In this article, a low-power and energy-efficient hybrid full adder circuit is proposed, which is implemented based on multi-threshold NAND and NOR gates and transmission gate multiplexers. In order to implement this circuit, carbon nano tube field effect transistors are utilised. For evaluating the proposed design, comprehensive simulations are performed with regard to the most important aspects power, delay and power-delay product. The results are presented and displayed the superiority of the proposed cell in different voltage levels, load conditions, temperatures and robustness against process variations. © 2018 Informa UK Limited, trading as Taylor & Francis Grou
A novel full adder circuit is presented. The main aim is to reduce power delay product (PDP) in the ...
A novel full adder circuit is presented. The main aim is to reduce power delay product (PDP) in the ...
Adders are constituted as the fundamental blocks of arithmetic circuits and are considered important...
In this article, a low-power and energy-efficient hybrid full adder circuit is proposed, which is im...
In this paper, a low-power high-speed hybrid full adder cell is proposed, which is implemented based...
The adder circuit is basic component of arithmetic logic design and that is the most important block...
The full adder circuit is one of the most significant and prominent fundamental parts in digital pro...
<div>In this paper two novel high performance designs for AND and OR basic gates and a novel Full-Ad...
Full Adder is the basic element for arithmetic operations used in Very Large Scale Integrated (VLSI)...
This paper presents two novel full adder cells based on Carbon Nanotube Field Effect Transistor (CNT...
Abstract Carbon Nanotube filed-effect transistor (CNFET) is one of the promising alternatives to the...
The full adder is a key component for many digital circuits like microprocessors or digital signal p...
Nowadays, energy consumption is the main concern in portable electronic systems such as laptops, sma...
Presenting a novel full adder cell will be increases all the arithmetic logic unit performance. In t...
High speed Full-Adder (FA) module is a critical element in designing high performance arithmetic cir...
A novel full adder circuit is presented. The main aim is to reduce power delay product (PDP) in the ...
A novel full adder circuit is presented. The main aim is to reduce power delay product (PDP) in the ...
Adders are constituted as the fundamental blocks of arithmetic circuits and are considered important...
In this article, a low-power and energy-efficient hybrid full adder circuit is proposed, which is im...
In this paper, a low-power high-speed hybrid full adder cell is proposed, which is implemented based...
The adder circuit is basic component of arithmetic logic design and that is the most important block...
The full adder circuit is one of the most significant and prominent fundamental parts in digital pro...
<div>In this paper two novel high performance designs for AND and OR basic gates and a novel Full-Ad...
Full Adder is the basic element for arithmetic operations used in Very Large Scale Integrated (VLSI)...
This paper presents two novel full adder cells based on Carbon Nanotube Field Effect Transistor (CNT...
Abstract Carbon Nanotube filed-effect transistor (CNFET) is one of the promising alternatives to the...
The full adder is a key component for many digital circuits like microprocessors or digital signal p...
Nowadays, energy consumption is the main concern in portable electronic systems such as laptops, sma...
Presenting a novel full adder cell will be increases all the arithmetic logic unit performance. In t...
High speed Full-Adder (FA) module is a critical element in designing high performance arithmetic cir...
A novel full adder circuit is presented. The main aim is to reduce power delay product (PDP) in the ...
A novel full adder circuit is presented. The main aim is to reduce power delay product (PDP) in the ...
Adders are constituted as the fundamental blocks of arithmetic circuits and are considered important...