AMD EPYC™ 7003 Series Processors
Proven Performance and Energy Efficiency
Achieve exceptional price performance and power savings with proven 3rd Gen AMD EPYC™ processors.1
Update your data center with cost effective, energy efficient solutions.
AMD EPYC™ 7003 Series Processors have set a standard for performance and efficiency for mainstream data center servers. Customers that have done extensive application qualification on DDR4/PCIe®4 generation systems and seek performant, cost-effective solutions to data center challenges, can find tremendous value with AMD EPYC™ 7003 processor-based servers.
Better Performance per CPU Price2
(64 Total Cores)
Better Energy Efficiency3
Benefits
Security
With security threats on the rise, you need to ensure maximum protection for your critical data. EPYC processors come with AMD Infinity Guard—a full suite of cutting-edge security features, built into the silicon and designed to defend against internal and external threats.4
AMD Infinity Guard helps decrease potential attack surfaces as software boots, executes, and processes your data. It includes:
- Secure Encrypted Virtualization (SEV) to help safeguard VM privacy and integrity
- Secure Nested Paging (SEV-SNP) for strong memory integrity protection capabilities
- Secure Memory Encryption (SME) to help guard against attacks on main memory
- AMD Shadow Stack™ for hardware-enforced stack protection capabilities against malware attacks
Energy Efficiency
EPYC processors power the most energy efficient x86 servers, delivering exceptional performance and reducing energy costs.5 EPYC CPUs can help minimize environmental impacts from data center operations while advancing your company’s sustainability objectives.
AMD has even bigger plans in place for the future. Our goal is to deliver 30x increase in energy efficiency for AMD processors and accelerators powering servers for AI-training and HPC from 2020-2025. Our goal equates to a 97% reduction in energy use per computation by 2025. If all AI and HPC server nodes globally were to make similar gains, billions of kilowatt-hours of electricity?could be saved in 2025 relative to?baseline trends.
Outstanding Return on IT Investment
Capture the value of your IT investment. Cut total cost of ownership in virtualized environments by an estimated 68% to deliver 320 VMs.6 EPYC processor-powered servers can improve time-to-value for your applications and help you gain business-critical insights faster.
EPYC processor-powered single-socket servers also deliver compute power that is right-sized for your workloads, so that you may be able to satisfy your business requirements without having to scale up to dual-socket servers— thus helping minimize licensing costs and reducing power consumption.
Partner Solutions
Backed by Industry Leaders
Major infrastructure and software providers work with AMD to help ensure your applications work exceptionally well with EPYC processor-powered servers. EPYC processors run virtually all x86 applications, enable worry free migration, and seamlessly integrate into existing x86 infrastructures.
Whether you are seeking virtualization, containerization, hybrid cloud, or software-defined infrastructure opportunities, there is an EPYC processor-powered solution to meet your needs—all thanks to our strong partnerships with these industry leaders.
Comparison
Name |
# of CPU Cores |
# of Threads |
Max. Boost Clock7 |
Base Clock |
L3 Cache |
Default TDP |
| AMD EPYC™ 7203P | 8 | 16 | Up to 3.4 GHz | 2.8 GHz | 64 MB | 120W |
| AMD EPYC™ 7203 | 8 | 16 | Up to 3.4 GHz | 2.8 GHz | 64 MB | 120W |
| AMD EPYC™ 7303P | 16 | 32 | Up to 3.4 GHz | 2.4 GHz | 64 MB | 130W |
| AMD EPYC™ 7303 | 16 | 32 | Up to 3.4 GHz | 2.4 GHz | 64 MB | 130W |
| AMD EPYC™ 7643P | 48 | 96 | Up to 3.6 GHz | 2.3 GHz | 256 MB | 225W |
| AMD EPYC™ 7773X | 64 | 128 | Up to 3.5 GHz | 2.2 GHz | 768 MB | 280W |
| AMD EPYC™ 7763 | 64 | 128 | Up to 3.5 GHz | 2.45 GHz | 256 MB | 280W |
| AMD EPYC™ 7713P | 64 | 128 | Up to 3.67 GHz | 2 GHz | 256 MB | 225W |
| AMD EPYC™ 7713 | 64 | 128 | Up to 3.67 GHz | 2 GHz | 256 MB | 225W |
| AMD EPYC™ 7663 | 56 | 112 | Up to 3.5 GHz | 2 GHz | 256 MB | 240W |
| AMD EPYC™ 7643 | 48 | 96 | Up to 3.6 GHz | 2.3 GHz | 256 MB | 225W |
| AMD EPYC™ 75F3 | 32 | 64 | Up to 4 GHz | 2.95 GHz | 256 MB | 280W |
| AMD EPYC™ 7663P | 56 | 112 | Up to 3.58 GHz | 2 GHz | 256 MB | 240W |
| AMD EPYC™ 7573X | 32 | 64 | Up to 3.6 GHz | 2.8 GHz | 768 MB | 280W |
| AMD EPYC™ 7543P | 32 | 64 | Up to 3.7 GHz | 2.8 GHz | 256 MB | 225W |
| AMD EPYC™ 7543 | 32 | 64 | Up to 3.7 GHz | 2.8 GHz | 256 MB | 225W |
| AMD EPYC™ 7513 | 32 | 64 | Up to 3.65 GHz | 2.6 GHz | 128 MB | 200W |
| AMD EPYC™ 74F3 | 24 | 48 | Up to 4 GHz | 3.2 GHz | 256 MB | 240W |
| AMD EPYC™ 7473X | 24 | 48 | Up to 3.7 GHz | 2.8 GHz | 768 MB | 240W |
| AMD EPYC™ 7453 | 28 | 56 | Up to 3.45 GHz | 2.75 GHz | 64 MB | 225W |
| AMD EPYC™ 7443P | 24 | 48 | Up to 4 GHz | 2.85 GHz | 128 MB | 200W |
| AMD EPYC™ 7443 | 24 | 48 | Up to 4 GHz | 2.85 GHz | 128 MB | 200W |
| AMD EPYC™ 7413 | 24 | 48 | Up to 3.6GHz | 2.65 GHz | 128 MB | 180W |
| AMD EPYC™ 73F3 | 16 | 32 | Up to 4 GHz | 3.5 GHz | 256 MB | 240W |
| AMD EPYC™ 7373X | 16 | 32 | Up to 3.8 GHz | 3.05 GHz | 768 MB | 240W |
| AMD EPYC™ 7343 | 16 | 32 | Up to 3.9 GHz | 3.2 GHz | 128 MB | 190W |
| AMD EPYC™ 7313P | 16 | 32 | Up to 3.7 GHz | 3 GHz | 128 MB | 155W |
| AMD EPYC™ 7313 | 16 | 32 | Up to 3.7 GHz | 3 GHz | 128 MB | 155W |
| AMD EPYC™ 72F3 | 8 | 16 | Up to 4.1 GHz | 3.7 GHz | 256 MB | 180W |
1. MLN-201: SPECrate®2017_int_base comparison based on published scores from www.spec.org as of 10/27/2023. Comparison of published 1P AMD EPYC 7203P (70.8 SPECrate®2017_int_base, 120 Total TDP W, 8 Total Cores, $2635 Est system $, 207 est system W, https://www.spec.org/cpu2017/results/res2023q3/cpu2017-20230828-38848.html) is 1.62x the performance of published 1P Intel Xeon Bronze 3408U (43.7 SPECrate®2017_int_base, 125 Total TDP W, 8 Total Cores, $3074 Est system $, 251 est system W, https://www.spec.org/cpu2017/results/res2023q4/cpu2017-20230925-39034.html) [at 1.96x the performance/system W] [at 1.89x the performance/system $]. AMD 1Ku pricing and Intel ARK.intel.com specifications and pricing as of 10/27/2023. SPEC®, SPEC CPU®, and SPECrate® are registered trademarks of the Standard Performance Evaluation Corporation. See www.spec.org for more information. The system pricing and watt estimates are based on Bare Metal GHG TCO v9.60. Actual costs and system watts will vary.
2. MLN-098B: SPECrate®2017_int_base comparison based on best performing systems published at www.spec.org as of 10/11/2023. Configurations: 2x AMD EPYC 7543 (567 SPECrate®2017_int_base, https://www.spec.org/cpu2017/results/res2021q4/cpu2017-20211011-29672.html , $7522 1Ku price total, 450W total TDP) versus 2x Intel Xeon Platinum 8358 (507 SPECrate®2017_int_base, https://www.spec.org/cpu2017/results/res2023q1/cpu2017-20230130-33812.html , $9214 1Ku price total, 500W total TDP) for 1.12x the performance at 1.36x the score per total CPU $ and 1.24x the performance/Watt. AMD 1Ku pricing and Intel ARK.intel.com specifications and pricing as of 10/11/23. SPEC®, SPEC CPU®, and SPECrate® are registered trademarks of the Standard Performance Evaluation Corporation. see www.spec.org for more information.
3. MLN-094B: SPECpower_ssj 2008 overall ssj_ops/watt comparison based on highest system results published as of 10/23/2023. Configurations: 2x AMD EPYC 7763 (64C) (25302 overall ssj_ops/watt, https://www.spec.org/power_ssj2008/results/res2022q3/power_ssj2008-20220617-01179.html) versus 2x Intel Xeon Platinum 8380 (40C) (13670 overall ssj_ops/watt, https://www.spec.org/power_ssj2008/results/res2022q4/power_ssj2008-20220926-01184.html) for 1.85x the performance per watt. SPEC® and SPECpower_ssj® are registered trademarks of the Standard Performance Evaluation Corporation. see www.spec.org for more information.
4. GD-183: AMD Infinity Guard features vary by EPYC™ Processor generations. Infinity Guard security features 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/products/processors/server/epyc/infinity-guard.html
5. EPYC-028: As of 2/2/22, of SPECpower_ssj® 2008 results published on SPEC’s website, the 55 publications with the highest overall efficiency results were all powered by AMD EPYC processors. More information about SPEC® is available at //www.spec.org. SPEC and SPECpower are registered trademarks of the Standard Performance Evaluation Corporation.
Links to these 55 results are:
1. //www.spec.org/power_ssj2008/results/res2020q4/power_ssj2008-20200918-01047.html
2. //www.spec.org/power_ssj2008/results/res2020q4/power_ssj2008-20200918-01046.html
3. //www.spec.org/power_ssj2008/results/res2021q2/power_ssj2008-20210324-01091.html
4. //www.spec.org/power_ssj2008/results/res2020q2/power_ssj2008-20200519-01031.html
5. //www.spec.org/power_ssj2008/results/res2021q1/power_ssj2008-20210309-01077.html
6. //www.spec.org/power_ssj2008/results/res2020q2/power_ssj2008-20200407-01022.html
7. //www.spec.org/power_ssj2008/results/res2021q2/power_ssj2008-20210408-01094.html
8. //www.spec.org/power_ssj2008/results/res2020q2/power_ssj2008-20200519-01034.html
9. //www.spec.org/power_ssj2008/results/res2021q2/power_ssj2008-20210413-01095.html
10. //www.spec.org/power_ssj2008/results/res2021q1/power_ssj2008-20210309-01078.html
11. //www.spec.org/power_ssj2008/results/res2020q2/power_ssj2008-20200519-01032.html
12. //www.spec.org/power_ssj2008/results/res2020q2/power_ssj2008-20200407-01023.html
13. //www.spec.org/power_ssj2008/results/res2020q2/power_ssj2008-20200407-01025.html
14. //www.spec.org/power_ssj2008/results/res2020q2/power_ssj2008-20200519-01033.html
15. //www.spec.org/power_ssj2008/results/res2020q2/power_ssj2008-20200407-01024.html
16. //www.spec.org/power_ssj2008/results/res2021q4/power_ssj2008-20211001-01130.html
17. //www.spec.org/power_ssj2008/results/res2021q2/power_ssj2008-20210602-01106.html
18. //www.spec.org/power_ssj2008/results/res2021q2/power_ssj2008-20210602-01105.html
19. //www.spec.org/power_ssj2008/results/res2020q3/power_ssj2008-20200714-01039.html
20. //www.spec.org/power_ssj2008/results/res2020q1/power_ssj2008-20191125-01012.html
21. //www.spec.org/power_ssj2008/results/res2021q2/power_ssj2008-20210615-01111.html
22. //www.spec.org/power_ssj2008/results/res2020q3/power_ssj2008-20200714-01040.html
23. //www.spec.org/power_ssj2008/results/res2020q2/power_ssj2008-20200324-01021.html
24. //www.spec.org/power_ssj2008/results/res2020q1/power_ssj2008-20191125-01011.html
25. //www.spec.org/power_ssj2008/results/res2020q2/power_ssj2008-20200313-01020.html
26. //www.spec.org/power_ssj2008/results/res2020q2/power_ssj2008-20200313-01019.html
27. //www.spec.org/power_ssj2008/results/res2020q1/power_ssj2008-20200310-01018.html
28. //www.spec.org/power_ssj2008/results/res2019q3/power_ssj2008-20190717-00987.html
29. //www.spec.org/power_ssj2008/results/res2019q3/power_ssj2008-20190717-00988.html
30. //www.spec.org/power_ssj2008/results/res2019q3/power_ssj2008-20190909-01004.html
31. //www.spec.org/power_ssj2008/results/res2019q3/power_ssj2008-20190717-00986.html
32. //www.spec.org/power_ssj2008/results/res2021q1/power_ssj2008-20210221-01066.html
33. //www.spec.org/power_ssj2008/results/res2019q3/power_ssj2008-20190717-00990.html
34. //www.spec.org/power_ssj2008/results/res2019q3/power_ssj2008-20190717-00985.html
35. //www.spec.org/power_ssj2008/results/res2020q3/power_ssj2008-20200728-01041.html
36. //www.spec.org/power_ssj2008/results/res2021q1/power_ssj2008-20210221-01063.html
37. //www.spec.org/power_ssj2008/results/res2019q3/power_ssj2008-20190716-00980.html
38. //www.spec.org/power_ssj2008/results/res2021q1/power_ssj2008-20210221-01064.html
39. //www.spec.org/power_ssj2008/results/res2021q1/power_ssj2008-20210221-01065.html
40. //www.spec.org/power_ssj2008/results/res2019q3/power_ssj2008-20190716-00982.html
41. //www.spec.org/power_ssj2008/results/res2021q1/power_ssj2008-20210223-01073.html
42. //www.spec.org/power_ssj2008/results/res2020q2/power_ssj2008-20200407-01029.html
43. //www.spec.org/power_ssj2008/results/res2020q2/power_ssj2008-20200407-01028.html
44. //www.spec.org/power_ssj2008/results/res2019q3/power_ssj2008-20190716-00981.html
45. //www.spec.org/power_ssj2008/results/res2019q4/power_ssj2008-20191203-01015.html
46. //www.spec.org/power_ssj2008/results/res2021q1/power_ssj2008-20210222-01068.html
47. //www.spec.org/power_ssj2008/results/res2020q2/power_ssj2008-20200407-01026.html
48. //www.spec.org/power_ssj2008/results/res2021q1/power_ssj2008-20210223-01074.html
49. //www.spec.org/power_ssj2008/results/res2019q3/power_ssj2008-20190911-01005.html
50. //www.spec.org/power_ssj2008/results/res2021q1/power_ssj2008-20210222-01069.html
51. //www.spec.org/power_ssj2008/results/res2019q3/power_ssj2008-20190730-00994.html
52. //www.spec.org/power_ssj2008/results/res2021q1/power_ssj2008-20210222-01071.html
53. //www.spec.org/power_ssj2008/results/res2020q2/power_ssj2008-20200407-01027.html
54. //www.spec.org/power_ssj2008/results/res2019q3/power_ssj2008-20190717-00984.html
55. //www.spec.org/power_ssj2008/results/res2021q1/power_ssj2008-20210222-01072.html
6. MLNTCO-010A: 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. The AMD EPYC™ SERVER VIRTUALIZATION and GREENHOUSE GAS EMISSIONS TCO ESTIMATION TOOL compares the 1P AMD EPYC™ EPYC_7453 (28c) and the 2P Intel® Xeon® Gold_6334 (8c) server solutions required to deliver 320 total virtual machines (VM), requiring 1 core and 8GB of memory per VM. The analysis includes hardware components and may include virtualization software (SW) if selected.