Journal ArticleDOI
Design of Robust, Energy-Efficient Full Adders for Deep-Submicrometer Design Using Hybrid-CMOS Logic Style
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TLDR
The proposed full adder is energy efficient and outperforms several standard full adders without trading off driving capability and reliability and is based on a novel xor-xnor circuit that generates xor and xnor full-swing outputs simultaneously.Abstract:
We present a new design for a 1-b full adder featuring hybrid-CMOS design style. The quest to achieve a good-drivability, noise-robustness, and low-energy operations for deep submicrometer guided our research to explore hybrid-CMOS style design. Hybrid-CMOS design style utilizes various CMOS logic style circuits to build new full adders with desired performance. This provides the designer a higher degree of design freedom to target a wide range of applications, thus significantly reducing design efforts. We also classify hybrid-CMOS full adders into three broad categories based upon their structure. Using this categorization, many full-adder designs can be conceived. We will present a new full-adder design belonging to one of the proposed categories. The new full adder is based on a novel xor-xnor circuit that generates xor and xnor full-swing outputs simultaneously. This circuit outperforms its counterparts showing 5%-37% improvement in the power-delay product (PDP). A novel hybrid-CMOS output stage that exploits the simultaneous xor-xnor signals is also proposed. This output stage provides good driving capability enabling cascading of adders without the need of buffer insertion between cascaded stages. There is approximately a 40% reduction in PDP when compared to its best counterpart. During our experimentations, we found out that many of the previously reported adders suffered from the problems of low swing and high noise when operated at low supply voltages. The proposed full adder is energy efficient and outperforms several standard full adders without trading off driving capability and reliability. The new full-adder circuit successfully operates at low voltages with excellent signal integrity and driving capability. To evaluate the performance of the new full adder in a real circuit, we embedded it in a 4- and 8-b, 4-operand carry-save array adder with final carry-propagate adder. The new adder displayed better performance as compared to the standard full addersread more
Citations
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Journal ArticleDOI
CMOS Full-Adders for Energy-Efficient Arithmetic Applications
TL;DR: Two high-speed and low-power full-adder cells designed with an alternative internal logic structure and pass-transistor logic styles that lead to have a reduced power-delay product (PDP) outperform its counterparts exhibiting an average PDP advantage.
Journal ArticleDOI
Performance Analysis of a Low-Power High-Speed Hybrid 1-bit Full Adder Circuit
TL;DR: In this paper, a hybrid 1-bit full adder design employing both complementary metal-oxide-semiconductor (CMOS) logic and transmission gate logic is reported and is found to offer significant improvement in terms of power and speed.
Journal ArticleDOI
Design of energy-efficient and robust ternary circuits for nanotechnology
TL;DR: These circuits are designed based on the unique properties of CNFETs, such as the capability of setting the desired threshold voltage by changing the diameters of the nanotubes, which makes them very suitable for the multiple- V t design method.
Journal ArticleDOI
ULPFA: A New Efficient Design of a Power-Aware Full Adder
TL;DR: Comparisons between adders based on full adders from the prior art and the ULPFA version demonstrate that the development outperforms the static CMOS and the CPL full adder, particularly in terms of power consumption and PDP by at least a factor of two.
Journal ArticleDOI
Low-Power and Fast Full Adder by Exploring New XOR and XNOR Gates
Hamed Naseri,Somayeh Timarchi +1 more
TL;DR: The proposed novel circuits for XOR/XNOR and simultaneous XOR–XNOR functions are highly optimized in terms of the power consumption and delay, which are due to low output capacitance and low short-circuit power dissipation.
References
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Low-power logic styles: CMOS versus pass-transistor logic
R. Zimmermann,Wolfgang Fichtner +1 more
TL;DR: This paper shows that complementary CMOS is the logic style of choice for the implementation of arbitrary combinational circuits if low voltage, low power, and small power-delay products are of concern.
Journal ArticleDOI
Performance analysis of low-power 1-bit CMOS full adder cells
TL;DR: A performance analysis of 1-bit full-adder cell is presented, after the adder cell is anatomized into smaller modules, and several designs of each of them are developed, prototyped, simulated and analyzed.
Proceedings ArticleDOI
Reducing power in high-performance microprocessors
TL;DR: The main trends that are driving the increased focus on design for low power are described and areas that need increased research focus in the future are also pointed out.
Journal ArticleDOI
New efficient designs for XOR and XNOR functions on the transistor level
TL;DR: In this article, two new methods are proposed to implement the exclusive-OR and exclusive-NOR functions on the transistor level, one uses non-complementary signal inputs and the least number of transistors, while the other one improves the performance of the prior method but two more transistors are utilized.
Journal ArticleDOI
A review of 0.18-/spl mu/m full adder performances for tree structured arithmetic circuits
TL;DR: In this article, the authors investigated the area and power-delay performances of low-voltage full adder cells in different CMOS logic styles for the predominating tree structured arithmetic circuits.