Heterogeneous 3d Network-on-Chip Architectures: Area and Power Aware Design Techniques

2016 IEEE Intl Conference on Computational Science and Engineering (CSE) and IEEE Intl Conference on Embedded and Ubiquitous Co

Vien

Mak

2016

Abstract-Recently wireless Networks-on-Chip (WiNoCs) have been proposed to overcome the scalability and performance limitations of traditional multi-hop wired NoC architectures. However, the adaptation of wireless technology for on-chip communication is still in its infancy. Consequently, several challenges such as simulation and design tools that consider the technological constraints imposed by the wireless channel are yet to be addressed. To this end, in this paper, we propose and efficient channel model for WiNoCs which takes into account practical issues and constraints of the propagation medium, such as transmission frequency, operating temperature, ambient pressure and distance between the on-chip antennas. The proposed channel model demonstrates that total path loss of the wireless channel in WiNoCs suffers from not only dielectric propagation loss (DPL) but also molecular absorption attenuation (MAA) which reduces the reliability of the system.

“…We compare with conventional channel model where signals are transmitted over pure air with no MAA (e.g. two-ray channel model in [20]) 2 .…”

Section: Simulation Resultsmentioning

confidence: 99%

Section: Simulation Resultsmentioning

confidence: 99%

An Analytical Channel Model for Emerging Wireless Networks-on-Chip

2016 IEEE Intl Conference on Computational Science and Engineering (CSE) and IEEE Intl Conference on Embedded and Ubiquitous Co

Vien

Mak

2016

“…Based on the serialization methodology, Pasricha [36] proposed a 3D NoC synthesis framework; their approach adopt routers that have several local ports, which have high power consumption due to the increased number of ports and high data rates across the crossbar. On the other hand, existing inhomogeneous architectures (Figure 3a) [1,2,32,33,[37][38][39][40][41][42] do not consider the dynamics of application traffic load in their inhomogeneous architectures. Applications in such 3D NoCs are not optimized, as communication bandwidth and performance constraints of the applications were not considered in the architecture generation.…”

Section: D Network-on-chipmentioning

confidence: 99%

Extending the Performance of Hybrid NoCs beyond the Limitations of Network Heterogeneity

Zong

Yakovlev

et al. 2017

JLPEA

Abstract:To meet the performance and scalability demands of the fast-paced technological growth towards exascale and big data processing with the performance bottleneck of conventional metal-based interconnects (wireline), alternative interconnect fabrics, such as inhomogeneous three-dimensional integrated network-on-chip (3D NoC) and hybrid wired-wireless network-on-chip (WiNoC), have emanated as a cost-effective solution for emerging system-on-chip (SoC) design. However, these interconnects trade off optimized performance for cost by restricting the number of area and power hungry 3D routers and wireless nodes. Moreover, the non-uniform distributed traffic in a chip multiprocessor (CMP) demands an on-chip communication infrastructure that can avoid congestion under high traffic conditions while possessing minimal pipeline delay at low-load conditions. To this end, in this paper, we propose a low-latency adaptive router with a low-complexity single-cycle bypassing mechanism to alleviate the performance degradation due to the slow 2D routers in such emerging hybrid NoCs. The proposed router transmits a flit using dimension-ordered routing (DoR) in the bypass datapath at low-loads. When the output port required for intra-dimension bypassing is not available, the packet is routed adaptively to avoid congestion. The router also has a simplified virtual channel allocation (VA) scheme that yields a non-speculative low-latency pipeline. By combining the low-complexity bypassing technique with adaptive routing, the proposed router is able to balance the traffic in hybrid NoCs to achieve low-latency communication under various traffic loads. Simulation shows that the proposed router can reduce applications' execution time by an average of 16.9% compared to low-latency routers, such as SWIFT. By reducing the latency between 2D routers (or wired nodes) and 3D routers (or wireless nodes), the proposed router can improve the performance efficiency in terms of average packet delay by an average of 45% (or 50%) in 3D NoCs (or WiNoCs).

“…1) [2], [22]- [25] however, do not consider the dynamics of application traffic load in their architectures generation. Applications in such 3D NoCs are not optimized as communication bandwidth and performance constraints of the applications were not considered in the architecture generation.…”

Section: A 3d Network-on-chip Architecturesmentioning

confidence: 99%

“…Moreover, Through Silicon Via (TSV) which has been accepted as a viable inter-layer wiring technique has a complex and expensive manufacturing process [1]. To optimize the performance and manufacturing cost of 3D NoCs with minimal distortion to the modularity, inhomogeneous architectures have been proposed to combine 2D and 3D routers in 3D NoCs [2]- [4]. Several inhomogeneous 3D architectures focusing on different NoC router architectures, minimal hopcount between 2D and 3D routers in each layer, and uniform distribution of 2D and 3D routers have been proposed [5].…”

Section: Introductionmentioning

confidence: 99%

An Efficient 2D Router Architecture for Extending the Performance of Inhomogeneous 3D NoC-Based Multi-Core Architectures

2016 International Symposium on Computer Architecture and High Performance Computing Workshops (SBAC-PADW)

Zong

2016

Abstract-To meet the performance and scalability demands of the fast-paced technological growth towards exascale and BigData processing with the performance bottleneck of conventional metal based interconnects, alternative interconnect fabrics such as inhomogeneous three dimensional integrated Network-onChip (3D NoC) has emanated as a cost-effective solution for emerging multi-core design. However, these interconnects tradeoff optimized performance for cost by restricting the number of area and power hungry 3D routers. Consequently, in this paper, we propose a low-latency adaptive router with a low-complexity single-cycle bypassing mechanism to alleviate the performance degradation due to the slow 2D routers in inhomogeneous 3D NoCs. By combining the low-complexity bypassing technique with adaptive routing, the proposed router is able to balance the traffic in the network to reduce the average packet latency under various traffic loads. Simulation shows that, the proposed router can reduce the average packet delay by an average of 45% in 3D NoCs.