Effects of Process Variations on 3-D Global Clock Distribution Networks

Giovanni De Micheli, Vasileios Pavlidis, Hu Xu
Assoc Computing Machinery, 2012
Article

Résumé

In three-dimensional (3D) integrated circuits, the effect of process variations on clock skew differs from 2D circuits. The combined effect of inter-die and intra-die process variations on the design of 3D clock distribution networks is considered in this article. A statistical clock skew model incorporating both the systematic and random components of process variations is employed to describe this effect. Two regular 3D clock tree topologies are investigated and compared in terms of clock skew variation. The statistical skew model used to describe clock skew variations is verified through Monte-Carlo simulations. The clock skew is shown to change in different ways with the number of planes forming the 3D IC and the clock network architecture. Simulations based on a 45-nm CMOS technology show that the maximum standard deviation of clock skew can vary from 15 ps to 77 ps. Results indicate that simply increasing the number of planes of a 3D IC does not necessarily lead to lower skew variation and higher operating frequencies. A multigroup 3D clock tree topology is proposed to effectively mitigate the variability of clock skew. Tradeoffs between the investigated 3D clock distribution networks and the number of planes comprising a 3D circuit are discussed and related design guidelines are offered. The skew variation in 3D clock trees is also compared with the skew variation of clock grids.

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https://infoscience.epfl.ch/record/173535?ln=fr

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Giovanni De Micheli, Vasileios Pavlidis, Hu Xu
Assoc Computing Machinery, 2012
Article

Résumé

Official source

https://infoscience.epfl.ch/record/173535?ln=fr

À propos de ce résultat

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Process-induced skew variation for scaled 2-D and 3-D ICs

Giovanni De Micheli, Vasileios Pavlidis, Hu Xu

Technology scaling and three-dimensional integration are two design paradigms that offer high device density. Process variations affect these design paradigms in different ways. The effect of process variations on clock skew for a 2-D circuit implemented at scaled technology nodes and for a 3-D circuit with an increasing number of planes is investigated in this paper. An accurate model used to describe the effect of the proper sources of variations on each of these design approaches is proposed. The distribution of the pair-wise skew variation is obtained for single scaled or multi-plane (not scaled) clock distribution networks. The accuracy of the presented statistical skew model is verified through Monte-Carlo simulations. As shown in this paper, the clock skew variation due to technology scaling and/or die stacking exhibits a considerably different behavior. A comparison between these two design paradigms is offered such that the appropriate technology node and number of planes are selected to produce a low clock skew variation and high operating frequency. A popular global clock tree topology is employed in a planar (2-D) circuit where technology scaling is applied and in a 3-D circuit with an increasing number of planes. For this clock tree topology, the maximum supported clock frequency increases from 2.75 GHz to 3.74 GHz by proper die-stacking at a 90 nm technology node. 3-D integration is shown to be an alternative to reduce skew variation without the need of aggressive technology scaling.

ACM Press2010

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Three-dimensional (3-D) integration is a promising solution to further enhance the density and performance of modern integrated circuits (ICs). In 3-D ICs, multiple dies (tiers or planes) are vertically stacked. These dies can be designed and fabricated separately. In addition, these dies can be fabricated in different technologies. The effect of different sources of variations on 3-D circuits, consequently, differ from 2-D ICs. As technology scales, these variations significantly affect the performance of circuits. Therefore, it is increasingly important to accurately and efficiently model different sources of variations in 3-D ICs. The process, voltage, and temperature variations in 3-D ICs are investigated in this dissertation. Related modeling and design techniques are proposed to design a robust 3-D IC. Process variations in 3-D ICs are first analyzed. The effect of process variations on synchronization and 3-D clock distribution networks, is carefully studied. A novel statistical model is proposed to describe the timing variation in 3-D clock distribution networks caused by process variations. Based on this model, different topologies of 3-D clock distribution networks are compared in terms of skew variation. A set of guidelines is proposed to design 3-D clock distribution networks with low clock uncertainty. Voltage variations are described by power supply noise. Power supply noise in 3-D ICs is investigated considering different characteristics of potential 3-D power grids in this thesis. A new algorithm is developed to fast analyze the steady-state IR-drop in 3-D power grids. The first droop of power supply noise, also called resonant supply noise, is usually the deepest voltage drop in power distribution networks. The effect of resonant supply noise on 3-D clock distribution networks is investigated. The combined effect of process variations and power supply noise is modeled by skitter consisting of both skew and jitter. A novel statistical model of skitter is proposed. Based on this proposed model and simulation results, a set of guidelines has been proposed to mitigate the negative effect of process and voltage variations on 3-D clock distribution networks. Thermal issues in 3-D ICs are considered by carefully modeling thermal through silicon vias (TTSVs) in this dissertation. TTSVs are vertical vias which do not carry signals, dedicated to facilitate the propagation of heat to reduce the temperature of 3-D ICs. Two analytic models are proposed to describe the heat transfer in 3-D circuits related to TTSVs herein, providing proper closed-form expressions for the thermal resistance of the TTSVs. The effect of different physical and geometric parameters of TTSVs on the temperature of 3-D ICs is analyzed. The proposed models can be used to fast and accurately estimate the temperature to avoid the overuse of TTSVs occupying a large portion of area. A set of models and design techniques is proposed in this dissertation to describe and mitigate the deleterious effects of process, voltage, and temperature variations in 3-D ICs. Due to the continuous shrink in the feature size of transistors, the large number of devices within one circuit, and the high operating frequency, the effect of these variations on the performance of 3-D ICs becomes increasingly significant. Accurately and efficiently estimating and controlling these variations are, consequently, critical tasks for the design of 3-D ICs.

EPFL2012

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Monte Carlo study of the critical properties of the three-dimensional 120 degrees model

Sandro Wenzel

We report on large scale finite-temperature Monte Carlo simulations of the prototypical classical 120 degrees or e(g) model for orbital ordering on the simple cubic lattice in three dimensions. Our study reveals a continuous phase transition to an orbitally ordered phase with unusual critical properties compared to standard magnetism. While the correlation length exponent nu approximate to 0.665 is close to the 3D XY value, the exponent eta approximate to 0.15 differs substantially from O(N) values. Our results are corroborated by simulation results from a discrete e(g)-clock model that we have defined.

Elsevier Science, Reg Sales Off, Customer Support Dept, 655 Ave Of The Americas, New York, Ny 10010 Usa2011

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EPFL2012