At a Glance
The Situation: All WFH, All the Time
The coronavirus outbreak is forcing a fundamental shift in the way we work. That being said, the move to remote work has been a long-time coming. This is only the beginning, according to business leaders. No surprise considering it could save them $11,000 per remote worker every year.1
The Challenge: Remote Access, Data Protection, and Doing More with Less
This development is driving IT teams to re-examine their plans and timelines for data center modernization. There is a laser focus on supporting WFH workers and ramping up cybersecurity. Along with security and collaboration, Forrester Research says that remote access is one of the three key technologies required to keep at-home employees productive and engaged.4
While 90% of IT professionals think remote workers are not secure, 92% also believe that the benefits of remote work outweigh the risks.5 And, so they’re in search of the best technologies to solve the problems that large-scale telecommuting can pose:
In addition to addressing these challenges, IT is still charged with reducing costs.
The Solution: Desktop Virtualization on HCI
Virtual desktop infrastructure (VDI) can provide employees with secure access to desktops, applications, and data from anywhere and on virtually any device. But traditional VDI is fraught with difficulties. Siloed infrastructure is tough to scale and requires specialized expertise.
That is why VDI on hyperconverged infrastructure (HCI) is in the spotlight. HCI consolidates storage, networking, and compute into one easy-to-manage system. It can help lower capital and operational expenses while boosting business agility and resilience.
For IT, implementing VDI on HCI offers:
For remote workforces, VDI on HCI enables:
Leading VDI solutions include VMware Horizon, Citrix VDI, and Microsoft Virtual Desktop. The top HCI offerings include VMware vSAN, Nutanix HCI, and Microsoft Azure Stack HCI.
The Game Changer: AMD EPYC™ Processors for VDI on HCI
Maximize the benefits of VDI on HCI with 2nd Gen AMD EPYC™, the leading high-performance x86 server processor6. When you deploy virtual desktops on HCI solutions powered by AMD EPYC™ you can:
Visit the links below to learn more about optimizing your VDI/HCI investment with AMD EPYC™ processors.
Dive deeper into AMD EPYC™
Greg Gibby is Sr. Product Marketing Manager, Data Center Products for AMD. His postings are his own opinions and may not represent AMD’s positions, strategies or opinions. Links to third party sites are provided for convenience and unless explicitly stated, AMD is not responsible for the contents of such linked sites and no endorsement is implied.
6. 16-n, 2P 2nd Gen EPYC™ 7702 powered server scores a world record result of 7100 SPECrate®2017_int_base http://spec.org/cpu2017/results/res2020q1/cpu2017-20191223-20452.pdf. The next highest published score is 3920 SPECrate®2017_int_base on a 16-n, 2-socket Xeon® 8180 powered server http://spec.org/cpu2017/results/res2018q1/cpu2017-20171222-01950.pdf as of 02/12/20. SPEC® and SPECrate® are trademarks of the Standard Performance Evaluation Corporation. Learn more at www.spec.org. ROM-517
7. For a complete list of world records see http://amd.com/worldrecords. ROM-169
8. 4-node, 2x EPYC 7F72 processor powered cluster (192 total cores) with a score of 13.27@ 14 tiles on the VMmark® 3.1.1 benchmark using vSAN™ (https://www.vmware.com/content/dam/digitalmarketing/vmware/en/pdf/vmmark/2020-04-14-DellEMC-PowerEdg...) delivers 24.8% more performance with a 16.7% higher tile/VM workload capacity than the VMmark® 3.1 vSAN performance of a 4-node, 2x Intel Xeon Platinum 8268 processor powered cluster (192 total cores) with a score of 10.63@12 tiles (https://www.vmware.com/content/dam/digitalmarketing/vmware/en/pdf/vmmark/2020-06-30-Supermicro-SYS-2...) as of 06/08/20. ROM-732
9. AMD Infinity Guard security features on EPYC™ processors must be enabled by server OEMs and/or Cloud Service Providers to operate. Check with your OEM or provider to confirm support of these features. Learn more about Infinity Guard at https://www.amd.com/en/technologies/infinity-guard. GD-177
10. 4-node, 2x EPYC™ 7742 processor powered cluster with a score of 24.08@ 28 tiles on the VMmark® 3.1.1 benchmark using vSAN (https://www.vmware.com/content/dam/digitalmarketing/vmware/en/pdf/vmmark/2020-04-28-DellEMC-PowerEdg...) delivers 2.27x the performance and 2.33x the tile/VM workload capacity than the VMmark® 3.1.1 vSAN performance of a 4-node, 2x Intel Xeon Platinum 8268 processor powered cluster with a score of 10.63@12 tiles (https://www.vmware.com/content/dam/digitalmarketing/vmware/en/pdf/vmmark/2020-06-30-Supermicro-SYS-2...) as of 06/08/20. ROM-737
11. Comparison results calculated by AMD based on a hypothetical scenario hosting 3,200 virtual machines on 2-socket Intel Xeon 6242 16 cores ea. (32 total cores) based systems compared to 1-socket AMD EPYC™ 7702P 64 total core system, each VM (virtual machine) allocated one core, (1) 1 TB hard drive @ $387, and 8GB of DRAM with a cost of $16.41 per GB using 16GB DDR4 DRAM. All calculations are based on AMD's best estimates of what actual costs and other values will be for both AMD and Intel based platforms. Each AMD 7702P system supports 64 VMs and each Intel 6242 system supports 32 VMs, for a total of 50 AMD powered servers and 100 Intel based servers. These estimates do not include and VM server management costs. System Configurations: Intel Xeon based servers include (2) Intel® Xeon® Gold 6242 @ $2,529 ea, with 256 GB of memory, a dual socket 2U rack mount server, each with power supplies, and NIC @ $2,500, for a total per server price of $12,146.56 ea. and a total hardware acquisition price of $1,214,656. AMD EPYC™ servers include a single socket 2U rack mount chassis, with (1) AMD EPYC™ 7702P at $4,425, with 512 GB of memory, a single socket 2U rack mount server, each with power supplies, and NIC @ $2,200, for a total per server price of $15,414.52 ea. and a total hardware acquisition price of $770,726. Power estimates: AMD 315 watts per server per hour, for a total solution power of 1360.8 kW per month for 50 servers. Intel 415 watts per server per hour, for a total soluton power of 3585.6 kW per month for 100 servers. Three-year total power with a PUE of 2 and a power cost of $0.12 per kWh: AMD - $97,977.60 and Intel - $258,163.20. Data center three-year real estate cost estimates based on $20/mth/sq ft and 27 sq ft per rack are for: Intel is 5 rack cabinets at $97,200 and for AMD of $48,600 (2.5 rack cabinets). Server Administration cost is calculated with an estimate of $110,500 annually per server administrator (includes 30% burden) with a ratio of one server administrator per 30 servers resulting in Intel cost of $1,105,000 (for 100 servers) and for AMD $552,500 (for 50 servers) for total 3 yr server administration costs. Total estimated 3 Year TCO as a result is $2,675,019 for the Intel-based Systems and $1,469,804 for the AMD EPYC powered systems. As a result, AMD EPYC based systems are estimated to deliver up to a 45% lower TCO (excluding software costs). Annual cost per VM: (1469804/3200)/3=$279; (2675091/3200)/3=$153.This scenario contains many assumptions and estimates and, while based on AMD internal research and best approximations, should be considered an example for information purposes only, and not used as a basis for decision making over actual testing. ROM-329
AMD, the AMD arrow, EPYC, and combinations thereof, are trademarks of Advanced Micro Devices, Inc. Citrix is a trademark of Citrix Systems, Inc. and/or one or more of its subsidiaries, and may be registered in the United States Patent and Trademark Office and in other countries. Nutanix Acropolis is a trademark of Nutanix Inc. VMware Horizon is a registered trademark of VMware in the US or other countries. VMware vSAN is a trademark of VMware in the US or other countries. Microsoft is a registered trademark of Microsoft Corporation in the US and/or other countries. VMware is a registered trademark of VMware in the US or other countries.