A fast and precise circuit simulation method for switching power converters using a mixture of circuits and behavioral models

Abstract

We propose a fast and precise simulation method for replicating the transient responses and frequency characteristics of switching power converters using a mixture of real circuits and behavioral models. The method used a behavioral simulation tool (Verilog-A), which was supported by an analog simulator such as SPECTRE®. The time-step became variable, however, the nonlinear operation of the circuit was considered and state-space equations were formulated by applying the hybrid-dynamical-system control scheme in behavioral modeling [1]. Each macro block can have either the real schematic and behavioral model. The transient simulation operates in such a way that the analog simulator advances the simulation step by step while obtaining results from behavioral blocks. Further application of the periodic steady state (PSS) and periodic stability (PSTB) analyses, allowed us to obtain the frequency characteristics in short time. For verification, we simulated the circuits of the current-mode buck DC-DC converter IC, which was previously fabricated using a 0.18-um CMOS process. When we chose blocks of a buffer, the switching and output circuits and RS-FF real transistor circuits, while the rest behavioral models, we achieved transient response and frequency characteristics that were 13 and 75 times faster, respectively, than the analog simulator alone, while keeping less than 3.9% and 2.5% of errors compared with IC's evaluation results.