Rajiv V. Joshi, Keunwoo Kim, et al.
IEEE Transactions on VLSI Systems
We propose selective scaling of device footprint for 65 nm and beyond CMOS technologies. The benefits of selective scaling of device footprint are illustrated using an ultrathin-body fully depleted silicon-on-insulator transistor as an example. We study the effect of footprint scaling on device, circuit, and system level performance. A complete 2-D device structure is modeled for the numerical analysis. The results predict that an optimal footprint design can provide 30% smaller chip layout area, 20% faster speed, and 10% less dynamic power on overall chip performance benchmarked with a 53-bit pipelined multiplier. The variability analysis on both dc and ac characteristics indicates that the benefits of selective footprint scaling are not degraded by device variation. © 2007 IEEE.
Rajiv V. Joshi, Keunwoo Kim, et al.
IEEE Transactions on VLSI Systems
Aditya Bansal, Jae-Joon Kim, et al.
IEEE Transactions on Electron Devices
Saibal Mukhopadhyay, Rajiv V. Joshi, et al.
ISQED 2008
Saibal Mukhopadhyay, Keunwoo Kim, et al.
ISQED 2005