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IBM System p

The IBM System p was a family of high-performance, scalable server computers introduced by IBM in October 2005, featuring the POWER5 and subsequent POWER5+ processors and designed primarily for enterprise workloads running AIX and Linux operating systems.^[1] These servers succeeded the earlier pSeries line, which had evolved from the RS/6000 series since the 1990s, and emphasized modularity, reliability, and advanced resource management to handle demanding applications in areas like e-business, scientific computing, and database processing.^[2] A defining feature of the System p was its integration of Advanced POWER Virtualization (APV), introduced with the POWER5 generation, which enabled technologies such as Micro-Partitioning for fine-grained allocation of CPU resources across multiple logical partitions, shared processor pools, and the Virtual I/O Server (VIOS) for virtualized storage and networking.^[2] This allowed up to 254 micro-partitions per system in high-end models, supporting dynamic resource adjustments via Dynamic Logical Partitioning (DLPAR) and Simultaneous Multithreading (SMT) for enhanced performance without dedicated hardware silos.^[2]^[3] Key models included the entry-level System p5 505 and 510 Express for rack-optimized deployments, mid-range p5 550 and 570 for balanced scalability, and high-end p5 590 and 595 capable of up to 64 cores and massive memory configurations for mission-critical environments.^[4]^[5] The platform's open architecture also facilitated Linux distributions from vendors like Red Hat and SUSE, broadening its appeal for heterogeneous computing.^[2] In April 2008, IBM rebranded and unified the System p with the midrange System i platform—previously focused on integrated business computing—into the broader IBM Power Systems family, leveraging the same POWER hardware base while preserving distinct operating environments like AIX/UNIX and IBM i.^[6] This merger streamlined IBM's server portfolio, enhancing hybrid capabilities for virtualization across workloads and paving the way for future POWER generations, though System p models remained supported through extended service until the early 2010s.^[6] The System p era marked a pivotal advancement in POWER-based computing, prioritizing efficiency and consolidation in data centers.

History

Origins and Early Development

The IBM System p lineage traces its origins to the RISC System/6000 (RS/6000), introduced by IBM in February 1990 as the company's first family of RISC-based UNIX servers and workstations.^[7] This platform represented a significant pivot from IBM's earlier proprietary mainframe (such as System/370) and minicomputer (such as System/3) architectures, which were optimized for business data processing, toward scalable, open-systems computing tailored for technical and scientific workloads.^[7] The RS/6000 emphasized high-performance computing for engineering simulations, scientific modeling, and graphics-intensive applications, filling a gap in IBM's portfolio where UNIX-based systems from competitors like Sun Microsystems dominated.^[8] At launch, the RS/6000 utilized IBM's newly developed POWER1 processor, a superscalar RISC design clocked at 20-30 MHz in initial models like the 320 and 540, delivering up to 11 MFLOPS on LINPACK benchmarks for floating-point operations.^[9]^[10] Integrated with AIX version 3, a POSIX-compliant UNIX operating system derived from AT&T System V Release 2 and 3 with BSD enhancements, the platform supported multi-user, multi-tasking environments and featured separate instruction and data caches for efficient execution.^[11] Early commercial deployments targeted research institutions and engineering firms, where the systems' price-to-performance ratio—often cited as superior to Sun's SPARC-based workstations—enabled rapid adoption for compute-intensive tasks like finite element analysis and CAD.^[8] For instance, the RS/6000 Model 540 achieved leading SPECfp89 scores, outperforming Sun-4 models in floating-point benchmarks while maintaining comparable pricing.^[12] Development accelerated through strategic partnerships, notably the AIM alliance formed in 1991 between IBM, Apple Computer, and Motorola to create a common RISC processor architecture.^[7] This collaboration refined the POWER instruction set into the PowerPC standard, but IBM independently advanced its server line with the POWER2 processor in 1993, which operated at up to 71.5 MHz and doubled floating-point throughput over the POWER1 for demanding scientific applications.^[13] These innovations solidified the RS/6000's role as a foundational platform for what would evolve into the System p family.

Branding Evolution and Key Milestones

In October 2000, IBM transitioned its RS/6000 server line to the eServer pSeries branding as part of a broader eServer strategy that unified its server offerings under a common "e" prefix for enhanced e-business focus.^[14] This rebranding aligned the POWER-based UNIX servers with IBM's evolving enterprise computing vision, retiring the RS/6000 name for servers while retaining it briefly for workstations until 2002.^[7] The eServer pSeries line saw significant evolution in 2004 with the introduction of the eServer p5 series, powered by the new POWER5 processors, which enabled advanced features like simultaneous multithreading and Micro-Partitioning for improved resource utilization in UNIX and Linux environments.^[15] This launch on July 13, 2004, marked a key milestone in performance advancement, positioning the pSeries as a competitive force in high-end computing.^[16] In 2003, IBM consolidated its UNIX server portfolio under the pSeries umbrella with enhancements to models like the p670 (introduced May 2003) and p690 (introduced 2001), integrating capacity on demand and advanced partitioning to streamline deployments and support workload consolidation.^[17] By 2005, IBM shifted to the System branding initiative, launching the System p5 servers on October 4, which continued to emphasize support for AIX 5L and Linux distributions through enhanced scalability and virtualization capabilities.^[1] This rebranding reflected IBM's streamlining of server and storage lines into the "System" family for clearer market positioning. In 2006, the lineup evolved further into the System p series, incorporating POWER5+ technologies while prioritizing AIX 5L compatibility and native Linux integration for enterprise applications.^[18] A pivotal 2007 milestone was the introduction of PowerVM as the unified virtualization platform (announced January 2007) for System p, enabling advanced logical partitioning and live migration to optimize resource sharing across AIX, Linux, and IBM i workloads, alongside the May 2007 launch of POWER6-based systems.^[19] The System p brand concluded as a standalone line in April 2008, when IBM merged it with System i into the unified Power Systems family to simplify offerings and leverage common POWER architecture across platforms.^[6] During its peak in the mid-2000s, System p and predecessor pSeries lines saw significant revenue growth, with pSeries up 15% in 2005, driven by strong demand in UNIX server markets and virtualization adoption.^[20]

Architecture

Processor Technology

The IBM System p servers utilized processors based on the POWER architecture, with the POWER5, launched in 2004 and foundational to the 2005 System p introduction, advancing to 1.9 GHz with dual cores and introducing simultaneous multithreading (SMT), supporting up to 64-way SMP in high-end models like the p5 595.^[21]^[22] The POWER5+ (2005) was a 90 nm shrink of the POWER5, operating at 1.5-2.2 GHz with a similar dual-core SMT design but improved efficiency and reduced power consumption.^[21] By 2007, the POWER6 reached up to 5.0 GHz in dual-core designs, maintaining scalability to 64-way SMP while incorporating IEEE 754r-compliant decimal floating-point capabilities for financial and transactional workloads.^[22] Key innovations across these processors addressed performance bottlenecks in enterprise environments. The POWER5 introduced SMT with two threads per core, allowing efficient resource utilization in multithreaded applications and providing significant improvements, with modeling showing 35-40% capacity gains in throughput-oriented workloads, alongside instruction set extensions for virtualization and large-page memory support.^[23]^[21] In the POWER6, a dedicated decimal floating-point unit accelerated precise arithmetic operations essential for banking and ERP systems, eliminating software emulation overhead and complying with industry standards for decimal data handling. These features, integrated into the POWER ISA versions (e.g., v2.02 for POWER5, and v2.05 for POWER6), optimized for scalable enterprise processing without relying on earlier 32-bit-only modes.^[21]^[22] Typical configurations highlighted the processors' balance of speed, density, and efficiency. For instance, the POWER5 featured dual cores at 1.9 GHz, with 1.9 MB shared L2 cache and 36 MB L3 cache per chip, supporting up to four logical threads via SMT for parallel enterprise tasks.^[21] The POWER6 offered dual cores at up to 5.0 GHz, 4 MB L2 cache per core, and 32 MB shared L3 cache per module, enhancing bandwidth for database and analytics workloads.^[22] All generations operated natively in 64-bit mode, addressing vast memory spaces (up to terabytes) and complex addressing required for large-scale SMP systems, while maintaining backward compatibility with 32-bit PowerPC applications through mode-switching mechanisms that preserved legacy software performance without hardware reconfiguration. This 64-bit emphasis enabled scalability to 64-way SMP in System p high-end models, facilitating clustered deployments for demanding commercial computing.^[21]^[22]

Hardware Design and Features

The IBM System p servers featured modular chassis designs that enabled flexible configurations for deskside, rack-mounted, or high-density blade form factors, optimized for enterprise workloads. These chassis incorporated partitioned hardware supporting logical partitioning (LPAR), allowing up to 64 partitions per system to isolate workloads and enhance resource utilization without dedicated physical separation.^[24] This design facilitated dynamic resource allocation across partitions, with support for both dedicated and shared processor modes in high-end models like the p5-595. Memory subsystems in System p utilized DDR2 SDRAM, with high-end configurations supporting up to 2 TB in models such as the p5-595, enabling large-scale in-memory processing for demanding applications. Storage integration included built-in SAS and SATA controllers, providing connectivity for hot-swappable disk bays with capacities reaching several terabytes; these supported RAID levels 0, 1, 5, 6, and 10 for data redundancy and performance optimization.^[3]^[25] I/O architectures emphasized high-bandwidth connectivity, featuring PCI-X slots operating at 133 MHz and early adoption of PCIe with up to 8 lanes for enhanced throughput in peripheral expansions. Options for 10 Gigabit Ethernet adapters were available, alongside the Host Ethernet Adapter (HEA), which integrated virtual Ethernet capabilities directly into the system hypervisor for efficient network virtualization without additional hardware.^[25] Power and cooling systems prioritized reliability and efficiency, incorporating redundant hot-swappable power supplies rated up to 2000 W and matching cooling fans to minimize downtime. During the POWER5 era, design innovations such as smaller die sizes and dynamic power management reduced overall power consumption compared to prior generations, contributing to energy-efficient operations in data centers.^[25]^[26] Scalability extended beyond single systems through cluster support via Cluster Systems Management (CSM), enabling configurations of up to 64 nodes (higher quantities available by special bid) for distributed computing environments, managed centrally for workload balancing and fault tolerance.^[27]

Software Support and Virtualization

The primary operating system for IBM System p servers is AIX, with supported versions ranging from AIX 5L (introduced for POWER architecture) through AIX 6.1, providing robust Unix-like functionality optimized for enterprise workloads.^[28] AIX on System p includes the Journaled File System 2 (JFS2), which supports large file sizes up to 16 TB and enhanced scalability for high-performance storage environments, introduced in AIX 5.1 and refined in subsequent releases.^[29] Additionally, the Workload Manager (WLM) feature enables resource partitioning by grouping processes into classes and allocating CPU, memory, and I/O based on defined policies, allowing administrators to prioritize critical applications and ensure service level agreements are met.^[30] IBM System p also supports major Linux distributions, with certifications beginning in 2003 for POWER processors; Red Hat Enterprise Linux (RHEL) AS 3 was updated in 2004 to fully support System p5 hardware, enabling deployment of open-source applications on partitioned environments.^[31] Similarly, SUSE Linux Enterprise Server (SLES) has been certified since early versions like SLES 9, providing kernel-level optimizations for POWER architecture and integration with System p's virtualization capabilities for consolidated server deployments.^[32] Virtualization on IBM System p is powered by PowerVM (previously known as Advanced POWER Virtualization), which facilitates logical partitioning (LPAR) to divide physical hardware into isolated virtual servers, supporting dynamic resource allocation without downtime.^[33] Key features include micro-partitioning, allowing up to 254 partitions per system with granular CPU entitlements as small as 0.1 processing units, enabling efficient resource sharing across diverse workloads.^[3] For entry-level systems without a dedicated management console, the Integrated Virtualization Manager (IVM) provides built-in tools to create and manage LPARs directly from a partition running the Virtual I/O Server (VIOS).^[34] System management for IBM System p relies on tools like the Hardware Management Console (HMC), a dedicated appliance for remote configuration, monitoring, and maintenance of multiple servers and their partitions from a centralized interface.^[35] Complementing the HMC, IBM Systems Director offers a platform-independent foundation for aggregating system data, automating tasks, and integrating with heterogeneous environments to streamline operations across physical and virtual resources.^[36] Security in the System p ecosystem is enhanced by Trusted AIX, which implements multilevel security (MLS) to process data at varying classification levels, meeting standards like the U.S. Department of Defense's Trusted Computer System Evaluation Criteria (TCSEC).^[37] Trusted AIX integrates Role-Based Access Control (RBAC), allowing fine-grained delegation of administrative privileges without granting full root access, thereby reducing risk in multi-user enterprise settings.^[38]

Server Models

pSeries Line

The pSeries line marked IBM's rebranding and advancement of its UNIX-based server portfolio, succeeding the RS/6000 series and emphasizing scalability for emerging e-business environments from 2000 to 2004. These servers integrated evolving POWER processor technology with enhanced reliability features, targeting midrange applications such as web hosting and transaction processing, as well as high-end workloads in database management and analytics. Key innovations included the commercial debut of the POWER4 processor architecture, which introduced dual-core designs and shared caches for improved throughput, alongside copper interconnects that enhanced signal integrity and reduced latency compared to aluminum wiring in prior generations.^[39]^[40] The pSeries 630, announced in August 2002, served as an entry-to-midrange model with up to four POWER4 processors at 1.0 GHz (upgradable to POWER4+ at 1.45 GHz), providing scalable symmetric multiprocessing for cost-effective deployments in e-business and departmental computing. It supported up to 32 GB of RAM and AIX 5L, enabling logical partitioning for virtualized environments and hot-plug components for minimal downtime. This model addressed growing demands for reliable, compact servers in telecommunications and small-scale database operations, offering a balance of performance and affordability.^[41]^[42] At the high end, the pSeries 690, launched in October 2001 as the first commercial system with POWER4 processors at 1.3 GHz, supported up to 32-way configurations ideal for high-performance computing and large-scale analytics. With a maximum of 256 GB RAM and AIX 5L support for dynamic logical partitioning, it facilitated server consolidation and workload isolation, achieving up to 10 times the performance of RS/6000 predecessors in SPEC CPU2000 benchmarks due to its multi-chip module design and high-bandwidth interconnects. Targeted at enterprise database servers and scientific simulations, the p690's copper-based wiring further bolstered reliability in demanding 24x7 operations.^[39] Building on this, the pSeries 595, introduced in February 2003, utilized POWER4+ processors at up to 1.5 GHz in 32-way enterprise configurations, optimizing for mission-critical analytics and transaction-heavy environments. It extended AIX 5L capabilities with advanced virtualization and up to 512 GB RAM, delivering sustained performance for data warehousing and ERP systems while inheriting the p690's reliability innovations like copper wiring for fault-tolerant operations. These models collectively drove adoption in sectors requiring robust, scalable UNIX computing before transitioning to POWER5-based systems in 2004.^[41]^[43]

eServer p5 and System p5

The eServer p5 and System p5 series, launched in 2004, introduced IBM's POWER5 dual-core processor technology to its UNIX server lineup, enabling enhanced symmetric multiprocessing (SMP) capabilities and marking a significant evolution from prior pSeries models. These systems supported AIX 5L and Linux distributions, with features like Micro-Partitioning for virtualization that allowed fine-grained resource allocation to improve efficiency. The series emphasized scalability for enterprise workloads, including database management and high-performance computing, while facilitating server consolidation by reducing the physical footprint compared to distributed x86 environments.^[44]^[45] Key entry-level models included the eServer p5 505, a compact 1U rack-mount server announced on October 4, 2005, featuring 1 or 2 single-core or dual-core POWER5 processors at speeds up to 1.65 GHz, suitable for file serving, web applications, and small-scale clustering. For midrange needs, the System p5 575, introduced in late 2005 with general availability in early 2006, offered 8 to 16 cores using dual-core POWER5+ processors at 1.9 GHz or 2.2 GHz, in a 4U form factor optimized for high-performance computing tasks such as scientific simulations and financial modeling. Enterprise-grade options were exemplified by the eServer p5 570, announced July 13, 2004, which scaled from 4 to 16 cores with POWER5 or POWER5+ processors at frequencies up to 2.2 GHz, providing up to 512 GB of DDR2 RAM in a modular 4U-per-building-block design for large databases and on-demand business operations.^[46]^[47]^[48] Design advances in the series centered on the POWER5 processor's dual-core architecture, which first enabled efficient SMP configurations by presenting multiple cores as a unified multiprocessor to the operating system, with subsequent POWER5+ enhancements supporting quad-core modules that appeared as four-way SMP units. The high-end System p5 595 exemplified this scalability, supporting up to 64 cores in SMP mode using POWER5+ processors at 2.1 GHz or 2.3 GHz, with a maximum of 2 TB DDR1 or DDR2 RAM and theoretical memory bandwidth exceeding 500 GB/s through distributed architecture and high-speed interconnects. These innovations improved throughput for parallel processing while incorporating reliability features like error-correcting code (ECC) memory and dynamic logical partitioning.^[21]^[3] The p5 series excelled in use cases involving x86 server consolidation, where virtualization technologies enabled 2-4x improvements in workload density by partitioning resources across fewer physical machines, reducing data center space and management overhead for applications like e-commerce and enterprise resource planning. By 2008, the series was phased out in favor of the Power Systems platform, with IBM providing migration paths through hardware upgrades and software compatibility to transition existing p5 deployments seamlessly.^[45]^[48]

System p Mainstream Models

The mainstream models of the IBM System p series, introduced between 2006 and 2008, represented the culmination of the product line under the System p branding, emphasizing scalability, reliability, and integration with advanced virtualization technologies before the transition to Power Systems. These servers targeted enterprise environments requiring robust performance for UNIX-based workloads, with a shift from POWER5+ to POWER6 processors enabling higher clock speeds and improved efficiency. Key offerings included midrange and high-end configurations designed for data centers handling complex applications such as databases and enterprise resource planning. The System p 570, launched in 2006 with POWER5+ processors, supported 4 to 16 CPUs in a scalable rack-mounted design, allowing up to 512 GB of DDR2 memory and extensive I/O expansion for midrange deployments. In 2007, the lineup expanded with the high-end System p 595, featuring POWER6 processors in a 32-way configuration scalable to 64 cores, which provided exceptional throughput for demanding workloads while maintaining compatibility with AIX and Linux operating systems. Entry-level options included the System p 510, introduced in 2005 with POWER5 or POWER5+ processors offering 1 to 4 cores, and the System p 520, introduced in 2006 with POWER5+ processors offering 1 to 4 cores, catering to smaller-scale consolidation and web serving needs in a compact 1U or 4U form factor, with up to 64 GB of memory per system (note: POWER6-based successors available from 2008). Significant enhancements in these models stemmed from the POWER6 processor, clocked at up to 4.7 GHz and incorporating dual integrated memory controllers per chip for improved bandwidth and reduced latency. This architecture enabled high-end configurations like the p 595 to reach up to 64 cores (with dual-core modules), supporting advanced partitioning via PowerVM for dynamic resource allocation across multiple logical partitions. Scalability was further bolstered by integration with the IBM System Storage DS8000 series, allowing System p servers to access up to 1 PB of enterprise-class storage through Fibre Channel attachments, facilitating large-scale data management without compromising performance. These models focused on energy-efficient operations for data centers, with POWER6 delivering up to 60% total cost of ownership reductions through virtualization and power management features like dynamic throttling, compared to prior generations. IBM highlighted scenarios where two System p 570 servers at 60% utilization could save over $100,000 annually in energy and space costs relative to distributed x86 alternatives. By 2008, prior to rebranding, the System p line had achieved widespread adoption, with converged System p revenues contributing positively to IBM's systems segment growth amid increasing demand for reliable UNIX servers.

BladeCenter p Servers

The IBM BladeCenter p servers represented a line of high-density blade computing solutions within the System p family, leveraging POWER architecture for enterprise and high-performance workloads. Introduced as part of IBM's eServer BladeCenter portfolio, these servers integrated multiple compute nodes into shared chassis to optimize space, power, and management in data centers.^[49] They supported AIX, Linux, and later IBM i operating systems, with virtualization capabilities enabling efficient resource allocation across nodes.^[50] Key models in the BladeCenter p series included the JS20, released in 2004 with dual 2.2 GHz POWER5 (PowerPC 970) processors, designed for initial entry into blade-based POWER computing.^[49] The JS21 followed in 2006, featuring dual-core POWER5+ (PowerPC 970MP) processors at speeds up to 2.5 GHz and supporting up to 16 GB of DDR2 ECC memory.^[51] The JS22, launched in 2007, advanced to dual 4.0 GHz POWER6 processors with integrated AltiVec SIMD extensions, offering up to 32 GB of memory and enhanced multithreading for demanding applications.^[50] Each model was a single-wide blade, compatible with standard BladeCenter chassis, and focused on scalability through modular expansion.^[52] These servers operated within the BladeCenter E (7U) or H (9U) chassis, which provided shared infrastructure for up to 14 single-wide blades per unit.^[53] The chassis design included redundant hot-swap power modules (up to 2,980 W each in the H model) distributed across two power domains for high availability, along with integrated cooling via multiple blower modules.^[54] Networking options encompassed Ethernet via integrated Gigabit controllers and switch modules (up to 10 Gb), as well as InfiniBand support in the BladeCenter H's high-speed I/O bays for low-latency interconnects.^[53] This shared midplane architecture minimized internal cabling, routing all blade I/O through the chassis backplane.^[53] Notable features included integrated storage with up to 146 GB of SAS disk per blade via dual-drive bays and an onboard RAID controller (RAID 0/1/10), suitable for local caching or boot volumes.^[55] Virtualization was enabled through PowerVM, supporting logical partitioning (LPAR) with up to 10 partitions per core, dynamic LPAR adjustments, and micro-partitioning for fine-grained resource sharing.^[50] Live Partition Mobility, available with PowerVM Enterprise Edition, allowed non-disruptive migration of running partitions across blades or chassis, provided shared storage and virtual I/O were configured.^[50] BladeCenter p servers found primary use in high-performance computing (HPC) clusters, where InfiniBand-enabled configurations facilitated parallel processing for scientific simulations and data analytics.^[56] They integrated with IBM's HPC software stack, including LoadLeveler for job scheduling and Parallel Environment for MPI-based applications on AIX or Linux.^[56] Deployments often scaled to dozens of chassis in clustered environments, supporting workloads like computational fluid dynamics and bioinformatics.^[56] Compared to traditional 1U rack servers, BladeCenter p offered approximately twice the compute density in equivalent rack space, achieved through compact 30 mm blade form factors and shared chassis resources.^[57] This design also reduced cabling complexity by up to 80% internally, as power, cooling, and networking were centralized, lowering deployment and maintenance costs in dense environments.^[53]

Workstations

The IBM System p lineup extended its POWER architecture to workstations designed for professional single-user environments, particularly in engineering, media production, and scientific visualization. These systems built on the same processor technology and software ecosystem as the server models but emphasized compact, deskside configurations optimized for interactive workloads such as computer-aided design (CAD) and content creation. The workstations maintained compatibility with System p features like advanced virtualization and reliability enhancements, allowing seamless integration into enterprise infrastructures.^[58] The flagship model was the IntelliStation POWER 285, introduced on October 4, 2005, as the POWER 285 Express with one or two dual-core POWER5+ processors at 1.9 or 2.1 GHz, providing up to 4 cores and up to 32 GB of DDR2 memory. This tower-form-factor system measured 533 mm high by 201 mm wide by 706 mm deep, weighing 35.5 to 43 kg, and featured four hot-swappable SCSI disk bays for up to 1.2 TB of storage, six PCI-X slots, and redundant cooling with N+1 fan redundancy. Graphics capabilities included 2D accelerators like the GXT135P for general use and high-end 3D options such as the GXT4500P or GXT6500P, which supported resolutions up to 2048x1536 at 60 Hz and were optimized for professional rendering in applications like mechanical CAD. These NVIDIA-based graphics accelerators enabled smooth performance in visualization tasks, with additional support for USB 3D input devices like the SpaceBall and SpacePilot for intuitive design workflows.^[58]^[1] Operating system support centered on AIX 5L versions 5.2 and 5.3, with Linux distributions available via the AIX Toolbox for enhanced interoperability, including iSCSI host support for networked storage. The platform earned certifications from independent software vendors (ISVs) for key professional tools, notably 64-bit CATIA V5 from Dassault Systèmes for handling large engineering assemblies in mechanical CAD/CAE workloads, as well as compatibility with media and design applications from vendors like Autodesk and Adobe for tasks in animation and digital content production. Reliability features such as ECC memory, fault isolation, and self-healing diagnostics ensured uptime for mission-critical professional use.^[58]^[59] The workstation line evolved from the earlier RS/6000 series, which dominated UNIX-based professional computing in the 1990s, transitioning to the IntelliStation POWER branding in the early 2000s with POWER4 integration into the pSeries family and culminating in full System p compatibility by 2005. This progression allowed legacy RS/6000 applications to migrate smoothly while leveraging newer POWER5 advancements for improved single-threaded performance in design tools. Although representing a specialized segment within the broader System p portfolio, these workstations were essential for engineering and technical markets, enabling high-fidelity simulations and rapid prototyping in industries like automotive and aerospace.^[60]^[58]

OpenPOWER Variants

The IBM eServer OpenPower 710, introduced in 2005, represented a low-cost entry point into the System p ecosystem, specifically designed as a developer-oriented station for extending access to POWER architecture beyond enterprise environments.^[61] This model utilized the POWER5 processor running at 1.65 GHz in a single-processor configuration for the base setup, with support for up to two processors, and offered 1 GB of base RAM expandable to 32 GB using 266 MHz DDR1 ECC memory.^[62] Housed in a compact 2U rack-mount form factor measuring 89 mm high, 483 mm wide, and 686 mm deep, it weighed between 16.8 kg and 23.2 kg, making it suitable for space-constrained development labs.^[62] The system's pricing started at $3,449 for the entry-level one-way model, excluding the operating system, positioning it as an affordable alternative to higher-end UNIX and Linux servers from competitors like HP and Sun.^[63]^[64] Targeted primarily at educational institutions, independent software vendors (ISVs), and developers, the OpenPower 710 facilitated the porting and testing of applications to the POWER Instruction Set Architecture (ISA).^[65] It supported SUSE Linux Enterprise Server 9 or later and Red Hat Enterprise Linux AS Version 3 or later as primary operating systems, with AIX 5L available through a Request for Price Quotation (RPQ).^[62] Basic software features included compatibility for high-performance engineering and scientific workloads, web serving, and application hosting, emphasizing ease of integration for Linux-based development.^[62] While optional advanced virtualization via Micro-Partitioning allowed up to 20 logical partitions, along with virtual SCSI and Ethernet support, the base configuration focused on straightforward single-node operations without the full suite of enterprise tools.^[62] Storage options comprised up to four hot-swappable Ultra320 SCSI bays, and networking included dual [Gigabit Ethernet](/page/Gigabit Ethernet) ports, all backed by redundant cooling and optional redundant power supplies.^[65] Despite its accessibility, the OpenPower 710 lacked comprehensive enterprise-grade Reliability, Availability, and Serviceability (RAS) features found in mainstream System p servers, such as advanced dynamic logical partitioning or full hot-plug PCI-X slot support under all operating systems.^[62] Error handling relied on fundamentals like ECC memory with single- and double-error detection, a service processor for fault monitoring, and first-failure data capture, but it omitted OEM memory compatibility and extensive redundancy options typical of production environments.^[62] This design trade-off prioritized cost reduction for non-production testing and porting tasks, enabling ISVs to certify applications on POWER ISA through programs like the Virtual Loaner Program and Migration Factory, while internal IBM and partner education leveraged it for pre-sales assessments and proof-of-concept demonstrations.^[65] The three-year limited warranty provided standard coverage, aligning with its role as a development tool rather than a mission-critical system.^[62]

Legacy and Successors

Market Impact and Adoption

The IBM System p series achieved significant commercial success in the UNIX server market, securing a leading position with 31.8% revenue share in 2005 and maintaining its status as the top UNIX vendor worldwide through 2006, particularly in high-demand sectors like finance, government, and manufacturing.^[66]^[67] Prominent adopters included major financial institutions such as Bank of America, which deployed System p for transaction processing and service-oriented architecture in foreign currency operations during the mid-2000s.^[68] In supercomputing, the platform powered several high-performance systems, contributing to IBM's 47.8% share of the TOP500 list in November 2006 and placements within the top 10 rankings.^[69] System p revenue grew 8.8 percent in 2007 compared to 2006, reflecting strong demand for POWER6-based models.^[70] The platform's virtualization capabilities facilitated widespread server consolidation, enabling organizations to achieve significant reductions in operational costs through lower energy consumption, space requirements, and administrative overhead.^[71] A key competitive advantage was the System p's Reliability, Availability, and Serviceability (RAS) features, supporting availability levels of 99.999% uptime for mission-critical workloads.^[72] Although initial acquisition costs were higher than those for x86-based alternatives, TCO analyses revealed savings for System p deployments, driven by reduced hardware footprint, software licensing efficiency, and long-term operational gains in enterprise environments.^[73]

Transition to Power Systems

In 2008, IBM unified its System p (targeted at UNIX environments with AIX and Linux) and System i (focused on i5/OS) server lines into a single Power Systems brand, leveraging POWER6 and subsequent POWER7 processors to streamline offerings for diverse workloads including virtualization and database management.^[6] This rebranding, announced in April 2008, aimed to simplify marketing and hardware development while enabling customers to mix operating systems on unified platforms, marking the end of the distinct System p identity.^[74] The high-end Power 595 with POWER6 processors was introduced in May 2008, supporting up to 64 cores for enterprise-scale computing and marking the transition from System p branding.^[75] Subsequent models transitioned seamlessly to the new branding without hardware changes, preserving backward compatibility for AIX and PowerVM environments. Hardware support for System p models generally ended in the early 2010s, though software compatibility continues on newer Power Systems via virtualization and emulation.^[76] IBM maintained ongoing support for System p legacy through software updates, including the release of AIX 7.1 in September 2010, which enhanced scalability and security while ensuring compatibility with POWER6 and later architectures.^[11] PowerVM virtualization updates have continued to evolve, with versions like PowerVM 3.1 supported until September 2025 and newer iterations (e.g., PowerVM 4.x) providing sustained compatibility for legacy System p applications on modern hardware through at least 2025.^[77]^[78] The Power Systems lineage evolved from POWER7 processors in 2010, which introduced eight-core designs for improved energy efficiency, to POWER10 in 2022, featuring AI-optimized accelerators and up to 15.4 TFLOPS per socket for hybrid cloud deployments.^[79] System p technologies, such as advanced virtualization and high-availability features, persist in these successors, enabling integration with IBM Cloud Pak for hybrid environments that blend on-premises Power hardware with public cloud resources. This transition influenced the broader ecosystem via the OpenPOWER Foundation, established by IBM in December 2013, which opened the POWER ISA for third-party development and led to diverse hardware innovations like NVIDIA's DGX systems and Google's server designs.^[80]

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[9]
IBM RS/6000 320 - The Centre for Computing History
It features a 20MHz CPU and contains 8MB to 128MB of memory and 160-MB to 800-MB internal disk. Multiple distributed I/O processors are used to further enhance ...Missing: POWER1 | Show results with:POWER1
[10]
A Brief History of AIX - IBM
Jun 8, 2023 · AIX 3 (1990) for Power based processor computers (initially RS/6000) based on UNIX AT&T System V.2 and V.3 with some added BSD 4.2 features plus IBM unique ...
[11]
[PDF] IBM RISC System/6000: architecture and performance - IEEE Micro
We chose three of the SPEC benchmarks (LI, Matrix300, and TOMCATV)-two extremes and a midpoint. LI does not show the advantages of the independent units; at the ...
[12]
[PDF] IBM Regains Performance Lead with Power2: 10/4/93 - CECS
Oct 4, 1993 · In fact, the new CPU's clock is not much faster than Power1, which tops out at 62.5 MHz.
[13]
IBM releases new S/390 server, renames entire product line
In addition to renaming the S/390 series, the company will call its RS/6000 supercomputer line the pSeries—the p standing for performance—said ...
[14]
IBM UNVEILS NEW eSERVER p5 SYSTEM TO ADVANCE UNIX ...
Jul 16, 2004 · IBM introduced the new eServer p5 systems, an advanced line of UNIX and Linux servers that use POWER5 microprocessors and Micro-Partitioning, an ...
[15]
IBM Touts New Power 5 Servers - CRN
Jul 13, 2004 · IBM's eServer P5 introduction is its second step in recent months toward re-energizing its servers with the new Power 5. The first ...
[16]
IBM INCREASES PERFORMANCE & FUNCTIONALITY TO UNIX ...
The pSeries CBU offerings for the p670 and p690 servers are specially priced and implemented with Capacity Upgrade on Demand (CUoD) technology.
[17]
Bye Bye System p and i, Hello Power Systems - IT Jungle
Mar 17, 2008 · Then in July 2007, IBM broke the System i division in two, pushing entry products into the Business Systems division and rolling high-end ...Missing: history | Show results with:history
[18]
Announcement Recap for October 2007 - IBM
Well it's Tuesday, which means its time to look at recent announcements.While I was on vacation last week, IBM made a lot of storage announcements October 23.
[19]
None
Below is a merged summary of the revenue information for System p/pSeries/UNIX servers in 2005, consolidating all details from the provided segments into a single, comprehensive response. To maximize clarity and density, I’ve included key information in a table format where applicable, followed by a narrative summary and a list of useful URLs. All details from the individual summaries are retained, with discrepancies or gaps noted.
[20]
[PDF] RS/6000 7044 Model 270
Feb 13, 2000 · One, two, three, or four 375 MHz POWER3-II 64-bit processors are connected to an IBM-designed high performance memory/system control chip set.
[21]
[PDF] The POWER4 Processor Introduction and Tuning Guide
This guide provides a comprehensive explanation of POWER4 performance, including code examples, performance measurements, and how to get the most from the ...
[22]
[PDF] IBM System p5 Quad-Core Module Based on POWER5+ Technology
The POWER5+ processor features single-threaded and multi-threaded execution for higher performance. A single die contains two identical processor cores, each of ...Missing: specs | Show results with:specs
[23]
[PDF] IBM Power 570 and IBM Power 595 (POWER6) System Builder
This edition applies to AIX releases 5.3 and 6.1, IBM i 5.4 with Licensed Machine Code V5R4M5 and. IBM i 6.1, and Linux systems whose release levels and service ...
[24]
IBM Power4 | IBM
Dubbed IBM Power4 (POWER was originally an acronym for “Performance Optimization With Enhanced RISC”), the new processor served as the brains for an IBM eServer ...Missing: p | Show results with:p
[25]
[PDF] System i and System p: Solution Planning - IBM
You can view general system properties (system type, system model, serial number, and capabilities), power-on properties, processor, I/O, and memory information.
[26]
[PDF] IBM System p5 590 and 595 Technical Overview and Introduction
This IBM Redpaper is a comprehensive guide covering the IBM. System p5 590 and p5 595 AIX 5L and Linux operating system servers. We introduce major hardware ...
[27]
[PDF] IBM System p5 570 Technical Overview and Introduction
Giuliano has worked for IBM for 14 years, devoting himself to RS/6000® and pSeries systems with his in-depth knowledge of the related hardware and solutions.Missing: evolution milestones
[28]
[PDF] IBM power5 chip: a dual-core multithreaded processor - Micro, IEEE
It is not unusual to see average exe- cution unit utilization rates of approximately. 25 percent across a broad spectrum of envi- ronments. To increase ...
[29]
[PDF] IBM Intelligent Cluster and System Cluster 1350 Installation and ...
v Cluster systems-management software, such as xCAT. The clusters support a maximum of 1024 nodes in addition to the one required management node. All nodes ...
[30]
[PDF] IBM AIX Version 6.1 Differences Guide
This edition applies to AIX Version 6.1, program number 5765-G62. Note: Before using this information and the product it supports, read the information in “ ...
[31]
[PDF] Dell EMC Host Connectivity Guide for IBM AIX
Support for RS/6000, eServer pSeries, System p. •. Up to 32 nodes (HACMP-dependent). •. HACWS option to fail over CWS to a standby workstation. •. Detection of ...
[32]
AIX Workload Manager - IBM
Jun 8, 2023 · The AIX Workload Manager ((WLM) feature groups running processes into classes to monitor workloads and optionally control them.
[33]
[PDF] Deploying Mission Critical Applications with Linux on POWER
In 2004, RHEL AS3 was updated to support the IBM System p5™ server, OpenPower servers, and JS20 blades. This distribution is based on a Linux 2.4 kernel with a ...
[34]
[PDF] Tuning Linux OS on System p - IBM Redbooks
This edition applies to Red Hat Enterprise Linux AS 4 and SUSE Linux Enterprise Server 10. Note: Before using this information and the product it supports, read ...
[35]
[PDF] IBM PowerVM Virtualization Introduction and Configuration
This document covers understanding PowerVM features, planning, implementing, and setting up PowerVM virtualization, and is updated to include new POWER7 ...
[36]
[PDF] Introduction to IBM PowerVM
Mar 1, 2023 · This edition applies to the following versions: 򐂰 Version 7, Release 2 of IBM AIX. 򐂰 Version 7, Release 4 of IBM i. 򐂰 Version 3, Release 1, ...
[37]
[PDF] Integrated Virtualization Manager for IBM Power Systems Servers
The IVM is a feature of the Virtual I/O Server, which is part of the IBM PowerVM technology. This device enables companies to consolidate multiple partitions ...
[38]
Hardware Management Console - IBM
The HMC is the only console that enables you to configure server partitions. · The HMC can control multiple partitions without needing a separate connection and ...
[39]
IBM Systems Director
IBM Systems Director provides a central point of control for aggregating and managing systems. It can be installed on one or more systems, called management ...Missing: p HMC
[40]
Trusted AIX - IBM
Trusted AIX enables AIX systems to process information at multiple security levels. It is designed to meet the US Department of Defense (DoD) TCSEC and ...Missing: p | Show results with:p
[41]
Multi-level security - IBM
Trusted AIX supports Role Based Access Control (RBAC). RBAC an operating system mechanism through which the root/system super user specific system functions ...
[42]
[PDF] IBM pSeries 690
In addition to unparalleled speed, the pSeries 690 has the ability to consolidate critical applications on a single, datacentre-class server.Missing: 630 595 history<|control11|><|separator|>
[43]
[PDF] IBM pSeries Systems Handbook 2003 Edition 003 Edition - filibeto.org
This edition applies to IBM Sserver pSeries and RS/6000 servers as configured and used with. AIX 5L, program number 5765-E62. Note: Before using this ...
[44]
[PDF] pSeries 630 Models 6C4 and 6E4 Technical Overview and ... - IBM
These are the same processor chips used in the IBM ^ pSeries 690. However, unlike the Multi-Chip Module (MCM) packaging used in the Model 690, these systems ...
[45]
[PDF] System Handbook - IBM Redbooks
predecessor, the IBM Sserver pSeries 690. Accompanying the p5-595 is the up to 32-way p5-590 that offers enterprise-class function and more performance than ...
[46]
[PDF] IBM System p5 505 and 505Q Technical Overview and Introduction
The System p5 505Q also offers a processor option with the 4-core 1.65 GHz processor with two 36 MB L3 caches. The processors on the p5-505 allow you to ...
[47]
IBM's New p5 Servers Geared For Server Consolidation
Version 5.3 will increase performance and support the new virtualization features. In addition, the servers will support SUSE Linux, Red Hat Linux and--on ...
[48]
IBM Power System 505 Server (9115-505) - Withdrawal notification
Feb 27, 2024 · Lifecycle dates, announcement letters and other information ; General Availability: 04-Oct-2005 , 105-399 ; No longer available for order, ...Missing: p5 | Show results with:p5<|separator|>
[49]
[PDF] IBM System p5 575 cluster node - Spectra
Feb 14, 2006 · The IBM System p5™ 575 cluster node is designed to excel at high perform- ance computing (HPC) applications for.
[50]
IBM Power System 570 Server (9117-570) - Withdrawal notification
Feb 27, 2024 · Lifecycle dates, announcement letters and other information ; General Availability: 15-Jul-2004 , 104-380 ; No longer available for order, ...Missing: p5 | Show results with:p5
[51]
[PDF] The IBM eServer BladeCenter JS20
An improved version of the POWER3 processor, known as the POWER3-II, was subsequently introduced. The POWER3-II featured processor clock speeds as high as 450.
[52]
[PDF] IBM BladeCenter JS12 and JS22 Implementation Guide
Table 1-2 lists the physical specifications of the BladeCenter JS22 Express. Table 1-2 BladeCenter JS22 physical specifications. 1.3 Physical specifications ...
[53]
None
Summary of each segment:
[54]
Overview - IBM BladeCenter JS22
Jan 24, 2019 · The IBM BladeCenter JS22 has 4.0 GHz dual-core POWER6 processors, up to 32 GB memory, 73/146 GB SAS disk drive, and dual Gigabit Ethernet.
[55]
[PDF] IBM BladeCenter Products and Technology
Feb 6, 2014 · This document describes the BladeCenter chassis and blade server technology, I/O modules, expansion options, networking, and storage ...
[56]
Overview - IBM BladeCenter H
Jan 24, 2019 · BladeCenter H Chassis comes with one pair of 2,900-watt 200 to 240 V ac power modules. These standard power modules support blade server bays ...
[57]
Overview - IBM BladeCenter JS21
Processor. Supports dual core 2.3 GHz or 2.5 GHz, single core 2.7 GHz 64-bit PowerPC 970 processors ; Memory. Up to 16 GB of system memory; The JS21 system board ...
[58]
[PDF] HPC Clusters Using InfiniBand on IBM Power Systems Servers
This document covers HPC clusters using InfiniBand on IBM Power6 servers running AIX or Linux, and the IBM HPC software stack.
[59]
[PDF] IBM BladeCenter solutions
BladeCenter offers the performance and manageability of IBM rack- optimized platforms—at twice the density of most of today's 1U servers.
[60]
None
Summary of each segment:
[61]
[PDF] IBM IntelliStation POWER 285 Express workstation - ibmfiles.com
Oct 4, 2005 · It is the first UNIX® engineering design workstation supporting 64-bit CATIA V5 for large engineering assemblies. For CATIA MCAD workloads, the.Missing: Autodesk | Show results with:Autodesk
[62]
Model 52x or IBM IntelliStation POWER 285 features and parts
Model 52 x or IBM® IntelliStation® POWER® 285 features and parts. Find instructions for installing, removing, and replacing features and parts. You can find ...Missing: ISV applications CATIA Autodesk
[63]
IBM Introduces New Low-Priced POWER5 Server Based On Linux
Jan 28, 2005 · The IBM eServer OpenPower 710 is a reliable, one- to two-way rack-mount system that supports the Linux operating system as distributed by both ...Missing: specifications | Show results with:specifications
[64]
[PDF] IBM eServer OpenPower 710 Technical Overview and Introduction
Table 1-1 lists the general system specifications of the OpenPower 710 server. Table 1-1 IBM eServer OpenPower 710 server specifications. 1.2 Physical package.
[65]
IBM Introduces New Low-Priced POWER5 Server Based on Linux
Jan 24, 2005 · The OpenPower 710 will have a starting price of $3,449 (excluding operating system) and includes a 1.65 GHz processor, one gigabyte (GB) memory, ...
[66]
IBM admits to low-end Linux on Power assault - The Register
Jan 25, 2005 · But at a starting price of $3,449 the OpenPower 710 will also rival systems running on Intel and AMD processors.
[67]
[PDF] IBM Systems and Technology Group University 2005
New IBM ~ OpenPower 710 is ideal for ... • Or if an ISV, have a commercially available application on Linux ... Application Porting, Testing, and. Support.
[68]
Windows bumps Unix as top server OS - CNET
Feb 21, 2006 · In another first, IBM secured the top spot in 2005, with 31.8 percent of the market to Hewlett-Packard's 29.8 percent and Sun's 26.2 percent.Missing: p | Show results with:p
[69]
IBM wallops Unix peers . . . again - The Register
Dec 13, 2006 · IBM once again ranked as the most favored Unix vendor from technology, sales, service and accuracy standpoints. Sun, however, redeemed itself by ...
[70]
[PDF] IBM power systems and service oriented architecture at Bank of ...
The Bank of America Global Banknote Services standard offering for financial institutions was the Global Foreign. Currency (GFC) system, a Web-based application ...
[71]
IBM holds lead on Top500 Supercomputers list - Computerworld
Nov 14, 2006 · IBM holds a 47.8 percent share of the biannual Top500 Supercomputers list to be released Tuesday at Supercomputing 2006, an industry convention ...
[72]
Merrill Lynch Takes a Closer Look at IBM's Server Sales in Q1
Apr 23, 2007 · Here's the important bit to remember: In all of 2007, if Merrill Lynch's numbers turn out to be accurate, IBM will book $5.3 billion in Power- ...
[73]
[PDF] Five Step Plan to Energy Efficiency in the Data Center - IBM
IBM helps clients define scope of server and storage consolidation engagements to improve efficiency and reduce operational costs. Offering benefits. ▫ Save up ...
[74]
https://www.eweek.com/networking/ibm-combining-system-i-system-p-lines/
[75]
IBM Power Systems compared to x86 for SAP landscapes
Aug 15, 2011 · Here is a short summary of the key attributes that most customers require and the reasons why Power Systems excels or conversely, where x86 ...
[76]
IBM Combining System i, System p Lines - eWeek
Apr 2, 2008 · According to its annual report, System i revenue fell 10 percent during the 2007 fiscal year, while System p revenue increased more than 8 ...
[77]
The 64-Core Power6-Based Power 595 Starts to Roll in May
Apr 14, 2008 · IBM supports a maximum of 1 TB of main memory using faster 667 MHz DDR2 memory; those wanting more capacity than that have to switch to slower ...Missing: history | Show results with:history
[78]
System to PowerVM Virtual I/O Server maps - IBM
Aug 25, 2025 · This page provides links to maps specifying which PowerVM Virtual I/O Server versions are compatible with various Power Systems processors.
[79]
End Of Support Announced For IBM Power Middleware Releases
Jan 15, 2024 · IBM is also announcing that PowerVM Standard Edition 3.1.X will have its support cut off on September 30, 2025, and the Watson ML Accelerator ...
[80]
[PDF] IBM Power10 Scale Out Servers - Technical Overview - IBM Redbooks
When configured as a Power Private Cloud system, each Power S1022 server requires a minimum of one base processor core activation. The maximum number of ...
[81]
The Next Step in the OpenPOWER Foundation Journey
Aug 20, 2019 · In addition to open sourcing the POWER ISA, IBM is also contributing a newly developed softcore to the community. In a very short time, an IBM ...Missing: influence | Show results with:influence