Single-Inductor Multiple-Output (SIMO) Switching Regulator Technology

Ultra-Low Quiescent Current in Less Space

Compared to traditional multiple DC-DC solutions, a single-inductor multiple-output (SIMO) power converter architecture provides space savings while maintaining high efficiency for extended battery life. By providing multiple outputs through a single inductor, the SIMO architecture, along with the regulator’s low quiescent current, enable the IC to extend battery life for space-constrained, battery-powered electronic products.

SIMO Architecture Overview

In a traditional switching-regulator topology, each switching regulator needs a separate inductor for each output. These inductors are larger and costly, making them a disadvantage for smaller form factors. Linear regulators are another option since they are fast, compact and low noise but they are lossy. There is another option of using a hybrid of multiple low-dropout regulators (LDOs) with DC-DC converters but this would result in a larger design than using LDOs alone.

The SIMO architecture provides the best solution for tiny devices that require longer battery life, by integrating functionality in smaller devices that would otherwise require multiple discrete components. By reducing the number of required inductors while still maintaining switching converter efficiencies, a SIMO architecture represents an even better and nearly ideal topology for smaller, ultra-low-power designs.

Figure 1. SIMO architecture block diagram.

SIMO Benefits

Inductor Saturation Current

Inductor saturation current (ISAT) is the current where the inductance drops by a certain percentage, and is determined by the inductor’s core size for a given core material and construction. By combining several inductors into one, there is a benefit to the total inductor sizing required. A SIMO provides benefits from:

  • Improved cost savings and footprint
  • Quantization of available component values
  • Time multiplexing: If one system is off when another is on, they can "share" their required ISAT
  • Averaging: Even when there are not exclusive time slots, the current usage peaks often occur at different times. This results in a reduced ISAT requirement

Power Dissipation

Maxim’s SIMO converters offer an optimal tradeoff between footprint and dissipation. They are architected to offer the benefits of a DC-DC converter with the footprint of a single DC-DC plus several integrated LDOs. Also, by reducing the inductor count, spacing between inductors is also removed and this also contributes to the reduction of total footprint.

Figure 2. The MAX77650 PMIC provides low heat dissipation and small footprint for space-constrained, battery-powered devices such as hearables and wearables.


Our new power management ICs (PMICs), the MAX77650 and MAX77651, were designed with micropower SIMO buck-boost DC-DC converters. An integrated 150mA LDO in the PMICs provides ripple rejection for noise-sensitive applications. In the MAX77650/MAX77651, the SIMO provides three independently programmable power rails from a single inductor for an innovative power management solution. The high integration of SIMO architecture helps significantly reduce the overall solution size compared to other discrete solutions.

SIMO Calculator

As an added design tool, our SIMO calculator is available to help you explore the tradeoffs associated with SIMO parameters. On the calculator tab of this spreadsheet-based tool, you can enter the system parameters in the corresponding values cell within the top section of rows. The calculated values that are deemed the most interesting are highlighted in yellow. If a parameter is outside the normal region, the cell will be highlighted in red. The comments section provides guidance on ways to enhance your design.

SIMO Webinar

Featured Products

Ultra-Low Power PMIC with 3-Output SIMO and Charger Optimized for Small Li+ Batteries


Highly Integrated with Ultra-Low 6.5µA Operating Current

SIMO Webinar

SIMO Webinar