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Statistical Crosstalk Aggressor Alignment Aware Interconnect Delay Calculation

This research focuses on calculating interconnect delays considering crosstalk aggressor alignment uncertainties. It introduces methods to model input and output signal arrival time distributions affected by process variations. The approach improves accuracy in predicting interconnect delay distributions.

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Statistical Crosstalk Aggressor Alignment Aware Interconnect Delay Calculation

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  1. Supported by NSF & MARCO GSRC Statistical Crosstalk Aggressor Alignment Aware Interconnect Delay Calculation Andrew B. Kahng, Bao Liu, Xu Xu UC San Diego http://vlsicad.ucsd.edu

  2. Outline • SSTA Background • Problem formulation • Method: theory and implementation • Experiment • Summary

  3. d2 p2 d1 p1 Background: Variability • Increased variability in nanometer-scale VLSI designs • Process: • OPC  Lgate • CMP  thickness • Doping  Vth • Environment: • Supply voltage  transistor performance • Temperature  carrier mobility  and Vth • These (PVT) variations result in circuit performance variation Gate/net DelayDistribution PVT Parameter Distributions

  4. FF FF max combinational logic Q D CLK max min Background: Timing Analysis • Min/Max-based • Inter-die variation • Pessimistic • Corner-based • Intra-die variation • Computational expensive • Statistical • pdf for delays • Reports timing yield

  5. Arrival time pdf gate delay pdfs Arrival time pdf D B I1 C A Background: SSTA • Represent delays and signal arrival times as random variables • Block-based • Each timing node has an arrival time distribution • Static worst case analysis • Efficient for circuit optimization • Path-based • Each timing node for each path has an arrival time distribution • Corner-based or Monte Carlo analysis • Accurate for signoff analysis

  6. Background: SSTA Correlations • Delays and signal arrival times are random variables • Correlations come from • Spatial • inter-chip, intra-chip, random variations • Re-convergent fanout • Multiple-input switching • Cross-coupling • …… g1 corr(g1, g2) g2 corr(g1, g3) corr(g2, g3) g3

  7. Multiple-Input Switching • Simultaneous signal switching at multiple inputs of a gate leads to up to 20%(26%) gate delay mean (standard deviation) mismatch [Agarwal-Dartu-Blaauw-DAC’04] Probability Gate delay

  8. Crosstalk Aggressor Alignment • We consider an equally significant source of uncertainty in SSTA, which is crosstalk aggressor alignment induced interconnect delay variation

  9. Problem Formulation • Given • Coupled interconnect system • Input signal arrival time distributions • Find • Output signal arrival time distributions • We present signal arrival times in polynomial functions of normal distribution random variables • E.g., for first order approximation of two input signal arrival times, their skew (crosstalk alignment) is given in normal distribution random variables with correlation taken into account xi = fi(r1, r2, …) ri ~ N(mi, si) x1 ~ N(m1, s1) x2 ~ N(m2, s2) x’=x2-x1 ~ N( m’=m2-m1, s’=(s12+s22+corr)1/2)

  10. Outline • SSTA Background • Problem formulation • Method: theory and implementation • Experiment • Summary

  11. Interconnect Delay as a Function of Crosstalk Alignment For 1000um global interconnects in 90nm technology

  12. Interconnect Delay as a Function of Crosstalk Alignment • More complex than the timing window concept • Can be computed by simulation or delay calculation • Approximated in a piece-wise quadratic function: d0 d1 t0 t1 t2 t3

  13. Closed-Form Interconnect Delay Distribution For a normal distribution crosstalk alignment x’

  14. Closed-Form Interconnect Output Signal Arrival Time Distribution For a normal distribution crosstalk alignment x’

  15. Statistical Delay Calculation for Coupled Interconnects Input: Coupled interconnects input signal arrival time distributions process variations Output: Output signal arrival time distributions • Interconnect delay calculation for sampled crosstalk alignments • Approximate interconnect delay in a piece-wise quadratic function of crosstalk alignment • Compute output signal arrival time distribution by closed-form formulas • Apply superposition for each input • Combine with other process variations

  16. Multiple Aggressors / Variations • An RLC interconnect system is a linear system, which enables to apply superposition for the effects of multiple crosstalk aggressors • Correlated variation sources • For each conditions • Compute conditional probabilities • Combine conditional probabilities • Independent variation sources • Superposition

  17. Runtime Analysis • Interconnect delay calculation for N sampled crosstalk alignment takes O(N) time, where N = min(1.5 max input transition time, 6 sigma of crosstalk alignment) / time_step • Fitting takes O(N) time • Computing output signal arrival time distribution takes constant time, e.g., updating in an iterative SSTA

  18. Iterative SSTA • STA-SI goes through an iteration of timing window refinement for reduced pessimism of worst case analysis • SSTA-SI goes through an iteration of signal arrival time pdf refinement with reduced deviations

  19. Outline • SSTA Background • Problem formulation • Method: theory and implementation • Experiment • Summary

  20. Experiment Setting • Quadratic function regression: Origin • Monte Carlo simulation: Hspice • Close-form model-based distribution calculation: C • Testcases: • BTPM model • 130nm industry designs

  21. Interconnect Delay Distribution For a pair of 1000um coupled global interconnects in 70nm BPTM technology, with 10, 20, 50 and 100ps input signal transition time, and crosstalk alignment in a normal distribution N(0, 10ps)

  22. Interconnect Delay Standard Deviation due to Varied Wire Width For a pair of 1000um coupled global interconnects in 70nm BPTM technology, with 10, 20, 50 and 100ps input signal transition time, and wire width variation in a normal distribution N(0, 10%)

  23. Experiment: Delay Variation Test case: 1000mm interconnects of 70nm BPTM technology Assume: wire width distribution N(1, 0.05) * Normal_width crosstalk alignment distribution N (m’, 3.33ps)

  24. Interconnect Output Signal Arrival Time Distribution For a pair of 1000mm coupled global interconnects in 70nm BPTM technology, with 10, 20, 50 and 100ps input signal transition time, and crosstalk alignment in a normal distribution N(0, 6ps)

  25. Experiment: Output Signal Arrival Time Variartion Test case 1: 1000mm interconnects of 70nm BPTM technology Test case 2: interconnects in a 130mm industry design

  26. Outline • SSTA Background • Problem formulation • Method: theory and implementation • Experiment • Summary

  27. Summary • SSTA must consider SI effects! • We take crosstalk aggressor alignment into account in statistical interconnect delay calculation • We approximate interconnect delay in a piecewise quadratic function of crosstalk aggressor alignment • We derive closed-form formulas for interconnect delay and output signal arrival time distribution for given input signal arrival times in polynomial functions of normal distributions • Our experiments show that neglecting crosstalk alignment effect could lead to up to 114.65% (71.26%) mismatch of interconnect delay means (standard deviations), while our method gives output signal arrival time means (standard deviations) within 2.09% (3.38%) of SPICE results

  28. Future Work: Statistical Gate Delay • Crosstalk aggressor signal arrival time variation  variation on the driver gate delay of the victim net due to the effective capacitive load change

  29. Thank you !

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