Near Field Communication (NFC) is already present in more than 1.5 Billion smartphones. Well-known applications like payment and access control are enabled by NFC, but also emerging and innovative use cases which are just appearing on the horizon now. This article gives you more information, background and how-to guides around our NFC demos, first exhibited at embedded world 2018 in Nürnberg - to help you put NFC Everywhere. Accessories and consumables Identifying and authenticating accessories and consumables can add significant value to a product, and for the first time we show live how this works: The demo showcases tool identification via NFC for 3 different kinds of tools: A drill bit, a standard flat-blade screwdriver and a Phillips screwdriver. Each of the tools has an embedded NTAG213 NFC tag, and the electric drill contains an NFC reader (CLRC663 plus). As soon as a tool is inserted, the main unit reads the tool type and usage (wear). Based on this information, it can reject non-genuine or worn-out tools, and adjust internal settings like max/min speed based on the tool type. The demo is based on the brand new NFC Nutshell kit by our partner GMMC, and the demo shows how easily an existing product can be retrofitted with NFC using this kit. Find a detailed description of accessory and consumable identification and authentication here: https://community.nxp.com/docs/DOC-340283 Parameterization, Diagnosis and Firmware update This demo shows how you can use an NFC phone to parameterize/configure a DIN rail module (or any other piece of electronics) with an NFC phone - even if the module is completely unpowered. The smart phone app lets you set the behavior of the lamps and also the language of the display. After the configuration (a simple tap) you switch on the main power, and the device comes up as configured. And NFC also lets you read out diagnostic data - no matter whether the device is powered on or off. So you can even replace your service UART by NFC. Thirdly, the demo shows how easy it is to even flash your firmware via NFC. Again, this works even when the device is switched off. This application is based on the NTAG I²C plus passive connected tag IC.   Find a detailed description and all source codes here: https://community.nxp.com/docs/DOC-333834. Interested how this looks like in a commercial product? Watch this video showing how easily the Schneider Zelio NFC Timer Relay can be configured via NFC. Access Management In the Access Management corner, we demonstrate the ultimate contactless connectivity for residential or hospitality applications through NXP NFC and BLE solutions and a superior contactless experience and security with MIFARE ® DESFire ® credential on cards, mobile devices and wearables. Our demonstrator is based on the PN7462 family, the all-in-one full NFC controller, the QN9021, a low power BLE system-on-chip, and the PCF8883T, capacitive proximity switch with auto-calibration, for very low power consumption. We also show two commercial products by our partners: 1) The Salto XS4 range of smart doorlocks, a simple to use and very efficient access control system. 2) A modular access control solution by Kronegger, using their tiny NFC reader boards. We also reveal a very small footprint complete reader board based on the new BGA package (VFBGA64; 4.5x4.5 mm²) for the PN7462 family complementing the existing HVQFN64 package.   NFC Tandem - The Best Of Two Worlds If you need NFC functionality both in powered and unpowered state, have a look at the NFC Tandem demo: An NFC reader (PN7150) and a passive connected NFC tag (NTAG I²C plus) sharing one antenna. A user can interact with the device when it is powered off (through the NTAG I²C plus); when the device is powered, it can read cards, tags or other connected tags. Find design files, a user manual and further downloads here: https://community.nxp.com/docs/DOC-340244 Single-Chip Integrated Solution: LPC8N04 MCU with passive NFC interface In this demo, we show our latest integrated NFC solution, the LPC8N04, a cost-effective MCU with integrated (passive) NFC connectivity. This MCU offers multiple features, including several power-down modes and a selectable CPU frequency of up to 8 MHz for ultra-low power consumption. The demo showcases its features in a conceptual clock format: - Easily set current time/date of the clock via an NFC phone - Real-time clock with optional alarm, programmed and controlled using an Android app - GPIO controlled bar graph indicating programmable "safe operating range" - I2C controlled OLED user display - Data (temperature) logging, configured using an Android App To learn more about this device, please visit: www.nxp.com/LPC8N04 Single-Chip Integrated Solution: NTAG SmartSensor NTAG SmartSensor allows consumers and brand owners to confirm that temperature sensitive products – like fish, wine or pharmaceuticals – have been properly handled. The NTAG SmartSensor allows for temperature sensing at the item level, so each individual product can be confirmed as safe to use. And a single tap with your NFC smartphone is all that's needed to read out the temperature history of the NTAG SmartSensor. Learn more about NTAG SmartSensor on our webpage or watch the video. If you are looking for a ready-made logger using the NTAG SmartSensor, here is a list of manufacturers offering NTAG SmartSensor based loggers. Electronic Shelf Labels With NFC-enabled Electronic Shelf Labels (ESL), wrong price indication, non-transparent processes, and unsatisfactory customer interactions are a thing of the past. In this demo we show labels from 2 manufacturers, one commercial electronic shelf label from SES Imagotag and one ePaper label from MpicoSys. Find more information in the article by Fabrice Punch, Senior Marketing Manager at NXP. Why NFC on ePaper label? NFC allows for creating a product with no batteries, so no recharging, and labels can be in constant use  No cables and connectors - labels can be fully sealed and made waterproof NFC is a well-proven and widely-supported standard  Allows for easy integration with both PC and smartphones    Applications for PicoLabel - MpicoSys ePaper labels Logistic labels (warehousing, supply chain management)  ID Badges (show image on employee, visitor and conference badges)  Authentication badges (identity, authentication, cryptographic security) Door signage (shared offices, conference centers) Manufacturing (replacing paper labels) NFC Cube The NFC Cube is the universal demo for NFC applications: It shows communication between a device and a card/tag, between a device and a phone, and between two devices. It uses the PN7462AU single-chip NFC controller with integrated Cortex M0 core. The NFC Cube kit is interoperable with our NTAG I 2 C plus Explorer board, which enables you to demonstrate how 2 devices can communicate via NFC. NFC Portfolio and Package Options Find here an overview of the package options of our NFC reader and connected tag ICs. Our Partners In The NFC Everywhere Demonstrator We would like to extend a special thanks to our partners who contributed to this demonstrator: Lab ID: NFC/RFID cards, tickets, labels and inlays Kronegger: Demo on logical access control, NFC reader modules and customized solutions Salto: Smart door lock demo GMMC: NFC Nutshell Kit for easy demonstration, retrofitting and development of small NFC reader solutions SES Imagotag: Commercial electronic shelf label with customer interaction via NFC MpicoSys: Commercial PicoLabel based on ePaper and content update via NFC Find out more Discover NFC Everywhere: https://www.nxp.com/nfc All about MIFARE: https://www.mifare.net Get your technical NFC questions answered: https://community.nxp.com/community/identification-security/nfc List of Approved Engineering Consultants (AEC) for NFC: https://nxp.surl.ms/NFC_AEC NFC Everywhere Brochure: https://www.nxp.com/docs/en/brochure/NFC-EVERYWHERE-BR.pdf 

Explore the MC34937, an industrial-grade 3-phase gate pre-driver for BLDC and PMSM motor control. The MC34937 can support 12V, 24V, and 36V motor control applications and easily interfaces to standard MCUs and DSPs. The demo shows the implementation of the MC34937 with Kinetis Microcontrollers E in a 36V battery-operated electric bike (eBike) application. This same system can be modified to be used in other industrial applications such as electric garden tools, industrial fans and pumps, and electric wheelchairs. Features Demo shows capability of Kinetis KE02 connecting to an MC34937 Motor Driver MC34937 able to drive 12V, 24V, 36V, 48V systems Featured NXP Products Kinetis E - KE02Z64 MC34937 3-phase gate pre-driver Block Diagram MC34937 Schematics and Software:

  Overview NXP digital signal controllers provide a switched-mode power supply solution that maximizes efficiency while reducing system costs through bill-of-materials savings. Our solution dynamically compensates for system disadvantages such as component aging and operational variability due to changing load conditions.   Reference Designs Product Name Link Features 3-Phase PMSM Control https://www.nxp.com/design/designs/3-phase-pmsm-control:PERMANENT-MAGNET-MOTOR The 3-Phase Permanent Magnet Synchronous (PMSM) Motor Control Reference Design is based on Kinetis V Series MCUs and intended to provide the example for 3-phase sensorless PMSM motor control solutions. The Reference design utilizes a closed-loop field-oriented vector speed (FOC) control mechanism. KV Series Full-Bridge DC-DC Switch Mode Power Supply (SMPS) https://www.nxp.com/design/designs/kv-series-full-bridge-dc-dc-switch-mode-power-supply-smps:FULL-BRIDGE-SMPS  Full Bridge DC-DC Switch Mode Power Supply   Block Diagram     Recommended Products   Category Products Features DSC Kinetis® V Series: Real-time Motor Control & Power Conversion MCUs based on Arm® Cortex®-M0+/M4/M7 | NXP  Kinetis V Series MCUs are based upon the Arm Cortex-M0+, Cortex-M4, and Cortex-M7 cores and are designed for a wide range of BLDC, PMSM, and ACIM motor control and digital power conversion applications. Temperature Sensor I²C Digital Temperature/Voltage Sensors | NXP  NXP I2C Temperature/Voltage monitors offer best-in-industry precision to fit any thermal management need.

Overview In the industrial world, it is critical to incorporate fail-safe technology where possible in applications such as crane steering machines, robotic lift, and assembly line robots to name a few. By doing so, you ensure you meet Safety Integrity Level (SIL) standards as found in the IEC 61508 standard. Also, you significantly increase human safety and protect products and property. This fail Safe Motor Control solution incorporates the MPC574xP family of MCUs that delivers the highest functional safety standards for industrial applications. The MPC574xP family incorporates a lockstep function that serves as a watchdog function to flag any problems with the MCU including a programmable Fault Collection and Control Unit (FCCU) that monitors the integrity status of the MCU and provides flexible safe state control. Also, this device is a part of the SafeAssure® program, helping manufacturers achieve functional safety standard compliance. Block Diagram Recommended Products Category Products Features Power Switch 12XS2 | 12 V Low RDSON eXtreme Switch | NXP  Watchdog and configurable Fail-safe mode by hardware Authentication time (on-chip calculations) < 50 ms Programmable overcurrent trip level and overtemperature protection, undervoltage shutdown, and fault reporting Output current monitoring Pressure Sensor MPXHZ6130A|Pressure Sensor | NXP  The MPXHZ6130A series sensor integrates on-chip, bipolar op amp circuitry and thin-film resistor networks to provide a high output signal and temperature compensation for automotive, aviation, and industrial applications. Temperature Sensor https://www.nxp.com/products/sensors/silicon-temperature-sensors/silicon-temperature-sensors:KTY8X High accuracy and reliability Long-term stability Positive temperature coefficient; fail-safe behavior MOSFET Pre-driver GD3000 |3-phase Brushless Motor Pre-Driver | NXP  Fully specified from 8.0 to 40 V covers 12 and 24 V automotive systems Extended operating range from 6.0 to 60V covers 12 and 42 V systems Greater than 1.0 A gate drive capability with protection Power Management and Safety Monitoring MC33908 | Safe SBC | NXP  Enhanced safety block associated with fail-safe outputs Designed for ASIL D applications (FMEDA, Safety manual) Secured SPI interface   Evaluation and Development Boards   Link Description MPC5744P Development Kit for 3-phase PMSM | NXP  The NXP MTRCKTSPS5744P motor control development kit is ideal for applications requiring one PMSM motor, such as power steering or electric powertrain. Evaluation daughter board - NXP MPC5744P, 32-bit Microcontroller | NXP  The KITMPC5744DBEVM evaluation board features the MPC5744P, which is the second generation of safety-oriented microcontrollers, for automotive and industrial safety applications

I am using Adafruit LED stripes with 60 LED's per meter. Each LED integrates the W2812B controller. WS2812B uses a serial protocol, and you can control each LED individually. The strip is made of flexible PCB material, and comes with a weatherproof sheathing.   https://www.adafruit.com/products/1138   WS2812B is an intelligent control LED light source that the control circuit and RGB chip are integrated in a package.   The data transfer protocol use single NZR communication mode. After the pixel power-on reset, the DIN port receive data from controller, the first pixel collects initial 24bit data, then send to the internal data latch, the other data is sent to the next cascade pixel through the DO port.   LED's in cascade: My LED panel uses 16 rows x 30 columns = 480 leds.   In a first approach, in order to generate the bit stream, a timer in PWM mode could be used and generate two different duty cycles for sending a "0" logic or "1" logic. Using PWM's + DMA can unload the CPU in the generation of each single bit. FlexIO module in the Kinetis K82 can do that in a very effective mode and generate 8 channels simultaneously.   But my objective is to unload the CPU as much as possible in the bit stream generation task and find an easy method of multiplexing the 8 FlexIO outputs. In this way, we can control more LED rows and get a minimum number of interrupts and CPU intervention.   I will use the FlexIO internal data shifters to send the data bit stream. One shifter for each row. As we only have 8 shifters, I can use external multiplexor to increase the number of rows. Unloading the CPU for the LED refresh process, we can mux several rows in each shifter output. The limit of LED’s will be the refresh time of the full panel.   FlexIO block diagram:     How are the "1" and "0" generated?   Each pixel needs 24 bits of Red-Green-Blue value (RGB)   For each row, I need to send 30 x 24 bits of RGB information. But I have to encode the data in the NZR/PWM protocol. I use a lookup table to transform 24 bpp information in 24 x 3 = 72 bits per pixel.     In this way the  DMA can send 30 x 24 x 3 = 1440 bits (A full row)  in 60 transfers of 24 bits into the shifter. We get only one DMA interrupt for each row:       Multiplexer implementation:       Frame Buffer LED:   typedef union { uint32_t  rgb;     struct{       uint8_t  b;       uint8_t  r;         uint8_t  g;       uint8_t  a;     }bytes; }ledrgb;   Extended LED encoded data:   typedef struct {   uint32_t g;   uint32_t r;   uint32_t b; }ledrgb_ext;     Lookup Table:   void init_conv_matrix(void) { videoconv[0]=0x92492400; videoconv[1]=0x92492600; videoconv[2]=0x92493400; videoconv[3]=0x92493600; videoconv[4]=0x9249A400; videoconv[5]=0x9249A600; videoconv[6]=0x9249B400; videoconv[7]=0x9249B600; videoconv[8]=0x924D2400; videoconv[9]=0x924D2600; videoconv[10]=0x924D3400; ... };   Part 3: Software for LED Panel emulation Or Return to Project page: LED Panel control with FlexIO

Overview NXP ®  offers solutions for the growing unmanned vehicle market in both civil and defense designs, supporting functions such as control, motion, vision, navigation, and communication. Target applications include: Unmanned Aerial Vehicle Unmanned Ground Vehicle Unmanned Underwater Vehicle Construction, demolition, inspection, or mining robot Firefighting or rescue robot Reference Designs NXP Product Link PX4 Robotic Drone FMU https://www.nxp.com/design/designs/px4-robotic-drone-fmu-rddrone-fmuk66:RDDRONE-FMUK66  KV Series Quad Motor Control https://www.nxp.com/design/designs/kv-series-quad-motor-control:KINETIS-DRONE-REFERENCE-DESIGN Block Diagram Recommended Products NXP Product Link MCU Kinetis® V Series: Real-time Motor Control & Power Conversion MCUs based on Arm® Cortex®-M0+/M4/M7 | NXP  LPC54000|Power Efficient 32-bit Microcontrollers (MCUs)|Cortex®-M4 Core | NXP  i.MX RT1060 MCU/Applications Crossover MCU | Arm® Cortex®-M7, 1MB SRAM | NXP  i.MX 6Solo Applications Processors | Single Arm® Cortex®-A9 @ 1GHz | NXP  i.MX 6Dual Applications Processors | Dual Arm® Cortex®-A9 @1.2GHz | NXP  i.MX 6Quad Applications Processors | Quad Arm® Cortex®-A9 | NXP  Wireless Connectivity Bluetooth®Smart/Bluetooth Low Energy | NXP  Interfaces In-Vehicle Network | NXP  I²C, SPI, Serial Interface Devices | NXP  USB Interfaces | NXP  NFC Reader NFC Readers | NXP  Wireless Power Wireless Power | NXP  Motor Driver GD3000 |3-phase Brushless Motor Pre-Driver | NXP  Voltage Regulator Linear Voltage Regulators | NXP  Switch Detector Signal Conditioners | NXP  Sensors Sensors | NXP  Tools and Software NXP Product Link i.MX RT1060 Evaluation Kit i.MX RT1060 Evaluation Kit | NXP  i.MX RT1020 Evaluation Kit i.MX RT1020 Evaluation Kit | NXP  SABRE Board for Smart Devices Based on the i.MX 6Quad Applications Processors i.MX 6Quad SABRE Development Board | NXP  i.MX RT1064 Evaluation Kit i.MX RT1064 Evaluation Kit | NXP  Kinetis® KV3x TWR-KV31F120M|Tower System Board|Kinetis® MCUs | NXP  i.MX RT1015 i.MX RT1015 Evaluation Kit | NXP  3-Phase Motor Control Low-Voltage, 3-Phase Motor Control Tower System Module | NXP  i.MX RT1050 Evaluation Kit i.MX RT1050 Evaluation Kit | NXP  NXP HoverGames drone kit including RDDRONE-FMUK66 and peripherals KIT-HGDRONEK66: NXP drone kit | NXP  Kinetis KV4x TWR-KV46F150M|Tower System Board|Kinetis MCUs | NXP  BSP, Drivers, and Middleware NXP Product Link Android OS for i.MX Applications Processors Android OS for i.MX Applications Processors | NXP  Embedded Linux for i.MX Applications Processors Embedded Linux for i.MX Applications Processors | NXP  MCUXpresso Software Development Kit (SDK) MCUXpresso SDK | Software Development for Kinetis, LPC, and i.MX MCUs | NXP  MCUXpresso Config Tools - Pins, Clocks, Peripherals MCUXpresso Config Tools|Software Development for NXP Microcontrollers (MCUs) | NXP 

Near Field Communication (NFC) is hot. It is available in hundreds of millions of smartphones, tablets, and other consumer electronics, and enters more and more the industrial space as well. This article shows how to implement the demos of our "Industrial NFC Demonstrator", first exhibited at embedded world 2017 in Nürnberg.           Parameterization & Diagnosis This demo shows how you can use an NFC phone to parameterize/configure a DIN rail module (or any other piece of electronics) with an NFC phone - even if the module is completely unpowered. The smart phone app lets you set the behavior of the lamps and also the language of the display. After the configuration (a simple tap) you switch on the main power, and the device comes up as configured. And NFC also lets you read out diagnostic data - no matter whether the device is powered on or off. So you can even replace your service UART by NFC. Thirdly, the demo shows how easy it is to even flash your firmware via NFC. Again, this works even when the device is switched off. This application is based on the NTAG I²C plus passive connected tag IC. See here a video from embedded world 2017 showing this demo.   Find a detailed description and all source codes here: https://community.nxp.com/docs/DOC-333834  Interested how this looks like in a commercial product? Watch this video showing how easily the Schneider Zelio NFC Timer Relay can be configured via NFC.   Device-to-device communication In this demo you see how NFC can establish a communication between 2 devices with up to 40 kbit/s. The angular position of the rotating disk is measured, communicated to the main board via NFC and displayed on an LED ring. The nice thing: The rotating disk is without battery. Energy harvesting via NFC provides supply power up to 15mW. This principle of using NFC as a cable replacement is especially interesting in cases where you want to communicate with fully sealed, isolated, moving or rotating units. The communication is bi-directional, and the data can be static (a button press, or configuration data) or dynamic (sensor measurements). The demo is based on the CLRC663 plus reader on the main unit and the NTAG I²C plus passive connected tag on the rotating disk. See here the video from embedded world 2017 demonstrating this application.   Find a detailed description and all source codes here: https://community.nxp.com/docs/DOC-333917       Access control In the Physical Access Control demo, we show a simple implementation of a basic access control solution using a Type 4 tag and a CLRC663 plus based reader, based on the public NFC Reader Library. NXP recommends for a complete real-life access control solution to use MIFARE DESFire credentials as with the MIFARE DESFire EV2 card. Supporting software library is under NDA. In this video from embedded world 2017 you see access control in action.   Download the source code here: http://nxp.com/assets/downloads/data/en/software/RC663Demo_ReadNdefT4T_v1.2.zip           1-tap Bluetooth Pairing This demo shows how easy it is to pair wireless devices to your phone with NFC - using an example of the Kinetis KW41 Freedom board (BLE MCU), with an NTAG I²C plus kit for Arduino® pinout for the NFC function. This new NTAG I²C plus kit is suitable for any board featuring an Arduino-compatible header, including LPCXpresso, Kinetis and i.MX boards. It is the ideal tool to evaluate and design-in an NTAG I²C plus tag chip in an embedded electronic system. Find a detailed description and all source codes here: https://community.nxp.com/docs/DOC-335241     Automation with Hexiwear A nice example of how to build versatile applications, is shown in the automation demo with the Hexiwear IOT development platform. Based on Kinetis MCUs and hundreds of available click-boards (plug-ins with sensors, actuators, transceivers - and of course also NFC), you can quickly build a prototype of your application. Two NFC-based click-boards are available: 1) A reader board based on PN7120 2) A board with NTAG I²C plus The automation demo uses 3 different Hexiwear base boards, connected between them via Zigbee. The NFC unit identifies a technician's badge, and also the tools he uses for his job. The second unit drives the instrument panel, and the third one the big LED screen. A video from embedded world 2017 shows how this works.   Find more information on Hexiwear at www.hexiwear.com.   Our partners in the NFC industrial demonstrator We would like to extend a special thanks to our partners who contributed to this demonstrator: Lab ID and Arti Grafiche Julia: NFC/RFID cards, tickets, labels and inlays Kronegger: Demo on logical access control, NFC reader modules and customized solutions Neosid: Small NFC/RFID transponders for tool identification and authentication   Find out more Discover NFC Everywhere: www.nxp.com/nfc All about MIFARE: https://www.mifare.net Get your technical NFC questions answered: https://community.nxp.com/community/nfc

Demo Owner: Mark Houston   Kinetis V series is a family of devices targeting motor and power control applications for the mass market with a strong focus on enablement. See two elements of that story: a product benchmark showing relative product performance and the Kinetis motor suite -- a tool that speeds your development time to market.       Features Motor speed capabilities Comparison to standard controllers Smooth transitions Featured NXP Products Kinetis V Kinetis V1 Kinetis V3 Kinetis V4 Development Tools Kinetis Motor Suite Design Resources Kinetis Motor Suite Fact Sheet

  Overview In the past , the production operator has to manually locate the components and assemble the various components with the right quantity for assembly production . And it is prone to Human error . So a solution its needed to provide a faster turnaround time for the production operation to consolidate all necessary components for assembly production for various models and decrease the error for human factors. In this particular deployment , the system assist the production operator to get all necessary components for assembly production without making mistakes due to Human error and also in shortest possible time. The system deployed using JN5168, raises productivity level of the production operator. The system also keep track of the Components stock levels and when require replenishment , it will raise a notification to the system. Block Diagram Products Category Zigbee Product URL JN5169: ZigBee and IEEE802.15.4 wireless microcontroller with 512 kB Flash, 32 kB RAM  Product Description The JN5169 is an ultra low power, high performance wireless microcontroller suitable for ZigBee applications.   Category LCD Driver Product URL PCF8553DTT: 40 × 4 LCD segment driver  Product Description PCF8553 is an ultra low-power LCD segment driver with 4 backplane- and 40 segment-driver outputs, with either an I²C- or an SPI-bus interface.

This post entry aims at explaining the debugging process oriented to EMVCo Contactless certification of a device integrating NXP's PN5180. The structure is the following: PN5180 Antenna design considerations Before going into the debugging process for the EMVCo Contactless Analog tests we will see some important considerations for an antenna design and impedance tuning oriented for an EMVCo compliant device. Antenna tuning recommendations The first recommendation is that with the Dynamic Power Control feature the PN5180 allows us to perform symmetrical antenna tuning instead of the typical asymmetrical tuning. This symmetrical tuning provides us with a better transfer function, being able to drive more power to the antenna. The following figure shows the Smith Chart with the S11 parameter plot of a device using a symmetrical antenna tuning:   The only disadvantage of the symmetrical tuning is that we need a current limiter to avoid destroying the chip because of exceeding the chip’s limits. In the case we are documenting today, the PN5180 DPC feature is used to limit the supply voltage and therefore the transmitter current depending on the load detected by the chip. Regarding the EMC filter, the inductor should fit with the following condition to guarantee a good relation between the AGC and the ITVDD: Another consideration is about the resistor used in the reception branch. This resistor controls the receiver sensibility and as a starting point is recommended to use a value to obtain an AGC in free air of: Reader Mode only design: AGC value in free air around 600dec Full NFC design: AGC value in free air around 300dec Finally, EMV contactless transactions are performed at 106kbps which would allow us to work with a high Q factor of the overall system. This means that the power gain can be higher, but at the same time it might also lead to some issues because of the lower bandwidth. In light of this, we have to bear in mind, that if the Q factor is too high it may lead to problems in the waveform tests. PN5180 DPC calibration The Dynamic Power Control is a feature that uses the AGC value to establish different power configurations depending on the load applied to the antenna. As I mentioned before, the main goal is to protect the chip from a transmitter current level that might destroy it. The first step before calibrating the DPC is to check the correlation between the AGC value and the transmitter current or ITVDD when different loads are applied to the antenna. Basically, we will play with the distance between the load and the device to get several points with different AGC values. Based on those measurements, we can plot a graph like the following: Normally we would use a reference PICC and a metal plane or phone to check that the behavior is linear and with no big difference between those loads. Once we have checked the correlation we can proceed with the calibration process, which can be done very easily with the NFC Cockpit software. Here the important thing is to control the ITVDD and keep it always below the chip’s limit. As you can see in the figure below, without the DPC, this symmetrical tuning would lead to a voltage above the limit for positions close to the reader antenna. However, with DPC we can control that voltage at any moment. Another consideration is that we have to make sure that the DPC is calibrated to have maximum power when the reference PICC is far from the reader to avoid a lack of power in the tests at those positions. EMV L1 Analog Tests Debugging process We are going to divide this debugging process into 3 main phases which are the power tests in the first instance, followed by the waveform tests and the reception tests. The reason why we set this order is to first debug the tests that may require HW modifications which have a strong impact on the other tests. This way, for example, if you have passed all power and waveform tests, debugging the reception tests may not have an impact on the results obtained previously. Power tests Tests setup In order to debug the power tests, we will need just an oscilloscope and an EMVCo reference PICC. We will need to connect the outputs J9 and J1 of the EMVCo reference PICC to the oscilloscope and set the jumper J8 of the reference PICC in non-linear load mode. The J9 of the EMVCo reference PICC is the DC_OUT output that we will use to measure the power received by the antenna. The J1 is the LETI_COIL_OUT output and we will use it to capture the command in the oscilloscope. The overall setup is depicted in the figure below. Performing tests We have to use the trigger to capture the REQA command sent from the DTE when the reference PICC is in the position we want to test. This capture can be seen in the two figures below. The yellow channel is the LETI_COIL_OUT of the EMVCo reference PICC and the blue channel represents the DC_OUT obtained from the J1 connector. As said previously, we will use the DC_OUT to measure the voltage in the period of the signal where there is no modulation, like this part highlighted with the red squared. We have zoomed into the period to get the average value using the oscilloscope measurement features. We will use this same procedure to evaluate the power tests in all positions. Depending on the position tested, the specifications define and certain range where the voltage measured should be fitted. In this sense, the maximum voltage level is common for all planes, but the minimum voltage allowed will decrease for positions further from the terminal.  In order to identify the critical positions for the power tests, we have to identify two different scenarios, the first one with the positions that might not reach the minimum voltage established, and the positions that might exceed the maximum value. For the first scenario the critical positions are the outer positions of the plane z = 4cm and the plane z=3cm as the external positions for plane z= 3cm have a bigger radius. The other scenario is that where you can be exceeding the maximum level. This situation can happen in the central positions of the lower planes, like plane z=1 or z=0. Debugging hints In order to overcome possible issues, we will give some tips that can be used for your design. Regarding a case of lack of power, first, we have to make sure that the DPC is correctly calibrated, meaning that you are operating in gear 0 for the external positions of planes 3 and 4 and that gear 0 is operating with full power. If we have verified those two things and we still have issues, we would need to change the tuning of the antenna and reduce the target impedance. This is graphically represented in the following Smith Chart: By reducing the impedance we increase the current that the PN5180 is driving to the antenna so the voltage would increase. Is important to always verify that we are working within the recommended operating range of the chip and that we are not exceeding the transmitter current limit. In a worst-case scenario, if we cannot achieve the voltage with these HW changes we would need to evaluate changes in the hardware design, like adding a ferrite sheet or changing the antenna dimensions or position. On the other hand, if the problem comes because we are exceeding the maximum voltage allowed by the specifications we can easily solve it by reducing the power configuration of the gear used in that specific position. Waveform tests Test setup For the waveform group of tests, we will use a setup consisting of the EMVCo reference PICC along with an oscilloscope and a PC software to evaluate the signal obtained from the oscilloscope. In our case, we will use the Wave Checker software from CETECOM. We need to connect the output J9 of the EMVCo reference PICC to the oscilloscope and set the jumper J8 of the EMVCo reference PICC in the fixed load position. The oscilloscope needs to be connected to the PC or laptop, so the software is able to get the waveform and analyze the parameters needed. Type A tests The waveform group of tests for Type A consists of the following test cases: TA121: t1 TA122: Monotonic Decrease TA123: Ringing TA124: t2 TA125: t3 and t4 TA127: Monotonic Increase TA128: Overshoot Some of these test cases are directly related to the parameters defined for the specific modulation phase for Type A at 106 kbps. This modulation phase along with the respective parameters is depicted in the figure below. When the Wave Checker gets the oscilloscope capture, it automatically analyzes the signal, performing all the measurements and comparing them with the specifications limits. Debugging hints for Type A The PN5180 has a few registers and parameters to control the wave shape generated by the NFC chip and transmitted by the antenna. These are the most relevant ones: TX_CLK_MODE_RM (RF_CONTROL_TX_CLK register) Rise and Fall times (RF_CONTROL_TX register) TX_OVERSHOOT_CONFIG register From all the different test cases we will show how to debug the t3 and t4 test case as it is usually the most problematic. For this purpose, we will start from a certain configuration where the waveform tests show the following results, with a fail in the t3 and t4 test case. In order to tackle this problem, we will rely on the TAU_MOD_RISING parameter from the RF_CONTROL_TX register of the PN5180. In this case, as the timings are slightly above the maximum allowed in the specifications we will decrease the TAU_MOD_RISING 3 points and execute again the tests. The results after the modification show that all test are passing with a certain margin:   Another parameter that the PN5180 has and can be used for the waveform tests is the TX_CLK_MODE_RM parameter from the RF_CONTROL_TX_CLK register. Below you can see two graphs that clearly illustrate the effect of this parameter over the waveform.  As you can see from the two figures, by changing the default high impedance configuration of 001, to a low side pull configuration the waveform results in a smoother decay of the envelope. Type B tests For Type B waveform, the specifications define the following test cases:  TB121: Modulation Index TB122: Fall time TB123: Rise time TB124: Monotonic Increase TB125: Monotonic Decrease TB126: Overshoots TB127: Undershoots Again, these tests are based on the different parameters that can be identified for the modulation phase of the Type B commands: Debugging hints for Type B The register and parameters that the PN5180 includes to control the waveform for type B are: TX_RESIDUAL_CARRIER (RF_CONTROL_TX register) TX_CLK_MODE_RM (RF_CONTROL_TX_CLK register) TX_UNDERSHOOT_CONFIG register TX_OVERSHOOT_CONFIG register For Type B, we will study the modulation index test case, as it is the one that needs to be adjusted more often. In this case, we start from a situation where the device presents problems in the modulation index at 1 cm, with a value below the limit. In order to make corrections of the modulation index we will use the TX_RESIDUAL_CARRIER parameter from the RF_CONTROL_TX register. This parameter controls the amplitude of the residual carrier during the modulated phase. For the present problem, we will increase it by 4 points and rerun the test. As you can see in the picture below, the modulation index is within the specifications limits with margin.  Adaptative Waveform Control The PN5180 has another interesting feature called Adaptative Waveform Control that is used to set a different transmitter configuration depending on the gear and protocol used at any moment. This way we can easily debug by positions and use specific configurations for a certain group of positions without the need of rerunning all the tests for the rest of the positions. With the AWC feature we can control the: TAU_MOD_FALLING TAU_MOD_RISING TX_RESIDUAL CARRIER We can see in the table an example of an AWC configuration for Type B. Where we have changed the Residual Carrier from gear 2 onwards. As you can see, It is also configured with a change in the falling and rising times from Gear 1. As you can see this Adaptative Waveform Control feature along with the DPC represent a powerful tool to easily debug waveform tests without a change in the HW. Reception tests The reception tests purpose is to evaluate the ability of the device to identify and correctly demodulate the responses from the PICC when this response comes in the limits of the specifications for amplitude and polarity of the modulation.  Tests setup The tools and setup needed to debug the reception tests for EMVCo are depicted in the following figure: Oscilloscope to capture the signal received by the reference PICC. Arbitrary Waveform Generator to generate the response of the PICC. PC Software to control the AWG and load the EMVCo responses to the EMVCo reference PICC. For our case, we will use the Wave Player software from CETECOM. EMVCo reference PICC. This time, we will use the output J9 of the reference PICC to the oscilloscope to capture the command from the reader and trigger the injection of the response from the waveform generator to reference PICC, connected to J2. We should connect the waveform generator to the computer that has the Wave Player software installed to load the EMVCo responses. Performing tests As said previously, the reception tests aim at testing the ability of the device to correctly interpret the response when it is generated at the limit of the amplitude and polarity of the modulation. Considering the positive and negative polarity and the maximum and minimum amplitude of the modulation we have the following four test cases that are performed both for Type A and Type B: Tx131: Minimum positive modulation Tx133 - Maximum positive modulation Tx135 - Minimum negative modulation Tx137 - Maximum negative modulation To debug these tests with the PN5180 we will use: RX_GAIN (RF_CONTROL_RX register) RX_HPCF (RF_CONTROL_RX register) MIN_LEVEL (SIGPRO_RM_CONFIG register) MIN_LEVELP (SIGPRO_RM_CONFIG register) The procedure is basically to use the Waveplayer to set the amplitude and polarity of the response and check in the device is the response was correctly received and demodulated. Debugging hints To debug the reception we will test different configuration for the RX_GAIN and RX_HPCF parameters that control the reception filters, amplifier and ADC blocks from the receiver branch. These receiver blocks are pictured in the diagram below. Depending on the values used for the RX_GAIN and RX_HPCF parameters, the filter will be defined accordingly. The following table shows the filter characteristics in relation to those values: If we don’t find a correct value to pass the test at a certain position, we should modify the Rx resistor in order to increase or decrease the receiver sensibility. Adaptative Receiver Control In the same line as the Adaptative Waveform Control, the PN5180 includes the Adaptative Receiver Control that can be used to define different reception configurations depending on the gear and protocol used. With the ARC we can control all the registers involved in the reception and apply a correction to the preconfigured value depending on the gear used.  We can see an example of the Adaptative Receiver Control configuration in the following table, where we have defined a correction of -1 to the MIN_LEVEL and the HPCF parameters from gear 1. We can also see that the RX_GAIN parameter has a correction of +2 from gear 0. The ARC is very useful when we can't find a proper configuration for all positions and we need a different set of values depending on the positions tested. Rx Matrix tool Another interesting tool for debugging the reception tests is the Rx Matrix tool. This tool is used to launch and tests different receiver configuration in an automated way. The Rx Matrix tool is integrated into NXP's NFC Cockpit and you can control the Arbitrary Waveform Generator to set the amplitude of the modulation used for the tests. We can select which parameters we want to change and in which range we want them to be tested and the Rx Matrix will automatically run all the possible combinations in a sweep.   With the Rx Matrix tool, we can select the expected response and the number of iterations we want to try for every possible configuration. That way we can obtain a success ratio for the communication and easily identify the best configuration for the position tested. An example of the Rx Matrix is given in the figure below. We have fixed the RX_GAIN and RX_HPCF parameters and performed a sweep for the MinLevel, testing it from a value of 0 to 8. We have set the Rx Matrix to execute 50 iterations for every configuration, obtaining the success ratio results plotted below. As you can see the Rx Matrix along with a Waveform Generator is a powerful tool to find the optimum receiver configuration in a short time and in an effortless way. PN5180 Ecosystem The PN5180 comes with a complete and useful product support package including: The demokit, that can be used to get introduced to the product and check its features. The NFC Cockpit, that we have talked about during this article, and that represents a powerful tool to control the PN5180 with a very intuitive and useful interface. We srongly recommend that you integrate this tool in your final device as it may save you a lot of time during the debugging phase. A complete documentation including the updated product datasheet, or a set of application notes to guide you through all the designing process, from the antenna design guide to the DPC configuration or use of the Rx Matrix tool. Last but not least, the NFC Reader library which is the recommended software stack for NXP's NFC frontends and NFC controllers with customizable firmware. NFC Reader Library The NFC Reader Library comes with built-in MCU support, but it can also run on different MCU platforms, as well as non-NXP. The library has been built in such a way that you can adapt it and implement the required driver for your host platform. Other characteristics are: It is free of charge and you can download the latest release from NXP’s website. It is a complete API for developing NFC and MIFARE-based applications. Includes an HTML-based API documentation for all the components, which is generated from source-code annotations.  Finally, the release includes several examples and applications. Among the examples and applications included in the NFC Reader Library we can highlight two applications that are very useful for the preparation of the Device Test Environment required for the EMVCo certification:  The SimplifiedAPI_EMVCo for the digital testing The SimplifiedAPI_EMVCo_Analog for the Analog testing. You can control all the parameters involved in both applications using the phNxpNfcRdLib_Config.h configuration file. The identification and modification of these parameters should be very easy as the code is well documented, like you can see in the code chunk in the image: Further information You can find more information about NFC in: Our NFC everywhere portal: https://www.nxp.com/nfc You can ask your question in our technical community: https://community.nxp.com/community/identification-security/nfc You can look for design partners: https://nxp.surl.ms/NFC_AEC And you can check our recorded training: http://www.nxp.com/support/online-academy/nfc-webinars:NFC-WEBINARS Video recorded session

Description Earlier this year NXP organized a promotional opportunity for amateur radio enthusiasts to use their creativity and build their own power amplifier designs. NXP received numerous creative submissions in this competitive Homebrew RF Design Challenge. We appreciate the dedication and enthusiasm from the community that made this contest a success. First place winner An MRF101AN broadband amplifier design with 1 W Input, 100 W Output 1.8-54 MHZ Amplifier deck. (For more information visit:NXP MRF-101 - RFPowerTools )  It is an amplifier with a bandwidth of 1.8MHz to 54MHz. Maximum output power of 100W up to 30MHz and 70W up to 50MHz. Maximum power supply 50V to 4A, with a Voltage Standing Wave Ratio of 1.5:1 maximum. The design dimensions of the PCB is 5x5 cm (2x2 in). and 310g weight including fan and heat sink. Second place winner A 600W broadband HF amplifier using affordable LDMOS devices (For more information visit: https://qrpblog.com/2019/10/a-600w-broadband-hf-amplifier-using-affordable-ldmos-devices/  ) This project is meant to demonstrate the capabilities of the MRF300 transistors as linear broadband devices in the 2-50MHz range and to be used by radio amateurs as a starting point for a medium-high power amplifier. This is also my entry to the NXP Homebrew RF Design Challenge 2019. To achieve the target of 600W output while also minimizing the level of even-number harmonics, a “push-pull” configuration of two transistors is used. Luckily, the manufacturer made it easy to design the PCB layout for such a thing by offering two versions (the MRF300AN & MRF300BN) that have mirrored pinout. The common TO-247 package is used, with the source connected to the tab. Each individual MRF300 LDMOS transistor is specified at 330W output over a 1.8-250MHz working frequency range, a maximum 28dB of gain and over 70% efficiency. The recommended supply range is 30-50Vdc. By studying the specifications, it looks like with correct broadband matching and some operational safety margin we can get close to 600W output at a voltage of around 45V across a resonably large bandwidth; the aim is to cover 1.8 to 54MHz. Main challenges when designing this amplifier are related to achieving good input and output matching over the entire frequency range as well as maintaining high and flat gain. Good linearity and a low level of harmonic products are mandatory. As the TO-247 is not a package specifically designed for high-power RF, there are some challenges with thermal design and PCB layout as well. Information taken from the essay by the winner. Third place winner A High Efficiency Switchmode RF Amplifier using a MRF101AN LDMOS Device for a CubeSat Plasma Thruster (For more information visit: Research - SuperLab@Stanford ) The Class E amplifier utilizes the active device as a switch, operating in only cutoff (off) and saturated (on) conditions. This minimizes the overlap of voltage and current, reducing losses in the active device. To further reduce loss the Class E amplifier utilizes an inductively tuned resonant network to achieve zero voltage switching, bringing the voltage across the switch to zero before turn on, eliminating energy stored in the output capacitance of the active device that would otherwise be dissipated. This is achieved with an inductively tuned series resonant output filter.  In the Class E amplifier losses are almost entirely determined by the current conducted by the active device so a high drain impedance is desired to maximize efficiency. The drain impedance is ultimately limited by the voltage rating of the switch. For our desired output power of 40W and the maximum voltage rating of 133V for the MRF101AN this impedance is still less than 50 ohms, so a L match circuit is used to match the drain impedance to 50 ohms. The load network in our design provides a drain impedance of 15.4+12.8j. As the MRF101AN will operate in saturation a high drive level is desired. To eliminate the need for a preamplifier and allow for digital control, we use a high speed gate drive chip typically used in switch-mode power supplies, LMG1020, to drive the MRF101AN instead of a RF preamplifier. A resonant network is used to provide voltage gain at the fundamental and third harmonic, providing a quasi-square wave on the gate which helps insure the device remains in saturation. Conclusion It was a close call and highly competitive! Each participant had their own creative, unique and impressive way of displaying the capabilities of these new parts. NXP is always up for new design challenges. Ready for the next challenge?

Most of the Ethernet PHY support multi-functions and provide much more flexible configure capability to fine tune timing or function enable by configure their registers. Ethernet PHY registers tool provide a simple way to read/write PHY registers by MDC/MDIO. This will help in development or issue debug. 

Description Drones, Rovers, and other Unmanned Vehicles (UVs) are being utilized across various industries including first responders, municipalities, and agriculture, as well as continued support and system development for the Department of Defense. As time progresses, more exciting practical uses are being uncovered. Whether the system is expected to deliver special payloads or protect people from malicious activities, UV systems require a high level of security, reliability, and performance. Block Diagram Products Category Name Product URL Microprocessor QorIQ® Layerscape Processors Based on Arm® Technology | NXP  Secure Authenticator A1006 | Secure Authenticator IC: Embedded Security Platform | NXP  A71CH | Plug and Trust for IoT | NXP  Motor Controllers (MCU) Arm® Cortex®-M7|Kinetis® KV5x Real-time Control MCUs | NXP  Arm® Cortex®-M4|Kinetis KV4x Real-time Control MCUs | NXP  i.MX RT1020 MCU/Applications Crossover Processor | Arm® Cortex-M7 | NXP  i.MX RT1050 MCU/Applications Crossover Processor| Arm® Cortex-M7, 512KB SRAM | NXP  i.MX RT1060 MCU/Applications Crossover Processor | Arm® Cortex®-M7, 1MB SRAM | NXP  Motor Controllers (DSC) MC56F84xxx|Digital Signal Controllers | NXP  Performance Level Digital Signal Controllers, USB FS OTG, CAN-FD | NXP  MC56F82xxx | NXP  Radar MCU S32R Radar Microcontroller - S32R27 | NXP  Camera Sensor MCU i.MX RT1050 MCU/Applications Crossover Processor| Arm® Cortex-M7, 512KB SRAM | NXP  BLE MCU Arm® Cortex®-M0+|Kinetis® KW41Z 2.4 GHz Bluetooth Low Energy Thread Zigbee Radio MCUs | NXP  Electronic Speed Controller MCU Arm® Cortex®-M4|Kinetis KV4x Real-time Control MCUs | NXP  Led Driver ASL150ySHN | Single-phase Auto LED Boost Driver | NXP  AVB Switch SJA1105TEL | Five-Ports AVB and TSN Automotive Ethernet Switch | NXP  Battery Monitor MC33772 | 6-Channel Li-ion Battery Cell Controller IC | NXP  Wireless Charger 15 Watt Wireless Charging Transmitter ICs | NXP  Accelerometer Digital Sensor - 3D Accelerometer | NXP  Related Demos from Communities URL Hands-On Workshop: HoverGames Drone - Commercial Open-Source Small Autonomous Vehicle for Robotic Drones and Rovers  An NXP DroneCode Platform for Developing Low-Cost Small Autonomous Vehicles and Leveraging High-Reliability Automotive Components  Related Communities URL HoverGames Drone Challenge 

  Overview Factory automation systems connect with each other through robust communication paths and with the user through intuitive HMIs. To meet these needs and the demand for greener, more efficient industrial processes, these systems require ultra-reliable solutions for fast connectivity and solid security. NXP®, a longtime leader in industrial applications, enables flexible design cycles and provides industrial system designers with longevity programs and innovative security features. We’re focused on customer success, next-gen IoT tech and Industry 4.0. Computer numeric control (CNC) machines are electro-mechanical devices that manipulate machine shop tools using computer programming inputs. CNC is one of two common methods (3D printing is the other) to generate product (typically metal or plastic) from a digital software file. CNC is a subtractive technique; excess material is removed in manufacturing the final product. Block Diagram Products Category MPU Product URL Layerscape® 1028A Industrial Applications Processor  Product Description The Layerscape LS1028A industrial applications processor includes a TSN-enabled Ethernet switch and Ethernet controllers to support converged IT and OT networks.   Category Power Management Product URL MC34VR500: Multi-Output DC/DC Regulator  Product Description The NXP® MC34VR500 power management solution for network processor systems is a high-efficiency, quad buck regulator with up to 4.5 A output and five user-programmable LDOs.   Category Temperature Sensor Product URL SA56004X: SMBus-Compatible, 8-Pin, Remote/Local Digital Temperature Sensor  Product Description The NXP Semiconductors SA56004X is an SMBus compatible, 11-bit remote/local digital temperature sensor with over-temperature alarms.   Category USB Type C Product URL PTN5150: CC logic for USB Type-C applications  Product Description PTN5150 is a small thin low power CC Logic chip supporting the USB Type-C connector application with Configuration Channel (CC) control logic detection and indication functions.   Category Logic Controller Product URL NX5P2190UK: Logic controlled high-side power switch  Product Description The NX5P2190 is an advanced power switch with adjustable current limit. It includes under-voltage and over-voltage lockout, over-current, over-temperature, reverse bias and in-rush current protection circuits.

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

Description   The convergence of an aging population and breakthrough technological advances has created endless opportunities for automated medical devices. These devices help ensure the future health of millions of people by providing advances in diabetes care, cardiac care, therapy adherence and general health and wellness applications. Regardless of the end use, developers of healthcare/medicals devices face similar challenges–the need to balance processing requirements with power consumption, a fast time-to-market, secure wireless connections and product longevity.   The application patient monitoring senses the vital signs of a patient and displays them. If any of the vital signs drops below a secure range the device will send an alert to the medical staff. For the entry version of this application an i.MX 6 ULL applications processor is recommended for its low power consumption, touch screen driver integration and low cost. Features   Checks patient vital signs and uploads them to the cloud Quick alerts if the patient is in danger Gathers the information of all the sensors in the human body Secure wireless connections Displays vital signs   Block Diagram       Products   Category Name 1: MCU and MPU Product URL 1 i.MX 6ULL Applications Processor | Single Arm® Cortex®-A7 @ 900 MHz | NXP  Product Description 1 The i.MX 6ULL applications processor includes an integrated power management module that reduces the complexity of an external power supply and simplifies power sequencing. Product URL 2 i.MX 6Quad Applications Processors | Quad Arm® Cortex®-A9 | NXP  Product Description 2 The i.MX 6 series of applications processors combines scalable platforms with broad levels of integration and power-efficient processing capabilities particularly suited to multimedia applications. Product URL 3 Arm® Cortex®-M0+|Kinetis® KM1x 50 MHz 32-bit MCUs | NXP  Product Description 3 The Kinetis® KM1x supports high-precision internal voltage reference with low temperature drift.   Category Name 2: Power Management Product URL 1 PMIC with 1A Li+ Linear Battery Charger | NXP  Product Description 1 The PF1550 is a Power Management Integrated Circuit (PMIC) designed specifically for use with i.MX processors on low-power portable, smart wearable and Internet-of-Things (IoT) applications. Product URL 2 14-Channel Configurable Power Management IC | NXP  Product Description 2 The PF0100 SMARTMOS PMIC provides a highly programmable/configurable architecture, with fully integrated power devices and minimal external components. Product URL 3 MC33772 | 6-Channel Li-ion Battery Cell Controller IC | NXP  Product Description 3 The MC33772 is a Li-Ion battery cell controller IC designed for automotive and industrial applications such as HEV, EV, ESS, UPS systems.   Category Name 3: Audio Product URL 1 Ultra-Low-Power Audio Codec | NXP  Product Description 1 The SGTL5000 is a low-power stereo codec is designed to provide a comprehensive audio solution for portable products that require line-in, mic-in, line-out, headphone-out and digital I/O. Product URL 2 TDA8932B | NXP  Product Description 2 The TDA8932B is a high efficiency class-D amplifier with low power dissipation.   Category Name 4: Peripherals Product URL 1 TJA1101 | 2nd generation PHY Transceiver | NXP  Product Description 1 TJA1101 is a high-performance single port, IEEE 100BASE-T1 compliant Ethernet PHY Transceiver. Product URL 2  PCF85263A | NXP  Product Description 2 The PCF85263A is a CMOS Real-Time Clock (RTC) and calendar optimized for low power consumption and with automatic switching to battery on main power loss.   Product URL 3 -50 to 50kPa, Differential and Gauge Pressure Sensor | NXP  Product Description 3 On-chip, bipolar op amp circuitry and thin film resistor networks to provide a high output signal and temperature compensation   Documentation Designing a Homemade Digital Output for Analog Voltage Output Sensor: https://www.nxp.com/docs/en/application-note/AN1586.pdf    Product Link MCIMX6ULL-EVK: Evaluation kit for the i.MX 6ULL and 6ULZ Applications Processor MCIMX6ULL-EVK|i.MX6ULL Evaluation Kit | NXP  FRDM-PF1550EVM: PF1550 Evaluation Board for low power application processors FRDM-PF1550EVM | PF1550 Evaluation Board | NXP  SABRE for Automotive Infotainment Based on the i.MX 6 Series SABRE|Automotive-Infotainment|i.MX6 | NXP  KITPF0100EPEVBE: Evaluation Kit - MMPF0100, 14 Channel Configurable PMIC EVB- MMPF0100, 14 Channel Configurable PMIC | NXP  TWR-KM34Z50M: Kinetis M Series Tower System Module TWR-KM34Z50M|Tower System Board|Kinetis MCUs | NXP  KITSGTL5000EVBE: Evaluation Kit - SGTL5000, Low Power Stereo Codec SGTL5000, Low Power Stereo Codec EVB | NXP  FRDM33772BTPLEVB: Evaluation Board for MC33772 with Isolated Daisy Chain Communication FRDM33772BTPLEVB | MC33772 TPL EVB | NXP  OM13516UL: PCF85263B Evaluation board OM13516UL: PCF85263B Evaluation board | NXP 

  i.MXRT系列具有内部ROM，并且ROM中暴露出了一些功能接口可供用户直接使用。 本文介绍了Flexspi Nor ROM APIs, 并且列举了API相关的参数及示例程序。 通过这些API可以很方便的操作外部Flexspi Nor Flash。用户无需关系细节。   Products Product Category NXP Part Number URL MCU MIMXRT1060 https://www.nxp.com/products/processors-and-microcontrollers/arm-microcontrollers/i-mx-rt-crossover-... MCU MIMXRT600 https://www.nxp.com/products/processors-and-microcontrollers/arm-microcontrollers/i-mx-rt-crossover-...   Tools NXP Development Board URL i.MX RT1060 Evaluation Kit https://www.nxp.com/design/development-boards/i-mx-evaluation-and-development-boards/mimxrt1060-evk-... i.MX RT600 Evaluation Kit https://www.nxp.com/design/development-boards/i-mx-evaluation-and-development-boards/i-mx-rt600-eval...   SDK SDK Version URL MCUXpresso SDK Builder https://mcuxpresso.nxp.com/en/welcome

  Overview Industrial control is a key element in any factory automation process. It may vary from a simple panel-mounted controller to large interconnected and interactive distributed control systems. This small form factor board target applications that require low power, low costs, and high performance. This solution is based on aLS1028A Industrial Application Processor. This processor includes two powerful 64-bit Arm®v8 cores that can support real-time processing for industrial control, as well as virtual machines for edge computing in the IoT.  NXP is your ideal partner for factory automation. From embedded hardware to software solutions, our industrial expertise and innovative spirit enable you to meet the highest expectations of industry 4.0 and industrial IoT markets. Use Cases Our portfolio enables the next generation of smart factories from edge to cloud. We enable industrial applications at all layers of factory automation. Our technology implements secure connections from manufacturing level up to the cloud. Some applications are: Manufacturing Logistics Operations Management Edge-Cloud Block Diagram Product Category MPU Product URL Layerscape® 1028A Industrial Applications Processor  Product Description The Layerscape LS1028A industrial applications processor includes a TSN-enabled Ethernet switch and Ethernet controllers to support converged IT and OT networks.   Category RTC Product URL PCF85063A: Tiny Real-Time Clock/calendar with alarm function and I2C-bus  Product Description The PCF85063ATL is a CMOS Real-Time Clock (RTC) and calendar optimized for low power consumption. An offset register allows fine-tuning of the clock.   Category Power Management Product URL MC34VR500: Multi-Output DC/DC Regulator  Product Description The NXP® MC34VR500 power management solution for network processor systems is a high-efficiency, quad buck regulator with up to 4.5 A output and five user-programmable LDOs.   Category Transceiver Product URL TJA1101: 2nd generation Ethernet PHY Transceivers - IEEE 100BASE-T1 compliant  Product Description TJA1101 is a high-performance single port, IEEE 100BASE-T1 compliant Ethernet PHY Transceiver.   Category Display Port Product URL PTN3460/PTN3460I - Commercial and Industrial e(DP) to LVDS bridge IC  Product Description PTN3460 is an (embedded) DisplayPort to LVDS bridge device that enables connectivity between an (embedded) DisplayPort (eDP) source and LVDS display panel.  

  Overview With the expansion of IoT technologies, it is required to implement devices that allow a trusted environment for such technologies. This device allows to have a secure environment thanks to the use of the A71CL Secure Element, which provides a root of trust at the IC level and chip-to-cloud security while working with IoT technologies. Besides the A71CL, the implementation uses a i.MX 8M Mini in order to work with high performance and low power consumption. Block Diagram Products Category MPU Product URL i.MX 8M Family - Arm® Cortex®-A53, Cortex-M4, Audio, Voice, Video  Product Description The i.MX 8M family of applications processors based on Arm® Cortex®-A53 and Cortex-M4 cores provide industry-leading audio, voice and video processing for applications that scale from consumer home audio to industrial building automation and mobile computers.   Category Power Management Product URL PF1510: Power Management Integrated Circuit (PMIC) for low power application processors  Product Description The PF1510 is a Power Management Integrated Circuit (PMIC) designed specifically for use with i.MX processors on low-power portable, smart wearable and Internet-of-Things (IoT) applications.   Category Transceiver Product URL TJA1101: 2nd generation Ethernet PHY Transceivers - IEEE 100BASE-T1 compliant  Product Description TJA1101 is a high-performance single port, IEEE 100BASE-T1 compliant Ethernet PHY Transceiver.   Category Secure Element Product URL EdgeLock™ SE050: Plug & Trust Secure Element Family – Enhanced IoT security with maximum flexibility  Product Description The EdgeLock SE050 product family of Plug & Trust devices offers enhanced Common Criteria EAL 6+ based security, for unprecedented protection against the latest attack scenarios.

Demo Owner: b14714 The motor control development toolbox is a comprehensive set of tools that plug into the MATLAB™/Simulink™ model-based design environment for rapid application development on MCUs.  The SFIO Toolbox is a new addition that can control Simulink system models by SFIO algorithms running directly on NXP DSC and Kinetis MCU hardware. NXP FreeMASTER debug monitor and data visualization tool interfaces provide an interface to monitor signals in real time for data logging and signal calibration. Features The motor control development toolbox is a comprehensive set of tools that plug into the MATLAB™/Simulink™ model-based design Auto code generation straight to the Micro. NXP developed a library and embedded target to interface with MATLAB and SimuLink Customers can directly go from the model based environment to the MCU without having to write C code by hand Featured NXP Products Motor Control