Otto Wagner

Implementation of the CELL Broadband Engine in a 65nm SOI Technology Featuring Dual-Supply SRAM Arrays Supporting 6GHz at 1.3V

The 65nm CELL Broadband Enginetrade design features a dual power supply, which enhances SRAM stability and performance using an elevated array-specific power supply, while reducing the logic power consumption. Hardware measurements demonstrate low-voltage operation and reduced scatter of the minimum operating voltage. The chip operates at 6GHz at 1.3V and is fabricated in a 65nm CMOS SOI technology.

Implementation of the Cell Broadband Engine™ in 65 nm SOI Technology Featuring Dual Power Supply SRAM Arrays Supporting 6 GHz at 1.3 V

The 65 nm cell broadband enginetrade (cell BE) is a multi-core SoC, implemented in a high performance SOI technology featuring a separate dual power supply for SRAM arrays to improve stability and performance using an elevated voltage. A new method is shown to analyze the SRAM cell under application conditions which was used to tune the cell for stability, write-ability and performance. An improved write scheme is shown which widens the overall functional window and allows setting the power/performance point of the arrays independently of the surrounding logic. Hardware measurements demonstrate the advantages of the dual power supply under different aspects.

A 32kB 2R/1W L1 data cache in 45nm SOI technology for the POWER7TM processor

Increasing demand for parallelism due to out-of-order and multi-threading computation requires fast and dense arrays with multi-port capabilities. The load-store-unit (LSU) of the POWER7™ microprocessor core has a 32kB L1 data cache composed of four 8kB blocks. In a two-cycle back-to-back operation it supports concurrently two independent read and one write operations. Organized in banks of 16 cells each, the two reads operate independently in any of these banks, including two reads within the same bank, even the same cell. A bank selected for write is blocked for any read operation. If read and write collide within the same bank, collision-control circuitry provides write-over-read priority. Each read port provides 4B from 1 of 256 locations, whereas the double-bandwidth write operation provides individual control of 8B to 128 locations.

An advanced optical diagnostic technique of IBM z990 eServer microprocessor

In this paper, we describe an advanced optical diagnostic technique used for diagnosing the IBM z990 eServer microprocessor (Slegel et al., 2004). Time-to-market pressure demands quick diagnostic turnaround time and high diagnostic resolution while the ever increasing design complexity, density, cycle time, and shrinking technologies dramatically add difficulties to diagnostics. Although design-for-test (DFT) and design-for-diagnostics (DFD) features are implemented in the latest microprocessors to help easing the diagnostic efforts, they may still not be sufficient to diagnose certain fails. The well-known picosecond imaging circuit analysis (PICA) (Kash and Tsang, 1997) tool, equipped with the high quantum efficiency superconducting single-photon detector (SSPD,) shows a unique diagnostic capability for optically probing the internal nodes of a chip. Several hard-to-diagnose examples will be used to demonstrate the unique capabilities of this technique