Congestion-aware wireless network-on-chip for high-speed communication

The design of system-on-chip (SoC) requires the complex integration between a multi-number of cores on a single chip. To establish the effective communication between multiple cores there aremore challenging issues on designing the network-on-chip (NoC) architectures. The proposed system deals with the utilization of on-chip antennas for the wireless communication between the long distance cores to minimize the latency and power. In this proposed work, we have designed high-speed wireless NoC (WiNoC) for on-chip communication. This high-speed WiNoC has been achieved by designing a congestion measure unit, which monitors and measures the congestion in the input data and establishes the effective wireless communication between the output channels and routers. The designed architecture is synthesized and implemented by using Altera Quartus II, where the SoC is designed using Qsys builder. The proposed WiNoC shows better performance parameters like throughput, latency and power than the conventional NoC

Wireless Channel Modeling For Networks On Chips

The advent of integrated circuit (chip) multiprocessors (CMPs) combined with the continuous reduction in device physical size (technology scaling) to the sub-nanometer regime will result in an exponential increase in the number of processing cores that can be integrated within a single chip. Today’s CMPs already support tens to low hundreds of cores and both industry and academic roadmaps project that future chips will have thousands of cores. Therefore, while there are open questions on how to harness the computing power offered by CMPs, the design of power-efficient and compact on-chip interconnection networks that connects cores, caches and memory controllers has become imperative for sustaining the performance of CMPs. As the limited scalability of bus-based networks degrades performance by reducing data rates and increasing latency, the Network-on-Chip (NoC) design paradigm has gained momentum, where a network of routers and links connects all the cores. However, power consumption of NoCs is a significant challenge that should be addressed to capitalize on the scaling advantages of multicores. Also, improvements in metal wire characteristics will no longer satisfy the power and performance requirements of on-chip communication. One approach to continue the performance improvements is to integrate new emerging technologies into the electronic design flow such as wireless/RF technologies, since they provide unique advantages that make them desirable in a NoC environment. First, wireless technologies are ubiquitous and offer a wide range of options in communication, and there exists a vast body of knowledge for the design and implementation of wireless chipsets using RF-CMOS technology. Second, wireless communication, unlike wired transmission, can be omnidirectional, which can facilitate one-hop unicast, multicast, and broadcast communication that can result in a reduction in power consumption while allowing for faster communication. Third, wireless communication can increase the communication data rate by the combination of Frequency Division Multiplexing (FDM) and Time Division Multiplexing (TDM) (and in the future, potentially spatial division multiplexing (SDM)). Therefore, Wireless NoC (WiNoC) interconnects have recently emerged as a viable solution to mitigate power concerns in the short to medium term while still providing competitive performance metrics, i.e., low power consumption, tens of Gbps data rates, and minimal circuit area (or volume) within the chip. Worth noting is that wireless links are not envisioned as replacing all wired links, but rather as augmenting the wired interconnection network. In this dissertation, we employ simulations in HFSS from Ansys® to present accurate wireless channel models for a realistic WiNoC environment. We investigate the performance of these models with different types of narrowband and wideband antennas. This entails estimation of the scattering parameters for the channels between multiple antenna elements in the WiNoC, from which we derive channel transfer functions and channel impulse responses. Using these results, we can estimate the throughput of the various WiNoC links, and this allows us to design effective multiple access (MA) schemes via FDM and TDM. For these MA schemes, we provide estimates of maximal throughput. To further the feasibility study, we investigate the performance of a simple binary transmission scheme--On-Off Keying (OOK)--through the resulting dispersive channels, which can facilitate one-hop unicast, multicast, and broadcast communication that can result in a reduction in power consumption while allowing for faster communication. Our investigation of the performance of On-Off Keying modulation (OOK) also includes an analytical expression for bit error ratio (BER) that can be evaluated numerically. This enables us to provide the equalization requirements needed to achieve our target BERs. Finally, we provide recommendations for WiNoC design and future tasks related to this research

Energy-efficient Adaptive Wireless NoCs Architecture

Abstract—With the increasing number of cores in chip multiprocessors, the design of an efficient communication fabric is essential to satisfy the bandwidth and energy requirements of multi-core systems. Scalable Network-on-Chip (NoC) designs are quickly becoming the standard communication framework to replace bus-based networks. However, the conventional metallic interconnects for inter-core communication consume excess energy and lower throughput which are major bottlenecks in NoC architectures. On-chip wireless interconnects can alleviate the power and bandwidth problems of traditional metallic NoCs. In this paper, we propose an adaptable wireless Network-on-Chip architecture (A-WiNoC) that uses adaptable and energy efficient wireless transceivers to improve network power and throughput by adapting channels according to traffic patterns. Our adaptable algorithm uses link utilization statistics to re-allocate wireless channels and a token sharing scheme to fully utilize the wireless bandwidth efficiently. We compare our proposed A-WiNoC to both wireless/electrical topologies with results showing a throughput improvement of 65%, a speedup between 1.4-2.6X on real benchmarks, and an energy savings of 25-35%. I