3.0GHz-10.4GT-UPI

3.0GHz-10.4GT-UPI Xeon 12 Core Processors

Overview

The 3.0GHz-10.4GT-UPI Xeon 12 Core processors represent a high-performance class of Intel Xeon processors, designed to deliver exceptional computational power, speed, and scalability. These processors are commonly used in workstations, servers, and enterprise environments where multi-threaded performance and data throughput are essential. The Xeon 12 Core family is a top choice for demanding tasks like database management, virtualization, high-performance computing (HPC), and complex simulations, making it a versatile component for a wide range of applications.

Key Features of 3.0GHz-10.4GT-UPI Xeon 12 Core Processors

Processor Speed and Efficiency

Operating at 3.0GHz, the 3.0GHz-10.4GT-UPI Xeon 12 Core processors provide optimal balance between clock speed and multi-core processing capability. The processor is capable of efficiently managing multiple threads, with a high clock speed that ensures rapid processing of instructions. The 10.4GT-UPI (Ultra Path Interconnect) technology boosts communication between cores, memory, and other connected components, reducing latency and enhancing data transfer rates across the system.

Core and Thread Count

With 12 cores, the Xeon 3.0GHz-10.4GT-UPI processor offers a massive increase in parallel processing capability compared to standard processors. Each core can handle multiple threads simultaneously, significantly improving multitasking performance. The multi-core architecture excels in environments where parallel processing is critical, such as cloud computing, AI, and large-scale computational tasks.

Reliability and Scalability

Xeon processors are designed with server-grade reliability in mind. The 3.0GHz-10.4GT-UPI Xeon 12 Core processor ensures minimal downtime, enhanced system stability, and longevity, even under heavy workloads. Scalability is a crucial advantage, as multiple processors can be used in a single server to scale performance for more demanding applications. The support for high-performance computing and virtualization environments is another key benefit of these processors.

Xeon 12 Core Processors

Server and Data Center Applications

The 3.0GHz-10.4GT-UPI Xeon 12 Core processors are widely used in servers and data centers. These processors are well-suited to environments requiring significant computational power, such as web hosting, cloud computing, and virtualization. The robust core count and processing capabilities ensure smooth operation and the ability to handle multiple virtual machines or large-scale workloads efficiently.

Scientific Research and High-Performance Computing (HPC)

In high-performance computing (HPC) applications, the Xeon 12 Core processor's multi-core architecture enables scientists and researchers to process vast amounts of data quickly and accurately. The processor excels in computational simulations, data modeling, and complex analyses across a variety of industries, including biotechnology, aerospace, and environmental science.

Artificial Intelligence and Machine Learning

AI and machine learning workloads benefit greatly from the Xeon 12 Core processors. The processor’s high core count and multi-threading capabilities allow for parallel processing of large datasets, significantly speeding up training times for AI models. Additionally, the support for high-speed data interconnects like UPI enables faster communication between components, which is crucial in AI workloads requiring massive amounts of data throughput.

Technical Specifications

Clock Speed

The 3.0GHz clock speed of the Xeon 12 Core processor offers optimal performance in both single-threaded and multi-threaded workloads. While higher clock speeds can be important for applications that rely on single-threaded performance, the Xeon processor optimizes parallel tasks, making it ideal for server and enterprise-level operations.

Cache Size

Intel Xeon processors are equipped with substantial cache memory to ensure rapid access to frequently used data. The 3.0GHz-10.4GT-UPI Xeon 12 Core processors typically feature a large Level 3 (L3) cache that minimizes latency and accelerates processing speed for data-intensive tasks. This cache plays a significant role in improving the overall system performance by reducing the need for slower access to main memory.

Thermal Design Power (TDP)

With an optimized TDP (Thermal Design Power) rating, the Xeon 12 Core processors manage heat dissipation effectively, making them suitable for high-performance workstations and data centers. The efficient cooling mechanisms enable the processors to sustain peak performance without compromising system stability, even under heavy load.

Intel Hyper-Threading Technology

Intel Hyper-Threading Technology is included in the Xeon 3.0GHz-10.4GT-UPI 12 Core processors. Hyper-Threading allows each core to handle two threads simultaneously, further improving multitasking performance. This allows the processor to execute more instructions per clock cycle, delivering a substantial boost to system performance in multithreaded applications like virtualization, video encoding, and rendering.

Intel Turbo Boost Technology

Intel Turbo Boost Technology automatically increases the processor's clock speed above its base frequency when required, providing an additional performance boost when running demanding tasks. This technology allows the Xeon 12 Core processors to achieve optimal performance levels, adjusting dynamically to the workload.

Performance Benchmarks and Comparisons

Multi-Core Performance

The 3.0GHz-10.4GT-UPI Xeon 12 Core processor excels in multi-core performance, outpacing many other processors in the same class. This is crucial in applications requiring heavy computational power, such as video editing, rendering, and scientific simulations. Benchmarks show that the Xeon 12 Core processor can outperform competitors in environments that demand massive parallel processing, delivering excellent scalability and efficiency.

Single-Core Performance

While multi-core performance is a primary strength, the 3.0GHz-10.4GT-UPI Xeon 12 Core also offers impressive single-core performance. This is beneficial for applications and tasks that rely on the power of a single thread, such as certain types of gaming, software development, and specific database operations. Benchmarks indicate that the processor offers a strong balance of single-core and multi-core performance, making it versatile for different workloads.

Energy Efficiency

Despite its high performance, the Xeon 12 Core processor is engineered for energy efficiency. The 3.0GHz-10.4GT-UPI processors deliver a strong performance-per-watt ratio, making them suitable for environments where energy consumption is a key consideration, such as large-scale data centers and enterprise systems.

Compatibility and Integration

Motherboard Compatibility

The 3.0GHz-10.4GT-UPI Xeon 12 Core processors are compatible with a wide range of enterprise-grade motherboards that support Intel’s server and workstation platforms. It is important to check the processor socket type and chipset compatibility before upgrading or building a system. The processors typically utilize the LGA 2011-v3 socket, ensuring compatibility with various high-performance motherboards.

Memory Compatibility

Xeon processors are designed to work seamlessly with high-performance memory. The 3.0GHz-10.4GT-UPI Xeon 12 Core processor supports quad-channel DDR4 ECC (Error Correcting Code) memory, providing both speed and data integrity, essential for mission-critical applications. The support for ECC memory ensures the system can detect and correct memory errors, preventing data corruption and enhancing stability in enterprise environments.

Support for Virtualization

Intel Xeon processors offer built-in support for hardware-assisted virtualization. This feature is particularly valuable in data centers and enterprise environments where virtualization is widely used to maximize resource utilization. The 3.0GHz-10.4GT-UPI Xeon 12 Core processor supports Intel VT-x and VT-d technologies, enabling the creation of virtual machines and direct access to hardware resources, thereby improving performance and flexibility.