Publication Type : Journal Article
Publisher : IEIE Transactions on Smart Processing and Computing (Scopus)
Source : IEIE Transactions on Smart Processing and Computing (Scopus), Volume 6, Issue 3, p.220-227 (2017)
Url : https://www.koreascience.or.kr/article/JAKO201719363529085.pdf
Keywords : Clock gating techniques, D Latch, LECTOR, power, Single and multi–stage D Flip-flop
Campus : Amritapuri
School : Department of Computer Science and Engineering, School of Engineering
Center : Electronics Communication and Instrumentation Forum (ECIF)
Department : Computer Science, Electronics and Communication
Year : 2017
Abstract : Technology development is leading to the invention of more sophisticated electronics appliances that require long battery life. Therefore, saving power is a major concern in current-day scenarios. A notable source of power dissipation in sequential structures of integrated circuits is due to the continuous switching of high-frequency clock signals, which do not carry any information, and hence, their switching is eliminated by a method called clock gating. In this paper, we have incorporated a recent clock-gating style named Leakage Control Transistor (LECTOR)-based clock gating to drive a multi-stage sequential architectures, and we focus on its performance under three different process corners (fast-fast, slow-slow, typical-typical) through Monte Carlo simulation at 18 GHz clock with 90 nm technology. This gating is found to be one of the best gated approaches for multi-stage architectures in terms of total power consumption.
Cite this Research Publication : Dr. Pritam Bhattacharjee, Alak Majumder, and Bipasha Nath, “A 23.52µW / 0.7V Multi-stage Flip-flop Architecture Steered by a LECTOR-based Gated Clock”, IEIE Transactions on Smart Processing and Computing (Scopus), vol. 6, no. 3, pp. 220-227, 2017.