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Owner's Manual
Dell Latitude 3330 Owner's Manual Regulatory Model: P18S Regulatory Type: P18S002 Notes, Cautions, and Warnings NOTE: A NOTE indicates important information that helps you make better use of your computer. CAUTION: A CAUTION indicates either potential damage to hardware or loss of data and tells you how to avoid the problem. WARNING: A WARNING indicates a potential for property damage, personal injury, or death. © 2013 Dell Inc. Trademarks used in this text: Dell™, the Dell logo, Dell Boomi™, Dell Precision™ , OptiPlex™, Latitude™, PowerEdge™, PowerVault™, PowerConnect™, OpenManage™, EqualLogic™, Compellent™, KACE™, FlexAddress™, Force10™ and Vostro™ are trademarks of Dell Inc. Intel®, Pentium®, Xeon®, Core® and Celeron® are registered trademarks of Intel Corporation in the U.S. and other countries. AMD® is a registered trademark and AMD Opteron™, AMD Phenom™ and AMD Sempron™ are trademarks of Advanced Micro Devices, Inc. Microsoft®, Windows®, Windows Server®, Internet Explorer®, MS-DOS®, Windows Vista® and Active Directory® are either trademarks or registered trademarks of Microsoft Corporation in the United States and/or other countries. Red Hat® and Red Hat® Enterprise Linux® are registered trademarks of Red Hat, Inc. in the United States and/or other countries. Novell® and SUSE® are registered trademarks of Novell Inc. in the United States and other countries. Oracle® is a registered trademark of Oracle Corporation and/or its affiliates. Citrix®, Xen®, XenServer® and XenMotion® are either registered trademarks or trademarks of Citrix Systems, Inc. in the United States and/or other countries. VMware®, Virtual SMP®, vMotion®, vCenter® and vSphere® are registered trademarks or trademarks of VMware, Inc. in the United States or other countries. -
Passmark Intel Vs AMD CPU Benchmarks - High End
PassMark Intel vs AMD CPU Benchmarks - High End http://www.cpubenchmark.net/high_end_cpus.html Shopping cart | Search Home Software Hardware Benchmarks Services Store Support Forums About Us Home » CPU Benchmarks » High End CPU's CPU Benchmarks Video Card Benchmarks Hard Drive Benchmarks RAM PC Systems Android iOS / iPhone CPU Benchmarks Over 600,000 CPUs Benchmarked High End CPU's - Intel vs AMD How does your CPU compare? This chart comparing high end CPU's is made using thousands of PerformanceTest benchmark Add your CPU to our benchmark results and is updated daily. These are the high end AMD and Intel CPUs are typically those chart with PerformanceTest V8 found in newer computers. The chart below compares the performance of Intel Xeon CPUs, Intel Core i7 CPUs, AMD Phenom II CPUs and AMD Opterons with multiple cores. Intel processors vs ---- Select A Page ---- AMD chips - find out which CPU's performance is best for your new gaming rig or server! CPU Mark | Price Performance (Click to select desired chart) PassMark - CPU Mark High End CPUs - Updated 26th of August 2013 Price (USD) Intel Xeon E5-2687W @ 3.10GHz 14,564 $1,929.99 Intel Xeon E5-2690 @ 2.90GHz 14,511 $1,920.99 Intel Xeon E5-2680 @ 2.70GHz 13,949 $1,725.99 Intel Xeon E5-2689 @ 2.60GHz 13,444 NA Intel Xeon E5-2670 @ 2.60GHz 13,312 $1,509.00 Intel Core i7-3970X @ 3.50GHz 12,873 $1,006.99 Intel Core i7-3960X @ 3.30GHz 12,749 $965.99 Intel Xeon E5-1660 @ 3.30GHz 12,457 $1,086.99 Intel Xeon E5-2665 @ 2.40GHz 12,453 $1,499.99 Intel Core i7-3930K @ 3.20GHz 12,086 $567.27 Intel Xeon -
Components © 2017
PCDS.fi Components Mini-ITX SFF Gaming & HTPC Chassis 1/11 2017 AKASA Mini-ITX Compact Thin Cypher Black ALU 1x2.5” VESA 120W Power Adapter 99€ S ILVERSTONE Mini-ITX SFF Slim HTPC Milo ML0 5 Black Slot Loading 1x5.25” 4x2.5” Audio USB 69€ Milo ML0 6 ALU Black Slot Loading 1x5.25” 4x2.5” Audio USB 82€ NEW Milo ML0 9 Black Slim 1x5.25” 4x2.5” Audio USB 82€ NEW Milo ML0 6-E ALU Black Slot Loading 1x5.25” 4x2.5” Audio USB 115€ FRACTAL DESIGN Mini-ITX SFF Slim Gaming & VR NEW Node 202 Black 2x2.5” CC56mm Audio USB Filter 109€ NEW Node 20 2 Integra Black 2x2.5” CC56mm Audio USB Filter Integra 450 PSU 165€ PHANTEKS Mini-ITX SFF Tower NEW ENTHOO EVOLV SHIFT Black 2x3.5” 1x2.5” Audio USB 200mm Fan 135€ S ILVERSTONE Mini-ITX SFF Slim Gaming & VR Milo ML0 7 Black Slot Loading 1x5.25” 1x3.5” 3x2.5” Audio USB 82€ NEW Milo ML0 8 Black Slim 1x5.25” 1x3.5” 2x2.5” CC58mm Audio USB Filter 115€ R AVEN RVZ01 Black Slot Loading 1x5.25” 1x3.5” 3x2.5” Audio USB 2x120mm Fans 129€ NEW R AVEN RVZ01- E Black 3x2.5” CC83mm Audio USB 2x120mm Fans 129€ NEW RAVEN RVZ03 Black 4x2.5” CC83mm Audio USB 2x120mm Fans 135€ NEW R AVEN RVZ0 2 Black Slim 1x5.25” 1x3.5” 2x2.5” Audio USB 115€ NEW R AVEN RVZ0 2 Window Black Slim 1x5.25” 1x3.5” 2x2.5” Audio USB Filter 125€ NEW Fortress FTZ 01 Black / Silver Slot Loading 1x5.25” 1x3.5” 3x2.5” Audio USB 3x120mm Fans 155€ Mini-ITX SFF Cube Chassis 1/11 2017 COOLER MASTER Mini-ITX SFF Cube Elite 1 3 0 Black 1x5.25” 2x3.5” 3x2.5” Audio USB 80+120mm Fans 69€ Elite 1 2 0 Black 1x5.25” 3x3.5”/2.5” Audio USB 80+120mm Fans 71€ Elite 110 Black -
Evaluation of AMD EPYC
Evaluation of AMD EPYC Chris Hollowell <[email protected]> HEPiX Fall 2018, PIC Spain What is EPYC? EPYC is a new line of x86_64 server CPUs from AMD based on their Zen microarchitecture Same microarchitecture used in their Ryzen desktop processors Released June 2017 First new high performance series of server CPUs offered by AMD since 2012 Last were Piledriver-based Opterons Steamroller Opteron products cancelled AMD had focused on low power server CPUs instead x86_64 Jaguar APUs ARM-based Opteron A CPUs Many vendors are now offering EPYC-based servers, including Dell, HP and Supermicro 2 How Does EPYC Differ From Skylake-SP? Intel’s Skylake-SP Xeon x86_64 server CPU line also released in 2017 Both Skylake-SP and EPYC CPU dies manufactured using 14 nm process Skylake-SP introduced AVX512 vector instruction support in Xeon AVX512 not available in EPYC HS06 official GCC compilation options exclude autovectorization Stock SL6/7 GCC doesn’t support AVX512 Support added in GCC 4.9+ Not heavily used (yet) in HEP/NP offline computing Both have models supporting 2666 MHz DDR4 memory Skylake-SP 6 memory channels per processor 3 TB (2-socket system, extended memory models) EPYC 8 memory channels per processor 4 TB (2-socket system) 3 How Does EPYC Differ From Skylake (Cont)? Some Skylake-SP processors include built in Omnipath networking, or FPGA coprocessors Not available in EPYC Both Skylake-SP and EPYC have SMT (HT) support 2 logical cores per physical core (absent in some Xeon Bronze models) Maximum core count (per socket) Skylake-SP – 28 physical / 56 logical (Xeon Platinum 8180M) EPYC – 32 physical / 64 logical (EPYC 7601) Maximum socket count Skylake-SP – 8 (Xeon Platinum) EPYC – 2 Processor Inteconnect Skylake-SP – UltraPath Interconnect (UPI) EYPC – Infinity Fabric (IF) PCIe lanes (2-socket system) Skylake-SP – 96 EPYC – 128 (some used by SoC functionality) Same number available in single socket configuration 4 EPYC: MCM/SoC Design EPYC utilizes an SoC design Many functions normally found in motherboard chipset on the CPU SATA controllers USB controllers etc. -
Multiprocessing Contents
Multiprocessing Contents 1 Multiprocessing 1 1.1 Pre-history .............................................. 1 1.2 Key topics ............................................... 1 1.2.1 Processor symmetry ...................................... 1 1.2.2 Instruction and data streams ................................. 1 1.2.3 Processor coupling ...................................... 2 1.2.4 Multiprocessor Communication Architecture ......................... 2 1.3 Flynn’s taxonomy ........................................... 2 1.3.1 SISD multiprocessing ..................................... 2 1.3.2 SIMD multiprocessing .................................... 2 1.3.3 MISD multiprocessing .................................... 3 1.3.4 MIMD multiprocessing .................................... 3 1.4 See also ................................................ 3 1.5 References ............................................... 3 2 Computer multitasking 5 2.1 Multiprogramming .......................................... 5 2.2 Cooperative multitasking ....................................... 6 2.3 Preemptive multitasking ....................................... 6 2.4 Real time ............................................... 7 2.5 Multithreading ............................................ 7 2.6 Memory protection .......................................... 7 2.7 Memory swapping .......................................... 7 2.8 Programming ............................................. 7 2.9 See also ................................................ 8 2.10 References ............................................. -
The Wysiwyg and Vivien Hardware Guide
The wysiwyg and Vivien Hardware Guide [Updated June 5, 2019] This guide describes the principles of selecting hardware components for a wysiwyg or Vivien workstation, and it is meant to be a guideline for choosing the right hardware for your intended use of the software. As such, actual hardware models are not specified for most components, but based on the information provided below, you will be able to decide on these yourself. Once you have, if you wish to confirm the components you selected, our Technical Support Department will be happy to look over your list; please see the end of this article for information on how to get in touch with us. Before discussing the various components and the criteria for selecting them, there are four important things to note. It strongly recommended that you read all this information and follow the advice before considering the purchase of new hardware. 1. Geometry must always be properly optimized, in all files, regardless of their complexity. Even the best/fastest/most expensive hardware will not be able to properly- handle a file that is not optimized and therefore contains inefficient geometry. If you haven’t done so already, please read through this thread on our Forum, in order to learn how to optimize your files. The key to understanding the optimization principles described here lies with the articles mentioned in the first paragraph of the first message, “Part 1” and “Part 2”; please ensure that you also click those links and read the information they reveal. 2. Even in an optimized file performance can be poor if your video card driver is out-of-date and/or your video card’s settings and/or Shaded View options are inappropriate. -
I Processori Amd Trinity
UNIVERSITA’ DEGLI STUDI DI PADOVA __________________________________________________ Facoltà di Ingegneria Corso di laurea in Ingegneria Informatica I PROCESSORI AMD TRINITY Laureando Relatore Luca Marzaro Prof. Sergio Congiu ___________________________________________________________ ANNO ACCADEMICO 2012/2013 ii iii A Giulia, mamma, papà e Diego iv Indice 1. Introduzione 1 1.1 Cenni storici AMD . 1 1.2 Evoluzione del processore: dall' Am386 alle APU Trinity . 2 2. Trinity: Architettura 5 2.1 Introduzione . 5 2.2 Da Llano a Trinity: architettura Piledriver . 6 2.3 Graphics Memory Controller: architettura VLIW4 . 8 2.4 Un nuovo socket: FM2 . 12 3. Specifiche tecniche 15 3.1 Modelli e dati tecnici . 15 3.2 Comparazione con Llano e Intel core i3 . 17 4. Prestazioni 19 4.1 Introduzione . 19 4.2 Applicazioni multimediali . 22 4.3 Calcolo e compressione . 25 4.4 Consumi . 30 5. Considerazioni finali 35 vi INDICE Bibliografia 37 Capitolo 1 Introduzione 1.1 Cenni storici AMD AMD (Advanced Micro Devices) è una multinazionale americana produttrice di semiconduttori la cui sede si trova a Sunnyvale in California. La peculiarità di tale azienda è la produzione di microprocessori, workstation e server, di chip grafici e di chipset. Si classifica seconda al mondo Figura 1.1: Jerry Sanders nella produzione di microprocessori con architettuta x86 dopo Intel. Il primo maggio 1969 Jerry Sanders (vedi Figura 1.1) e sette amici fondano la AMD. Sei anni più tardi, lanciano nel mercato la prima memoria RAM marchiata AMD, la Am9102 e presentano AMD 8080, una variante dell'INTEL 8080 che lancia l'azienda nel mondo dei microprocessori. Dal 1980 AMD si impone come uno dei principali concorrenti di Intel nel mercato dei processori x86- compatibili. -
Solaris 10 OS on AMD Opteron Processor-Based Systems
Solaris™ 10 OS on AMD Opteron™ Processor-based Systems < A powerful combination for your business Sun and AMD take x64 computing to a new level with the breakthrough performance of AMD Opteron™ processor-based systems combined with the Solaris™ 10 OS — the most advanced operating system on the planet. By combining the best of free and open source software with the most powerful industry-standard platforms, customers can take advantage of the most robust and secure, yet economical Web, database, and application servers. A unique partnership Price/performance Coengineering and technology collaboration World-record performance Sun and AMD software engineers work jointly Leveraging more than 20 years of Symmetric on a range of codevelopment efforts including Multiprocessing (SMP) expertise, Sun has future development of HyperTransport, virtu- tuned and optimized Solaris 10 for the AMD alization, fault management, compiler perform- Opteron platform to deliver exceptional ance, and other ways Solaris may take advantage performance and near-linear scalability. For Highlights of the AMD Opteron architecture. Solaris 10 enterprises with demanding compute, net- • Supports the latest generation 5/08 also includes support for the latest gener- work, and Web applications, the combination of AMD x64 processors ation of AMD x64 processors and UltraSPARC of Solaris 10 and AMD Opteron processor-based • PowerNow! enhancements CMT systems. systems is often an ideal fit. Dozens of perform- provide additional power man- ance and price/performance world record agement capabilities Growing the Solaris™ OS ecosystem for AMD64 benchmarks demonstrate this exceptional • Remote client display virtualiztion Sun and AMD are working together with key combination. Solaris 10 has set more than • Solaris Trusted Extensions optimi- target ISVs, system builders, and independent 50 world records, employing various industry- zations for better interoperability hardware vendors (IHVs) to fuel growth of the standard benchmarks or workload scenarios and security Solaris 10 ecosystem around AMD64. -
AMD's Early Processor Lines, up to the Hammer Family (Families K8
AMD’s early processor lines, up to the Hammer Family (Families K8 - K10.5h) Dezső Sima October 2018 (Ver. 1.1) Sima Dezső, 2018 AMD’s early processor lines, up to the Hammer Family (Families K8 - K10.5h) • 1. Introduction to AMD’s processor families • 2. AMD’s 32-bit x86 families • 3. Migration of 32-bit ISAs and microarchitectures to 64-bit • 4. Overview of AMD’s K8 – K10.5 (Hammer-based) families • 5. The K8 (Hammer) family • 6. The K10 Barcelona family • 7. The K10.5 Shanghai family • 8. The K10.5 Istambul family • 9. The K10.5-based Magny-Course/Lisbon family • 10. References 1. Introduction to AMD’s processor families 1. Introduction to AMD’s processor families (1) 1. Introduction to AMD’s processor families AMD’s early x86 processor history [1] AMD’s own processors Second sourced processors 1. Introduction to AMD’s processor families (2) Evolution of AMD’s early processors [2] 1. Introduction to AMD’s processor families (3) Historical remarks 1) Beyond x86 processors AMD also designed and marketed two embedded processor families; • the 2900 family of bipolar, 4-bit slice microprocessors (1975-?) used in a number of processors, such as particular DEC 11 family models, and • the 29000 family (29K family) of CMOS, 32-bit embedded microcontrollers (1987-95). In late 1995 AMD cancelled their 29K family development and transferred the related design team to the firm’s K5 effort, in order to focus on x86 processors [3]. 2) Initially, AMD designed the Am386/486 processors that were clones of Intel’s processors. -
AMD Opteron™ 4000 Series Platform
AMD Opteron™ 4000 Series Platform The world’s lowest power x86 cloud processor1 just got more efficient The AMD Opteron™ 4200 Series processor — the world’s lowest power processor1,3 at fewer than 5 watts per core — while designed for challenging workloads still delivers a performance punch. AMD Opteron™ 4000 Series Platform Product Comparison ™ AMD Opteron 4100 ™ Series Processor AMD Opteron 4200 Series Processor Features Features Benefits 33% increase in core count packed with plenty of processing Processor Cores 4 and 6 core options 6 and 8 core options performance in a smaller2, more efficient3 8-core design while maintaining the same power/thermal ranges L2: 512 K/core L2: 2 MB shared by 2 cores Processor Cache L3: 6 MB L3: 8 MB Twice the L2 cache per core over the previous generation 2 memory channels supporting R/U 2 memory channels supporting ULV- 20% faster memory and new 1.25V ULV memory offering; Memory DDR3 and LV R/U DDR3 up to 1333MHz DIMM, UDIMM, RDIMM up to 1600MHz high memory bandwidth EE/Std/HE EE/Std/HE HE/Std/SE power options to match workload performance Power and power requirements HyperTransport™ Technology 2X HT3 Links (between CPUs) 2X HT3 Links (between CPUs) Helps improve overall system balance and scalability for scale-out (HT) Up to 25.6 GB/s per link @ 6.4 GT/s Up to 25.6 GB/s per link @ 6.4 GT/s computing environments like HPC, database and web serving Up to 8 cores, new features include Up to 20% greater throughput4 expected, 33% more cores5; FMAC in the Performance Up to 6 cores AMD Turbo CORE technology, FMAC, Flex FP help drive more performance by executing FMA4 instructions that Flex FP and an all new architecture execute complex calculations in half the cycles as the competition Features include enhanced APML (in APML-enabled platforms), AMD New power-saving features like C6 C6 Power State shuts down power to idle cores. -
Cache Hierarchy and Memory Subsystem of the Amd Opteron Processor
[3B2-14] mmi2010020016.3d 30/3/010 12:7 Page 16 .......................................................................................................................................................................................................................... CACHE HIERARCHY AND MEMORY SUBSYSTEM OF THE AMD OPTERON PROCESSOR .......................................................................................................................................................................................................................... THE 12-CORE AMD OPTERON PROCESSOR, CODE-NAMED ‘‘MAGNY COURS,’’ COMBINES ADVANCES IN SILICON, PACKAGING, INTERCONNECT, CACHE COHERENCE PROTOCOL, AND SERVER ARCHITECTURE TO INCREASE THE COMPUTE DENSITY OF HIGH-VOLUME COMMODITY 2P/4P BLADE SERVERS WHILE OPERATING WITHIN THE SAME POWER ENVELOPE AS EARLIER-GENERATION AMD OPTERON PROCESSORS.AKEY ENABLING FEATURE, THE PROBE FILTER, REDUCES BOTH THE BANDWIDTH OVERHEAD OF TRADITIONAL BROADCAST-BASED COHERENCE AND MEMORY LATENCY. ......Recent trends point to high and and latency sensitive, which favors the use growing demand for increased compute den- of high-performance cores. In fact, a com- sity in large-scale data centers. Many popular mon use of chip multiprocessor (CMP) serv- server workloads exhibit abundant process- ers is simply running multiple independent and thread-level parallelism, so benefit di- instances of single-threaded applications in rectly from additional cores. One approach multiprogrammed mode. In addition, for Pat Conway to exploiting -
Comparatif Des Processeurs
Comparatif des processeurs Le microprocesseur (ou processeur) est un composant essentiel de votre ordinateur. Pourtant sur les étiquettes, cet élément est rarement mis en avant, car commercialement ce n'est pas toujours vendeur, les gens font plus attention à la capacité du disque dur, au look de l'ordinateur, ou éventuellement à la puce vidéo. Alors attention quand même, le processeur ne fait pas tout. De la même façon qu'on ne choisit pas une voiture uniquement en fonction du moteur, on ne choisit pas non plus un ordinateur uniquement en fonction du processeur, mais c'est un élément qu'il faut savoir évaluer, au risque de se retrouver avec un ordinateur que vous trouverez toujours trop lent alors qu'il avait l'air très performant en rayon ;) Ce tableau vous aidera à évaluer une grande partie des processeurs existants. La liste des processeurs est triée par ordre alphabétique, et la colonne de droite indique le « score » du processeur. Le score à lui tout seul ne veut rien dire, mais c'est lui qui vous permettra de comparer un processeur par rapport à un autre. Plus le score est élevé, mieux c'est ! Le modèle de microprocesseur est affiché dans les propriétés système et sur l'étiquette en rayon Notez bien sa référence, une seule lettre peut tout changer ! Marque et modèle du processeur Score AMD A10 Micro-6700T APU 1875 AMD A10 PRO-7350B APU 3354 AMD A10 PRO-7800B APU 5313 AMD A10 PRO-7850B APU 5630 AMD A10-4600M APU 3121 AMD A10-4655M APU 2566 AMD A10-4657M APU 3449 AMD A10-5700 APU 4220 AMD A10-5745M APU 2788 AMD A10-5750M APU 3377