Abstract: An isolation technique is provided for improving the overall planarity of isolation regions relative to adjacent active area silicon mesas. The isolation process results in a trench formed in field regions immediately adjacent the active regions. The trench, however, does not extend entirely across the field region. By preventing large area trenches, substantial dielectric fill material and the problems of subsequent planarization of that fill material is avoided. Accordingly, the present isolation technique does not require conventional fill dielectric normally associated with a shallow trench process. While it achieves the advantages of forming silicon mesas, the present process avoids having to rework dielectric surfaces in large area field regions using conventional sacrificial etchback, block masking and chemical-mechanical polishing. The improved isolation technique hereof utilizes trenches of minimal width etched into the silicon substrate at the periphery of field regions, leaving a field mesa.

Abstract: A circuit and method for reducing voltage oscillations at the output leads of a digital integrated circuit. A circuit for reducing voltage oscillations on the output leads of a digital integrated circuit comprising a positive voltage charge pump unit coupled to an output driver, a negative voltage charge pump unit also coupled to the output driver and a sense and control unit coupled to both the negative voltage charge pump unit and the positive voltage charge pump unit is presented. The sense and control unit is configured to determine whether switching current is present in the source or drain of the output driver. If switching current is present in the source, then the sense and control unit is further configured to connect the positive voltage charge pump unit to the source. If switching current is present in the drain, then the sense and control unit is still further configured to connect the negative voltage charge pump unit to the drain.

Abstract: The bits of a data block are assigned to a plurality of logical groups such that at most one bit corresponding to a component is assigned to a logical group. This assignment ensures that a component failure may introduce at most one bit error to a logical group. Each logical group uses a single error correcting code to detect and correct bit errors. A parity bit is appended to a data block that includes a plurality of logical groups. The parity bit may be used in conjunction with the single error correcting codes to determine whether a detected error is a single bit error or a multiple bit error. If the detected error is a single bit error, the error correction codes may be used to correct the error. If the detected error is a multiple bit error, an uncorrectable error may be reported.

Abstract: In a first aspect of the invention, branch prediction hardware, comprising logic and interconnect, is configurable via a control line to alter the manner in which the branch prediction is generated. The configuration can be done programmatically in software. Or, the configuration can be done by hardware in response to processor events. Such processor events include the loading of the CS register and changes in the instruction workload. In a second aspect of the invention, related to speculative execution, the directions of a plurality of branches are predicted based partly on resolved branch history information. Tentative branch history information is then stored for each of the predicted branches. When a predicted branch is resolved, the resolved branch history information is updated based on the stored tentative branch history information for the branch most recently resolved. Additionally, the predictions may be partly based on preceding unresolved branch predictions if any are outstanding.