scholarly journals Novel Design of Low-Power High-Speed Hybrid Full Adder Design using Gate Diffusion Input (GDI) Technique

VLSI technology become one of the most significant and demandable because of the characteristics like device portability, device size, large amount of features, expenditure, consistency, rapidity and many others. Multipliers and Adders place an important role in various digital systems such as computers, process controllers and signal processors in order to achieve high speed and low power. Two input XOR/XNOR gate and 2:1 multiplexer modules are used to design the Hybrid Full adders. The XOR/XNOR gate is the key punter of power included in the Full adder cell. However this circuit increases the delay, area and critical path delay. Hence, the optimum design of the XOR/XNOR is required to reduce the power consumption of the Full adder Cell. So a 6 New Hybrid Full adder circuits are proposed based on the Novel Full-Swing XOR/XNOR gates and a New Gate Diffusion Input (GDI) design of Full adder with high-swing outputs. The speed, power consumption, power delay product and driving capability are the merits of the each proposed circuits. This circuit simulation was carried used cadence virtuoso EDA tool. The simulation results based on the 90nm CMOS process technology model.

Sensors ◽  
2021 ◽  
Vol 21 (7) ◽  
pp. 2260
Author(s):  
Khuram Shehzad ◽  
Deeksha Verma ◽  
Danial Khan ◽  
Qurat Ul Ain ◽  
Muhammad Basim ◽  
...  

A low power 12-bit, 20 MS/s asynchronously controlled successive approximation register (SAR) analog-to-digital converter (ADC) to be used in wireless access for vehicular environment (WAVE) intelligent transportation system (ITS) sensor based application is presented in this paper. To optimize the architecture with respect to power consumption and performance, several techniques are proposed. A switching method which employs the common mode charge recovery (CMCR) switching process is presented for capacitive digital-to-analog converter (CDAC) part to lower the switching energy. The switching technique proposed in our work consumes 56.3% less energy in comparison with conventional CMCR switching method. For high speed operation with low power consumption and to overcome the kick back issue in the comparator part, a mutated dynamic-latch comparator with cascode is implemented. In addition, to optimize the flexibility relating to the performance of logic part, an asynchronous topology is employed. The structure is fabricated in 65 nm CMOS process technology with an active area of 0.14 mm2. With a sampling frequency of 20 MS/s, the proposed architecture attains signal-to-noise distortion ratio (SNDR) of 65.44 dB at Nyquist frequency while consuming only 472.2 µW with 1 V power supply.


The present paper proposes a high speed and low power consumption by travelling novel XOR and XNOR gates. The present circuit consist optimized power intakeas well asdelay due to smallamount produced capacitance and power dissipation for low short circuit. Here we utilize 6 new hybrid 1 bit full adder circuitthat produces to and fro XOR/XNOR gates. Here the present circuit has its own advantages like rapidity, power consumption and delay in power product, dynamic capability and so on. Here we proposed signals like HSPICE, Cadence simulations for investigating the performance results which are based on 65-nm CMOS process technical models that indicate high speed and power against FA signals. So here we propose a novel new transistor sizing method that optimizes the PDP circuits. The present circuit investigates on various supply terms of variations like threshold voltages, size of transistors, input noise and output capacitance by utilizing numerical computation particle swam optimization algorithm for achieving desired value in optimum PDP with few iterations


2021 ◽  
Author(s):  
Pratibha Aggarwal ◽  
Bharat Garg

Abstract Adders are one of the most important digital components used in any arithmetic applications. Many improvements in past have been made to improve its architecture. In this paper, we present two new symmetric designs for Energy efficient full adder cells featuring GDI (Gate-Diffusion Input) logic. The main design objectives for these adder modules are to operate at Low-Power with reduced area but also provide full-voltage swing. In the first (AEG-FA) design, a new approach of Inverted and Non-Inverted Carry-ins were taken to give complementary Carry-out and Sum with desired performance. These were then applied in different combinations to form higher bit width Adder architecture. This provides a higher degree of design freedom to target a wide range of applications, hence reducing design efforts. The second (PEG-FA) design is based on conventional approach which tries to reduce the critical path delay and lower switching activity in GDI circuit, providing Low-Power and high speed digital component at full voltage swing circuit. Many of the previously reported adders in literature suffered from the problems of low-swing and high noise when operated at low supply voltages. These two new designs successfully operate at low voltage with high signal integrity and driving capability. In order to evaluate the performance of proposed full adders, we incorporated 8-bit ripple carry adders. The studied circuits are optimized for energy efficiency using 45 nm CMOS process technology. The comparison between these novel circuits with standard full adder cells shows improvement in terms of Area, Delay, Power and Power-Delay-Product (PDP), Area-Delay Product (ADP), Area-Power Product (APP). At architecture level proposed adder shows 12.8% over CMOS, 14.8% over hybrid and 11.4% over other GDI logic power savings, by having almost 55% reduction in area.


In the application of digital signal process multipliers play a vital role. With advances in technology, several researchers have tried and try to design multipliers which supply high speed, low power consumption, regularity of layout and thus less space or maybe combination of them in one multiplier factor. Thus, Compact VLSI design for four bit multiplier factor is planned during this paper that is appropriate for low power and high speed applications. Multiplier factor with high performance is achieved through the novel style of hybrid single bit full adder and Dadda algorithmic rule. The important path delay and power consumption of the planned multiplier factor square measure reduced by 65.9% and 24.5% severally when put next with existing multipliers. The planned multiplier factor is synthesized exploitation CADENCE five.1.0 EDA tool and simulated exploitation spectre virtuoso.


Electronics ◽  
2019 ◽  
Vol 8 (5) ◽  
pp. 589 ◽  
Author(s):  
Tianchen Shen ◽  
Jiabing Liu ◽  
Chunyi Song ◽  
Zhiwei Xu

A high-speed, low-power divide-by-3/4 prescaler based on an extended true single-phase clock D-flip flop (E-TSPC DFF) is presented. We added two more transistors and a mode control signal to the conventional E-TSPC based divide-by-4 divider to achieve the function of the divide-by-3/4 dual modulus frequency divider. The designed divide-by-3/4 achieved higher speed and lower power operation with mode control compared with the conventional ones. The prescaler was comprised of sixteen transistors and integrates an inverter in the second DFF to provide output directly. The power consumption was minimized due to the reduced number of stages and transistors. In addition, the prescaler operating speed was also improved due to a reduced critical path. We compared the simulation results with conventional E-TSPC based divide-by-3/4 dividers in the same process, where the figure-of-merit (FoM) of the proposed divider was 17.4–75.5% better than conventional ones. We have also fabricated the prescaler in a 40 nm complementary metal oxide semiconductor (CMOS) process. The measured highest operating frequency was 9 GHz with 0.303 mW power consumption under 1.35 V power supply, which agrees with the simulation well. The measurement results demonstrate that the proposed divider achieves high-speed and low-power operation.


2012 ◽  
Vol 9 (24) ◽  
pp. 1900-1905
Author(s):  
Kamran Delfan Hemmati ◽  
Mojtaba Behzad Fallahpour ◽  
Abbas Golmakani ◽  
Kamyar Delfan Hemmati

Author(s):  
SYAM KUMAR NAGENDLA ◽  
K. MIRANJI

Now a Days in modern VLSI technology different kinds of errors are invitable. A new type of adder i.e. error tolerant adder(ETA) is proposed to tolerate those errors and to attain low power consumption and high speed performance in DSP systems. In conventional adder circuit, delay is mainly certified to the carry propagation chain along the critical path, from the LSB to MSB. If the carry propagation can be eliminated by the technique proposed in this paper, a great improvement in speed performance and power consumption is achieved. By operating shifting and addition in parallel, the error tolerant adder tree compensates for the truncation errors. To prove the feasibility of the ETA, normal addition operation present in the DFT or DCT algorithm is replaced by the proposed addition arithmetic and the experimental results are shown. In this paper we propose error tolerant Adder (ETA). In the view of DSP applications the ETA is able to case the strict restriction on accuracy, speed performance and power consumption when compared to the conventional Adders, the proposed one provides 76% improvement in power-delay product such a ETA plays a key role in digital signal processing system that can tolerate certain amount of errors.


2011 ◽  
Vol 20 (01) ◽  
pp. 15-27 ◽  
Author(s):  
XIAN TANG ◽  
KONG PANG PUN

A novel switched-current successive approximation ADC is presented in this paper with high speed and low power consumption. The proposed ADC contains a new high-accuracy and power-efficient switched-current S/H circuit and a speed-improved current comparator. Designed and simulated in a 0.18-μm CMOS process, this 8-bit ADC achieves 46.23 dB SNDR at 1.23 MS/s consuming 73.19 μW under 1.2 V voltage supply, resulting in an ENOB of 7.38-bit and an FOM of 0.357 pJ/Conv.-step.


Author(s):  
Mohd Tafir Mustaffa

Comparator is one of the main blocks that play a vital task in the performance of analog to digital converters (ADC) in all modern technology devices. High-speed devices with low voltage and low power are considered essential for industrial applications. The design of a low-power comparator with high speed is required to accomplish the requirements mostly in electronic devices that are necessary for high-speed ADCs. However, a high-speed device that leads the scaling down of CMOS process technology will consume more power. Thus, power reduction techniques such as multi-threshold super cut-off stack (MTSCStack), dual-threshold transistor stacking (DTTS), a bulk-driven, and a bulk-driven differential pair were studied in this work. This study aims to find and build the combination of these techniques to produce a comparator that can operate in low power without compromising existing performance using the 0.13-µm CMOS process. A comparator with a combination of MTSCStack, DTTS, and NMOS bulk-driven differential pair shows the most promising result of 6.29 µW for static power, 17.15 µW for dynamic power, and 23.44 µW for total power.


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