Abstract
The continuous scaling of interconnect wires in deep submicron (DSM) circuits results in increased interconnect delay, power, and crosstalk noise. In this work, we develop a game-theoretic framework and multimetric optimization algorithms for the simultaneous optimization during wire sizing of (i) interconnect delay and crosstalk noise, and (ii) interconnect delay, power, and crosstalk noise. We formulate the wire sizing optimization problem as a normal form-game model and solve it using Nash equilibrium theory. Game theory allows the optimization of multiple metrics with conflicting objectives. This property is exploited in modeling the wire sizing problem while simultaneously optimizing various design parameters like interconnect delay, power, and crosstalk noise, which are conflicting in nature. The nets connecting the driving cell and the driven cell are divided into net segments. The net segments within a channel are modeled as players and the range of possible wire sizes forms the set of strategies. The payoff function is modeled (i) as the geometric mean of interconnect delay and crosstalk noise in the case of first formulation, and (ii) as the weighted sum of interconnect delay, power, and crosstalk noise in the second formulation. The net segments are optimized from the ones closest to the driven cell towards the ones at the driving cell. Complete information about the coupling effects among the nets is extracted after the detailed routing phase. The time and space complexities of the proposed wire sizing formulations are linear in terms of the number of net segments. Experimental results on several medium and large open-core designs indicate that the proposed algorithm for simultaneous optimization of interconnect delay and crosstalk noise yields an average reduction of 21.48% in interconnect delay and a 26.25% reduction in crosstalk noise without any area overhead, over and above the optimization from the Cadence place and route tools. It is shown through experimental results that the algorithm performs significantly better than simulated annealing and genetic search. Further, new simple but accurate models are developed for three parallel interconnect net segments. It is shown that these models yield the same level of accuracy with significantly better run times compared to the models reported in Chen et al. [2004]. A mathematical proof of existence for the Nash equilibrium solution for the proposed wire sizing formulation is also provided.
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