System on a chip

About: System on a chip is a research topic. Over the lifetime, 11331 publications have been published within this topic receiving 147395 citations. The topic is also known as: system-on-a-chip & SOC.

Networks on Chip: A New Paradigm for Systems on Chip Design

Abstract: This paper is meant to be a short introduction to a new paradigm for systems on chip (SoC) design. The premises are that a component-based design methodology will prevail in the future, to support component re-use in a plug-and-play fashion. At the same time, SoCs will have to provide a functionally-correct, reliable operation of the interacting components. The physical interconnections on chip will be a limiting factor for performance and energy consumption.

Power-driven design of router microarchitectures in on-chip networks

Abstract: As demand for bandwidth increases in systems-on-a-chip and chip multiprocessors, networks are fast replacing buses and dedicated wires as the pervasive interconnect fabric for on-chip communication. The tight delay requirements faced by on-chip networks have resulted in prior microarchitectures being largely performance-driven. While performance is a critical metric, on-chip networks are also extremely power-constrained. In this paper, we investigate on-chip network microarchitectures from a power-driven perspective. We first analyze the power dissipation of existing network microarchitectures, highlighting insights that prompt us to devise several power-efficient network microarchitectures: segmented crossbar, cut-through crossbar and write-through buffer. We also study and uncover the power saving potential of existing network architecture: express cube. These techniques are evaluated with synthetic as well as real chip multiprocessor traces, showing a reduction in network power of up to 44.9%, along with no degradation in network performance, and even improved latency-throughput in some cases.

SUNMAP: a tool for automatic topology selection and generation for NoCs

Abstract: Increasing communication demands of processor and memory cores in Systems on Chips (SoCs) necessitate the use of Networks on Chip (NoC) to interconnect the cores. An important phase in the design of NoCs is he mapping of cores onto the most suitable opology for a given application. In this paper, we present SUNMAP a tool for automatically selecting he best topology for a given application and producing a mapping of cores onto that topology. SUNMAP explores various design objectives such as minimizing average communication delay, area, power dissipation subject to bandwidth and area constraints. The tool supports different routing functions (dimension ordered, minimum-path, traffic splitting) and uses floorplanning information early in the topology selection process to provide feasible mappings. The network components of the chosen NoC are automatically generated using cycle-accurate SystemC soft macros from X-pipes architecture. SUNMAP automates NoC selection and generation, bridging an important design gap in building NoCs. Several experimental case studies are presented in the paper, which show the rich design space exploration capabilities of SUNMAP.

Block based design methodology

Abstract: A method and apparatus for designing a circuit system, including selecting a plurality of pre-designed circuit blocks to be used to design the circuit system, collecting data reflecting the experience of the designer regarding the pre-designed circuit blocks, the designer's experience being adaptable to a processing method, accepting or rejecting a design of the circuit system in a manner based on the designer's experience data and acceptable degree of risk, upon acceptance, forming block specifications containing criteria and modified constraints for each of the circuit blocks, upon acceptance, forming block specifications for deploying the circuit blocks on a floor plan of a chip, as a system on a chip, in compliance with the criteria and modified constraints, and substantially without changing the selected circuit block and the processing method.

Analysis of error recovery schemes for networks on chips

Abstract: In this article, we discuss design constraints to characterize efficient error recovery mechanisms for the NoC design environment. We explore error control mechanisms at the data link and network layers and present the schemes' architectural details. We investigate the energy efficiency, error protection efficiency, and performance impact of various error recovery mechanisms.