Overview This reference design enables development of a vector control algorithm for a three-phase AC induction motor implemented on NXP® digital signal controllers MC56F8013/MC56F8023. Targeted mainly at consumer and industrial applications Cost-effective and highly reliable, the algorithm implements a single shunt current sensing, eliminating the need for more than one sensor High range of motor operating speeds up to 18000RPM An adaptive closed loop rotor flux estimator enhances control performance and increases the overall robustness of the system A reference manual provides a detailed description of the application, including a design of hardware and software Features 3-phase AC induction motor drive Designed to fit into consumer and industrial applications Uses 56F8013 or 56F8023 32 MIPS Digital Signal Controller Running on a 3-phase High Voltage Power Stage Control technique incorporating: Vector control of three-phase AC induction motor with position encoder Closed-loop speed control Both directions of rotation Both motor and generator modes Reconstruction of three-phase motor currents from DC-Bus shunt resistor Closed loop current control Flux and torque independent control Adaptive rotor flux space-vector estimator Field-weakening for high speeds High-speed range, max speed – 18000 RPM (2-pole motor) FreeMASTER software control interface (motor start/stop, speed setup) FreeMASTER software monitor FreeMASTER software graphical control page (required speed, actual motor speed, start/stop status, DC-Bus voltage level, motor current, system status) FreeMASTER software speed scope (observes actual and desired speeds, DC-Bus voltage and motor current) FreeMASTER software high-speed recorder (reconstructed motor currents, vector control algorithm quantities) DC-Bus overvoltage and undervoltage, overcurrent protection Block Diagram Board Design Resources

Demo Owner: Nik Jedrzejewski The PICO-IMX7-EMMC from TechNexion is a small footprint SOM equipped with a wide array of high-speed connectivity. ___________________________________________________________________________________________________________________ Featured NXP Products: i.MX 7 Series Applications Processors: Multicore, ARM® Cortex®-A7 Core, ARM Cortex-M4 Core External link Computex 2016

Introduction The FRWY LS1046A comes with the mikroBUS connector that enables the capability to connect different peripheral depending on the application's requirements. The mikroBUS intends to be used for prototyping purposes that facilitate the interconnection of several peripherals. The PN7120 I2C connection delivers a secure and trustworthy connection between both NXP products. Overview The following demo belongs to examples of different usages of the LS1046A MPU, these demonstrations will soon be part of the LSDK. This document showcase the NFC capability to provide an additional layer of security to any access area. NFC access points authorize people with a registered RFID tag to grant access to a particular area. In case the RFID tag isn’t registered or authorized, the access is restricted. The system should alert the denied access to a supervisor in order to take action. The video below shows two NFC applications that can be implemented in the LS1046A, by connecting the Mikroe-2395 module based on the NXP PN7120. This demonstration allows registering new users by entering sensitive data into a local database. The second application validates an NFC tag by comparing the tag ID, with the ones previously registered in the database. The user can access the applications using the LAN with another device like a tablet, this allows the database to be in a non-easy access location for security purposes. Block Diagram Video Products NXP Product Link FRWY LS1046A TP https://www.nxp.com/design/qoriq-developer-resources/ls1046a-freeway-board:FRWY-LS1046A Mikroe-2395 https://www.mikroe.com/nfc-click NXP NTAG 213/215/216 https://www.nxp.com/products/rfid-nfc/nfc-hf/ntag/ntag-for-tags-labels/ntag-213-215-216-nfc-forum-type-2-tag-compliant-ic-with-144-504-888-bytes-user-memory:NTAG213_215_216

Overview This reference design describes a 3-phase sensorless brushless DC (BLDC) motor control with back-EMF (electromotive force) zero-crossing detection, supporting the NXP® 56F80X and 56F83XX Digital Signal Controllers (DSCs) for motor control applications. It can also be applied to Our 56F81XX DSCs The system is designed as a motor drive system for three-phase BLDC motors and is targeted for applications in both industrial and appliance fields (e.g. compressors, air conditioning units, pumps or simple industrial drives) The reference design incorporates both hardware and software parts of the system including hardware schematics Features BLDC sensorless motor 115 or 230V AC Supply Targeted for 56F80X, 56F83XX, and 56F81XX Digital Signal Controllers Running on 3-phase BLDC Motor EVM at 12V, 3-Phase BLDC Low-Voltage Power Stage Speed control loop Motor mode in both direction of rotation Manual interface (RUN/STOP switch, UP/DOWN push buttons control, LED indication) Overvoltage, undervoltage, overcurrent and overheating fault protection Hardware autodetection FreeMASTER control interface (speed set-up) FreeMASTER software remote monitor Block Diagram Board Design Resources

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

Overview NXP brings a broad portfolio of proven PowerQUICC ®  network communications products, firmware and reference designs that support multiple network interfaces. These reference designs have the flexibility to integrate new features and are adaptable across product lines to protect your investment and maintain an edge over the competition. The NXP ®  MPC8323E-RDB is a turnkey hardware/software reference platform designed to rapidly provide the core elements of tomorrow's multiservice gateway products. Built on Power Architecture technology, the MPC8323E-RDB leverages the processing power of the MPC8323E PowerQUICC II Pro integrated communications processor. Features MPC8323E Integrated Multiservice Gateway features: Flexible WAN interfaces RJ45 100BT Ethernet and connectors for ADSL2+/VDSL2, WiMAX IPv4 Router with VPN capability RJ45 100BT Ethernet and connectors for ADSL2+/VDSL2, WiMAX Up to 640 DMIPS e300 CPU QUICC Engine ®  technology acceleration, 200 MHz Bridging/Routing with NAP/NAPT Firewall support (ACL) QoS for IPTV, VoIP and high-speed data VPN termination and pass-through Board Interfaces: Flexible network interfaces 10/100 Ethernet ADSL2+/VDSL2 WiMAX FXS ports (2) for analog phones 4-port 10/100 Ethernet LAN Two USB 2.0 host (480 Mbps) type A MiniPCI slots (2) Development Environment Our well established vertical ecosystem provides customers with the exact development flow they desire. The MPC8323E-RDB is kitted with: Encased CPE form factor board Linux ®  2.6 (LTIB) Design Resources

Overview The QorIQ® communications processors include single-, dual-, quad- and multicore processor architectures with integrated support for communications protocols such as EtherCAT. The new programmable logic controller (PLC) reference platform is equipped to ease development of industrial control systems PLC reference platform implements the KPA (koenig-pa GmbH) EtherCAT Master protocol with ISaGRAF Firmware and QNX Neutrino® RTOS on the high-performance QorIQ P1025 processor Supported by powerful development tools from all four companies, including the KPA EtherCAT Studio, ISaGRAF 6 Workbench, QNX Momentics® Tool Suite, and CodeWarrior® Development Suit Features Integrated ISaGRAF Firmware, KPA EtherCAT Master stack and QNX Neutrino RTOS on the QorIQ ®  P1 Tower ®  module EtherCAT master protocol and customer control application run simultaneously on a single QorIQ P1025 processor to deliver one millisecond EtherCAT master cycle time QorIQ P1 processors can also provide simultaneous support for complex applications, as well as additional industrial protocols like PROFINET, PROFIBUS and EtherNet/IP ™ Powerful development tools include the KPA EtherCAT Studio, ISaGRAF 6 Workbench, QNX Momentics Tool Suite, and CodeWarrior ®  Development Suite ISaGRAF 6 Workbench and Firmware kernel can fully support all IEC 61499 and IEC 61131-3 standard PLC programming languages Software and hardware developed on TWR-P1025 can be easily deployed on a range of QorIQ P1 processors, including the P1012, P1021, P1016 and P1025 processors QorIQ P1 processor family offers pin-compatible single-core variants for cost reduction, and dual-core variants which scale up to 3,700 million instructions per second (MIPS) for more complex control algorithms. Customers may distribute processing functions across two cores, or isolate real-time control functions on one core while running maintenance and communications functions on the other core. Commercial EtherCAT Master stack available from KPA Commercial Neutrino RTOS available from QNX Block Diagram Platform Requirements One TWR-P1025 QorIQ Tower Module Target slaves required to run the demo: Beckhoff EK1100 EtherCAT coupler Beckhoff EL1004 4-channel digital input terminal 24 V DC, 3 ms Beckhoff EL2004 4-channel digital output terminal 24 V DC, 0.5 A Beckhoff EL9011 end cap An image of the complete PLC Reference Platform run-time software. Download the PLC Reference Platform evaluation software. ISaGRAF 6 Workbench for offline tools Utility Software (Windows) TeraTerm for RS232 communications USB to UART driver for console port TFTP Server to load images to TWR-P1025 Design Resources

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

Overview of the Kinetis Microcontroller K70 and PEG graphics software development tool followed by a demo of the LCD Controller Module.      Features Graphical LCD Controller demo in the K70 Kinetis Microcontrollers Large Internal memory that could be used to drive LCD module, without needing external memory Support for B&W, Monochrome and Color LCDs (CSTN, TFT) 800x600 resolution with 24bpp Graphical LCD Drivers:  available: eGUI and PEG (Portable Embedded Gui) Featured NXP Products Graphic LCD MCUs: K7x EGUI: NXP eGUI: Graphical LCD Driver for MCUs/MPUs Block Diagram

Demo Benefits 1. More power – Higher voltage enables higher power density, which helps reduce the number of transistors to combine. 2. Faster development time – With higher voltage, the output power can be increased while retaining a reasonable output impedance. 3. Design Reuse – This impedance benefit also ensures pin-compatibility with current 50 V LDMOS transistors for better scalability. 4. Manageable current level – Higher voltage reduces the current losses in the system. 5. Wide safety margin – The higher breakdown voltage of 182 V improves ruggedness and allows for higher efficiency classes of operation Products MRFX1K80H MRFX1K80N MRF1K50H MRFE6VP61K25H Training 65 V LDMOS Introduction Related IMS MicroApps: The Latest High Voltage LDMOS Technology Delivers Industry’s Highest Output Power in a Single Package  Other Links NXP Announces New 65 V LDMOS Technology that Speeds RF Power Design 

Demo This demo shows how the FlexIO peripheral can be utilized to connect directly to an RGB TFT display to deliver a rich graphical display. The demo uses the versatile Tower ecosystem to connect the TWR-K80F150M MCU board to the display. The demo is well documented by an Application note and associated software     Features Dynamic Graphical LCD (480x272) with 16bt RGB interface Images stored in fast external Serial NOR flash FlexIO utilized to generate 16bit interface to TFT display with minimal CPU intervention   _______________________________________________________________________________________________________   Featured NXP Products: Product Link Kinetis® K80 MCU Tower® System Module TWR-K80F150M|Tower® System Board|Kinetis® MCUs | NXP  Graphical LCD Tower System Module with RGB Interface Graphical LCD Tower Module with RGB Interface | NXP  _______________________________________________________________________________________________________ Links AN5275: Using FlexIOhttp://cache.nxp.com/files/microcontrollers/doc/app_note/AN5275.pdf?fsrch=1&sr=1&pageNum=1 AN5280: Using Kinetis FlexIO to drive a Graphical LCD http://cache.nxp.com/files/archives/doc/app_note/AN5280SW.zip

Radar-detected Emergency Break via V2X to following traffic. RoadLink V2X platform, Ethernet Switch & 77GHz Radar Dolphin transceiver Features enabled by NXP Disrupting the market with an RFCMOS Radar-solution: •Highly integrated, minimal-footprint •Low Power Consumption •Sophisticated Functional Safety Features •Fully invisible mounting •Attractive System Cost Recommended Products •RoadLink Chipset •RF Transceiver (TEF5x00) •Baseband IC (SAF5x00) •Security IC (SXF1700) •Dolphin 77GHz Radar Chip •Ethernet Switch Resources Website http://www.nxp.com/products/rf/millimeter-wave-solutions/radar-technology:RADAR-TECH Video https://www.youtube.com/watch?v=H5eLhER9jZ4

Demo NXP’s new MRF13750H transistor delivers 750 W CW for 915 MHz applications. Based on 50 V silicon LDMOS, the MRF13750H is an attractive alternative to vacuum tubes for very high power industrial systems. Applications range from industrial heating/drying, curing, and material welding, as well as particle accelerators Product MRF13750H 750 W CW 915 MHz Applications Industry’s highest power for 915 and 1300 MHz 50 V LDMOS 915 MHz reference circuit 750 W CW Gain 19.5 dB Efficiency 63%

In this document you can find some pictures taken in the process of building the LED Panel.   Mounting the LED's:   First prototype for controlling only one LED strip using Level Shifter 74AHCT125: Final Panel:     Wiring LED's:     The interface board between LED stripes and the multiplexer board:   Interface board mounted: First test of the panel without multiplexer board : The multiplexer board using NXP CBT3257A:   Testing Mutiplexer board:     Adding the  Power  Supply and cables:   Panel  Test:     Part 2: LED control method using the FlexIO Or Return to Project page: LED Panel control with FlexIO Product Link Freedom Development Platform for Kinetis® K82, K81, and K80 MCUs FRDM-K82F|Freedom Development Platform|Kinetis® MCUs | NXP 

  Overview The Point of Sale reference design demonstrates how the control, security, and connectivity features found on the NXP ®  MCF5329 ColdFire ®  MPU and MCS908QG8 MCU work together to create a secure Industrial Point of Sale System. Complete with an Open Source Embedded Linux® Software Solution, the Point of Sale Reference Design serves as a reference for any industrial design that requires flexible connectivity options, secure communication, or a human interface at a low cost and with a fast development cycle. Archived content is no longer updated and is made available for historical reference only.   Features The Point of Sale Reference Design was designed with the following considerations: Low system cost Easy and intuitive graphical user interface Multiple connectivity solutions to accommodate various POS system connectivity requirements Secure networking communications, transactions, and memory accesses Fast development cycle The Industrial Point of Sale Reference Design also features an Open Source Software Solution: µCLinux Operating System running on the MCF5329 Microprocessor NanoX Graphical User Interface (GUI) Configuration Tool running in the µCLinux environment Communication protocol for secure ethernet transactions MySQL Server Database used to store/access sales transactions       Code Generation Tools Model-Based Design Toolbox Printed Circuit Boards and Schematics Point of Sale Reference Design Schematics Point of Sale Gerber Files (Reference Design)

Demo   SCM-i.MX6D is the smallest single chip system module integrating NXPs high end apps processor along with memory PMIC and Flash. Demo will show this small yet powerful module running graphics, android applications as well as other IoT/ portable applications. The SCM will be integrated with an external WiFi along with a sensor hub and will be demonstrating the SCM capability along with WiFi.     Features Ultra-small SCM i.MX 6D includes i.MX 6Dual, 16 MB SPI NOR flash, PMIC PF0100, 109 discrete devices, and enabled for 1 or 2 GB LPDDR2 Single 17 mm x 14 mm x 1.7 mm footprint Displaying a video game and Miracast using a Wi-Fi connection to a Smart TV   Featured NXP Products Single Chip System Modules (SCM) Single Chip Module i.MX 6Dual

Overview This reference design is based on 32-bit DSC MC56F84789, to demo a simple servo motor control solution. This reference design jump-starts your ability to leverage the NXP® DSCs' advanced feature sets via complete software, tools and hardware platform. Can be expended to dual servo motors control on single chip. Speed regulation: < 0.05% (from 0% to 100% load under nominal speed) with encoder and 32-bit speed control algorithm. Speed ratio: 1 : 2000 with position and speed closed loop control – intelligent PID, the minimal operational speed is up to 0.5RPM. Only low cost Quadrature Encoder (1000 lines) is required, HALL sensors removed. System dynamic response: 90Hz for speed closed loop, and 30Hz for position closed loop – PID regulator. Speed acceleration/deceleration: from 1 to 10,000ms (configurable). Brake function: regenerative braking, stop in one revolution. Bidirectional operation: forward and reverse with speed and torque limitation. Faults protection such as abnormal speed, over-/under-voltage, over-current etc. FreeMASTER software control interface and monitor. Features MC56F84789 Simple Servo Motor Control MAPS-56F84000 EVK Board MAPS-MC-LV3PH Motor Control Power Stage Block Diagram Board Design Resources

Demo See NXP breakthrough automotive designs using radar that enhance safety and the driver experience with ADAS and other safety applications Products S32R27 Radar Processor • CPU: Dual Z7’s with Lock-step Z4 enabling ASIL-D applications • Embedded memory: 2 MB Flash & 1.5 MB SRAM (both ECC) • Radar signal processing toolkit: best in class performance per power MR3003 Radar Transceiver • Fully integrated SiGe radar front end for 76-81 GHz • Tx 5-bit phase rotators, and Tx BPSK modulator • 3 transmitter and 4 receiver channels • ISO 26262 compliant – ASIL level B • Optimized for fast chirp modulation • Support for 4 GHz bandwidth TEF810X Radar Transceiver • Fully integrated RFCMOS radar front end for 76-81 GHz • 3 transmitter and 4 receiver channels • LVDS, CIF and CSI-2 interface • ISO 26262 compliant – ASIL level B • Lowest power: 1.2 W • Support for 4 GHz bandwidth

Overview Remote virtual smartphones promise the same benefits as remote computer desktops and cloud-based gaming: low-cost client hardware, sandboxed user environments, and persistent user state. The way they work is that the physical smartphone runs only thin-client software and the smartphone application runs remotely on a server. To be economical, this server hosts multiple of these virtual smartphones, taking advantage of hardware virtualization support built into its processor. Slotted into the machine, an add-on GPU provides high-performance graphics. To reduce latency for real-time gameplay, the server is best located near the end-user in the edge of the mobile network. For virtual smartphones to be compatible with physical smartphones, Arm compatibility is required. At the 2020 Consumer Electronics Show, NXP demonstrated the Layerscape LX2160A processor hosting Redfinger’s cloud-based Android emulator and virtual smartphone. NXP’s processor integrates 16 CPU cores, enabling it to host 16 or more virtual smartphones. Games and other software execute with the same look and feel as if they were running locally on a smartphone. Like other Layerscape processors, the LX2160A delivers excellent performance per watt and is designed to work in high-temperature environments, such as being packed densely in a rack in a data center or deployed remotely at an edge-computing site. Although NXP designed it for stringent embedded applications, the LX2160A processor is powerful enough for servers—making it a great solution for Android emulation.     Block Diagram NXP Products Name of Product QorIQ LX2160A Development Board | NXP    Related Documents from Community Name of Document Discover i.MX: Industry-Leading Processor Solution for Media, Smart Home, Smart Industrial, Health/Medical and Broad Embedded Applications    Related Communities Name of Document Layerscape 

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