August 26-30, 2024

Registration deadline: July 20, 2024
Payment deadline: August 16, 2024

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Course material will be distributed only if fees have been paid by the deadline for payment.

MONDAY, August 26

TUESDAY, August 27

WEDNESDAY, August 28

THURSDAY, August 29

FRIDAY, August 30

Power Management
August 26-30, 2024
EPFL Premises, Lausanne, Switzerland

Fundamentals of SC Converters and Topologies
Filip Tavernier, KU Leuven

This lecture will discuss the working principle, fundamental characteristics, and taxonomy of switched-capacitor DC-DC converters. Three analysis techniques will be introduced that can help to understand and design SC converters: Charge Flow Analysis, Charge Balance Analysis, and Branch Analysis. These techniques will be applied to gain insight into the most commonly used SC converter topologies.

Analysis and Modeling of SC Converters
Filip Tavernier, KU Leuven

This lecture will discuss the output impedance model and give an overview of the extrinsic losses of SC converters. Next, the converter topology selection and its optimization for minimal losses will be discussed, both for single-topology and multi-topology SC converters. Finally, multi-phase interleaving will be discussed as a technique to reduce switching noise.

Power Stages
Bernhard Wicht, Leibniz University Hanover

After a brief overview of various power transistor types, this lecture covers power switch sizing, associated parasitics, and isolation methods. Consequently, the influence on switching behavior and losses is investigated. Fundamental circuits include switch-stacking and back-to-back configurations.

Gate Drivers and Protection
Bernhard Wicht, Leibniz University Hanover

This lecture provides a detailed overview of gate driver circuits and their impact on power management system performance. The design of low-side and high-side gate drivers aims for optimizing delay, power dissipation, and area. Further topics include gate supply techniques like bootstrapping and parasitic dv/dt triggered turn-on. The lecture also covers the design of fast and robust level shifters, emphasizing resistor-based, cross-coupled, and capacitive level shifters.

GaN Drivers and Circuit Design
Bernhard Wicht, Leibniz University Hanover

Gallium nitride (GaN) enables compact and efficient power electronics in various applications. With a significantly lower gate as well as output charge, GaN offers superior switching performance at frequencies in the MHz domain. This talk covers system and circuit approaches for GaN power stages and gate drivers and discusses how monolithic integration advances the overall system objectives.

Protection and Sensing
Bernhard Wicht, Leibniz University Hanover

Power management designs must deal with high voltages and large currents that require protection of the connected loads and power stage from damage. They have to ensure operation within the maximum ratings. This lecture emphasizes fundamental protection functions like over-voltage, over-current, thermal protection, short circuits, and open loads. During regular operation, various conditions and quantities must be controlled and require sensing circuits, such as zero-voltage crossing detection. As an essential topic, current sensing circuits are discussed in detail.

Fundamentals of Inductive DC-DC Converters
Bernhard Wicht, Leibniz University Hanover

With the increasing need for efficient power supplies, inductor-based switched-mode power supplies are widely used. They provide excellent power efficiency at the expense of increased complexity and noise. This talk introduces voltage and current mode control for inductive DC-DC converters, including control loop design and basic circuit blocks. A particular focus is on fast-switching converters with small passive components that enable a high level of integration.

Hybrid Converters
Bernhard Wicht, Leibniz University Hanover

Hybrid DC-DC converters pursue a promising approach by combining capacitor-based and inductive concepts in a single converter structure. Resonant operation enables switching frequencies in the multi-megahertz range at significantly reduced dynamic losses. Better utilization of passives enables fully integrated converter designs, including passive components either on-chip or by co-integration in the same package. This lecture explores system and circuit-level solutions and presents examples, in particular, for portable applications and wearables.

Fundamentals of Linear Regulators
Pavan Hanumolu, University of Illinois

Design, analysis, and practical circuit implementation of low dropout regulators (LDOs) are presented. We begin with a review of traditional LDO regulator topologies and evaluate their key performance metrics such as dropout voltage, power supply rejection ratio, load and line regulation accuracy, settling time in the presence of load step, current efficiency, and stability. Following this, we describe alternate LDO architectures and illustrate how one can tradeoff some of the performance metrics.

LED Drivers Design
Pavan Hanumolu, University of Illinois

LED-based lighting is emerging as a preferred choice for both home/commercial lighting and in portable applications such as camera flash, display backlights in mobile phones, tablets, laptops. This tutorial focuses on design techniques for LED drivers geared specifically to battery-driven portable applications. Efficient DC-DC switching converter architectures to implement such LED drivers along with design examples will be presented.

Digitally Controlled DC-DC Converters
Pavan Hanumolu, University of Illinois

Digital control techniques offer flexibility, reduced sensitivity to component variations, and reconfigurability of DC-DC converters compared to their analog counterparts. The circuit- and system-level tradeoffs involved in the design of digitally-controlled switching converters will be discussed. Circuit techniques to implement analog-to-digital converters and digital PWM controllers will be presented.

Time-Based Control of DC-DC Converters
Pavan Hanumolu, University of Illinois

Time-based control techniques for the design of high switching frequency buck converters are presented. We first describe how to use time as the processing variable (as opposed to voltage, current, or charge) and then discuss the implementation time-based controller that operates with CMOS-level digital-like signals but without adding any quantization error. Finally, the circuit implementation details of the time-based buck converter are described.

Interference and PSRR
Michiel Steyaert, KU Leuven

Some EMC interference effects in integrating RF circuits are addressed and discussed. The coupling mechanism of different building blocks to the sensitive RF circuits are addressed. Design techniques for high power supply rejection ratio in basic analog building blocks are studied.

Bandgap Voltage References
Michiel Steyaert, KU Leuven

The lectures start with an introduction on merits of MOSTs versus bipolar transistors in the different positions of an operational amplifier. Then the design procedures are given for optimal op-amp design by means of the pole-zero position and Bode diagrams. A second-order Miller op-amp is discussed in great detail followed by a design procedure for third-order nested Miller op-amps. All of them are optimized towards high GBW, low noise and minimum power consumption. Finally a considerable number of other configurations are discussed and compared, among which a few very-low-voltage fully-differential operational amplifiers, involving internal common-mode feedback.

DC-DC: From Discrete Towards Fully CMOS Integrated
Michiel Steyaert, KU Leuven

Trends and techniques towards fully integrated CMOS DC-DC converters is studied. Both inductive and capacitive DC-DC converters are analyzed. The different required on chip components such as inductors are discussed. Different control loop techniques are presented in order to achieve high integrated density and meanwhile achieving low ripple requirements. Many designed cases, both boost and buck are analyzed and compared with classical LDO regulators.

Practical Techniques of Frequency Compensation
Vadim Ivanov, Texas Instruments

Every analog IC comprises multiple feedback loops. Interaction between these loops makes frequency compensation of such system non-trivial task, unsupported by the general control theory. Every MOS or bipolar transistor is nonlinear, which may cause conditional stability and complicate compensation.
We will consider system structure design for stability, needed for it elementary circuit cells additional to the textbook techniques, as well as ways to achieve unconditional system stability when component parameters vary, and when load and signal source impedance is not well defined. Examples include LDOs stable with any load capacitance, transconductors with wide (few volts) input voltage range, and multistage operational amplifiers.

Design of the LDO’s with Instant Load Regulation and
Unconditional Stability
Vadim Ivanov, Texas Instruments

Discussed is a new class of LDO’s: any load stable, with instant transient response, large power supply rejection and low noise. Examples include the embedded in SoC LDOs for the SRAM unit (5 ns reaction time on the load steps), LDO for radio transmitter (shaping the required noise vs. frequency curve) and LDO for memory retention in the shutdown state (300 nA quiescent current). These LDOs can operate with or without off-chip load capacitors; they are robust to the process and temperature variations and portable to any CMOS process.

Circuit Techniques for Integrated Switching Regulators
Vadim Ivanov, Texas Instruments

Power switches: static and dynamic power loss, switch sizing, wire bonds and their inductance, parasitic vertical PNP and lateral NPN structures, substrate noise, signal grounding and isolation of the control circuitry. Switch Control: Low and high-side gate drivers, use of the bootstrap capacitors with charge regeneration, transfer of the control signal to the high-side. Low and high-side synchronous rectifiers: comparator design, minimization of delays, elimination of shoot-through currents. Feedback and frequency compensation: continuous and discontinuous operation, current and voltage mode; inductor current sensing with and without external elements; oscillator and PWM circuits; error amplifier.

Nanopower Design Techniques and Efficient Energy Harvesting
Vadim Ivanov, Texas Instruments

This lecture covers power management of systems having long periods of idle time with very low power consumption alternated by active high power states, like systems with power harvesting. Circuit techniques used in ultra low power analog circuits applicable in power harvesting systems will be presented, including nanoampere biasing, voltage references with sub-volt supply, active rectifiers, comparators, oscillators and error amplifiers. Also covered design techniques and circuits of DC/DC converters, providing high efficiency at a wide range of loads down to the microampere range and battery chargers with maximum power point tracking and battery protection.