DOCSLIB.ORG

LAT-INS-T2442.Pdf

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
LAT-INS-T2442.Pdf ANALOG SOLUTIONS FOR MULTI- MARKET - AUTOMOTIVE AND INDUSTRIAL LAT-INS-T2442 EMMANUEL CARCENAC GLOBAL DISTRIBUTION MARKETING MANAGER NOVEMBER 08, 2016 PUBLIC Advanced Analog Portfolio Overview In-Vehicle Networking Safety & Power Management Drivers & Energy Secure Car Access • MPU system power management • CAN, CAN-FD/PN transceiver • Intelligent Battery Sensors • Immobilizer / Remote Key entry IC (i.MX, LS, FPGA, …) • CAN FD Shield • Li-Ion Battery Cell Controller • Passive key entry / Keyless go • Single cell battery charger • LIN, Quad LIN transceiver • DC/stepper motor power driver • 2-way RF keyless access • Functional Safe System Basis Chip • Flexray transceiver • BLDC motor gate driver • Motorcycle braking • Networking System Basis Chip • Programmable switches • Sub-GHz multi-protocol RF • Valve Controller SoC • Twisted pair Ethernet transceiver • Small fuel engine controller Modem supporting: • Switch Monitoring Serial Interface • Ethernet switch • LED Buck/Boost Controllers • Sigfox, W-Mbus, ZigBee,… • IO-Link master & slave transceiver R M IoT #1 in In-Vehicle Networking #1 in Safety Benchmark BMS Solution #1 in Car Access MCU Cross Selling Enablement Tools Evaluation GUI & SW FRDM & TWR HW boards MCU/MPU SDK SW drivers example code 1 PUBLIC IN VEHICLE NETWORKING CAN, LIN, FLEXRAY, ETHERNET 2 PUBLIC IN-VEHICLE connectivity NETWORKS MORE CONNECTIONS – More Bandwidth 1000 Mbps +1Gbps Ethernet 6 5.3 40 Ethernet 100Mbps 35 5 +100Mbps Ethernet 30 3.7 Nodes/Car 25 +CAN FD 4 30 kg 10 Mbps 20 +IsoCAN Year 2014 2016 2018 2020 2 km wire 3 +Partial 2.3 350 parts 5 Mbps Networking 2 +FlexRay 1.3 CAN +LIN +FT CAN Network Nodes/Year [Billion] Nodes/Year Network 1 0.6 1 Mbps 0.2 0.01 0.05 0 1994 1998 2002 2006 2010 2014 2018 2022 20 kbps Year 3 PUBLIC CAN in non-Automotive applications Building Control Industrial Transportation HVAC Heavy Machinery Elevators Forklifts Access / Security Farm Equipment Automation Trains Surveillance SAE J1939 Buses Factory Automation Connected Consumer PLC I/O Wearables Safety Systems ePOS Robotics Drones Motor Drives Medical devices eBikes Energy Conservation Asset tracking Energy Storage Converters Smart metering Tools & Appliances 4 PUBLIC Evolution in CAN: CAN FD with Flexible/Higher Datarate A smart evolutionary step NXP in driving seat Sensors / Embedded Control MM / ADAS Providing fast CAN FD network 100 M transceivers Ethernet Broad-R Providing Reach 10 M Top EMC FlexRay performances CAN FD rate (bit/s) rate - 1 M CAN Data Enabling mixed networks 100 K PSI5 SOP Providing total Q4-17 LIN Implementation Cost per Node 10 K simulation environment Boosting net data transfer Over 10x more data vs. CAN 2.0 Driving Enabling bigger, simpler IVNs Less gateways & couplers definition Minimizing HW/SW impact Preserving investments made of standards 5 PUBLIC CAN Portfolio 1/2 NXP HS-CAN PORTFOLIO - STANDARD FUNCTIONS: Battery MCU System voltage Basic Standby Dual-Standby TJA1057G TJA1044G TJA1046 12V 5V HVSON Mbps Optimised IN PRODUCTION IN PRODUCTION IN PRODUCTION Passenger 3V3 TJA1057G/3 TJA1044G/3 Vehicles Pin 5: VIO IN PRODUCTION IN DEVELOPMENT - SAMPLES: Q3-16 / SOP: Q1-17 TJA1051 TJA1042 TJA1059 Full 24V 5V Support IN PRODUCTION IN PRODUCTION IN PRODUCTION Commercial 3V3 TJA1051/3 TJA1042/3 Vehicles Pin 5: VIO IN PRODUCTION IN PRODUCTION NXP HS-CAN PORTFOLIO - ADVANCED POWER MODES: Sleep Partial Networking FD-Passive TJA1043 TJA1145 TJA1145/FD 12V and 24V Support Mbps IN PRODUCTION IN PRODUCTION IN PRODUCTION REASONS TO Parts internally Chokeless EMC HVSON package Max 1Mbps bit Supports max 2 / 6 PROMOTE:PUBLIC dual sourced performance option available Mbps rate for HS-CAN 5Mbps CAN FD CAN Portfolio 2/2 NXP HS-CAN PORTFOLIO - VeLIO COMPLIANT HS-CAN: Standby (PIN 5: n.c.) Standby (PIN 5: VIO) Dual-Standby 12V Optimised TJA1044V TJA1044V/3 Passenger Vehicles IN DEVELOPMENT - SAMPLES: Q3-16 / SOP: Q1-17 IN DEVELOPMENT - SAMPLES: Q3-16 / SOP: Q1-17 HVSON Mbps Standby (PIN 5: SPLIT) Standby (PIN 5: VIO) Full 24V Support TJA1049 TJA1049/3 TJA1059 Commercial Vehicles IN PRODUCTION IN PRODUCTION IN PRODUCTION TJA1900 MULTI-CHIP MODULES SERIES ISOLATED HS-CAN TJA1046 + TJA1029 TJA1044 + TJA1043 + TJA1029 TJA1901 TJA1902 TJA1052i IN DEVELOPMENT - SAMPLES: Q1-16 / SOP: Q3-16 IN DEVELOPMENT - SAMPLES: Q1-16 / SOP: Q3-16 IN PRODUCTION LEGACY CAN FUNCTIONS: Fault-Tolerant CAN Single Wire CAN CAN Controller TJA1055 MC33897 SJA1000 IN PRODUCTION IN PRODUCTION Mbps IN PRODUCTION Max 1Mbps bit REASONS TO Parts internally Chokeless EMC HVSON package Supports max 2 / rate for HS-CAN PROMOTE: dual sourced performance option available 5Mbps CAN FD 7 PUBLIC Mbps UJA1018 LIN Transceiver Portfolio Overview LED lighting LIN SBC + LIN switch + Voltage TJA1028 + LED driver regulator Mini LIN SBC LIN + WWD + GPI + 1/2WAKEs + Unique EoL Mini-SBCs + HVMPO config. via SPI + TxD + High- TJA1027 dominant TJA1029 + INH TJA1021 Speed MC33662 Core LIN transceiver timeout Basic LIN transceiver + WAKE Standard LIN transceiver LIN Standard LIN transceiver Standalone LIN Transceivers TJA1022 TJA1024 Dual LIN transceiver Quad LIN transceiver Multi-LIN Transceivers + 2nd LIN + 3rd & 4th channel LIN channel 8 PUBLIC Jasper Compliant FlexRay Physical Layer Products Overview Clamp 30 Clamp 15 Transceiver Transceiver Active Star TJA1080A st TJA1081 TJA1082 1 Gen Voltage Reg. Control Basic transceiver Trx & Active Star SSOP16 TSSOP14 SSOP20 TJA1085 4-Branch 2nd Gen TJA1081B TJA1083 HVQFN44 Improved EMC Voltage Reg. Control TSSOP14 Jaspar Compliant SSOP16 TJA1086 2-Branch HVQFN44 Clamp 15: Optimized for ECUs switched off by the ignition key Clamp 30: Optimized for ECUs permanently connected to the battery In Production Under Dev. Planned 9 PUBLIC The Added Value of Ethernet 10 PUBLIC Introducing Ethernet: NXP provides Auto-Native Portfolio Flexible, Scalable solution TJA1102 TJA1100 100MBPS PHY – RELEASED Dual-OABR PHY • Open Alliance BroadR-Reach Compliant • Fully automotive qualified • Robust automotive grade EMC and ESD • Minimal external component count • Enhanced Power Management to save battery life TJA1102 Dual-PHY – Production Q2 2017 • Single chip dual BroadR-Reach PHY • Enables better scalability SJA1105/T FIVE-PORT SWITCH – RELEASED • Layer 2 Store and Forward Switch, • Supports AVB, TSN and Deterministic Ethernet • Up to 1-Gb network speed, • MII/RMII/RGMII Interface • Port Mirroring and VLAN support (IEEE 802.1Q TJA1102 and IEEE 802.1P) Dual-OABR PHY AVB AUTOSAR Host Processor (i.MX, MPC5748G)e.g. MPC574xC/D/G 11 PUBLIC From PHY to System Basis Chip Functional Safety System Basis Chip (fit for ASIL C/D) Increased Functionality: - Transceiver(s) - Power Regulation: LDO, DC/DC Body & Gateway System Basis Chip - System power management - System protection & Diagnostics - Functional Safety support CAN/ LIN System Basis Chip Mini LIN Mini CAN System Basis Chip System Basis Chip Multi LIN Channel Multi CAN Channel Star Coupler Ethernet Switch Integration Level & Performance & Level Integration LIN CAN FR Transceiver Transceiver Transceiver PHY No PHY Communication speed 12 PUBLIC 1 Body Peripherals/General purpose SBC Selection Mini SBC Mid Range SBC Power SBC CAN or LIN CAN & LIN CAN&LIN TJA1028 UJA116x(A) UJA107xA UJA1169 MC33903/4/5 UJA113x(FD) MC33909 Family Family Family Family Family Family Family • LIN only • CAN only • CAN only or CAN & LIN • CAN & LIN • 5V LDO, 70mA • 5V LDO, 100mA • 5V or 3,3V LDO, 250mA • 5V or 3,3V SMPS, 500mA • HVSON8 • HVSON14 • Ext. PNP option • Several add-on features • HTSSOP32 or HVSON20 or SOIC32EP • HTQFP48 or LQFP48EP TJA1128 Family In Production In Development Approved Concept Available for ordering Project and timing committed. Product concept committed internally. Indicative timing only. 13 PUBLIC Body Applications SBC Overview Types Features & Options Supply Sleep Iq Vbatt MCU Supply External Partial with ext VIO AMUX CAN PHY LIN SPI Watch Dog INH LIMP WAKE Package size Mode µA Sense internal 5V Supply Networking PNP 250mA 350 mA - - t.b.d. - up to 2 Y O Y 2 HTSSOP32 UJA107x Y 5V or 3.3V - 6.1 x 11 mm Timeout 150 mA Y up to 2 Y SOIC32 Y 15 Y 400 mA P/N - Y - Y Window up to 4 MC33903 5V or 3.3V (std) (P/S/D) Safe 7.5 x 11 mm Random Timeout 150 mA Yes Y 0 or 1 Y SOIC32 Y 15 Y 400 mA P/N Y - Y Window up to 4 MC33904/5 5V or 3.3V Ext PNP (std) (904/5) Safe 7.5 x 11 mm Random UJA1161A / - - - - FD Active - - - - - 1 HVSON14 O Y 2 Mbps O 3 x 4.5 mm UJA1162A UJA1163A / 100mA - - - - FD Active - - O O - - 1 HVSON14 - 2 Mbps 3 x 4.5 mm UJA1164A 5V UJA1167A / 100mA 30 mA FD Active HVSON14 Y - - - O - Y Y O - 1 UJA1168A 5V (option) 2 Mbps 3 x 4.5 mm 250mA 100mA FD Active HVSON20 Y 250 mA O - O - Y Y - Y 1 UJA1169 5V or 3.3V (option) 2 Mbps 5.5 x 3.5 mm 500 mA FD Active HTQFP48 Y Y - - 100mA - O up to 2 Y Y - Y 1 UJA113x 5V or 3.3V 2 Mbps 10 x 10 mm 500 mA HS CAN LQFP48 Y 125 Y 500mA - 200mA Y - up to 4 Y Y - Y 6 MC33909 5V or 3.3V 1Mbps 7 x7 mm Y = Supported 14 PUBLIC O = Optional (support on some variants) SYSTEM BASIS CHIP & POWER MANAGEMENT IC 15 PUBLIC NXP PowerSBC Application examples 16 PUBLIC FUNCTIONAL SAFETY VALUES 5P’s Functional Safety Pillars & Differentiation Philosophy – Culture Philosophy • « To design systems that work correctly we MUST understand and correct how they can go wrong » Daniel Saul Goldin, NASA Administrator • SafeAssure : Corporate commitment to support functional Safety Process – Discipline Products Process • Analog & Sensor ISO26262 Development Process Compliance certified by TÜV-SAAR People – Know how • Training, Safety Culture & mindset. Expertise on ISO26262 Standard,
Load more

Recommended publications
  • TI Designs: TIDA-01428 Automotive Discrete SBC Pre-Buck, Post-Boost with CAN Reference Design
    TI Designs: TIDA-01428 Automotive Discrete SBC Pre-Buck, Post-Boost With CAN Reference Design Description Features The TIDA-01428 reference design implements a • Wide-Input Voltage, Fixed 3.3-V Buck Converter discrete system basis chip (SBC) with a 1-A, wide-VIN, • Low-Input Voltage, Fixed 5-V Boost Converter buck converter to 3.3 V followed by a compact, low- • CAN Transceiver With Flexible Data-Rate (FD) up input voltage, fixed 5-V boost converter for powering a to 5 MBPS controller area network (CAN) physical layer interface. The design has been tested for CISPR 25 radiated • Passes Class 4 CISPR 25 Radiated Emissions emissions and conducted emissions using the voltage • Passes Class 4 CISPR 25 Conducted Emissions method and for immunity to bulk current injection (BCI) • Passes ISO 11452-4 Bulk Current Injection per ISO 11452-4 with CAN communication operating at 500 KBPS. The TIDA-01428 is an EMC-vetted • Able to Survive Load Dump Voltages up to 42 V power tree plus CAN reference design that can be • Maintains Regulated 3.3-V and 5-V Supplies used in many automotive applications. Through Battery Input Voltages Down to 4.3 V Resources Applications • Automotive Body Control Module (BCM) TIDA-01428 Design Folder LM53601-Q1 Product Folder • Automotive Front Camera TPS61240-Q1 Product Folder • Automotive Head Unit TMS320F28030PAGQ Product Folder TCAN1042V-Q1 Product Folder SN74LVC2G06-Q1 Product Folder CSD17313Q2 Product Folder ASK Our E2E Experts 3.3-V .uck 5-V La53601-v1 TtS61240-v1 CANH a/h t]}o}¡ CAb TMS320 TCAb1042V-v1 C28030tADv CANL Copyright © 2017, Texas Instruments Incorporated An IMPORTANT NOTICE at the end of this TI reference design addresses authorized use, intellectual property matters and other important disclaimers and information.
    [Show full text]
  • D4.1 Preliminary BMS Design and Sensor Integration Concept
    Ref. Ares(2021)2904016 - 30/04/2021 Delivering the 3b generation of LNMO cells for the xEV market of 2025 and beyond Preliminary BMS design and sensor integration concept Horizon 2020 | LC-BAT-5-2019 Research and innovation for advanced Li-ion cells (generation 3b) GA # 875033 Deliverable No. D4.1 Deliverable Title Preliminary BMS design and sensor integration concept Due Date 2020-04-30 Deliverable Type Report Dissemination level Public Written By Stefan Waldhör (FhG) 2021-04-30 Checked by Simone Mannori (ENEA) 2021-04-24 Approved by Claudio Lanciotti (MIT), Boschidar Ganev (AIT) 2021-04-29 Status Final 2021-04-30 This project has received funding from the European Union’s H2020 research and innovation programme under Grant Agreement no. 875033. This publication reflects only the author’s view and the Innovation and Networks Executive Agency (INEA) is not responsible for any use that may be made of the information it contains. Revision History Version Date Who Changes 1.1 2021-04-30 AIT • Reviewed final version of the document 1.0 2021-04-28 FhG • Final version of the document 0.14 2021-04-28 MIT • Review of the document 0.13 2021-04-21 FHG • Add conclusion • Add section on mechanical integration 0.12 2021-04-21 VALEO • Add section on thermal management system • Add image of foxBMS 2 Master Unit • Add paragraph on foxBMS 2 Master Unit • Update system architecture block diagram with TMB 0.11 2021-04-19 FhG • Add section on the Interface Board • Add section on data storage and connectivity • Add section on mechanical integration • Fix
    [Show full text]
  • Fault Tolerant Design Techniques for Smart Power Drivers and Diagnostic Circuits
    Fault Tolerant Design Techniques for Smart Power Drivers and Diagnostic Circuits Fehlertolerante Design-Techniken für Smart Power-Treiber und Diagnoseschaltungen Der Technischen Fakultat der Friedrich-Alexander Universität Erlangen-Nürnberg Zur Erlangung des Grades DOKTOR-INGENIEUR vorgelegt von Sri Navaneethakrishnan Easwaran Erode, India 1 Als Dissertation genehmigt von der Technischen Fakultät der Friedrich-Alexander-Universität Erlangen-Nürnberg Tag der mündlichen Prüfung: 23.05.2017 Vorsitzender des Promotionsorgans: Prof. Dr.-Ing. Reinhard Lerch Gutachter: Prof. Dr.-Ing. Dr.-Ing. habil. Robert Weigel Prof. Dr.-Ing. Martin März 2 Dedicated to my family 3 Abstract The demand for electronic control is increasing and is replacing most of the hydraulics in the automotive. Automobiles produced today have a longer life expectancy than at any time in the past. One of the strongest contributors for this is the increase in electronic equipment and systems that have replaced mechanical devices. Without proper electrical protection, however, these electronic systems in automobiles can fail without warning there by creating risk for the driver and passengers including injuries and life threat. Power semiconductor devices that are used in these electronic systems handle high currents in the order of 2A at 40V. Due to this high voltage and high current several design measures have to be considered in the design to make these circuits fault tolerant. The unintentional or inadvertent activation of the powerFETs should be avoided else it would trigger very high currents. In the light of this, the purpose of the present doctoral dissertation is set to contribute to the design of Smart Power Drivers for airbag squib driver applications.
    [Show full text]
  • MC33907 08 Safe System Basis Chip Hardware Design and Product Guidelines
    NXP Semiconductors Document Number: AN4766 Application Note Rev. 6.0, 2/2019 MC33907_08 safe system basis chip hardware design and product guidelines 1 Introduction Contents 1 Introduction . 1 This application note provides design guidelines for integrating the 2 Overview . 1 MC33907_08 system basis chip (SBC) into automotive and 2.1 Typical block diagram . 2 industrial electronic systems. It shows how to optimize PCB layout 2.2 Voltage regulators . 3 and gives recommendations regarding external components. 2.3 Built-in CAN transceiver . 4 2.4 Built-in LIN transceiver . 4 To minimize the EMC impact from embedded DC/DC converters, 2.5 Analog multiplexer . 4 pay attention to PCB component routing when designing with the 2.6 Configurable I/Os . 4 MC33907_08. 2.7 Safety outputs . 4 2.8 Fail-safe machine . 5 2.9 Low-power mode off . 5 2.10 Watchdog . 5 2.11 MCU flash programming . 5 2 Overview 2.12 Simplified internal power tree . 6 3 Known device behaviors . 7 The MC33907 and MC33908 are multi-output power supply 3.1 Unexpected current limitation report after start up . 7 integrated circuits dedicated to the automotive market. The 4 Application schematic . 8 MC33907_08 simplifies system implementation by providing ISO 5 Optional configurations . 9 26262 system solutions, documentation, and an optimized MCU 5.1 Pre-regulator, buck or buck-boost configuration . 9 interface, enabling customers to minimize the cost and complexity 5.2 VCCA, current capability . 10 of their designs. The MC33907_08’s integral EMC and ESD 5.3 VAUX . 10 protection also facilitates less complex system designs with 5.4 IO_0 ignition connection .
    [Show full text]
  • TLIN1028-Q1 Automotive Local Interconnect Network (LIN)
    TLIN1028-Q1 www.ti.com SLLSEX4A – AUGUST 2019 – REVISEDTLIN1028-Q1 OCTOBER 2020 SLLSEX4A – AUGUST 2019 – REVISED OCTOBER 2020 TLIN1028-Q1 Automotive LIN 125-mA System Basis Chip (SBC) 1 Features 2 Applications • AEC-Q100 (Grade 1): Qualified for automotive • Body electronics and lighting applications • Hybrid, electric & powertrain systems • Local interconnect network (LIN) physical layer • Automotive infotainment and cluster specification ISO/DIS 17987–4 compliant and • Appliances conforms to SAE J2602 recommended practice for LIN 3 Description • Functional Safety-Capable The TLIN1028-Q1 is a local interconnect network – Documentation available to aid functional safety (LIN) physical layer transceiver, compliant to LIN 2.2A system design ISO/DIS 17987–4 standards, with an integrated low • Supports 12-V applications dropout (LDO) voltage regulator. • Wide operating ranges This LIN system basis chip (SBC) reduces system – ±58 V LIN bus fault protection complexity by providing a 3.3 V or 5 V rail with up to – LDO output supporting 3.3 V or 5 V 70 mA (D) or 125 mA (DRB and DDA) of current to – Sleep mode: Ultra-low current power microprocessors, sensors or other devices. consumption allows wake-up event from: The TLIN1028-Q1 has an optimized current-limited • LIN bus or local wake through EN pin wave-shaping driver which reduces electromagnetic – Power-up and down glitch-free operation emissions (EME). The TLIN1028-Q1 converts the LIN protocol data stream on the TXD input into a LIN bus • Protection features: signal. The receiver converts the data stream to logic- – ESD protection, VSUP under-voltage protection level signals that are sent to the microprocessor – TXD dominant time out (DTO) protection, through the open-drain RXD pin.
    [Show full text]
  • Automotive Solutions for Electro-Mobility Contents
    Automotive Solutions for Electro-Mobility Contents 3 Smart Mobility 4 Electro-Mobility 5 Key Applications 6 Main Traction Inverter 7 On-Board Charger (OBC) 8 48V Start-Stop System 9 Bidirectional DC/DC Converter 10 Battery Management System 11 48V Electric Traction 12 Acoustic Vehicle Alerting System (AVAS) 13 HV Battery Disconnect & Fire-off System 14 Vehicle Control Unit (VCU) 16 Key Technologies 18 Development Tools 18 Product Selectors samples, Evaluation Boards 19 SPC5 Automotive MCU Evaluation Tools 21 AutoDevKit Smart Mobility It is estimated that 80% of all innovations in the automotive industry today are directly or indirectly enabled by electronics. With vehicle functionality improving with every new model this means a continuous increase in the semiconductor content per car. With over 30 years’ experience in automotive electronics, ST is a solid, innovative, and reliable partner with whom to build the future of transportation. ST’s Smart Mobility products and solutions are making driving safer, greener and more connected through the combination of several of our technologies. SAFER Driving is safer thanks to our Advanced Driver Assistance Systems (ADAS) – vision processing, radar, imaging and sensors, as well as our adaptive lighting systems, user display and monitoring technologies. GREENER Driving is greener with our automotive processors for engine management units, engine management systems, high-efficiency smart power electronics at the heart of all automotive sub-systems and devices for hybrid and electric vehicle applications. 80% MORE CONNECTED And vehicles are more connected using our infotainment-system and telematics of all innovations processors and sensors, as well as our radio tuners and amplifiers, positioning in the automotive technologies, and secure car-to-car and car-to-infrastructure (V2X) connectivity solutions.
    [Show full text]
  • Automotive Power Selection Guide Ultimate Power – Perfect Control
    Automotive Power Selection Guide Ultimate power – perfect control www.infineon.com/automotivepower The ultimate power to control your applications including automotive, transportation, industrial, lighting and motor control. For a comprehensive and reliable portfolio of products Our commitment to quality is demonstrated through for automotive and other applications, look no further than our focus on automotive excellence, the most rigorous zero the product range from Infineon. We have used our 40 defect program in the industry. years of experience of developing and producing products to meet the demands of the automotive market, and our This selection guide provides an overview of our ICs innovative technologies to design and produce a large and their packages, which are automotive qualified and number of power products that meet all requirements of available for your current and future electronic system the automotive industry and also the transportation, designs. lighting and motor-drive industries. 2 Automotive applications › Electric sunroof › Rear wiper › Airbag › Suspension › Window li › Power seat › Electric mirrors Power door › Font wiper › › Body control module/gateway › Starter alternator › Steering › Lighting › Throttle control › Headlight leveling › Engine control › Transmission › HVAC › Hybrid › Brake system Automotive power components used in other applications Industrial drives Electric toys 3 We meet all requirements for cost-effective application solutions Smart Power ICs Power System ICs Embedded Power ICs › Smart multi-channel
    [Show full text]
  • Power Supply Platform and Functional Safety Concept Proposals for a Powertrain Transmission Electronic Control Unit
    electronics Article Power Supply Platform and Functional Safety Concept Proposals for a Powertrain Transmission Electronic Control Unit Diana Raluca Biba 1, Mihaela Codruta Ancuti 1,*, Alexandru Ianovici 2, Ciprian Sorandaru 1 and Sorin Musuroi 1 1 Electrical Engineering Department, Faculty of Electrical and Power Engineering, University Politehnica Timisoara, 300223 Timisoara, Romania; [email protected] (D.R.B.); [email protected] (C.S.); [email protected] (S.M.) 2 Continental Automotive, Powertrain Transmission Department, 90411 Nurnberg, Germany; [email protected] * Correspondence: [email protected]; Tel.: +40-766-699556 Received: 12 May 2020; Accepted: 15 September 2020; Published: 27 September 2020 Abstract: In the last decade, modern vehicles have become very complex, being equipped with embedded electronic systems which include more than a thousand of electronic control units (ECUs). Therefore, it is mandatory to analyze the potential risk of automotive systems failure because it could have a significant impact on humans’ safety. This paper proposes a novel, functional safety concept at the power management level of a system basis chip (SBC), from the development phase to system design. In the presented case, the safety-critical application is represented by a powertrain transmission electronic control unit. A step-by-step design guideline procedure is presented, having as a focus the cost, safety, and performance to obtain a robust, cost-efficient, safe, and reliable design. To prove compliance with the ISO 26262 standard, quantitative worst-case evaluations of the hardware have been done. The assessment results qualify the proposed design with automotive safety integrity levels (ASIL, up to ASIL-D).
    [Show full text]
  • AN13091, EV Traction Motor Power Inverter Control Reference Platform
    AN13091 EV Traction Motor Power Inverter Control Reference Platform Rev. 1 — 19 March 2021 Application note 1 Acronyms Table 1. Acronyms Acronym Definition PIM Power Inverter Module VCU Vehicle Control Unit ECU Electronic Control Unit TC Traction Control SDK Software Development Kit SBC System Basis Chip SPI Serial Peripheral Interface MCU Micro-Controller Unit IGBT Insulated-Gate Bipolar Transistor GD Gate Driver ASIL Automotive Safety Integrity Level RDC Resolver-to-Digital Converter SiC Silicon Carbide CMF Common Mode Failure NXP Semiconductors AN13091 EV Traction Motor Power Inverter Control Reference Platform 2 General Description The NXP EV Power Inverter Control Reference Platform provides a hardware reference design, system basic software, and a complete system functional safety enablement as a foundation on which to develop a complete ASIL-D compliant high voltage, high-power traction motor inverter for electric vehicles. The Reference Platform has been designed into an evaluation prototype demonstrating 150 kW peak output power and >96% electrical efficiency operating from a 320 V supply voltage. The hardware reference platform is comprised of four boards: • System control board – Same design and components apply when transitioning from IGBT to SiC • Power stage driver board – GD3100 can be used for IGBT and SiC • Current sensor board • Vehicle interface board Figure 1. Inverter Control Reference Platform boards System control board: AN13091 All information provided in this document is subject to legal disclaimers. © NXP B.V. 2021. All rights reserved. Application note Rev. 1 — 19 March 2021 2 / 42 NXP Semiconductors AN13091 EV Traction Motor Power Inverter Control Reference Platform • This board contains three key NXP integrated circuits.
    [Show full text]
  • Product Catalog 2021/2022 Product Catalog 2021/2022
    Product Catalog 2021/2022 Product Catalog 2021/2022 Elmos Product Catalog | 2021/2022 1 Driving future mobility Made for you: Perfectly fitting ICs Elmos ICs bring innovation into the customer’s system. Innovation Matters - this is our Next to a broad range of ASSPs (Application Specific Standard Product) Elmos offers claim. We are one of the world’s most experienced semiconductor companies for the ASICs (Application Specific Integrated Circuit), that are specifically designed to the cus- automotive industry. Our components communicate, measure, regulate and control tomer’s needs. The advantage of an ASIC: The special chip is tailor-made for use in the safety, comfort, powertrain and network functions. For over 35 years, Elmos has been customer application and its individual design stays protected. bringing new functions to life and making mobility worldwide safer, more comfortable and more energy efficient. With our solutions we are already the worldwide #1 in appli- Best possible system integration, which means creating a higher functionality whilst cations with great future potential, such as ultrasonic distance measurement, ambient simultaneously reducing the complexity at system level, is the target of the work. System light and intuitive HMI. knowledge combined with expertise and the optimal choice of possible integration strat- egies are prerequisites for success. Elmos ICs serve the following global megatrends: Autonomous driving Our design teams are experts in the following application fields: Electromobility/CO reduction 2 Sensor ICs Safety, connectivity and comfort Ultrasonic Distance, Sensor Signal Processor, Optical IR, Smoke Detector, Passive Infrared With locations all over the world, we are represented in all key markets and always close Motor Control ICs to the customer.
    [Show full text]
  • High Power X-Band RF Test Stand Development and High Power Testing of the CLIC Crab Cavity
    High Power X-band RF Test Stand Development and High Power Testing of the CLIC Crab Cavity Benjamin J. Woolley This thesis is submitted in partial fulfilment of the requirements for the degree of Doctor of Philosophy August 2015 Abstract This thesis describes the development and operation of multiple high power X-band RF test facilities for high gradient acceleration and deflecting structures at CERN, as re- quired for the e+ e- collider research programme CLIC (Compact Linear Collider). Signif- icant improvements to the control system and operation of the first test stand, Xbox-1 are implemented. The development of the second X-band test stand at CERN, Xbox-2 is followed from inception to completion. The LLRF (Low Level Radio Frequency) system, interlock system and control algorithms are designed and validated. The third test stand at CERN, Xbox-3 is introduced and designs for the LLRF and control systems are pre- sented. The first of the modulator/klystron units from Toshiba and Scandinova is tested. CLIC will require crab cavities to align the bunches in order to provide effective head- on collisions. An X-band travelling wave cavity using a quasi-TM11 mode for deflection has been designed, manufactured and tested at the Xbox-2 high power test stand. The cavity reached an input power level in excess of 50 MW, at pulse widths of 150 ns with a measured breakdown rate (BDR) of better than 10 -5 breakdowns per pulse (BDs/pulse). At the nominal pulse width of 200 ns, the cavity reached an input power level of 43 MW with a BDR of 10-6 BDs/pulse.
    [Show full text]
  • 33742 33742S Advance Information System Basis Chip
    查询MC33742DWR2供应商Freescale Semiconductor,捷多邦,专业PCB打样工厂,24小时加急出货 Inc. MOTOROLA Document order number: MC33742 SEMICONDUCTOR TECHNICAL DATA Rev 2.0, 10/2004 Advance Information 33742 33742S System Basis Chip (SBC) with Enhanced High-Speed CAN Transceiver SYSTEM BASIS CHIP WITH ENHANCED The 33742 and the 33742S are monolithic integrated circuits combining HIGH-SPEED CAN many functions frequently used by automotive environmental control units (ECUs). The 33742 is an SBC having a fully protected fixed 5.0 V low-drop regulator with current limit, overtemperature pre-warning, and reset. An output drive with . sense input is also provided to implement a second 5.0 V regulator, using an . external PNP bipolar junction transistor. The 33742 has normal, standby, stop, c and sleep modes, an internally switched high-side power supply output with n four wake-up inputs, programmable window watchdog, interrupt, reset, SPI I input control, and a high-speed CAN transceiver compatible with CAN 2.0 A , and B protocols for module-to-module communication. r DW SUFFIX o Features CASE 751F-05 t • High-Speed 1.0 Mbps CAN Interface with Bus Diagnostic Capability 28-TERMINAL SOICW c (Detection of CANH and CANL Short to Ground, to VDD, and to VSUP) u • Low-Drop Voltage 5.0 V, 200 mA V Regulator with Current-Limiting, d DD ORDERING INFORMATION n Overtemperature Pre-Warning, and Output Monitoring with Reset Temperature o • Additional 5.0 V Regulator with External Series Pass Transistor Device Package Range (TA) c • Normal, Standby, Stop, and Sleep Modes with Low Sleep
    [Show full text]