Abstract

A hybrid control method using a comparator and a charge control method is proposed for a single-inductor multiple-output (SIMO) DC-DC converter. SIMO DC-DC converters have the weaknesses relating to cross-regulation, as all the output channels share the energy stored in a single inductor. Although multiple control methods such as Time-Multiplexing Control (TMC) and Ordered Power Distributing Control (OPDC) have been proposed to prevent cross-regulation or to improve load capability, effective use of limited resources appears to have not yet been achieved. This paper introduces a hybrid control topology that (1) utilizes comparator-based regulations for most outputs and (2) uses a new charge control loop method for the last output to reduce cross-regulation with low hardware complexity. In addition, the proposed scheme efficiently reuses the system’s redundant energy by adaptively controlling the freewheeling switch that opens the path to the input battery to store the surplus energy resources again. The proposed SIMO DC-DC converter was designed and validated with a 0.18 μm 3.3 V CMOS process. The converter has four regulated outputs of 0.9, 1.2, 1.5, and 2.2 V, and as a result of the simulation, it was found that the cross-regulation was estimated to be 0.4 mV/mA when the output current changes by ~200 mA. In addition, estimated peak power conversion efficiency of 88.5% was achieved at a total output power of 405 mW.

Highlights

  • Power Management Units (PMUs) have become indispensable blocks in today’s portable electronic products

  • This study proposes a novel structure for Single Inductor Multiple Output (SIMO) DC-DC converters to address the aforementioned issues

  • This research proposes a SIMO DC-DC converter with a hybrid control method, which (1) manages the voltage regulation of the first (n − 1) output channels based on a comparator and (2) manages the voltage regulation of the last output channel through a charge control loop

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Summary

Introduction

Power Management Units (PMUs) have become indispensable blocks in today’s portable electronic products. Multiple switching regulators are customized to provide separate supply voltage requirements in each sub-block leading to the silicon area and power overhead. This approach is no longer attractive, especially because the inductor inside the switching regulator occupies a huge area. One of the most efficient solutions for these systems is to use a Single Inductor Multiple Output (SIMO) DC-DC converter as a switching regulator [2,3,4,5,6,7,8,9,10,11,12,13,14,15,16,17,18,19]. The power conversion efficiency of the DC-DC converter is one of the important specifications

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