Journal of Advancement in Communication System (e-ISSN: 3048-4758)

As we extended from deep sub-micron technology to nanometer regimes, the conventional Cu wire will not be able to continue. So, substitute approaches such as Carbon Nano Tube (CNT) interconnects have been suggested to ignore the problems associated with global interconnects. Hence in this work, crosstalk analysis of CMOS buffer-driven of different interconnects have been analyzed for peak overshoot of Cu and CNTs for 32nm technology. For analyzing peak overshoot, we have varied the interconnect lengths from 100um to 500um in 32 technology node for Cu, SWCNT and MWCNT. The values of the peak overshoot changes, as the interconnect length increases, the peak overshoot is going to be increases. As Compared to Cu, SWCNT and MWCNT, the peak overshoot for SWCNT is lesser than copper and MWCNT. The MWCNT interconnect is less than that of conventional Copper interconnects.

Venkataiah, C., Ramanjaneyulu, N., Rao, Y. M., Prakash, V. N. V., Murthy, M. K., & Rao, N. S. (2022). Design and performance analysis of buffer inserted on-chip global nano interconnects in VDSM technologies. Nanotechnology for Environmental Engineering, 1-7.

Sulochana, V., Venkataiah, C., Agrawal, S., & Singh, B. (2021). Novel Circuit Model of Multi-walled CNT Bundle Interconnects Using Multi-valued Ternary Logic. IETE Journal of Research, 1-13.

Venkataiah, C., Satya-Prakash, V. N. V., Mallikarjuna, K., & Prasad, T. J. (2019). Investigating the effect of chirality, oxide thickness, temperature and channel length variation on a threshold voltage of MOSFET, GNRFET, and CNTFET. J Mech Continua Math Sci. https://doi. org/10.26782/jmcms. spl, 3(2019.09), 00018.

Kumbhare, V. R., Paltani, P. P., Venkataiah, C., & Majumder, M. K. (2019). Analytical study of bundled MWCNT and edged MLGNR interconnects: impact on propagation delay and area. IEEE Transactions on Nanotechnology, 18, 606-610.

Venkataiah, C., Satyaprasad, K., & Jayachandra Prasad, T. (2019). Insertion of an Optimal Number of Repeaters in Pipelined Nano-interconnects for Transient Delay Minimization. Circuits, Systems, and Signal Processing, 38(2), 682-698.

Venkataiah, C., Satyaprasad, K., & Prasad, T. J. (2018). FDTD algorithm to achieve absolute stability in performance analysis of SWCNT interconnects. Journal of computational electronics, 17(2), 540-550.

Venkataiah, C., Satyaprasad, K., & Prasad, T. J. (2018). Crosstalk Induced Performance Analysis of Single Wall Carbon Nanotube Interconnects Using Stable Finite-Difference Time-Domain Model. Journal of nanoelectronics and optoelectronics, 13(6), 846-855.

Venkataiah, C., Satyaprasad, K., & Prasad, T. J. (2018). Signal integrity analysis for coupled SWCNT interconnects using stable recursive algorithm. Microelectronics journal, 74, 13-23.

Reddy, C.V.S., Venkataiah, C., Kumar, V. R., Maheshwaram, S., Jain, N., Dasgupta, S., & Manhas, S. K. (2018). Design and simulation of CNT based nano-transistor for greenhouse gas detection. Journal of Nanoelectronics and Optoelectronics, 13(4), 593-601.

Venkataiah, C., Satyaprasad, K., Prasad, T.J. (2018). Impact of Supply and Threshold Voltage Scaling on Performance of Cu and CNT Interconnects. International Journal of Pure and Applied Mathematics, 118(5), 117-126.