Contrasting a NoC and a Traditional Interconnect Fabric with Layout Awareness

Angiolini, Federico; Meloni, Paolo; Carta, Salvatore; Benini, Luca; Raffo, Luigi

doi:10.1109/date.2006.244033

Cited by 72 publications

(61 citation statements)

References 16 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Clearly most of the power is consumed by the input modules, as shown by previous work [8,13], but the effect is weaker in soft NoCs than in hard. This also conforms with the area composition of the routers; most of the router area is dedicated to buffering in the input modules, while the smallest router component is the crossbar [1].…”

Section: Router Power Compositionmentioning

confidence: 66%

“…Other work focuses on complete systems and reports the power budgeted for communication using an NoC [11,12]. Finally, NoCs have been compared to other interconnect types by using application-independent metrics, such as the amount of energy to move a unit of data over different kinds of interconnect [13]. We build on some of the concepts introduced in this literature; however, we also address many FPGA-specific questions that were not addressed in any prior work.…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

The power of communication: Energy-efficient NOCS for FPGAS

Abdelfattah

Betz

2013

2013 23rd International Conference on Field Programmable Logic and Applications

View full text Add to dashboard Cite

Integrating networks-on-chip (NoCs) on FPGAs can improve device scalability and facilitate design by abstracting communication and simplifying timing closure, not only between modules in the FPGA fabric but also with large "hard" blocks such as high-speed I/O interfaces. We propose mixed and hard NoCs that add less than 1% area to large FPGAs and run 5-6× faster than the soft NoC equivalent. A detailed power analysis, per NoC component, shows that routers consume 14× less power when implemented hard compared to soft, and whether hard or soft most of the router's power is consumed in the input modules for buffering. For complete systems, hard NoCs consume less than 6% (and as low as 3%) of the FPGA's dynamic power budget to support 100 GB/s of communication bandwidth. We find that, depending on design choices, hard NoCs consume 4.5-10.4 mJ of energy per GB of data transferred. Surprisingly, this is comparable to the energy efficiency of the simplest traditional interconnect on an FPGA -soft point-to-point links require 4.7 mJ/GB. In many designs, communication must include multiplexing, arbitration and/or pipelining. For all these cases, our results indicate that a hard NoC will be more energy efficient than the conventional FPGA fabric.

show abstract

Section: Router Power Compositionmentioning

confidence: 66%

Section: Introductionmentioning

confidence: 99%

The power of communication: Energy-efficient NOCS for FPGAS

Abdelfattah

Betz

2013

2013 23rd International Conference on Field Programmable Logic and Applications

View full text Add to dashboard Cite

show abstract

“…As shown in Figure 9, the static NoC consists of 6 switches (1 switch of 8x8, 2 switches of 9x9, 2 switches 10x10 and 1 switch of 11x11), whileboth NoC 1 (for application A) and NoC 3 (for application C) consists of 4 switches (3 switches of 10x10 and 1 switch of 11x11) and NoC 2 (for application B) consists of 4 switches (1 switch of 10x9, 2 switches of 10x10 and 1 switch of 10x11), as shown in Figure 10. The static NoC option, as shown in Table 5, is characterized by a higher area usage, a higher average power consumption (evaluated as proposed in [2]) and a higher average latency, with respect to the three adhoc NoCs specifically designed for each application. Using the specific NoCs, it can be reported reductions of 34% in latency and 24% in power consumption.…”

Section: Express Lines and Topology Reconfiguration Analysismentioning

confidence: 99%

“…Then, designing custom-tailored NoC interconnects that satisfy the performance and design constraints of the SoC for all the different combinations of possible executed applications is a key goal to achieve optimal commercial products [13,2]. However, as general-purpose processor cores are used to run software tasks of different applications in SoCs, the communication between the cores cannot be precharacterized and fully optimized, since the application processes can be mapped differently to the cores, typically with the support of the compiler.…”

Section: Introduction and Problem Descriptionmentioning

confidence: 99%

A Reconfigurable Network-on-Chip Architecture for Optimal Multi-Processor SoC Communication

Rana

Atienza

Santambrogio

et al. 2010

IFIP Advances in Information and Communication Technology

View full text Add to dashboard Cite

Summary. Network-on-Chip (NoC) has emerged as a very promising paradigm for designing scalable communication architecture for Systems-on-Chips (SoCs). However, NoCs designed to fulfill the bandwidth requirements between the cores of an SoC for a certain set of running applications may be highly sub-optimal for another set of applications. In this context, methods that can lead to versatility enhancements of initial NoC designs to changing working conditions, imposed by variable sets of executed real-life applications at each moment in time, are very important for designing competitive NoCs in industrial SoCs.In this work, we present a run-time reconfigurable NoC framework based on the partial dynamic reconfiguration capabilities of Field-Programmable Gate Arrays (FPGAs). This new NoC framework can dynamically create/delete express lines between SoC components (implementing dynamically circuit-switching channels) and perform run-time NoC topology and routing-table reconfigurations to handle interconnection congestion, with a very limited performance overhead. Moreover, we show in our experimental results that the addition of these dynamic reconfiguration capabilities into basic NoCs using our framework only implies a very limited area overhead (around 10% on average) with respect to the initial NoC designs; thus, it can bring great benefits when compared to traditional non-reconfigurable NoC design approaches for worst-case bandwidth requirements in SoCs with many possible sets of running applications.

show abstract

“…Kim et al have used a star-based NOC for communication using the principle of CDMA (Code Division Multiple Access) [7], Pande et al compared various network topologies for interconnection networks in terms of latency, throughput, and energy dissipation [6]. Adriahantenaina et al proposed a tree-based implementation of NOC [8], where each node in the tree behaves as a router in NOC several researchers have suggested that 2-D mesh architecture for NOC will be more efficient in terms of latency, power consumption and ease of implementation, as compared to other topologies. The Octagon NOC demonstrated in [9] is an example of a novel regular NOC topology.…”

Section: Introductionmentioning

confidence: 99%

Network on Chip for 3D Mesh Structure with Enhanced Security Algorithm in HDL Environment

Kumar¹,

Singhal²,

Kuchhal³

2012

IJCA

View full text Add to dashboard Cite

Network on chip (NOC) architecture is an approach to develop large and complex systems on a single chip. In this work 3D mesh topological structures has been implemented with enhanced TACIT Security in HDL environment. The architecture supports physical and architectural level design integration. Basic communication mechanism between resources is envisioned to be packet switched message passing through the switches. For the node identification in 3D networks 8 × 8 × 8 Mesh configuration is taken. A new Algorithm is proposed for secured data transmission among nodes. TACIT algorithm is used for data encryption and decryption and applicable for n bit block size and key. Design is implemented in Xilinx 14.2 VHDL software, and functional simulation was carried out in Modelsim 10.1 b, student edition. Hardware parameters such as size cost and timings are extracted from the design code. General Terms

show abstract

Contrasting a NoC and a Traditional Interconnect Fabric with Layout Awareness

Cited by 72 publications

References 16 publications

The power of communication: Energy-efficient NOCS for FPGAS

The power of communication: Energy-efficient NOCS for FPGAS

A Reconfigurable Network-on-Chip Architecture for Optimal Multi-Processor SoC Communication

Network on Chip for 3D Mesh Structure with Enhanced Security Algorithm in HDL Environment

Contact Info

Product

Resources

About