I. Introduction

Increased power levels in consumer electronic systems are driving the need for integrated power supply modules in 3D architectures for efficient power management. Delivering noise-free power with the required voltage and current levels is a major barrier to such systems, in power efficiency and system miniaturization. Various voltage regulators and noise filters are incorporated currently between the power source and device load in order to regulate the power supply. These regulators consist of a network of switches and storage components such as capacitors and inductors that transfer power to the load at the desired levels. The key barriers to miniaturization, performance and cost in integrated voltage regulators arise from the lack of suitable magnetic materials with required properties such as permeability, loss, frequency-stability and current-handling. Today's inductors for power supply are either components that are surface-mount assembled on the board or integrated in the package or on-chip. Trade-offs between power handling, efficiency and size impose key constraints to inductor design, which forms the key focus of this paper.