Demo NXP’s Smart Defrost Solution is the newest way to defrost food. From frozen solid to sliceable food in minutes. Our solution uses RF and a smart tuning unit to evenly defrost food. The NXP Smart Defrost reference design consists of the following:    Defrost Appliance Concept                              Smart Defrost Reference Design Block Diagram Reference Design Features • RF creates the energy used to raise food temperature • Smart Tuning Unit intelligently adjusts operation for properties of the food within the defrost chamber • Electrodes provide the delivery of energy into the defrost cavity • Defrost cavity is a shielded, enclosed space for defrosting frozen food • Host control for main appliance control and user input interface Benefits • Reduced time-to-market • Simple integration into system • Predictable repeatable results • Creates even defrost environment • Reliable • Cost-effective interconnection • Minimum software needed for control Links https://www.nxp.com/pages/defrosting:RF-DEFROSTING-PG   Fact Sheets https://www.nxp.com/docs/en/fact-sheet/SmartDefrostRDFS.pdf  https://www.nxp.com/docs/en/fact-sheet/SDS31300FS.pdf

Demo Need to increase the power of your system? Check out our MRFX1K80H design reuse video to see the benefits of 65 V technology in action. In this video, Danny Molezion, FAE from Richardson RFPD and Jim Davies, NXP Applications Engineer swap out NXP’s 1250 W device with the MRFX1K80H device using the same PCB. Product www.nxp.com/65V www.nxp.com/MRFX1K80H   Links http://www.richardsonrfpd.com/NXP65V Press Release|NXP 

Demo NXP, the number one supplier of high power RF power transistors, has a new 5G cellular base station concept alongside many other innovative cellular infrastructure solutions and technologies that is being shown at industry events. Product innovations from NXP are in the areas of 5G, from Gigabit LTE leading up to 5G using GaN and silicon LDMOS for macro and small cell base stations. Learn more about the steps that NXP is taking toward enabling the 5G wave Features Smaller footprint to reduce installation costs Network infrastructure evolution Active antenna rise Power consumption Multiple standards to support with 3G, 4G to 5G Link  5G Infrastructure|NXP 

Demo i.MX RT1050 from NXP showing three different Storyboard Suite demo applications; Washing Machine, Home Automation and Medical demos. Based on the Arm ®  Cortex ® -M7, the i.MX RT series bridges the gap between the performance of applications processors and the usability of MCUs, without compromising low-power or low cost. Video Overview (Click here) NXP Products Product Link i.MX RT1050 Evaluation Kit i.MX RT1050 Evaluation Kit | NXP  4.3" LCD Panel 4.3" LCD Panel RK043FN02H-CT | NXP 

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

This post entry provides a detailed description of how a Bluetooth Low Energy (BLE) pairing solution via NFC was developed using two of our reference development boards: The NTAG I 2 C plus kit for Arduino pinout The Freedom KW41Z board. This document has been structured as follows: NFC for easy one-tap pairing solution NFC pairing is one popular feature you can find in cameras, speakers, printer, routers, wearables and many more. Just bringing two NFC-enabled devices close together is all it takes to create a connection. Just to mention a few of examples, with just a swipe you can: Connect your phone to a wireless speaker. Connect your new devices to the home network. Connect accessories to the control unit. In all these scenarios… NFC and Bluetooth are a perfect combination, since the pairing process with NFC becomes: Faster compared to the traditional pairing methods. Easier, reducing technical support More reliable, making sure you connect to the right device. The technical basis for this “tap to connect” process is provided in the NFC Connection Handover specification running atop the NFC Forum protocol stack. It defines a framework of messages and data containers that allow bootstrapping of alternative (i.e., other than NFC) carrier connections in a standardized way. For this reason, NFC pairing solution offers a unified user experience and interoperability across different manufacturers.  NFC solutions to implement secure simple pairing There are two types of solutions recommended to add NFC pairing functionality to designs: NFC static pairing with NTAG 213 The first solution is embedding an NTAG 213 NFC label. In such a case, the pairing credentials need to be previously loaded in to the tag memory as well as in the device MCU during manufacturing. NFC dynamic pairing with NTAG I2C plus The second solution is embedding an NTAG I 2 C plus tag. In such a case, the pairing credentials can be dynamically updated by the device MCU during the product lifetime. In addition, other features such as an automatic wake-up field detection signal are possible. Precisely, the combination of a passive NFC interface with a contact I2C interface allows the product to behave as a tag and be read via NFC and to connect to a host or application processor via  I 2 C. In addition, NDEF messages can be generated and updated by the host MCU depending on the application requirements. Later, these NDEF messages can be read by any NFC phone, including iOS devices with the latest OS version. Hardware setup Mapping the previous diagram to the demo hardware, we have: The NTAG I 2 C plus tag, using the Arduino pinout kit The MCU, using Kinetis KW41Z. The applicatiob logic, which updates the NDEF contents based on different use cases. Some details about the hardware used in the next sections: Kinetis KW41Z The Kinetis KW41Z is a high integrated chip with multi-protocol radio features enabling Bluetooth Low Energy (BLE) and 802.15.4 radio protocols such as Thread. KW41Z has as large memory of 512KB that can support multiple radio protocols running in a single application instace and implements nine low-power modes and a wide operating voltage range (0.9V/4.2V), for optimum current consumption. Finally, the software support package includes: BLE, Thread and 802.15.4 generic network stacks, several sample demo apps, support for RTOS and full integration in MCUXpresso. The Kinetis KW41Z evaluation is supported with the FRDM-KW41Z development board. The board main components are: a reference crystal, an accelerometer, an Arduino header, some LEDs and buttons, a JTAG and OpenSDA connectors,and an external flash memory. NTAG I2C plus kit for Arduino pinout The NTAG I 2 C plus Arduino kit consist of two PCBs stacked together: The upper PCB is the antenna board with the connected tag The lower PCB is an interface adaptor board to the Arduino pinout. This kit can be used to connect and evaluate the NTAG I 2 C plus  into many popular MCUs with Arduino compliant headers, for example:  Kinetis (e.g. KW41Z, i.MX (e.g. UDOO Neo, i.MX 6UL, i.MX 6 ULL, i.MX 7D) and LPC MCUs (e.g. LPCXpresso MAX, V2 and V3 boards). The kit support package includes several software examples, including the BT pairing example based on KW41Z.  The OM29110ARD is a generic interface board which offers support for connection to any PCB implementing Arduino connectors. It exposes: 3.3V and 5V power supply pins. I 2 C , SPI and UART host interfaces. Generic GPIOs (e.g. to be used for field detect, interrupts, reset pins or others) As such, it allows the NTAG I 2 C plus to be plugged into Arduino devices seamlessly. Once the NTAG I 2 C plus  board is stacked on the KW41Z, the pining routing between the two boards is as follows. It uses:  The  I 2 C  interface pins. The 3.3V supply pin. One GPIO is routed for the field detection pin. The Vout, for the energy harvesting pin. The ground reference. BLE pairing with NFC on KW41Z and NTAG I2C plus This section details how the Bluetooth Low Energy (BLE) pairing with NFC on KW41Z and NTAG I 2 C plus works. The following block diagram is a simplified representation of the demo that shows: The Bluetooth and NFC interfaces The buttons and LEDs involved in the process. Starting BLE advertising After SW4 is pressed: The application goes from IDLE to searching mode, advertising the BLE device The LED 3 starts blinking in RED color. Writing BLE pairing NDEF message Once the BLE advertising is activated, the next step is for the KW41 to write the pairing message into the NTAG I 2 C  plus memory. After SW3 is pressed: The KW41 uses the  I 2 C interface with the NTAG I 2 C plus to load a pre-defined NDEF message with the BLE pairing details. At the same time, the LED 4 is set to GREEN. Pairing with the BLE device While the LED 4 is set to green, the BLE pairing message is exposed through the NTAG I 2 C plus  RF interface. During this interval, any NFC-enabled device: Can read out the NDEF pairing message. Pass the BT credentials to the Android system or the host processor. And automatically create a Bluetooth link according to the exchanged network credentials. In case of an Android system, no third-party implementation is needed on this part as long as the pairing message follows the NFC Forum specifications. Writing default NDEF message Once the pairing information is read out of the NTAG I²C plus, the KW41Z removes the pairing content and turns back to normal operation mode. In addition, in this specific demo, the NDEF pairing message is programmed to remain in the NTAG I²C plus memory for only ten seconds. After these 10 seconds: The green LED is switched off. And the pairing NDEF message is overwritten by the default NDEF about the NTAG I²C plus demo app. Video The following video shows how the Bluetooth Low Energy (BLE) pairing with NFC on KW41Z and NTAG I 2 C plus works. How to integrate NTAG I2C plus into FRDM-KW41Z hid_device sample project In this section, we describe, step by step, how NFC is integrated in an existing default demo application taken from the KW41Z support package.   FRDM-KW41Z startup In the board website, there are very clear instructions on how to get started www.nxp.com/demoboard/FRDM-KW41Z. For instance: How to test KW41Z. How to get the tools, in our case: MCUXpresso, and the SDK for KW41Z. How to import, build and runn the examples included in the SDK for KW41Z, in our case: the ones inside the wireless_examples folder Importing FRDM-KW41Z SDK and hid_device sample project After that, we import the FRDM-KW41Z SDK and we import the sample project used as a basis for adding NTAG I 2 C plus support, this is the hid_device example located under the wireless/Bluetooth folder. Importing NTAG I2C plus middelware The NTAG I 2 C plus  middleware can be easily imported as a new folder in the project tree using the MCUXpresso File / Import menu. Once imported, the internal structure of the middleware should have this structure: HAL_I2C: The HAL_I2C files support access to the Kinetis I 2 C interface. HAL_ISR:  The HAL_ISR files support the interrupt handling and callback registration for the Kinetis MCU. HAL_NTAG: The HAL_NTAG source files provide an API that allow you to communicate with the NTAG chip and implements the NTAG command set to perform memory access operations from the I 2 C interface.  For instance, this API can be used to perform: Read / Write memory operations on EEPROM and SRAM (for example, to read data, you just need to indicate the memory address and length of the data to be read) Read / Write access to NTAG I 2 C plus registers (for example, you just need to indicate the register macro to be read). Functions for enabling the pass-through mode and handling the data exchange between interfaces (setting the data transfer direction is as easy as using this function). HAL_TMR: The HAL_TMR files support access to the timing hardware of the Kinetis MCU. Adding / changing GPIO pin settings All pin and GPIO settings are defined within the pin_mux.c file. For our application, the I 2 C pins need and a GPIO for the field detection need to be enabled.  Regarding the host interface: the I 2 C  pins for NTAG communication are configured using the BOARD_InitI2C() function, it sets the required I 2 C  port (port 0 for this MC) and set the right mode for the clock (SCL) and data (SDA) lines. Regarding the field detection: it is defined within the source code even though it is not used so far. It is left defined for future use. Within the pin_mux.c file, there are other functions which initialize; for instance, the buttons, LEDs, etc. These functions are called during the hardware initialization. NTAG I2C plus software and hardware initialization We move to the main_application, where some pieces of code need to be added. All code that has been added, is inside the #ifdef NTAG_I2C clause. First, we added: The I 2 C_driver and the ntag_app header files . The ntag_handle handler declaration. Then, the HW initialization is performed calling I2C_initDevice and the NFC_Initdevice() function is called to fill the  ntag_handle software handler. HID_device demo extensions The BLE demo application is written in the hid_device.c file and the whole behavior is handled in this file. The C-code printout in the blue box  below shows the content of the BleApp_HandleKeys() function, which handles the BLE activity and the changes made related to the NFC use case. Similarly, all new code additions are within the #ifdef NTAG_I2C clause. Mainly, the BleApp_HandleKeys() function function was extended to: Copy the pairing NDEF message to the NTAG I 2 C plus chip when the button SW3 is pressed. Set the LED 3 to green while the pairing NDEF message is available. Start a timer counter from the moment the SW3 button is pressed In addition, when the time counter is expired (expiration was defined to 10 seconds): The memory content of the NTAG I 2 C plus chip is overwritten by default NDEF message. The LED 3 is set to off. NDEF message for BLE pairing definition The last part missing to cover the NFC integration into the KW41Z refers to the files created within the application to declare the NDEF pairing and NDEF messages. The NFC Data Exchange Format (NDEF) is the NFC Forum specification defining an interoperable, common data format for information stored in NFC tags and NFC devices. The spec also details how to enable tags to deliver instructions to an NFC device so that the device will perform a specific action when a particular tag is read (open a browser, initiate a phone call, pairing, etc.). Every NDEF message can be automatically processed by any NFC device and execute the appropriate action without requiring the installation of any customized software / application and independently of the hardware manufacturer. There are several NDEF record formats that you can use in your implementation. Each NDEF record indicates to the application processor which kind of payload the message carries. In our demo app, the default NDEF message used belongs to a smart poster record and the NDEF pairing message, follows the protocol defined in the NFC Forum connection handover specification. Going to the source code, two application files for the NDEF handling were created: The app_ntag.h declares the two NDEF messages used in this demo. The app_ntag.c, implements a function which writes the NDEF message into the tag. As mentioned, the NDEF used for this BLE pairing was built according to the Connection Handover and BT secure simple pairing specifications and rules. On the image below, we copied the declaration of the NDEF pairing message. This is actually the hex bytes that are written into the tag memory. To highlight son relevant parts: We find the capability container and the NDEF TLV. These two fields are used by the NFC device to detect if the tag is loaded with NDEF formatted data into a Type 2 tag (like the NTAG I 2 C plus). After that, we find the record type name. This is the MIME type for the Bluetooth out of band pairing (written in its ASCII representation). It is followed by the device Bluetooth MAC address, and the complete local name (Freescale HID). The terminator TLV In case you are interested to know more about the NDEF message structure, you can check the NFC Forum specifications The data (MAC address 00:04:9F:00:00:04 & device name FSL_HID) read by the NFC device is sent to the Bluetooth controller to establish the Bluetooth connection. Default NDEF message definition  The NDEF used as thedefault_ndef message consist of two records: The first record was built according to the SmartPoster specification from the NFC Forum, which describe how to store a plain message followed by an URL. The second record is what is called Android Application record. On the image below, we copied the declaration of the NDEF default message. To highlight son relevant parts:   As the NDEF BLE message, the first data fields we find correspond to the container and the NDEF TLV structure for a Type 2 Tag. Then, we find the smart poster record, which includes a text field. In this example, it codes the text “NTAG I2C Explorer”  and a URI field which codes a the NTAG Explorer kit website URL. After that, we find the Android application record, which is used to automatically launch the app  or, if the app is not installed, redirect the user to Google Play. Finally, the terminator TLV. After 10 seconds, the application removes the BLE pairing NDEF and replaces it by the above described NDEF message. This can be easily demonstrated by tapping the phone after these 2 seconds, and validate that the NTAG I 2 C plus demo is automatically opened. Video recorded session   Available resources BLE pairing with NFC on KW41 and NTAG I 2 C plus source code www.nxp.com/downloads/en/snippets-boot-code-headers-monitors/SW4223.zip NTAG I 2 C plus kit for Arduino pinout www.nxp.com/demoboard/OM23221ARD FRDM-KW41Z board www.nxp.com/demoboard/FRDM-KW41Z

Demo This demo shows an intelligent and efficient automotive system which encompasses surround view (360 Video camera) paired with a LIDAR (360 Laser surround view) for pedestrian detection, traffic sign recognition, speed detection, etc. Products Links NXP BlueBox https://www.nxp.com/design/development-boards/automotive-development-platforms/nxp-bluebox-autonomous-driving-development-platform:BLBX?&fsrch=1&sr=2&pageNum=1 QorIQ® LS2088A Reference Design Board https://www.nxp.com/design/qoriq-developer-resources/qoriq-ls2088a-reference-design-board:LS2088A-RDB?&lang_cd=en S32V230 Family of Processors https://community.nxp.com/external-link.jspa?url=http%3A%2F%2Fwww.nxp.com%2Fproducts%2Fautomotive-products%2Fmicrocontro…  S32R Radar Microcontroller - S32R27 https://community.nxp.com/external-link.jspa?url=http%3A%2F%2Fwww.nxp.com%2Fproducts%2Fautomotive-products%2Fmicrocontro…  32-bit Automotive General Purpose MCUs https://community.nxp.com/external-link.jspa?url=http%3A%2F%2Fwww.nxp.com%2Fproducts%2Fautomotive-products%2Fmicrocontro…  Other Links ADAS & Autonomous Driving|NXP  V2X Communications|NXP 

Demo Wheel rotation is controlled by the SB0400 DC motor pre-driver. When the wheel is stopped manually, the Wheel Speed Sensor -KMI23- detects it & sends a signal to the SB0400 motor pre-driver & S32K MCU to activate the electromagnet Products 32-bit Automotive General Purpose MCUs|NXP Motorcycle Two-Wheel Antilock Braking (ABS)|NXP KMI23_KMI25|NXP  Links Motorcycle Two-Wheel Antilock Braking (ABS)|NXP  Analog Expert Software and Tools|NXP  Recommended product Link S32K144EVB https://www.nxp.com/design/development-boards/automotive-development-platforms/s32k-mcu-platforms/s32k144-evaluation-board:S32K144EVB?&fsrch=1&sr=1&pageNum=1

Demo Enable Your Device with Amazon® Alexa®  Quickly integrate Alexa voice capabilities into your product Reference design based on i.MX 7Dual applications processor Easily create high-performance, far-field voice experiences with Echo-quality performance using Amazon’s best-in-class 7-microphone circular array Technology for “Alexa” wake word recognition Beam forming Noise reduction Acoustic echo cancellation Barge-in capabilities Products i.MX 7Dual Arm Cortex-A7 Processor|NXP  12-Channel Configurable PMIC|NXP  Link Amazon Alexa Reference Design based on the Pico i.MX7 Dual|NXP  Training Voice Control Solutions: Creating Amazon® Alexa® Devices with i.MX 

Demo On this demo, we are showing a comparison between CAN-FD and classic CAN on the LPC54618 microcontroller. The LPC board is doing a firmware update using both CAN protocols Dual LPC54618 microcontroller CAN-FD kits illustrate the speed benefits of CAN-FD versus classic CAN One board acts as the vehicle console display and the other emulates a radio which serves the HMI over the CAN link Selecting between CAN and CAN-FD demonstrates the benefits in the display updates and in a simulated firmware update transfer Product Link LPCXpresso54618 CAN-FD kit OM13094 | LPCXpresso Development Board | LPC Microntrollers (MCUs) | NXP  LPC546XX LPC546XX Microcontroller (MCU) Family | NXP  Block Diagram

Demo See how NXP integrates automotive and microcontroller technology to develop next-generation drones including high reliability, industrial quality, and additional security with drone-code compliant flight management unit running PX4. Video Features Electronic speed controllers with Field Oriented Control of BLDC (Brushless DC motors) TJA110 2-wire  Automotive Ethernet PHY Transceiver|NXP  SCM-i.MX6 Training https://register.gotowebinar.com/rt/9153317036356506113  Find our more at www.nxp.com/uav

Demo Low-cost evaluation board running a PMSM motor Products Links S32K144 Evaluation Board https://www.nxp.com/design/development-boards/automotive-development-platforms/s32k-mcu-platforms/s32k144-evaluation-board:S32K144EVB?&fsrch=1&sr=1&pageNum=1 Low-Cost Motor Control Solution for DEVKIT Platform https://www.nxp.com/design/development-boards/automotive-development-platforms/hardware-tools-accessories/low-cost-motor-control-solution-for-devkit-platform:DEVKIT-MOTORGD?&fsrch=1&sr=1&pageNum=1 FreeMASTER Run-Time Debugging Tool FreeMASTER Run-Time Debugging Tool | NXP  Model-Based Design Toolbox https://www.nxp.com/design/automotive-software-and-tools/model-based-design-toolbox:MC_TOOLBOX?&&&code=MC_TOOLBOX&nodeId=0152109D3F12B8F6F8 Model-Based Design Toolbox for S32K14x Automotive MCU rev2.0  Model-Based Design Toolbox For Panther (MPC574xP) Family of Processors 2.0  Learning Model-Based Design Toolbox Motor Control Example Motor Control Class: Motor Control System Motor Control Class with Model-Based Design

Demo This is an ideal tri-radio system solution. The demo shows one board with 3 Wi-Fi radios. They are 2.4GHz, 5 GHz, 802.11AC working in conjunction with BLE devices, then running a virtual IoT network where different virtual machines will handle different parts of the processes. One of the virtual machines will handle all IoT communications (from the BLE devices). Another virtual machine will take care of the DLNA  (Video streaming to a wireless tablet) and the last virtual machine will run the firewall system. All data that is being transferred through the platform can be visually displayed on the GUI for each of the instances shown. Products Product Link QorIQ® LS1043A reference design board QorIQ® LS1043A-RDB | NXP  Freedom Development Kit for Kinetis® KW41Z/31Z/21Z MCUs https://www.nxp.com/design/development-boards/freedom-development-boards/wireless-connectivy/freedom-development-kit-for-kinetis-kw41z-31z-21z-mcus:FRDM-KW41Z?&fsrch=1&sr=8&pageNum=1 Training Containers 

Demo In this demo, we are showing an 802.11AD 60GHz Wireless Demo with 3Gbps throughput using two LS1046ARDB (ARM Cortex A72 Quad Core) gateways and an LS1012ARDB gateway. These gateways simulate communication between stations. Products Product Link QorIQ® Layerscape 1012A Low Power Communication Processor Layerscape LS1012A Communication Processor for the IoT | NXP  QorIQ® LS1012A Development Board https://www.nxp.com/design/qoriq-developer-resources/qoriq-ls1012a-development-board:LS1012A-RDB?&fsrch=1&sr=2&pageNum=1 QorIQ® Layerscape 1046A and 1026A Multicore Communications Processors QorIQ® Layerscape 1046A | NXP  QorIQ® LS1046A Development Board QorIQ® LS1046A Development Board | NXP  Training New Kid on the Block - 60 GHz Wi-Fi 

Demo Neural network classification method based on SqueezeNet. Images are captured by the camera processed and classified by the S32V processor and then displayed on the TV monitor with a confidence percentage calculated for each object visualized. Based on SqueezeNet, 501x fewer parameters than AlexNet Low power consumption - Less than 10 watts total Average top 1 accuracy of 58% and top 5 accuracies of 92% CNN built with APEX-DNN library Product Link S32V Vision and Sensor Fusion Evaluation Board https://www.nxp.com/design/development-boards/automotive-development-platforms/s32v-mpu-platforms/s32v-vision-and-sensor-fusion-evaluation-board:SBC-S32V234  S32V234 S32V234 Vision Processor | NXP 

Demo Watch as the i.MX 8 development vehicle takes data in from the camera and uses one GPU and applies an image segmentation algorithm. The info is then fed to another GPU dedicated to a neural network inference engine which recognizes the traffic sign Products i.MX 8 Series Applications Processors|NXP  Training i.MX 8 Applications Processors Family Overview: i.MX 8, i.MX 8X, i.MX 8M  i.MX 8M Processor Overview and the Road Ahead  Micron’s Memory Solutions for the New i.MX 8 Microprocessor   

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%

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 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 Watch this training video about NXP’s new 65 V LDMOS technology that speeds RF power design. This extra-high voltage LDMOS process will give rise to a new generation of products: the MRFX series   Products MRFX1K80H|1800 W CW, 1.8-470 MHz, 65 V|NXP  MRFX1K80N|1800 W CW, 1.8-470 MHz, 65 V|NXP