HP 832739-B21 Intel Xeon E5-2667V4 8-Core 3.2GHz 25MB L3 Cache 9.6GT/S QPI Speed Socket FCLGA 2011 135W 14NM Processor for HP XL7X0F Gen9 Server

Core Count: Eight Cores for High-performance Computing

The HP Intel Xeon E5-2667V4 Processor features an impressive core count of 8, making it an ideal choice for users looking for high-performance computing capabilities. With eight cores, this processor can handle a wide range of demanding tasks, from complex calculations to intensive multitasking.

Improved Multithreading

One of the major benefits of having eight cores is improved multithreading capabilities. Multithreading allows the processor to execute multiple tasks simultaneously, improving overall system performance. With eight cores, the HP Intel Xeon E5-2667V4 Processor can handle more threads at once, resulting in faster and more efficient processing.

Enhanced Workload Distribution

The eight cores in this processor enable efficient workload distribution across multiple threads. Each core can handle a specific task, ensuring that the workload is evenly distributed and minimizing processing bottlenecks. This feature is particularly useful for users working with resource-intensive applications or running multiple virtual machines.

Optimized Performance for Multitasking

The high core count of the HP Intel Xeon E5-2667V4 Processor allows for smooth multitasking capabilities. Users can run multiple applications simultaneously without experiencing significant slowdowns or performance issues. This is particularly beneficial for professionals working on complex projects that require running multiple software tools simultaneously.

Improved Gaming Performance

Gamers can also benefit from the eight-core configuration of this processor. Many modern games are designed to take advantage of multiple cores to deliver smoother gameplay and improved graphics. With eight cores, users can enjoy a more immersive gaming experience with higher frame rates and better overall performance.

Efficient Video Editing and Rendering

Video editing and rendering tasks can be extremely demanding on computer hardware. The eight cores of the HP Intel Xeon E5-2667V4 Processor allow for faster video editing and rendering, reducing the time required to process and export high-resolution videos. This is particularly advantageous for professionals working in the film or media industry.

Improved Data Analysis

Data analysis tasks, such as statistical modeling or simulations, can benefit greatly from the high core count of this processor. With eight cores, users can process large datasets more efficiently, leading to faster and more accurate results. This is crucial for researchers, scientists, and businesses that rely on data-driven decision-making.

Seamless Virtualization

The HP Intel Xeon E5-2667V4 Processor's eight cores make it an excellent choice for virtualization. Virtualization allows users to create multiple virtual machines on a single physical machine, enabling more efficient resource utilization. With eight cores, users can run multiple virtual machines simultaneously without sacrificing performance.

Base Clock Speed: 3.2GHz for Smooth Performance

The HP Intel Xeon E5-2667V4 Processor boasts a base clock speed of 3.2GHz, ensuring smooth and responsive performance across a wide range of applications and tasks. The base clock speed represents the frequency at which the processor operates under normal conditions.

Efficient Task Execution

The 3.2GHz base clock speed enables the processor to execute tasks quickly and efficiently. Whether you're browsing the web, working on documents, or running resource-intensive applications, the high base clock speed ensures a smooth user experience without noticeable delays or lags.

Improved Single-Core Performance

A higher base clock speed translates into improved single-core performance. Single-core performance is crucial for tasks that cannot be efficiently parallelized across multiple cores. Applications that rely heavily on single-core performance, such as certain games or software tools, will benefit from the 3.2GHz base clock speed of this processor.

Fast Startup and Responsiveness

The 3.2GHz base clock speed contributes to faster system startup times and overall responsiveness. With a higher base clock speed, the processor can quickly handle the initial tasks required to boot up the system, allowing users to get to work or start gaming without unnecessary delays.

Smooth Gaming Experience

Gamers can enjoy a smoother gaming experience with the 3.2GHz base clock speed. Many games rely on single-core performance for tasks such as physics calculations or AI processing. The high base clock speed ensures that these tasks are executed quickly, resulting in better frame rates and improved gameplay.

Efficient Content Creation

Content creators, such as graphic designers or video editors, can benefit from the 3.2GHz base clock speed when working with resource-intensive software tools. These tools often require significant processing power to handle complex tasks like rendering or applying effects. The high base clock speed enables faster processing, reducing waiting times and improving productivity.

Improved Productivity

The fast startup and responsiveness provided by the 3.2GHz base clock speed contribute to improved productivity. Users can launch applications quickly and switch between tasks seamlessly, minimizing downtime and allowing for efficient multitasking.

Smooth Multimedia Playback

The high base clock speed ensures smooth playback of multimedia content such as high-definition videos or music streaming. Users can enjoy high-quality media without stuttering or buffering issues, enhancing the entertainment experience.

L3 Cache: 25MB for Enhanced Performance

The HP Intel Xeon E5-2667V4 Processor features a generous L3 cache size of 25MB, which plays a crucial role in enhancing overall performance. The L3 cache serves as a high-speed storage area that stores frequently accessed data, allowing the processor to access it quickly.

Improved Data Access Speed

The large 25MB L3 cache enables faster data access by reducing the time required to fetch information from the main memory. When the processor needs to access data, it first checks the L3 cache. If the data is present in the cache, it can be retrieved much faster than if it had to be fetched from the main memory. This results in improved performance and reduced latency.

Efficient Program Execution

The L3 cache plays a crucial role in improving program execution. As the processor executes instructions, it stores frequently accessed data in the cache, reducing the need to fetch it from the main memory repeatedly. This significantly speeds up program execution and enhances overall system performance.

Seamless Multitasking

The large L3 cache size allows for seamless multitasking capabilities. When running multiple applications simultaneously, each application can utilize a portion of the L3 cache for storing frequently accessed data. This ensures efficient data sharing between applications and minimizes performance bottlenecks.

Smooth Gaming Performance

Gamers can benefit from the 25MB L3 cache size when playing demanding games that require quick access to textures, models, and other game assets. The large cache size ensures that these assets are readily available, improving game loading times and reducing in-game stutters or delays.

Faster Rendering and Compilation

Content creators, such as video editors or software developers, can take advantage of the 25MB L3 cache size for faster rendering and compilation times. These tasks often involve accessing large amounts of data, and the large cache size reduces the time required to fetch this data, resulting in faster processing.

Improved Database Performance

The large L3 cache size is particularly beneficial for database systems that handle significant amounts of data. Databases often rely on frequent data access, and the large cache size allows for faster retrieval of commonly accessed data, improving overall database performance.

Enhanced Virtual Machine Performance

Virtualization environments can benefit from the 25MB L3 cache size when running multiple virtual machines simultaneously. Each virtual machine can utilize a portion of the cache for storing frequently accessed data, improving overall performance and reducing latency.

QPI Speed: 9.6GT/S for High-Speed Data Transfer

The HP Intel Xeon E5-2667V4 Processor boasts a QPI (Quick Path Interconnect) speed of 9.6GT/S, facilitating high-speed data transfer between the processor and other system components. The QPI speed represents the bandwidth at which data can be transferred between the processor and other connected devices.

Reduced Data Bottlenecks

The high QPI speed of 9.6GT/S ensures that data transfer between the processor and other system components is efficient and fast. This reduces potential bottlenecks that could slow down overall system performance, particularly when transferring large amounts of data or performing memory-intensive tasks.

Improved System Responsiveness

The fast QPI speed contributes to improved system responsiveness. As data is quickly transferred between the processor and other system components, tasks can be executed more efficiently, resulting in a smoother user experience without noticeable delays or lags.

Enhanced Memory Performance

The QPI speed directly affects memory performance, as it determines how quickly data can be transferred to and from the memory modules. With a QPI speed of 9.6GT/S, the processor can efficiently access and retrieve data from the memory, reducing latency and improving overall system performance.

Seamless Gaming Experience

Gamers can benefit from the high QPI speed when playing demanding games that rely on quick data transfers between the processor and the graphics card. The fast data transfer ensures that game assets are loaded quickly, reducing loading times and improving overall gaming performance.

Faster Data Analysis

Data analysis tasks, such as statistical modeling or simulations, can benefit greatly from the high QPI speed. With faster data transfer rates, the processor can quickly access and process large datasets, reducing the time required for complex calculations and analysis.

Enhanced Virtualization Performance

Virtualization environments can take advantage of the high QPI speed when transferring data between virtual machines and the underlying hardware. The fast data transfer rate ensures efficient communication and reduces latency, improving overall virtualization performance.

Efficient File Transfers

The high QPI speed enables faster file transfers between storage devices and the processor. Whether copying large files or transferring data between external devices, the fast data transfer rate ensures quick and efficient file transfers, saving time and improving productivity.

Socket Type: FCLGA 2011 for Compatibility

The HP Intel Xeon E5-2667V4 Processor features a socket type of FCLGA 2011, ensuring compatibility with compatible motherboards. The socket type refers to the physical interface between the processor and the motherboard, allowing for proper installation and communication.

Wide Motherboard Compatibility

The FCLGA 2011 socket type ensures compatibility with a wide range of motherboards that support this socket. Users can choose from various motherboard options, depending on their specific requirements and preferences, without worrying about compatibility issues.

Future-Proofing

Investing in a processor with a widely supported socket type like FCLGA 2011 helps future-proof your system. As new motherboard models are released, users can easily upgrade their system by replacing the motherboard while keeping the processor intact. This allows for cost-effective upgrades without the need to replace the entire system.

Upgrade Flexibility

The FCLGA 2011 socket type provides users with the flexibility to upgrade their system in the future. If more powerful processors become available in the same socket type, users can simply replace their current processor with a newer model, enhancing system performance without significant changes to other components.

Customization Options

The FCLGA 2011 socket type allows users to customize their system according to their specific needs. Users can choose a motherboard that offers the desired features, such as multiple expansion slots, advanced connectivity options, or support for overclocking. This customization ensures that the system meets individual requirements and preferences.

Easier Troubleshooting and Maintenance

The widely supported FCLGA 2011 socket type simplifies troubleshooting and maintenance tasks. If issues arise with the motherboard, users can easily replace it without affecting the processor. This reduces downtime and allows for faster resolution of hardware problems.

Support for Multiple Processors

The FCLGA 2011 socket type also supports multiple processors in a single system. Users requiring higher processing power can install multiple compatible processors, allowing for parallel processing and improved system performance.

Scalability for Server Systems

The FCLGA 2011 socket type is commonly used in server systems due to its scalability. Server systems often require multiple processors to handle heavy workloads and high-demand applications. The FCLGA 2011 socket type allows for easy expansion and scalability, ensuring that the system can grow alongside increasing demands.

Power Consumption: 135W for Energy Efficiency

The HP Intel Xeon E5-2667V4 Processor has a power consumption of 135W, offering a balance between performance and energy efficiency. Power consumption refers to the amount of electrical power required by the processor to operate under normal conditions.

Energy Efficiency

The 135W power consumption of this processor ensures energy efficiency without compromising on performance. By consuming less power, users can reduce their electricity bills and contribute to a more sustainable environment. The processor's energy-efficient design allows for longer battery life in mobile devices or lower power consumption in desktop systems.

Cooler Operation

The lower power consumption of 135W results in cooler operation, reducing the need for excessive cooling mechanisms and minimizing noise levels. Cooler operation also contributes to the longevity of the processor by reducing heat-related stress, enhancing overall system reliability.

Reduced Environmental Impact

The energy-efficient design of the HP Intel Xeon E5-2667V4 Processor helps reduce its environmental impact. By consuming less power, the processor reduces carbon emissions and helps conserve natural resources. This makes it an ideal choice for users who prioritize sustainability and want to minimize their ecological footprint.

Lower Operating Costs

The lower power consumption translates into lower operating costs for businesses and individuals. By using a processor with a power consumption of 135W, users can save on electricity bills, especially in systems that run continuously or in large-scale server environments.

Efficient Cooling Solutions

The reduced power consumption allows for more efficient cooling solutions. Cooling systems, such as fans or liquid cooling setups, can operate at lower speeds or with less power, resulting in quieter operation and reduced energy consumption for cooling purposes.

Longer Battery Life

The energy-efficient design of the HP Intel Xeon E5-2667V4 Processor contributes to longer battery life in mobile devices, such as laptops or tablets. With lower power consumption, users can enjoy extended usage time without having to recharge their devices frequently.

Environmentally Friendly Computing

Choosing a processor with a power consumption of 135W aligns with environmentally friendly computing practices. By reducing energy consumption, users can contribute to sustainability efforts and help minimize the carbon footprint associated with computing activities.

Manufacturing Technology: 14NM for Enhanced Performance and Efficiency

The HP Intel Xeon E5-2667V4 Processor is manufactured using a 14nm (nanometer) process technology. The manufacturing technology represents the size of the smallest feature that can be created on the processor's silicon die. A smaller manufacturing technology offers several benefits, including improved performance and energy efficiency.

Increased Transistor Density

The 14nm manufacturing technology allows for increased transistor density on the processor's silicon die. Transistors are the building blocks of modern processors, and a higher density means more transistors can be packed into a smaller area. This results in improved performance as more transistors are available for processing tasks.

Improved Power Efficiency

The smaller 14nm manufacturing technology enables improved power efficiency compared to larger manufacturing processes. With smaller transistors