New ternary adders, which are fundamental components of ternary addition, are presented in this paper. They are on the basis of a logic style which mostly generates binary signals. Therefore, static power dissipation reaches its minimum extent. Extensive different analyses are carried out to examine how efficient the new designs are. For instance, the ternary ripple adder constructed by the proposed ternary half and full adders consumes 2.33 μW less power than the one implemented by the previous adder cells. It is almost twice faster as well. Due to their unique superior characteristics for ternary circuitry, carbon nanotube field-effect transistors are used to form the novel circuits, which are entirely suitable for practical applications.
1. Introduction
On-chip interconnections have become a serious challenge as more and more modules are packed into a chip. They dissipate lots of energy, increase response time, and cause coupling effects by adding more capacitance, resistance, and inductance to a circuit [1]. Multiple-valued logic (MVL) is an alternative solution to interconnect complexity and growing power dissipated by wires [2]. It reduces the amount of wires inside and outside a chip dramatically as more complex designs require a large number of wires for connecting circuit components. In addition, MVL has the high potential for increasing computational speed, reducing switching activity, and implementing many arithmetic and logic functions in a single chip [2, 3]. Among many MVL systems, ternary logic (also known as three-valued logic) has soared in popularity due to its simplicity and efficiency [4, 5].
In spite of potential superiorities of ternary logic, binary is still the dominant logic for circuit design in the industry. One of the main reasons is the intrinsic behaviour of transistors. The on-off characteristic of a transistor makes it an ideal device to implement Boolean algebra. However, dualism does not correspond to real-world applications effectively. Another reason why ternary logic is not as popular as its binary counterpart is mainly because of the lack of sufficient practical, high-performance logic gates and computational components. To make ternary logic applicable in practice, efficient circuits must be developed before all else.
Voltage-mode MVL circuits are based on multithreshold designs [6, 7]. Therefore, traditional metal-oxide-semiconductor field-effect transistor (MOSFET) is not entirely suitable candidate for MVL implementation due to the fact that MOS devices are inherently single-threshold [8]. Since the introduction of new nanoscale devices such as quantum-dot cellular automata (QCA) and carbon nanotube field-effect transistor (CNTFET), many worthwhile endeavours have been made to present novel ternary circuits with high efficiency. The unique characteristic which makes CNTFET technology highly appropriate for ternary circuitry is the ability of adjusting threshold voltage by altering the diameter of CNTs under the gate terminal [9]. The tuneable threshold voltage brings essential flexibility which is a great necessity for ternary designs. Furthermore, CNTFETs operate far faster and even consume less power in comparison with traditional MOS devices [10, 11]. Although commercial CNTFET chips are not ready yet, many valuable achievements have been made so far. The implementation of CNTFET-based logic gates has been reported in [12, 13]. In addition, the first carbon nanotube computer has been recently developed [14].
A gate-level implementation for ternary half adder (THA) has been presented by Dhande and Ingole [15]. The main drawback is having a very large number of transistors. Lin et al. [16] have replaced some ternary gates with binary ones to reduce transistor count and decrease static power dissipation. Their design has 158 transistors (THA-158T). The final attempt is a NAND-based structure presented by Moaiyeri et al. [17]. In spite of a great reduction, it still needs 112 transistors (THA-112T). A new ternary full adder (TFA) has been presented by Ebrahimi et al. [18]. It is on the basis of two cascaded so-called THAs, in which the output carry is not produced. A carry generator subcircuit produces the final carry from the initial inputs and the output of the first pseudo-THA. The entire block requires 106 transistors (TFA-106T). Another TFA, which directly generates both outputs (Sum and Cout) from the input variables, has recently been presented by Keshavarzian and Sarikhani [19]. It needs 132 transistors to form the whole adder cell (TFA-132T).
In this paper, new ternary adders are presented on the basis of a logic style where a large portion is founded upon binary structures. As a result, static power dissipation reaches its minimum extent. The new adder cells operate very rapidly and have a reasonable number of transistors compared with the ones presented in the literature so far. Moreover, they benefit from full-swing operation, capability of working in high frequencies, and strong driving power.
Due to the inaccurate chip fabrication of CNTFET technology, diversity of using CNTs with different diameters decreases the manufacturability issue. Nevertheless, fabrication of multichirality CNTs is inevitable for ternary circuitry due to the fact that ternary circuits are based on multi-Vt designs [6, 7]. The entire novel ternary circuits are developed by CNTs with only three different diameters as it is very common in ternary logic circuitry [16–19]. The proposed designs show low sensitivity to undesired environmental and process variations.
The rest of the paper is organized as follows: Section 2 will express how we are motivated to design new circuits. The proposed ternary adders are presented in Section 3. Section 4 includes simulation results and comparisons. Eventually, Section 5 concludes the paper.
2. Motivation
Implementation of ternary logic is based on an additional voltage level in comparison with binary logic. The voltage level of Vdd/2 stands for the logic value “1” in the unbalanced ternary notation [20], whereas zero and Vdd voltages represent the logic values of “0” and “2,” respectively. Voltage dividers such as resistors [21] or capacitors [22] are used to divide voltage. Current flows through the path established from the power supply to the ground each time voltage division occurs. A significant portion of the total power consumption in ternary circuits is static power. Although the usage of capacitors leads to less power dissipation, they provide weak current drivability.
A great advantage of complementary-symmetry metal-oxide-semiconductor (COS-MOS, or CMOS) technology for implementing logic functions is the elimination of continuous static current in binary circuits, due to the fact that either the pull-down or the pull-up network is switched off. This is the reason why some recent works have replaced as many ternary gates as possible with binary ones [16]. A comparison between the average power consumption of THAs presented by Dhande and Ingole [15] and Lin et al. [16] demonstrates that it is more beneficial to use CMOS-based binary circuits as much as possible. The fewer times voltage division takes place, the less power dissipates. In this paper, one of the main targets is to use a logic style in which voltage division occurs as few times as possible so that the static power is reduced to its smallest amount.
The logic style directly influences delay, power consumption, and area characteristics, which are the most important parameters for performance evaluation. There are two definitions of a ternary function other than the standard one. The first (second) interpretation is negative (positive) ternary, denoted by − (+), in which the logic value “1” is replaced with “0” (“2”) [23]. Therefore, they are in fact binary functions. Figure 1 illustrates the utilized logic style, which is based upon (1). Positive and negative complementary outputs (Out¯+ and Out¯-) are first generated. Then, binary inverters convert Out¯+ and Out¯- to Out− and Out+, respectively. Finally, two transistors perform voltage division to generate STOut (1). Therefore, voltage division takes place only once for implementing a ternary function. This logic style is employed in this paper to design new ternary adders.
(1)STOut=(Out¯+¯)+(Out¯-¯)2=(Out-)+(Out+)2.
The utilized logic style for implementing new adder cells.
3. New Single-Bit Ternary Adders3.1. New Ternary Half Adder
Adder is a fundamental component for all arithmetic operations such as subtraction, multiplication, and division. Half adder is the simplest adder block which performs addition of two input signals. The proposed ternary half adder is illustrated in Figure 2, in which diameters of CNTs are indicated for each transistor. For CNTFETs with diameters of 1.489 nm, 1.096 nm, and 0.783 nm, the chirality numbers are (19, 0), (14, 0), and (10, 0), and subsequently the threshold voltages are 0.289 V, 0.392 V, and 0.549 V, respectively, ((2), (3)) [24]. The (n1, n2) indices are the chirality numbers which indicate wrapping vector along which a sheet of graphite is rolled up to form a carbon nanotube (CNT). These CNTs are used as the channel of the transistor. The diameter of an SWCNT can be as small as 0.4 nm [25]. The typical diameters change between 0.7 nm and 3 nm with mean diameter of 1.7 nm [26].
(2)DCNT=0.0783×n12+n22+n1×n2,(3)Vth≈0.43DCNT(nm).
The proposed ternary half adder (#Tube = 3), (a) Sum generator subcircuit, (b) Carry generator subcircuit.
The final outputs (Sum and Cout) are generated in a parallel manner. Two different subcircuits create Sum¯+ and Sum¯- (Figure 2(a)) by taking input values shown in Table 1. The first set of transistors, which are marked with “1,” connects the node Sum¯+ to the power supply when either (a,b)=(0,0) or (a,b)=(0,1)∣(1,0), considering input permutations. Two other parallel paths, on which transistors are marked with “2,” are supplemented in order to connect the output node to Vdd when either (a,b)=(2,2) or (a,b)=(1,2)∣(2,1). Within the pull-down network, the third path connects the node Sum¯+ to the ground whenever (a,b)=(1,1). Finally, the fourth set of transistors is switched on when (a,b)=(0,2)∣(2,0). Table 1 summarizes the way paths connect the nodes Sum¯+ and Sum¯- to the appropriate voltage source, in light of different input patterns.
Midoutput values of the Sum generator subcircuit.
a
b
a¯+
a¯-
b¯+
b¯-
Sum
Sum¯+
Path(s)
Sum¯-
Path(s)
0
0
2
2
2
2
0
2
1
2
5
0
1
2
2
2
0
1
2
1
0
7, 8
0
2
2
2
0
0
2
0
4
0
7
1
0
2
0
2
2
1
2
1
0
7, 8
1
1
2
0
2
0
2
0
3
0
8
1
2
2
0
0
0
0
2
2
2
6
2
0
0
0
2
2
2
0
4
0
7
2
1
0
0
2
0
0
2
2
2
6
2
2
0
0
0
0
1
2
2
0
9
The same concept leads us to the output carry generator subcircuit (Figure 2(b)). Table 2 shows which transistors set up the proper path to connect the midoutput Cout¯- to the proper voltage source. Cout- is always “0.” Therefore, it is constantly connected to GND. PT and NT inverters (PTI and NTI) are also required to produce a¯+/b¯+ and a¯-/b¯-, respectively (Figure 2(a)). The entire block has 64 transistors, and it is mostly composed of binary parts, in which either the pull-down or pull-up network is switched off. Therefore, static current does not flow within the subcircuits which generate midoutputs.
Midoutput values of the carry generator subcircuit for THA.
a
b
a¯+
a¯-
b¯+
b¯-
Cout
Cout-
Cout¯-
Path(s)
0
0
2
2
2
2
0
0
2
1
0
1
2
2
2
0
0
0
2
1
0
2
2
2
0
0
0
0
2
2
1
0
2
0
2
2
0
0
2
1
1
1
2
0
2
0
0
0
2
1
1
2
2
0
0
0
1
0
0
3
2
0
0
0
2
2
0
0
2
2
2
1
0
0
2
0
1
0
0
3
2
2
0
0
0
0
1
0
0
3
3.2. New Ternary Full Adder
Full adder performs addition of three input signals. A ternary full adder, whose block diagram is depicted in Figure 3(a), has been presented by Keshavarzian and Sarikhani [19]. Both outputs (Sum and Cout) are directly generated from the input variables. Ebrahimi et al. [18] have proposed another TFA. Figure 3(b) reveals how the final outputs are generated within its block. The output carry is considered as a function of the initial inputs as well as the output of the first pseudo-THA.
Strategies of building a ternary full adder block, (a) the block diagram of TFA presented by Keshavarzian and Sarikhani [19], (b) the block diagram of TFA presented by Ebrahimi et al. [18], and (c) the block diagram of the proposed TFA.
The output carry of the proposed TFA is produced directly from the initial inputs (Figure 3(c)). In this manner, output carry is generated far faster, which is a great advantage especially in a ripple adder structure. On the other hand, the proposed Sum generator subcircuit (Figure 2(a)) is cascaded twice to create the final output Sum. The direct approach of generating the output Sum requires multiple pass-transistors in series, which cause slow operation. This is the reason why Keshavarzian and Sarikhani [19] supplement a ternary buffer in order to rectify the drawback to some extent. Unlike the output Sum, Cout is a simple function, which is entirely appropriate to be implemented directly from the initial inputs.
The proposed carry generator subcircuit for TFA is shown in Figure 4. Table 3 shows how transistors connect the midoutputs Cout¯+ and Cout¯- to the proper voltage source depending on what input pattern is considered (Table 3, Second Column), regardless of its permutations. Two-input Sum generator subcircuits (Figure 2(a)) are cascaded in series to create the output Sum (Figure 3(c)). Although it is also possible to obtain the final output Sum directly from the initial inputs, the number of pass-transistors in series increases inside the body of the subcircuit, and hence it leads to deficient overall performance. As a result, cascaded Sum generators are preferable. The entire full adder cell has 142 transistors.
Midoutput values of the carry generator subcircuit for TFA.
∑(Inputs)
Input pattern
Cout
Cout¯+
Path(s)
Cout¯-
Path(s)
0
(0, 0, 0)
0
2
1
2
3, 4
1
(0, 0, 1)
0
2
1
2
3, 4
2
(0, 0, 2)
0
2
1
2
4
2
(0, 1, 1)
0
2
1
2
3
3
(0, 1, 2)
1
2
1
0
6
3
(1, 1, 1)
1
2
1
0
5
4
(0, 2, 2)
1
2
1
0
6
4
(1, 1, 2)
1
2
1
0
5, 6
5
(1, 2, 2)
1
2
1
0
5, 6
6
(2, 2, 2)
2
0
2
0
5, 6
The proposed carry generator subcircuit for TFA (#Tube = 3).
4. Simulation Results
High-performance and state-of-the-art CNTFET-based designs are selected for comparison. Extensive simulation setups are taken into account to examine new adder cells in several aspects. All circuits are simulated with Synopsys HSPICE and 32 nm CNTFET technology [27, 28] in three power supply voltages (1 V, 0.9 V, and 0.8 V) at room temperature. This compact SPICE model includes all nonidealities such as Schottky barrier effects, parasitic Drain/Source/Gate capacitances and resistances, and CNT charge Screening Effects. A brief description of the parameters of the CNTFET model, which has been designed for unipolar MOSFET-like devices with one or more CNTs, is shown in Table 4.
CNTFET model parameters.
Parameter
Description
Value
Lch
Physical channel length
32 nm
Lgeff
The mean free path in the intrinsic CNT channel
100 nm
Ldd/Lss
The length of doped CNT drain/source-side extension region
32 nm
Kgate
The dielectric constant of high-k top gate
16
Tox
The thickness of high-k top gate dielectric material
4 nm
Csub
The coupling capacitance between the channel region and the substrate
20 pF/m
Efi
The Fermi level of the doped S/D tube
6 eV
Fan-out of 4 ternary inverters (FO4) was employed as the output load in order to provide a realistic simulation setup. Transient responses of the proposed THA and TFA in 100 MHz operating frequency are plotted in Figures 5 and 6, respectively. Average power consumption during all transitions is also measured. Finally, power-delay product (PDP) is a balance between delay and power factors (4). Simulation results are shown in Table 5. The best results are shown in boldface for better clarification.
(4)PDP=Max(Delay)×Avg(Power).
Simulation results of one-digit adders.
Design
Vdd=0.8 V
Vdd=0.9 V
Vdd=1 V
Delay(psec)
Power(μW)
PDP(aJ)
Delay(psec)
Power(μW)
PDP(aJ)
Delay(psec)
Power(μW)
PDP(aJ)
Ternary half adder
ProposedTHA
38.74
0.282
10.94
28.42
0.880
25.01
25.43
2.778
70.66
THA by Lin et al. [16]
91.40
0.771
70.43
66.64
2.291
152.7
54.03
5.817
314.3
THA by Moaiyeri et al. [17]
50.35
0.415
20.88
39.49
1.264
49.91
35.08
3.806
133.5
Ternary full adder
ProposedTFA
58.94
0.456
26.89
43.95
1.472
64.68
35.66
4.595
163.9
TFA by Ebrahimi et al. [18]
189.5
0.597
113.1
139.4
1.893
263.9
116.8
5.463
638.3
TFA by Keshavarzian and Sarikhani [19]
119.2
0.607
72.32
102.4
1.912
195.9
81.98
5.413
443.8
Transient response of the proposed THA.
Transient response of the proposed TFA.
There are three nanotubes under the gate terminal of all transistors (#Tubes = 3). Channel length is 32 nm (Lg=32 nm), and the distance between the centers of two adjacent CNTs under the gate of a transistor is set 20 nm (Pitch = 20 nm). Transistor width of a CNTFET can be approximately calculated by (5) [29], where Wmin is the minimum width of the gate. Therefore, by considering this equation, each transistor width is 60 nm. In addition to delay, power, and PDP, total number of transistors and total width of the adder cells (6) are also reported in Table 6 as reasonable criteria of area competence.
(5)Wgate≈Max(Wmin,#Tubes×Pitch),(6)Total Cell Width=∑iWidth(Ti).
Area comparison.
Design
#Transistors
Total cell width (nm)
Ternary half adder
Proposed THA
64
3840
THA by Lin et al. [16]
158
9480
THA by Moaiyeri et al. [17]
112
6720
Ternary full adder
Proposed TFA
142
8520
TFA by Ebrahimi et al. [18]
106
6360
TFA by Keshavarzian and Sarikhani [19]
132
7920
Simulation results demonstrate the absolute superiority of the proposed circuits. The new designs consume the least power due to their unique structure which is mainly composed of binary parts. For example, the given THA consumes 1.411 μW and 0.384 μW less power in 0.9 V power supply than the designs presented by Lin et al. [16] and Moaiyeri et al. [17], respectively. Voltage division occurs only twice to create the final outputs (Sum and Cout), whereas it happens several times in each ternary component of previous THAs. In addition, the performance of the proposed THA is approximately twice higher than the design introduced in [17], while it has also 48 fewer transistors. Moreover, previous ternary half adders require a Vdd/2 voltage reference. It causes additional on-chip interconnection, which is in contrast with initial MVL targets. The logic style utilized in this paper eliminates the requirement of any extra voltage source.
It takes four successive pass-transistors to charge or discharge the output nodes of the design given by Ebrahimi et al. [18]. It causes poor driving power especially when the circuit faces long wires or high load capacitors. As a result, it operates very slowly. In the proposed structures, the binary inverters situated in the middle isolate CMOS binary circuits from load capacitors, and they bring sufficient driving power for charging and discharging output loads. This is exactly what the ternary buffer in TFA-132T does. In spite of six pass-transistors in series, it operates faster than TFA presented in [18]. To examine driving capability more accurately, capacitors ranged from 1 fF up to 6 fF are applied as output loads. The results of this experiment are plotted in Figure 7. Delay parameter does not increase sharply as output capacitors enlarge, and the new structures operate efficiently despite the existence of large load capacitors.
Delay versus load capacitors, (a) THAs, (b) TFAs.
In addition, the output value of the first pseudo-THA has to be generated first in TFA-106T to produce the output carry. The same output is only generated from the initial inputs in the new design. Therefore, it gets ready 76% faster than in the structure presented in [18]. The delay of the output carry for the given TFA in 0.9 V power supply is 22.192 psec, while the same parameter is 94.942 psec for the previous design.
To observe how temperature variation affects the performance of the proposed circuits, simulations are repeated with different ambient temperatures ranged from 0°C to 80°C. The result of this experiment is depicted in Figure 8. The performance of the proposed designs does not alter sharply in the presence of temperature fluctuations.
PDP versus temperature variations, (a) THAs, (b) TFAs.
Since static power is a large fraction of average power consumption in ternary circuits, it is also measured separately for all designs. To measure static power dissipation, static (DC) input signals are applied to the circuits so that switching activity does not occur. This measurement must be repeated nine times for different input patterns of a 2-input ternary function (THA). It has to be repeated 33 = 27 times if a ternary function has three input variables (TFA). The average and the maximum static powers are reported in Table 7. Static power dissipation reaches its minimum extent in the proposed designs due to their unique structure which is mostly composed of binary parts. For instance, voltage division occurs only twice for the presented THA when all of the input variables equal “2,” whereas it happens six times and four times in THA-158T and THA-112T, respectively.
Static power comparison.
Design
Average static power×10−7 (W)
Maximum static power×10−7 (W)
Ternary half adder
Proposed THA
5.2661
11.058
THA by Lin et al. [16]
16.540
49.030
THA by Moaiyeri et al. [17]
6.4400
18.767
Ternary full adder
Proposed TFA
6.4724
13.829
TFA by Ebrahimi et al. [18]
10.897
21.250
TFA by Keshavarzian and Sarikhani [19]
11.290
26.604
Capability of working in high frequencies is put into practice for the proposed structures as well. Figure 9 shows how sharply power increases by the increase of operating frequency from 100 MHz to 1 GHz. The new circuits operate efficiently in high frequencies, and they consume less power than previous designs.
Average power consumption versus operating frequencies, (a) THAs, (b) TFAs.
One of the challenges in CNTFET fabrication is that the diameter of carbon nanotubes cannot be set very precisely. DCNT varies with a standard deviation from 0.04 nm to 0.2 nm for each mean diameter value [30]. To observe how tolerant the proposed designs are against process variation, Monte Carlo transient analysis is taken into consideration. This analysis is performed with a reasonable number of 30 iterations, in which the simulation is repeated 10 times and the largest deviation is reported. The statistical significance of 30 iterations is quite high. There is a 99% probability that over 80% of all possible component values operate properly if a circuit operates correctly for all of the 30 iterations [31]. Distribution of the diameter is assumed as Gaussian with 6-sigma distribution, which is a reasonable assumption for large number of fabricated CNTs [32]. The results of this experiment are shown in Figure 10 for the proposed ternary half adder, which is highly robust and tolerant against process variation.
Maximum PDP variation versus DCNT variation.
Single-bit adder cells are used to form larger adders. In order to test the practicability of the new designs in a large circuit, a seven-Ternary digIT (7-TIT) ripple adder is constructed by combining a THA and six TFAs (Figure 11). THA-112T and TFA-132T are also put together to form another ternary ripple adder for comparison.
A 7-TIT ternary ripple adder constructed by a THA and six TFAs.
To measure worst-case delay, different input patterns are fed to the adder blocks (Figure 12) in a way that a transition propagates from the input of the first stage (a0) to the outputs of the last stage (s6). This input pattern is designed in a way it causes all possible transitions in the output Sum of the last stage (s6). A long duration of iterative input pattern is also fed to the adder blocks to measure average power consumption. Simulation results are reported in Table 8. Although the proposed ripple adder has a few more transistors, it consumes less power and it operates far faster than the structure built by the previous adder cells.
Simulation results of 7-TIT ternary ripple adders.
Design
Delay(psec)
Power(μW)
PDP(fJ)
#Transistors
Total width(nm)
Ripple adder by the proposed THA and TFA
187.84
7.5778
1.4234
916
54960
Ripple adder by THA-112T and THF-132T
371.84
9.9079
3.6841
904
54240
Input patterns which are fed to the ternary ripple adders to measure maximum delay.
Eventually, to provide a comparison between MOSFET and CNTFET technologies, the proposed ternary half adder is also implemented with 32 nm channel length bulk CMOS [33]. A brief description of the parameters of this model is shown in Table 9. The MOSFET implementation of the proposed THA is illustrated in Figure 13. Each transistor is marked with a pair of numbers. The upper number indicates threshold voltage and the lower number is the width of the transistor (Wgate). Due to weaker on-current driving capability of bulk CMOS technology [34], buffers are supplemented, after the midoutputs are generated, to strengthen output signals. Driving power in MOSFETs is 3-4 times weaker than CNTFETs [35]. Therefore, transistor widths are also extended enough to overcome this deficiency, paying the price of enlarging area. Transient response of this adder cell is plotted in Figure 14. The whole cell is simulated under the same conditions as mentioned before for the CNTFET-based THAs. Table 10 shows the simulation results of both technologies. They demonstrate the fact that CNTFETs are absolutely more promising candidates for ternary circuitry. The CNTFET-based THA operates 44 times faster, consumes approximately 10 times less power, and occupies 3.3 times less area than its MOSFET counterpart.
Bulk CMOS model parameters.
Parameter
Description
Value
Lch
Physical channel length
32 nm
Leff
The effective gate channel length
12.6 nm
Rdsw
The source and drain resistance per unit channel width
150 Ω-μm
Tox
The gate oxide thickness
1 nm
Cgbo
The gate-to-bulk overlap capacitance per unit channel length
25.6 pF/m
Cgdl/Cgsl
The overlap capacitance between gate and lightly doped drain/source region
265.3 pF/m
Simulation results of the new THA with MOSFET and CNTFET technologies.
Design
Delay(psec)
Power(μW)
PDP(fJ)
#Transistors
Total width(nm)
The proposed THA with MOSFET technology
1248
8.257
10.30
76
12762
The proposed THA with CNTFET technology
28.42
0.880
0.025
64
3840
MOSFET implementation of the proposed ternary half adder.
Transient response of the proposed THA with MOSFET technology.
5. Conclusions
New ternary adders have been proposed in this paper based on a logic style which is mostly composed of binary parts. Therefore, static power consumption reaches its minimum amount. Extensive different analyses have been carried out to examine efficiency in all aspects. The proposed designs benefit from low power consumption, high driving power, full-swing operation, and capability of working in low voltages and high frequencies. They can be used in larger circuits and practical environments.
A comparison between MOSFET and CNTFET has been also provided to conclude the superior technology for ternary circuitry. Due to more flexibility of adjusting the desired threshold voltage and high on-current driving capability, CNTFETs are definitely more promising devices for implementing ternary circuits in the future. Simulation results confirm that a CNTFET-based ternary design surpasses MOSFET implementation in terms of speed, power consumption, and area.
Conflict of Interests
The authors declare that there is no conflict of interests regarding the publication of this paper.
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