RHT_NoC: A Reconfigurable Hybrid Topology Architecture for Chiplet-Based Multicore System

IF 3.1 2区工程技术 Q2 COMPUTER SCIENCE, HARDWARE & ARCHITECTURE

IEEE Transactions on Very Large Scale Integration (VLSI) Systems Pub Date : 2025-06-05 DOI:10.1109/TVLSI.2025.3572112

Dongyu Xu;Wu Zhou;Zhengfeng Huang;Huaguo Liang;Xiaoqing Wen

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引用次数: 0

Abstract

Chiplet-based system-on-chip (SoC) architectures, leveraging 2.5-D/3-D integration technologies, provide scalable solutions for a wide range of applications. Achieving high performance and cost-effectiveness in these systems relies heavily on optimizing die-to-die interconnect topologies and designs, which are essential for seamless interchiplet communication. This article introduces a reconfigurable hybrid topology (RHT) architecture designed for chiplet-based multicore systems. RHT achieves high performance and energy efficiency by dynamically reconfiguring the network topology to traffic variations, adaptively selecting transport subnets, and optimizing link bandwidth allocation, thereby minimizing congestion and maximizing packet throughput. Furthermore, RHT leverages global traffic information to dynamically combine Torus loops, maximizing opportunities for rapid packet transmission delivery while guaranteeing minimal hop counts. Moreover, RHT accelerates packet transmission via bufferless combined loops, extending the continuous sleeping periods of routers, improves power gating efficiency, and significantly reduces static power consumption. Simulation results indicate that the Mesh-DyRing achieves over a 40% reduction in network latency and more than a 20% decrease in power consumption overhead compared to the baseline design. When compared to WiNoC, an advanced hybrid wired-wireless topology design, the Mesh-DyRing-PG configuration reduces power consumption by 56.2% while maintaining equivalent average network latency.

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RHT_NoC：基于芯片的多核系统的可重构混合拓扑结构

基于芯片的系统级芯片（SoC）架构利用2.5 d /3-D集成技术，为广泛的应用提供可扩展的解决方案。在这些系统中实现高性能和成本效益在很大程度上依赖于优化模对模互连拓扑和设计，这对于无缝芯片间通信至关重要。本文介绍了为基于芯片的多核系统设计的可重构混合拓扑（RHT）架构。RHT通过根据流量变化动态地重新配置网络拓扑，自适应地选择传输子网，优化链路带宽分配，从而最大限度地减少拥塞，最大限度地提高数据包吞吐量，从而实现高性能和高能效。此外，RHT利用全球流量信息来动态组合环面环路，在保证最小跳数的同时，最大限度地提高了快速数据包传输的机会。此外，RHT通过无缓冲组合环路加速分组传输，延长路由器的连续休眠时间，提高电源门控效率，显著降低静态功耗。仿真结果表明，与基线设计相比，Mesh-DyRing实现了超过40%的网络延迟减少和超过20%的功耗开销减少。与WiNoC（一种先进的混合有线无线拓扑设计）相比，Mesh-DyRing-PG配置在保持同等平均网络延迟的同时，降低了56.2%的功耗。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IEEE Transactions on Very Large Scale Integration (VLSI) Systems 工程技术-工程：电子与电气

CiteScore

6.40

自引率

7.10%

发文量

187

审稿时长

3.6 months

期刊介绍： The IEEE Transactions on VLSI Systems is published as a monthly journal under the co-sponsorship of the IEEE Circuits and Systems Society, the IEEE Computer Society, and the IEEE Solid-State Circuits Society. Design and realization of microelectronic systems using VLSI/ULSI technologies require close collaboration among scientists and engineers in the fields of systems architecture, logic and circuit design, chips and wafer fabrication, packaging, testing and systems applications. Generation of specifications, design and verification must be performed at all abstraction levels, including the system, register-transfer, logic, circuit, transistor and process levels. To address this critical area through a common forum, the IEEE Transactions on VLSI Systems have been founded. The editorial board, consisting of international experts, invites original papers which emphasize and merit the novel systems integration aspects of microelectronic systems including interactions among systems design and partitioning, logic and memory design, digital and analog circuit design, layout synthesis, CAD tools, chips and wafer fabrication, testing and packaging, and systems level qualification. Thus, the coverage of these Transactions will focus on VLSI/ULSI microelectronic systems integration.