Community Involvement

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  1. REDIRECT Community Involvement Server Configuration

This is a comprehensive technical documentation article for the server configuration designated as **Template:ServerConfiguration**.

This document is intended for system architects, data center operators, and senior IT professionals requiring in-depth technical understanding of this specific hardware blueprint.

--- Template:About Template:Technical Documentation Header Template:Infobox Server Platform

Template:ServerConfiguration: Technical Deep Dive

The **Template:ServerConfiguration** (TSC) represents a standardized, high-density, dual-socket server platform optimized for workload consolidation, virtualization density, and high-throughput transactional processing. It balances raw computational power with substantial I/O bandwidth, making it a highly versatile workhorse in modern data center environments.

1. Hardware Specifications

The TSC is designed around a standard 2U rackmount form factor, emphasizing thermal efficiency and component accessibility. The core philosophy centers on maximizing memory density and PCIe lane availability for advanced SAN and NIC configurations.

1.1 Central Processing Units (CPUs)

The platform mandates dual-socket support, utilizing processors with high core counts and substantial L3 cache, adhering to the latest server CPU microarchitecture standards available at the time of deployment specification.

**CPU Configuration Options**
Specification Option A (High Core Density) Option B (High Clock Speed/Memory Bandwidth)
Processor Family Intel Xeon Scalable (Sapphire Rapids) or AMD EPYC Genoa Intel Xeon Scalable (Sapphire Rapids) or AMD EPYC Genoa
Model Example (Intel) Xeon Gold 6448Y (32 Cores, 64 Threads) Xeon Platinum 8480+ (56 Cores, 112 Threads)
Model Example (AMD) EPYC 9354P (32 Cores, 64 Threads) EPYC 9654 (96 Cores, 192 Threads)
Total Cores/Threads (Dual Socket) 64C/128T (Min) 112C/224T (Max)
Base Clock Frequency 2.4 GHz (Nominal) 2.0 GHz (Nominal)
Max Turbo Frequency Up to 3.9 GHz Up to 3.7 GHz
L3 Cache Total 120 MB per socket (240 MB Aggregate) 384 MB per socket (768 MB Aggregate)
PCIe Lanes Supported 80 Lanes per socket (160 Total) 128 Lanes per socket (256 Total)
  • Note: The selection between Option A and Option B must be driven by the primary workload requirements (see Section 3). Option B maximizes thread count but may slightly reduce sustained single-thread performance compared to Option A's higher base clock.*

1.2 Memory Subsystem

The TSC leverages DDR5 ECC Registered DIMMs (RDIMMs) to support high capacity and bandwidth. The platform supports 16 DIMM slots per socket (32 total slots).

**Memory Configuration Details**
Parameter Specification Rationale
Memory Type DDR5 ECC RDIMM Error Correction and high-speed data transfer.
Maximum Speed Supported 4800 MT/s (JEDEC standard load) Dependent on CPU memory controller configuration and population density.
Total Slot Count 32 (16 per CPU) Maximizes memory adjacency for NUMA locality.
Minimum Configuration 256 GB (8 x 32GB DIMMs, balanced across sockets) Ensures proper NUMA topology recognition.
Recommended Configuration 1024 GB (16 x 64GB DIMMs) Optimal balance for high-density virtualization.
Maximum Capacity 4 TB (32 x 128GB DIMMs) Requires specific high-density DIMM support from the motherboard BIOS.
Memory Channel Architecture 8 Channels per CPU Critical for achieving maximum memory throughput.

1.3 Storage Architecture

The storage subsystem is designed for high IOPS density, favoring NVMe over traditional SAS/SATA where possible, though backward compatibility is maintained for legacy RAID configurations.

The chassis provides 16 front-accessible SFF drive bays, configurable via a dedicated backplane supporting SAS/SATA or NVMe (U.2/E3.S).

**Storage Configuration Matrix**
Bay Type Quantity Interface Support Primary Controller
Front Bays (SFF) 16 (Hot-Swap) NVMe (PCIe Gen 5 x4) or SAS3/SATA 6Gbps Dedicated Hardware RAID Controller (e.g., Broadcom Tri-Mode)
Internal Boot Drive(s) 2 (Optional) M.2 NVMe (PCIe Gen 4) Onboard SATA/M.2 Host Controller
Maximum Theoretical Throughput (All NVMe) ~ 60 GB/s (Read Aggregated) Based on 16 drives utilizing PCIe Gen 5 x4 lanes.

The primary storage controller must be a PCIe Gen 5 capable expansion card (x16 slot required) to avoid I/O bottlenecks imposed by the CPU/Chipset interface limitations. Refer to PCIe Lane Allocation documentation for specific slot assignments.

1.4 Networking Capabilities

Network connectivity is bifurcated into a Base-T/Management interface and high-speed data fabric interfaces via PCIe add-in cards.

  • **LOM (LAN on Motherboard):** 2x 25GBASE-T (RJ45) for management, Baseboard Management Controller (BMC), and low-latency network access.
  • **PCIe Expansion:** The configuration supports up to 4 full-height, full-length PCIe Gen 5 x16 slots. Standard deployment specifies one slot dedicated to networking:
   *   4x 10GbE SFP+ Adapter (Standard Deployment)
   *   *Alternative:* 2x 100GbE QSFP28 Adapter (High-Performance Network Deployment)

1.5 Power and Cooling

The TSC platform demands high-efficiency power delivery due to the high TDP components (up to 350W per CPU).

  • **PSUs:** Dual redundant (1+1) 2000W 80 PLUS Platinum certified power supplies.
  • **Voltage Input:** Supports 100-240V AC, 50/60 Hz.
  • **Cooling:** Utilizes high-static-pressure, redundant (N+1) system fans managed by the BMC. Thermal design power (TDP) headroom must be maintained at 20% above the configured CPU TDP envelope, especially when using 128GB DIMMs due to increased thermal density.

2. Performance Characteristics

The performance profile of the TSC is defined by its high core density, massive memory bandwidth, and fast, low-latency storage access via PCIe Gen 5.

2.1 Compute Benchmarks (Synthetic)

The following benchmarks illustrate the potential throughput when the system is configured with dual AMD EPYC 9654 processors (192 Cores total) and 2TB of DDR5-4800 memory.

**Synthetic Benchmark Results (Dual EPYC 9654)**
Benchmark Metric Result (Aggregate) Context
SPECrate 2017 Integer Rate (Higher is better) 1,850 Measure of throughput for server-side applications.
SPECrate 2017 Floating Point Rate (Higher is better) 1,920 Measure of scientific and engineering application throughput.
Linpack (HPL) GFLOPS (Peak Theoretical) ~ 15.5 TFLOPS Measured FP64 performance under optimized conditions.
Memory Bandwidth (Stream Triad) GB/s ~ 650 GB/s Achievable aggregate read/write bandwidth.

2.2 I/O Latency and Throughput

Storage performance is heavily dependent on the controller choice and drive technology (NVMe vs. SAS). For the recommended NVMe configuration (16x U.2 Gen 5 drives on a Gen 5 x16 controller):

  • **Sequential Read Throughput:** Consistently measured above 55 GB/s.
  • **Random Read IOPS (4K Q1/T1):** Exceeds 7 million IOPS.
  • **Storage Latency (P99):** Under 15 microseconds for random 4K reads against a well-provisioned RAID-10 equivalent volume.

The 25GbE Base-T interconnects provide approximately 11.5 GB/s throughput per link, while the optional 100GbE cards can deliver near-line-rate performance for high-bandwidth data transfers, crucial for storage virtualization or high-frequency trading environments.

2.3 Power Efficiency (Performance per Watt)

While the maximum power draw can peak near 3.5 kW under full load (CPU stress testing, all drives active), the efficiency under typical virtualization load (60-70% utilization) is excellent due to the high core density.

  • **Efficiency Target:** The platform aims for a sustained performance-per-watt ratio exceeding 50 SPECrate/kW at 75% utilization, aligning with Tier III data center energy standards.

3. Recommended Use Cases

The versatility of the TSC makes it suitable for several demanding roles within an enterprise infrastructure stack.

3.1 High-Density Virtualization Host

With up to 224 threads and 4TB of high-speed memory, the TSC excels as a hypervisor host (e.g., VMware ESXi, KVM, Hyper-V).

  • **Density:** Capable of safely hosting 250+ standard virtual machines (VMs) with guaranteed minimum resource allocations.
  • **NUMA Optimization:** The dual-socket design necessitates careful VM placement to maintain NUMA locality, ensuring high performance for latency-sensitive guest operating systems.

3.2 Database and In-Memory Computing (IMC)

The large memory capacity (up to 4TB) combined with high-speed NVMe storage makes this configuration ideal for large-scale SQL or NoSQL databases.

  • **In-Memory Databases:** Configurations approaching 4TB RAM are perfectly suited for massive SAP HANA or specialized time-series databases where the entire working set fits in physical memory.
  • **Transactional Workloads (OLTP):** The high IOPS capability of the NVMe array supports rapid commit times and high concurrent transaction rates.

3.3 Application Consolidation and Microservices

For environments heavily invested in containerization (Kubernetes, OpenShift), the TSC provides a dense compute platform.

  • **Container Density:** The high core count allows for efficient scheduling of thousands of containers, maximizing resource utilization across the physical hardware.
  • **CI/CD Pipelines:** Excellent performance for running large-scale, parallelized build and test automation jobs.

3.4 High-Performance Computing (HPC) Workloads

While specialized accelerators (GPUs) are not mandatory in the base template, the robust CPU and memory subsystem support HPC workloads that are compute-bound rather than massively parallelized (e.g., certain fluid dynamics simulations or Monte Carlo methods). The optional high-speed networking (100GbE) is crucial here for inter-node communication via MPI.

4. Comparison with Similar Configurations

To contextualize the TSC, it is beneficial to compare it against two common alternatives: a Single-Socket (SS) configuration and a High-Density GPU (HPC) configuration.

4.1 Configuration Matrix Comparison

**Template Comparison**
Feature Template:ServerConfiguration (TSC) Single-Socket High-Core (SS-HC) GPU-Optimized (GPU-Opt)
Socket Count 2 1 2
Max Cores (Approx.) 192 64 128 (Plus 4-8 Accelerators)
Max RAM Capacity 4 TB 2 TB 2 TB (Shared with Accelerators)
PCIe Gen 5 Slots (x16) 4 3 6-8 (Often sacrificing standard I/O)
Primary Strength Workload Consolidation, I/O Bandwidth Power Efficiency, Licensing Consolidation Massive Parallel Compute (AI/ML)
Typical Cost Index (Base) 1.0x 0.6x 2.5x (Due to accelerators)

4.2 Detailed Feature Analysis

  • **Versus Single-Socket (SS-HC):** The TSC doubles the total available PCIe lanes (160 vs. 80 lanes, assuming equivalent processor generation), which is the critical differentiator. An SS-HC easily bottlenecks when loading multiple high-speed NVMe arrays or dual 100GbE adapters simultaneously. The TSC mitigates this systemic I/O starvation.
  • **Versus GPU-Optimized (GPU-Opt):** The GPU-Opt platform sacrifices general-purpose CPU resources and standard networking slots to accommodate multiple GPUs. While superior for deep learning inference/training, the TSC offers significantly better performance for traditional virtualization, database operations, and tasks that rely heavily on CPU cache and memory bandwidth rather than massive parallel floating-point operations.

5. Maintenance Considerations

Proper maintenance is essential to ensure the thermal envelope and power delivery remain within specification, particularly given the high component density.

5.1 Thermal Management and Airflow

The 2U chassis design requires specific attention to airflow management.

1. **Front-to-Back Airflow:** Ensure a clear path for cool air intake (Zone A) and hot air exhaust (Zone C). Obstructions in the rack aisle can lead to thermal throttling, especially under sustained 100% CPU load. 2. **Component Clearance:** When installing PCIe cards, ensure adequate spacing (minimum 1 slot gap) between high-power adapters (e.g., 300W HBAs or NICs) to prevent localized hotspots that stress the mainboard VRMs. 3. **Fan Redundancy:** Monitor the BMC health status for fan failure alerts. Loss of a single fan may not immediately cause failure, but sustained operation without full fan redundancy significantly reduces the system’s safe operating temperature threshold, potentially forcing the CPUs into lower power states (throttling).

5.2 Power Delivery and Redundancy

The dual 2000W Platinum PSUs provide significant headroom. However, proper PDU configuration is mandatory.

  • **Input Requirement:** Each rack unit must be fed from two independent power feeds (A and B sides) sourced from separate UPS systems.
  • **Load Balancing:** While the PSUs are redundant, the total measured power draw under peak load should not exceed 1.6 kW per PSU to maintain the Platinum efficiency rating and maximize headroom for transient spikes.
  • **Firmware Updates:** Regular updates to the BMC firmware are crucial, as these updates often contain critical thermal profiling adjustments and power state management improvements specific to the installed CPU stepping.

5.3 Serviceability and Component Access

The TSC design prioritizes field-replaceable units (FRUs).

  • **Hot-Swap Components:** Drives, PSUs, and system fans are designed for hot-swapping without system shutdown. Always initiate the drive removal sequence via the management interface to ensure the RAID controller has gracefully spun down the spindle or prepared the NVMe for safe removal.
  • **Memory Access:** Accessing the DIMM slots requires lifting the top chassis cover and potentially removing the CPU heatsinks (depending on the specific vendor implementation) if servicing slots adjacent to the CPU socket base. This procedure must be performed in a controlled, ESD-safe environment.

5.4 Operating System and Driver Support

The platform relies heavily on up-to-date OS kernel support for optimal performance, particularly concerning memory management and PCIe Gen 5 capabilities.

  • **Storage Drivers:** Use certified vendor drivers for the RAID controller (e.g., Broadcom/LSI) that specifically enable the full throughput of Gen 5 NVMe devices. Generic OS drivers may limit performance to Gen 4 speeds.
  • **NUMA Awareness:** Ensure the hypervisor or OS scheduler is fully NUMA-aware to prevent cross-socket memory access penalties, which can degrade performance by up to 30% in memory-bound workloads.

---


Intel-Based Server Configurations

Configuration Specifications Benchmark
Core i7-6700K/7700 Server 64 GB DDR4, NVMe SSD 2 x 512 GB CPU Benchmark: 8046
Core i7-8700 Server 64 GB DDR4, NVMe SSD 2x1 TB CPU Benchmark: 13124
Core i9-9900K Server 128 GB DDR4, NVMe SSD 2 x 1 TB CPU Benchmark: 49969
Core i9-13900 Server (64GB) 64 GB RAM, 2x2 TB NVMe SSD
Core i9-13900 Server (128GB) 128 GB RAM, 2x2 TB NVMe SSD
Core i5-13500 Server (64GB) 64 GB RAM, 2x500 GB NVMe SSD
Core i5-13500 Server (128GB) 128 GB RAM, 2x500 GB NVMe SSD
Core i5-13500 Workstation 64 GB DDR5 RAM, 2 NVMe SSD, NVIDIA RTX 4000

AMD-Based Server Configurations

Configuration Specifications Benchmark
Ryzen 5 3600 Server 64 GB RAM, 2x480 GB NVMe CPU Benchmark: 17849
Ryzen 7 7700 Server 64 GB DDR5 RAM, 2x1 TB NVMe CPU Benchmark: 35224
Ryzen 9 5950X Server 128 GB RAM, 2x4 TB NVMe CPU Benchmark: 46045
Ryzen 9 7950X Server 128 GB DDR5 ECC, 2x2 TB NVMe CPU Benchmark: 63561
EPYC 7502P Server (128GB/1TB) 128 GB RAM, 1 TB NVMe CPU Benchmark: 48021
EPYC 7502P Server (128GB/2TB) 128 GB RAM, 2 TB NVMe CPU Benchmark: 48021
EPYC 7502P Server (128GB/4TB) 128 GB RAM, 2x2 TB NVMe CPU Benchmark: 48021
EPYC 7502P Server (256GB/1TB) 256 GB RAM, 1 TB NVMe CPU Benchmark: 48021
EPYC 7502P Server (256GB/4TB) 256 GB RAM, 2x2 TB NVMe CPU Benchmark: 48021
EPYC 9454P Server 256 GB RAM, 2x2 TB NVMe

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⚠️ *Note: All benchmark scores are approximate and may vary based on configuration. Server availability subject to stock.* ⚠️

Community Involvement Server Configuration

This document details the "Community Involvement" server configuration, a versatile and cost-effective solution tailored for organizations and groups needing robust server capabilities without requiring the highest-end performance. It's ideally suited for hosting community forums, game servers, development/testing environments, and small to medium-sized databases. This configuration prioritizes a balance between performance, scalability, and maintainability, making it an excellent choice for long-term deployment.

1. Hardware Specifications

The "Community Involvement" server is built around providing a solid foundation for a variety of workloads. Component selection focuses on proven reliability and a good price/performance ratio.

Component Specification
CPU Dual Intel Xeon Silver 4310 (12 Cores / 24 Threads, 2.1 GHz Base, 3.3 GHz Turbo)
CPU Socket LGA 4189
Chipset Intel C621A
RAM 128GB DDR4 ECC Registered 3200MHz (8 x 16GB DIMMs) - Scalable to 512GB
Storage - OS/Boot 500GB NVMe PCIe Gen4 SSD (Read: 3500 MB/s, Write: 3000 MB/s)
Storage - Data 4 x 4TB SAS 12Gbps 7.2K RPM HDD in RAID 10 - 16TB Usable Capacity. RAID Configuration details are crucial.
RAID Controller Hardware RAID Controller with 8GB Cache (Supports RAID Levels 0, 1, 5, 6, 10) - Hardware RAID vs Software RAID
Network Interface Card (NIC) Dual 10 Gigabit Ethernet (10GbE) ports (Intel X710-DA4) - Network Interface Card
Power Supply Unit (PSU) 750W Redundant Power Supply (80+ Platinum Certified) - Power Supply Redundancy
Chassis 2U Rackmount Server Chassis with Hot-Swappable Fans - Server Chassis
Remote Management Integrated IPMI 2.0 with Dedicated Network Port - IPMI Remote Management
Motherboard Form Factor ATX

Detailed Component Notes:

  • **CPU:** The Intel Xeon Silver 4310 provides a good balance of cores and clock speed for most community-driven applications. The dual-CPU configuration allows for improved parallelism and scalability. Consider CPU Benchmarking for performance analysis.
  • **RAM:** 128GB of ECC Registered DDR4 RAM ensures data integrity and stability, especially critical for database and server applications. The 3200MHz speed provides a performance boost. Memory Types and Considerations provides further detail.
  • **Storage:** The combination of a fast NVMe SSD for the operating system and a RAID 10 array of SAS HDDs provides both speed and data redundancy. RAID 10 offers excellent performance and fault tolerance, protecting against single drive failures. Storage Technologies explores various options.
  • **Networking:** Dual 10GbE ports provide high bandwidth connectivity for demanding applications and future scalability. Network Topologies are relevant here.
  • **PSU:** The redundant 750W PSU ensures high availability and protects against power supply failures. The 80+ Platinum certification guarantees high energy efficiency, lowering operating costs. Power Consumption and Efficiency is a key consideration.
  • **Remote Management:** IPMI 2.0 allows for remote server management, even when the operating system is down. This is crucial for unattended operation and troubleshooting.


2. Performance Characteristics

The "Community Involvement" server configuration delivers solid performance for its target workloads. The following benchmarks are representative results obtained under controlled testing conditions.

  • **CPU Performance (SPECint 2017):** Approximately 85-95 (Dual CPU Score) - CPU Benchmarking Tools
  • **Storage Performance (IOMeter):**
   *   NVMe SSD (Sequential Read): 3400 MB/s
   *   NVMe SSD (Sequential Write): 2900 MB/s
   *   RAID 10 Array (Sequential Read): 700 MB/s
   *   RAID 10 Array (Sequential Write): 600 MB/s

Real-World Performance Examples:

  • **Community Forum (phpBB):** Supports up to 500 concurrent users with minimal latency.
  • **Game Server (Minecraft):** Can comfortably handle a server with 50-75 players, depending on the complexity of the world and installed mods.
  • **Development Environment (Docker/Kubernetes):** Can host multiple containerized applications with good performance.
  • **Small Database (MySQL/PostgreSQL):** Suitable for storing and managing data for applications with moderate data volumes and user traffic.

3. Recommended Use Cases

This server configuration is particularly well-suited for the following applications:

  • **Community Forums and Websites:** Provides sufficient resources to handle moderate traffic and data storage requirements.
  • **Game Servers:** Ideal for hosting smaller to medium-sized game servers, such as Minecraft, Team Fortress 2, or similar.
  • **Development and Testing Environments:** Provides a stable and reliable platform for software development, testing, and continuous integration/continuous deployment (CI/CD).
  • **Small to Medium-Sized Databases:** Suitable for hosting databases used by community applications, such as user accounts, forum posts, or game data.
  • **File Sharing and Collaboration:** Can be used to host file sharing services like Nextcloud or ownCloud.
  • **Media Streaming Server:** Capable of streaming video and audio content to a moderate number of users. Media Server Software options are numerous.
  • **Virtualization Host (Limited):** While not its primary strength, it can support a small number of virtual machines (2-4) with modest resource requirements. Virtualization Technologies should be considered.

4. Comparison with Similar Configurations

The "Community Involvement" configuration offers a compelling balance of price and performance. Here's a comparison with other potential server configurations:

Configuration CPU RAM Storage Network Estimated Cost (USD) Notes
Community Involvement Dual Intel Xeon Silver 4310 128GB DDR4 500GB NVMe + 16TB SAS RAID 10 Dual 10GbE $4,500 - $6,000 Best value for balanced performance and reliability.
Entry-Level Server Single Intel Xeon E-2336 64GB DDR4 1TB NVMe Single 1GbE $2,500 - $3,500 Lower cost, but limited performance and scalability. Suitable for very small communities.
High-Performance Server Dual Intel Xeon Gold 6338 256GB DDR4 1TB NVMe + 32TB SAS RAID 10 Dual 25GbE $8,000 - $12,000 Significantly higher performance, but also a much higher cost. Overkill for most community applications.
Budget Server (DIY) AMD Ryzen 9 5900X 64GB DDR4 2TB NVMe Single 1GbE $2,000 - $3,000 Can be cost-effective, but may lack enterprise-grade reliability and support. DIY Server Builds

Key Considerations when comparing:

  • **Scalability:** The "Community Involvement" configuration offers good scalability for future growth.
  • **Reliability:** The use of ECC Registered RAM, a hardware RAID controller, and redundant power supplies enhances reliability.
  • **Cost:** The configuration provides a good price/performance ratio.
  • **Manageability:** Integrated IPMI 2.0 simplifies remote management.

5. Maintenance Considerations

Maintaining the "Community Involvement" server requires regular attention to ensure optimal performance and reliability.

  • **Cooling:** The 2U chassis is designed for rackmount environments and requires adequate airflow to prevent overheating. Regularly check fan operation and clean dust filters. Server Room Cooling best practices should be followed.
  • **Power Requirements:** The server requires a dedicated 120V/240V power circuit with sufficient amperage. Ensure proper grounding.
  • **Software Updates:** Keep the operating system, firmware, and all software up to date with the latest security patches and bug fixes. Server Security Best Practices are paramount.
  • **RAID Monitoring:** Regularly monitor the health of the RAID array and replace any failing drives promptly. RAID Monitoring Tools can automate this process.
  • **Log Analysis:** Review system logs regularly to identify and address potential issues. System Log Analysis
  • **Physical Security:** Secure the server in a locked rack in a physically secure location.
  • **Backup and Disaster Recovery:** Implement a robust backup and disaster recovery plan to protect against data loss. Data Backup Strategies are essential.
  • **Dust Control:** Regularly clean the server chassis to prevent dust buildup, which can lead to overheating and component failure. Server Maintenance Schedule
  • **Power Supply Testing:** Periodically test the redundant power supply functionality to ensure it's working correctly.

This documentation provides a comprehensive overview of the "Community Involvement" server configuration. By following these guidelines, organizations can deploy and maintain a reliable and cost-effective server solution for their community-driven applications. ```


Intel-Based Server Configurations

Configuration Specifications Benchmark
Core i7-6700K/7700 Server 64 GB DDR4, NVMe SSD 2 x 512 GB CPU Benchmark: 8046
Core i7-8700 Server 64 GB DDR4, NVMe SSD 2x1 TB CPU Benchmark: 13124
Core i9-9900K Server 128 GB DDR4, NVMe SSD 2 x 1 TB CPU Benchmark: 49969
Core i9-13900 Server (64GB) 64 GB RAM, 2x2 TB NVMe SSD
Core i9-13900 Server (128GB) 128 GB RAM, 2x2 TB NVMe SSD
Core i5-13500 Server (64GB) 64 GB RAM, 2x500 GB NVMe SSD
Core i5-13500 Server (128GB) 128 GB RAM, 2x500 GB NVMe SSD
Core i5-13500 Workstation 64 GB DDR5 RAM, 2 NVMe SSD, NVIDIA RTX 4000

AMD-Based Server Configurations

Configuration Specifications Benchmark
Ryzen 5 3600 Server 64 GB RAM, 2x480 GB NVMe CPU Benchmark: 17849
Ryzen 7 7700 Server 64 GB DDR5 RAM, 2x1 TB NVMe CPU Benchmark: 35224
Ryzen 9 5950X Server 128 GB RAM, 2x4 TB NVMe CPU Benchmark: 46045
Ryzen 9 7950X Server 128 GB DDR5 ECC, 2x2 TB NVMe CPU Benchmark: 63561
EPYC 7502P Server (128GB/1TB) 128 GB RAM, 1 TB NVMe CPU Benchmark: 48021
EPYC 7502P Server (128GB/2TB) 128 GB RAM, 2 TB NVMe CPU Benchmark: 48021
EPYC 7502P Server (128GB/4TB) 128 GB RAM, 2x2 TB NVMe CPU Benchmark: 48021
EPYC 7502P Server (256GB/1TB) 256 GB RAM, 1 TB NVMe CPU Benchmark: 48021
EPYC 7502P Server (256GB/4TB) 256 GB RAM, 2x2 TB NVMe CPU Benchmark: 48021
EPYC 9454P Server 256 GB RAM, 2x2 TB NVMe

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⚠️ *Note: All benchmark scores are approximate and may vary based on configuration. Server availability subject to stock.* ⚠️

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