Crosstalk aware static timing analysis: a two step approach

Interconnect parasitic effects are one of the limiting factors for the performances of deep submicron VLSI designs, where the interconnect induced delay, dominates over the gate delay. Furthermore, as coupling capacitance between wires increases due to the geometry scaling, the design verification process must accurately take into account crosstalk induced effects. In this paper, we describe CASTA (Crosstalk Aware Static Timing Analysis), a new efficient and accurate methodology for the timing performance verification of large VLSI designs, which accurately considers the crosstalk induced delay and noise injection. Our approach is based on the combination of Static Timing Analysis (STA) with interconnect network order reduction macromodeling techniques and it allows us to evaluate the crosstalk effects during gate-level delay calculation, thus enlightening potential timing hazards. The timing effects due to the crosstalk between adjacent interconnects are accounted by a order reduction based macromodel of the overall linear interconnect network. The effectiveness of the proposed methodology has been demonstrated with the analysis of the crosstalk effects on a 0.25 /spl mu/m, high density CMOS technology.

[1]  Lawrence T. Pileggi,et al.  Performance computation for precharacterized CMOS gates with RC loads , 1996, IEEE Trans. Comput. Aided Des. Integr. Circuits Syst..

[2]  Lawrence T. Pileggi,et al.  RICE: rapid interconnect circuit evaluation using AWE , 1994, IEEE Trans. Comput. Aided Des. Integr. Circuits Syst..

[3]  C. Forzan,et al.  Modeling the Effect of Wire Resistance in Deep Submicron Coupled Interconnects for Accurate Crosstalk Based Net Sorting , 1998 .

[4]  Andrew T. Yang,et al.  Stable and efficient reduction of large, multiport RC networks by pole analysis via congruence transformations , 1996, DAC '96.

[5]  Lawrence T. Pileggi,et al.  Asymptotic waveform evaluation for timing analysis , 1990, IEEE Trans. Comput. Aided Des. Integr. Circuits Syst..

[6]  Lawrence T. Pileggi,et al.  RICE: rapid interconnect circuit evaluator , 1991, 28th ACM/IEEE Design Automation Conference.

[7]  Malgorzata Marek-Sadowska,et al.  Crosstalk reduction for VLSI , 1997, IEEE Trans. Comput. Aided Des. Integr. Circuits Syst..

[8]  Lawrence T. Pileggi,et al.  A Gate-Delay Model for High-Speed CMOS Circuits , 1994, 31st Design Automation Conference.

[9]  Roland W. Freund,et al.  Efficient linear circuit analysis by Pade´ approximation via the Lanczos process , 1994, EURO-DAC '94.

[10]  H. B. Bakoglu,et al.  Circuits, interconnections, and packaging for VLSI , 1990 .

[11]  Lawrence T. Pileggi,et al.  Calculating worst-case gate delays due to dominant capacitance coupling , 1997, DAC.

[12]  Xiaonan Zhang Coupling effects on wire delay. Challenges in deep submicron VLSI design , 1996 .

[13]  A. Rubio,et al.  Analysis of crosstalk interference in CMOS integrated circuits , 1992 .