EE4C10 Analog circuit design fundamentals
Course content:
- Introduction to analog design: motivation of analog design; introduction to integrated circuits and CMOS. of basic analog circuits (single-transistor stages, differential pairs, current mirrors).
- Transistor device physics: brief review of MOSFET device physics; MOSFET static and dynamic characteristics; device large-signal behavior, small-signal model.
- Single-stage amplifiers: common-source, common-gate, common-gate amplifier stages, including large-signal behavior, small-signal behavior, input/output impedance.
- Differential amplifiers: large-signal and small-signal analysis; differential-mode and common-mode behavior.
- Current mirrors and biasing: basic current mirrors; cascode current mirrors; current mirror as active load of a differential pair; biasing of common-source, common-gate and common-drain stages; biasing of differential pairs.
- Frequency response of amplifiers: frequency response of common-source, common-gate and common-drain stages; frequency response of differential pairs.
- Noise: review of basic noise principles (ampiutude distribution, power spectral density, singal-to-noise ratio), type of noise in electornic devices; input- and output-referred noise; noise in single-staeg amplifiers, current mirrors and differential pairs.
- Feedback: general properties; feedback topologies; analysis of stability, including gain margin and phase margin.
Study goals:
- Students will be able to identify and describe the following fundamental aspects of analog circuit design:
- Basic physics of CMOS transistors
- Small-signal and large-signal models and behavior of CMOS transistors
- Working principle of basic transistor circuits, such as single-stage CMOS amplifier topologies (common-source, common-gate, common-drain), differential pair and current mirrors
- Biasing techniques for simple transistor circuits.
- Source of noise in CMOS circuits and their physical origin.
- Effect of noise on the performance of analog circuits
- The definition and the relevance of the frequency response of analog circuits
- The theory of feedback applied to analog circuits.
- Students will be able to perform the following analysis using analytical and approximate calculation methods:
- Calculate the gain, the input/output impedance of single-transistor stages, basic and cascaded current mirrors and differential pairs with resistive or active loads.
- Calculate the noise performance (input- and output-referred noise, signal-to-noise ratio) of basic analog circuits (single-transistor stages, differential pairs, current mirrors).
- Calculate the frequency response of basic analog circuits (single-transistor stages, differential pairs, current mirrors) with and without feedback.
- Evaluate the stability of a feedback loop in an analog circuit.
- Students will be able to simulate the transistor-level description of basic analog circuits using a Spice-like simulator. In particular, they will be able to simulate and evaluate the following:
- DC operation
- Frequency response
- Noise performance
- Transient behavior
- Stability of feedback loops
- Students will be able to describe the trade-offs involved in the design of a basic analog circuit, such as a current mirror and a single transistor amplifier, and be able to apply such trade-offs in the design of those circuits.
- Students will be able to design simple analog circuits (a current mirror or a single-transistor amplifier, including the bias circuit) for a given specification and will be able to verify their design by both analytical calculation/estimation and circuit simulations.
Teachers
dr.ir. Qinwen Fan (ECTM)
high-performance class D audio amplifiers; smart power inverters in wide bandgap semiconductors, low-power DC-DC converters for energy harvesters; low-power circuits for IoT nodes.
dr. Fabio Sebastiano (EI)
cryogenic electronics, quanutm computation, analog/mixed-signal circuit design, frequency references, sensors, sensor readout
dr. Dante Muratore
Analog and mixed-signal CMOS circuit design for biomedical applications and sensor interfaces; circuit-algorithm co-design; neurophysiology.
prof.dr. Kofi Makinwa (EI)
Design of precision analog circuits, sigma-delta ADCs, low-offset amplifiers, voltage and frequency references, sensor interface circuits and smart sensors.
dr. Sijun Du (EI)
Power management integrated circuit (PMIC), energy harvesting, wireless power transfer, DC/DC converters.
prof.dr. Leo de Vreede (ELCA)
RF, Microwave, Power Amplifiers, Device Characterization & modeling
Last modified: 2024-10-01
Details
Credits: | 5 EC |
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Period: | 4/0/0/0 |
Contact: | Qinwen Fan |