SA/BA/MA projects
Have you heard of industry 4.0, smart grids, smart buildings, smart cities, intelligent traffic systems and intelligent self-driving cars? Did you ever wonder what makes them smart and intelligent?
The answer is control and automation and that’s what we do at the Automatic Control Laboratory (IfA). We use control theory, optimization, machine learning, and game theory to develop controllers and algorithms that are the backbone of nearly all modern technology. At our lab we span the whole area from pure theory to real-world applications and we are looking for you to help us push forward the state of the art. If you want to learn techniques and gain knowledge that enable you to work in any field from medical applications to spacecraft and from electrical grids to finance then the Automatic Control Laboratory is the place for you!
Lists of currently running and recently completed projects can be found in the sub-navigation menu above. Reports for several projects are available through the ETHZ Research Collection:
Open projects
Learning Model Predictive Control Under Environmental Changes Using Meta-Learning
Model predictive control (MPC) is a widely used control technique that optimizes control inputs while fulfilling process constraints. By utilizing the data collected while interacting with the system, learning-based MPC approaches can progressively improve their performance, reaching closed-loop optimality. However, these approaches fail when the system dynamics change over time, for example as a result of unmodeled effects or degradation. In this project, we will design controllers that can quickly adapt to changes in the dynamics and maintain high performance by leveraging meta-learning.
Keywords
Model Predictive Control, Learning-based Control, Meta-Learning
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Semester Project
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Published since: 2025-06-08 , Earliest start: 2025-07-01
Organization Automatic Control Laboratory
Hosts Zuliani Riccardo
Topics Engineering and Technology
Safe and Reliable High-Performance Model Predictive Control using Differentiable Optimization
Safety violations in control systems can lead to catastrophic outcomes, from autonomous vehicle crashes to power grid failures. While Model Predictive Control (MPC) offers powerful safety mechanisms through constraint enforcement, a critical dilemma emerges: improved controller performance often comes at the expense of safety margins. Traditional tuning approaches that prioritize performance metrics may inadvertently compromise safety guarantees. This project addresses this fundamental challenge by developing a tuning framework that enhances MPC performance while providing anytime safety guarantees—ensuring the system remains safe even during ongoing optimization. The approach offers a principled solution for deploying high-performance, safety-critical control in autonomous systems, robotics, and industrial processes.
Keywords
Model Predictive Control, Learning-based Control, Differentiable Optimization
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Master Thesis
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Published since: 2025-06-08 , Earliest start: 2025-07-01
Organization Automatic Control Laboratory
Hosts Zuliani Riccardo
Topics Engineering and Technology
Adaptive control via reinforcement learning: stability, optimality, and robustness
This project explores reinforcement learning (RL) for adaptive control of linear time-invariant systems, with a focus on achieving stability, optimality, and robustness. While RL-based adaptive control methods are gaining popularity, most lack rigorous stability guarantees, especially when applied to the linear quadratic regulator (LQR) problem. Building on recent advances in sequential stability analysis, the project aims to develop RL algorithms that ensure closed-loop stability and convergence to the optimal LQR policy. Theoretical insights will be validated through simulations on representative control systems.
Keywords
data-driven control, adaptive control, reinforcement learning, linear time-invariant system
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Master Thesis , ETH Zurich (ETHZ)
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Published since: 2025-06-06 , Earliest start: 2025-09-07 , Latest end: 2026-07-01
Organization Automatic Control Laboratory
Hosts Bartos Marcell , Zhao Feiran
Topics Mathematical Sciences , Information, Computing and Communication Sciences
Advanced Volume Control for Pipetting
Improving volume control precision and robustness in automated pipetting remains a challenge, often limited by traditional indirect methods. This project explores direct volume control by leveraging internal air pressure measurements and the ideal gas law. Key obstacles include friction, pressure oscillations, varying liquid viscosities, evaporation, and liquid retention. Collaborating with Hamilton Robotics, the goal is to develop a robust control architecture for their precision pipette (MagPip) suitable for diverse liquids. The approach involves mathematical modeling based on sensor data, designing robust control strategies to handle nonlinearities and disturbances, and validating through simulation and real-world experiments.
Keywords
Modeling, nonlinear control, system identification, learning-based control, state estimation, fluid dynamics
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Semester Project
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Published since: 2025-04-14 , Earliest start: 2025-05-01 , Latest end: 2025-09-01
Organization Automatic Control Laboratory
Hosts Zakwan Muhammad
Topics Mathematical Sciences , Information, Computing and Communication Sciences , Engineering and Technology
Contact
ETH Zurich
Automatic Control Laboratory
Physikstrasse 3
8092 Zurich
Switzerland