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In this work, we have proposed an ABCD parameter matrix based model to analyze the impact of mutual inductance on the crosstalk induced effects (i.e. delay and noise) in two identically coupled SWCNT (i.e., Single walled carbon nanotube) bundle interconnects. For our study we have considered both in-phase and out of phase switching of those nano-interconnects of varying width, length and sparsity...
Crosstalk induced overshoot/undershoot effects in Multilayer Graphene Nano Ribbon interconnects (MLGNRs) are investigated using ABCD parameter matrix approach for intermediate level interconnects at 8 nm technology node. The worst case crosstalk induced peak overshoot voltage for perfectly specular doped multilayer zigzag GNR interconnects is comparable to that of copper interconnects. It is observed...
In this paper, the crosstalk effects in both small and large diameter multiwalled carbon nanotube bundle interconnects (MWCNTs) for the future nanoscale integrated circuits are studied with the help of ABCD parameter matrix approach for global levels of interconnects at 22- and 14-nm technology nodes. Here, isolated MWCNTs are modeled using an equivalent single conductor transmission line. The simulation...
Crosstalk effects in Multilayer Graphene Nano Ribbon interconnects (GNRs) are investigated with the help of ABCD parameter matrix approach for intermediate and global level interconnects at 11 nm technology node. For long intermediate and global levels of interconnects, the worst case crosstalk delays for perfectly specular, doped multilayer GNR interconnects are far lesser than that of copper interconnects...
Due to continued scaling of feature sizes, signal integrity and performance of today's copper based nanoscale interconnects are severely impacted. In this work, an ABCD parameter based model is presented for fast and accurate estimation of crosstalk delay and noise for identically coupled copper based nano-interconnect systems. Using the proposed analytical model, the crosstalk delay and noise are...
Cross talk effects in large diameter Multiwalled Carbon Nanotube bundle interconnects (MWCNTs) for the future nanoscale integrated circuits are investigated with the help of ABCD parameter matrix approach for intermediate and global interconnects at 22 nm and 14 nm technology nodes. Here, isolated MWCNTs are modeled using an equivalent single conductor transmission line. Simulation results show that...
In the proposed work, crosstalk effects are investigated in two identically coupled SWCNT bundle interconnects at 21 nm and 15 nm technology nodes for intermediate and global interconnects. An ABCD parameter based approach has been used to investigate crosstalk delay and noise in both sparse and dense SWCNT bundle interconnect system. The simulation results show that the proposed model is not only...
Single-walled carbon nanotubes (SWCNTs) have the potential to revolutionize the interconnects in future nanoscale integrated circuits. In the proposed work, crosstalk effects are investigated in SWCNTs at 21 nm and 15 nm technology nodes for intermediate as well as global interconnects. An ABCD parameter based approach has been used to investigate crosstalk delay and noise in both sparse as well as...
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