DES-N1740 i.MX 8 and the Vulkan API - The Future of High Performance Graphics Implementations Get a deep dive into the brand new Vulkan API from Khronos. Learn how the programming paradigms have changed from OpenGL ES, how to use Vulkan API and its enormous performance advantages, and how to unlock the full potential of i.MX 8 series GPUs. Watch Video Presentation Get a deep dive into the brand new Vulkan API from Khronos. Learn how the programming paradigms have changed from OpenGL ES, how to use Vulkan API and its enormous performance advantages, and how to unlock the full potential of i.MX 8 series GPUs. Watch Video Presentation Design | Software & Services

IOT-GATE-iMX7 - NXP i.MX7 Internet of Things Gateway NXP i.MX7 CPU, dual-core Cortex-A7 1GHz Up to 2GB DDR3 and 32GB eMMC 3G/LTE modem, WiFi 802.11a/b/g/n, BT 4.1 2x 1000Mbps Ethernet, 4x USB2, RS485, RS232 Support for PoE powered mode Fanless design in aluminum, rugged housing Miniature size – 10.8 x 8.3 x 2.4 cm Designed for reliability and 24/7 operation Wide temperature range of -40C to 85C Mainline Linux kernel and full Linux BPS IOT-GATE-iMX7 is built around the NXP i.MX7 System-on-Chip featuring an advanced ARM Cortex-A7 CPU coupled with a dedicated real-time ARM Cortex-M4 MCU. The SoC is supplemented with up-to 2GB DDR3 and 32GB of on-board eMMC storage.   Featuring a wide range of embedded interfaces, IOT-GATE-iMX7 is a versatile platform for industrial automation and control systems. Dual Gbit Ethernet, 3G/LTE modem, dual-band 802.11a/b/g/n WiFi and Bluetooth 4.1 make IOT-GATE-iMX7 an excellent solution for networking, communications and IoT applications.   IOT-GATE-iMX7 is provided with a full Board Support Package and ready-to-run images for the Linux operating system. The IOT-GATE-iMX7 BSP includes Linux kernel 4.1.15, Yocto Project file-system and U-Boot boot-loader. In addition, CompuLab will support IOT-GATE-iMX7 with mainline Linux and upstream Yocto Project. IOT-GATE-iMX7 spec IOT-GATE-iMX7 evaluation kit IOT-GATE-iMX7 pricing General Re: IOT-GATE-iMX7 - NXP i.MX7 Internet of Things Gateway Yocto project repository for CompuLab i.MX-based products is managed at https://github.com/compulab/yocto-compulab-layer  Support for IOT-GATE-iMX7 is currently being added into this repository and should be online within one week. Re: IOT-GATE-iMX7 - NXP i.MX7 Internet of Things Gateway Where can I find the Yocto project repository for this hardware. Is it maintained within free-scale community or a different meta layer

0001-ASoC-mxs-saif-修复设置-主-基本速率.zip <meta http-equiv="Content-Type" content="text/html; charset=utf-8" /> <meta http-equiv="Content-Type" content="text/html; charset=utf-8" /> 概述

INS-N1820 ハンズオンワークショップ センサーマイニングとアルゴリズム開発 <meta http-equiv="Content-Type" content="text/html; charset=utf-8" /> 参加者は、前のクラスのセンサーデータロガーを使用して、特定のセンサーイベントやシグネチャを表すデータを収集します。その後、参加者はセンサーマイニングおよびアルゴリズム開発ツールを使用して、加速度計、磁力計、ジャイロスコープ用の簡単なアルゴリズムを作成します。このハンズオンクラスの終わりまでに、参加者は、アルゴリズムを迅速に作成およびテストするためのツールを使用して、センサーの経験を積むことができます。 <meta http-equiv="Content-Type" content="text/html; charset=utf-8" /> 参加者は、前のクラスのセンサーデータロガーを使用して、特定のセンサーイベントやシグネチャを表すデータを収集します。その後、参加者はセンサーマイニングおよびアルゴリズム開発ツールを使用して、加速度計、磁力計、ジャイロスコープ用の簡単なアルゴリズムを作成します。このハンズオンクラスの終わりまでに、参加者は、アルゴリズムを迅速に作成およびテストするためのツールを使用して、センサーの経験を積むことができます。 インサイト&イノベーション

INS-N1893 Panel: Future Security Challenges and Trends In this session, a panel of multi-disciplinary experts will describe and discuss the challenges of securing the connected world around us. The session will cover three major facets of creating secure solutions, addressing the challenges and emerging trends for: *Device Security - Securing edge nodes, smart cards, certifications *Network Security - Secure data transmission, security protocols *Internet of Things Security -Trust, crypto, tamper Subject matter experts will present an overview of each of these topics, followed by an interactive dialogue with the audience. It is hoped that the audience will gain a high-level understanding of the multi-faceted challenges of securing end to end solutions, and how semiconductor companies will work with ecosystem partners, innovators, and policy makers to address those challenges.   In this session, a panel of multi-disciplinary experts will describe and discuss the challenges of securing the connected world around us. The session will cover three major facets of creating secure solutions, addressing the challenges and emerging trends for: *Device Security - Securing edge nodes, smart cards, certifications *Network Security - Secure data transmission, security protocols *Internet of Things Security -Trust, crypto, tamper Subject matter experts will present an overview of each of these topics, followed by an interactive dialogue with the audience. It is hoped that the audience will gain a high-level understanding of the multi-faceted challenges of securing end to end solutions, and how semiconductor companies will work with ecosystem partners, innovators, and policy makers to address those challenges.   Insight & Innovation

SMI-N2078 SECO- ものづくりからものづくりへ -ミッシングリンク <meta http-equiv="Content-Type" content="text/html; charset=utf-8" /> 今日の新しい起業家やイノベーターは、新しいMakerムーブメントのおかげで、迅速にプロトタイプを作成できます。しかし、この無限の可能性の世界は、大量生産で製品を製造するとなると、概念実証の作成と製造の間のステップ、つまりリンクが欠落しているため、大きな制限にぶつかります。このスピーチでは、SECOがコミュニティ運動とボードであるUDOOを通じて、新たに獲得したMaker Movementの経験と埋め込まれた専門知識を融合させることで、MakersとIndustryの間のギャップをどのように拾ったかを紹介します。 <meta http-equiv="Content-Type" content="text/html; charset=utf-8" /> 今日の新しい起業家やイノベーターは、新しいMakerムーブメントのおかげで、迅速にプロトタイプを作成できます。しかし、この無限の可能性の世界は、大量生産で製品を製造するとなると、概念実証の作成と製造の間のステップ、つまりリンクが欠落しているため、大きな制限にぶつかります。このスピーチでは、SECOがコミュニティ運動とボードであるUDOOを通じて、新たに獲得したMaker Movementの経験と埋め込まれた専門知識を融合させることで、MakersとIndustryの間のギャップをどのように拾ったかを紹介します。 スマートマシナリー&インダストリアルオートメーション

AMF-AUT-T2348 - The NXP Audio Video Bridging (AVB) Stack Ethernet adoption in new OEM platforms is accelerating, as a result of increased media, communication, and ADAS streams between different end points in vehicles. The required Quality of Service and synchronization is typically achieved through the implementation of Audio Video Bridging (AVB) specifications, or derivatives of AVB. NXP has a unique position in the market given our capability to offer a full solution for AVB in the car, from end points (MPUs as well as MCUs), PHYs, switches, plus the needed software stacks. In addition, the software stacks are full featured, including critical but often initially forgotten components such as Media Clock Recovery. Get an introduction to the basis of the AVB technology, and how NXP can help you deploy AVB in your products. Ethernet adoption in new OEM platforms is accelerating, as a result of increased media, communication, and ADAS streams between different end points in vehicles. The required Quality of Service and synchronization is typically achieved through the implementation of Audio Video Bridging (AVB) specifications, or derivatives of AVB. NXP has a unique position in the market given our capability to offer a full solution for AVB in the car, from end points (MPUs as well as MCUs), PHYs, switches, plus the needed software stacks. In addition, the software stacks are full featured, including critical but often initially forgotten components such as Media Clock Recovery. Get an introduction to the basis of the AVB technology, and how NXP can help you deploy AVB in your products.

处理器概述 <meta http-equiv="Content-Type" content="text/html; charset=utf-8" /> <meta http-equiv="Content-Type" content="text/html; charset=utf-8" />

AMF-AUT-T2347 - The NXP IVI Platform Complexity is increasing abruptly in the IVI market, while TTM has decreased from 5 to 2-3 years over a few product generations. The entire ecosystem is moving from a close to an open system model, and from proprietary/close source to standard interfaces/open source components. NXP is committed to support you in this new reality, as well as providing help in leveraging the extensive BOM NXP typically has in IVI solutions. Through the IVI Platform, NXP offers a solid and complete base for fast product development, integrating productized and optimized BSP and middleware components, with out of the box security. Find out more during a one hour presentation, covering platform features, delivery mechanisms, roadmap and availability. Complexity is increasing abruptly in the IVI market, while TTM has decreased from 5 to 2-3 years over a few product generations. The entire ecosystem is moving from a close to an open system model, and from proprietary/close source to standard interfaces/open source components. NXP is committed to support you in this new reality, as well as providing help in leveraging the extensive BOM NXP typically has in IVI solutions. Through the IVI Platform, NXP offers a solid and complete base for fast product development, integrating productized and optimized BSP and middleware components, with out of the box security. Find out more during a one hour presentation, covering platform features, delivery mechanisms, roadmap and availability.

センサーの概要 <meta http-equiv="Content-Type" content="text/html; charset=utf-8" /> <meta http-equiv="Content-Type" content="text/html; charset=utf-8" />

NET-N1868 Market Drivers and Time Sensitive Networks Time-Sensitive Networking (TSN), a set of IEEE® 802 Ethernet sub-standards, is making deterministic Ethernet possible – especially for the automotive and industrial markets. This session will cover the advantages of TSN and current TSN standards and products. Watch Video Presentation Time-Sensitive Networking (TSN), a set of IEEE® 802 Ethernet sub-standards, is making deterministic Ethernet possible – especially for the automotive and industrial markets. This session will cover the advantages of TSN and current TSN standards and products. Watch Video Presentation Smart Networks

DES-N1837 Using Software Analysis Tools to Improve Application Performance This session will discuss which analysis tool to use and when. Through customer success stories of using the CodeWarrior Analysis Tools, you will learn how to overcome business critical software issues, improve application performance and meet criteria for quality requirements. Watch Video Presentation This session will discuss which analysis tool to use and when. Through customer success stories of using the CodeWarrior Analysis Tools, you will learn how to overcome business critical software issues, improve application performance and meet criteria for quality requirements. Watch Video Presentation Design | Software & Services

Building Linux Image with QT5 for UDOO Quad Hi everybody, The attached document walks you through to build a Linux image for UDOO Quad board with QT5 support by using a Yocto Project build environment. The Kernel used in this process is 3.14.52. I hope you find it useful. Best regards, Carlos

INS-N2022 新しいNXPによるサプライチェーン機能の拡大と供給継続性 <meta http-equiv="Content-Type" content="text/html; charset=utf-8" /> NXPのサプライチェーン・チームは、新しいNXPのグローバル製造フットプリントの概要と、供給保証と危機管理のための統合戦略を紹介します。現在のサプライチェーンシステム統合活動の概要と、今後の顧客注文管理戦略について説明します。NXPのお客様に影響を与える変更を強調することに特に重点が置かれます。 ビデオプレゼンテーションを見る <meta http-equiv="Content-Type" content="text/html; charset=utf-8" /> NXPのサプライチェーン・チームは、新しいNXPのグローバル製造フットプリントの概要と、供給保証と危機管理のための統合戦略を紹介します。現在のサプライチェーンシステム統合活動の概要と、今後の顧客注文管理戦略について説明します。NXPのお客様に影響を与える変更を強調することに特に重点が置かれます。 ビデオプレゼンテーションを見る インサイト&イノベーション

Wayv Portable, Battery-Operated RF Cooking Appliance See how the Wayv uses RF power transistors in a compact, small, and light-weight cooking appliance that gives the flexibility to heat food anytime and anywhere. The Wayv is a battery operated device with a heating chamber and a user interface for programming your cooking needs Demo / product features Battery operated using NXP’s high efficiency RF power solutions Rapidly heats food Safe and eco-friendly Features: Compact, portable, lightweight, and rugged Environmentally friendly solution No toxic fumes during cooking Wireless Design & Developmet (WDD) top pick for IMS 2016 http://www.wirelessdesignmag.com/videos/2016/06/top-5-ims-2016?platform=hootsuite _______________________________________________________________________________________________________ NXP Recommends http://www.nxp.com/Wayv MHT1008N RF Cooking Transistor Driver: http://www.nxp.com/products/rf/rf-power-transistors/rf-cooking/2450-mhz-12.5-w-cw-28-v-rf-ldmos-transistor-for-consumer-and-commercial-cooking:MHT1008N MHT1004N RF Cooking Transistor Final Stage Amplifier: http://www.nxp.com/products/rf/rf-power-transistors/rf-cooking/2450-mhz-300-w-cw-32-v-rf-ldmos-transistor-for-consumer-and-commercial-cooking:MHT1004N MKW40Z Kinetis MCU: http://www.nxp.com/products/microcontrollers-and-processors/arm-processors/kinetis-cortex-m-mcus/w-series-wireless-m0-plus-m4/kinetis-kw41z-2.4-ghz-dual-mode-ble-and-802.15.4-wireless-radio-microcontroller-mcu-based-on-arm-cortex-m0-plus-core:KW40Z MMA25312B InGaP HBT Linear Amplifier: http://www.nxp.com/products/rf/rf-amplifiers-low-medium-power/wideband-amplifiers/linear-amplifiers/2300-2700-mhz-26-db-31-dbm-ingap-hbt-linear-amplifier:MMA25312B RF Cooking|NXP _______________________________________________________________________________________________________ Other Links: http://www.wayvtech.com/ _______________________________________________________________________________________________________ News The Wayv Of The Future: Portable, Battery-Operated Microwave Communications Infrastructure

EUF-INS-T2477 - Sensor Update Sense everything you need on a connected world with NXP sensors. Sense everything you need on a connected world with NXP sensors.

AUT-N1944 Design the Car of the Future i.MX 8 Virtualization and Media Capabilities for Next Gen eCockpits The hottest topic in automotive design today is the concept of the eCockpit -- where all visual functions in the car are controlled across multiple screens and fully integrated for the driver’s convenience. The key technology that enables eCockpit to run on a single processor also offers new capabilities in industrial, embedded and consumer products such as drones, manufacturing HMI interfaces and smart displays. This class will cover the fundamental technologies and architectural techniques in the i.MX 8 processor which enables rich eCockpit functionality, how NXP has implemented the world’s most significant full chip virtualization capabilities in an ARM-based processor and breaks down the eCockpit demo from the Tech Lab.  Watch Video Presentation The hottest topic in automotive design today is the concept of the eCockpit -- where all visual functions in the car are controlled across multiple screens and fully integrated for the driver’s convenience. The key technology that enables eCockpit to run on a single processor also offers new capabilities in industrial, embedded and consumer products such as drones, manufacturing HMI interfaces and smart displays. This class will cover the fundamental technologies and architectural techniques in the i.MX 8 processor which enables rich eCockpit functionality, how NXP has implemented the world’s most significant full chip virtualization capabilities in an ARM-based processor and breaks down the eCockpit demo from the Tech Lab.  Watch Video Presentation Secure Connected & Automated Vehicles

NXP Technology Days - Barcelona - November 17, 2016 Design, Software & Services EUF-DES-T2474 - Interface Solutions  Insight & Innovation EUF-INS-T2477 - Sensor Update  Secure Connected & Automated Vehicles Advanced Analog Products for Automotive and Industrial Markets  EUF-AUT-T2475 - Analog Products  Secure Mobile, Healthcare & Wearables EUF-MHW-T2470 - Wireless Solutions  Smart Home & Buildings EUF-HMB-T2472 - Are You Ready for the Next Generation of NFC?  Smart Networks EUF-NET-T2471 - Layerscape Update 

Example MPC5777C MCAN-FD simpleTX RX-ISR GHS616 ******************************************************************************** * Detailed Description: * * Configures the MCANs to transmit and receive a CAN FD message with or without * bit rate switching for data phase. This is defined by BRS macro. * Baudrate during arbitration phase is set to 500kbps, during data phase 1Mpbs * because of PHY used on the EVB. * * In this config, MCAN_0 transmits a message. MCAN_1 receives the message. * * MCAN_0 sends message each 1sec. This interval is generated by PIT. * Single TX buffer is used to send n bytes. The message ID is changed for each * transmission. Two standard and 2 extended IDs are sent. * * MCAN_1 is configured to receive a message, ISR is used to read new message. * There are 2 standard and 2 extended ID filter tables defined. Classic filter * configuration is set, means filter ID & mask. * Messages with matched standard ID are received into RXFIFO_0, messages with matched * extended ID then stored in RXFIFO_1. *   * EVB connection: * * J37 and J38 to position 2-3 to connect MCAN1 TX/RX to transceiver * * CAN0-CANH on P15-1 to CAN1-CANH on P14-1 * CAN0-CANL on P15-2 to CAN1-CANL on P14-2 * * * ------------------------------------------------------------------------------ * Test HW:         MPC5777C-512DS Rev.A + MPC57xx MOTHER BOARD Rev.C * MCU:             PPC5777CMM03 2N45H CTZZS1521A * Fsys:            PLL1 = core_clk = 264MHz, PLL0 = 192MHz * Debugger:        Lauterbach Trace32 * Target:          internal_FLASH * Terminal:        19200-8-no parity-1 stop bit-no flow control on eSCI_A *           use USB connector (J21) on minimodule * * EVB connection:  ETPUA30 (PortP P23-15) --> USER_LED_1 (P7-1) *                  ETPUA31 (PortP P23-14) --> USER_LED_2 (P7-2) * ******************************************************************************** ******************************************************************************** * Detailed Description: * * Configures the MCANs to transmit and receive a CAN FD message with or without * bit rate switching for data phase. This is defined by BRS macro. * Baudrate during arbitration phase is set to 500kbps, during data phase 1Mpbs * because of PHY used on the EVB. * * In this config, MCAN_0 transmits a message. MCAN_1 receives the message. * * MCAN_0 sends message each 1sec. This interval is generated by PIT. * Single TX buffer is used to send n bytes. The message ID is changed for each * transmission. Two standard and 2 extended IDs are sent. * * MCAN_1 is configured to receive a message, ISR is used to read new message. * There are 2 standard and 2 extended ID filter tables defined. Classic filter * configuration is set, means filter ID & mask. * Messages with matched standard ID are received into RXFIFO_0, messages with matched * extended ID then stored in RXFIFO_1. *   * EVB connection: * * J37 and J38 to position 2-3 to connect MCAN1 TX/RX to transceiver * * CAN0-CANH on P15-1 to CAN1-CANH on P14-1 * CAN0-CANL on P15-2 to CAN1-CANL on P14-2 * * * ------------------------------------------------------------------------------ * Test HW:         MPC5777C-512DS Rev.A + MPC57xx MOTHER BOARD Rev.C * MCU:             PPC5777CMM03 2N45H CTZZS1521A * Fsys:            PLL1 = core_clk = 264MHz, PLL0 = 192MHz * Debugger:        Lauterbach Trace32 * Target:          internal_FLASH * Terminal:        19200-8-no parity-1 stop bit-no flow control on eSCI_A *           use USB connector (J21) on minimodule * * EVB connection:  ETPUA30 (PortP P23-15) --> USER_LED_1 (P7-1) *                  ETPUA31 (PortP P23-14) --> USER_LED_2 (P7-2) * ******************************************************************************** General Re: Example MPC5777C MCAN-FD simpleTX RX-ISR GHS616 Hi Luke, yes, you are correct. The MCAN1's base is 0xFFE3_8000 on MPC5777C. In fact this macro is not used in the code, so have no effect.  It comes from other project (for MPC5777M I think) and I forgot to delete it. BR, Petr Re: Example MPC5777C MCAN-FD simpleTX RX-ISR GHS616 Hello PetrS‌ Could you check my question about thie code? when I cheked main.c, I think that #define MCAN1_BASE_ADDR 0xFFEE8000 is not correct. As far as I know, MCAN1's base is 0xFFE3_8000... Could you check it? Thank you.

Example JTAG access – Addendum to application notes AN3283 and AN4365 This example follows application notes AN3283 and AN4365. It is intended for users who develop own JTAG programmer. It shows how to implement basic functions: - enter debug mode during reset - enable external debug mode - OnCE access to GPR, SPR and memory - Nexus access to memory The example is written in PRACTICE script language using Trace32 debugger from Lauterbach (www.lauterbach.com). Low level functions for JTAG are used, so users can see sequences of ‘0’s and ‘1’s which are sent to JTAG interface. Used commands are described in this document: www2.lauterbach.com/pdf/general_ref_j.pdf This example was tested on MPC5607B device and VLE instruction set was used for OnCE access. General