Intel Xeon E5-2630V4 CM8066002032301 2.2GHz 25MB L3 8gt/S QPI FCLGA2011 85W 14NM Processor

Clock Speed

The Intel Xeon E5-2630V4 Processor is designed to provide high-performance computing for servers and workstations. One of its key features is its clock speed of 2.2GHz. Clock speed refers to the number of cycles the processor can execute per second. A higher clock speed means that the processor can perform more calculations and complete tasks faster.

Improved Performance

With a clock speed of 2.2GHz, the Intel Xeon E5-2630V4 Processor delivers exceptional performance for demanding applications. Whether you are running complex simulations, performing data analysis, or running virtual machines, the high clock speed ensures that tasks are completed quickly and efficiently.

Enhanced Multitasking

The high clock speed of the Intel Xeon E5-2630V4 Processor allows for efficient multitasking. With multiple cores and threads, the processor can handle multiple tasks simultaneously without sacrificing performance. This is particularly important for servers and workstations that need to handle multiple requests and processes at the same time.

Smooth Gaming Experience

Gamers can also benefit from the high clock speed of the Intel Xeon E5-2630V4 Processor. The faster the processor can process instructions, the smoother and more responsive games will be. Gamers will experience reduced lag and faster load times, allowing for an immersive gaming experience.

Overclocking Potential

If you're an advanced user or overclocking enthusiast, the high clock speed of the Intel Xeon E5-2630V4 Processor provides a solid foundation for pushing your system's performance even further. By increasing the clock speed beyond its base frequency, you can achieve even faster processing speeds and improved overall system performance.

Efficient Resource Utilization

The high clock speed of the Intel Xeon E5-2630V4 Processor also contributes to efficient resource utilization. By completing tasks quickly, the processor reduces idle time and ensures that resources are used efficiently. This is essential for maximizing productivity and minimizing costs in server and workstation environments.

Cache

The Intel Xeon E5-2630V4 Processor features a generous 25MB L3 cache. The cache is a small, high-speed memory that stores frequently accessed data for faster retrieval. The size of the cache can greatly impact the performance of the processor.

Improved Data Access

With a large 25MB L3 cache, the Intel Xeon E5-2630V4 Processor can store a significant amount of data that is frequently accessed by the CPU. This reduces the need to retrieve data from slower main memory, resulting in faster data access times. Applications that rely heavily on data access, such as databases and content delivery systems, will benefit greatly from the large cache size.

Reduced Memory Latency

The cache acts as a buffer between the CPU and main memory, reducing memory latency. Latency refers to the time it takes for data to be retrieved from memory. A larger cache means that more data can be stored closer to the CPU, reducing the time it takes to access that data. This results in faster overall system performance and improved responsiveness.

Improved Multi-threading Performance

The large cache size of the Intel Xeon E5-2630V4 Processor enhances its multi-threading performance. Multi-threading allows multiple threads to run simultaneously, improving overall system performance. With a larger cache, each thread has more space to store and retrieve data, reducing contention and improving efficiency.

Optimized Workstation Performance

Workstations that handle large datasets or perform complex calculations can greatly benefit from the large cache size. Tasks such as 3D rendering, video editing, and scientific simulations rely heavily on data access. The large cache of the Intel Xeon E5-2630V4 Processor ensures that these tasks can be completed efficiently, resulting in faster rendering times and smoother workflow.

Enhanced Virtualization Performance

Virtualization environments also benefit from the large cache size. Virtual machines often share resources, including CPU cache. With a larger cache, virtual machines can have more cache space dedicated to their specific tasks, reducing resource contention and improving overall performance.

Bus Speed

The Intel Xeon E5-2630V4 Processor features a high-speed 8gt/s QPI (Quick Path Interconnect) bus speed. The bus speed determines how quickly data can be transferred between the processor and other components in the system.

Faster Data Transfer

The 8gt/s QPI bus speed of the Intel Xeon E5-2630V4 Processor enables fast data transfer between the processor and other system components, such as memory and peripherals. This ensures that data can be moved quickly and efficiently, reducing bottlenecks and improving overall system performance.

Improved System Responsiveness

A high bus speed contributes to improved system responsiveness. With faster data transfer, operations that rely on frequent communication between the processor and other components, such as disk I/O or network communication, can be performed more quickly. This results in a more responsive system, with reduced latency and improved user experience.

Scalability and Expandability

The high bus speed of the Intel Xeon E5-2630V4 Processor allows for scalability and expandability. Servers and workstations that require high-performance computing often need to accommodate multiple processors or connect to external devices. The high bus speed enables efficient communication between multiple processors and peripherals, ensuring seamless scalability and expandability.

Optimized Data-Intensive Applications

Data-intensive applications, such as databases, big data analytics, and content delivery systems, greatly benefit from the high bus speed. These applications often involve transferring large amounts of data between the processor and memory or storage devices. The high bus speed ensures that data can be moved quickly, reducing processing time and improving overall application performance.

Reduced System Bottlenecks

The high bus speed of the Intel Xeon E5-2630V4 Processor helps to reduce system bottlenecks. Bottlenecks occur when the speed of data transfer becomes a limiting factor in system performance. By providing a fast and efficient bus speed, the processor ensures that data can flow smoothly between components, reducing or eliminating bottlenecks and maximizing system performance.

Socket Type

The Intel Xeon E5-2630V4 Processor is designed to fit the FCLGA2011 socket type. The socket type refers to the physical interface between the processor and the motherboard. It determines compatibility and plays a crucial role in system stability and performance.

Wide Compatibility

The FCLGA2011 socket type of the Intel Xeon E5-2630V4 Processor offers wide compatibility with motherboards that support this socket. This allows for easy integration into existing systems or the flexibility to choose from a variety of compatible motherboards when building a new system.

Robust Connection

The FCLGA2011 socket type provides a robust connection between the processor and the motherboard. The socket type ensures a secure and reliable connection, minimizing the risk of loose or unstable connections that can lead to system instability or performance issues.

Support for Advanced Features

The FCLGA2011 socket type supports advanced features and technologies that enhance system performance and functionality. This includes support for multiple memory channels, high-speed interfaces, and expansion slots. By choosing a processor with a compatible socket type, users can take full advantage of these advanced features.

Scalability and Upgradability

The FCLGA2011 socket type allows for scalability and upgradability. Servers and workstations that use this socket type can easily be upgraded to more powerful processors in the future without requiring a motherboard replacement. This provides flexibility and cost-effectiveness, allowing users to adapt their systems to changing requirements.

Stable and Reliable Performance

The FCLGA2011 socket type ensures stable and reliable performance. The secure connection between the processor and the motherboard minimizes the risk of data corruption or system instability. This is particularly important for critical applications or systems that require continuous operation without interruptions.

Power Consumption

The Intel Xeon E5-2630V4 Processor has a power consumption of 85W. Power consumption refers to the amount of electrical power the processor requires to operate at its specified performance levels.

Energy Efficiency

The 85W power consumption of the Intel Xeon E5-2630V4 Processor demonstrates its energy efficiency. Lower power consumption means that the processor consumes less electricity, resulting in reduced energy costs. It also contributes to a greener and more environmentally friendly computing environment.

Cooler Operation

A lower power consumption leads to cooler operation of the processor. Heat dissipation is a critical factor in maintaining system stability and longevity. By consuming less power, the processor generates less heat, reducing the strain on cooling systems and ensuring optimal operating temperatures.

Reduced Operating Costs

The Intel Xeon E5-2630V4 Processor's energy efficiency translates into reduced operating costs. By consuming less power, the processor contributes to lower electricity bills, particularly in large-scale server environments where multiple processors are deployed. This can result in significant cost savings over the lifespan of the system.

Sustainability and Environmental Impact

Choosing a processor with lower power consumption, such as the Intel Xeon E5-2630V4 Processor, helps to reduce environmental impact. Lower power consumption means fewer greenhouse gas emissions and a smaller carbon footprint. This is an important consideration for organizations committed to sustainability and reducing their environmental impact.

Optimized Power Budget Allocation

The 85W power consumption of the Intel Xeon E5-2630V4 Processor allows for optimized power budget allocation in server and workstation environments. It provides flexibility in designing power-efficient systems by allowing for more processors or allocating additional power to other components, such as storage or graphics cards.

Manufacturing Technology

The Intel Xeon E5-2630V4 Processor is manufactured using a 14nm process technology. The manufacturing technology refers to the size of the transistors and other components on the processor's chip. Smaller transistors offer several advantages in terms of performance, power efficiency, and cost-effectiveness.

Improved Performance per Watt

The 14nm manufacturing technology of the Intel Xeon E5-2630V4 Processor enables improved performance per watt. Smaller transistors consume less power and generate less heat, resulting in increased power efficiency. This translates into improved performance for a given power budget, allowing for more processing power without compromising energy efficiency.

Higher Clock Speeds

The smaller transistors made possible by the 14nm manufacturing technology allow for higher clock speeds. This is because smaller transistors can switch on and off faster, enabling faster processing speeds. The higher clock speeds of the Intel Xeon E5-2630V4 Processor contribute to its overall performance and responsiveness.

Reduced Cost per Transistor

Advancements in manufacturing technology, such as the 14nm process used in the Intel Xeon E5-2630V4 Processor, result in a reduction in cost per transistor. This allows for more transistors to be packed onto a single chip without significantly increasing production costs. The increased transistor density translates into more processing power and advanced features at a lower cost.

Enhanced Power Efficiency

The 14nm manufacturing technology enhances power efficiency by reducing leakage current. Leakage current occurs when transistors consume power even when they are not actively switching. By minimizing leakage current, the Intel Xeon E5-2630V4 Processor achieves higher power efficiency, resulting in reduced energy consumption and heat generation.

Future-Proofing

Choosing a processor manufactured using advanced technology, such as the 14nm process, future-proofs your system to some extent. As technology continues to advance, processors with smaller transistors will become more prevalent. By investing in a processor with advanced manufacturing technology, you ensure that your system remains relevant and compatible with future software and hardware advancements.

Part Number

The Intel Xeon E5-2630V4 Processor has the part number CM8066002032301. The part number uniquely identifies the specific model of the processor and is used for compatibility, identification, and ordering purposes.

Easy Identification

The part number CM8066002032301 makes it easy to identify the Intel Xeon E5-2630V4 Processor. By referencing the part number, users can ensure that they are purchasing the correct model for their specific needs. This is particularly important when ordering or upgrading processors in server or workstation environments.

Compatibility Assurance

The part number provides compatibility assurance. By using the correct part number, users can ensure that the processor is compatible with their existing system or motherboard. This helps to prevent compatibility issues and ensures a seamless integration of the processor into the system.

Ordering Convenience

The part number simplifies the ordering process. By providing the part number, users can easily communicate their requirements to suppliers or retailers. This streamlines the ordering process, saving time and ensuring that the correct processor is delivered.

Documentation and Support

The part number facilitates documentation and support. Users can easily find documentation, manuals, and support resources specific to the Intel Xeon E5-2630V4 Processor by referencing its part number. This ensures that users have access to relevant information and assistance when needed.

Product Lifecycle Management

The part number plays a crucial role in product lifecycle management. Manufacturers use part numbers to track and manage inventory, product versions, and updates. By referencing the part number, users can stay informed about product availability, updates, and end-of-life announcements.