracker, which could be implemented by ADC module Tamper detection with more active pin pairs Integrated encryption module/accelerator High speed SPI interface to extend memory space Secure boot Code protection USB/UART/SPI communication ports, etc. Block Diagram Products Category Name 1 MCU and MPU Product URL 1 Arm Cortex-M4|Kinetis K21 120 MHz 32-bit USB MCUs | NXP  Product Description 1 The Kinetis K21 MCU features a hardware encryption coprocessor for secure data transfer and storage. Faster than software implementations and with minimal CPU loading. Supports a wide variety of algorithms - DES, 3DES, AES, MD5, SHA-1, SHA-256 Product URL 2 i.MX RT1170 Crossover MCU Family - First Ghz MCU with Arm® Cortex®-M7 and Cortex-M4 Cores | NXP  Product Description 2 i.MX RT1170 includes NXP’s EdgeLock™ 4A security subsystem, including secure boot and crypto engines Category Name 2 Card Reader Product URL 1 High integrated and low power smart card interface | NXP  Product Description 1 The TDA8035 is the cost efficient successor of the established integrated contact smart card reader IC TDA8024. It offers a high level of security for the card by performing current limitation, short-circuit detection, ESD protection as well as supply supervision. Product URL 2 CLRC663 plus | High-performance multi-protocol NFC frontend | NXP  Product Description 2 The CLRC663 plus is a high-performance NFC Frontend with low-power consumption. Is the perfect choice for NFC applications with high-performance requirements like access control, payment, gaming. Category Name 3 RTC Product URL 1 PCF2129 | NXP  Product Description 1 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. Designs Products Links Linux Point of Sale (POS) Reader https://www.nxp.com/design/designs/linux-point-of-sale-pos-reader:SLN-POS-LRDR 

See a "routing on a chip" solution on the QorIQ Processor T1040 QDS with Layer 2 switching, including Layer 2 and Layer 3 processing through the L2 switch and FMan, and detailing drivers and stacks support.       Features Integrated switching (LAN, WAN, WLAN) Firewall support with HW offload DMZ partition using NXP Embedded Hypervisor Remote administration   Featured NXP Products T1040: QorIQ T Series Quad- and Dual-Core Communications Processors

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

Demo The i.MX 6UltraLite SABRE CPU boards and base boards, powered by the ultra-efficient ARM Cortex-A7 core, showcase the i.MX 6UltraLite running the Linux OS with low run-current and simple power supply circuit.SABRE CPU and base board running Linux OS   SABRE CPU and base board running Linux OS Low run-current and simple power supply circuit Attached EVM card demonstrates the payment card interface compatibility Featured NXP Product i.MX 6UltraLite Applications Processor|NXP i.MX Applications Processors|ARM® Cores|NXP   Other

  Features Packet Tools Software gives you insight you normally only get from sophisticated test equipment. Packet Tools uses the on-chip debug and trace capabilities of the QorIQ Processors to give you unprecedented insights into your system. This is the same insight you'll use to create real differentiation in your products. This video gives you a VERY quick overview of the Packet Tools so you can get a great idea of what the software is all about.   Featured NXP Products Processor Expert QorIQ Optimization Suite Processor Expert QorIQ Packet Analysis Tool

Demo Owner: Andrew Patterson Mentor Graphics' Andrew Patterson demonstrates AUTOSAR and vehicle network design using Mentor Embedded design tools and run-time software on MCUs. Also showcased is combining infotainment and instrument cluster solutions on i.MX 6 series applications processors.     https://community.nxp.com/players.brightcove.net/4089003392001/default_default/index.html?videoId=4282653864001" style="color: #05afc3; background-color: #ffffff; font-size: 14.4px;" target="_blankFeatures Showcasing the setup of a typical car entertainment system Android Jelly Bean OS on an i.MX6 with Wi-Fi enable It can behave as an access point so other smart devices can connect or as a client and reach out to external networks Instrument cluster display running Linux clients with various applications that can connect to the car Featured NXP Products ARM® Cortex®-A9 Cores: i.MX 6 Series Multicore Processors Links NXP Connect - Mentor Graphics  

Demo Kinetis V series iIs supported broadly with 3 main hardware development platforms that target different customer and application needs.   Features: Freedom Platform: Freedom solutions typically target cost sensitive customers with a lower level of integration and flexibility included in the system, a low voltage solution operating at less than 50V.   Customers who are highly cost sensitive can start development with just the FRDM board, but for those customer who want to get the motor turning quickly we provide all the system components necessary to create a complete reference design that will get the motor running out of the box.   Kinetis Motor Suite supports Sinusoidal control technique (also known as FOC, field oriented control) with the FRDM-MC-LVPMSM, which can also be operated with and without a sensor to improve position control accuracy or startup capability. FRDM-MC-LVPMSM Board spec: 24V, 5Amp, 120W   The customer should purchase MCU FRDM card along with the FRDM-MC-LVPMSM to build their reference design. The motor must be purchased separately under FRDM-MC-LVMTR part number , or they can use their own motor if it meets the Motor Driver card power specification. FRDM-MC-LVMTR spec: 4000RPM, 24V, 40W   Tower Platform: The Tower Platform allows customers to very quickly turn their application motor straight out the box, and target customers who need more connectivity in their system, and access to more of the MCU pins.   To build the system the customer should purchase the appropriate TWR MCU card, the TWR-ELEV to connect to the TWR-MC-LV3PH driver card. This kit ships with the motor and power supply.   Board Spec: Voltage: 12-24/50V Output: 8Amp, 400W Over current & under voltage protection, encoder/hall sensor sensing circuitry Supported architectures: 3-phase BLDC & PMSM   High Voltage Platform: The High Voltage Platform allows customers to very quickly spin their high voltage end application motor straight out the box. The High voltage platforms targets customers with motors rated at above 50V but less than 240V.   Customer should purchase the HVP-MC3PH kit along with the appropriate MCU Controller card to build the reference design. The HVP-MC3PH includes the HVP-KV46F150M controller card in the box.   Board Spec: 115/230 volt, 1KW 3-ph motor control development platform for BLDC, PMSM  >1Hp. Main board with inverter & PFC circuitry supports plug-in controller cards for Kinetis KV1x/KV3x/KV4x MCUs Voltage: 85 to 240V The customer must supply their own high voltage motor to complete the system. ________________________________________________________________________________________________________________________ Featured NXP Products: Hardware: ARM Cortex-M0+/M4/M7 Cores|Kinetis V MCUs|NXP FRDM-KV31F|Freedom Development Platform|Kinetis MCU|NXP FRDM-KV10Z|Freedom Development Platform|Kinetis MCU|NXP FRDM-MC-LVPMSM|Freedom Development Platform|NXP FRDM-MC-LVBLDC|Freedom Development Platform|NXP FRDM-MC-LVMTR|Freedom Development Platform|NXP High-Voltage Development Platform|NXP Low-Voltage, 3-Phase Motor Control Tower System Mod|NXP   Software: KINETIS MOTOR SUITE: Simple motor control developme|NXP Motor Control Development Toolbox|NXP Kinetis Designs|NXP ARM Cortex-M0+/M4/M7 Cores|Kinetis V MCUs|NXP 3-Phase AC Induction Motor Control Design|NXP 3-Phase PMSM Motor Control Reference Design|NXP 3-Phase Brushless DC Motor Control Design|NXP

Demo Features IoT Gateway based on phyCORE-i.MX7 phyBOARD-Zeta   NXP Recommends i.MX 7 Series Applications Processors: Multicore, ARM® Cortex®-A7 Core, ARM Cortex-M4 Core   Other Links system-on-module-i.mx7   C23D