Integrated Circuits and Systems group, IIT Madras

This is an old revision of the document!


Headline

EE5325: Power Management Integrated Circuits(Jul-Nov 2019)

Instructor

Teaching Assistant

Classroom

  • ESB207B

Schedule

F slot (Tue 4:50-5:40; Wed 11:00-11:50 ; Thu 9:00-9:50; Fri 8:00-8:50)

Course page on moodle

Registered students can login and see the course page at https://courses.iitm.ac.in/. Resources, tutorials, exam schedules, discussion forum etc. can be accessed from the moodle page.

Teaching Assistants

Login to moodle at https://courses.iitm.ac.in/ to post questions and contact faculty.

Evaluation

  • Assignments (10%)
  • Quiz-I (20%)
  • Quiz-II (20%)
  • Final Exam (30%)
  • Final Project (20%)

Objectives

To develop understanding of why power management circuits are needed in a VLSI system. What are different components of a power management system with focus on dc-dc converters. How to design a chip level dc-dc converter from a given system level specifications.

Course Contents

Introduction to Power Management and Voltage Regulators: Need of power management, power management applications, classification of power management, power delivery of a VLSI system, power conversion, discrete vs. integrated power management, types of voltage regulators (switching Vs linear regulators) and applications, converter’s performance parameters (voltage accuracy, power conversion efficiency, load regulation, line regulation, line and load transient response, settling time, voltage tracking), local Vs remote feedback, kelvin sensing, Point-of-Load (POL) regulators.

Linear Regulators: Bandgap Voltage Reference, Low Drop-Out Regulator (LDO), Source and sink regulators, shunt regulator, pass transistor, error amplifier, small signal model and stability analysis, compensation techniques, current limiting, power supply rejection ratio (PSRR), NMOS vs. PMOS regulator, current regulator.

Switching DC-DC Converters: Types (Buck, boost, buck-boost), power FETs, choosing L and C, PWM modulation, leading, trailing and dual edge modulation, Losses in switching converters, output ripple, voltage Vs current mode control, CCM and DCM modes, hysteretic control, switched capacitor dc-dc converters, Small signal model of dc-dc converter, loop gain analysis of un-compensated dc-dc converter, type-I, type-II and type-III compensation, compensation of a voltage mode dc-dc converter, compensation of a current mode dc-dc converter, Selecting topology, selecting switching frequency and external components, sizing power FETs, segmented power FET, designing building blocks (gate driver, PWM modulator, error amplifier, oscillator, ramp generator, feedback resistors), current sensing, PFM/PSM mode for light load, effect of parasitic on reliability and performance, current limit and short circuit protection, soft start control, chip level layout and placement guidelines, board level layout guidelines, EMI considerations.

Introduction to Advanced Topics in Power Management: Digitally controlled dc-dc converters, digitally controlled LDOs, time-based control for voltage regulators, adaptive compensation, dynamic voltage scaling (DVS), Single-Inductor Multiple-Outputs (SIMO) Converters, dc-dc converters for LED lighting, Li-ion battery charger.

References

  • Switch-Mode Power Supplies: SPICE Simulations and Practical Designs by Christophe P. Basso, BPB Publications, 2010
  • Fundamentals of Power Electronics, 2nd edition by Robert W. Erickson, Dragan Maksimovic, Springer (India) Pvt. Ltd, 2005
  • Power Management Techniques for Integrated Circuit Design By Ke-Horng Chen, Wiley-Blackwell, 2016

Pre-requisites

Attendance

Attendance will be strictly enforced.

Recorded Lectures

  • Lecture-1: handout (Course contents)
  • Lecture-2: handout (Introduction to power management, application, need, discrete vs. integrated PMIC, dc-dc converter, types of dc-dc converter, linear vs switching regulator)
  • Lecture-3: handout (Linear vs switching regulator, selecting between linear and switching regulators, power management of a smartphone, performance parameters-efficiency, accuracy, line and load regulation, line transient)
  • Lecture-4: handout (Load transient, PSRR, remote vs. local feedback, point-of-load,kelving sensing, droop compensation)
  • Lecture-5: handout (droop compensation, current regulator, bandgap voltage reference)
  • Lecture-6: handout (PTAT and CTAT voltage reference, designing a bandgap reference using PTAT and CTAT, Brokaw bandgap reference)
  • Lecture-7: handout (Sub-1V bandgap reference, linear regulator introduction)

You can find lectures from previous years below: