1-Bit Full Adder Circuit using XOR-XNOR Cells with Power and Area Optimization

This paper revel a realization of a superior circuit design of 1 bit full adder. The circuit is planned and implemented by using planar DG –MOSFETs at 45 nm technology. In CPU, arithmetic logic unit (ALU) is the core heart.   The adder cell is the important and necessary unit of an ALU. In the present paper, an improved 1-bit full adder circuit is proposed that consumes lower power and reduced number of transistors. The proposed adder circuit consists of 9 transistors and called as 9-T adder cell.  The planar DG-MOSFETs are new emerging transistors which can work n nanometer range and overcome the short channel effects. The simulation of proposed circuit is done in tanner tool version 13.0 using level 54 model files. The simulation is done to compare power, power delay product with supply voltage. The result is also checked at room temperature. This circuit performance of the proposed circuits compared with other reported circuits in literatures and it is seen approximately more than 99.9% reduction in power consumption. Keywords: Low power; Area Efficent; Full Adder; GDI; Multiplexer

Design and Analysis of Multiplexer based Approximate Adder for Low Power Applications

Low power consumption is crucial for error-acceptable multimedia devices, with picture compression approaches leveraging various digital processing architectures and algorithms. Humans can assemble useful information from partially inaccurate outputs in many multimedia applications. As a result, producing exact outputs is not required. The demand for an exact outcome is fading because new innovative systems are forgiving of faults. In the domain where error-tolerance is accepted, approximate computing is a new paradigm that relaxes the requirement for an accurate modeling while offering power, time, and delay benefits. Adders are an essential arithmetic module for regulating power and memory usage in digital systems. The recent implementation and use of approximate adders have been supported by trade-off characteristics such as delay, lower power consumption. This study examines the delay and power consumption of conventional and approximate adders. Also, a simple, fast, and power-efficient multiplexer-based approximate adder is proposed, and its performance outperforms the adders compared with existing adders. The proposed adder can be utilized in error-tolerant and various digital signal processing applications where exact results are not required. The proposed and existing adders are designed using EDA software for the performance calculations. With a delay of 81 pS, the proposed adder circuit reduces power consumption compared to the exact one. The experiment shows that the designed approximate adder can be used to implement circuits for image processing systems because it has a smaller delay and uses less energy

Design and Analysis of Low Run-time Leakage in a 13 Transistors Full adder in 45nm Technology

In this paper a new full adder is proposed The number of Transistors used in the proposed full adder is 13 Average leakage is 62 of conventional 28 transistor CMOS full adder The leakage power reduction results in overall power reduction The proposed full adder is evaluated by virtuoso simulation software using 45 nm technology of cadence tool

Design Optimization of Double Gate Based Full Adder

Full adder is the essential block of circuit of arithmetic’s found in microprocessor and microcontroller in ALU (arithmetic and logic unit). Improving the performance of the adder is very important for up gradation the performance of digital circuit of electronics in which adder is utilized. The main aim of designing of arithmetic circuit is the power consumption. In an arithmetic circuit, the adder is a critical module for operation of addition and also the core for many operations related to arithmetic. Therefore it is obliged to decrease the consumption of power of adder circuit so as to diminish the consumption of the module related to arithmetic. In this paper, a review of double gate based full adder is presented. Various works on this research work which is already available is presented and also problem related to them are presented. Keywords: DG-MOSFET, ALU, XOR, Full Adder,PTI, GDI, Diffused Gdi,Finfet, ELK, Power Grating , Stacking

Design of Low2power Full Adder Using Different Hybrid Logic Styles

Full adder is a basic and most important digital component. To improve the full adder architecture many improvements has been made. Here we present Hybrid CMOS full adder, ULP (Ultra low power) full adder and two new design full adders that is Hybrid logic style and GDI(gate diffusion input ) Structure. These two new full adders consists less number of transistors (i.e.12 transistors) compared to previously designed full adders. The motive of adder cell is to provide high speed, low power consumption and also to give high voltage swing. The Hybrid CMOS logic full adder and ULP full adder uses CPL logic, transmission gates and Static CMOS logic styles. New hybrid full adder uses semi XOR-XNOR gates and GDI-MUX full adder with a new design which eliminates the use XOR-XNOR gates and also uses GDI (gate diffusion input) cell with 12 transistors provides low power, high speed and also full voltage swing. Theses design are implemented in Cadence virtuoso software using 90nm technology GPDK tool kit and comparison of Power, Delay and Power delay product (PDP) is done

Design of Low Power and Area Efficient 8 Bit USR Using mGDI Technology

Technology is growing at a faster rate after the evolution of VLSI, which mainly focuses on three major criteria-speed, area and power. All these criteria determine the compactness of a product in order to produce an efficient output at a higher rate by consuming less power. To achieve the above-mentioned factors, an efficient 8-bit Universal Shift Register (USR) has been designed using modified Gate Diffusion Input (mGDI) technique. The results have been simulated using the TANNER EDA tool and found to contribute for low power and area

Power and area efficient cascaded effectless GDI approximate adder for accelerating multimedia applications using deep learning model

Approximate computing is an upsurging technique to accelerate the process through less computational effort while keeping admissible accuracy of error-tolerant applications such as multimedia and deep learning. Inheritance properties of the deep learning process aid the designer to abridge the circuitry and also to increase the computation speed at the cost of the accuracy of results. High computational complexity and low-power requirement of portable devices in the dark silicon era sought suitable alternate for Complementary Metal Oxide Semiconductor (CMOS) technology. Gate Diffusion Input (GDI) logic is one of the prompting alternatives to CMOS logic to reduce transistors and low-power design. In this work, a novel energy and area efficient 1-bit GDI-based full swing Energy and Area efficient Full Adder (EAFA) with minimum error distance is proposed. The proposed architecture was constructed to mitigate the cascaded effect problem in GDI-based circuits. It is proved by extending the proposed 1-bit GDI-based adder for different 16-bit Energy and Area Efficient High-Speed Error-Tolerant Adders (EAHSETA) segmented as accurate and inaccurate adder circuits. The proposed adder’s design metrics in terms of delay, area, and power dissipation are verified through simulation using the Cadence tool. The proposed logic is deployed to accelerate the convolution process in the Low-Weight Digit Detector neural network for real-time handwritten digit classification application as a case study in the Intel Cyclone IV Field Programmable Gate Array (FPGA). The results confirm that our proposed EAHSETA occupies fewer logic elements and improves operation speed with the speed-up factor of 1.29 than other similar techniques while producing 95% of classification accuracy

A Comparative Review on ALU using CMOS and GDI techniques for Power Dissipation and Propagation Delay

Arithmetic and Logic Circuits are to be designed with less power, compact size, less propagation delay in this fast growing era of technology. Arithmetic operations are indispensable and the basic functions for any high speed low power applications like digital signal processing, microprocessors, image processing, etc. Consumption of power is the major issue in designing these circuits. Also the number of transistors required is also the one of the issues in designing the circuits. To minimize the transistors required in designing the circuits and to reduce the power consumption of the circuits, the authors have referred some techniques to overcome these problems in this paper. By reviewing all these techniques, the authors try to implement the GDI technique to reduce the power consumption and transistors count or the area required to design the circuits

Design and Analysis of High Speed Low Power Hybrid Adder Using Transmission Gates

Addition is the vital arithmetic operation and it acts as a base for many arithmetic operations such as multipliers, dividers, etc. A full adder acts as a basic component in complex circuits. Full adder is the essential segment in many applications such as DSP, Microcontroller, Microprocessor, etc. There exists an inevitable swap between speed and power indulgence in VLSI design systems. A new modified hybrid 1-bit full adder using TG is presented. Here, the circuit is replaced with a simple XNOR gate, which increases the speed. Due to this, transistor count gets reduced results in better optimization of area. The analysis has been carried out also for 2, 4, 8 and 16 bit and it is compared with the various techniques. The result shows a significant improvement in speed, area, power dissipation and transistor counts