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AMD EPYC 7502P processor 2.5 GHz 128 MB L3
SKU
100-000000045
Login for pricing
In Stock
32 Cores, 64 Threads, 2.5GHz, 3.35GHz Boost, 128MB L3 Cache, Socket SP3, 180W
| Processor socket | Socket SP3 |
|---|---|
| Box | No |
| Processor cores | 32 |
| Processor family | AMD EPYC |
| SKU | 100-000000045 |
| EAN | 8592978166045 |
| Manufacturer | AMD |
| Availability | In Stock |
| Product Family | EPYC |
2nd Gen AMD EPYC are a new breed of server processors which sets a higher standard for data centers.
Groundbreaking design makes AMD EPYC #1 in performance across industry standard benchmarks, holding 80 world records to date. Performance you can count on to propel your modern data center workloads. ’Hardened at the Core’ protection helps defend against side-channel attacks and EPYC's secure encrypted virtualization features help keep your data safe. The processor’s agility helps you manage new deployments and changing workloads, with the system resources you need, simply and cost-effectively. AMD is the server processor company you can count on for innovation and leadership today and into the future.
Performance Leadership
Virtually everything runs better on AMD EPYC 7002 Series powered servers. Whether you run enterprise applications, virtualized and cloud computing environments, software-defined infrastructure, high-performance computing, or data analytic applications. EPYC processor-based systems are #1 on industry benchmarks, including those measuring integer, floating-point, virtualization, database, and HPC performance. AMD EPYC 7742 processor has set new world records that establish AMD as THE performance leader.
The secret is under the hood
AMD Infinity Architecture is a hybrid multi-die architecture that is reaching new heights with AMD EPYC 7002 Series processors. AMD Infinity Architecture now decouples two streams: eight dies for the processor cores, and one I/O die that supports security and communication outside the processor. With the agility to deliver the leading-edge process technology for CPU cores while letting I/O circuitry develop at its own rate, new capabilities can be brought to market faster with EPYC because its die design is not monolithic. This has allowed EPYC to race to leadership in the market and continue to innovate in the future.
Forged from the finest silicon
AMD is first to market an x86 processor based on 7nm technology. With double the core density and optimizations that improve instructions per cycle, the result is 4x the Floating-Point performance of 1st Gen AMD EPYC.
7nm process technology also brings energy efficiency. 2nd Gen AMD EPYC can provide the same performance at half the power consumption.
EPYC by the numbers
AMD EPYC has been engineered for data centers that rely on CPU performance. From oil and gas exploration, to in-memory databases, to big data analytics to production rendering to standard data center applications, highly parallel workloads have more cores to work with. AMD EPYC 7002 generation processors scale from 8 to 64 cores (16 to 128 threads per socket). No other x86 vendor today enables such a core density in the market.
Be top of the security chain
AMD EPYC is ‘Hardened at the Core’ with advanced security features. It is the first server CPU with an integrated and dedicated security processor providing the foundation for Secure Boot, Secure Memory Encryption (SME) and Secure Encrypted Virtualization (SEV). So you can worry less about data risk and focus more on running your business.
Enabling software boot without corruption
The AMD EPYC processor secure root of trust is designed to validate the initial BIOS software boot without corruption. In virtualized environments, you can cryptographically check that your entire software stack is booted without corruption on a cloud server or services you choose.
Restrict internal vulnerabilities
With encrypted memory, attacks on the integrity of main memory (such as cold-boot attacks) are inhibited because any data obtained is encrypted. High-performance encryption engines integrated into the memory channels help speed performance. All of this is accomplished without modifications to your application software.
Safeguarding virtual and cloud infrastructure
2nd Gen EPYC helps safeguard privacy and integrity by encrypting each virtual machine with one of up to 509 unique encryption keys known only to the processor. This aids in protecting confidentiality of your data even if a malicious virtual machine finds a way into your virtual machine’s memory, or a compromised hypervisor reaches into a guest virtual machine.
All-in feature set
AMD takes pride in having transparent relationships with its partners and customers. This means having an “all-in” feature set that isn’t contrived to extract higher prices from customers.
With AMD EPYC, you have the agility to choose the processor your application requires without worrying about whether an important feature or capability is included. Whatever the number of cores you choose, you’ll have the I/O, memory, and memory bandwidth to accomplish what you need.
First-to-market PCIe 4.0 readiness
AMD EPYC is the first and only current x86-architecture server processor supporting PCIe 4.06. PCIe 4.0 delivers double the I/O performance over PCIe 3.0. You can use 128 lanes of I/O to double the network bandwidth that ties together HPC clusters and satisfies voracious needs for east-west bandwidth. For other application needs and in virtualized environments, you can connect with higher speed to GPU accelerators, NVMe drives, and you can even use integrated disk controllers to access spinning disks without the typical bottleneck of a PCIe RAID controller.
X86 compatibility
You can have confidence in AMD EPYC 7002 generation processors because virtually all software will just work. We work with the open source community and major software vendors to help ensure your applications and enabling software will work exceptionally well with EPYC. The broad ecosystem of open tools and libraries are more reasons why top cloud providers such as AWS, Microsoft Azure, Oracle Cloud are providing services to customers based on AMD EPYC processors.
1-Socket EPYC server advantage
Traditional CPUs typically must scale up to a 2-socket server to overcome an imbalance of resources. With AMD EPYC, 1-socket servers satisfy most of your workload needs, helping you increase density and reduce capital, power, and cooling expenses.
With a 1-socket EPYC server, you can cut licensing costs up to 50% with ‘per-socket software’ such as VMware vSphere or vSAN.
Groundbreaking design makes AMD EPYC #1 in performance across industry standard benchmarks, holding 80 world records to date. Performance you can count on to propel your modern data center workloads. ’Hardened at the Core’ protection helps defend against side-channel attacks and EPYC's secure encrypted virtualization features help keep your data safe. The processor’s agility helps you manage new deployments and changing workloads, with the system resources you need, simply and cost-effectively. AMD is the server processor company you can count on for innovation and leadership today and into the future.
Performance Leadership
Virtually everything runs better on AMD EPYC 7002 Series powered servers. Whether you run enterprise applications, virtualized and cloud computing environments, software-defined infrastructure, high-performance computing, or data analytic applications. EPYC processor-based systems are #1 on industry benchmarks, including those measuring integer, floating-point, virtualization, database, and HPC performance. AMD EPYC 7742 processor has set new world records that establish AMD as THE performance leader.
The secret is under the hood
AMD Infinity Architecture is a hybrid multi-die architecture that is reaching new heights with AMD EPYC 7002 Series processors. AMD Infinity Architecture now decouples two streams: eight dies for the processor cores, and one I/O die that supports security and communication outside the processor. With the agility to deliver the leading-edge process technology for CPU cores while letting I/O circuitry develop at its own rate, new capabilities can be brought to market faster with EPYC because its die design is not monolithic. This has allowed EPYC to race to leadership in the market and continue to innovate in the future.
Forged from the finest silicon
AMD is first to market an x86 processor based on 7nm technology. With double the core density and optimizations that improve instructions per cycle, the result is 4x the Floating-Point performance of 1st Gen AMD EPYC.
7nm process technology also brings energy efficiency. 2nd Gen AMD EPYC can provide the same performance at half the power consumption.
EPYC by the numbers
AMD EPYC has been engineered for data centers that rely on CPU performance. From oil and gas exploration, to in-memory databases, to big data analytics to production rendering to standard data center applications, highly parallel workloads have more cores to work with. AMD EPYC 7002 generation processors scale from 8 to 64 cores (16 to 128 threads per socket). No other x86 vendor today enables such a core density in the market.
Be top of the security chain
AMD EPYC is ‘Hardened at the Core’ with advanced security features. It is the first server CPU with an integrated and dedicated security processor providing the foundation for Secure Boot, Secure Memory Encryption (SME) and Secure Encrypted Virtualization (SEV). So you can worry less about data risk and focus more on running your business.
Enabling software boot without corruption
The AMD EPYC processor secure root of trust is designed to validate the initial BIOS software boot without corruption. In virtualized environments, you can cryptographically check that your entire software stack is booted without corruption on a cloud server or services you choose.
Restrict internal vulnerabilities
With encrypted memory, attacks on the integrity of main memory (such as cold-boot attacks) are inhibited because any data obtained is encrypted. High-performance encryption engines integrated into the memory channels help speed performance. All of this is accomplished without modifications to your application software.
Safeguarding virtual and cloud infrastructure
2nd Gen EPYC helps safeguard privacy and integrity by encrypting each virtual machine with one of up to 509 unique encryption keys known only to the processor. This aids in protecting confidentiality of your data even if a malicious virtual machine finds a way into your virtual machine’s memory, or a compromised hypervisor reaches into a guest virtual machine.
All-in feature set
AMD takes pride in having transparent relationships with its partners and customers. This means having an “all-in” feature set that isn’t contrived to extract higher prices from customers.
With AMD EPYC, you have the agility to choose the processor your application requires without worrying about whether an important feature or capability is included. Whatever the number of cores you choose, you’ll have the I/O, memory, and memory bandwidth to accomplish what you need.
First-to-market PCIe 4.0 readiness
AMD EPYC is the first and only current x86-architecture server processor supporting PCIe 4.06. PCIe 4.0 delivers double the I/O performance over PCIe 3.0. You can use 128 lanes of I/O to double the network bandwidth that ties together HPC clusters and satisfies voracious needs for east-west bandwidth. For other application needs and in virtualized environments, you can connect with higher speed to GPU accelerators, NVMe drives, and you can even use integrated disk controllers to access spinning disks without the typical bottleneck of a PCIe RAID controller.
X86 compatibility
You can have confidence in AMD EPYC 7002 generation processors because virtually all software will just work. We work with the open source community and major software vendors to help ensure your applications and enabling software will work exceptionally well with EPYC. The broad ecosystem of open tools and libraries are more reasons why top cloud providers such as AWS, Microsoft Azure, Oracle Cloud are providing services to customers based on AMD EPYC processors.
1-Socket EPYC server advantage
Traditional CPUs typically must scale up to a 2-socket server to overcome an imbalance of resources. With AMD EPYC, 1-socket servers satisfy most of your workload needs, helping you increase density and reduce capital, power, and cooling expenses.
With a 1-socket EPYC server, you can cut licensing costs up to 50% with ‘per-socket software’ such as VMware vSphere or vSAN.
| Processor | |
|---|---|
| Processor base frequency | 2.5 GHz |
| Processor manufacturer | AMD |
| Cooler included | No |
| Thermal Design Power (TDP) | 180 W |
| Processor cache | 128 MB |
| Processor model | 7502P |
| Processor threads | 64 |
| Processor operating modes | 32-bit |
| Processor boost frequency | 3.35 GHz |
| Component for | Server/workstation |
| Processor lithography | 7 nm |
| Processor family | AMD EPYC |
| Processor cores | 32 |
| Box | No |
| Processor socket | Socket SP3 |
| Processor cache type | L3 |
| Memory | |
| Memory types supported by processor | DDR4-SDRAM |
| Memory clock speeds supported by processor | 3200 MHz |
| Memory channels | Octa-channel |
| Memory bandwidth (max) | 204.8 GB/s |
| Graphics | |
| Discrete graphics card | No |
| On-board graphics card model | Not available |
| On-board graphics card | No |
| Discrete graphics card model | Not available |
| Power | |
|---|---|
| Thermal Design Power (TDP) | 180 W |
| Technical details | |
| PCI Express slots version | 4.0 |
| Thermal Design Power (TDP) | 180 W |
| Market segment | Server |
| Processor cache type | L3 |
| Features | |
| Maximum number of PCI Express lanes | 128 |
| Thermal Design Power (TDP) | 180 W |
| PCI Express slots version | 4.0 |
| Market segment | Server |
| Harmonized System (HS) code | 85423119 |
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|---|---|---|---|---|---|---|
| SKU |
100-000000045
|
CD8069504449000
|
100-000000323
|
100-000000340
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100-000000341
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BX806895320
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| Description |
2nd Gen AMD EPYC are a new breed of server processors which sets a higher standard for data centers.
Groundbreaking design makes AMD EPYC #1 in performance across industry standard benchmarks, holding 80 world records to date. Performance you can count on to propel your modern data center workloads. ’Hardened at the Core’ protection helps defend against side-channel attacks and EPYC's secure encrypted virtualization features help keep your data safe. The processor’s agility helps you manage new deployments and changing workloads, with the system resources you need, simply and cost-effectively. AMD is the server processor company you can count on for innovation and leadership today and into the future. Performance Leadership Virtually everything runs better on AMD EPYC 7002 Series powered servers. Whether you run enterprise applications, virtualized and cloud computing environments, software-defined infrastructure, high-performance computing, or data analytic applications. EPYC processor-based systems are #1 on industry benchmarks, including those measuring integer, floating-point, virtualization, database, and HPC performance. AMD EPYC 7742 processor has set new world records that establish AMD as THE performance leader. The secret is under the hood AMD Infinity Architecture is a hybrid multi-die architecture that is reaching new heights with AMD EPYC 7002 Series processors. AMD Infinity Architecture now decouples two streams: eight dies for the processor cores, and one I/O die that supports security and communication outside the processor. With the agility to deliver the leading-edge process technology for CPU cores while letting I/O circuitry develop at its own rate, new capabilities can be brought to market faster with EPYC because its die design is not monolithic. This has allowed EPYC to race to leadership in the market and continue to innovate in the future. Forged from the finest silicon AMD is first to market an x86 processor based on 7nm technology. With double the core density and optimizations that improve instructions per cycle, the result is 4x the Floating-Point performance of 1st Gen AMD EPYC. 7nm process technology also brings energy efficiency. 2nd Gen AMD EPYC can provide the same performance at half the power consumption. EPYC by the numbers AMD EPYC has been engineered for data centers that rely on CPU performance. From oil and gas exploration, to in-memory databases, to big data analytics to production rendering to standard data center applications, highly parallel workloads have more cores to work with. AMD EPYC 7002 generation processors scale from 8 to 64 cores (16 to 128 threads per socket). No other x86 vendor today enables such a core density in the market. Be top of the security chain AMD EPYC is ‘Hardened at the Core’ with advanced security features. It is the first server CPU with an integrated and dedicated security processor providing the foundation for Secure Boot, Secure Memory Encryption (SME) and Secure Encrypted Virtualization (SEV). So you can worry less about data risk and focus more on running your business. Enabling software boot without corruption The AMD EPYC processor secure root of trust is designed to validate the initial BIOS software boot without corruption. In virtualized environments, you can cryptographically check that your entire software stack is booted without corruption on a cloud server or services you choose. Restrict internal vulnerabilities With encrypted memory, attacks on the integrity of main memory (such as cold-boot attacks) are inhibited because any data obtained is encrypted. High-performance encryption engines integrated into the memory channels help speed performance. All of this is accomplished without modifications to your application software. Safeguarding virtual and cloud infrastructure 2nd Gen EPYC helps safeguard privacy and integrity by encrypting each virtual machine with one of up to 509 unique encryption keys known only to the processor. This aids in protecting confidentiality of your data even if a malicious virtual machine finds a way into your virtual machine’s memory, or a compromised hypervisor reaches into a guest virtual machine. All-in feature set AMD takes pride in having transparent relationships with its partners and customers. This means having an “all-in” feature set that isn’t contrived to extract higher prices from customers. With AMD EPYC, you have the agility to choose the processor your application requires without worrying about whether an important feature or capability is included. Whatever the number of cores you choose, you’ll have the I/O, memory, and memory bandwidth to accomplish what you need. First-to-market PCIe 4.0 readiness AMD EPYC is the first and only current x86-architecture server processor supporting PCIe 4.06. PCIe 4.0 delivers double the I/O performance over PCIe 3.0. You can use 128 lanes of I/O to double the network bandwidth that ties together HPC clusters and satisfies voracious needs for east-west bandwidth. For other application needs and in virtualized environments, you can connect with higher speed to GPU accelerators, NVMe drives, and you can even use integrated disk controllers to access spinning disks without the typical bottleneck of a PCIe RAID controller. X86 compatibility You can have confidence in AMD EPYC 7002 generation processors because virtually all software will just work. We work with the open source community and major software vendors to help ensure your applications and enabling software will work exceptionally well with EPYC. The broad ecosystem of open tools and libraries are more reasons why top cloud providers such as AWS, Microsoft Azure, Oracle Cloud are providing services to customers based on AMD EPYC processors. 1-Socket EPYC server advantage Traditional CPUs typically must scale up to a 2-socket server to overcome an imbalance of resources. With AMD EPYC, 1-socket servers satisfy most of your workload needs, helping you increase density and reduce capital, power, and cooling expenses. With a 1-socket EPYC server, you can cut licensing costs up to 50% with ‘per-socket software’ such as VMware vSphere or vSAN. |
Intel® Trusted Execution Technology
Intel® Trusted Execution Technology for safer computing is a versatile set of hardware extensions to Intel® processors and chipsets that enhance the digital office platform with security capabilities such as measured launch and protected execution. It enables an environment where applications can run within their own space, protected from all other software on the system. Intel® Virtualization Technology for Directed I/O (VT-d) Intel® Virtualization Technology for Directed I/O (VT-d) continues from the existing support for IA-32 (VT-x) and Itanium® processor (VT-i) virtualization adding new support for I/O-device virtualization. Intel VT-d can help end users improve security and reliability of the systems and also improve performance of I/O devices in virtualized environments. Intel® Virtualization Technology (VT-x) Intel® Virtualization Technology (VT-x) allows one hardware platform to function as multiple “virtual” platforms. It offers improved manageability by limiting downtime and maintaining productivity by isolating computing activities into separate partitions. Intel® 64 Intel® 64 architecture delivers 64-bit computing on server, workstation, desktop and mobile platforms when combined with supporting software.¹ Intel 64 architecture improves performance by allowing systems to address more than 4 GB of both virtual and physical memory. Cache CPU Cache is an area of fast memory located on the processor. Intel® Smart Cache refers to the architecture that allows all cores to dynamically share access to the last level cache. Intel® AES New Instructions Intel® AES New Instructions (Intel® AES-NI) are a set of instructions that enable fast and secure data encryption and decryption. AES-NI are valuable for a wide range of cryptographic applications, for example: applications that perform bulk encryption/decryption, authentication, random number generation, and authenticated encryption. Intel® Turbo Boost Technology Intel® Turbo Boost Technology dynamically increases the processor's frequency as needed by taking advantage of thermal and power headroom to give you a burst of speed when you need it, and increased energy efficiency when you don’t. Max Turbo Frequency Max Turbo Frequency is the maximum single-core frequency at which the processor is capable of operating using Intel® Turbo Boost Technology and, if present, Intel® Turbo Boost Max Technology 3.0 and Intel® Thermal Velocity Boost. Frequency is typically measured in gigahertz (GHz), or billion cycles per second. Execute Disable Bit Execute Disable Bit is a hardware-based security feature that can reduce exposure to viruses and malicious-code attacks and prevent harmful software from executing and propagating on the server or network. Intel® Hyper-Threading Technology Intel® Hyper-Threading Technology (Intel® HT Technology) delivers two processing threads per physical core. Highly threaded applications can get more work done in parallel, completing tasks sooner. Intel vPro® Platform Eligibility The Intel vPro® platform is a set of hardware and technologies used to build business computing endpoints with premium performance, built-in security, modern manageability and platform stability. Intel® VT-x with Extended Page Tables (EPT) Intel® VT-x with Extended Page Tables (EPT), also known as Second Level Address Translation (SLAT), provides acceleration for memory intensive virtualized applications. Extended Page Tables in Intel® Virtualization Technology platforms reduces the memory and power overhead costs and increases battery life through hardware optimization of page table management. Enhanced Intel SpeedStep® Technology Enhanced Intel SpeedStep® Technology is an advanced means of enabling high performance while meeting the power-conservation needs of mobile systems. Conventional Intel SpeedStep® Technology switches both voltage and frequency in tandem between high and low levels in response to processor load. Enhanced Intel SpeedStep® Technology builds upon that architecture using design strategies such as Separation between Voltage and Frequency Changes, and Clock Partitioning and Recovery. Intel® Speed Shift Technology Intel® Speed Shift Technology uses hardware-controlled P-states to deliver dramatically quicker responsiveness with single-threaded, transient (short duration) workloads, such as web browsing, by allowing the processor to more quickly select its best operating frequency and voltage for optimal performance and power efficiency. Intel® Deep Learning Boost (Intel® DL Boost) on CPU A new set of embedded processor technologies designed to accelerate AI deep learning use cases. It extends Intel AVX-512 with a new Vector Neural Network Instruction (VNNI) that significantly increases deep learning inference performance over previous generations. Instruction Set Extensions Instruction Set Extensions are additional instructions which can increase performance when the same operations are performed on multiple data objects. These can include SSE (Streaming SIMD Extensions) and AVX (Advanced Vector Extensions). Intel® Run Sure Technology Intel® Run Sure Technology, includes advanced RAS (reliability, availability and serviceability) features that deliver high reliability and platform resiliency, to maximize uptime of servers running mission-critical workloads. Intel® Turbo Boost Max Technology 3.0 Intel® Turbo Boost Max Technology 3.0 identifies the best performing core(s) on a processor and provides increased performance on those cores through increasing frequency as needed by taking advantage of power and thermal headroom. Max # of UPI Links Intel® Ultra Path Interconnect (UPI) links are a high speed, point-to-point interconnect bus between the processors, delivering increased bandwidth and performance over Intel® QPI. # of AVX-512 FMA Units Intel® Advanced Vector Extensions 512 (AVX-512), new instruction set extensions, delivering ultra-wide (512-bit) vector operations capabilities, with up to 2 FMAs (Fused Multiply Add instructions), to accelerate performance for your most demanding computational tasks. Intel® Resource Director Technology (Intel® RDT) Intel® RDT brings new levels of visibility and control over how shared resources such as last-level cache (LLC) and memory bandwidth are used by applications, virtual machines (VMs) and containers. Intel® Speed Select Technology - Performance Profile A capability to configure the processor to run at three distinct operating points. Intel® Speed Select Technology - Base Frequency Enables users to increase guaranteed base frequency on certain cores (high priority cores) in exchange for lower base frequency on remaining cores (low priority cores). Improves overall performance by boosting frequency on critical cores. Intel® Volume Management Device (VMD) Intel® Volume Management Device (VMD) provides a common, robust method of hot plug and LED management for NVMe-based solid state drives. Intel® Optane™ Persistent Memory Supported Intel® Optane™ persistent memory is a revolutionary tier of non-volatile memory that sits between memory and storage to provide large, affordable memory capacity that is comparable to DRAM performance. Delivering large system-level memory capacity when combined with traditional DRAM, Intel Optane persistent memory is helping transform critical memory constrained workloads – from cloud, databases, in-memory analytics, virtualization, and content delivery networks. Mode-based Execute Control (MBEC) Mode-based Execute Control can more reliably verify and enforce the integrity of kernel level code. Intel® Transactional Synchronization Extensions Intel® Transactional Synchronization Extensions (Intel® TSX) are a set of instructions that add hardware transactional memory support to improve performance of multi-threaded software. |
Accelerate Workload Performance Data centers that require the best CPU performance, security features, and scalability count on Solution Briefs and White Papers Find the technical resources you need to learn more about AMD EPYC™. Where to Buy EPYC™️ Powered Solutions Find a partner offering AMD EPYC™ Processors and solutions. AMD Data Center Insights and Updates Sign up to receive the latest data center news and server content. AMD Infinity Guard Help minimize potential attack surfaces as software is booted, executed, and processes your critical data AMD Infinity Architecture With architecture, performance, and security leadership, our approach to processor design accelerates the pace of innovation so that you can break through years of data center stagnation.
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No
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No
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Intel® Trusted Execution Technology
Intel® Trusted Execution Technology for safer computing is a versatile set of hardware extensions to Intel® processors and chipsets that enhance the digital office platform with security capabilities such as measured launch and protected execution. It enables an environment where applications can run within their own space, protected from all other software on the system. Intel® Virtualization Technology for Directed I/O (VT-d) Intel® Virtualization Technology for Directed I/O (VT-d) continues from the existing support for IA-32 (VT-x) and Itanium® processor (VT-i) virtualization adding new support for I/O-device virtualization. Intel VT-d can help end users improve security and reliability of the systems and also improve performance of I/O devices in virtualized environments. Intel® Virtualization Technology (VT-x) Intel® Virtualization Technology (VT-x) allows one hardware platform to function as multiple “virtual” platforms. It offers improved manageability by limiting downtime and maintaining productivity by isolating computing activities into separate partitions. Intel® 64 Intel® 64 architecture delivers 64-bit computing on server, workstation, desktop and mobile platforms when combined with supporting software.¹ Intel 64 architecture improves performance by allowing systems to address more than 4 GB of both virtual and physical memory. Cache CPU Cache is an area of fast memory located on the processor. Intel® Smart Cache refers to the architecture that allows all cores to dynamically share access to the last level cache. Intel® AES New Instructions Intel® AES New Instructions (Intel® AES-NI) are a set of instructions that enable fast and secure data encryption and decryption. AES-NI are valuable for a wide range of cryptographic applications, for example: applications that perform bulk encryption/decryption, authentication, random number generation, and authenticated encryption. Intel® Turbo Boost Technology Intel® Turbo Boost Technology dynamically increases the processor's frequency as needed by taking advantage of thermal and power headroom to give you a burst of speed when you need it, and increased energy efficiency when you don’t. Max Turbo Frequency Max Turbo Frequency is the maximum single-core frequency at which the processor is capable of operating using Intel® Turbo Boost Technology and, if present, Intel® Turbo Boost Max Technology 3.0 and Intel® Thermal Velocity Boost. Frequency is typically measured in gigahertz (GHz), or billion cycles per second. Execute Disable Bit Execute Disable Bit is a hardware-based security feature that can reduce exposure to viruses and malicious-code attacks and prevent harmful software from executing and propagating on the server or network. Intel® Hyper-Threading Technology Intel® Hyper-Threading Technology (Intel® HT Technology) delivers two processing threads per physical core. Highly threaded applications can get more work done in parallel, completing tasks sooner. Intel® VT-x with Extended Page Tables (EPT) Intel® VT-x with Extended Page Tables (EPT), also known as Second Level Address Translation (SLAT), provides acceleration for memory intensive virtualized applications. Extended Page Tables in Intel® Virtualization Technology platforms reduces the memory and power overhead costs and increases battery life through hardware optimization of page table management. Intel® Speed Shift Technology Intel® Speed Shift Technology uses hardware-controlled P-states to deliver dramatically quicker responsiveness with single-threaded, transient (short duration) workloads, such as web browsing, by allowing the processor to more quickly select its best operating frequency and voltage for optimal performance and power efficiency. Intel® Crypto Acceleration Intel® Crypto Acceleration reduces the performance impact of pervasive encryption and increases the performance of encryption-intensive workloads including SSL web serving, 5G infrastructure, and VPN/firewalls. Intel® Software Guard Extensions (Intel® SGX) Intel® Software Guard Extensions (Intel® SGX) provide applications the ability to create hardware enforced trusted execution protection for their applications’ sensitive routines and data. Intel® SGX provides developers a way to partition their code and data into CPU hardened trusted execution environments (TEE’s). Intel® Speed Select Technology – Core Power Enables flexibility for workloads that benefit from higher base frequency on a subset of the processor’s cores. While the max turbo frequency across the cores remain constant across the cores, a subset of the cores can be assigned as to run at a higher base frequency than specified, while the other cores run at lower base frequency. Intel® Speed Select Technology – Turbo Frequency Enables flexibility for workloads that benefit from higher turbo frequency on a subset of the processor’s cores. While the base frequency remains constant across the cores, a subset of the cores can be assigned to run at a higher turbo frequency than specified, while the other cores run at lower turbo frequency. Intel® Deep Learning Boost (Intel® DL Boost) on CPU A new set of embedded processor technologies designed to accelerate AI deep learning use cases. It extends Intel AVX-512 with a new Vector Neural Network Instruction (VNNI) that significantly increases deep learning inference performance over previous generations. Instruction Set Extensions Instruction Set Extensions are additional instructions which can increase performance when the same operations are performed on multiple data objects. These can include SSE (Streaming SIMD Extensions) and AVX (Advanced Vector Extensions). Intel® Run Sure Technology Intel® Run Sure Technology, includes advanced RAS (reliability, availability and serviceability) features that deliver high reliability and platform resiliency, to maximize uptime of servers running mission-critical workloads. Intel® Total Memory Encryption TME – Total Memory Encryption (TME) helps protect data against exposure via physical attack on memory, such as cold-boot attacks. Max # of UPI Links Intel® Ultra Path Interconnect (UPI) links are a high speed, point-to-point interconnect bus between the processors, delivering increased bandwidth and performance over Intel® QPI. # of AVX-512 FMA Units Intel® Advanced Vector Extensions 512 (AVX-512), new instruction set extensions, delivering ultra-wide (512-bit) vector operations capabilities, with up to 2 FMAs (Fused Multiply Add instructions), to accelerate performance for your most demanding computational tasks. Intel® Resource Director Technology (Intel® RDT) Intel® RDT brings new levels of visibility and control over how shared resources such as last-level cache (LLC) and memory bandwidth are used by applications, virtual machines (VMs) and containers. Intel® Speed Select Technology - Base Frequency Enables users to increase guaranteed base frequency on certain cores (high priority cores) in exchange for lower base frequency on remaining cores (low priority cores). Improves overall performance by boosting frequency on critical cores. Intel® Volume Management Device (VMD) Intel® Volume Management Device (VMD) provides a common, robust method of hot plug and LED management for NVMe-based solid state drives. Intel® Optane™ Persistent Memory Supported Intel® Optane™ persistent memory is a revolutionary tier of non-volatile memory that sits between memory and storage to provide large, affordable memory capacity that is comparable to DRAM performance. Delivering large system-level memory capacity when combined with traditional DRAM, Intel Optane persistent memory is helping transform critical memory constrained workloads – from cloud, databases, in-memory analytics, virtualization, and content delivery networks. Mode-based Execute Control (MBEC) Mode-based Execute Control can more reliably verify and enforce the integrity of kernel level code. Intel® Transactional Synchronization Extensions Intel® Transactional Synchronization Extensions (Intel® TSX) are a set of instructions that add hardware transactional memory support to improve performance of multi-threaded software. |
| Short Description |
32 Cores, 64 Threads, 2.5GHz, 3.35GHz Boost, 128MB L3 Cache, Socket SP3, 180W
|
Intel® Xeon® Gold 6226R Processor (22M Cache, 2.90 GHz)
|
24 cores, 48 threads, 2.65GHz base clock, 3.6GHz boost clock, 128MB L3 cache, 180W TDP
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24 cores, 48 threads, 2.85 GHz base frequency, 4.0 GHz boost frequency, 128MB L3 cache, 200W TDP
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32 cores, 64 threads, 2.8 GHz base frequency, 3.7 GHz boost frequency, 256MB L3 cache, 225W TDP
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Intel® Xeon® Gold 5320 Processor (39M Cache, 2.20 GHz)
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| Manufacturer |
AMD
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Intel
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AMD
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AMD
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AMD
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Intel
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