Advanced Analog Circuit Design

    June 23-27, 2025

    Registration deadline: May 23, 2025
    Payment deadline: June 13, 2025

    Download one-page schedule here

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

    MONDAY, June 23

    8:30 am-12:00 pm Time Assisted Analog Design Pavan Hanumolu
    1:30-5:00 pm Analog Builiding Blocks Kofi Makinwa

    TUESDAY, June 24

    8:30 am-12:00 pm Stability of (2-stage) Operational Amplifiers Kofi Makinwa
    1:30-3:00 pm Noise Kofi Makinwa
    3:30-5:00 pm Offset and CMRR Limitations Kofi Makinwa

    WEDNESDAY, June 25

    8:30 am-12:00 pm Offset and 1/f Noise Reduction Techniques Kofi Makinwa
    1:30-5:00 pm CMOS Switched-Capacitor Circuit Design Christian Enz

    THURSDAY, June 26

    8:30-10:00 am Practical Techniques of Frequency Compensation Vadim Ivanov
    10:30 am-12:00 pm Bandgap Voltage Reference Vadim Ivanov
    1:30-5:00 pm Techniques for OpAmp Speed and Accuracy Improvement Vadim Ivanov

    FRIDAY, June 27

    8:30-10:00 am Gain Boosting & How to Judge OpAmp Settling Behaviour Klaas Bult
    10:30 am-12:00 pm Design Mistakes You’d Rather Not Talk About Klaas Bult
    1:30-5:00 pm Continuous-Time Filters Christian Enz
    registration

    Scroll to Top


    Abstracts

    Advanced Analog Circuit Design
    August 23-27, 2025
    EPFL Premises, Lausanne, Switzerland

    Time Assisted Analog Design
    Pavan Hanumolu, University of Illinois, USA

    Time-based signal processing is emerging as a viable alternative to analog signal processing traditionally performed in voltage, current, or charge domains. This tutorial discusses time-based techniques to implement classical analog functions such as filtering, control and data conversion. Time-based circuits using voltage controlled ring oscillators will be presented and their design tradeoffs will be elucidated with the aid of circuit design examples.

    Analog Building  Blocks
    Kofi Makinwa, TU Delft, The Netherlands

    Analog integrated circuits consist of building blocks with one single or two transistors. The gain, input- and output impedance is analyzed of the three single-transistor stages i.e. the amplifier, the source follower and the cascode. The differential pairs, current source and inverter amplifiers are the most used two-transistor configurations. They are analyzed in detailed. Negative resistors are added for higher Gain and Gain-Bandwidth. Design procedures are discussed for all of them.

    Stability of Operational Amplifiers
    Kofi Makinwa, TU Delft, The Netherlands

    Two-stage operational amplifiers in unity-gain configuration, suffer from peaking unless a compensation capacitance is added, or the current is increased in the second stage. These stability conditions are examined in detail, followed by five techniques to eliminate the positive zero. One of them is feedforward, which allows a gain of over a factor of two in power efficiency. The design plans are extended to three-stage amplifiers, which offer new stabilization opportunities.

    Noise
    Kofi Makinwa, TU Delft, The Netherlands

    Abstract.

    Offset and CMRR Limitations
    Kofi Makinwa, TU Delft, The Netherlands

    Abstract.

    Offset and 1/f Noise Reduction Techniques
    Kofi Makinwa, TU Delft, The Netherlands

    The design of precision analog interfaces in CMOS is severely impaired by offset, offset drift and 1/f noise. The material covered in this module analyzes these impairments in detail and reviews the common solutions for their remedy: chopping, autozeroing, correlated double sampling and offset stabilization. We will discuss the residual nonidealities as well as pros and cons of each technique and review typical application examples. In addition, we will survey recent advances in the state-of-the-art.

    CMOS Switched-Capacitor Circuit Design
    Christian Enz, EPFL, Switzerland

    Discrete-time signals, Laplace and z-transform; Basic building blocks (opamps, switches, capacitors); Sample-and-hold circuits; SC integrators, bilinear filters and and biquads; SC amplifiers; Correlated double sampling and chopper stabilization; Nonideal effects and their correction.

    Practical Techniques of Frequency Compensation
    Vadim Ivanov, Texas Instruments, USA

    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.

    Bandgap Voltage References
    Vadim Ivanov, Texas Instruments, USA

    Discussed are error sources of the bandgap voltage references and techniques for improving their accuracy: circuit techniques for low-noise bandgap generation core, feedback amplifier with chopping offset elimination, output buffer with mOhm output impedance and fast settling on load changes; single- dual and triple temperature trimming; packaging requirements; testing and application particulars. Also presented circuit solutions for reverse bandgap reference, operational from 0.9V supply, and reference structure and implementations with nanoampere consumption.

    Techniques for OpAmp Speed and Accuracy Improvement
    Vadim Ivanov, Texas Instruments, USA

    Presented is a top down design process of the OpAmps based on the structural design methodology. We will start from selection of the gain structure, followed by the implementations of gain structures as well as gradual addition of various specific functions like PSRR/CMRR improvement, slew enhancement, overload recovery. We will consider offset improvement by trimming as well as by auto-zeroing and chopping, high-and low-voltage design specifics. Most of the circuits solutions were not published before and have been used in recent industrial ICs. Yet it is not another cookbook with analog circuit recipes. The goal of this presentation is to arm the engineers with a tool helping to invent the solution for any analog design problem and, at the same time, be reasonably sure that this solution is one of the best possible for any given process and set of constraints.

    Gain Boosting & How to Judge OpAmp Settling Behaviour
    Klaas Bult, Analog Design Consult, The Netherlands

    Gain-Boosting is a means to enhance the gain of single-stage amplifiers beyond any limit, without degrading the amplifiers speed in terms of GBW or settling behaviour. This lecture discusses how to design a gain-boosting amplifier for optimal settling behaviour and also details the perfect way to judge OpAmp settling behaviour, showing any (start of) ringing (even at the lowest level) or slow settling components, applicable to any type of amplifier.

    Design Mistakes You’d Rather Not Talk About
    Klaas Bult, Analog Design Consult, The Netherlands

    Every designer makes mistakes and mistakes are not the things we are proudest of, but they are the events that we learn from most. Unfortunately, they almost never get published as only succeses are accepted in Journals and Conferences. This lecture is talking about mistakes I’ve made – and learned from a lot, the hard way.

    Continuous-Time Filters
    Christian Enz, EPFL, Switzerland

    Continuous-time filters play an important role in many communication systems and at the data conversion interface, where they are required for anti-aliasing and reconstruction. This module begins by reviewing the basic s-domain filter approximations and then looks into implementations strategies. We review active RC and gm-C topologies and study their imperfections and sensitivities to nonideal effects.

    registration

    Scroll to Top


Search

Time Zone

  • Lausanne, Delft (CET)
  • Santa Cruz (PST)
  • New-York (EST)
  • India (IST)

Local Weather

Lausanne
1°
clear sky
humidity: 96%
wind: 1m/s NNW
H 6 • L -1
5°
Sat
5°
Sun
5°
Mon
Weather from OpenWeatherMap