This paper presents the design and evaluation of the proposed Clocked CMOS Differential Adiabatic Logic (CCDAL), a two-phase clock operated charge recovery logic. The evaluation of the logic is made through implementation of an 8-bit Carry Save multiplier circuit operated using two complementary sinusoidal power clock signals. The proposed logic circuit inherits all the advantages of Clocked CMOS Adiabatic Logic (CCAL) and further exhibits improved drivability and circuit robustness resulting in higher frequency performance even while operating at low power. The adiabatic multiplier has been verified upto a maximum operating frequency of 500 MHz. Extensive simulations support the claim that proposed multiplier is energy efficient at high frequencies compared to other two-phase adiabatic counterparts, namely, Quasi Static Energy Recovery Logic (QSERL) and Two-phase Adiabatic Dynamic Logic (2PADL) and Clocked CMOS Adiabatic Logic (CAL). The multiplier is designed using 180 nm technology library and simulations are carried out using industry standard Cadence® Virtuoso tool. © 2018 American Scientific Publishers.

Sasipriya P

Electrical

School of Electrical Engineering

Chennai Campus

V S Kanchana   Bhaaskaran

Electronics

School of Electronics Engineering

Vellore Institute of Technology (VIT) is a private university located in&nbsp;Tamil Nadu, India. Founded in 1984, as Vellore Engineering College, the institution offers 20 undergraduate, 34 postgraduate, four integrated and four research programs. It has campuses in Vellore, Amravati, Bhopal and Chennai.

VIT is one of the top ranked private universities in India according to NIRF, THE and QS Rankings.&nbsp;Govt. of India has recognized&nbsp;VIT, Vellore as an&nbsp;Institution of Eminence. This has allowed VIT to take independent quality initiatives and move up in world ranking.

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VIT University

Journal of Low Power Electronics

Design and Analysis of Clocked CMOS Differential Adiabatic Logic (CCDAL) for Low Power

This paper presents the quasi-adiabatic logic for low power powered by two phase sinusoidal clock signal. The proposed logic called two phase adiabatic dynamic logic (2PADL) realizes the advantages of energy efficiency through the use of gate overdrive and reduced switching power. It has a single rail output and the proposed logic does not require the complementary input signals for any of its variables. The 2PADL logic is operated by two complementary clock signals acting as power supply. The validation of the proposed logic is carried out through practical circuits such as (i) sequential circuits using energy recovery technique suitable for memory circuits, (ii) an adiabatic carry look ahead adder (CLA) designed using 2PADL to study the speed performance and to prove its energy efficiency across a range of frequencies and (iii) a multiplier circuit using 2PADL compared against CMOS counterpart. The CLA adder is also implemented using the other static adiabatic logics, namely, quasi static energy recovery logic (QSERL), clocked CMOS adiabatic logic (CCAL) and conventional static CMOS logic to compare against 2PADL and validate its power advantages. The performance of the CCAL logic is tested for higher frequencies by implementing the widely presented CLA circuit. The result proves that the design is energy efficient and operates up to the frequency of 600 MHz. The simulation was carried out using industry standard Cadence® Virtuoso tool using 180[Formula: see text]nm technology library files.

Journal of Circuits, Systems and Computers

Design of Low Power VLSI Circuits Using Two Phase Adiabatic Dynamic Logic (2PADL)

The novel pre-resolve and Sense Adiabatic Logic (PSAL) is a less complex quasi-adiabatic logic circuit usable for frequency range from 100 KHz to 500 MHz. It employs a large height pre-resolved nMOS structured tree and a differential sensing logic. The logic realizes superior energy efficiency through reduced silicon area requirement, low circuit latency, glitch-free output and less switching transients. Significant reduction in switched capacitance realizes enhanced speed performance. Furthermore, evaluation of more than one level of gate (or a complex gate) in each phase makes use of less number of buffers possible, in the adiabatic pipeline. With circuit latency being a major impediment of four-phase adiabatic logic styles, PSAL achieves better throughput and reduced critical path length leading to improved frequency performance. The nMOS structured cascode tree and differential sensing logic help overcome the incomplete charge-recovery and the floating output node problems prevalent in adiabatic logic structures. Full custom and modular flow is adopted in the circuit designs. The design is proved energy-efficient for both low and high frequency ranges of the order of 200 KHz and 500 MHz, respectively for an 8-bit multiplier. Full-custom designs are done using 350 nm CMOS technology library from Austria Micro Systems. Performance efficiency is proved through comparisons with static CMOS and PFAL equivalent circuits through extensive post-layout simulations.

PRE-RESOLVE AND SENSE ADIABATIC LOGIC FOR 100 KHZ TO 500 MHZ FREQUENCY CLASSES

This paper presents Differential Cascode Pre-resolve Adiabatic Logic (DCPAL) that can operate with greater functionality, larger fan-in and high energy efficiency. It is a diode free and dual rail logic operated by four phase power clock for the adiabatic pipeline. Less complex with differential cascode structure and fewer numbers of transistors, the pre-resolving feature for the complementary inputs achieves reduction in latency, significant drop in the switched capacitance that realizes power efficiency, better silicon area efficiency, reduced leakage paths and glitch-free output with reduced switching transients. Energy efficiency against static CMOS equivalent and better speed performance against 2N2P, 2N2N2P, PFAL and IPGL equivalent circuits are proved. By the use of post-layout simulations of multi-bit adder and multiplier circuits adopted through full-custom circuit design, the DCPAL achieves adiabatic gain values in the range of 20.85 at 100 MHz power clock frequency to 9.88 at 500 MHz against the static CMOS equivalent 8-bit Wallace tree multiplier circuit. Energy saving of 50% and 45% is achieved against optimized 2N2N2P and PFAL 8-bit multiplier circuits at 500 MHz, and energy saving against these circuits enhances further at higher frequencies. Copyright © 2008 American Scientific Publishers All rights reserved.

Journal	Data powered by TypesetJournal of Low Power Electronics
Publisher	Data powered by TypesetAmerican Scientific Publishers
ISSN	1546-1998
Open Access	No