J V R Ravindra

Work place: Department of ECE, C-ACRL, Vardhaman College of Engineering, Hyderabad, Telangana, India

E-mail: jvrravindra@gmail.com

Website:

Research Interests:

Biography

J.V.R.Ravindra received Bachelor's degree in Electronics and Communication Engineering from Osmania University, Hyderabad, India and a Master's degree also from Osmania University in Systems and Signal processing. He received PhD degree from the Center for VLSI and Embedded systems Technologies of the International Institute of Information Technology (IIIT-H), Hyderabad, India. He is currently working as a Principal and Professor at Vardhaman College of Engineering, Hyderabad, India. His research interests are device-circuit co-design for nano-scale Silicon and non-Silicon technologies, low-power electronics for portable computing and wireless communications, and new computing models enabled by emerging technologies.  He has published more than 100 papers in referred journals and conferences and holds two patents. He is a senior member of IEEE, ACM, and a fellow IETE.

Author Articles
Prediction of Intermittent Failure by Presage Debacle Model in Network on Chip

By Sangeeta Singh J V R Ravindra B. Rajendra Naik

DOI: https://doi.org/10.5815/ijcnis.2022.04.06, Pub. Date: 8 Aug. 2022

With the emergence of deep sub-micron technology, the reliability issues in on-chip interconnect has enormously increased. This includes single event upsets, like soft errors, and hard faults which are rapidly becoming important factors to be considered. Aggressive technology scaling renders these architectures vulnerable to system performance, intermittent failure, capacitive crosstalk, and power dissipation problem. To improve the performance of the area and power consumption along with bandwidth, throughput and latency, a Buffer Potency Power Gating Technique is carried out to predict the Intermittent Failure by Presage Debacle Model in Network on Chip. In the Presage Debacle Model, the links present in the application-specific topology are provided with real application traffic to assist in prediction of the intermittent failure. By predicting the failure, the output of the model provides the power dissipated over the connection of the application link. Then the crosstalk noise in the topology is reduced by the Adaption of Simulated Annealing (SA) based Particle Swarm Optimization (PSO) congruence algorithm. The optimization congruence algorithm assigns each task in the application software to each node in the topology to determine the network's optimal output. It continuously changes the task park position in the topology system and reduces the crosstalk of the NoC. Consecutively, the area and power consumption are minimized by Buffer Potency Power Gating Technique. Buffer efficiency is increased and the power-gating is a practical way to mitigate NoC power control schemes properly and effectively without any loss in performance. Thus the prediction of intermittent failure is obtained by utilizing NoC to improve the performance of area and power consumption.

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