HPE P11612-001 Intel Xeon Gold 5218 Processor 16 Core 2.3GHz 22MB Smart Cache
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Product Overview of Intel Xeon Gold 5218 Processor
- Type of Product: Server Processor
- Manufacturer: HPE
- Part Number: P11612-001
- Model: Gold 5218
Technical Specifications
Core and Performance
- Number of Cores: 16-core
- Base Clock Speed: 2.30 GHz
- Maximum Turbo Frequency: 3.90 GHz
- Ultrapath Interconnect (UPI) Speed: 10.4 GT/s
- UPI Links: 2
Instruction Set and Extensions
- Instruction Set: 64-bit
- Instruction Set Extensions: Intel AVX-512
Cache Memory Details
- Smart Cache Size: 22 MB
- Manufacturing Process: 14 nm
- Maximum Thermal Design Power (TDP): 125 W
- Compatible Socket Type: FCLGA3647
Memory Specifications
Capacity and Types
- Maximum Memory Capacity: 1 TB (dependent on memory type)
- Supported Memory Types: DDR4-2667
- Peak Memory Speed: 2.67 GHz
- Maximum Memory Channels: 6
- ECC Memory Support: Yes
Core Count: 16
Enhanced Performance
The Intel Xeon Gold 5218 Processor boasts an impressive core count of 16, making it a powerhouse for demanding workloads and resource-intensive applications. With more cores, the processor can handle multiple tasks simultaneously, resulting in enhanced performance and improved efficiency. Whether you are running complex simulations, performing data analysis, or running virtual machines, the 16 cores ensure smooth and responsive operation even under heavy workloads.
Parallel Processing
Parallel processing is a key advantage of having 16 cores in the Intel Xeon Gold 5218 Processor. This feature allows the processor to divide tasks into smaller sub-tasks and execute them simultaneously across the cores. As a result, complex computations can be completed faster, reducing overall processing time. The ability to parallelize tasks is particularly beneficial for industries such as scientific research, engineering, and financial modeling that rely on computationally intensive operations.
Multi-Threaded Applications
The high core count of the Intel Xeon Gold 5218 Processor also benefits multi-threaded applications. These applications are designed to split their workload into multiple threads that can be executed independently. With 16 cores, the processor can handle a larger number of threads simultaneously, resulting in improved performance for applications that support multi-threading. This is particularly advantageous for tasks such as video editing, 3D rendering, and compiling code.
Virtualization
Virtualization is another area where the 16-core count shines. Virtual machines (VMs) allow users to run multiple operating systems and applications on a single physical server. Each VM requires dedicated resources, including CPU cores. With 16 cores, the Intel Xeon Gold 5218 Processor can support a higher number of VMs without sacrificing performance. This enables businesses to consolidate their IT infrastructure, reduce hardware costs, and improve overall system efficiency.
Base Clock Speed: 2.3GHz
Fast and Responsive Performance
The base clock speed of 2.3GHz in the Intel Xeon Gold 5218 Processor ensures fast and responsive performance across various applications and workloads. The base clock speed represents the frequency at which the processor operates under normal conditions. Higher clock speeds result in faster execution of instructions, leading to quicker task completion and improved overall system responsiveness.
Single-Threaded Performance
The base clock speed plays a crucial role in single-threaded performance. Single-threaded applications rely on a single core to execute tasks sequentially. With a higher base clock speed of 2.3GHz, the Intel Xeon Gold 5218 Processor can handle single-threaded tasks more efficiently and deliver faster results. This is beneficial for applications that are not well-optimized for multi-threading or for tasks that cannot be parallelized effectively.
Boosting Capabilities
In addition to the base clock speed, the Intel Xeon Gold 5218 Processor also features Intel Turbo Boost Technology, which dynamically increases the clock speed when additional performance is required. This intelligent technology automatically detects workload demands and adjusts the clock speed accordingly, providing an extra burst of performance when needed. This ensures that even resource-intensive tasks can be completed swiftly, maximizing productivity and reducing waiting times.
Overclocking Potential
For users who seek even higher performance levels, the base clock speed of 2.3GHz offers a solid foundation for overclocking. Overclocking involves manually increasing the clock speed beyond the default specifications to achieve higher performance. With the Intel Xeon Gold 5218 Processor's base clock speed of 2.3GHz, users can potentially achieve significant performance gains through overclocking while maintaining stability and reliability.
Smart Cache: 22MB
Improved Data Access
The Intel Xeon Gold 5218 Processor comes equipped with a generous 22MB of Smart Cache, which enhances data access and retrieval speeds. Smart Cache is a shared memory pool that stores frequently accessed data closer to the processor cores, reducing the time required to fetch information from the main memory. With 22MB of Smart Cache, the processor can hold a larger amount of data within reach, resulting in faster execution of instructions and improved overall system performance.
Reduced Memory Latency
The larger Smart Cache size of 22MB in the Intel Xeon Gold 5218 Processor helps reduce memory latency. Memory latency refers to the time it takes for the processor to access data stored in the main memory. By storing frequently accessed data in the Smart Cache, the processor can bypass the slower main memory, significantly reducing latency and improving overall system responsiveness. This is particularly beneficial for applications that rely heavily on data retrieval, such as database management systems and content delivery networks.
Multi-Core Efficiency
The Smart Cache's 22MB size also enhances multi-core efficiency. With multiple cores simultaneously accessing and executing instructions, efficient data sharing becomes crucial. The Smart Cache acts as a central repository for frequently accessed data that can be shared among the cores, eliminating the need for redundant data transfers between cores and reducing inter-core communication overhead. This results in improved parallel processing performance and better utilization of each core's processing power.
Improved Gaming Performance
The Smart Cache's larger size has a positive impact on gaming performance as well. Modern games rely on fast data access to load textures, models, and other game assets quickly. With 22MB of Smart Cache, the Intel Xeon Gold 5218 Processor can store a significant amount of frequently accessed game data, reducing load times and ensuring smooth gameplay. Gamers can enjoy immersive gaming experiences with minimal lag and interruptions.
Upi Speed: 10.4GT/S
Enhanced Interconnectivity
The Upi Speed of 10.4GT/s in the Intel Xeon Gold 5218 Processor provides enhanced interconnectivity between multiple processors and other system components. Upi stands for "Ultra Path Interconnect," which is Intel's high-speed interconnect technology designed to facilitate communication between processors in multi-socket systems. With a Upi Speed of 10.4GT/s, the processor can quickly exchange data and synchronize operations with other processors, enabling efficient parallel processing and improved system scalability.
Scalability and Flexibility
The high Upi Speed of 10.4GT/s allows the Intel Xeon Gold 5218 Processor to scale effectively in multi-processor configurations. In systems with multiple processors, each processor can work on a separate task simultaneously, leading to faster computation and increased system throughput. This scalability is essential for applications that require high-performance computing, such as scientific simulations, data analytics, and rendering farms. The Upi Speed ensures that each processor can communicate efficiently, maximizing the benefits of a multi-processor setup.
System Responsiveness
Efficient interconnectivity provided by the Upi Speed has a direct impact on overall system responsiveness. With faster data exchange between processors, tasks can be distributed more effectively, reducing processing bottlenecks and improving overall system performance. This is particularly important for applications that rely on inter-processor communication, such as distributed computing or real-time data processing. The high Upi Speed ensures that data can be shared seamlessly, enabling smooth and responsive operation even under heavy workloads.
Improved Memory Bandwidth
The Upi Speed also has a positive impact on memory bandwidth. Memory bandwidth refers to the rate at which data can be read from or written to the memory. With a faster Upi Speed, the Intel Xeon Gold 5218 Processor can transfer data to and from the memory more quickly, resulting in improved memory performance. This is particularly beneficial for memory-intensive applications, such as in-memory databases, virtualization, and high-performance computing, where fast memory access is crucial for achieving optimal performance.
Socket Type: FCLGA3647
Compatibility and Upgradability
The Intel Xeon Gold 5218 Processor features the FCLGA3647 socket type, which ensures compatibility with compatible motherboards. The socket type defines the physical interface between the processor and the motherboard, allowing for easy installation and integration into existing systems. The FCLGA3647 socket type is widely supported by server-grade motherboards, providing users with a diverse range of options when it comes to choosing a compatible platform. This ensures that users can seamlessly upgrade their systems without the need for significant hardware changes.
Server-Grade Performance
The FCLGA3647 socket type is primarily designed for server-grade processors like the Intel Xeon Gold 5218. This socket type supports high-performance features and technologies required for demanding server workloads. By utilizing a server-grade socket, users can harness the full potential of the processor and leverage its advanced capabilities, such as ECC memory support, multi-socket configurations, and enterprise-level reliability. The FCLGA3647 socket type ensures that users can build robust and scalable server systems that meet their specific requirements.
Future-Proofing
Opting for a processor with the FCLGA3647 socket type offers future-proofing benefits. As technology evolves, new processors are released with improved performance and features. By choosing a motherboard with the FCLGA3647 socket, users can easily upgrade to newer processors without replacing the entire system. This saves both time and money, allowing users to stay up to date with the latest advancements in processing power without the need for a complete system overhaul. The FCLGA3647 socket type ensures long-term compatibility and investment protection.
Enterprise-Grade Reliability
The FCLGA3647 socket type is synonymous with enterprise-grade reliability. Server systems built using this socket type are known for their stability, durability, and high availability. The FCLGA3647 socket supports features such as error-correcting code (ECC) memory, which detects and corrects memory errors in real-time, ensuring data integrity and system stability. Additionally, the FCLGA3647 socket type is designed to handle the demands of continuous operation in mission-critical environments, making it an ideal choice for enterprise applications, data centers, and other business-critical workloads.
Manufacturing Technology: 14NM
Improved Efficiency
The Intel Xeon Gold 5218 Processor is fabricated using a 14nm manufacturing technology, which offers improved efficiency compared to older manufacturing processes. The manufacturing technology refers to the size of transistors and other components on the processor chip. Smaller transistors allow for more transistors to be packed onto the chip, resulting in increased processing power and reduced power consumption.
Higher Performance
The 14nm manufacturing technology enables the Intel Xeon Gold 5218 Processor to deliver higher performance levels. With smaller transistors, signals can travel shorter distances, resulting in reduced latency and faster overall performance. Additionally, the smaller size allows for higher clock speeds and improved power delivery, boosting the processor's capabilities for demanding workloads and resource-intensive applications.
Lower Power Consumption
The 14nm manufacturing technology also contributes to lower power consumption. Smaller transistors require less power to switch on and off, resulting in reduced energy consumption. This leads to improved energy efficiency and reduced heat generation, which is particularly important for server environments where power consumption and cooling costs can be significant. The Intel Xeon Gold 5218 Processor's 14nm manufacturing technology ensures optimal performance while keeping power consumption in check.
Heat Dissipation
The smaller components in the 14nm manufacturing technology enable better heat dissipation. As transistors become smaller, they generate less heat during operation. This allows for more efficient cooling solutions and helps maintain optimal operating temperatures even under heavy workloads. Effective heat dissipation is crucial for system stability and longevity, as excessive heat can cause performance degradation and potentially damage components. The 14nm manufacturing technology ensures that the Intel Xeon Gold 5218 Processor can operate reliably even in demanding environments.
Power Consumption: 125W
Efficient Power Management
The Intel Xeon Gold 5218 Processor has a power consumption rating of 125W, which reflects its efficient power management capabilities. Power consumption refers to the amount of electrical power consumed by the processor during operation. With a power consumption rating of 125W, the processor strikes a balance between performance and energy efficiency, ensuring optimal system operation while minimizing power wastage.
Reduced Operational Costs
The efficient power management of the Intel Xeon Gold 5218 Processor translates into reduced operational costs. Lower power consumption results in lower electricity bills, making it an attractive choice for businesses that require multiple servers running around the clock. Additionally, the reduced power consumption leads to less heat generation, requiring less cooling infrastructure. This further contributes to cost savings, as cooling systems can be more energy-efficient and require less maintenance.
Environmental Impact
The Intel Xeon Gold 5218 Processor's power consumption rating of 125W reflects its commitment to environmental sustainability. By consuming less power, the processor helps reduce greenhouse gas emissions and minimizes the carbon footprint associated with data centers and server farms. The lower power consumption also aligns with energy efficiency initiatives and regulations, making the processor an environmentally responsible choice for organizations aiming to reduce their environmental impact.
Thermal Design Power (TDP)
The 125W power consumption rating represents the Thermal Design Power (TDP) of the Intel Xeon Gold 5218 Processor. TDP is a measure of the maximum amount of heat generated by the processor that the cooling system needs to dissipate. A lower TDP value indicates more efficient power management and lower heat generation. The 125W TDP of the Intel Xeon Gold 5218 Processor ensures that it can operate reliably within specified thermal limits, providing stable performance without compromising system integrity.