G Sushma scite author profile

Network on-Chip (NoC) – the network-based communication between operational cores and intellectual property cores in a single chip – has been eliciting much interest in recent years. The major barrier to the effective design of NoCs has been high-speed data transfer and connections that are only required when necessary in massively parallel, multi-core, low-power applications. To solve these issues, a new technique called Pareto African Buffalo Optimized Mapping Weighted Directive Graph Theory (PABOMWDGT) is proposed in this study. The suggested method aims to locate efficient operational cores integrated on the device in the shortest time and demonstrate the effectiveness of 3D NoC. In this approach, a selection of IP cores from the benchmark dataset are first listed along with their connections. The mapping approach on the 3D NoC topology is optimized for the African buffalo. Random initialization of the IP cores (also known as buffalos) in the optimization technique's search space is performed. Every IP core in the population is used to estimate the various objective functions. The Pareto function is then examined using the African buffalo optimization technique of Deming Regression. A fitness metric is employed to determine the best fit. The position of the buffalos is updated and the best option is identified when one buffalo's fitness level exceeds that of the other. The process is repeated until the maximum number of iterations is reached. Then, mapping is done based on the probability. It is seen that it takes less time to develop an effective mapping of cores in the 3D NoC architecture. Experimental results show that the proposed PABOMWDGT technology is superior to state-of-art techniques with a 0.74 packet / cycle / IP block throughput, 140 clock cycle delay, and 11 ms computation time.

show abstract

Multiobjective piecewise regressive elitism spotted hyena optimized mapping for 3D NoC architecture design

2023

Int. j. inf. tecnol.

EMSOA based application mapping framework for power optimisation in 3D-NoC

International Journal of Electronics

2022

Multicriteria Deming Regressive African Buffalo Optimized Mapping for 3D NoC Architecture Design

Alagarsamy

Mathematical Problems in Engineering

et al. 2022

Purpose. Networks-on-Chip (NoC) is a network-based communication between operating cores and intellectual property (IP) cores integrated on the same chip. An efficient design of NoC ensures high-speed data transfer and minimum essential connections in large-scale multicore, low power applications. Design/methodology/approach. A unique technique called Multicriteria Deming Regressive African Buffalo Optimized Mapping Weighted Directive Graph Theory (MDRABOMWDGT) is introduced for an efficient Network-on-Chip architecture design. The main aim of the proposed technique is to find efficient operating cores integrated on the chip with minimum time. Initially, a set of IP cores are listed with their connections from the benchmark dataset. Then Multicriteria Deming Regressive African Buffalo Optimization is applied to the topology for mapping strategy on 3D NoC, with communication metrics such as throughput, latency, and computation time. The optimization technique initializes the population of cores in search space. For each core in the network, communication metrics are measured; then Deming regression is applied to analyze multicriteria functions for minimizing computation time. Further, fitness is measured to get an optimal IP core for improving the performance of mapping in 3D NoC. Findings. Comprehensive experimental evaluation is conducted using a benchmark dataset, communication metrics are measured, and results show significant improvement in performance with respect to energy parameters compared to state-of-the-art works. Originality/value. The mapping strategy for 3D NOC is developed and the results are compared with the state-of-the-art techniques.

show abstract

Pareto Technique Optimization for 3d Noc Architecture

2022

SSRN Journal