Template:Infobox Server Configuration

Technical Documentation: Server Configuration Template:Stub

This document provides a comprehensive technical analysis of the Template:Stub reference configuration. This configuration is designed to serve as a standardized, baseline hardware specification against which more advanced or specialized server builds are measured. While the "Stub" designation implies a minimal viable product, its components are selected for stability, broad compatibility, and cost-effectiveness in standardized data center environments.

1. Hardware Specifications

The Template:Stub configuration prioritizes proven, readily available components that offer a balanced performance-to-cost ratio. It is designed to fit within standard 2U rackmount chassis dimensions, although specific chassis models may vary.

1.1. Central Processing Units (CPUs)

The configuration mandates a dual-socket (2P) architecture to ensure sufficient core density and memory channel bandwidth for general-purpose workloads.

Template:Stub CPU Configuration

Specification	Detail (Minimum Requirement)	Detail (Recommended Baseline)
Architecture	Intel Xeon Scalable (Cascade Lake or newer preferred) or AMD EPYC (Rome or newer preferred)	Intel Xeon Scalable Gen 3 (Ice Lake) or AMD EPYC Gen 3 (Milan)
Socket Count	2	2
Base TDP Range	95W – 135W per socket	120W – 150W per socket
Minimum Cores per Socket	12 Physical Cores	16 Physical Cores
Minimum Frequency (All-Core Turbo)	2.8 GHz	3.1 GHz
L3 Cache (Total)	36 MB Minimum	64 MB Minimum
Supported Memory Channels	6 or 8 Channels per socket	8 Channels per socket (for optimal I/O)

The selection of the CPU generation is crucial; while older generations may fit the "stub" moniker, modern stability and feature sets (such as AVX-512 or PCIe 4.0 support) are mandatory for baseline compatibility with contemporary operating systems and hypervisors.

1.2. Random Access Memory (RAM)

Memory capacity and speed are provisioned to support moderate virtualization density or large in-memory datasets typical of database caching layers. The configuration specifies DDR4 ECC Registered DIMMs (RDIMMs) or Load-Reduced DIMMs (LRDIMMs) depending on the required density ceiling.

Template:Stub Memory Configuration

Specification	Detail
Type	DDR4 ECC RDIMM/LRDIMM (DDR5 requirement for future revisions)
Total Capacity (Minimum)	128 GB
Total Capacity (Recommended)	256 GB
Configuration Strategy	Fully populated memory channels (e.g., 8 DIMMs per CPU or 16 total)
Speed Rating (Minimum)	2933 MT/s
Speed Rating (Recommended)	3200 MT/s (or fastest supported by CPU/Motherboard combination)
Maximum Supported DIMM Rank	Dual Rank (2R) preferred for stability

It is critical that the BIOS/UEFI is configured to utilize the maximum supported memory speed profile (e.g., XMP or JEDEC profiles) while maintaining stability under full load, adhering strictly to the Memory Interleaving guidelines for the specific motherboard chipset.

1.3. Storage Subsystem

The storage configuration emphasizes a tiered approach: a high-speed boot/OS volume and a larger, redundant capacity volume for application data. Direct Attached Storage (DAS) is the standard implementation.

Template:Stub Storage Layout (DAS)

Tier	Component Type	Quantity	Capacity (per unit)	Interface/Protocol
Boot/OS	NVMe M.2 or U.2 SSD	2 (Mirrored)	480 GB Minimum	PCIe 3.0/4.0 x4
Data/Application	SATA or SAS SSD (Enterprise Grade)	4 to 6	1.92 TB Minimum	SAS 12Gb/s (Preferred) or SATA III
RAID Controller	Hardware RAID (e.g., Broadcom MegaRAID)	1	N/A	PCIe 3.0/4.0 x8 interface required

The data drives must be configured in a RAID 5 or RAID 6 array for redundancy. The use of NVMe for the OS tier significantly reduces boot times and metadata access latency, a key improvement over older SATA-based stub configurations. Refer to RAID Levels documentation for specific array geometry recommendations.

1.4. Networking and I/O

Standardization on 10 Gigabit Ethernet (10GbE) is required for the management and primary data interfaces.

Template:Stub Networking and I/O

Component	Specification	Purpose
Primary Network Interface (Data)	2 x 10GbE SFP+ or Base-T (Configured in LACP/Active-Passive)	Application Traffic, VM Networking
Management Interface (Dedicated)	1 x 1GbE (IPMI/iDRAC/iLO)	Out-of-Band Management
PCIe Slots Utilization	At least 2 x PCIe 4.0 x16 slots populated (for future expansion or high-speed adapters)	Expansion for SAN connectivity or specialized accelerators

The onboard Baseboard Management Controller (BMC) must support modern standards, including HTML5 console redirection and secure firmware updates.

1.5. Power and Form Factor

The configuration is designed for high-density rack deployment.

• **Form Factor:** 2U Rackmount Chassis (Standard 19-inch width).
• **Power Supplies (PSUs):** Dual Redundant, Hot-Swappable, Platinum or Titanium Efficiency Rating (>= 92% efficiency at 50% load).
• **Total Rated Power Draw (Peak):** Approximately 850W – 1100W (dependent on CPU TDP and storage configuration).
• **Input Voltage:** 200-240V AC (Recommended for efficiency, though 110V support must be validated).

2. Performance Characteristics

The performance profile of the Template:Stub is defined by its balanced memory bandwidth and core count, making it a suitable platform for I/O-bound tasks that require moderate computational throughput.

2.1. Synthetic Benchmarks (Estimated)

The following benchmarks reflect expected performance based on the recommended component specifications (Ice Lake/Milan generation CPUs, 3200MT/s RAM).

Template:Stub Estimated Synthetic Performance

Benchmark Area	Metric	Expected Result Range	Notes
CPU Compute (Integer/Floating Point)	SPECrate 2017 Integer (Base)	450 – 550	Reflects multi-threaded efficiency.
Memory Bandwidth (Aggregate)	Read/Write (GB/s)	180 – 220 GB/s	Dependent on DIMM population and CPU memory controller quality.
Storage IOPS (Random 4K Read)	Sustained IOPS (from RAID 5 Array)	150,000 – 220,000 IOPS	Heavily influenced by RAID controller cache and drive type.
Network Throughput	TCP/IP Throughput (iperf3)	19.0 – 19.8 Gbps (Full Duplex)	Testing 2x 10GbE bonded link.

The key performance bottleneck in the Stub configuration, particularly when running high-vCPU density workloads, is often the memory subsystem's latency profile rather than raw core count, especially when the operating system or application attempts to access data across the Non-Uniform Memory Access boundary between the two sockets.

2.2. Real-World Performance Analysis

The Stub configuration excels in scenarios demanding high I/O consistency rather than peak computational burst capacity.

• **Database Workloads (OLTP):** Handles transactional loads requiring moderate connections (up to 500 concurrent active users) effectively, provided the working set fits within the 256GB RAM allocation. Performance degradation begins when the workload triggers significant page faults requiring reliance on the SSD tier.
• **Web Serving (Apache/Nginx):** Capable of serving tens of thousands of concurrent requests per second (RPS) for static or moderately dynamic content, limited primarily by network saturation or CPU instruction pipeline efficiency under heavy SSL/TLS termination loads.
• **Container Orchestration (Kubernetes Node):** Functions optimally as a worker node supporting 40-60 standard microservices containers, where the CPU cores provide sufficient scheduling capacity, and the 10GbE networking allows for rapid service mesh communication.

3. Recommended Use Cases

The Template:Stub configuration is not intended for high-performance computing (HPC) or extreme data analytics but serves as an excellent foundation for robust, general-purpose infrastructure.

3.1. Virtualization Host (Mid-Density)

This configuration is ideal for hosting a consolidated environment where stability and resource isolation are paramount.

• **Target Density:** 8 to 15 Virtual Machines (VMs) depending on the VM profile (e.g., 8 powerful Windows Server VMs or 15 lightweight Linux application servers).
• **Hypervisor Support:** Full compatibility with VMware vSphere, Microsoft Hyper-V, and Kernel-based Virtual Machine.
• **Benefit:** The dual-socket architecture ensures sufficient PCIe lanes for multiple virtual network interface cards (vNICs) and provides ample physical memory for guest allocation.

3.2. Application and Web Servers

For standard three-tier application architectures, the Stub serves well as the application or web tier.

• **Backend API Tier:** Suitable for hosting RESTful services written in languages like Java (Spring Boot), Python (Django/Flask), or Go, provided the application memory footprint remains within the physical RAM limits.
• **Load Balancing Target:** Excellent as a target for Network Load Balancing (NLB) clusters, offering predictable latency and throughput.

3.3. Jump Box / Bastion Host and Management Server

Due to its robust, standardized hardware, the Stub is highly reliable for critical management functions.

• **Configuration Management:** Running Ansible Tower, Puppet Master, or Chef Server. The storage subsystem provides fast configuration deployment and log aggregation.
• **Monitoring Infrastructure:** Hosting Prometheus/Grafana or ELK stack components (excluding large-scale indexing nodes).

3.4. File and Backup Target

When configured with a higher count of high-capacity SATA/SAS drives (exceeding the 6-drive minimum), the Stub becomes a capable, high-throughput Network Attached Storage (NAS) target utilizing technologies like ZFS or Windows Storage Spaces.

4. Comparison with Similar Configurations

To contextualize the Template:Stub, it is useful to compare it against its immediate predecessors (Template:Legacy) and its successors (Template:HighDensity).

4.1. Configuration Matrix Comparison

Configuration Comparison Table

Feature	Template:Stub (Baseline)	Template:Legacy (10/12 Gen Xeon)	Template:HighDensity (1S/HPC Focus)
CPU Sockets	2P	2P	1S (or 2P with extreme core density)
Max RAM (Typical)	256 GB	128 GB	768 GB+
Primary Storage Interface	PCIe 4.0 NVMe (OS) + SAS/SATA SSDs	PCIe 3.0 SATA SSDs only	All NVMe U.2/AIC
Network Speed	10GbE Standard	1GbE Standard	25GbE or 100GbE Mandatory
Power Efficiency Rating	Platinum/Titanium	Gold	Titanium (Extreme Density Optimization)
Cost Index (Relative)	1.0x	0.6x	2.5x+

The Stub configuration represents the optimal point for balancing current I/O requirements (10GbE, PCIe 4.0) against legacy infrastructure compatibility, whereas the Template:Legacy is constrained by slower interconnects and less efficient power delivery.

4.2. Performance Trade-offs

The primary trade-off when moving from the Stub to the Template:HighDensity configuration involves the shift from balanced I/O to raw compute.

• **Stub Advantage:** Superior I/O consistency due to the dedicated RAID controller and dual-socket memory architecture providing high aggregate bandwidth.
• **HighDensity Disadvantage (in this context):** Single-socket (1S) high-density configurations, while offering more cores per watt, often suffer from reduced memory channel access (e.g., 6 channels vs. 8 channels per CPU), leading to lower sustained memory bandwidth under full virtualization load.

5. Maintenance Considerations

Maintaining the Template:Stub requires adherence to standard enterprise server practices, with specific attention paid to thermal management due to the dual-socket high-TDP components.

5.1. Thermal Management and Cooling

The dual-socket design generates significant heat, necessitating robust cooling infrastructure.

• **Airflow Requirements:** Must maintain a minimum front-to-back differential pressure of 0.4 inches of water column (in H2O) across the server intake area.
• **Component Specifics:** CPUs rated above 150W TDP require high-static pressure fans integrated into the chassis, often exceeding the performance of standard cooling solutions designed for single-socket, low-TDP hardware.
• **Hot Aisle Containment:** Deployment within a hot-aisle/cold-aisle containment strategy is highly recommended to maximize chiller efficiency and prevent thermal throttling, especially during peak operation when all turbo frequencies are engaged.

5.2. Power Requirements and Redundancy

The redundant power supplies (N+1 or 2N configuration) must be connected to diverse power paths whenever possible.

• **PDU Load Balancing:** The total calculated power draw (approaching 1.1kW peak) means that servers should be distributed across multiple Power Distribution Units (PDUs) to avoid overloading any single circuit breaker in the rack infrastructure.
• **Firmware Updates:** Regular firmware updates for the BMC, BIOS/UEFI, and RAID controller are mandatory to ensure compatibility with new operating system kernels and security patches (e.g., addressing Spectre variants).

5.3. Operating System and Driver Lifecycle

The longevity of the Stub configuration relies heavily on vendor support for the chosen CPU generation.

• **Driver Validation:** Before deploying any major OS patch or hypervisor upgrade, all hardware drivers (especially storage controller and network card firmware) must be validated against the vendor's Hardware Compatibility List (HCL).
• **Diagnostic Tools:** The BMC must be configured to stream diagnostic logs (e.g., Intelligent Platform Management Interface sensor readings) to a central System Monitoring platform for proactive failure prediction.

The stability of the Template:Stub ensures that maintenance windows are predictable, typically only required for major component replacements (e.g., PSU failure or expected drive rebuilds) rather than frequent stability patches.

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.* ⚠️

1. Colocation Server – Technical Documentation

This document details the technical specifications, performance characteristics, recommended use cases, comparisons, and maintenance considerations for a typical "Colocation Server" configuration. This configuration targets businesses and organizations needing dedicated server resources without the upfront capital expenditure and ongoing operational overhead of owning and maintaining their own data center. The specifications outlined are representative of a mid-range, high-performance colocation offering, and can be customized based on specific client needs. This article assumes a baseline understanding of Server Hardware and Data Center Infrastructure.

1. Hardware Specifications

The following specifications represent a commonly deployed colocation server. Exact specifications will vary depending on the provider and selected tier. This configuration prioritizes a balance between performance, reliability, and cost-effectiveness.

Component	Specification	Details
**CPU**	Dual Intel Xeon Gold 6338 (2.0 GHz, up to 3.4 GHz Turbo)	32 Cores / 64 Threads per CPU, Total 64 Cores / 128 Threads. Supports AVX-512 instruction set for accelerated workloads. CPU Cooling is crucial.
**RAM**	256 GB DDR4 ECC Registered 3200MHz	8 x 32GB Modules. ECC (Error-Correcting Code) provides increased reliability. Registered DIMMs improve stability at high capacities. Memory Management is critical for optimal performance.
**Storage – Primary (OS)**	2 x 480GB NVMe PCIe Gen4 SSD	RAID 1 configuration for redundancy. High IOPS and low latency for operating system and frequently accessed files. Utilizes NVMe Protocol for superior performance.
**Storage – Secondary (Data)**	8 x 4TB SAS 12Gbps 7.2K RPM HDD	RAID 6 configuration for data protection and capacity. Suitable for large data storage with moderate performance requirements. RAID Configuration provides data redundancy.
**Network Interface**	Dual 10 Gigabit Ethernet (10GbE)	Redundant network connectivity. Supports VLAN Tagging and Bonding. Can be upgraded to 25GbE or 40GbE for higher bandwidth requirements.
**Remote Management**	IPMI 2.0 with Dedicated Network Port	Allows out-of-band management for remote power control, KVM-over-IP access, and system monitoring. IPMI is vital for remote administration.
**Power Supply**	2 x 800W 80+ Platinum Redundant Power Supplies	Provides power redundancy and high efficiency. Supports wide voltage range (100-240VAC). Power Distribution Unit (PDU) compatibility is essential.
**Chassis**	2U Rackmount Server	Standard 19-inch rackmount form factor. Designed for optimal airflow. Server Rack considerations are paramount.
**Motherboard**	Supermicro X12DPG-QT6	Dual Socket LGA 4189. Supports the specified CPUs and RAM. Includes multiple PCIe slots for expansion. Motherboard Architecture is foundational to server performance.
**Operating System**	Client-Provided (Supported OS: Linux Distributions, Windows Server)	The customer is responsible for OS installation and licensing. Operating System Considerations are important for compatibility and security.

2. Performance Characteristics

The performance of this colocation server is dependent on the specific workload. The following benchmarks provide a general indication of its capabilities. Testing was performed in a controlled colocation environment with consistent cooling and power.

• **CPU Performance (SPECint 2017):** Approximately 260 (Normalized score) – Demonstrates strong integer processing capabilities, suitable for database servers and application servers. CPU Benchmarking is a standard practice for evaluating performance.
• **CPU Performance (SPECfp 2017):** Approximately 180 (Normalized score) – Indicates good floating-point performance, useful for scientific computing and simulations.
• **Storage Performance (IOPS – Primary):** Up to 700,000 IOPS (Random Read/Write) – The NVMe SSDs provide extremely fast storage performance.
• **Storage Performance (Throughput – Secondary):** Up to 2.5 GB/s (Sequential Read/Write) – The SAS HDDs offer good throughput for large file transfers.
• **Network Performance:** 10 Gbps sustained throughput. Latency typically under 1ms within the colocation facility. Network Performance Monitoring is crucial for identifying bottlenecks.

• • Real-World Performance Examples:**

• **Web Server (Apache/Nginx):** Capable of handling thousands of concurrent requests with low latency.
• **Database Server (MySQL/PostgreSQL):** Supports large databases and complex queries with good response times.
• **Application Server (Java/Python):** Provides sufficient resources for running demanding applications.
• **Virtualization Host (VMware/KVM):** Can host multiple virtual machines with reasonable performance. Virtualization Technology is a common use case.

3. Recommended Use Cases

This colocation server configuration is well-suited for a variety of applications, including:

• **Web Hosting:** Reliable and scalable hosting for websites, web applications, and e-commerce platforms.
• **Database Hosting:** Hosting of relational databases (MySQL, PostgreSQL, SQL Server) and NoSQL databases (MongoDB, Cassandra). Database Administration is vital for optimal database performance.
• **Application Hosting:** Running business-critical applications, such as ERP, CRM, and SCM systems.
• **Virtualization:** Hosting virtual machines for development, testing, and production environments.
• **Gaming Servers:** Hosting online game servers for a smooth and responsive gaming experience.
• **Backup and Disaster Recovery:** Providing a secure and reliable location for data backups and disaster recovery solutions. Data Backup Strategies are essential for data protection.
• **Big Data Analytics:** Processing and analyzing large datasets for business intelligence and data mining.
• **Media Streaming:** Delivering video and audio content to a global audience.
• **Scientific Computing:** Running computationally intensive simulations and models.

4. Comparison with Similar Configurations

The following table compares this colocation server configuration with other common options.

Configuration	CPU	RAM	Storage	Network	Cost (Approx. Monthly)	Use Cases
**Entry-Level Colocation**	Dual Intel Xeon E-2324G	64GB DDR4	2 x 480GB SSD	1GbE	$300 - $500	Small Websites, Development Servers, Basic Application Hosting
**Mid-Range Colocation (This Configuration)**	Dual Intel Xeon Gold 6338	256GB DDR4	2 x 480GB NVMe + 8 x 4TB SAS	10GbE	$800 - $1200	Database Servers, Application Servers, Virtualization Hosts, Medium-Sized Websites
**High-End Colocation**	Dual Intel Xeon Platinum 8380	512GB DDR4	4 x 1.92TB NVMe + 16 x 8TB SAS	40GbE	$1500 - $2500+	Large-Scale Databases, High-Performance Computing, Mission-Critical Applications, Large Virtualization Environments
**Cloud Server (AWS EC2 Equivalent)**	Variable (Based on Instance Type)	Variable	Variable	Variable	Variable (Pay-as-you-go)	Scalable Applications, Development/Testing, Burst Capacity

• • Key Considerations:**

• **Cost:** Colocation offers a predictable monthly cost, while cloud servers offer pay-as-you-go pricing.
• **Control:** Colocation provides greater control over hardware and software configurations.
• **Scalability:** Cloud servers are generally more scalable than colocation servers.
• **Security:** Colocation facilities offer robust physical security, but the customer is responsible for OS and application security. Server Security Best Practices are crucial.
• **Maintenance:** Colocation providers handle hardware maintenance, while the customer is responsible for software maintenance.

5. Maintenance Considerations

Maintaining a colocation server requires careful planning and coordination with the colocation provider.

• **Cooling:** Colocation facilities provide redundant cooling systems to maintain optimal server temperatures. However, it's essential to ensure that the server chassis is properly ventilated and that airflow is not obstructed. Data Center Cooling Techniques are vital for preventing overheating.
• **Power:** Redundant power supplies are critical. The colocation provider provides redundant power feeds and Uninterruptible Power Supplies (UPS) to protect against power outages. Monitor power consumption to ensure it stays within allocated limits.
• **Remote Management:** Utilize the IPMI interface for remote monitoring, power control, and troubleshooting.
• **Security:** Implement strong security measures, including firewalls, intrusion detection systems, and regular security audits. Network Security Protocols are essential.
• **Operating System Updates:** Regularly update the operating system and applications to patch security vulnerabilities and improve performance.
• **Data Backups:** Implement a robust data backup strategy to protect against data loss. Consider offsite backups for disaster recovery.
• **Physical Access:** Understand the colocation provider's physical access policies and procedures.
• **Hardware Monitoring:** Utilize server monitoring tools to track CPU usage, memory usage, disk I/O, and network traffic. Server Monitoring Tools are invaluable for proactive maintenance.
• **Rack Space:** Understand the limitations of rack space and power density within the colocation facility.
• **Connectivity:** Ensure network connectivity is stable and reliable. Monitor network latency and bandwidth usage.
• **Vendor Support:** Establish a clear support plan with both the colocation provider and any hardware vendors.

This documentation provides a comprehensive overview of a typical colocation server configuration. It is important to consult with the colocation provider to discuss specific requirements and customize the configuration to meet individual needs. Regular review of this documentation and adaptation to evolving technologies are recommended.

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.* ⚠️