Ternary Arithmetic Logic Unit Design Utilizing Carbon Nanotube Field Effect Transistor (CNTFET) and Resistive Random Access Memory (RRAM)

Zahoor, Furqan; Hussin, Fawnizu Azmadi; Khanday, Farooq Ahmad; Ahmad, Mohamad Radzi; Nawi, Illani Mohd

doi:10.3390/mi12111288

Cited by 17 publications

(4 citation statements)

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“…Binary systems describe voltage levels 0 and V DD with two logic values, 0 and 1. Ternary logic circuits have three stable states (0, 1 and 2) that are used to build a digital circuits [22] [23]. The voltage value of ternary systems is tabulated in table 1.…”

Section: Existing Ternary Logic Gatesmentioning

confidence: 99%

Low power CNTFET-based ternary multiplier for digital signal processing applications

Chauhan,

Bansal

2024

Eng. Res. Express

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Multiplication is a fundamental arithmetic process, although it necessitates more hardware resources. Researchers in advanced technology attempted to boost the speed and lower the power in digital signal processing applications by utilizing multipliers. The majority of digital signal processing applications demanded increased speed. In addition, ternary logic based on CNTFETs is a feasible alternative for Si-MOSFETs. The article proposes a ternary multiplier, which is designed using proposed ternary logical and combinational circuits that includes STI, TNAND, TNOR, and ternary decoder. The proposed and existing designs are simulated, compared, and analysed on the parameters of delay, average power, and noise using the HSPICE simulator. Therefore, the results show 10%, 81% and 81% improvement in delay, average power, and PDP respectively for proposed TMUL. The noise margin of the proposed TMUL is increased up to 54% over existing circuits. The proposed TDecoder, STI, TNAND, and TNOR are 95%, 97%, 81%, and 95% more energy efficient than existing designs, respectively.

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Section: Existing Ternary Logic Gatesmentioning

confidence: 99%

Low power CNTFET-based ternary multiplier for digital signal processing applications

Chauhan,

Bansal

2024

Eng. Res. Express

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“…In comparison to conventional designs, a significant reduction in transistor count was demonstrated, along with lower power consumption and improvements in latency and the noise margin [113]. CNTFETs with resistive random access memory (RRAM) were offered as design features for non-volatile ternary logic gates by Zahoor et al [58,[114][115][116][117]. Instead of using huge devices (resistor) to achieve ternary logic gate, the design used activeload RRAM and CNTFET.…”

Section: Logic Circuitsmentioning

confidence: 99%

Carbon nanotube field effect transistors: an overview of device structure, modeling, fabrication and applications

et al. 2023

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The research interest in the field of carbon nanotube field effect transistors (CNTFETs) in the post Moore era has witnessed a rapid growth primarily due to the fact that the conventional silicon based complementary metal oxide semiconductor (CMOS) devices are approaching its fundamental scaling limits. This has led to significant interest among the researchers to examine novel device technologies utilizing different materials to sustain the scaling limits of the modern day integrated circuits. Among various material alternatives, carbon nanotubes (CNTs) have been extensively investigated owing to their desirable properties such as minimal short channel effects, high mobility, and high normalized drive currents. CNTs form the most important component of CNTFETs, which are being viewed as the most feasible alternatives for the replacement of silicon transistors. In this manuscript, detailed description of the recent advances of state of the art in the field of CNTFETs with emphasis on the most broadly impactful applications for which they are being employed is presented. The future prospects of CNTFETs while considering aggressively scaled transistor technologies are also briefly discussed.

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“…Thus, novel data processing technologies need to be explored to critically address the issue of insufficient computing capacities particularly in "memory" which nowadays constitutes about 60% of the processor area thus constituting for the major target of the designers for device miniaturization. Presently, researchers in nanoelectronics field are focusing their efforts on resistive random access memory (RRAM) which is one form of memristor technology as a feasible option for existing CMOS-based device miniaturization [5][6][7][8][9][10][11][12][13]. The research in RRAM continues to witness a tremendous growth as it is seen as the promising alternative to existing CMOS devices owing to its numerous advantages such as scalability, high data retention, CMOS and 3D integrability, multistate programmability, good endurance, lower power consumption and relatively high speed [14].…”

Section: Introductionmentioning

confidence: 99%

Resistive random access memory: introduction to device mechanism, materials and application to neuromorphic computing

et al. 2023

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The modern-day computing technologies are continuously undergoing a rapid changing landscape; thus, the demands of new memory types are growing that will be fast, energy efficient and durable. The limited scaling capabilities of the conventional memory technologies are pushing the limits of data-intense applications beyond the scope of silicon-based complementary metal oxide semiconductors (CMOS). Resistive random access memory (RRAM) is one of the most suitable emerging memory technologies candidates that have demonstrated potential to replace state-of-the-art integrated electronic devices for advanced computing and digital and analog circuit applications including neuromorphic networks. RRAM has grown in prominence in the recent years due to its simple structure, long retention, high operating speed, ultra-low-power operation capabilities, ability to scale to lower dimensions without affecting the device performance and the possibility of three-dimensional integration for high-density applications. Over the past few years, research has shown RRAM as one of the most suitable candidates for designing efficient, intelligent and secure computing system in the post-CMOS era. In this manuscript, the journey and the device engineering of RRAM with a special focus on the resistive switching mechanism are detailed. This review also focuses on the RRAM based on two-dimensional (2D) materials, as 2D materials offer unique electrical, chemical, mechanical and physical properties owing to their ultrathin, flexible and multilayer structure. Finally, the applications of RRAM in the field of neuromorphic computing are presented.

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Ternary Arithmetic Logic Unit Design Utilizing Carbon Nanotube Field Effect Transistor (CNTFET) and Resistive Random Access Memory (RRAM)

Cited by 17 publications

References 50 publications

Low power CNTFET-based ternary multiplier for digital signal processing applications

Low power CNTFET-based ternary multiplier for digital signal processing applications

Carbon nanotube field effect transistors: an overview of device structure, modeling, fabrication and applications

Resistive random access memory: introduction to device mechanism, materials and application to neuromorphic computing

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