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Dynamical Systems, Control and Optimization

Space Greenhouse

Picture : schematic view of the space greenhouse

The Dynamical Systems, Control and Optimization group gathers about a dozen professors and over 30 PhD students and postdoctoral researchers. It participates in various projects including the Inter-university Attraction Pole on Dynamical Systems, Control and Optimization (DYSCO).

Principal Investigators :

Pierre-Antoine AbsilVincent Blondel, Jean-Charles Delvenne, Yves Deville, Denis DochainFrançois Glineur, Julien Hendrickx, Raphaël Jungers, Philippe Lefèvre, Yurii Nesterov, Pierre Schaus, Paul Van Dooren, Vincent Wertz

Research Areas :

Identification of dynamical systems is one of the first steps in the study of dynamical systems, since it addresses the issue of finding an appropriate model for its input/output behavior. Much of our work on identification has focused on understanding the connections between, identifiability, informative experiments, the information matrix and the minimization of a prediction error criterion.

Several new multi-agent models have been proposed and studied with behavior reminiscent of the partial entrainment behavior of the Kuramoto-Sakaguchi model, but with a greater potential for analysis and with applications to systems not related to coupled oscillators. The main emphasis on these dynamic models is to analyze the asymptotic clustering behavior. The analysis of such models is relevant in the study of opinion formation, interconnected water basins, platoon formation in cycling races, and the minimum cost flow problem.

We study fundamental issues in modeling, control design and stability analysis of physical networks described by hyperbolic systems of conservation laws and by distributed parameter systems modeling e.g. tubular reactors. We also study problems related to optimal prediction of nonlinear systems, such as the flow in channels (modeled by Saint-Venant equations), the modeling of the water level in water basins in order to prevent flooding and the prediction and control of traffic jams.

Optimization techniques play a fundamental role in the area of dynamical systems and they are being developed and analyzed at several levels, depending on the type of variables one wishes to optimize. Variables can be discrete (as in graph theoretic problems) or continuous (as in parametric optimization), but can also be infinite dimensional (as in optimal control over function spaces) and constrained (as in optimization on manifolds or on cones). The group has activities in each of these areas and also develops special purpose numerical techniques for dealing efficiently with such problems.

The activities here include microbial ecology and the modeling of wastewater treatment, including applications to various biological wastewater systems. We developed population balance models covering a large spectrum of applications in the industry of polymer production, crystallization, biotechnology or any process in which the size distribution of particles is essential for process quality. We also study the design and application of observers converging in finite time for a class of fed-batch processes.

We combine theoretical and experimental approaches to investigate the neural control of movement and its interactions with our environment. The mathematical models that are developed are based on experimental results from both normal and pathological subjects (clinical studies) and focus on the interaction between different types of eye movements and on eye/hand coordination. Our main research objective is to gain further insight into the nature and characteristics of high-level perceptual and motor representations in the human brain. 

Most recent publications

Below are listed the 10 most recent journal articles and conference papers produced in this research area. You also can access all publications by following this link : see all publications.


Journal Articles


1. Van Dessel, Guillaume; Glineur, François. Optimal inexactness schedules for tunable oracle-based methods. In: Optimization Methods and Software, Vol. 39, no.3, p. 664-698 (2024). doi:10.1080/10556788.2023.2296982. http://hdl.handle.net/2078.1/293060

2. Zamani, Moslem; Glineur, François; Hendrickx, Julien. On the Set of Possible Minimizers of a Sum of Convex Functions. In: IEEE Control Systems Letters, Vol. 8, p. 1871-1876 (2024). doi:10.1109/lcsys.2024.3414378. http://hdl.handle.net/2078.1/293048

3. Goujaud, Baptiste; Moucer, Céline; Glineur, François; Hendrickx, Julien; Taylor, Adrien B.; Dieuleveut, Aymeric. PEPit: computer-assisted worst-case analyses of first-order optimization methods in Python. In: Mathematical Programming Computation, Vol. 16, no.3, p. 337-367 (2024). doi:10.1007/s12532-024-00259-7. http://hdl.handle.net/2078.1/293047

4. Monnoyer de Galland de Carnières, Charles; Vizuete Haro, Renato Sebastian; Hendrickx, Julien; Panteley, Elena; Frasca, Paolo. Random Coordinate Descent for Resource Allocation in Open Multiagent Systems. In: IEEE Transactions on Automatic Control, Vol. 69, no.11, p. 7600-7613 (2024). doi:10.1109/tac.2024.3394349. http://hdl.handle.net/2078.1/292991

5. Vuille, Alexis; Berger, Guillaume; Jungers, Raphaël M. Data-Driven Stability Analysis of Switched Linear Systems Using Adaptive Sampling. In: IFAC-PapersOnLine, Vol. 58, no.11, p. 31-36 (2024). doi:10.1016/j.ifacol.2024.07.421. http://hdl.handle.net/2078.1/290787

6. Vary, Simon; Ablin, Pierre; Gao, Bin; Absil, Pierre-Antoine. Optimization without Retraction on the Random Generalized Stiefel Manifold. In: Proceedings of Machine Learning Research, Vol. 235, p. 49226-49248 (2024). http://hdl.handle.net/2078.1/290550

7. Ren, Wei; Jungers, Raphaël M.; Dimarogonas, Dimos V. Zonotope-based Symbolic Controller Synthesis for Linear Temporal Logic Specifications. In: IEEE Transactions on Automatic Control, , p. 1-16 (2024). doi:10.1109/tac.2024.3394313 (Soumis). http://hdl.handle.net/2078.1/287279

8. Farid, Yousef; Jungers, Raphaël M. Binary Combinatorial Optimization-based Path Planning and Optimal Reach Control in Piecewise Linear Neural Abstraction Domain. In: I E E E Transactions on Neural Networks and Learning Systems, (2024). (Soumis). http://hdl.handle.net/2078.1/285558

9. Si, Wutao; Absil, Pierre-Antoine; Huang, Wen; Jiang, Rujun; Vary, Simon. A Riemannian Proximal Newton Method. In: SIAM Journal on Optimization, Vol. 34, no.1, p. 654-681 (2023). doi:10.1137/23m1565097. http://hdl.handle.net/2078.1/285108

10. Bendokat, Thomas; Zimmermann, Ralf; Absil, Pierre-Antoine. A Grassmann manifold handbook: basic geometry and computational aspects. In: Advances in Computational Mathematics, Vol. 50, no.1 (2024). doi:10.1007/s10444-023-10090-8. http://hdl.handle.net/2078.1/282834


Conference Papers


1. Bousselmi, Nizar; Pustelnik, Nelly; Hendrickx, Julien; Glineur, François. Comparison of Proximal First-Order Primal and Primal-Dual Algorithms via Performance Estimation. In: Eusipco 2024, 2024, 978-9-4645-9361-7, p. 2647-2651 xxx. http://hdl.handle.net/2078.1/293043

2. Vernimmen, Pierre; Glineur, François. Convergence analysis of an inexact gradient method on smooth convex functions. In: ESANN 2024 proceedings, 2024, 978-2-87587-090-2 xxx. doi:10.14428/esann/2024.es2024-171. http://hdl.handle.net/2078.1/293029

3. Vizuete Haro, Renato Sebastian; Frasca, Paolo; Panteley, Elena. SIS Epidemics on Open Networks: A Replacement-Based Approximation. In: n/. (2024). 2024 xxx. doi:10.48550/arXiv.2403.16727; 10.23919/ecc64448.2024.10591224. http://hdl.handle.net/2078.1/292993

4. Jungers, Raphaël M.. Statistical comparison of Path-Complete Lyapunov Functions: a Discrete-Event Systems perspective. In: In Proc. of IFAC-WODES'24. (2024). 2024 xxx. http://hdl.handle.net/2078.1/285977

5. Debauche, Virginie; Jungers, Raphaël M.. Formal Synthesis of Lyapunov Stability Certificates for Linear Switched Systems using ReLU Neural Networks. 2024 xxx. http://hdl.handle.net/2078.1/283182

6. Debauche, Virginie; Alec Edwards; Jungers, Raphaël M.; Alessandro Abate. Stability Analysis of Switched Linear Systems with Neural Lyapunov Functions. 2024 xxx. http://hdl.handle.net/2078.1/283176

7. Vizuete Haro, Renato Sebastian; Hendrickx, Julien. Nonlinear Network Identifiability: The Static Case. In: IEEE Conference on Decision and Control. Proceedings. (2023). I E E E, 2023 xxx. doi:10.1109/cdc49753.2023.10383333. http://hdl.handle.net/2078.1/293007

8. Massart, Estelle; Abrol, Vinayak. Coordinate descent on the Stiefel manifold for deep neural network training. In: ESANN 2023 proceedings, 2023, 978-2-87587-088-9 xxx. http://hdl.handle.net/2078.1/289245

9. Wang, Zheming; Chen, Bo; Jungers, Raphaël M.; Yu, li. Data-driven reachability analysis of Lipschitz nonlinear systems via support vector data description. 2023 xxx. http://hdl.handle.net/2078.1/284535

10. Rafanomezantsoa, Ny Rindralalaina; Frenay, Mariane; Colognesi, Stéphane; Parmentier, Philippe P.; Wertz, Vincent. Recensement des pratiques de pédagogie active à l’Université d’Antananarivo (UA), à Madagascar. 2023 xxx. http://hdl.handle.net/2078.1/281953