Design of Unbalanced Ternary Logic Gates and Arithmetic Circuits
Vallabhuni Vijay, Chandra Shaker Pittala, K Koteshwaramma, Abdul Subhahan Shaik, Kancharapu Chaitanya, Shiva Birru, Soma Medapalli, Varun Thoranala, X.-Y Wang, L Chungryeol, M Divya, S Sunithamani, H Gharavi, M Moaiyeri, S Pal, R Katayoun, S Hosseini, S.-Y Kim, V Vijay, Ch, Srivalli, Chandra Shaker, Pittala, Vallabhuni Vijay, Rajeev Ratna Vallabhuni, M Saritha, Sruthi Chikkapally, Vallabhuni Vijay, Chandra Shaker Pittala, Sadulla Shaik, Chandra Shaker Pittala, J Sravana, G Ajitha, P Saritha, Mohammad Khadir, V Vijay, S Venkateswarlu, Rajeev Vallabhuni, B Rani, Ch, Srivalli, Vallabhuni, C Vijay, Chandrashaker Sai Kumar Reddy, P Ashok Pittala, Babu, Vallabhuni, C Vijay, Veerastu Sai Kumar Reddy, Chandrashaker Sivanagaraju, Pittala, Bandi Mary, Sowbhagya Rani, Devi Vasumathi, Chandra Majety, Vallabhuni Shaker Pittala, Kanumalli Vijay, Siripuri Satya Sandeep, Kiran, K Bindu, Chandra Shaker Pittala, Vallabhuni, Vijay, S Swathi, Rajeev Ratna Vallabhuni, S Lakshmanachari, G Avanthi, Vallabhuni Vijay, Chandra Shaker Pittala, Chandra Shaker Pittala, M Vallabhuni Rajeev Ratna, Saritha, V Saipreethi, P Vijay, Chandra, M Shaker, Shaik Divya, Sadulla, Manchala Sreeja, Vallabhuni Vijay, Vallabhuni, C Vijay, Chandrashaker Sai Kumar Reddy, Pittala, China Sonagiri, Venkateswarlu, Rajeev Vallabhuni, Jujavarapu Sravana, Chandra Shaker Pittala, Mikkili Divya, B Rani, Vallabhuni Vijcaay, Vallabhuni Vijay, Pittala Chandra Shekar, Shaik Sadulla, Putta Manoja, Rallabhandy Abhinaya, Nakka Merugu, Nikhil, Vallabhuni
Abstract
The design of ternary Logic gates-Ternary NAND, Ternary NOR and Standard Ternary Inverter based on the 18nm FinFET technology is proposed. The Ternary logic systems replaced Existing Binary logic systems with their good operating speed, energy efficiency, information density and Reduced circuits like chip area and interconnections. Instead of using large Resistors, the proposed model consists of 18nm FinFETs, reducing the number of resistors used. The proposed ternary logic gates are then used to carry the arithmetic operations that are basic and implement various complex functions. These ternary logic gates show the significant advantages of chip area, energy and power consumptions, denser fabrication and component count. The ternary half-adder and ternary half-subtractor circuits are then implemented by utilizing the proposed gates and then verified through the simulations. The results are then compared with the existing designs of MOSFET based Ternary logic gates. The parameters like power consumption are compared with the current MOSFET models, and then the proposed models are simulated. For simulations, Cadence Virtuoso tool and MATLAB are used to verify the authenticity of proposed designs.