Week 1: June 26-30, 2023

Week 2: July 3-7, 2023

Registration deadline: June 7, 2023
Payment deadline: June 16, 2023

TEACHING HOURS

Monday, June 26

Tuesday, June 27

Wednesday, June 28

Thursday, June 29

Friday, June 30

Monday, July 3

Tuesday, July 4

Wednesday, July 5

Thursday, July 6

Friday, July 7

Low-Power Analog IC Design
On-Line Class
June 26 – July 7, 2023

MOS Transistor Modeling for Low-Voltage and Low-Power Circuit Design
Christian Enz, EPFL, Switzerland

Evolution of CMOS technologies: process scaling, low-voltage constraint. Basic long-channel static theory. Short- and narrow-channel effects. Quasi-static dynamic model. Thermal and flicker noise model. Parameter extraction. The EKV model and its use for LV and LP analog circuit design.

Basic low-Power low-Voltage Circuit Techniques
Willy Sansen, KU Leuven, Belgium

Weak inversion and bipolar operation of MOS transistors. BiCMOS versus CMOS. Passive components and pseudo-resistive networks. Elementary building blocks operated at low supply voltage and/or low current: current mirrors, standard and special structures; differential pairs and linearization techniques; elementary voltage-gain cells, MOS- inverter amplifier. Low-voltage cascode and pseudo-cascode configurations. LP/LV current and voltage references. Translinear circuits and principle of log-domain filters.

Differential Amplifying Blocks with Positive Feedback
Willy Sansen, KU Leuven, Belgium

Practical designs are built up by means of differential pairs, current sources and two-transistor cascodes. They are analyzed in detailed followed by fully-differential voltage and current amplifiers. Positive feedback is added as well to enhance both the Gain and the Gain-Bandwidth. Design procedures are discussed in all regions of operations (from weak to strong inversion and velocity saturation).

Noise Performance of Elementary Transistor Stages
Willy Sansen, KU Leuven, Belgium

Long list of opamp configurations is discussed to show which alternative circuit tricks have been used to comply with certain specifications. Considerable design detail is presented on the symmetrical opamp and on the folded cascode. This lecture includes mainly circuit realizations in CMOS but also some in BICMOS technology.

Stability of Operational Amplifiers
Willy Sansen, KU Leuven, Belgium

Multistage operational amplifiers require compensation capacitances for stability. The conditions for stability are discussed for both two-stage and three-stage operational amplifiers. Techniques are given to avoid the positive zero and to realize minimum power consumption at the same time. Several design examples are worked out.

Systematic Design of Low-Power Operational Amplifiers
Willy Sansen, KU Leuven, Belgium

For low-power optimization, an operational amplifier can be designed for high speed and stability according to three different design procedures, all leading to the same final result. They will be discussed for a two- and three stage amplifier. The compromises with other specifications such as noise, input and output range will be discussed as well and illustrated for a number of often used configurations.

Important Opamp Configurations
Willy Sansen, KU Leuven, Belgium

Long list of opamp configurations is discussed to show which alternative circuit tricks have been used to comply with certain specifications. Considerable design detail is presented on the symmetrical opamp and on the folded cascode. This lecture includes mainly circuit realizations in CMOS but also some in BICMOS technology.

Fully-Differential Operational Amplifiers
Willy Sansen, KU Leuven, Belgium

Together with distortion, noise is the main limitation of the performance of analog circuits. It is introduced with simplified expressions for both the MOST and bipolar transistor and applied to the elementary stages with one and two transistors. Also the noise due to parasitic resistances is identified and described. Considerable attention goes to resistive and capacitive noise matching in ultra-low-noise amplifiers.

Bandgap and Current Reference Circuits
Willy Sansen, KU Leuven, Belgium

Voltage references are required in all ADC’s. Current references are required for all biasing. Bandgap references in CMOS technologies are discussed. The compromises at low power consumption are highlighted. Realizations are presented of bandgap references down to 0.8 V supply voltage.

Design of Low-power Analog Circuits using the Inversion Coefficient
Christian Enz, EPFL, Switzerland

The supply voltage of CMOS chips has constantly been scaled down in the last years to reach now the sub-1V region. This supply voltage reduction is mainly driven on one hand by the technology constraints to maintain a reasonable electric field within the MOS device to avoid high-field effects and on the other hand by the needs of digital circuits to reduce the dynamic power consumption. Analog circuits unfortunately don’t take any advantage of this voltage down-scaling since almost all their performances are degraded and some basic circuits would even stop operating correctly. We will discuss the main challenges faced when designing analog circuits for ultra-low voltage (ULV) operation. We will first present the fundamental limits set by ULV, together with the technology limitations (such as matching) for analog circuits. We will then have a closer look at the MOS transistor operation with a particular focus on weak inversion, the Gm/ID characteristic and the inversion coefficient design approach. We then will review several basic building blocks capable of operating at ULV, including both continuous-time and sampled-data circuits. Finally we will investigate the potential of designing RF circuits in ULV taking advantage of ultra-deep submicron processes and give some design examples.

Micropower ADCs
Kofi Makinwa, TU Delft, The Netherlands

With the current trend towards increasingly autonomous systems, micropower ADCs have become critical components. In this presentation, the basic principles of micropower SAR and sigma-delta ADCs will be discussed. It will also be shown how these two proven techniques can be combined to realize high resolution micropower ADCs.

Distortion in Elementary Transistor Circuits
Willy Sansen, KU Leuven, Belgium

For low supply voltage, a larger fraction of the total supply voltage has to be used, leading to more distortion. The several sources of nonlinear distortion are discussed for MOSTs and bipolar transistor, single-ended and differential. Also the role of feedback is examined in detail. All distortion mechanisms are analyzed in full operational amplifier configurations.

Low-Power Continuous-Time Filters
Willy Sansen, KU Leuven, Belgium

High-frequency filters are usually continuous-time type filters. They are simple in schematic and are able to handle large signals with low distortion. Moreover they need tuning circuits to be able to set the frequency and the quality factor. Most important filter schematics are reviewed and compared for high-frequency capability and power consumption.

Low-Power Frequency Reference Circuits
Taekwang Jang, ETHZ Switzerland

A reference clock frequency is required for various applications such as digital systems, sensor interfaces, data converters, wake-up controllers, and communication circuits. High precision and low noise property of the clocks are generally preferred for the stable operation of the applications. At the same time, the power overhead of the frequency reference needs to be minimized to improve the power efficiency of the system.
In this lecture, we discuss the fundamental background for frequency reference designs, including oscillation methodologies, power consumption requirements, and noise properties. Also, non-idealities such as temperature dependency, line sensitivity, and process variation are discussed. Finally, the latest designs and circuit techniques are introduced to understand the critical challenges and how to overcome those to achieve state-of-the-art performance.

Nanopower Design Techniques & Efficient Energy Harvesting
Vadim Ivanov, Texas Instruments, USA

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.