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Power Integrity Test and Verification. CK Cheng UC San Diego ckcheng@ucsd.edu. Outline. Motivation Prediction Metrics Measurement Remarks. Motivation: Huge Analog Circuits. Package: Voltage regulator Distributed RLC model Silicon Chips: Through Silicon Vias Micro Bumps
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Power Integrity Test and Verification CK Cheng UC San Diego ckcheng@ucsd.edu
Outline • Motivation • Prediction • Metrics • Measurement • Remarks
Motivation: Huge Analog Circuits • Package: • Voltage regulator • Distributed RLC model • Silicon Chips: • Through Silicon Vias • Micro Bumps • Metal wires
Power Integrity: One Major Challenge in Near Future • Power network is expensive • takes +30% resources • Power Supply, Board, Package, Pins, Through Silicon Vias, Micro Bumps, Wires • VRM, Decoupling Capacitors, Equivalent Series Resistance • Power network design becomes more stringent • Technology scaling, V drops, P increases • Equivalent Impedance Z=V/I=V2/P (P=VI) • 3D ICs: Same footprint, larger load. • Power Networks: Huge analog circuits with tighter design margins
Prediction: Accuracy? • Circuit Model: Millions to Billions of objects • Wide range of frequency • Extraction of huge 3 D structure • Model order reduction • Current Load Model: Many possible patterns • Many IPs with many modes of operations • Frequency ranges, wave slopes, peaks, average • Vectorless patterns • Simulation: No tools can handle all the details • CPU, Memory capacity • Small time steps and many steps • Very coarse model or local view of tiny details • Prediction: temporal and spatial relation of whole system
Measurement • Metrics • Static voltage drops • Dynamic peak, average drops • Electronic migration • Leakage power • Signal delay • On-Chip Sensors • Under sampling • Excitation generation
Remarks • 3D ICs • Bare die testing • Integration • Standard • Interface • Current patterns • Procedure • Mode setting • Staticand dynamic behaviors • Worst case coverage