Characterizing power delivery systems with on/off-chip voltage regulators for many-core processors

Abstract

Design of power delivery system has great influence on the power management in many-core processor systems. Moving voltage regulators from off-chip to on-chip gains more and more interest in the power delivery system design, because it is able to provide fast voltage scaling and multiple power domains. Previous works are proposed to implement power efficient on-chip regulators. It is also important to analyze the characteristics of the entire power delivery system to explore the tradeoff between the promising properties and costs of employing on-chip regulators. In this work, we develop an analytical model to evaluate important characteristics of the power delivery system, including on-chip/off-chip voltage regulators and the passive on-chip/on-board parasitic. Compared with SPICE simulations, our model achieves a fast system-level evaluation with comparable accuracy. Based on the model, geometric programming is utilized to find the optimal power efficiency of different architectures of power delivery systems under constraints of output voltage stability and area. Experiments show that compared with the conventional architecture using off-chip regulators, the hybrid one using both on-chip and off-chip voltage regulators achieves 1.0% power efficiency improvement and 68% area reduction of voltage regulators on average. We conclude that the hybrid architecture has potential for high power efficiency and small area at heavy workload, but careful account for the overhead of on-chip regulators is needed.