Abstract

Integrating a large number of on-chip voltage regulators holds the promise of solving many power delivery challenges through strong local load regulation and facilitates system-level power management. The quantitative understanding of such complex power delivery networks (PDNs) is hampered by the large network complexity and interactions between passive on-die/package-level circuits and a multitude of nonlinear active regulators. We develop a fast combined GPU-CPU analysis engine encompassing several simulation strategies, optimized for various subcomponents of the network. Using accurate quantitative analysis, we demonstrate the significant performance improvement brought by onchip low-dropout regulators (LDOs) in terms of suppressing high-frequency local voltage droops and avoiding the mid-frequency resonance caused by off-chip inductive parasitics. We perform comprehensive analysis on the tradeoffs among overhead of on-chip LDOs, maximum voltage droop and overall power efficiency. We conduct systematic design optimization by developing a simulation-based nonlinear optimization strategy that determines the optimal number of on-chip LDOs required and on-board input voltage, and the corresponding voltage droop and power efficiency for PDNs with multiple power domains.