HP 873378-B21 Xeon Gold 6136 12-Core Processor 3.0GHz 24.75MB L3 Cache

Core Count: 12

The HP Xeon Gold 6136 Processor is equipped with an impressive core count of 12. This means that it has 12 individual processing units, allowing it to handle multiple tasks simultaneously. The high number of cores is especially beneficial for users who require a high-performance processor for demanding applications such as data analysis, virtualization, and content creation.

Improved Multitasking

With 12 cores, the HP Xeon Gold 6136 Processor excels at multitasking. Each core can handle its own set of instructions and perform calculations independently of the others. This enables users to run multiple applications simultaneously without experiencing any slowdowns or performance bottlenecks. Whether you're editing videos while running complex simulations or managing a large database while compiling code, the processor's 12 cores ensure smooth and efficient multitasking.

Enhanced Performance

More cores translate to better performance. The HP Xeon Gold 6136 Processor's 12 cores allow it to execute instructions in parallel, significantly improving overall processing power. This is particularly advantageous for tasks that can be divided into smaller, independent units, such as rendering complex graphics or running simulations. With the ability to distribute the workload across multiple cores, the processor can complete tasks faster and deliver superior performance compared to processors with fewer cores.

Optimized Virtualization

Virtualization is a key feature for many businesses and organizations that rely on server infrastructure. The 12 cores of the HP Xeon Gold 6136 Processor enable efficient virtualization by allowing multiple virtual machines (VMs) to run simultaneously without compromising performance. Each core can be assigned to a specific VM, ensuring that resources are allocated effectively and maximizing overall system utilization. This makes the processor an ideal choice for virtualized environments where scalability, flexibility, and performance are crucial.

Future-Proofing

Investing in a processor with a high core count like the HP Xeon Gold 6136 ensures future-proofing your system. As software and applications become increasingly multithreaded, more cores will be utilized to achieve optimal performance. By choosing a processor with 12 cores, you can be confident that your system will be able to handle future software advancements and maintain its efficiency and responsiveness.

Efficient Resource Utilization

With 12 cores, the HP Xeon Gold 6136 Processor excels at distributing workloads evenly, ensuring efficient resource utilization. This is particularly important in environments where multiple users or applications are competing for resources. The processor's ability to divide tasks across cores allows for better resource allocation, preventing bottlenecks and ensuring that each task receives the necessary processing power.

Base Clock Speed: 3.0GHz

The HP Xeon Gold 6136 Processor boasts a base clock speed of 3.0GHz. The base clock speed represents the minimum frequency at which the processor operates when running at its default settings. This feature plays a crucial role in determining the overall performance and responsiveness of the processor.

Faster Single-Threaded Performance

The high base clock speed of 3.0GHz ensures faster single-threaded performance for applications that rely on a single core. Tasks such as web browsing, word processing, and email management benefit from higher clock speeds as they typically utilize only one core. The increased frequency allows these applications to execute instructions faster, resulting in snappier response times and smoother user experiences.

Improved Responsiveness

A higher base clock speed enhances the overall responsiveness of the system. When launching applications or performing basic tasks, the processor's ability to swiftly process instructions at its base clock speed ensures minimal delays and lag. This is particularly noticeable when loading large files, opening software, or switching between multiple applications. The HP Xeon Gold 6136 Processor's 3.0GHz base clock speed ensures that your system remains responsive and can handle demanding tasks without slowdowns.

Efficient Workload Distribution

The base clock speed also plays a role in workload distribution across the processor's cores. A higher base clock speed allows for better load balancing, ensuring that tasks are efficiently distributed across the available cores. This results in improved overall system performance and prevents individual cores from becoming overwhelmed or underutilized.

Overclocking Potential

For users who are interested in pushing the performance boundaries of their system, a higher base clock speed provides a solid foundation for overclocking. Overclocking involves increasing the clock speed of the processor beyond its default settings to achieve even greater performance. With a base clock speed of 3.0GHz, the HP Xeon Gold 6136 Processor offers potential for overclocking enthusiasts to further boost their system's capabilities.

Energy Efficiency

Despite its high base clock speed, the HP Xeon Gold 6136 Processor remains energy-efficient. The processor is designed to dynamically adjust its clock speed based on workload demands, reducing power consumption during periods of low activity. This ensures that energy is utilized efficiently, resulting in a more environmentally friendly and cost-effective system.

L3 Cache: 24.75MB

The HP Xeon Gold 6136 Processor comes equipped with a generous L3 cache size of 24.75MB. The L3 cache acts as a high-speed storage area that stores frequently accessed data and instructions, providing quick access to vital information for the processor.

Improved Data Access Speed

The larger L3 cache size of 24.75MB allows for faster data access speeds. When the processor needs to access data or instructions, it first checks the L3 cache. With a larger cache size, there is a higher probability that the required information is already stored in the cache, eliminating the need to retrieve it from slower system memory or storage. This leads to reduced latency and improved overall system performance.

Enhanced Multitasking Performance

The generous L3 cache size of the HP Xeon Gold 6136 Processor enables better multitasking performance. With more cache available, the processor can store and retrieve data from multiple applications simultaneously, without experiencing significant performance degradation. This is particularly beneficial for users who frequently switch between resource-intensive tasks or run multiple applications concurrently.

Efficient Workload Distribution

The larger L3 cache size also facilitates efficient workload distribution across the processor's cores. When multiple cores are working on different tasks, they can share data and instructions stored in the L3 cache, reducing the need for frequent communication with slower memory or storage resources. This results in smoother task execution and improved overall system efficiency.

Improved Gaming Performance

Gamers can benefit from the larger L3 cache size of the HP Xeon Gold 6136 Processor as well. Many modern games rely on quick access to game assets and instructions, which are stored in memory or storage devices. With a larger cache size, the processor can store more frequently accessed game data, reducing load times and improving in-game performance. Gamers will experience faster level loading, smoother gameplay, and reduced stuttering or frame rate drops.

High-Performance Computing

High-performance computing (HPC) applications often require large amounts of data to be processed quickly. The generous L3 cache size of 24.75MB on the HP Xeon Gold 6136 Processor allows for efficient processing of large datasets, enabling faster simulations, data analysis, and scientific computations. The processor's ability to store and retrieve frequently accessed data from the cache enhances the overall performance of HPC applications, leading to faster results and increased productivity.

Upi Speed: 10.4GT/s

The HP Xeon Gold 6136 Processor features a Upi (Ultra Path Interconnect) speed of 10.4GT/s. Upi is a high-speed interconnect technology that enables fast communication between processors, allowing for efficient data transfer and synchronization.

Improved Scalability

The high Upi speed of 10.4GT/s enhances the scalability of systems using multiple processors. In multi-socket configurations, where multiple processors work together to handle demanding workloads, efficient communication between processors is crucial. The fast Upi speed ensures that data can be exchanged quickly, minimizing latency and ensuring that all processors in the system work in harmony. This results in improved overall system performance and responsiveness.

Enhanced Data Sharing

The fast Upi speed also facilitates efficient data sharing between processors. In scenarios where different processors need to access shared data, such as in distributed computing or server environments, the high Upi speed allows for rapid data transmission. This enables faster collaboration and synchronization between processors, ensuring that the data remains consistent across all nodes and minimizing delays in data-intensive operations.

Optimized Cluster Computing

Cluster computing, where multiple computers work together as a single system, relies on fast interconnects to achieve efficient communication between nodes. The HP Xeon Gold 6136 Processor's Upi speed of 10.4GT/s ensures rapid data transfer between processors within the cluster, enabling seamless collaboration and resource sharing. This makes the processor an excellent choice for cluster computing environments that require high-performance interconnectivity.

Improved Virtualization Performance

Virtualized environments can also benefit from the fast Upi speed of the HP Xeon Gold 6136 Processor. In virtualized systems, where multiple virtual machines (VMs) run on a single physical server, efficient communication between processors is crucial for optimal performance. The high Upi speed allows for fast data transfer between processors, facilitating smooth operation and minimizing performance bottlenecks. This ensures that each VM receives the necessary processing power and resources, resulting in improved overall virtualization performance.

Reduced Network Congestion

The fast Upi speed helps reduce network congestion in systems where multiple processors communicate with each other. By quickly exchanging data through the Upi interface, processors can offload some of the communication burden from the network infrastructure. This results in more efficient data transfer within the system and reduces the strain on external network connections, leading to improved overall system performance and reduced latency.

Socket Type: FCLGA3647

The HP Xeon Gold 6136 Processor is designed to fit into a socket with the FCLGA3647 (Flip-Chip Land Grid Array) form factor. The socket type is an important consideration when selecting a processor as it determines compatibility with the motherboard and affects system performance and expandability.

Compatibility and Upgradability

The FCLGA3647 socket type ensures compatibility with motherboards specifically designed to support this socket. By choosing a processor with this socket type, users can be confident that it will fit seamlessly into their existing system or selected motherboard. Additionally, the FCLGA3647 socket type allows for easy processor upgrades in the future. As technology advances and new processors are released, users can simply replace their existing processor with a compatible FCLGA3647 model without needing to invest in a new motherboard.

Robust Power Delivery

The FCLGA3647 socket type supports a robust power delivery system, ensuring that the processor receives a stable and consistent power supply. This is crucial for maintaining optimal performance and preventing instability or crashes. The socket's design allows for efficient power distribution, minimizing voltage fluctuations and ensuring that the processor operates within its specified power requirements. This results in reliable and consistent performance, even under heavy workloads.

Scalability and Expandability

The FCLGA3647 socket type offers excellent scalability and expandability options. It supports a wide range of processors, including high-performance models like the HP Xeon Gold 6136. This allows users to build systems that can be easily scaled up or expanded in the future by simply upgrading to a more powerful processor without needing to replace the entire motherboard. Whether you're building a workstation for content creation or a server for enterprise applications, the FCLGA3647 socket type provides the flexibility needed to accommodate future upgrades.

Reliable Connection

The FCLGA3647 socket type ensures a reliable connection between the processor and the motherboard. The socket's mechanical design provides secure connectivity, preventing accidental disconnections or poor contact that can lead to system instability or performance issues. The reliable connection ensures that data and instructions are transmitted accurately and efficiently, resulting in consistent performance and reducing the risk of errors or data corruption.

Industry Standard

The FCLGA3647 socket type is an industry-standard form factor used by many manufacturers, including HP. This means that users have access to a wide range of compatible motherboards and system components from various vendors, ensuring greater flexibility when building or upgrading their systems. The industry standard also ensures better long-term support and availability of compatible components, making it easier to find replacement parts or upgrade options in the future.

Manufacturing Technology: 14NM

The HP Xeon Gold 6136 Processor is manufactured using a 14nm (nanometer) process technology. The manufacturing technology plays a significant role in determining the processor's power efficiency, performance, and thermal characteristics.

Power Efficiency

The 14nm manufacturing technology used in the HP Xeon Gold 6136 Processor offers excellent power efficiency. Smaller transistors and components result in reduced power consumption, allowing the processor to deliver high performance while minimizing energy usage. This is particularly important for systems that require high computational power but have strict power constraints or are designed for energy-conscious environments. The processor's power efficiency helps reduce electricity costs and contributes to a greener, more sustainable computing environment.

Improved Thermal Performance

The 14nm manufacturing technology also enhances the processor's thermal performance. By shrinking the size of transistors and components, heat generation is minimized, resulting in lower operating temperatures. This allows for better heat dissipation and improved cooling efficiency, ensuring that the processor remains within safe temperature limits even during heavy workloads. The improved thermal performance contributes to system stability, longevity, and overall reliability.

Higher Clock Speeds

The smaller transistor size made possible by the 14nm manufacturing technology enables higher clock speeds. With reduced electrical resistance and improved transistor switching speed, the HP Xeon Gold 6136 Processor can achieve higher frequencies without compromising stability or increasing power consumption excessively. Higher clock speeds translate to faster processing times and improved overall system performance, making the processor well-suited for demanding applications that require quick execution of instructions.

Increased Transistor Density

The 14nm manufacturing technology allows for increased transistor density on the processor die. This means that more transistors can be packed into a smaller area, resulting in greater computational power within the same physical space. The increased transistor density enables more complex processing capabilities and improved overall performance without the need for larger, more power-hungry processors. This makes the HP Xeon Gold 6136 Processor an efficient choice for users who require high computational power in a compact form factor.

Compatibility and Availability

The 14nm manufacturing technology is widely adopted across the industry, ensuring compatibility with a wide range of system components and software. Users can be confident that the HP Xeon Gold 6136 Processor will work seamlessly with other compatible hardware and software solutions. Additionally, the widespread use of 14nm manufacturing technology ensures better availability of processors and related components, making it easier to find replacement parts or upgrade options in the future.

Power Consumption: 150W

The HP Xeon Gold 6136 Processor has a maximum power consumption of 150W. Power consumption is an important consideration when selecting a processor as it affects energy usage, heat generation, and system stability.

Energy Efficiency

Despite its high performance, the HP Xeon Gold 6136 Processor remains energy-efficient. The processor is designed to deliver exceptional performance while minimizing power consumption. This is achieved through the use of advanced power management technologies that dynamically adjust the processor's clock speed, voltage, and other parameters based on workload demands. By optimizing power consumption, the processor helps reduce electricity costs and contributes to a more environmentally friendly computing environment.

Cooler Operation

The 150W power consumption of the HP Xeon Gold 6136 Processor ensures cooler operation compared to processors with higher power requirements. The lower power consumption results in reduced heat generation, allowing for more efficient cooling. This is particularly important for systems that operate in environments with limited airflow or have strict thermal constraints. The cooler operation contributes to system stability and longevity by keeping temperatures within safe limits.

Compatibility with Power Supplies

The 150W power consumption of the HP Xeon Gold 6136 Processor ensures compatibility with a wide range of power supply units (PSUs). Most standard ATX power supplies are capable of delivering sufficient power to support the processor's requirements. This