Intel Xeon Processor SR1XS E5-2670V3 12 Core 2.3GHz 30MB L3 Cache

Core Count: 12

The Power of 12 Cores

The Intel SR1XS Processor is equipped with an impressive 12 cores, making it a powerful choice for users who demand high-performance computing. With a core count this high, users can expect exceptional multitasking capabilities, allowing them to run multiple applications simultaneously without experiencing any slowdowns or performance bottlenecks. Whether you're a professional content creator, a data analyst, or a gamer, the 12 cores of the Intel SR1XS Processor will ensure that your tasks are completed quickly and efficiently.

Improved Work Efficiency

The abundance of cores in the Intel SR1XS Processor enables improved work efficiency. Each core can handle its own set of instructions simultaneously, which means that complex tasks can be divided among the cores, resulting in faster processing times. This is particularly advantageous for users who engage in resource-intensive activities such as video editing or 3D rendering. With 12 cores at your disposal, you can expect significant reductions in rendering times and faster completion of computationally demanding tasks.

Seamless Gaming Experience

Gaming enthusiasts will also benefit greatly from the 12-core configuration of the Intel SR1XS Processor. Modern games are becoming increasingly demanding in terms of processing power, and a higher core count allows for smoother gameplay and improved frame rates. The additional cores ensure that the processor can handle the game's computational requirements while simultaneously running background processes such as streaming software or voice chat applications. With the Intel SR1XS Processor's 12 cores, you can enjoy an immersive gaming experience without any performance hiccups.

Improved Virtualization Performance

Virtualization has become an integral part of many businesses and organizations. With the Intel SR1XS Processor's 12 cores, virtualization performance is greatly enhanced. The increased core count allows for the efficient allocation of resources to virtual machines, ensuring smooth operation and reduced latency. Whether you're running multiple virtual machines for testing purposes or managing a virtualized infrastructure for your business, the 12 cores of the Intel SR1XS Processor will provide the necessary processing power to handle the workload effectively.

Future-Proofing Your System

Investing in a processor with a high core count, such as the Intel SR1XS Processor, is also a way to future-proof your system. As software and applications continue to evolve and become more demanding, having more cores will become increasingly important. By choosing a processor with 12 cores, you ensure that your system is ready to handle the demands of future software releases and advancements in technology.

Efficient Parallel Processing

Parallel processing refers to the ability of a processor to execute multiple tasks simultaneously. With 12 cores, the Intel SR1XS Processor excels in parallel processing tasks. Whether you're running scientific simulations, performing complex data analysis, or engaging in other highly parallelizable tasks, the 12 cores allow for efficient distribution of workloads across multiple threads. This results in faster execution times and improved overall system performance.

Speed: 2.3GHz

Faster Processing Speed

The Intel SR1XS Processor boasts a clock speed of 2.3GHz, delivering exceptional processing power to users. The higher clock speed allows for faster execution of instructions, resulting in quicker task completion and improved overall system responsiveness. Whether you're browsing the web, editing documents, or playing games, the 2.3GHz speed ensures that your system can handle these tasks with ease.

Smooth Multitasking

With its 2.3GHz speed, the Intel SR1XS Processor enables seamless multitasking. The higher clock speed allows for faster context switching between different applications, reducing lag and ensuring a smooth user experience. Whether you're working on multiple projects simultaneously or have several resource-intensive applications running in the background, the 2.3GHz speed ensures that your system can handle the load without any slowdowns.

Enhanced Gaming Performance

Gaming enthusiasts will appreciate the 2.3GHz speed of the Intel SR1XS Processor. The higher clock speed translates into improved gaming performance, with faster loading times and smoother gameplay. Whether you're playing graphically demanding AAA titles or engaging in fast-paced multiplayer games, the 2.3GHz speed ensures that your system can keep up with the demands of modern gaming.

Efficient Multimedia Processing

When it comes to multimedia tasks such as video editing or encoding, a higher clock speed is crucial for efficient processing. The 2.3GHz speed of the Intel SR1XS Processor allows for faster rendering and encoding times, enabling users to complete multimedia projects in less time. Whether you're editing a video for professional purposes or simply creating content for personal enjoyment, the higher clock speed ensures that your system can handle these tasks efficiently.

Quick System Responsiveness

The 2.3GHz speed of the Intel SR1XS Processor contributes to quick system responsiveness. Whether you're launching applications, switching between tasks, or performing system operations, a higher clock speed ensures that these actions are executed swiftly. This not only improves user productivity but also enhances the overall user experience by minimizing waiting times and reducing frustration.

Efficient Compilation and Development

For software developers and programmers, a higher clock speed is essential for efficient compilation and development processes. The 2.3GHz speed of the Intel SR1XS Processor allows for faster compilation times, reducing the waiting time between making code changes and seeing the results. This enables developers to iterate quickly and improves overall productivity.

Cache: 30MB L3

Improved Data Access

The Intel SR1XS Processor features a generous 30MB L3 cache, which plays a crucial role in improving data access speeds. The cache is a small but ultra-fast memory that stores frequently accessed data and instructions, allowing the processor to quickly retrieve the necessary information without having to access the slower main memory. With a larger cache like the 30MB L3 found in this processor, the chances of finding the required data in cache are higher, resulting in faster access times and improved overall system performance.

Reduced Memory Latency

The presence of a large L3 cache, such as the 30MB L3 in the Intel SR1XS Processor, helps reduce memory latency. Memory latency refers to the time it takes for the processor to access data from the main memory. By keeping frequently accessed data in the cache, the processor can avoid waiting for data to be fetched from the main memory, reducing latency and ensuring faster processing times. This is particularly beneficial for applications that heavily rely on memory access, such as databases or scientific simulations.

Efficient Task Switching

The 30MB L3 cache of the Intel SR1XS Processor also contributes to efficient task switching. When switching between different tasks or applications, the processor can store relevant data and instructions in the cache, allowing for faster context switching. This results in smoother multitasking and improved overall system responsiveness. Whether you're working on multiple projects simultaneously or have several resource-intensive applications running, the large L3 cache ensures that task switching is seamless and efficient.

Enhanced Gaming Performance

Gamers will also benefit from the large L3 cache of the Intel SR1XS Processor. The cache helps store frequently accessed game assets, such as textures or game logic, improving load times and reducing in-game stuttering. This results in a smoother gaming experience with faster level loading and improved overall performance. Whether you're exploring vast open-world environments or engaging in competitive multiplayer matches, the 30MB L3 cache ensures that your gaming experience is optimized.

Improved Virtual Machine Performance

Virtualization is a common practice in many businesses and organizations. The large L3 cache of the Intel SR1XS Processor enhances virtual machine performance by allowing for better caching of frequently accessed data and instructions within the virtual environment. This reduces latency and improves overall virtual machine responsiveness. Whether you're running multiple virtual machines for testing purposes or managing a virtualized infrastructure for your business, the 30MB L3 cache ensures smooth operation and improved performance.

Faster Data Analysis

The 30MB L3 cache also benefits users who engage in data analysis tasks. With a larger cache, more data can be stored closer to the processor, reducing the time required to access and process large datasets. This enables faster data analysis, making it easier to draw insights and make informed decisions. Whether you're analyzing financial data, conducting scientific research, or performing big data analytics, the large L3 cache of the Intel SR1XS Processor ensures efficient processing of data.

Qpi Speed: 8GT/S

High-Speed Data Transfer

The Intel SR1XS Processor features a QPI (QuickPath Interconnect) speed of 8GT/s, enabling high-speed data transfer between the processor and other system components. The QPI acts as a communication link between the processor and the memory, ensuring fast and efficient data exchange. With an 8GT/s QPI speed, users can expect improved overall system performance, reduced latency, and faster data access times.

Efficient Multi-Processor Communication

In multi-processor systems, efficient communication between processors is crucial for optimal performance. The high QPI speed of 8GT/s in the Intel SR1XS Processor facilitates efficient inter-processor communication, allowing for faster data sharing and synchronization. This is particularly important in scenarios where multiple processors need to collaborate on complex tasks or share large datasets. The high QPI speed ensures that communication between processors is smooth and does not become a performance bottleneck.

Enhanced Memory Bandwidth

The QPI speed of 8GT/s also contributes to enhanced memory bandwidth. Memory bandwidth refers to the maximum amount of data that can be transferred from the memory to the processor within a given time frame. A higher QPI speed allows for faster data transfer between the memory and the processor, resulting in increased memory bandwidth. This is particularly beneficial for memory-intensive tasks such as large-scale data processing or running memory-bound applications. With the Intel SR1XS Processor's 8GT/s QPI speed, users can expect improved memory performance and faster data access.

Improved Scalability

The high QPI speed of 8GT/s in the Intel SR1XS Processor also enables improved system scalability. Scalability refers to a system's ability to handle increased workloads or accommodate additional components without sacrificing performance. With a high QPI speed, system scalability is enhanced as it allows for faster communication between processors and other system components. This means that as your workload grows or you add more components to your system, the Intel SR1XS Processor can handle the increased demands efficiently, ensuring consistent performance.

Support for High-Speed Peripherals

The high QPI speed of 8GT/s in the Intel SR1XS Processor also benefits users who rely on high-speed peripherals. Peripherals such as storage devices or network adapters that support high data transfer rates can take full advantage of the fast QPI speed, ensuring efficient data exchange with the processor. This results in faster file transfers, reduced backup times, and improved network performance. Whether you're working with large files, transferring data over a high-speed network, or using storage devices with fast read/write speeds, the Intel SR1XS Processor's high QPI speed ensures seamless integration and optimal performance.

Reduced System Bottlenecks

The high QPI speed of 8GT/s in the Intel SR1XS Processor helps reduce system bottlenecks. Bottlenecks occur when a component or subsystem becomes a limiting factor in overall system performance. With a fast QPI speed, data can be quickly transferred between the processor and other system components, reducing the chances of a bottleneck occurring. This ensures that all components can operate at their maximum potential, resulting in improved overall system performance and responsiveness.

Socket: FCLGA-2011-3

Compatibility and Upgradeability

The Intel SR1XS Processor utilizes the FCLGA-2011-3 socket, which offers compatibility and upgradeability options for users. The socket refers to the physical interface between the processor and the motherboard. By using the FCLGA-2011-3 socket, users can enjoy broad compatibility with a variety of motherboards that support this socket type. It also provides an upgrade path for future processor upgrades without requiring a motherboard replacement. This ensures that your system remains compatible with the latest processor offerings and allows for future expansion and enhancements.

Support for High-Performance Memory

The FCLGA-2011-3 socket also supports high-performance memory modules. Memory modules, such as DDR4, offer faster data transfer rates and improved overall system performance compared to older memory technologies. By utilizing the FCLGA-2011-3 socket, users can take full advantage of these high-performance memory modules, resulting in faster data access, reduced latency, and improved multitasking capabilities. Whether you're a professional content creator working with large files or a gamer looking to maximize system performance, the FCLGA-2011-3 socket ensures compatibility with high-performance memory for optimal results.

Scalability for Multi-GPU Setups

The FCLGA-2011-3 socket provides scalability options for users who require multi-GPU setups. Multi-GPU setups involve using multiple graphics cards to enhance graphics performance in applications such as gaming or professional design software. The FCLGA-2011-3 socket supports motherboards that offer multiple PCIe slots, allowing for the installation of multiple graphics cards. This enables users to scale their system's graphics performance by adding additional GPUs, resulting in improved frame rates, smoother gameplay, and enhanced visual quality.

Support for High-Speed Storage

The FCLGA-2011-3 socket also supports high-speed storage options. With the increasing demand for faster storage technologies such as solid-state drives (SSDs), the FCLGA-2011-3 socket ensures compatibility with motherboards that offer the necessary interfaces, such as PCIe or M.2 slots. This enables users to take full advantage of high-speed storage devices, resulting in faster boot times, reduced application loading times, and improved overall system responsiveness. Whether you're working with large files or running applications that require fast storage access, the FCLGA-2011-3 socket ensures compatibility with high-speed storage options.

Future-Proofing Your System

By utilizing the FCLGA-2011-3 socket, users can future-proof their system to some extent. The socket offers compatibility with current and future processor generations that utilize this socket type. This means that as new processors are released, users can upgrade their system without requiring a motherboard replacement. This ensures that your system remains compatible with the latest processor offerings and allows for future expansion and enhancements. By choosing the Intel SR1XS Processor with the FCLGA-2011-3 socket, you're investing in a system that can accommodate future upgrades and advancements in technology.

Nm Technology: 22NM

Efficient Power Consumption

The 22nm technology used in the Intel SR1XS Processor ensures efficient power consumption. The term "nm" refers to the size of transistors used in the manufacturing process, with smaller values indicating higher transistor density. With a smaller transistor size of 22nm, the Intel SR1XS Processor can pack more transistors into a given area, resulting in improved power efficiency. This means that the processor can deliver high-performance computing while consuming less power, resulting in reduced energy costs and a smaller carbon footprint.

Cooler Operation and Thermal Management

The 22nm technology also contributes to cooler operation and better thermal management. Smaller transistors generate less heat compared to larger ones, allowing for more efficient dissipation of heat from the processor. This results in cooler operation, reducing the need for excessive cooling measures such as noisy fans or bulky cooling systems. The improved thermal management also ensures that the processor can maintain optimal operating temperatures, preventing thermal throttling and maintaining consistent performance levels.

Higher Integration and Miniaturization

The 22nm technology enables higher integration