DOCSLIB.ORG

IBM Power Systems: Идеальная Платформа Для Снижения Операционных Расходов Информационной Системы

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
IBM Power Systems: Идеальная Платформа Для Снижения Операционных Расходов Информационной Системы IBM Power Systems: идеальная платформа для снижения операционных расходов информационной системы Алексей Бойко IBM Power Systems Product Manager [email protected] © 2013 IBM Corporation IBM Power Systems Research Institute of Suzhou PowerCore Jiangsu Industrial Technology Company Technology © 2013 IBM Corporation IBM Power Systems Реалии сегодняшние отличаются от вчерашних 1996 2011 65% Hardware 11% 14% Software 33% 14% People 46% 7% Other 10% Структура затрат на работающую систему очень сильно изменилась. Использование прогрессивных технологий «железа» позволяет сократить расходы на ПО и обслуживающий персонал. 3 © 2013 IBM Corporation IBM Power Systems Система ценностей ЦОД ✓Уверенность в завтрашнем дне ✓Масштабируемость ✓Энергоэффективность ✓Производительность ✓Производительность на ядро ✓Занимаемое место ✓RAS ✓Уникальная гибкость 4 © 2013 IBM Corporation IBM Power Systems Функции RAS IBM Power RAS и Intel Xeon 5 © 2013 IBM Corporation IBM Power Systems Немного о процессорах IBM Power © 2013 IBM Corporation IBM Power Systems IDC: 10 Year UNIX Server Market 1Q03 – 1Q13 Annual UNIX Server Market Revenue Share 1Q13 R4Q WW Unix Server Segment 60% 55% 50% POWER6 Live Partition 45% POWER5 Mobility Micro-Partitioning 40% 35% POWER7 Workload Optimized Revenue Share Revenue 30% Leadership 25% 20% POWER4 Dynamic LPARs 15% IBM HP Oracle Source: IDC Server Tracker 1Q13 May Power Systems Share 1Q13: UNIX Linux - IDC Server 2013 Tracker I IBM Proprietary 7 © 2013 IBM Corporation IBM Power Systems RISC процессоры на Марсе «Because of this, he added that an Intel Core i7 processor, for example, wouldn't survive a day on Mars because of the extremes in temperature.» The single-board computer aboard NASA's Curiosity rover is built around a PowerPC RAD750 microprocessor provided by BAE Systems. ComputerWorld August 8 2012 http://www.computerworld.com/s/article/9230060/NASA_Your_smartphone_is_as_smart_as_the_Curiosity_rover CBS News http://www.cbsnews.com/network/news/space/home/spacenews/files/081012_msl_update.html © 2013 IBM Corporation IBM Power Systems PowerPC Still in the Spirit NASA sends IBM chipkill with RS/6000 on Mars Pathfinder (1996) Spirit and Opportunity Rovers Powered by PowerPC 9 © 2013 IBM Corporation IBM Power Systems IBM POWER processor roadmap ~ 3 Year Revolution ~ 18 month “+” Evolution POWER8 POWER7/7+ Most POWER6/6+ Most POWERful, POWERful & Scalable POWER5/5+ Scalable and Exclusive Processor in Performance Fastest Industry Processor Hardware . More Cores POWER4/4+ In Industry . 4,6,8 Core Virtualization . Larger Cache . 32MB On-Chip eDRAM . 4th Gen SMT for Unix & Linux . Dual Core . Power Optimized Cores . Reliability ++ First Dual Core . High Frequencies . Mem Subsystem ++ . Accelerators + .Dual Core & Quad Core Md in Industry . Virtualization + . 4 Thread SMT++ . more… .Enhanced Scaling . Memory Subsystem + . Reliability + . 22nm .2 Thread SMT . Dual Core . Altivec . VSM & VSX High Level design complete .Distributed Switch + . Chip Multi Processing . Instruction Retry . Protection Keys+ and in implementation phase .Core Parallelism + . Dyn Energy Mgmt . 45nm . Distributed Switch IBM is the leader . Shared L2 .FP Performance + . 2 Thread SMT + Power 7+ 32nm . Dynamic LPARs (32) .Memory bandwidth + . Protection Keys . Faster in Processor and .180nm, 130nm .130nm, 90nm . 65nm . 10mb cache/core Server design . Accelerators 2001 2004 2007 2010/2013 Binary Compatible & Increased Core Performance © 2013 IBM Corporation IBM Power Systems Один процессор – от блейдов до High End серверов Power 795 Power 780+ Virtualization & Mgmt. Power Midrange 770+ Power Express 760+ Power Enterprise 750+ Power 720/740+ Power 710/730+ High Performance Computing IBM PureFlex Power Только p700 PowerLinux System 775 7R1 / 7R2+ p460 P460+ Blades Power P270+ 755 p260 7R4+ P260+ p24L 11 © 2013 IBM Corporation IBM Power Systems Power Systems Software AIXIX IBM i Linux Red Hat or SUSE PowerVM PowerHA Systems Director PowerVP PowerSC PowerVC © 2013 IBM Corporation IBM Power Systems Высокая доступность - ключевое требование Решения IBM Power обеспечивают доступность 99.997+% • Almost five 9’s availability, the gold standard • 67% of corporations now require a minimum of 99.99% uptime or better for mission critical hardware, operating systems and main line of business (LOB) applications • AIX on Power consistently has the least amount of downtime in ITIC studies for several years Source: ITIC 2013 Global Server Hardware, Server OS Reliability Survey, ITIC, • Industry leading availability for all (All rights reserved); January 2013. workloads, including SAP 13 © 2013 IBM Corporation IBM Power Systems IBM Power - виртуализация и доступность для различных платформ PowerVM обеспечивает 98% доступности • PowerVM versus competitive virtualization study with over 61,000 clients analyzed • PowerVM virtualization contributes to both stability and reliability of an organization’s implementation • Virtualized x86 system availability decreases as an organization’s size increases • Key factors – Reliability and availability that meet today’s business requirements – PowerVM on Power demonstrates superior reliability and availability over all other Source: Does Your Virtualization Platform Matter? Getting the Most Out of Your IT virtualization platforms Platforms with Virtualization; Solitaire Interglobal Ltd (All rights reserved); April 2012. – Detailed claims and discussion 14 © 2013 IBM Corporation IBM Power Systems Сравнение производительности x86 и IBM POWER7+ x86 Power 7+ P7+ vs x86 Core Performance P780+ Ratio 2-socket 8 Socket P7+ Util: 100% P7+ Util: 70% P7+ Util: 80% E5-2690 Power 7+ x86 Util: 100% x86 Util: 50% x86 Util: 20% # Cores 16 64 B’mark IBM Consv. Typical Cust. Utilization Utilization Utilization ERP SAP 2-Tier 7960 10000 (16c) 1.26 1.76 5.03 SPECjbb (k JOPS) 1580 6884 1.09 1.52 4.36 SPECint_rate 693 3730 1.35 1.88 5.38 SPECfp_rate 510 2880 1.41 1.98 5.65 SPECjEnterprise2010 8310 13161 (16c) 1.58 2.21 6.32 15 © 2013 IBM Corporation IBM Power Systems PowerVM обеспечивает большее количество виртуальных нагрузок Source: Does Your Virtualization Platform Matter? Getting the Most Out of Your IT Platforms with Virtualization; Solitaire Interglobal Ltd (All rights reserved); April 2012. 16 © 2013 IBM Corporation IBM Power Systems Безопасность © 2013 IBM Corporation IBM Power Systems Безопасность ограничена «слабым звеном» 18 © 2013 IBM Corporation IBM Power Systems Безопасность системы виртуализации критична для баз данных 0 зафиксированных взломов PowerVM hypervisor • The PowerVM hypervisor has never had a reported security vulnerability and provides the bullet-proof security that customers demand for mission-critical workloads • The VIOS, which is part of the overall virtualization has had 0 reported security vulnerabilities • Dare to compare – search any security tracking DB and compare Power against x86 19 © 2013 IBM Corporation IBM Power Systems Сравнение решений на разных платформах Production Return to Config Questions In this example we see our 2 socket Power POWER System Competitive System System against their 2 socket Intel system. At Benchmark ERP DB Licensing OracleEE OracleEE first glance it appears that Power is at a slight Fraction of DB Cores 100% 100% (-9%) disadvantage in terms of HW TCA. Virtualization PowerVM None Clustering None Veritas However, that delta quickly goes away when Oracle RAC None RAC Oracle DB software licenses, even with their DB SW Discount 70% 70% Based on DB Licensing - overwritable lower per core multiplier for x86, is calculated Architecture Power Intel/x86 System Power740+/8/3.612 HP DL380/2900 into the TCA. In addition, because this is # Systems 3 10 Frequency (MHz) 3612 2900 modeled for an ERP/Oracle workload, Mem Option Mem per System VMware would not be in play for the GB per System 256 256 HW Discount 0% 22% Power system includes discounted HW, SW (OS/PVM), Maint. Production environment. Therefore their Sustained Utilization 65% 40% ability to keep sustained utilization levels System Cores 48 160 233% above 40% is unlikely, while we can keep it Database License Cores 48 160 well above 65% sustained using PowerVM. Memory 768 2560 Performance 22519 25920 We have VCS and Oracle RAC included in the HW TCA $ 166,008 $ 151,120 -9% x86 environment for planned downtime, while SW TCA $ 684,000 $ 1,692,000 147% PVM uses LPM to ensure availability during TOTAL TCA $ 850,008 $ 1,843,120 117% planned maintenance related downtime SW TCO $ 984,960 $ 2,616,480 166% TOTAL 3-yr TCO $ 1,861,968 $ 4,497,100 142% 3-Year Savings $ 2,635,132 © 2013 IBM Corporation IBM Power Systems IBM POWER технологические ценности • Технологии – Ясные планы развития – Лидерство в процессорных технологиях POWER8 Встроенные «Green Technology» POWER7 22 nm – POWER6 45 nm 65 nm – Общая архитектура от «блейдов» до «High-end» POWER5 130 nm • Производительность POWER4 180 nm – Масштабируемость – Лидер по производительности при различных нагрузках – Лучшая производительность на ядро – Высокая пропускная способность памяти и системы ввода-вывода • Виртуализация – Консолидация на высоком уровне – Виртуализация процессоров, памяти и I/O – Динамическое перемещения «партиций» и приложения – Снижение стоимости инфраструктуры • RAS(надежность,доступность, обслуживание) Virt I/O Server – Power Systems используют RSS технологии «mainframe» Shared I/O – «Горячие» установка/ обслуживание Hypervisor – Alternate Processor Recovery Single SMP Hardware System – Operating Systems Availability Leadership 21 © 2013 IBM Corporation IBM Power Systems Thanks! Спасибо! Вопросы? [email protected] (495)-775-8800 ext 2904 © 2013 IBM Corporation .
Load more

Recommended publications
  • RAD750 at Our Website: Click HERE RAD750• Board
    Full-service, independent repair center -~ ARTISAN® with experienced engineers and technicians on staff. TECHNOLOGY GROUP ~I We buy your excess, underutilized, and idle equipment along with credit for buybacks and trade-ins. Custom engineering Your definitive source so your equipment works exactly as you specify. for quality pre-owned • Critical and expedited services • Leasing / Rentals/ Demos equipment. • In stock/ Ready-to-ship • !TAR-certified secure asset solutions Expert team I Trust guarantee I 100% satisfaction Artisan Technology Group (217) 352-9330 | [email protected] | artisantg.com All trademarks, brand names, and brands appearing herein are the property o f their respective owners. Find the BAE Systems RAD750 at our website: Click HERE RAD750 Board Hardware Specification Document Number 234A524 Release Date August 1, 2000 Copyright by BAE SYSTEMS All Rights Reserved Document Number: 234A524 RAD750 CompactPCI Hardware Specification Notices Before using this information and the product it supports, be sure to read the general information on the back cover of this book. Trademarks The following are trademarks of International Business Machines Corporation in the United States, or other countries, or both: IBM IBM Logo PowerPC PowerPC 750 The following are trademarks of BAE SYSTEMS in the United States, or other countries, or both: RAD750 The following are registered trademarks of PCI Industrial Computer Manufacturing Group in the United States, or other countries, or both: PICMG CompactPCI Other company, product, and service names may be trademarks or service marks of others. Preliminary Edition (Version 4.0, 8/1/2000) This unpublished document is the preliminary edition of RAD750 3U CompactPCI board Hardware Specification.
    [Show full text]
  • Microkernel Mechanisms for Improving the Trustworthiness of Commodity Hardware
    Microkernel Mechanisms for Improving the Trustworthiness of Commodity Hardware Yanyan Shen Submitted in fulfilment of the requirements for the degree of Doctor of Philosophy School of Computer Science and Engineering Faculty of Engineering March 2019 Thesis/Dissertation Sheet Surname/Family Name : Shen Given Name/s : Yanyan Abbreviation for degree as give in the University calendar : PhD Faculty : Faculty of Engineering School : School of Computer Science and Engineering Microkernel Mechanisms for Improving the Trustworthiness of Commodity Thesis Title : Hardware Abstract 350 words maximum: (PLEASE TYPE) The thesis presents microkernel-based software-implemented mechanisms for improving the trustworthiness of computer systems based on commercial off-the-shelf (COTS) hardware that can malfunction when the hardware is impacted by transient hardware faults. The hardware anomalies, if undetected, can cause data corruptions, system crashes, and security vulnerabilities, significantly undermining system dependability. Specifically, we adopt the single event upset (SEU) fault model and address transient CPU or memory faults. We take advantage of the functional correctness and isolation guarantee provided by the formally verified seL4 microkernel and hardware redundancy provided by multicore processors, design the redundant co-execution (RCoE) architecture that replicates a whole software system (including the microkernel) onto different CPU cores, and implement two variants, loosely-coupled redundant co-execution (LC-RCoE) and closely-coupled redundant co-execution (CC-RCoE), for the ARM and x86 architectures. RCoE treats each replica of the software system as a state machine and ensures that the replicas start from the same initial state, observe consistent inputs, perform equivalent state transitions, and thus produce consistent outputs during error-free executions.
    [Show full text]
  • IBM Systems Group
    IBM STG Deep Computing IBM Systems Group Deep Computing with IBM Systems Barry Bolding, Ph.D. IBM Deep Computing SciComp 2005 Confidential | Systems Group 2004 © 2004 IBM Corporation IBM Systems and Technology Group Deep Computing Components High Performance Computing Leadership Research and Innovation Systems Expertise – pSeries – xSeries – Storage – Networking Innovative Systems © 2004 IBM Corporation IBM Systems and Technology Group Deep Computing Focus Government Research Labs – Energy and Defense Weather/Environmental – Weather Forecasting Centers – Climate Modeling Higher Education/Research Universities Life Sciences – Pharma, BioTech, Chemical Aero/Auto Petroleum Business Intelligence, Digital Media, Financial Services, On Demand HPC © 2004 IBM Corporation IBM STG Deep Computing Deep Computing Teams and Organization Confidential | Systems Group 2004 © 2004 IBM Corporation IBM Systems and Technology Group Deep Computing Technical Team Kent Winchell Technical Team Deep Computing Barry Bolding Jeff Zais Technical Manager Technical Manager Public Sector Industrial Sector Farid Parpia John Bauer Martin Feyereisen Doug Petesch HPC Applications HPC Storage Auto/Aero Auto/Aero Life Sciences Government, HPC Business Intelligence “Suga” Sugavanam Wei Chen Charles Grassl Guangye Li EDA Government HPC Applications Auto/Aero Asia Pacific HPC HIgher Ed. BlueGene/L Stephen Behling Ray Paden Si MacAlester Harry Young Higher Ed GPFS CFD HPC Storage Digitial Media Digital Media Joseph Skovira James Abeles Scott Denham Janet Shiu Schedulers
    [Show full text]
  • Computer Architectures an Overview
    Computer Architectures An Overview PDF generated using the open source mwlib toolkit. See http://code.pediapress.com/ for more information. PDF generated at: Sat, 25 Feb 2012 22:35:32 UTC Contents Articles Microarchitecture 1 x86 7 PowerPC 23 IBM POWER 33 MIPS architecture 39 SPARC 57 ARM architecture 65 DEC Alpha 80 AlphaStation 92 AlphaServer 95 Very long instruction word 103 Instruction-level parallelism 107 Explicitly parallel instruction computing 108 References Article Sources and Contributors 111 Image Sources, Licenses and Contributors 113 Article Licenses License 114 Microarchitecture 1 Microarchitecture In computer engineering, microarchitecture (sometimes abbreviated to µarch or uarch), also called computer organization, is the way a given instruction set architecture (ISA) is implemented on a processor. A given ISA may be implemented with different microarchitectures.[1] Implementations might vary due to different goals of a given design or due to shifts in technology.[2] Computer architecture is the combination of microarchitecture and instruction set design. Relation to instruction set architecture The ISA is roughly the same as the programming model of a processor as seen by an assembly language programmer or compiler writer. The ISA includes the execution model, processor registers, address and data formats among other things. The Intel Core microarchitecture microarchitecture includes the constituent parts of the processor and how these interconnect and interoperate to implement the ISA. The microarchitecture of a machine is usually represented as (more or less detailed) diagrams that describe the interconnections of the various microarchitectural elements of the machine, which may be everything from single gates and registers, to complete arithmetic logic units (ALU)s and even larger elements.
    [Show full text]
  • An Evaluation of Soft Processors As a Reliable Computing Platform
    Brigham Young University BYU ScholarsArchive Theses and Dissertations 2015-07-01 An Evaluation of Soft Processors as a Reliable Computing Platform Michael Robert Gardiner Brigham Young University - Provo Follow this and additional works at: https://scholarsarchive.byu.edu/etd Part of the Electrical and Computer Engineering Commons BYU ScholarsArchive Citation Gardiner, Michael Robert, "An Evaluation of Soft Processors as a Reliable Computing Platform" (2015). Theses and Dissertations. 5509. https://scholarsarchive.byu.edu/etd/5509 This Thesis is brought to you for free and open access by BYU ScholarsArchive. It has been accepted for inclusion in Theses and Dissertations by an authorized administrator of BYU ScholarsArchive. For more information, please contact [email protected], [email protected]. An Evaluation of Soft Processors as a Reliable Computing Platform Michael Robert Gardiner A thesis submitted to the faculty of Brigham Young University in partial fulfillment of the requirements for the degree of Master of Science Michael J. Wirthlin, Chair Brad L. Hutchings Brent E. Nelson Department of Electrical and Computer Engineering Brigham Young University July 2015 Copyright © 2015 Michael Robert Gardiner All Rights Reserved ABSTRACT An Evaluation of Soft Processors as a Reliable Computing Platform Michael Robert Gardiner Department of Electrical and Computer Engineering, BYU Master of Science This study evaluates the benefits and limitations of soft processors operating in a radiation-hardened FPGA, focusing primarily on the performance and reliability of these systems. FPGAs designs for four popular soft processors, the MicroBlaze, LEON3, Cortex- M0 DesignStart, and OpenRISC 1200 are developed for a Virtex-5 FPGA. The performance of these soft processor designs is then compared on ten widely-used benchmark programs.
    [Show full text]
  • MICROPROCESSOR EVALUATIONS for SAFETY-CRITICAL, REAL-TIME February 2009 APPLICATIONS: AUTHORITY for EXPENDITURE NO
    DOT/FAA/AR-08/55 Microprocessor Evaluations for Air Traffic Organization Operations Planning Safety-Critical, Real-Time Office of Aviation Research and Development Applications: Authority for Washington, DC 20591 Expenditure No. 43 Phase 3 Report February 2009 Final Report This document is available to the U.S. public through the National Technical Information Services (NTIS), Springfield, Virginia 22161. U.S. Department of Transportation Federal Aviation Administration NOTICE This document is disseminated under the sponsorship of the U.S. Department of Transportation in the interest of information exchange. The United States Government assumes no liability for the contents or use thereof. The United States Government does not endorse products or manufacturers. Trade or manufacturer's names appear herein solely because they are considered essential to the objective of this report. This document does not constitute FAA certification policy. Consult your local FAA aircraft certification office as to its use. This report is available at the Federal Aviation Administration William J. Hughes Technical Center’s Full-Text Technical Reports page: actlibrary.act.faa.gov in Adobe Acrobat portable document format (PDF). Technical Report Documentation Page 1. Report No. 2. Government Accession No. 3. Recipient's Catalog No. DOT/FAA/AR-08/55 4. Title and Subtitle 5. Report Date MICROPROCESSOR EVALUATIONS FOR SAFETY-CRITICAL, REAL-TIME February 2009 APPLICATIONS: AUTHORITY FOR EXPENDITURE NO. 43 PHASE 3 REPORT 6. Performing Organization Code 7. Author(s) 8. Performing Organization Report No. TAMU-CS-AVSI-72005 Rabi N. Mahapatra, Praveen Bhojwani, Jason Lee, and Yoonjin Kim 9. Performing Organization Name and Address 10. Work Unit No.
    [Show full text]
  • Présentation Powerpoint
    ADCSS – 2010 AGASSE section Beyond the Aurora Architecture for the new challenging applications. The Enhanced Avionics Architecture for the Exploration Missions. A. Tramutola – A. Martelli BSOOS Turin Corporate Communications 1 3 Nov.2010 ESTEC All rights reserved © 2010, Thales Alenia Space Presentation contents Aurora Avionic Architecture as starting point EXOMARS : Aurora implementation Major requirements for exploration mission EDL, RVD and ROVER functional architecure Common elements : communication bus and CPU CDMU : processor – coprocessor configuration Avionic Test Bench to support avionic design Conclusion Corporate Communications 2 3 Nov.2010 ESTEC All rights reserved © 2010, Thales Alenia Space Aurora Avionic Architecture as starting point RF to Ground TCS GNC EPS Command, Control and Data Handling RF short range Mission modules Corporate Communications 3 3 Nov.2010 ESTEC All rights reserved © 2010, Thales Alenia Space Aurora Avionic Architecture as starting point Main functions implemented in the Aurora Architecture are : • TM/TC Management, Storage Management and On-Board Time (OBT) Management needed for interface with ground or with other spacecraft • Thermal Management, Electrical Power Supply (EPS) Management for spacecraft TCS and EPS subsystem control • Spacecraft Modes Management (SCMG), AMM/ FDIR Management, Equipment Management which are the principal Data Handling function. They handle the on-board system through the different mission phases, define the level of autonomy, execute the mission timeline, the detection
    [Show full text]
  • Lessons from 30 Years of Flight Software
    Lessons from 30 Years of Flight Software David McComas NASA Goddard Space Flight Center Software Engineering Division Flight Software Systems Branch 1 9/22/15 Finding the Best Practices in R&D Software What is R&D? - R&D is developing new solutions for a specific problem domain Flight software at Goddard has two relationships with R&D - Part of the spacecraft and instruments that serve as tools for scientists to perform their R&D - Advance the state of technology in components with embedded processors and in the software technology itself This presentation looks back on 30 years of flight software development at the Goddard Space Flight Center observing trends and capturing lessons learned 2 My 30 Year Perspective 1.5 Years Line Management 29 Years Flight Projects 3 NASA Perspective Answering the “Big” questions EARTH - How is the global earth system changing? - How will the Earth system change in the future? HELIOPHYSICS - What causes the sun to vary? - How do the Earth and Heliosphere respond? - What are the impacts on humanity? PLANETS - How did the sun's family of planets and minor bodies originate? - How did the solar system evolve to its current diverse state? - How did life begin and evolve on Earth, and has it evolved elsewhere in the Solar System? - What are the characteristics of the Solar System that lead to the origins of life? ASTROPHYSICS - How does the Universe Work? - How did we get here? - Are we alone? To help answer these questions NASA builds spacecraft, vehicles and instruments with lots of software on board 4 Goddard Perspective NASA's Goddard Space Flight Center in Greenbelt, Maryland, is home to the nation's largest organization of scientists, engineers and technologists who build spacecraft, instruments and new technology to study Earth, the sun, our solar system and the universe.
    [Show full text]
  • Convex Optimization for Trajectory Generation Arxiv:2106.09125V1 [Math.OC] 16 Jun 2021
    Preprint Convex Optimization for Trajectory Generation A Tutorial On Generating Dynamically Feasible Trajectories Reliably And Efficiently Danylo Malyuta a,? , Taylor P. Reynolds a, Michael Szmuk a, Thomas Lew b, Riccardo Bonalli b, Marco Pavone b, and Behc¸et Ac¸ıkmes¸e a a William E. Boeing Department of Aeronautics and Astronautics, University of Washington, Seattle, WA 98195, USA b Department of Aeronautics and Astronautics, Stanford University, Stanford, CA 94305, USA Reliable and efficient trajectory generation methods are a fundamental need for autonomous dynamical systems of tomorrow. The goal of this article is to provide a comprehensive tutorial of three major con- vex optimization-based trajectory generation methods: lossless convexification (LCvx), and two sequential convex programming algorithms known as SCvx and GuSTO. In this article, trajectory generation is the computation of a dynamically feasible state and control signal that satisfies a set of constraints while opti- mizing key mission objectives. The trajectory generation problem is almost always nonconvex, which typ- ically means that it is not readily amenable to efficient and reliable solution onboard an autonomous ve- hicle. The three algorithms that we discuss use problem reformulation and a systematic algorithmic strat- egy to nonetheless solve nonconvex trajectory generation tasks through the use of a convex optimizer. The theoretical guarantees and computational speed offered by convex optimization have made the algo- rithms popular in both research and industry circles. To date, the list of applications include rocket land- ing, spacecraft hypersonic reentry, spacecraft rendezvous and docking, aerial motion planning for fixed- wing and quadrotor vehicles, robot motion planning, and more. Among these applications are high-profile rocket flights conducted by organizations like NASA, Masten Space Systems, SpaceX, and Blue Origin.
    [Show full text]
  • 2010 IEEE Radiation Effects Data Workshop
    2010 IEEE Radiation Effects Data Workshop Proceedings Denver, Colorado 19-23 July 2010 IEEE Catalog Number: CFP10422-PRT ISBN: 978-1-4244-8402-7 2010 IEEE Radiation Effects Data Workshop Copyright © 2010 by the Institute of Electrical and Electronic Engineers, Inc. All rights reserved. Copyright and Reprint Permissions Abstracting is permitted with credit to the source. Libraries are permitted to photocopy beyond the limit of U.S. copyright law for private use of patrons those articles in this volume that carry a code at the bottom of the first page, provided the per-copy fee indicated in the code is paid through Copyright Clearance Center, 222 Rosewood Drive, Danvers, MA 01923. For other copying, reprint or republication permission, write to IEEE Copyrights Manager, IEEE Service Center, 445 Hoes Lane, Piscataway, NJ 08854. All rights reserved. IEEE Catalog Number: CFP10422-ART ISBN 13: 978-1-4244-8404-1 Printed copies of this publication are available from: Curran Associates, Inc 57 Morehouse Lane Red Hook, NY 12571 USA Phone: (845) 758-0400 Fax: (845) 758-2633 E-mail: [email protected] Produced by IEEE eXpress Conference Publishing For information on producing a conference proceedings and receiving an estimate, contact [email protected] http://www.ieee.org/conferencepublishing The Radiation Effects Data Workshop (REDW) is a session of the Nuclear and Space Radiation Effect Conference (NSREC) Technical Program. The workshop is held as a poster session that is documented by this Workshop Record Publication, which serves as a permanent archive of the REDW. Posters were presented during the 2010 NSREC held at the Sheraton Denver Downtown Hotel, Denver, Colorado, on July 21.
    [Show full text]
  • A Framework to Analyze Processor Architectures for Next-Generation On-Board Space Computing
    A Framework to Analyze Processor Architectures for Next-Generation On-Board Space Computing Tyler M. Lovelly, Donavon Bryan, Kevin Cheng, Rachel Kreynin, Alan D. George, Ann Gordon-Ross NSF Center for High-Performance Reconfigurable Computing (CHREC) Department of Electrical and Computer Engineering, University of Florida, Gainesville, FL, USA flovelly,donavon,cheng,kreynin,george,[email protected] Gabriel Mounce Air Force Research Laboratory (AFRL), Space Vehicles Directorate Kirtland Air Force Base, Albuquerque, NM, USA [email protected] Abstract— Due to harsh and inaccessible operating environ- lengthy, complex, and costly process, and since space mission ments, space computing presents many unique challenges with design typically requires lengthy development cycles, there respect to stringent power, reliability, and programmability con- is a large technological gap between commercial and space straints that limit on-board processing performance and mission processors that results in limited and outdated processor capabilities. However, the increasing need for real-time sensor selections for space missions. and autonomous processing, coupled with limited communica- tion bandwidth with ground stations, are increasing the demand for high-performance, on-board computing for next-generation While current space processors increasingly lag behind the space missions. Since currently available radiation-hardened capabilities of emerging commercial processors, computing space processors cannot satisfy this growing demand, research requirements for space missions are becoming more de- into various processor architectures is required to ensure that manding. Furthermore, improving sensor technology and potential new space processors are based on architectures that increasing mission data rates, problem sizes, and data types will best meet the computing needs of space missions.
    [Show full text]
  • Comparative Analysis of Space-Grade Processors
    COMPARATIVE ANALYSIS OF SPACE-GRADE PROCESSORS By TYLER MICHAEL LOVELLY A DISSERTATION PRESENTED TO THE GRADUATE SCHOOL OF THE UNIVERSITY OF FLORIDA IN PARTIAL FULFILLMENT OF THE REQUIREMENTS FOR THE DEGREE OF DOCTOR OF PHILOSOPHY UNIVERSITY OF FLORIDA 2017 © 2017 Tyler Michael Lovelly To my country ACKNOWLEDGMENTS This work was supported in part by the Industry/University Cooperative Research Center Program of the National Science Foundation under grant nos. IIP-1161022 and CNS-1738783, by the industry and government members of the NSF Center for High- Performance Reconfigurable Computing and the NSF Center for Space, High- Performance, and Resilient Computing, by the University of Southern California Information Sciences Institute for remote access to their systems, and by Xilinx and Microsemi for provided hardware and software. 4 TABLE OF CONTENTS page ACKNOWLEDGMENTS .................................................................................................. 4 LIST OF TABLES ............................................................................................................ 7 LIST OF FIGURES .......................................................................................................... 8 ABSTRACT ..................................................................................................................... 9 CHAPTER 1 INTRODUCTION .................................................................................................... 11 2 BACKGROUND AND RELATED RESEARCH ......................................................
    [Show full text]