This post entry provides a detailed information about the EMVCo L1 certification process for contactless payment devices. The structure is the following: EMV Introduction Objective When a company is developing a POS device, there are some challenges to consider for a successful deployment in the market: The device needs to have a good performance to provide the client with a good user experience. Moreover, the device should be able to operate seamlessly with other devices and cards in the market in a secure and reliable way.   These key characteristics are tackled by the EMV specifications. Summarizing, EMV is a group of specifications for smart payment cards and terminals that were created by EMVCo to guarantee interoperability and acceptance of secure payment transactions. EMV stands for Europay, Mastercard, and Visa, the three companies that originally created the standard. These specifications are now managed by EMVCo, an organization of six members – including Mastercard, UnionPay, Visa, AmEx, Discover, and JCB.   EMVCo organization We can see in the figure below the structure of the organization. EMVCo is managed by the Board of Managers that consists of two representatives of every member of the organization. On top of the Board of Managers, the Executive Committee provides guidance on the group’s long-term strategy.     From a more technical point-of-view, it is organized in several Working Groups, each of them dedicated to specific topics. EMVCo also has the Associates Program, so key industry stakeholders can provide input and feedback to the Board of Managers, Executive Committee, and Working Groups.   EMV Technologies EMV specifications encompass a wide range of technologies, including: Contact chip technology, where smartcards and readers provide with cryptographical security advantages in comparison with the traditional magnetic stripe. EMV specifications also regulate contactless payment devices based on NFC technology.  Mobile Transactions where the mobile phone would play the role of a contactless device. The QR code technology, where the transaction can be made using a QR reader. Payment tokenization, that enables to perform transactions without compromising sensible card information. And other technologies like Secure Remote Commerce, 2nd Gen or 3-D Secure.   EMV Contactless specifications EMV Contactless specifications is now on version 2.6 but planning to move to version 3.0 by the end of the year.   The EMV Contactless specifications are structured in three books and the Contactless Interface Specifications that substitutes the Book D from previous versions of the specs. The Book A describes the overall architecture of the system, and the instructions involved in the communication between the entry point and the kernel. The Book B addresses the specifications regarding the Entry Point, which is the piece of sw in charge of the transaction pre-processing, or protocol activation among other tasks. Book C consists of 6 different levels for each of the kernels that are defined in the specifications. The EMV Contactless Interface Specifications describe the minimum set of functionalities that are required for the correct operation between the PICCs and the PCD.   In addition we will mention other relevant documents like: The PCD Test Bench and Test Case Requirements, that describes the test cases that are carried out by the testing laboratory in order to evaluate the devices. Note that there are 2 different documents, one for the Analog L1 tests and another one for the Digital tests. Another document describes the Device Test Environment, which is the software needed to control the device during the testing phase Another document describes the requirements regarding the Contactless symbol that should appear in all EMVCo Contactless POS in the market.   PCD L1 Type Approval The following diagram summarizes the process for the PCD L1 Type Approval:     In the first step the Product Provider shall submit a Request for Registration form to EMVCo. Once EMVCo reviews and accepts the form, the product provider will receive a contract that has to be signed. Upon reception of this contract, EMVCo will assign a product provider registration number. In the second step the Product Provider will choose a Test Laboratory and complete a document called Implementation Conformance Statement in which it provides detailed information about the device and its features. The third step is the Product Validation phase. In this phase the laboratory performs the product testing, where the device goes through a set of tests to evaluate the digital and analog performance. In a final phase and considering the test reports from the Laboratory, the Product Provider might decide to send the product to EMVCo for approval. In that case, EMVCo would analyze the tests reports and grant with a Letter of Approval in case the reports demonstrate sufficient product conformance.   In our case we are going to focus on the Analog L1 PCD tests.    EMV Analog L1 PCD Tests Environment Before going directly to the actual set of tests, it worth it to explain some components about the testing environment to better understand the testing procedure. We have the following elements: Device Test Environment Contactless symbol Positioning conventions EMVCo Reference PICC   Device Test Environment (DTE) The Device Test Environment is a software application that is used to control the device under evaluation during the whole testing process. This application has to be developed by the product provider and shall be implemented in compliance with a set of requirements defined in the specifications. The software is submitted to the test laboratory along with the samples of the device under certification. The DTE shall implement different applications or modes of operation that would be used depending on the testing scenario. These application are:   PCD Controls: It allows the test operator to execute single basic commands from the ISO14443 standard (Carrier ON/OFF, WUPA, WUPB,..) Pre-validation application: This application is used to test the communication of the device with a set of actual EMV compliant cards. Loopback application: It is used to test the device for the majority of the Analog and Digital L1 PCD Tests. In this case the reader is communicating with a Card simulator connected to a reference antenna. Transaction send application: This application can be used by the laboratory to evaluate the compliancy of the device with the waveform requirements defined for the Analog L1 PCD Tests. The main characteristic of this mode of operation is that the device sends a sequence of commands without waiting the responses from the PICC.   Contactless symbol The contactless symbol is the logo that you can see in the lower image. It helps the user identify the area in the Point Of Sale where he has to tap the card in order to trigger the transaction. This symbol has to be visible in the device surface or screen before and during the transaction. The Contactless symbol is extremely important for the testing procedure as it marks the reference point for all the positions that the device should be tested.   Using this reference point EMVCo defines an operating volume.   Positioning convention All test position are included in this operating volume. Depending on the test case, it will be run in one or more positions. Every position is expressed with a set of 3 coordinates or parameters, representing the height, the radius, and the angle respectively.     In the figure above you can see the operating volume along with the different values that each parameter can have.   EMVCo Reference PICC The EMVCo Reference PICC is the reference antenna used to communicate with the PCD under test. It has 4 ports and 2 jumpers that are used to configure the PICC for different purposes. For example, jumper 8 is used to select between linear and non-linear load depending on the type of tests that are performed. In the same line, the MOD IN port where a Signal Generator will inject a certain modulation to emulate a PICC response. The DC OUT port is used to measure the voltage level in the power tests and the LETI COIL OUT is used to measure the waveform tests among others. In the figure below you can also see the reference point of the antenna where the two white lines crossed:   Power tests The power tests are evaluated in all positions with the purpose of guaranteeing that the device is emitting enough field in all the positions. Depending on the height the limiting values will differ. In the figure below you can see the different planes with the respective limiting values.     The critical positions for the power tests are usually the outer positions for plane z=4 and z=3 where the voltage measured may not be strong enough to pass the tests. On top of that and depending on the transmission configuration used, it can also happen that the voltage measured at positions (1, 0, 0) and (0, 0, 0) can exceed the maximum level.   Waveform tests The purpose of the waveform tests is to evaluate the wave shape of the modulation used in the commands from the PCD. That way, if the wave shape fits with the requirements an EMVCo compliant PICC would not have any problem understanding the commands sent by the PCD.   The waveform evaluation for Type A modulation include the following test cases: t1 (TB121) Monotonic Decrease (TB122) Ringing (TB123) t2 (TB124) t3 and t4 (TB125) Monotonic Increase (TB126) Overshoot (TB127)     In the same way, the Type B test cases are the following: Modulation Index (TB121)# Fall time (TB122) Rise time (TB123) Monotonic Increase (TB124) Monotonic Decrease (TB125) Overshoots (TB126) Undershoots (TB127)     Reception tests The objective of the communication or responsiveness tests is to guarantee that the PCD is able to properly finish a transaction when the response of the PICC is in the limits of the specifications in terms of amplitude and polarity.   That way we find 4 different tests: Minimum load modulation, positive polarity (Tx131) Maximum load modulation, positive polarity (Tx133) Minimum load modulation, negative polarity (Tx135) Maximum load modulation, negative polarity (Tx137)   In the two figures below we can easily check the difference in the load modulation level between the oscilloscope capture for the Tx131 and the Tx133.     Other tests Besides the power, waveform and communication tests there are other tests included in the EMVCo Analog L1 Test cases. Here is the list of these other tests:   Carrier frequency (TAB112) Field resetting (TAB113) Power off (TAB114) Polling sequence (TAB115) FDTA PICC (TA139) BitRate (TA141 & TB141) BitCodingPCD (TA142 & TB142) BitCodingPICC (TA143 & TB146) BitBoundaries (TB147) TFSOFF (TB145 & TB148)   EMV Contactless Specs v3.0 The most important change is that the tests will no longer be carried out with one specific EMVCo reference PICC but with three. The first two are Class 1 antennas tuned to 16.1MHz and 13.56MHz, and the third reference PICC is a Class 3 antenna tuned to 13.56MHz.     This is important since the device will need to pass the test for 3 different antennas, making the testing process between 2 and 3 times slower and the tuning of the device more difficult than for the 2.6 version of the specs.   Other changes are a second different load for the linear load tests and the modifications of some waveform tests limits.   NXP Product portfolio for POS The product portfolio that NXP offers for contactless POS device includes three main chips: CLRC663 plus: EMVCo 2.6 ready chip compliant both for analog and digital L1 requirements. The CLRC663 plus is able to work with a transmitter current of 350 mA and a limiting value of 500 mA. This feature allows us to increase the field strength radiated and overcome power issues because of the design of the POS or the antenna.  PN5180: The PN5180 chip is also an EMVCo compliant frontend, that supports highly innovative and unique features like the Dynamic Power Control that optimizes the RF performance even under detuned antenna conditions. Other features are the Adaptative Waveform Control or the Adaptative Receiver Control to automatically adjust the transmitter modulation or the receiver parameters. These and many other features turn the PN5180 into the best NFC frontend in the market. PN7462: It supports contact and contactless interface in the same chip. It is an NFC controller, so includes an MCU with a configurable host interface. For the contactless interface, it implements similar functionalities as the PN5180, like the Dynamic Power Control, the Adaptative Receiver Control, and the Adaptative Waveform Control.   Further Information You can find more information about NFC in: Our NFC everywhere portal: https://www.nxp.com/nfc You can ask your question in our technical community: https://community.nxp.com/community/identification-security/nfc You can look for design partners: https://nxp.surl.ms/NFC_AEC And you can check our recorded training: http://www.nxp.com/support/online-academy/nfc-webinars:NFC-WEBINARS   Video recorded session

This demo which shows a complete Ethernet AVB audio amplifier solution built with NXP silicon and software.     Features Audio Video Bridging for automotive infotainment purposes System AVB amplifier for car audio nodes Analog video/audio is converted into AVB and outputs to vybrid Tower running AVB stack Featured NXP Products Vybrid Qorivva MCU Development Hardware Used Vybrid TWR board

Demo This demo shows an infotainment and ADAS system based on NXP Ethernet components and is divided in three main parts: Infotainment, Network and ADAS. In the infotainment part, a “Head Unit” ECU plays locally an MPEG movie and also streams it over Ethernet to the second “Rear Seat Unit” ECU. Both ECUs also execute in the backroad the NXP AVB SW stack. This enables the two ECUs to be perfectly synchronized with each other. Therefore the two ECUs can playback the very same video (and audio) frame at the same time on their local displays. In the network part the new Automotive Ethernet Switch (SJA1105EL) and PHYs (TJA1100HN) implement the Ethernet connectivity of the system. The switch executes the AVB “gPTP” synchronization SW that enables the infotainment application described above to operate. In the ADAS part a surround view camera captures a video stream and streams it to a “Cluster” ECU also connected via the automotive Ethernet network. The camera is based on the NXP “MPC5604E ” Salsa processor and on a competitor’s BroadR-Reach PHY. This also shows the interoperability of the TJA1100HN PHY with competitor’s products. Features: All displays are implemented with NXP i.MX6 processor, and a full implementation of the NXP Ethernet AVB Stack running on Linux. The camera is based on an NXP Salsa processor (MPC5304EKIT) . The Switch board that connects all displays and the camera uses the NXP SJA1105EL Automotive Ethernet switch and the TJA1100HN BroadR-Reach Ethernet PHY ______________________________________________________________________________________________________________ Featured NXP Products: Product Link IEEE 100BASE-T1 compliant Automotive Ethernet PHY Transceiver TJA1100HN | Automotive Ethernet PHY Transceiver | NXP  i.MX 6 Series i.MX 6 Series Applications Processors | Multicore Arm Cortex-A7/A9/M4 | NXP  Audio Video Bridging Software https://www.nxp.com/design/design-services/audio-video-bridging-software:AVB-SOFTWARE?&fsrch=1&sr=4&pageNum=1 Development Kit Enabling Video Over Ethernet with NXP® MPC5604E MCU NXP® MPC5604EKIT:Development Kit | NXP  ___________________________________________________________________________________________________________

Description   A shared power bank is the sharing economy business model (which has been booming in in recent years). A shared power bank is an publicly accessible charging station, which provides power bank to customers.   A common scenario would be a customer running low on battery on their mobile phone. Using a smartphone app they would locate a nearby charging station, for instance in a cafe. Each station has either six or twelve rechargeable batteries, which can be taken out of the box and connected to an iOS or Android device.   Features   Smartphone app to indicate where a nearby charging station is located Each station has either six or twelve rechargeable batteries   Block Diagram     Products     Category Name 1: MCU Product URL 1 Arm Cortex-M4|Kinetis K22 100 MHz 32-bit USB MCUs | NXP  Product Description 1 The Kinetis® K22 offers analog, communication, timing and control peripherals to meet diverse requirements   Category Name 2: Bluetooth Product URL 1 QN908x: Ultra-Low-Power Bluetooth Low Energy System on Chip (SoC) Solution | NXP  Product Description 1 QN908x integrates a Bluetooth Low-Energy radio, controller, protocol stack and profile software on a single chip, providing a flexible and easy to use Bluetooth Low Energy SoC solution.   Category Name 3: Peripherals Product URL 1 PCA9535A | NXP  Product Description 1 The PCA9535A is a low-voltage 16-bit General Purpose Input/Output (GPIO) expander with interrupt and reset for I²C-bus/SMBus applications.     Tools   Product Link FRDM-K22F: NXP Freedom Development Platform for Kinetis® K22 MCUs FRDM-K22F|NXP Development Platform|Kinetis® MCU | NXP  QN9080DK: A highly extensible platform for application development of QN908x QN9080DK: A highly extensible platform for application development of QN908x | NXP 

  Description An energy display is an easy way for a user to view all the information collected by the sensors around their home. This application needs to support multiple protocols such as Zigbee and IEEE802.15.4 in order to be able to share the information with all the sensors around it. The Sigfox protocol could also be included in the features of this display. Block Diagram Products Category Name 1: Microcontroller Product URL 1 LPC546XX Microcontroller (MCU) Family | NXP  Product Description 1 The LPC546xx MCU family combines power efficiency with multiple high-speed connectivity options, advanced timers, and analog features. The LPC546xx LCD Controller supports both Super-Twisted Nematic (STN) and Thin-Film Transistor (TFT) displays. It has a dedicated DMA controller, selectable display resolution (up to 1024 x 768 pixels), and supports up to 24-bit true-color mode. Product link 2 Zigbee and IEEE 802.15.4 wireless microcontroller with 512 kB Flash, 32 kB RAM | NXP  Product Description 2 The JN5169 is an ultra-low-power, high-performance wireless microcontroller suitable for ZigBee applications that allows OTA upgrade capability without external memory.   Category Name 2: Transceiver Product URL 1 Low-Power Multi-Channel UHF RF Wireless Platform | NXP  Product Description 1 The OL2385 device is a radio frequency transceiver with an embedded MCU designed for a wide range of industrial and home applications requiring a very high link budget for bidirectional RF communication. The OL2385 is a 2-way RF channel with the most common modulation schemes for networking applications covering a full range of frequency bands from 160 up to 960 MHz   Category Name 3: Wireless charging receiver Product URL 1 NXxA4WP | NXP  Product Description 1 The NX1A4WP is an A4WP (Alliance for Wireless Power) compliant wireless power receiver front end. The integrated rectifier supports voltages of up to 20 V and is protected by an integrated automatic clamping function and an automatic over-power protection function.   Category Name 4: DC-to-DC Boost Converter Product URL 1 PCA9410/9410A | NXP  Product Description 1 The PCA9410 is highly efficient 3.0 MHz, 500 mA, step-up DC-to-DC converters, it converts input voltages from 2.5 V to 5.25 V to a fixed output voltage of 5.0 V. The PCA9410 delivers efficiency of up to 94 % enables an extended battery life in all portable designs.   Category Name 5: RTC with battery backup Product URL 1 PCF2129 | NXP  Product Description 1 The PCF2129 is a CMOS Real Time Clock (RTC) and calendar with an integrated Temperature Compensated Crystal Oscillator. The PCF2129 has a selectable I2C-bus or SPI-bus, a backup battery switch-over circuit, a programmable watchdog function, a timestamp function, and many other features.   Category Name 6: Security IC Product URL 1 A71CH | Plug and Trust for IoT | NXP  Product Description 1 A71CH is a ready-to-use secure element for IoT devices providing a root of trust at the IC level and delivers, chip-to-cloud security right out of the box. The A71CH includes a complete product support package that simplifies design-in and reduces time-to-market.   Category Name 7: Low-rate multiplexor Product URL 1 Universal LCD driver for low multiplex rates | NXP  Product Description 1 The PCF85133 is a peripheral device which interfaces to almost any Liquid Crystal Display (LCD) with low multiplex rates, also features an internal LCD bias generation with voltage-follower buffers. The PCF85133 has a selectable backplane drive configuration: static or 2, 3, or 4 backplane multiplexing Related Documentation Document URL Title https://www.nxp.com/docs/en/application-note/TN00025.zip  LPC54608 LCD Dual Frame Buffer with eXecute-In-Place (XIP) from Quad SPI flash https://www.nxp.com/docs/en/nxp/application-notes/AN12027.zip Connecting TFT LCD with LCD controller of LPC MCU https://www.nxp.com/docs/en/application-note/AN11662.pdf High-performance PCB antennas for ZigBee networks Training URL CIT-N1778 Smart Metering RF Technologies  Power Management  Related Demos from Communities URL Designing with the New Ultra-Low-Power BLE System on Chip 

Demo   Virtualized Network Platforms demonstrates the capability of QorIQ® Layerscape processors in virtualized Customer Premises and Provider edge solutions using Open System Architecture and Open Standards like OF, ODP and OPNFV. NXP’s Layerscape processors represent the ideal union of processing power and hardware acceleration engines for SDN and NFV applications. Layerscape processors are SDN and NFV ready with Dynamic Service Chaining support which enables a customizable network, meaning operators can add new services more quickly than legacy equipment would allow. Dynamic VNFs provide end-to-end network virtualization and offload processing from edge to cloud. The Layerscape platform software includes 3rd party commercial applications like Trend Micro™ and optimized open source applications which take advantage of NXP’s integrated hardware acceleration engines, Data Path Acceleration Architecture (DPAA) and AIOP to accelerate the data plane. The platform is user programmable and supports standard APIs such as ODP for easy application portability.   Features Demonstration of an SDN and NFV-based Virtualized Network Platform that enables bi-directional, dynamic and on-demand service delivery – by connecting access appliances (wired and wireless) to edge appliances and showcases traffic flow from different virtual network functions.   The access equipment can virtualize network processing such as firewall, anti-virus, and deep packet inspection (DPI) to the bigger network equipment (edge appliances) and enable service providers to push services (network appliances) to the access equipment. This solution demonstrates an "intelligent edge" such as a vCPE, empowered by the dynamic re-distribution of network processing by the virtualized access platform. Service-chaining, Trend-Micro (DPI) and Quality of Service (QoS) are also demonstrated.   Demonstrates Docker® virtualization support on LS2085ARDB by running Docker-based virtual network function using SEC Hardware acceleration for showcasing Openssl benchmarking from vNF.   This Virtualized Customer Premise Equipment (vCPE) solution is implemented with Open-Contrail, OpenNFV, OpenStack, OpenDaylight, OpenFlow, OpenVswitch and runs on NXP's QorIQ Layerscape LS Series 64-bit ARM platform. Specific solutions include the QorIQ LS1043 Wireless Gateway and the LS2085 Virtualized Edge Appliance.

Overview QorIQ® P2020 UTM/Security Appliance Solution enables OEMs to develop a range of security applications including UTM appliances, IPS/IDS appliances, content security appliances, secure routers, VPN routers, secured switches and business gateways. The QorIQ P2020-based UTM appliance enables ODMs and customers to develop a production-ready, BOM optimized, certified, off-the-shelf UTM appliance solution. It allows our customers to leverage high-performance multicore QorIQ silicon and VortiQa® software optimized for multicore for UTM security appliances. Features NXP’s high-performance QorIQ ®  P2020 processor in 45 nm SOI technology VortiQa ®  software for enterprise equipment optimized for multicore processors Integrated security engine: protocol support includes SNOW, ARC4, 3DES, AES, RSA/ECC, RNG, single-pass SSL/TLS, Kasumi Cost-optimized bill of materials by hardware ODMs FCC, UL and CE certified—ready to ship Complete appliance portfolio from low to high end Block Diagram Board Design Resources

Experience a great showcase of network function virtualization and network service insertion using OpenStack Cloud Orchestration Software.     Features Network Function Virtualization of HAProxy - Server Load Balance OpenSource Software and IPTables Firewall for Network Service Insertion to show case DC Networks deployment use case This demo show cases Network Function Virtualization and Network Service Insertion using OpenStack Cloud Orchestration Software Orchestrating HAProxy and IP Tables virtual network functions using OpenStack Havana release Network function configuration relay using OpenStack dashboard Featured NXP Products T4240: QorIQ T Series T4240/T4160/T4080 24/16/8 Virtual Core Links Networking Block Diagram  

Description NXP’s enterprise storage server solution is focused on our new I²C Fast-mode Plus (Fm+) devices which go from zero to 1 MHz so you can go to the next design level with higher data rates and up to 540 pF bus loading. In computing, telecom and networking systems architecture the trend is for greater use of I²C-bus as a maintenance and control bus, so more bandwidth and more devices on the bus are required.   Block Diagram Products Category Name 1: Microprocessor Product URL 1 QorIQ® Layerscape 1043A | NXP  Product Description 1 The QorIQ® LS1043A processor is NXP's first quad-core, 64-bit Arm®-based processor for embedded networking, it delivers greater than 10 Gbps of performance in a flexible I/O package supporting fanless designs. The new 0.9V LS1043A delivers additional power savings for applications such as Wireless LAN and to Power over Ethernet systems.   Category Name 2: I²C-bus Level Translator Product URL 1 PCA9509P | NXP  Product Description 1 The PCA9509P is a level translating I²C-bus/SMBus repeater with two voltage supplies that enable processor low voltage 2-wire serial bus to interface with standard I²C-bus or SMBus I/O. While retaining all the operating modes and features of the I²C-bus system during the level shifts, it also permits extension of the I²C-bus by providing bidirectional buffering for both lines. Product URL 2 PCA9617A | NXP  Product Description 2 The PCA9617A is an IC that provides level shifting between low voltage (0.8 V to 5.5 V) and higher voltage (2.2 V to 5.5 V) Fast-mode Plus (Fm+) I²C-bus or SMBus applications. The static offset design of the port B PCA9617A I/O drivers prevents them from being connected to the static or incremented offset of other bus buffers. Product URL 3 PCA9306 | NXP  Product Description 3 The PCA9306 is a dual bidirectional I²C-bus and SMBus voltage-level translator with an enable (EN) input, and is operational from 1.0 V to 3.6 V and 1.8 V to 5.5 V. The PCA9306 features a 2-bit bidirectional translator for SDA and SCL lines in mixed-mode I²C-bus applications and also provides bidirectional voltage translation with no direction pin.   Category Name 4: PCIe Switch Product URL 1 CBTL04083A; CBTL04083B | NXP  Product Description 1 The  CBTL04083A/B has minimized the impedance of the switch such that the attenuation observed through the switch is negligible, and also minimized the channel-to-channel skew as well as channel-to-channel crosstalk, as required by the high-speed serial interface.   Category Name 5: GTL Level Translator Product URL 1 4-bit LVTTL to GTL transceiver | NXP  Product Description 1 The GTL2014 is a 4-bit translating transceiver designed for 3.3 V LVTTL system interface with a GTL-/GTL/GTL+ bus, where GTL-/GTL/GTL+ refers to the reference voltage of the GTL bus and the input/output voltage thresholds associated with it.   Category Name 6: Memory Switch Product URL 1 CBTW28DD14 | NXP  Product Description 1 The CBTW28DD14 is a 14-bit bus switch/multiplexer (MUX) is designed for 1.5 V or 1.8 V supply voltage operation designed for operation in DDR2, DDR3 or DDR4 memory bus systems. The CBTW28DD14 uses NXP proprietary high-speed switch architecture providing high bandwidth, very little insertion loss at low frequency, and very low propagation delay, allowing use in many applications requiring switching or multiplexing of high-speed signals.   Category Name 7: I2C Mux Product URL 1 PCA9846 | NXP  Product Description 1 The PCA9846 is an ultra-low voltage, quad bidirectional translating switch controlled via the I²C-bus. The SCL/SDA upstream pair fans out to four downstream pairs, or channels. Any or all SCx/SDx channels can be selected, determined by the programmable control register.   Category Name 8: Load Switch Product URL 1 Logic controlled high-side power switch | NXP  Product Description 1 The NX5P2924 is a high-side load switch that features a low ON resistance N-channel MOSFET with a controlled slew rate that supports 2.5 A of continuous current.   Category Name 9: I2C Expander Product URL 1 PCAL6416A | NXP  Product Description 1 The PCAL6416A is a 16-bit general-purpose I/O expander that provides remote I/O expansion for most microcontroller families via the I2C-bus interface. The PCAL6416A has built-in level shifting feature that makes these devices extremely flexible in mixed-signal environments where communication between incompatible I/O voltages is required.   Category Name 10: Dip switch Product URL 1 PCA8550 | NXP  Product Description 1 The primary function of the 4-bit 2-to-1 I²C multiplexer is to select either a 4-bit input or data from a non-volatile register and drive this value onto the output pins.   Category Name 11: LED Dimmer Product URL 1 PCA9532 | NXP  Product Description 1 The PCA9532 is a 16-bit I²C-bus and SMBus I/O expander optimized for dimming LEDs in 256 discrete steps for Red/Green/Blue (RGB) color mixing and backlight applications.   Category Name 12: VGA Switch Product URL 1 Low power DisplayPort to VGA adapter with integrated 1 : 2 VGA switch | NXP  Product Description 1 PTN3355 is a DisplayPort to VGA adapter with an integrated 1: 2 VGA switch optimized primarily for motherboard applications, it also integrates a DisplayPort receiver. The PTN3355 supports I²C-bus over AUX per DisplayPort standard and bridges the VESA DDC channel to the DisplayPort Interface.   Category Name 13: LDC Driver Product URL 1 32 x 4 automotive LCD driver for low multiplex rates | NXP  Product Description 1 The PCA85162 is a peripheral device which interfaces to almost any Liquid Crystal Display (LCD) with low multiplex rates. It generates the drive signals for any static or multiplexed LCD containing up to four backplanes and up to 32 segments.       Category Name 14: UART Product URL 1 SC16IS740/750/760 | NXP  Product Description 1 The SC16IS740/750/760 is a slave I²C-bus/SPI interface to a single-channel high-performance UART. It offers data rates up to 5 Mbit/s and guarantees low operating and sleeping current.   Category Name 15: USB 3.0 Pre-Driver Product URL 1 SuperSpeed USB 3.0 redriver | NXP  Product Description 1 PTN36001 is a dual-channel USB 3.0 Pre-Driver that supports data signaling rate of 5 Gbit/s through each channel. The data flow of one channel is facing the USB host, and another channel is facing the USB peripheral or device. Related Documentation   Document URL Title https://www.nxp.com/webapp/Download?colCode=AN5226  AN5226, Common Board Design for LS1046A, LS1043A and LS1088A Processors https://www.nxp.com/docs/en/application-note/AN5125.pdf AN5125, Introduction to Device Trees https://www.nxp.com/webapp/Download?colCode=AN4311 SerDes Reference Clock Interfacing and HSSI Measurements Recommendations https://www.nxp.com/webapp/Download?colCode=AN5097  Hardware and Layout Design Considerations for DDR4 SDRAM Memory Interfaces Tools   Tools URL QorIQ® LS1043A Development Board | NXP  Training Training URL NET-N1886 Tips for Silicon Bring-Up of QorIQ LS1043A Processor  APF-DES-T1853 - QorIQ LS1043A Application Solution Kit (IoT, NAS, RGW)  LS1012A, LS1043A and LS1046A Design Cycle using N…  APF-DES-T1853 - QorIQ LS1043A Application Solution Kit (IoT, NAS, RGW)  Related Demos from Communities Related Demos URL QorIQ Processing Platforms  Layerscape  IoT Solutions Platform based on LS1043 

Demo Owner: Carlos Neri Want to learn how to create USB based speakers? In this video, you'll learn how you can build speakers to play any sound from any USB system using only TOWER K40X256, TWR-Audio and TWR- serial modules. Watch how you can increase and decrease volume as well as change the frequency on the fly without any audio distortion.     Features Entirely built on the K40X256 Tower system Features HID for volume control to the host USB Stack Featured NXP Products TWR-K40X256: Kinetis K40 Tower System Module TWR-SER: Serial (USB, Ethernet, CAN, RS232/485) Tower System Module TWR-SER2: Enhanced Serial (Dual Ethernet, High-Speed USB) Tower System Module TWR-AUDIO-SGTL: SGTL5000 Codec Tower System Audio Module TWR-ELEV: Tower System Elevator Module Links Tower System Modular Development Platform  

Boundary Devices demo is a handheld, battery powered wireless streaming application. The demo consists of an NXP SCM-i.MX 6SoloX V-Link device (i.MX6SoloX/PF0100/512MB LPDDR2) + Boundary Devices’ V-Link Top board with 802.11ac module + Boundary Devices’ Carrier board with 5MP MIPI Camera and Battery SCM V-Link technology is ideal for handheld/space-constrained applications allowing customers to integrate vertically. Features: The demo application streams data via wireless from the 5MP camera on the handheld device to a desktop board which shows the stream on a 7” display. There is a point-to-point link from the handheld device to the desktop device. V-Link Top board from Boundary Devices – QCA9377 802.11ac + BT4.1 module. Pre-certified and ready for production. Mounts on top of SCM V-Link module which is ideal for space constrained applications. 22mm x 19mm board dimensions. Available Linux/Android Drivers for easy Wi-Fi + BT software integration for kernel 3.14.28 and above. On 5GHz network utilizing SDIO 3.0, Wi-Fi throughput is 90Mb/s. ___________________________________________________________________________________________________ Featured NXP Products: Single Chip System Modules (SCM)|NXP Partner Boundary Devices

Demo      Features Detect fatigue using a camera via an algorithm based on optical absorption rate of facial blood vessels Efficient processing with up to 1.2MHz Quad ARM Cortex-A9 architecture with a NEON multimedia processing acceleration engine Video processing unit in i.MX 6Quad to record front camera video in H.264 format Face tracking algorithm to track the driver's head for a real driving use case   NXP Recommends i.MX6Q|i.MX 6Quad Processors|Quad Core

Overview The NXP® 800 MHz MPC8377E PowerQUICC® II Pro processor built on Power Architecture® technology features integrated hardware acceleration for wireless security, MiniPCI or MiniPCI Express®-based interfaces for 802.11N radio modules, dual-band concurrent operation, Gigabit Ethernet (GbE) LAN and WAN interfaces, USB 2.0 host/device interface and IEEE® 802.3af PoE-compliant solution for dual-concurrent MIMO operation. Features 800 MHz MPC8377E PowerQUICC ®  II Pro processor built on Power Architecture technology Integrated hardware acceleration for wireless security MiniPCI or MiniPCI Express based interfaces for 802.11N radio modules Dual-band concurrent operation with 3 x 3 MIMO (GbE) LAN and WAN interfaces USB 2.0 host/device interface IEEE ®  802.3af PoE-compliant solution for dual-concurrent MIMO operation Block Diagram Board Design Resources

Built to automotive grade specifications, this Qi compliant wireless charging reference design charges up devices in the car. The devices can integrate into the dash or center console of car.     https://community.nxp.com/players.brightcove.net/4089003392001/default_default/index.html?videoId=4282648274001" style="color: #05afc3; background-color: #ffffff; font-size: 14.4px;" target="_blank   Features Wireless Charging Reference design for Automotive applications Integration into dash board or center console 5 Watts of power following Qi standard Near field Communication (NFC) Loop included   Featured NXP Products 5 Watt Wireless Automotive 5 Watt Wireless Industrial Links WCT-5WTXAUTO: Multi-Coil Wireless Charging Tr Block Diagram  

SECO presents three independent displays powered by NXP's i.MX6 applications processor as well as a single board computer using an i.MX 6 processor for a digital display. SECO also demonstrates i.MX 6 with UDOO, a open hardware computer at the FTF Americas 2014. Features Qseven standard i.mx6 productscarrier board running OpenGL and a half-size Qseven board i.MX6 single board computer for digital signage UDOO board, educational Do-It-Yourself (DYI), i.MX6 quad core with Arduino compatible IDE with Basic input and outputs with peripherals Featured NXP Products i.MX6 Links SECO - Partner Profile Information Videos   UDOO Smart Theremin    

The latest and smallest addition to the NXP SCM portfolio, SCM-i.MX 6SoloX, plays a promotional video on repeat on an evaluation board. The SCM-i.MX 6SoloX integrates NXP i.MX 6SoloX applications processor, NXP PF0100 power management, and system passive components (de-coupling capacitors and resistors). It is designed and enabled for LPDDR2 and eMMC memory via vertical stacking (PoP/ePoP)   With this level of integration in an ultra-compact 13mm x 13mm footprint it can save as much as 50% in PCB area.   Features: Reduce overall hardware design time and bring products to market faster. Overall PCB area reduction over current discrete solutions. Reduces design complexity of integrating DDR memory and power management. Get started with an evaluation board and Linux OS, early access program now available. _____________________________________________________________________________________________________ Featured NXP Products: Single Chip System Modules (SCM)|NXP i.MX 6SoloX Family of Applications Processors|NXP

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 

With IoT, municipalities are controlling our infrastructure via the Internet and what was once physically secure is now open to attack. Using the Green Hills Crypto toolkit and INTEGRITY RTOS on NXP's Crypto platform, a secure firewall can enable our infrastructure to utilize the new IoT technology.       Features Internet connectivity, secured communications and M2M management Cryptography reference board running certified INTEGRITY RTOS Demo shows tablet connected to devices with the ability to change devices' behavior in a private, hack-proof system   Featured NXP Products Crypto Coprocessor|NXP Links Real-Time Operating Systems (RTOS), Embedded Development Tools, OptimizingCompilers, IDE tools, Debuggers - Green Hills … Securing the Internet of Things with Green Hills Softwa Block Diagram  

Description Application demo recognizes 10 keywords: "yes", "no", "up", "down", "left", "right", "on", "off", "stop", "go" spoken into the on-board microphone. Use terminal output - 115200 baud - to see results. This demo was created as part of hands-on lab demonstrating model conversion which can be found here: https://community.nxp.com/docs/DOC-344227. Software The RT1060 SDK should already be installed in MCUXpresso IDE. Drag-and-drop the .zip file into the Project Explorer view, and then compile and flash. NXP Product Link i.MX RT1060 Evaluation Kit i.MX RT1060 Evaluation Kit | NXP 

This demo shows a use case of the NXP QN9021 in the Zepp Bluetooth Smart sports sensor to send sensor data to smartphone app for data analysis and provide feedback to users     Features: Zepp Bluetooth Smart sports sensors are designed to monitor performance with a smartphone app for baseball, golf and tennis. Zepp allows you to get to know your swing or stroke inside and out through instant 3D and video analysis. Users can learn from the pros; capture your personal mechanics and compare your swing side-by-side to many of the world’s greatest athletes _________________________________________________________________________________________________________________________   Featured NXP Products: Ultra low power Bluetooth LE system-on-chip s|NXP _________________________________________________________________________________________________________________________   Other Helpful links: ZEPP _________________________________________________________________________________________________________________________