Introduction LS1046A has four 32-bit/64-bit Arm® Cortex®-v8 A72 CPUs arranged as a single cluster of four cores. LS1046A shares a single 2 MB L2 with and maximum operation of 1.2 GHz, three PCI Express 3.0 controllers in a 23 mm x 23 mm package. Overview The following demo is part of a bundle of examples that shortly will be available in the LSDK. As can be seen in the video, there is a menu for the user to select the desired demo and start testing the different approaches the FRWY LS1046A TPU is capable of executing. This example intends to show the CPU performance according to CoreMark or Dhrystone metrics. This results in CoreMarks/mW or DMIPS performance running on the LS1046A. The user is able to select the number of cores to use for the test and then the results come out as Performance (Iterations/second) and Watts. This is intended to show the customers the LS1046A capabilities of pure CPU performance despite the oriented application. With a cost lower than 10 dollars per unit, the LS1046A returns 32,000 CoreMarks while consuming an average of 10 W working at 1.2 GHz. Block Diagram Video Products NXP Product Link FRWY LS1046A TP LS1046A Freeway Board | NXP 

Demo Owner: Neil Krohn NXP's MM9Z1_638 is a fully integrated battery monitoring device for mission critical automotive and industrial applications. An S12Z microcontroller, SMARTMOS analog control IC, CAN protocol module and LIN interface for communications functions are embedded into this single-package soltuion. The MM9Z1_^38 battery sensor measures key battery parameters for monitoring state of health, state of charge and state of function for early batteries as well as emerging battery applications, such as 14 V stacked cell Li-Ion, high voltage junction boxes, and 24 V truck batteries.     Features The MM9Z1_638 is a fully integrated battery monitoring device for mission critical automotive and industrial applications. An S12Z microcontroller, SMARTMOS analog control IC, CAN protocol module and LIN interface for communications functions are embedded into this single-package solution. The MM9Z1_38 battery sensor measures key battery parameters for monitoring state of health, state of charge and state of function for early batteries as well as emerging battery applications, such as 14 V stacked cell Li-Ion, high voltage junction boxes, and 24 V truck batteries. Featured NXP Products MM9Z1_638: Battery Sensor with CAN and LIN Product Features: Wide range battery current measurement; on-chip temperature measurement Four battery voltage measurements with internal resistor dividers, and up to five direct voltage measurements for use with an external resistor divider Measurement synchronization between voltage channels and current channels Five external temperature sensor inputs with internal supply for external sensors Low-power modes with low-current operation Links Freescale Concept Car  

Cloud-Connected Parking Spot Sensor Demo This demo shows a use case of the LS1021 IoT GW along with a FRDM-KW24 powered Magnetometer sensor to monitor the  car parking spot  locations such as garage parking  in a building, Traffic Management and Traffic Monitoring   The data can be reported and monitored from the Cloud. Features: Small footprint platform with a wide variety of high-speed connectivity and low-speed serial interfaces through the use of the ARM-based QorIQ LS1021A embedded processor. The  FRDM-KW2 sensor data is send via Thread to the LS1021 IoT GW and The Proximetry Agent posts information to cloud server. _______________________________________________________________________________________________________ Featured NXP Products: Product Link Freedom Development Platform for Kinetis® KW2x MCUs FRDM-KW24D512|Freedom Development Platform|Kinetis | NXP  LS1021A-IoT Gateway Reference Design https://www.nxp.com/design/designs/ls1021a-iot-gateway-reference-design:LS1021A-IoT?&lang_cd=en _______________________________________________________________________________________________________ N15

Overview   Artificial intelligence, and machine learning specifically, is transforming industries from Consumer to Industrial. To date, many applications host AI/ML inferencing on conventional computers in the cloud or locally. Meanwhile, edge computing is enabling other computing workloads to move from conventional information technology (IT) to lower-cost systems close to where data is generated. Although many AI/ML workloads run fine on edge systems’ CPUs, others are more intense: either multiple AI/ML functions must run simultaneously or performance requirements (e.g., frame rates) are too great. The solution to gaining the combined benefits of AI/ML and edge computing is acceleration. At the 2020 Consumer Electronics Show, NXP demonstrated the LS1046A-FRWY platform simultaneously running two or more high-intensity AI/ML functions. These include face recognition, object detection (both general and safety gear), posture recognition, and gaze detection. The scenario demonstrated is factory safety. An operator within a safety zone is monitored for attentiveness, personal protective equipment, and access control. Helping to make this possible is external acceleration based on the Google Edge TPU. Interfacing to the Layerscape LS1046A processor via its copious PCI Express ports, two M.2 TPU cards slotted in the FRWY system offload AI/ML inferencing. Based on the Layerscape LS1046A processor with four powerful Arm Cortex-A72 CPU cores, the compact, cost-effective LS1046A-FRWY platform gives developers a leg up on implementing high-performance AI/ML applications at the edge.   Diagram     Products Product Name LS1046A Freeway Board | NXP  Related Community Documents Document Name NXP Helps Industrial System Developers Apply AI/ML to Their Designs  Five Easy Steps To Deploy Machine Learning On Layerscape 

A sample refrigerator design with two microcontrollers.  The K70 controls the user touch display and while the MC56F8257 DSC manages and controls the compressor.     Features See how NXP ICs work together in this refrigerator reference design LCD controller Graphics controllers and touch sensing interface Graphics being driven by the Kinetis Microcontrollers K70 Compressor is controlled by a Digital Signal Controller (DSC) driving a sensorless permanent magnet vector control of the motor Featured NXP Products Product Link Kinetis® K7x Graphic LCD Microcontrollers (MCUs) based on Arm® Cortex®-M4 Core Kinetis® K7x Graphic LCD Microcontrollers (MCUs) based on Arm® Cortex®-M4 Core | NXP  Kinetis® K70-120–150 MHz, High-Speed USB, Ethernet, DDR and Anti-Tamper Microcontrollers based on Arm® Cortex®-M4 Core Arm Cortex-M4|Kinetis K70 120-150 MHz 32-bit MCUs | NXP  DSC MC56F8257 Motor Control Tower System Module DSC MC56F8257 Motor Control Tower Module | NXP  Links Digital Signal Controllers Kinetis MCUs based on ARM® Cortex®-M Cores  

Overview The Sub-GHz Remote Control Dimmer reference design based on the MKW01Z128 MCU operates in a custom IEEE 802.15.4 star network for home automation applications. Users can control various RGB bulbs connected to a network using the KW01-RCD-RD board as a remote control. Controlled devices are USB-KW019032 boards, and each board simulates an RGB bulb in a GUI. Features Low-cost MKW01Z128 sub-1GHz wireless node solution with an FSK, GFSK, MSK or OOK modulation-capable transceiver Reference design area with small footprint, low-cost RF node Unbalanced input/output port Flexible RF-Front End for different bands operation Programmable output power from -18 dBm to +13 dBm in 1dB steps (RFIO output) Integrated dual band chip antenna for 800MHz and 900MHz ISM bands Micro-miniature coaxial connector (MMCX) for conducted RF measurements Block Diagram Board Design Resources

Smart Pump Monitor Demo This demo shows a small water pump rig consisting of a water pump and 3 valves put together to collect data for supervised machine learning. Normal operation as well as abnormal conditions may be simulated with the rig. There are 2 sensor boards attached by clamps to the water pipe. Each sensor board has many sensors on it, but only the accelerometer will be used to gather the data. One board is used for data logging.  The other runs a model which was generated via machine learning based on data logged from the first board.  Pump vibration measurements are processed through the model by the MCU on that board to determine the operating state of the system Features Use of accelerometer to measure pipe vibration Sensing algorithm detects when the pump is clogged or drawing on air How to find patterns in data taken by NXP Sensors Links Sensor Fusion 10-Axis Sensor Data Logger http://www.nxp.com/files/sensors/doc/user_guide/RD-KL25-AGMP01-UG.pdf Related demos NXP Sensor Toolbox Demo Vibration Monitoring - Prediction using NXP Sensors Sensor Fusion for Kinetis MCUs

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

Description A gamepad is a device used to interact with a videogame through a PC or console.  This gamepad in particular, includes an LCD display and touch panel for a better gaming experience. In addition, as the play environment becomes more mobile and a game can easily be connected to any network (at a friend’s house, an Internet café, a community gaming center or even an amusement park) NXP offers secure, connected devices and technologies. Add in our sensing solutions with high-performance sensing capability, processing capacity and customizable software, power management ICs and wireless charging solutions to get a complete system solution.   Features   LCD Display Touch Panel NFC Pair BLE connectivity USB Type C LED driver Smart amplifier for speaker     Block Diagram       Products   Category Name 1: MCU Product URL 1 LPC546XX Microcontroller (MCU) Family | NXP  Product Description 1 Offering the ultimate in flexibility and performance scalability, the LPC546xx MCU family provides up to 220 MHz performance while retaining power-efficiency as low as 100 uA / MHz. Its 21 communication interfaces makes it ideal for the HMI and connectivity needs of next-generation IoT applications.   Category Name 2: Drivers Product URL 1 PCA9955BTW | NXP  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. Product link 2 9.5 V boosted audio system with adaptive sound maximizer and speaker protection | NXP  Product Description 2 The TFA9890A is a high efficiency class-D audio amplifier with a sophisticated speaker boost and protection algorithm. Product link 3 TEA172x | NXP  Product Description 3 These highly integrated devices enable low no-load power consumption below 10 mW, reduce component count for a cost-effective application design, and provide advanced control modes that deliver exceptional efficiency. Product link 4 Logic controlled high-side power switch | NXP  Product Description 4 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.   Category Name 3: USB Product URL 1 USB PD and type C current-limited power switch | NXP  Product Description 1 The NX5P3290 is a precision adjustable current-limited power switch for USB PD application. The device includes under voltage lockout, over-temperature protection, and reverse current protection circuits to automatically isolate the switch terminals when a fault condition occurs. Product link 2 PTN5150 | NXP  Product Description 2 The PTN5150 enables USB Type-C connector to be used in both host and device ends of the Type-C cable. It can support Type-C to USB legacy cables and adapters defined in USB Type-C Spec.   Category Name 4: Wireless Product URL 1 PN7150 | High performance NFC controller for smart devices | NXP  Product Description 1 PN7150 is the the plug andn play NFC solution for easy integration into any OS environment, reducing Bill of Material (BOM) size and cost. Product link 2  NTAG213F, NTAG216F | NFC Forum Type 2 Tag compliant IC with field detection | NXP  Product Description 2 The NTAG213F offers innovative functionalities such as: the configuration of a field detection, the SLEEP mode, the FAST_READ command, and a configurable password protection. These capabilities fit perfectly for applications in electronics that require the following features: connection handover, Bluetooth® simple pairing, Wi-Fi protected set-ups, device authentication or gaming. Product link 3 QN908x: Ultra-Low-Power Bluetooth Low Energy System on Chip (SoC) Solution | NXP  Product Description 3 QN908x is an ultra-low-power, high-performance and highly integrated Bluetooth® Low Energy (BLE) solution for Bluetooth Smart applications such as human interface devices, and app-enabled smart accessories.   Documentation Connecting TFT LCD with LCD controller of LPC MCU:  https://www.nxp.com/docs/en/nxp/application-notes/AN12027.zip    Tools Product Link OM13098: LPCXpresso54628 Development Board OM13098 | LPCXpresso Development Board | LPC Microntrollers (MCUs) | NXP 

Overview With over 35 million installed nodes, PROFIBUS is the world’s most successful communication technology used in industrial automation. Its growth and expansion is aided by the addition of PROFIBUS functionality to PowerQUICC® and QorIQ® communications processors. Integration of PROFIBUS Layer 2 creates a single-chip solution with a direct connection to a RS485 transceiver, eliminating cost and board space associated with an external PROFIBUS ASIC NXP® offers PROFIBUS Layer 2 firmware for PowerQUICC and QorIQ processors with a QUICC Engine® controller, eliminating the need for a costly PROFIBUS ASIC and leaving the processor core almost entirely free for processing Features PROFIBUS Reference Platform supports PROFIBUS Slave certified by ComDec, a PROFIBUS certification lab hosted by Siemens AG PROFIBUS Master Eliminates costly PROFIBUS FPGA or ASIC by running PROFIBUS Layer 2 (FDL) on QUICC Engine ®  controller hardware integrated inside the MPU Protocol and customer control application can run simultaneously on one chip Commercial PROFIBUS slave stack available from Technologie Management Gruppe (TMG) Evaluate using Tower ®  System modules (TWR-P1025-KIT) QorIQ ®  P1, T1 and LS1 processors can also provide simultaneous support for Industrial Ethernet protocols like PROFINET, EtherCAT and EtherNet/IP ™ PowerQUICCC MPC8309 processor delivers an impressive 835 DMIPS core performance for less than 1.6 watts Block Diagram Get Started Getting Started With NXP PROFIBUS for PowerQUICC and QorIQ NXP offers PROFIBUS Layer 2 firmware for PowerQUICC and QorIQ processors with a QUICC Engine controller. The PROFIBUS software supports both Master and Slave modes of operation and can be evaluated on the P1025 processor. Instructions for accessing the hardware evaluation platform and the software are given below. PROFIBUS for PowerQUICC and QorIQ can be evaluated using TWR-P1025-KIT To build/install/load the PROFIBUS software you will need CodeWarrior for Power Architecture V10.3 The PROFIBUS Slave package includes the following: CodeWarrior for Power Architecture V10.3 project archive containing: QUICC Engine PROFIBUS microcode (binary) PROFIBUS Layer 2 driver example (source code) PROFIBUS Layer 7 stack (binary provided by TMG) A sample application (source code) The /Docs folder of the project contains: Readme file Release Notes PROFIBUS Microcode User Manual NXP PROFIBUS Slave Layer 2 API description Sample test logs Software Getting Started Guide Hardware Getting Started Guide Design Resources

Overview This reference design is based on 32-bit DSC MC56F84789, to demo a 3in1 Air-Conditioner Outdoor Unit. This reference design jump-starts your ability to leverage the NXP ®  DSCs' advanced feature sets via complete software, tools and hardware platform. High performance, low cost all DC VF air-conditioner outdoor unit control system Three control objectives (interleaved single-phase PFC converter, fan and compressor) with one MCU device Input voltage range of 85 – 265VAC/40 – 70H Single-phase two channels interleaved PFC converter compatible with global mains input, 99.9% power factor, 8% input current THDi Sensorless FOC algorithm for both compressor and fan Anti-typhoon startup for fan, and on-line load torque compensation control for compressor to reduce system vibration and noise Reliable startup performance under full load and input voltage range Extreme low/high speed (from 1Hz to 150Hz) performance with extended flux observer Over-/under-voltage, over-current, over-temperature, over-input power protection and lock of rotor detection FreeMASTER GUI for easy debugging Features MC56F84789 3in1 Air-Conditioner Outdoor Unit Block Diagram Board Design Resources

电容式感应触摸按键可以穿透绝缘材料外壳，准确无误地侦测到手指的有效触摸。并保证了产品的灵敏度、稳定性、可靠性等不会因环境条件的改变或长期使用而发生变化，并具有防水和强抗干扰能力，超强防护，超强适应温度范围 电容式触摸按键控制芯片通常广泛适用于遥控器、灯具调光、各类开关以及车载、小家电和家用电器控制界面等应用中。芯片内部集成高分辨率触摸检测模块和专用信号处理电路，以保证芯片对环境变化具有灵敏的自动识别和跟踪功能。芯片还必须满足用户在复杂应用中对稳定性、灵敏度、功耗、响应速度、防水、带水操作、抗震动、抗电磁干扰等方面的高体验要求。本文将介绍一套基于NXP KE16Z64的轻量级TSI算法。 基于KE1XZ64平台的TSI轻量级算法： KE1XZ64继承了KE family的高可靠抗干扰性，并提供了更小的引脚封装尺寸，让客户硬件设计更加便利。其内部集成了改进版的TSI模块，性能更加稳定可靠，该模块支持自耦和互耦两种方式：自耦模式下最多可支持25个按键，互耦模式最多可支持36个按键，因此能够覆盖当前市场上绝大部分的触摸应用场景。 NXP官方的NT LIB软件虽然功能完善，但由于代码量大且程序架构复杂等原因，部分客户不愿意选用。所以该市场对于轻量级应用代码还是有需求的。 此参考设计展示了TSI轻量级算法的具体实现，按照配置模式分为两个对应的参考例程：自耦模式为12个按键的功能实现，硬件基于KE16 PCB，主要适用于按键所需数目少的应用场景；互耦模式为36个按键的功能实现，硬件基于RT-TSI-KE16，主要适用于按键所需数目多的应用场景。该算法精简可靠，十分易于移植，使客户可以很快地上手。并且可以结合使用NXP的GUI监测软件FreeMaster，方便中后期的灵敏度调试及问题追踪。 此套算法在实验室通过了IEC61000-4-6注入电流可靠性测试。 参考代码及说明文档请详见附件压缩包。

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

Demo This solution showcases the i.MX 6QuadPlus along with the MMPF0100 Power Management to enable the 2D/3D cluster, infotainment and rear view camera.      Features: High performance smooth 3D graphics based on the i.MX 6QuadPlus applications processor running on Linux. On the fly rendering of the infotainment menu. Seamlessly integrate extremely responsive instruments and highly complex 3D content Optimal usage of the CPU and GPU to achieve high-end graphics on the power effective and system cost effective i.MX Switch between HD video playback and the rear view camera on the secondary display Menu can be blended over the map (BG layer) using transparency   _______________________________________________________________________________________________________________________ Featured NXP Products: Product Link i.MX 6QuadPlus Processor i.MX 6QuadPlus Applications Processors | Quad Arm® Cortex®-A9 with extreme graphics performance and enhanced power manag…  i.MX 6DualPlus Processor i.MX 6DualPlus Applications Processors | Dual Arm Cortex-A9 for extreme graphics performance| 1.2 GHz | NXP  14-Channel Configurable Power Management IC 14-Channel Configurable Power Management IC | NXP  SABRE for Automotive Infotainment Based on the i.MX 6 Series SABRE|Automotive-Infotainment|i.MX6 | NXP    _________________________________________________________________________________________________________________________   Screen shot 1: Cluster with 3D maps Real-Time 3D map (created in Blender): 640 abstract buildings. 20 different building types. 3 “special” buildings. One building type. 5x5 map grid. Dynamic, directional lighting. Calculating and updating car chase camera every frame. Smooth 3D animations even at 30 Hz. This is no video!     Screen shot 2: Secondary Display playing Video or RearView Camera

Demo Implementation of CarPlay on an NXP Processor highlighting Siri control, with Linux OS Features: CarPlay head unit implementation developed and available from NXP Professional Services, just one of many available functions for auto infotainment. Available for several NXP processors running Linux, including the i.MX6D and i.MX6Q, and the SABRE for Automotive Infotainment Development system. _______________________________________________________________________________________________________ Featured NXP Products: NXP Software for Apple Carplay|NXPhttp://www.nxp.com/products/software-and-tools/run-time-software/professional-services-software-technology/nxp-software-technology-for-carplay:SOFTWARE-APPLE-CARPLAY Professional Services Software Technology|NXP i.MX6Q|i.MX 6Quad Processors|Quad Core|NXP SABRE-2|Automotive-Infotainment|i.MX6|NXP _______________________________________________________________________________________________________

Overview This thermostat reference design is an example of how a thermostat can be built taking advantage of the features of the NXP® MC9S08LL MCU, which has a very flexible LCD module that allows driving an 8x24 LCD and power saving modes while keeping track of the time and the LCD information and a 12-bit analog to digital converter. Features Low-power battery (2 AA) operation Small Glass (2-4 uA) Large Glass (7-9 uA) Support for two LCD displays 8x24 mode for greater flexibility 2x26 mode optimized for lowest power Standard HVAC connectivity Temperature sensors Programmable heat/cool temp Block Diagram Board Design Resources

Classic board games with a touch of magic. NFC adds extra functionality to familiar fun. Interact more intuitively, speed up gameplay, and easily pick up where you left off. Experience board game immersions like you never have before. NFC helps bringing the 2-D board game experience to life. Players move their NFC-equipped pieces across the board as usual, but they can now be electronically tracked. The game processor uses this tracking data - coupled with information about the piece itself that can also be stored in the tag, creating an exciting gaming environment that's alive with action. It also enables new gameplay dimensions like on-line and interactive play scenarios.   Features enabled by NXP •Detection of up to 40 RFID Objects on large surface powered by single RFID reader •Direction detection of the game pieces •Connectivity to host system via USB or BLE   Recommended Products SLRC 610 – High perfromance RFIDreader Icode SLIx – Ultra low power RFID tag LPC11uxx – Microcontroler with embeded FS USB 74HCxxx – Ultra thin Analog Switches   Resources More information about NFC gaming: http://www.nxp.com/solutions/portable-wearable/gaming.html

  Overview The IoT Low Power Sensor Node reference design is a compact form factor, open source design. It enables low power nodes based on IEEE 802.15.4 protocols such as Thread and ZigBee to communicate data to a wireless sensor network. NXP supplements the Kinetis KW2xD with tools and software that include hardware evaluation and development boards, software development IDE and demo applications and drivers.   Features   MKW24D512 802.15.4 Kinetis MCU Full IEEE 802.15.4 compliant wireless node for Thread network Reference design area with small footprint, low-cost RF node Integrated PCB meander horizontal antenna 2 Interrupt push button switches (LLWU) 1 FXOS87000CQ Combo sensor   Block Diagram Board Design Resources

Hi:    In industrial application, high RS485 Bus requires more real time performance, possible higher throughput. Normally in NXP MCUxpresso SDK, it provides basic sample codes to demonstrate UART, DMA peripherals usage, but not RS485. Though enough driver API could support such applicatio. But for newbie or fast prototype requirement, it's hard to build it in short time. This design show how to use DMA for RS485 application, and how to use UART "Smart" Features to implement high throughput.

Demo Summary An autonomous vehicle platform leveraging NXP’s new BlueBox engine, and deploying NXP silicon and software solutions at each ADAS node. The system demonstration incorporates the BlueBox central computing engine, together with radar, lidar, and vision sensing, as well as an on-board secure V2X system     Local Motors 3D Printed Car and NXP V2X Tech Showcase - YouTube      Demo / product features   BlueBox—a unique solution designed to help meet the stringent automotive safety, power and processing performance requirements of autonomous vehicle platforms S32V automotive vision and sensor fusion processor LS2085A embedded compute processor Up to 90,000 DMIPS at < 40 W, ISO 26262 supported   NXP Recommends   Product Link NXP BlueBox https://www.nxp.com/design/development-boards/automotive-development-platforms/nxp-bluebox-autonomous-driving-development-platform:BLBX?&tid=vanBlueBox S32V234 S32V234 Vision Processor | NXP        Document Number: https://community.nxp.com/docs/DOC-330366       A20