Demo Advantages of i.MX6 Dual/Quad Plus Features Memory bandwidth utilization greatly improved On-die caches for GPU Multi-source GPU composition Featured NXP Products i.MX6DP i.MX6QP

Description A bicycle with an integrated electric motor and a rechargeable battery, making it an eco-friendly, zero-emission vehicle ideal for smart cities. An important feature of an E-Bike is that it must be reliable and can be used for long periods.   Block Diagram   Products Category Name 1: Microcontroller Product 1 URL 1 https://www.nxp.com/products/processors-and-microcontrollers/arm-microcontrollers/general-purpose-mcus/ke-series-cortex-m4-m0-plus/kinetis-ke02-20-mhz-entry-level-microcontrollers-mcus-based-on-arm-cortex-m0-plus-core:KE02 Product 1 Description 1 The Kinetis KE02 includes a powerful array of analog, communication and timing and control peripherals with specific flash memory size and the pin count. The K02 acts as a low-power, high-robustness, and cost-effective microcontroller with one 6-channel FlexTimer/PWM and two 2-channel FlexTimer/PWM. Product 2 URL 1 Arm® Cortex®-M4|Kinetis® K64 120 MHz 32-bit MCUs | NXP  Product 2 Description 1 Kinetis ®  K64-120 MHz, 256 KB SRAM Microcontrollers (MCUs) based on Arm ®  Cortex ® -M4 Core   Category Name 2: Gate driver Product 1 URL 1 https://www.nxp.com/products/power-management/motor-and-solenoid-drivers/bldc-h-bridge-stepper/3-phase-brushless-motor-pre-driver:GD3000 Product 1 Description 1 The GD3000 is a gate driver IC for three-phase motor drive applications providing three half-bridge drivers, each capable of driving two N-channel MOSFETs.   Category Name 3: LED Driver Product URL 1 https://www.nxp.com/products/power-management/lighting-driver-and-controller-ics/ic-led-controllers/16-channel-fm-plus-ic-bus-57-ma-20-v-constant-current-led-driver:PCA9955BTW Product Description 1 The PCA9955B is an I2C-bus controlled 16-channel constant current LED driver optimized for dimming and blinking 57 mA Red/Green/Blue/Amber (RGBA) LEDs in amusement products. Each LED output has its own 8-bit resolution (256 steps) fixed frequency individual PWM controller that operates at 31.25 kHz with a duty cycle that is adjustable from 0 % to 100 % to allow the LED to be set to a specific brightness value.   Category Name 4: Logic USB Type-C Configuration Channel Product URL 1 https://www.nxp.com/products/interfaces/usb-interfaces/usb-type-c-true-plugn-play/usb-pd-phy-and-cc-logic/cc-logic-for-usb-type-c-applications:PTN5150 Product Description 1 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. The PTN5150 enables USB Type-C connector to be used in both host and device ends of the Type-C cable   Category Name 5: Current-Limited Power Switch Product URL 1 https://www.nxp.com/products/power-management/load-switches/usb-pd-and-type-c-current-limited-power-switch:NX5P3290UK Product Description 1 The NX5P3290 includes under-voltage lockout, over-temperature protection, and reverse current protection circuits to automatically isolate the switch terminals when a fault condition occurs.   Category Name 6: Secure Product 1 URL 1 A71CH | Plug and Trust for IoT | NXP  Product Description 1 Plug and Trust - The fast, easy way to deploy secure IoT connections   Category Name 7: NFC Product 1 URL 1 PN5180 | Full NFC Forum-compliant frontend IC | NXP  Product Description 1 Full NFC Forum-compliant frontend IC   Category Name 8: GPIO Expander Product 1 URL 1 PCAL6534 | Level translating GPIO Expander | NXP  Product Description 1 Ultra-low-voltage, level translating, 34-bit I2C-bus/SMBus I/O expander   Category Name 8: NFC smartcard Product 1 URL 1 https://www.nxp.com/products/rfid-nfc/mifare-hf/mifare-desfire/mifare-desfire-ev2:MIFARE_DESFIRE_EV2_2K_8K Product Description 1 Secure, contactless multi-application IC with an enhanced feature set for Smart City applications Related Documentation   Document URL Title https://www.nxp.com/docs/en/application-note/AN10439.pdf Wafer-level chip-scale package https://www.nxp.com/docs/en/application-note/AN5322.pdf AN5322, TPMS wheel location introduction and main concepts Training Training URL https://community.nxp.com/docs/DOC-341509 Related Demos from Communities URL Kinetis Microcontrollers  MCUXpresso SDK  MCUXpresso Software and Tools  UAV Speed Control with Kinetis KV5x Cortex-M7 MCU and GD3000 Motor Pre-Drivers   

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

Demo The Automotive Magnetic Sensors demo will showcase the use of Rotational Wheel Speed Sensors for car ABS and Angular Sensors for Electric Throttle Control (ETC) as well as for Steering Angle measurement.     Features: NXP supplies magnetic sensors for rotational wheel speed and true angular measurement systems: ABS speed sensors with simple ferrites instead of expensive rare earth magnets, and with best in class jitter performance required for iTPMS, Angular sensors with outstanding accuracy of ±1˚ over full temp range and lifetime while operating in a wide temperature range up to 160 °C/320 °F. _______________________________________________________________________________________________________     Featured NXP Products: Sensors for Automotive|NXP _______________________________________________________________________________________________________     S01

This demo shows a demonstration of NXP's wireless charging reference design for a tablet computer.       Features Consumer and Automotive Applications Compliance with wireless power consortium QI standard Transfer efficiency Touch sensing Featured NXP Products WCT1000 Links Link to Wireless Charging Links to document page Block Diagram  

Littlevgl is a very good lightweight GUI software, which is convenient to use in MCU environment. This document describes how to port in I.MXRT environment, and how to modify LCD resolution and memory size in current SDK.

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

Demo The NXQ1TXH5 is a one-chip low power Qi transmitter, and it enables an ultra-low cost wireless charging transmitter dramatically reducing application cost while still providing latest WPC version 1.2 Qi compliant performance.   The NXQ1TXH5 demo is provided in an exciting form-factor with a backlight module on which Qi enabled phones can be charged. The demonstration shows the extremely low component count, which is interesting for professionals to understand, and at the same time showing a real-life eye-catching form-factor that draws non-technically skilled person attention. The demonstration challenges people to actually charge their phone and experience charging without wires.   One of the table modules is provided with a table-fan in which there is a Qi power receiver built-in. It can be used as a standby-demo to further draw attention to the demo, even when no phone is placed, and it avoids phones getting lost when there is no expert attending the demo.     The Qi wireless charging demo consists of a module that can be built into any table, using a 181mm round hole and it can simply be dropped into the hole. It is delivered with a universal mains power supply and hence easy to install. Below pictures show the Qi wireless charging table module demo, as well as dimensions to help building it into available infrastructure.   Demo / product features   Ultra low component count solution. Reducing application cost by 30-50% compared to other solutions Easy to layout on 2-sided PCB Excellent EMI behaviour without additional external filtering Ultra low standby power of 10 mW meeting 5-start smartphone charger standby rating High efficiency of 75% Excellent thermal behaviour due to NXPs proprietary low RDSon power silicon technology NXP Recommends   NXQ1TXH5 - Low cost version; contact your local sales representative for information on NXQ1TXL5

Demo Demo shows LS1021A-IoT gateway solutions for the Smart Home, Industrial and City with fog/Edge to Cloud connectivity  Secure: Secure Boot, Secure Debug, Tamper Detect, Trust Zone and Trust Architecture support Acceleration & Offload:  >2Gbps IPSEC encrypted traffic Performance HW Cryptographic Accelerators, CAN & QUICC Engine for industrial protocols Video Surveillance: Secure Network Video Surveillance with > 60 channels   Product Link LS1021A-IoT Gateway Reference Design LS1021A-IoT Gateway Reference Design | NXP 

Vital signs patient monitoring module using K60 Family MCU. Medical grade device, meets stringent safety / regulatory requirements Multi channel, real time data collection and processing:  Electrocardiogram, blood pressure, blood oxygenation etc. Usable as bed-side unit or part of distributed patient monitoring system This Project of Interest If You: Are interested in industrial medical products Are interested in real time analysis of live sensor data Description The module was developed as main functional part of portable patient monitor. It has a compact design, and unified serial interface to the host unit.  We developed it as a single board PC designed for main patient monitor application hosting and system purposes. The module provides comprehensive solution for patient vital signs monitoring. It has simplified connections, requiring only a power connection and a single data connection to the host or the distributed monitoring system. The design also meets the safety requirements for galvanic isolation of the patient. Kinetis K60 Family MCU was used as a core of this module, for data acquisition, signal preprocessing (digital filtration), data analysis and system tasks including extended supervisor functionality (with additional NIBP reserve/alarm system). The module has the following features: Module can be used in a bed-side unit, or part of a distributed monitoring system 7-lead electrocardiogram (ECG) (3-lead capable mode without RLD); Respiration rate (transimpedance on ECG lead I or lead II); SpO2 (oxygen saturation) using Nellcor OxiMax™ technology NIBP (noninvasive blood pressure) with patient adaptive fast measure mode for continuous monitoring, STAT mode; Body temperature, 2 channels Optional IBP (invasive blood pressure) up to 4 channels. This module meets all IEC safety requirements and is CE certified (as a part of patient monitor). Full Listing of Products/Components Protected by NDA IoT Physical Modules Sensors ECG / Respiration Blood oxygenation Blood pressure: invasive, non-invasive Body temperature Kinetis K60 MCU used for: Data acquisition Signal preprocessing and filtering Analysis, result output Supervisory functions Alarm generation IoT System Capabilities Under NDA

Connecting the Streets of Austin with Live V2X Demonstration – NXP FTF 2016 “Together with Siemens and Electric Cab of Austin NXP is showing how V2X and other connected technologies are going to change the face of our cities as we know them – making them more efficient, cleaner and less congested” Demo / product features V2X technology warns drivers of traffic hazards, increasing the safety for the driver, while taking people or objects into account, essentially “seeing around corners”. V2X technology warns drivers of traffic hazards even one mile ahead, increasing the safety for the driver, while taking people or objects into account, essentially “seeing around corners”. The strength of V2X comes from its ability to take control of traffic. V2X technology helps make roads safer and eases traffic by warning drivers and presenting alternatives when problems occur. For example, when only one lane is open, the V2X system controls on-coming vehicles with traffic lights to safely share the single lane. V2X will also advise drivers on optimal speed to pass the traffic light during a green phase and the remaining time of the green signal. V2X-enabled traffic lights detect pedestrians, cyclists and other vulnerable road users and signal for crossing vehicles to stop to allow the pedestrians to cross Transparent truck with IoT truck V2X – V2V Drone-to-car communication Emergency vehicle approaching Security – hacker use case Pedestrian crossing Real-time camera video streaming over 802.11p from IoT truck Vulnerable road user detection based on RFID tags and broadcast VRU warning via V2X NXP Recommends V2X comms RoadLink Chipset RF Transceiver (TEF5x00) Baseband IC (SAF5x00) Security IC (SXF1700) Dolphin 77GHz Radar Chip Ethernet Switch Videos

Demo Owner: Jeffrey Maguire See a complete multi-tenant data center platform running the OpenStack® cloud OS on QorIQ multicore SoCs.     Features Open Stack Cloud OS multi-tenant data center platform supporting NFV service chaining on QorIQ Processing Platforms P4080 / T4240 multicore ScCs IPTables / EBT Tables firewall as a cirtual service for tenant isolation HAProxy server load balancing as a virtual service   Featured NXP Products T4240: QorIQ T Series T4240/T4160/T4080 24/16/8 Virtual Core P4080: QorIQ P4080/P4040/P4081 Communications Processors with Data Path  

Description   An ultrasonic-based measurement or a camera implementation are a key part of applications dealing with non-contact object distance measurement and object detection, like an automotive parking distance sensor, blind spot detection and object detection. For an ultrasonic implementation, the S12ZVC integrates a 16-bit MCU, automotive voltage regulator, CAN physical layer, and high-speed timers with input capture and output compare, making it a single chip solution for low-end parking aid systems. For a camera implementation, the i.MX 8 applications processor along with the S32V234 vision processor offers the power required for image processing and intercommunication between multiple cameras and modules.   Features   Automotive voltage regulator CAN physical layer High speed timers with input capture and output compare Ultrasonic technology or cameras for the detection and avoidance of close objects   Block Diagram       Products   Category Name 1: MCU Product URL 1 S12ZVC Mixed-Signal MCUs|MagniV | NXP  Product Description 1 The S12ZVC platform, part of the S12 MagniV® mixed-signal MCU family, offers a low-cost, highly integrated solution that enables the design of smallest possible automotive CAN-termination nodes, while the family concept gives you scalability for platform design. Product URL 2 i.MX 8 Family Applications Processor | Arm Cortex-A53/A72/M4 | NXP  Product Description 2 Fast multi-OS platform deployment via advanced full-chip hardware virtualization and domain protection. Incorporate vision and speech recognition interactivity via a powerful vision pipeline and audio processing subsystem. Product URL 3 S32V234 Vision Processor | NXP  Product Description 3 The S32V234 MPU offers an Image Signal Processor (ISP), powerful 3D Graphic Processor Unit (GPU), dual APEX-2 vision accelerators, automotive-grade reliability, functional safety, and security capabilities for supporting computation intensive ADAS, NCAP front camera, object detection and recognition, surround view, and automotive image processing.   Category Name 2: Ethernet Product URL 1 SJA 110EL | Five ports AVB Automotive Ethernet Switch | NXP  Product Description 1 The SJA1105EL Ethernet switch offers a flexible solution for implementing modular and cost-optimized ECUs capable of supporting any in-vehicle connectivity requirement. Product URL 2 TJA1101 | 2nd generation PHY Transceiver | NXP  Product Description 2 TJA1101 is a high-performance single port, IEEE 100BASE-T1 compliant Ethernet PHY Transceiver. Product URL 3 TJA1102/TJA1102S | Automotive Ethernet Transceivers | NXP  Product Description TJA1102 (TJA1102S) is a highly integrated dual (respectively single) port, IEEE 100BASE-T1 compliant Ethernet PHY Transceiver.   Category Name 3: Power Management Product URL 1 PMIC for high-performance applications | NXP  Product Description 1 The PF8100/PF8200 PMIC family is designed for high-performance processing applications such as infotainment, telematics, clusters, vehicle networking, ADAS, vision and sensor fusion.   Category Name 4: CAN Product URL 1 TJA1057 | High speed CAN transceiver | NXP  Product Description 1 The TJA1057 is part of the Mantis family of high-speed CAN transceivers. It provides an interface between a Controller Area Network (CAN) protocol controller and the physical two-wire CAN bus.   Documentation S32R Radar Signal Compression: https://www.nxp.com/docs/en/application-note/AN5375.pdf    Tools Product Link DEVKIT-S12ZVC: Development Board for 9S12ZVCA192 MCU Evaluation DEVKIT-S12ZVC development platform for S12ZVC | NXP  MCIMX8QM-CPU: i.MX 8QuadMax Multisensory Enablement Kit (MEK) i.MX 8QuadMax/QuadPlus Multisensory Enablement Kit | NXP  S32V234EVB: S32V Vision and Sensor Fusion Evaluation System S32V Vision and Sensor Fusion Evaluation System | NXP  OM14500-TJA1102: Evaluation Board, TJA1102HN 100BASE-T1 Automotive Ethernet PHY TJA1102/S Evaluation Board | NXP  SJA1105Q-EVB: Ethernet Switch & PHY Evaluation Board. SJA1105Q-EVB | Ethernet Switch and PHY Evaluation Board | NXP 

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

Overview This reference design describes the design of a 3-phase BLDC (Brushless DC) motor drive, which supports the NXP® 56F80X and 56F83XX Digital Signal Controllers (DSCs). The speed-closed loop BLDC drive using a Hall sensor is implemented The system is targeted for applications in both industrial and appliance fields (e.g. washing machines, compressors, air conditioning units, pumps or simple industrial drives required high reliability and efficiency) Features Voltage control of BLDC motor using Hall sensor Targeted for 56F80X, 56F83XX, and 56F81XX Digital Signal Controllers Running on 3-phase Motor Board Control technique incorporates: Voltage BLDC motor control with speed-closed loop Current feedback loop Both directions of rotation Motoring mode Minimal speed 500 RPM Maximal speed 1000 RPM (limited by power supply) Manual interface (Start/Stop switch, Up/Down push button control, LED indication) FreeMASTER software control interface (motor start/stop, speed set-up) FreeMASTER software monitor Block Diagram Board Design Resources

Demo Summary This demo can read both 1D and 2D barcode information. Built from the NXP tower system, the demo utilizes the FlexIO camera driver provided by the Kinetis SDK to bring in image data. The data is analyzed by open source barcode reader software (ZXing).   Product features Fast processing of 1D or 2D codes utilizing the ARM Cortex-M4F at 120MHz. Simultaneous gray scale QVGA image capture and display in the Tower system. FlexIO camera driver utilized to interface to OV7670 camera module   NXP Recommends Product Link Kinetis® K8x Secure Microcontrollers (MCUs) based on Arm® Cortex®-M4 Core https://www.nxp.com/products/processors-and-microcontrollers/arm-microcontrollers/general-purpose-mcus/k-series-cortex-m4/k8x-secure:K8X-SCALABLE-SECURE-MCU?&cof=0&am=0 Freedom Development Platform for Kinetis® K82, K81, and K80 MCUs https://www.nxp.com/design/development-boards/freedom-development-boards/mcu-boards/freedom-development-platform-for-kinetis-k82-k81-and-k80-mcus:FRDM-K82F?&tid=vanFRDM-K82F QR Demo User's Guide https://www.nxp.com/docs/en/user-guide/QRDEMOUG.pdf?&fsrch=1&sr=1&pageNum=1

Cellular Freedom Quickly move sensor data to the cloud using the FRDM-K64F End-Device certified Skywire cellular modems provide a path to production Complete mbed code provided This Demo Is Probably of Interest If You: Need a quick proof of concept Have to demonstrate cellular connectivity to a customer or client Don’t want to build your own Thing for your IoT demo Differentiation - This Demo Highlights End-Device certified modems require no Carrier certifications to use on the cellular network XBee R footprint makes your design futureproof Global options for devices deployed or moved anywhere in the world Description The NXP FRDM-K64F is the development board for the NXP Kinetis series, providing an affordable, flexible way to build prototypes. For applications requiring cellular connectivity, the NimbeLink Sensor Shield plugs into the FRDM-K64F development board and, in turn, accepts a plug-in NimbeLink Skywire end-device certified cellular modem, providing quick cellular access. This first-in-the-industry plug-in cellular solution is easier and more compact than USB or other modem connection options, and the pre-certified Skywire embedded modem eliminates the cost and complexity of obtaining carrier certifications. The NimbeLink shield comes with four integrated MEMS sensors for easy proof-of-concept development. Sensors include an accelerometer, a temperature sensor, an atmospheric pressure sensor, light sensor, a humidity sensor, an accelerometer and two pushbutton switches. The shield also provides headers similar to those on an Arduino board. These accept any of hundreds of compatible expansion boards allowing the addition of capabilities like GPS, screens, motor controllers, and more. The NimbeLink Sensor Shield requires 5-12vdc power and accepts a variety of antennas. Full Listing of Products/Components Note: For full listing or additional information for Products/Components used in this demo see "This Demo's IoT Highlights" in Left Column. Note: If you aren't looking at this demo in the IoT Solutions Center, please use below link to access NXP IoT Solutions Center: https://community.freescale.com/community/iot-center/demos/skywire-m2mmanager-demo What this Demo is All About Video Link : 4994 IoT Physical Components Gateways Boards/Modules: FRDM-K64F Software: ARM mbed End User Products: NimbeLink Sensor Shield and Skywire Modem Wireless Connectivity End-Device certified Skywire cellular modem Sensors MEMS accelerometer, temperature, humidity and pressure sensors. Light sensor, potentiometer and pushbutton switches. Cloud Infrastructure/Services Verizon ThingSpace IoT System Capabilities Cloud/App Communications/Interworking See the data from your Sensor Shield in the cloud using the Verizon ThingSpace portal on any connected device. IoT Development Capabilities Embedded Platforms NimbeLink can help you customize your cellular product design to take advantage of the latest NXP advances in technology. IoT Product Type Product/Component Vendor Research or Procure This Product/Component End User Hardware Skywire Sensor Shield Commercial Skywire Sensor Shield End User Hardware Skywire end-device certified cellular modem Commercial Skywire Modem

Overview The NXP® Home Energy Manager (HEM) reference platform features an i.MX283 application processor, MC13224V ZigBee® module, 9S08QE32 MCU and MC34726 DC/DC buck. The reference platform is aimed at jumpstarting customer developments around the HAN (Home Area Network). Comprises a control board based on the low-power, yet powerful i.MX283 running connectivity interfaces to the: Smart meter Home automation system Broadband IP network User interface Micro-grid generation unit In order to accommodate a fast-paced changing connectivity landscape, the control board features extension connectors ready for: Powerline modems GPRS/3G data modem U-SNAP connectivity peripherals Mass storage cards Features Low-power Based on the latest low-power NXP ®  Arm9™ i.MX283  processor including integrated power management and supporting advanced voltage and frequency scaling techniques for optimized power consumption Running Our low-power ZigBee radio 1.5W max at full operating speed Low-cost Unique integration on the i.MX283 eliminates external components, enables 4-layer PCB Complete solution available Source code Hardware schematics Gerbers Bill of materials Complimentary software available through 3rd party partners Linux based frameworks Windows Embedded Compact 7 based framework Java-based framework Remote In-Home Display software Block Diagram Design Resources

Overview This NXP® reference design is a speed closed-loop BLDC drive using a sensorless technique that serves as an example of a BLDC motor control design using an NXP K60 MCU. Simple and easy to understand control approach to BLDC, using MQX in a time-critical application. Contains two versions of the application software, one with the MQX RTOS, and the other bare-metal The MQX version contains a web server to demonstrate the benefits of an MQX-based solution Both use the same source code for motor control Features BLDC motor control using the BEMF integration method for position determination Targeted for the TWR-K60N512 controller board Speed closed-loop with speed measurement Adjustable speed ramp Motor mode in both directions of rotation Minimum speed of 400 rpm Maximum speed of 4000 rpm Tested up to 30 rpm with a one-pole pair motor Overvoltage, Undervoltage and overcurrent fault protection FreeMASTER control interface Control via a web server Block Diagram Board Design Resources

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