U. Salim

Bio: U. Salim is an academic researcher. The author has contributed to research in topics: Flip-flop & Static timing analysis. The author has an hindex of 1, co-authored 1 publications receiving 383 citations.

Flow-through latch and edge-triggered flip-flop hybrid elements

Abstract: This paper describes a hybrid latch-flipflop (HLFF) timing methodology aimed at a substantial reduction in latch latency and clock load. A common principle is employed to derive consistent latching structures for static logic, dynamic domino and self-resetting logic.

Comparative analysis of master-slave latches and flip-flops for high-performance and low-power systems

Abstract: In this paper, we propose a set of rules for consistent estimation of the real performance and power features of the flip-flop and master-slave latch structures. A new simulation and optimization approach is presented, targeting both high-performance and power budget issues. The analysis approach reveals the sources of performance and power-consumption bottlenecks in different design styles. Certain misleading parameters have been properly modified and weighted to reflect the real properties of the compared structures. Furthermore, the results of the comparison of representative master-slave latches and flip-flops illustrate the advantages of our approach and the suitability of different design styles for high-performance and low-power applications.

Improved sense-amplifier-based flip-flop: design and measurements

Abstract: Design and experimental evaluation of a new sense-amplifier-based flip-flop (SAFF) is presented. It was found that the main speed bottleneck of existing SAFF's is the cross-coupled set-reset (SR) latch in the output stage. The new flip-flop uses a new output stage latch topology that significantly reduces delay and improves driving capability. The performance of this flip-flop is verified by measurements on a test chip implemented in 0.18 /spl mu/m effective channel length CMOS. Demonstrated speed places it among the fastest flip-flops used in the state-of-the-art processors. Measurement techniques employed in this work as well as the measurement set-up are discussed in this paper.

High-performance and low-power conditional discharge flip-flop

Abstract: In this paper, high-performance flip-flops are analyzed and classified into two categories: the conditional precharge and the conditional capture technologies. This classification is based on how to prevent or reduce the redundant internal switching activities. A new flip-flop is introduced: the conditional discharge flip-flop (CDFF). It is based on a new technology, known as the conditional discharge technology. This CDFF not only reduces the internal switching activities, but also generates less glitches at the output, while maintaining the negative setup time and small D-to-Q delay characteristics. With a data-switching activity of 37.5%, the proposed flip-flop can save up to 39% of the energy with the same speed as that for the fastest pulsed flip-flops.

The implementation of the Itanium 2 microprocessor

Abstract: This 64-b microprocessor is the second-generation design of the new Itanium architecture, termed explicitly parallel instruction computing (EPIC). The design seeks to extract maximum performance from EPIC by optimizing the memory system and execution resources for a combination of high bandwidth and low latency. This is achieved by tightly coupling microarchitecture choices to innovative circuit designs and the capabilities of the transistors and wires in the 0.18-/spl mu/m bulk Al metal process. The key features of this design are: a short eight-stage pipeline, 11 sustainable issue ports (six integer, four floating point, half-cycle access level-1 caches, 64-GB/s level-2 cache and 3-MB level-3 cache), all integrated on a 421 mm/sup 2/ die. The chip operates at over 1 GHz and is built on significant advances in CMOS circuits and methodologies. After providing an overview of the processor microarchitecture and design, this paper describes a few of these key enabling circuits and design techniques.

Conditional-capture flip-flop for statistical power reduction

Abstract: This paper describes a family of novel low-power flip-flops, collectively called conditional-capture flip-flops (CCFFs). They achieve statistical power reduction by eliminating redundant transitions of internal nodes. These flip-flops also have negative setup time and thus provide small data-to-output latency and attribute of soft-clock edge for overcoming clock skew-related cycle time loss. The simulation comparison indicates that the proposed differential flip-flop achieves power savings of up to 61% with no impact on latency while the single-ended structure provides the maximum power savings of around 67%, as compared to conventional flip-flops. With a typical switching activity of 0.33, the power consumption is reduced by as much as 23-30% with comparable minimum data-to-output latency. It is also indicated that the proposed single-ended structure provides power comparable to the fully static master-slave design with significantly reduced data-to-output latency. An eight-bit counter was fabricated using a 0.35-/spl mu/m CMOS technology, and the experimental results indicate that the counter using the differential CCFF saves the overall power consumption by about 30% as compared to that using the conventional flip-flop.