Peter J. Camporese

IBM POWER6 microprocessor physical design and design methodology

The IBM POWER6™ microprocessor is a 790 million-transistor chip that runs at a clock frequency of greater than 4 GHz. The complexity and size of the POWER6 microprocessor, together with its high operating frequency, present a number of significant challenges. This paper describes the physical design and design methodology of the POWER6 processor. Emphasis is placed on aspects of the design methodology, technology, clock distribution, integration, chip analysis, power and performance, random logic macro (RLM), and design data management processes that enabled the design to be completed and the project goals to be met.

Circuit design techniques for the high-performance CMOS IBM S/390 parallel enterprise server G4 microprocessor

This paper describes the circuit design techniques used for the IBM S/390® Parallel Enterprise Server G4 microprocessor to achieve operation up to 400 MHz. A judicious choice of process technology and concurrent top-down and bottom-up design approaches reduced risk and shortened the design time. The use of timing-driven synthesis/placement methodologies improved design turnaround time and chip timing. The combined use of static, dynamic, and self-resetting CMOS (SRCMOS) circuits facilitated the balancing of design time and performance return. The use of robust PLL design, floorplanning, and clock distribution minimized clock skew. Innovative latch designs permitted performance optimization without adding risk. Microarchitecture optimization and circuit innovations improved the performance of timing-critical macros. Full custom array design with extensive use of SRCMOS circuit techniques resulted in an on-chip L1 cache having 2.0-ns cycle time.

IBM eServer z900 high-frequency microprocessor technology, circuits, and design methodology

The IBM eServer z900 microprocessor is a seventh-generation zSeries™ (formerly S/390®) CMOS design which has achieved 1.3-GHz operation. This paper describes the 0.18-µm bulk CMOS, seven-level copper metal process and the high-frequency circuit, integration, and design methodologies developed to achieve this operation. The microprocessor was floorplanned to closely mimic the flow of the microarchitecture pipeline and reduce the communication delay overhead between units. Novel circuit techniques were used in the implementation of the arrays and cache hit detection logic to save power and reduce circuit complexity without sacrificing performance. A four-dimensional gate library and novel synthesis algorithms were developed to yield synthesized control implementations with the performance characteristics of a fully custom circuit design.

A 1.1 GHz first 64 b generation 2900 microprocessor

The first 64 b S/390 microprocessor implemented in a 0.18 /spl mu/m, 7-level copper interconnect bulk CMOS process, runs operating system and applications at 1.1 GHz. The frequency is achieved with interconnect width and repeater optimization, selective use of low-Vt devices, tapered library gates, and improved synthesis and circuit tuning algorithms.