Pawan Kapur scite author profile

Performance of deep-submicrometer very large scale integrated (VLSI) circuits is being increasingly dominated by the interconnects due to decreasing wire pitch and increasing die size. Additionally, heterogeneous integration of different technologies in one single chip is becoming increasingly desirable, for which planar (two-dimensional) ICs may not be suitable. This paper analyzes the limitations of the existing interconnect technologies and design methodologies and presents a novel three-dimensional (3-D) chip design strategy that exploits the vertical dimension to alleviate the interconnect related problems and to facilitate heterogeneous integration of technologies to realize a system-on-a-chip (SoC) design. A comprehensive analytical treatment of these 3-D ICs has been presented and it has been shown that by simply dividing a planar chip into separate blocks, each occupying a separate physical level interconnected by short and vertical interlayer interconnects (VILICs), significant improvement in performance and reduction in wire-limited chip area can be achieved, without the aid of any other circuit or design innovations. A scheme to optimize the interconnect distribution among different interconnect tiers is presented and the effect of transferring the repeaters to upper Si layers has been quantified in this analysis for a two-layer 3-D chip. Furthermore, one of the major concerns in 3-D ICs arising due to power dissipation problems has been analyzed and an analytical model has been presented to estimate the temperatures of the different active layers. It is demonstrated that advancement in heat sinking technology will be necessary in order to extract maximum performance from these chips. Implications of 3-D device architecture on several design issues have also been discussed with especial attention to SoC design strategies. Finally, some of the promising technologies for manufacturing 3-D ICs have been outlined.

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Fiber grating sensors in medicine: Current and emerging applications

Mishra

Singh

Tiwari

et al. 2011

Sensors and Actuators A: Physical

244

112

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Technology and reliability constrained future copper interconnects. I. Resistance modeling

Kapur

McVittie

Saraswat

2002

IEEE Trans. Electron Devices

229

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A realistic assessment of future interconnect performance is addressed, specifically, by modeling copper (Cu) wire effective resistivity in the light of technological and reliability constraints. The scaling-induced rise in resistance in the future may be significantly exacerbated due to an increase in Cu resistivity itself, through both electron surface scattering and diffusion barrier effect. The impact of these effects on resistivity is modeled under various technological conditions and constraints. These constraints include the interconnect operation temperature, the effect of copper-diffusion barrier thickness and its deposition technology, and the quality of interconnect/barrier interface. Reliable effective resistivity trends are established at various tiers of interconnects, namely, at the local, semiglobal, and global levels. Detailed implications of the effect of resistivity trends on performance are addressed in the second part of this work.

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Power Comparison Between High-Speed Electrical and Optical Interconnects for Interchip Communication

Cho

Kapur

Saraswat

2004

J. Lightwave Technol.

163

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Pawan Kapur

3-D ICs: a novel chip design for improving deep-submicrometer interconnect performance and systems-on-chip integration

Fiber grating sensors in medicine: Current and emerging applications

Technology and reliability constrained future copper interconnects. I. Resistance modeling

Power Comparison Between High-Speed Electrical and Optical Interconnects for Interchip Communication

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