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Engineering, Technology & Applied Science Research Vol. 9, No. 6, 2019, 4933-4936 4933 
 

www.etasr.com Ghabri et al.: Performance Optimization of 1-bit Full Adder Cell based on CNTFET Transistor 

 

Performance Optimization of 1-bit Full Adder Cell 

based on CNTFET Transistor 
 

Houda Ghabri 

LETI Laboratory 
National School of Engineering of Sfax  

Sfax, Tunisia  

houda.ghabri@gmail.com 

Dalenda Ben Issa 

LETI Laboratory 
National School of Engineering of Sfax  

Sfax, Tunisia  

dalenda_benissa@yahoo.fr 

Hekmet Samet 

LETI Laboratory 
National School of Engineering of Sfax  

Sfax, Tunisia  

hekmet.samet@enis.rnu.tn 
 

 

Abstract—The full adder is a key component for many digital 

circuits like microprocessors or digital signal processors. Its main 

utilization is to perform logical and arithmetic operations. This 

has empowered the designers to continuously optimize this circuit 

and ameliorate its characteristics like robustness, compactness, 

efficiency, and scalability. Carbon Nanotube Field Effect 
Transistor (CNFET) stands out as a substitute for CMOS 

technology for designing circuits in the present-day technology. 

The objective of this paper is to present an optimized 1-bit full 

adder design based on CNTFET transistors inspired by new 

CMOS full adder design [1] with enhanced performance 

parameters. For a power supply of 0.9V, the count of transistors 

is decreased to 10 and the power is almost split in two compared 

to the best existing CNTFET based adder. This design offers 

significant improvement when compared to existing designs such 

as C-CMOS, TFA, TGA, HPSC, 18T-FA adder, etc. Comparative 

data analysis shows that there is 37%, 50%, and 49% 

amelioration in terms of area, delay, and power delay product 

respectively compared to both CNTFET and CMOS based 
adders in existing designs. The circuit was designed in 32nm 

technology and simulated with HSPICE tools. 

Keywords-1-bit full adder; CNTFET; PDP; low power; 

HSPICE 

I. INTRODUCTION  

Semiconductor technologies are in a constant innovation 
race to create a new functionality and meet growth-up 
expectations. Implemented semiconductor devices for 
scientific, industry and consumers, are expected to offer high 
performance with high speed, scalability, and, especially, low 
power consumption. In embedded electronic products such as 
mobile phones, laptops and connected watches, power 
consumption is a key element that influences directly circuit 
operation. Metal Oxide Semiconductor Field Effect Transistors 
(MOSFETs) can’t no longer comply with Moore’s Law [2-3], 
which led to the need of finding alternative technologies. Each 
technology has its advantages and disadvantages. Carbon 
Nanotube Field Effect Transistor (CNFET) is the most 
promising technology with interesting advantages. It is widely 
adopted and has become one of the most interesting research 
areas [4, 5]. CNFET is flexible in overcoming challenges like 
ballistic transport, short channel effects, low OFF-current 
properties, etc. Because the complete adder circuit is 

indispensable in any digital product, the performance of any 
digital circuit can be improved by enhancing it performance. 
Efforts to optimize performance are continuous, efforts such as 
the Conventional–Complementary Metal Oxide Semiconductor 
[1], the Removed Single Driving Full Adder (RSD-FA) [6], the 
Hybrid Pass Transistor Logic with Static CMOS output drive 
(HPSC) [3], the 18 Transistor 1-bit Full Adder [7], the Hybrid 
Multi-Threshold Full Adder (HMTFA) [8], and the low power 
based CNTFET [9]. The implementation of these adder circuits 
takes place using various logic families, therefore the above 
mentioned adders have different advantages and disadvantages. 
In this paper, a new schematic with 10T transistor is proposed, 
inspired from the new CMOS full adder design [1]. After 
simulation and analysis, this design offers an interesting PDP 
with limited number of transistors. Table I shows the 
comparison results for the proposed and the existing full adder 
designs implemented using CNFET and CMOS based on 
power, delay, and power delay product parameters (PDP). The 
proposed full adder circuit was designed with CNFET 
technology simulated at 32nm with a voltage supply of +0.9V 
using the HSPICE tool. The model used is a Stanford nano 
model.  

II. BACKGROUND OF CNFET 

Among new technologies, CNTFET is placed as one with 
the most potential thanks to its specific physical characteristics. 
It offers many advantages like quasi-ballistic transport due to 
high mobility, fast switching due to high carrier speed, and 
almost one-dimensional structure of carbon nanotube for better 
electrostatic control [10]. In fact, each carbon nanotube reacts 
as a channel contrary to MOSFET, where the entire silicon acts 
as a channel [11]. The mobility in n and p types of CNFET is 
identical and the two types of transistor transfer the same 
driving current. This allows the creation of a completely novel 
logic not possible with MOSFET transistors. 

III. EXISTING ADDER DESIGNS 

Many full adder designs are available in the literature. 
Among them, the 23T full adder cell, which is an improved 
version of the 18T adder block [12], combining two logics, 
pass-transistor and transmission gate. There are five inverter 
stages to have the final output (Sum) causing a longer critical 
path and utilizing an important number of transistors. The 

Corresponding author: Houda Ghabri



Engineering, Technology & Applied Science Research Vol. 9, No. 6, 2019, 4933-4936 4934 
 

www.etasr.com Ghabri et al.: Performance Optimization of 1-bit Full Adder Cell based on CNTFET Transistor 

 

logical operations are performed serially and not 
simultaneously. Two different blocks are used to generate the 
Sum and the Cout. This impacts strongly the speed of this 
circuit and the consumed power. Another interesting design is 
the hybrid full adder cell [12, 13]. Two different circuits are 
used to generate simultaneously the Sum and the Cout output. 
Two cascaded XOR/XNOR cells are used to generate the Sum 
signal and many inverters are required. As a result, a huge 
number of transistors are used and the critical path becomes 
very long, causing speed problem. In order to solve this issue 
the CNTCPL architecture was proposed [14]. Because its 
critical path is composed of only two pass transistors, the delay 
is very short. In addition, using CNTFET technology increases 
speed, and overcomes the inconvenience of non-full-swing 
nodes. Although this design solves the problem of speed, it is 
not an appropriate choice for low-power applications. This 
design suffers from many issues, such as low driving capability 
caused by utilization of pass-transistor logic, high transistor 
counts due to duplicate blocks for Sum and Cout, and finally 
signal integrity problem caused by cascading blocks in series, 
especially in high frequencies. CNTFA based on CNTFET 
transistor is the last studied full adder design [14]. This circuit 
is composed in intermediate XOR and XNOR functions and 
pass-transistor logic. The generated XOR/XNOR signals are 
used as selectors in a multiplexer-based structure at the second 
stage to generate Sum. Sum and output carry are generated in 
parallel by a pass-transistor based block. This design has 
multiple merits like high-speed computation and low power 
consumption, but when facing high load capacitors, it suffers 
from downfalls due to its low driving capability. As discussed 
above, the known full adder circuits have many disadvantages 
and performance optimization to follow the growing 
expectation is an open research topic. In this context we 
propose a new CNTFET full adder design trying to find a 
solution to some of these problems. 

IV. PROPOSED FULL ADDER CIRCUIT 

Inspired from the new CMOS full adder design [1] we 
propose a 1-bit full adder based on 10 CNTFET transistors that 
calculate the Sum and carry using less transistors. The Sum and 
carry of any full adder are achieved from the input bits 
including the previous stage carry. The expressions giving the 
relationship between the input and output bits are: 

Sum = A ⊕ B ⊕ Cin (1) 

Carry = A.B + B.Cin + A.Cin (2) 

where A and B are the inputs, the outputs are Sum and Carry 
and Cin represents the carry input, if any. The proposed full 
adder design requires 10 transistors and consists of two 
XOR/XNOR gates. The implemented circuit composed of two 
XOR gates which are designed by using four transistors each is 
shown in Figure 1. 

Less transistor count results to less load capacitance values 
and so the switching power dissipation is less in this CNTFET 
based full adder compared to other techniques. We are 
presenting the smallest full adder design in CNTFET 
technology (Figure 1). Transistor number reduction allowed us 
a considerable gain in consumption and generally in PDP. The 

simulation results of the proposed full adder are presented in 
Figure 2. To show the amelioration done by the proposed 
design we compared the simulation results with the best 
CNTFET based adder in literature. Comparison parameters 
were power, delay and PDP. The mathematical calculations 
needed to perform this comparison are explained below. 

 

 
Fig. 1.  The proposed full adder cell 

A. Power Consumption Calculation 

PDP keeps a balance between delay and power, it is the 
multiplication result of the maximum delay and the average 
power consumption: 

PDP = Max(Delay)×P��� (3) 

Power average is the sum of two powers: static power and 
dynamic and short-circuit power [5]. Static power comes from 
biasing and leakage currents. The most important component of 
power consumption, the dynamic power, is a result of the load 
capacitances charging and discharging. The load capacitance, 
Cload, can be presented as a mix of a fixed capacitance, Cfix, and 
a variable capacitance, Cvar, as follows: 

Cload = Cfix+Cvar  (4) 
where Cfix is the technology-dependent due to diffusion 
capacitance and interconnect dependent capacitances, Cvar is 
composed of the input capacitances of subsequent stages and a 
part of the diffusion capacitance at the gate output and can 
therefore be taken care of by proper transistor sizing. 

P���= Ids×Vdd×fc×Cload  (5) 
where Ids is the drain to source current (A), Vdd is the supply 
voltage (V), Cload is the output load capacitance (F), and fc is 
the clock frequency (HZ). 

B. Calculation of Propagation Delay 

The adder is a fundamental element in most electronic 
systems. That is why the optimization of its response delay 
affects directly the speed of the whole system. The speed of the 
adder response is mainly dependent on the propagation delay of 
the carry signal which is usually minimized by reducing the 
path length of the carry signal. The delay is calculated from the 
time that the input signal reaches ½Vdd to the time that the 
output signal reaches the same voltage level. 



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www.etasr.com Ghabri et al.: Performance Optimization of 1-bit Full Adder Cell based on CNTFET Transistor 

 

 
Fig. 2.  Output waveforms of the proposed full adder design 

In the present design, the carry signal is generated by 
controlled transmission of the input carry signal and either of 
the input signals A or B (when A=B). As the carry signal 
propagates only through the single transmission gate, the carry 
propagation path is minimized leading to a substantial 
reduction in propagation delay. The delay incurred in the 
propagation is further reduced by efficient transistor sizing and 
deliberate incorporation of strong transmission gates. Based on 
this information, power consumption and PDP are calculated 
for the proposed design. In Table I, the performance of the 
proposed full adder is compared with existing designs [9]. The 
number of transistors for the proposed full adder is 10. The 
calculated delay is 4ps. For 0.9 Supply the power consumption 
is 0.073µW and the calculated PDP is 0.592 aJ. 

TABLE I.  COMPARATIVE ANALYSIS FOR NUMBER OF TRANSISTORS, 
DELAY, POWER, AND PDP 

Full Adder 
Transistor 

count 

Power 

(µW) 
Delay (ps) PDP (aJ) 

C-CMOS [2] 28 0.124 12.355 1.532 

TGA [13] 20 0.135 10.104 1.364 

CPL [17]  1.33 0.84 0.38 

TFA [18] 16 0.109 11.701 1.275 

HPSC [3] 26 0.095 30.654 2.912 

CLRCL [15] 10 5.903 231.18 1364.65 

OURS1 [4] 28 0.163 10.866 1.771 

HCTG [5] 16 0.124 12.116 1.502 

RSD-FA [6] 26 0.091 9.427 0.857 

18T-FA [6] 18 0.088 8.93 0.785 

HMTFA [7] 23 0.1216 16.909 2.056 

1bFA16 [9] 16 .073 8.12 0.592 

Proposed 10 0.073 4 0.295 

V. CONCLUSIONS 

A novel full adder cell inspired from recent CMOS design 
has been presented. Although many designs have been 
presented recently with the aim of reducing the number of 
transistors, they suffer from serious problems such as PDP, and 
delay. Although reducing the number of transistors intrinsically 
leads to less area and power consumption, the other 
performance parameters should be taken into consideration in 
order to make the circuit work properly in real conditions. 
Simulation results prove that the proposed full adder exhibits 
improvement in area, delay, and PDP by approximately 37%, 
50%, and 49% respectively compared to the best CNTFET-
based adder found in the literature. In future work, this design 
can be further extended for a 32-bit full adder implementation. 

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