10×10 Mesh无线片上网络多通道性能评价

A. Lit, Popoola Oluwaseun Lydia, S. Suhaili, R. Sapawi, K. Kipli, D. N. S. Dharmiza
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引用次数: 1

摘要

由于其CMOS兼容性和架构灵活性,无线片上网络(NoC)被设想为传统NoC的补充,这是无线传输不需要布线基础设施的优势。片上无线信道实际上用于最小化远程处理核心之间的通信延迟,因为它能够以单跳方式与远程通信处理核心进行通信。本文研究了单通道、双通道和三通道对网格- winoc体系结构的影响。此外,四个和九个无线电集线器均匀分布在mesh-WiNoC拓扑结构中,以评估其全局传输延迟、网络吞吐量和能量特性。在基于循环精确系统c的Noxim模拟器上对所研究的测试架构进行了随机流量负载场景下的WiNoC性能评估。本研究的贡献在于,它着眼于在10 × 10网格WiNoC架构中使用4和9无线电集线器场景的最佳无线信道数量,以获得传输延迟和能耗方面的最佳性能。实验结果表明,在mesh-WiNoC架构下,两种研究的无线集线器数量在传输延迟和吞吐量方面具有几乎相同的系统性能。然而,具有4个无线电集线器的meshWiNoC架构表现出更好的能量特性,与具有6个和9个无线电集线器的架构相比,分别节省了9.63%和13.60%的能量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Performance Evaluation of Multi-Channel for 10×10 Mesh Wireless Network-on-Chip Architecture
Wireless Network-on-Chip (NoC) is envisioned as complementary to the conventional NoC due to its CMOS compatibility and architectural flexibility, which is advantageous as no wiring infrastructure is required for wireless transmission. On-chip wireless channels are used to actually minimize the communication latency between the distant processing cores because of its ability to communicate with long-distance communication processing cores in a single-hop. This paper investigates the effect of the single-, dual-, and triple-channels on the mesh-WiNoC architecture. Additionally, four and nine radio hubs are evenly distributed throughout the mesh-WiNoC topological structure to evaluate its global transmission latency, network throughput, and energy characteristics. The investigated architectures under test are simulated on the cycle-accurate systemC based Noxim simulator under a random traffic workload scenario for WiNoC performance evaluation. This study’s contribution is that it looks into the best number of wireless channels to use in a 10 × 10 mesh WiNoC architecture for 4 and 9 radio hub scenarios to get the best performance in transmission latency and energy consumption. Experimental results show that for both investigated number of radio hub on mesh-WiNoC architecture demonstrates nearly identical system performance in terms of transmission latency and throughput. However, the meshWiNoC architecture with 4 radio hub demonstrates better energy characteristics, saving 9.63% and 13.60% of energy, respectively, when compared to the architecture with 6 and 9 radio hub.
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