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239 results on '"Giancarlo Ferrari-Trecate"'

1. Learning to Boost the Performance of Stable Nonlinear Systems

Author

Luca Furieri, Clara Lucia Galimberti, and Giancarlo Ferrari-Trecate

Subjects
Closed-loop stability, distributed control, internal model control, learning for control, optimal control, uncertain systems, Control engineering systems. Automatic machinery (General), TJ212-225, Technology
Abstract

The growing scale and complexity of safety-critical control systems underscore the need to evolve current control architectures aiming for the unparalleled performances achievable through state-of-the-art optimization and machine learning algorithms. However, maintaining closed-loop stability while boosting the performance of nonlinear control systems using data-driven and deep-learning approaches stands as an important unsolved challenge. In this paper, we tackle the performance-boosting problem with closed-loop stability guarantees. Specifically, we establish a synergy between the Internal Model Control (IMC) principle for nonlinear systems and state-of-the-art unconstrained optimization approaches for learning stable dynamics. Our methods enable learning over specific classes of deep neural network performance-boosting controllers for stable nonlinear systems; crucially, we guarantee $\mathcal {L}_{p}$ closed-loop stability even if optimization is halted prematurely. When the ground-truth dynamics are uncertain, we learn over robustly stabilizing control policies. Our robustness result is tight, in the sense that all stabilizing policies are recovered as the $\mathcal {L}_{p}$ -gain of the model mismatch operator is reduced to zero. We discuss the implementation details of the proposed control schemes, including distributed ones, along with the corresponding optimization procedures, demonstrating the potential of freely shaping the cost functions through several numerical experiments.

Published
2024
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2. What Population Reveals about Individual Cell Identity: Single-Cell Parameter Estimation of Models of Gene Expression in Yeast.

Author

Artémis Llamosi, Andres M Gonzalez-Vargas, Cristian Versari, Eugenio Cinquemani, Giancarlo Ferrari-Trecate, Pascal Hersen, and Gregory Batt

Subjects
Biology (General), QH301-705.5
Abstract

Significant cell-to-cell heterogeneity is ubiquitously observed in isogenic cell populations. Consequently, parameters of models of intracellular processes, usually fitted to population-averaged data, should rather be fitted to individual cells to obtain a population of models of similar but non-identical individuals. Here, we propose a quantitative modeling framework that attributes specific parameter values to single cells for a standard model of gene expression. We combine high quality single-cell measurements of the response of yeast cells to repeated hyperosmotic shocks and state-of-the-art statistical inference approaches for mixed-effects models to infer multidimensional parameter distributions describing the population, and then derive specific parameters for individual cells. The analysis of single-cell parameters shows that single-cell identity (e.g. gene expression dynamics, cell size, growth rate, mother-daughter relationships) is, at least partially, captured by the parameter values of gene expression models (e.g. rates of transcription, translation and degradation). Our approach shows how to use the rich information contained into longitudinal single-cell data to infer parameters that can faithfully represent single-cell identity.

Published
2016
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31. Bayesian Error-in-Variables Models for the Identification of Distribution Grids

Author

Jean-Sebastien Brouillon, Emanuele Fabbiani, Pulkit Nahata, Keith Moffat, Florian Dorfler, and Giancarlo Ferrari-Trecate

Subjects
current measurement, line admittance estimation, bayesian inference, General Computer Science, load modeling, Bayesian inference, Distribution grids, Error-in-variables, Line admittance estimation, Power systems identification, admittance, errorin-variables, bayes methods, power systems identification, voltage measurement, networks, standards, systems, phasor measurement units, distribution grids, management
Abstract

The increasing integration of renewable energy requires a good model of the existing power distribution infrastructure, represented by its admittance matrix. However, a reliable estimate may either be missing or quickly become obsolete, as distribution grids are continuously modified. In this work, we propose a method for estimating the admittance matrix from voltage and current measurements. By focusing on μPMU measurements and partially observed networks, we show that voltage collinearity and noisy samples of all electric variables are the main challenges for accurate identification. Moreover, the accuracy of maximum likelihood estimation is often insufficient in real-world scenarios. To overcome this problem, we develop a flexible Bayesian framework that allows one to exploit different forms of prior knowledge about individual line parameters, as well as network-wide characteristics such as the sparsity of the interconnections. Most importantly, we show how to use maximum likelihood estimates for tuning relevant hyperparameters, hence making the identification procedure self-contained. We also discuss numerical aspects of the maximum a posteriori estimate computation. Realistic simulations conducted on benchmark electrical systems demonstrate that, compared to other algorithms, our method can achieve significantly greater accuracy than previously developed methods. ISSN:1949-3053 ISSN:1949-3061

Published
2023

35. Robust Classification Using Contractive Hamiltonian Neural ODEs

Author

Muhammad Zakwan, Liang Xu, and Giancarlo Ferrari-Trecate

Subjects
FOS: Computer and information sciences, perturbation methods, Computer Science - Machine Learning, training, Control and Optimization, stability of nonlinear systems, robustness, dynamical systems, sensitivity, neural networks, Machine Learning (cs.LG), machine learning, Control and Systems Engineering, trajectory, artificial neural networks
Abstract

Deep neural networks can be fragile and sensitive to small input perturbations that might cause a significant change in the output. In this letter, we employ contraction theory to improve the robustness of neural ODEs (NODEs). A dynamical system is contractive if all solutions with different initial conditions converge to each other exponentially fast. As a consequence, perturbations in initial conditions become less and less relevant over time. Since in NODEs the input data corresponds to the initial condition of dynamical systems, we show contractivity can mitigate the effect of input perturbations. More precisely, inspired by NODEs with Hamiltonian dynamics, we propose a class of contractive Hamiltonian NODEs (CH-NODEs). By properly tuning a scalar parameter, CH-NODEs ensure contractivity by design and can be trained using standard backpropagation. Moreover, CH-NODEs enjoy built-in guarantees of non-exploding gradients, which ensure a well-posed training process. Finally, we demonstrate the robustness of CH-NODEs on the MNIST image classification problem with noisy test data.

Published
2023

36. On the Optimality and Convergence Properties of the Iterative Learning Model Predictive Controller

Author

Ugo Rosolia, Yingzhao Lian, Emilio T. Maddalena, Giancarlo Ferrari-Trecate, and Colin N. Jones

Subjects
iterative algorithms, iterative learning control, Systems and Control (eess.SY), Electrical Engineering and Systems Science - Systems and Control, Computer Science Applications, optimal control, mpc, Optimization and Control (math.OC), Control and Systems Engineering, FOS: Mathematics, FOS: Electrical engineering, electronic engineering, information engineering, Electrical and Electronic Engineering, Mathematics - Optimization and Control, predictive control
Abstract

In this technical note we analyse the performance improvement and optimality properties of the Learning Model Predictive Control (LMPC) strategy for linear deterministic systems. The LMPC framework is a policy iteration scheme where closed-loop trajectories are used to update the control policy for the next execution of the control task. We show that, when a Linear Independence Constraint Qualification (LICQ) condition holds, the LMPC scheme guarantees strict iterative performance improvement and optimality, meaning that the closed-loop cost evaluated over the entire task converges asymptotically to the optimal cost of the infinite-horizon control problem. Compared to previous works this sufficient LICQ condition can be easily checked, it holds for a larger class of systems and it can be used to adaptively select the prediction horizon of the controller, as demonstrated by a numerical example., Comment: technical note

Published
2023

43. Consensus-Based Current Sharing and Voltage Balancing in DC Microgrids With Exponential Loads

Author

Mustafa Sahin Turan, Pulkit Nahata, and Giancarlo Ferrari-Trecate

Subjects
Equilibrium point, Steady state (electronics), business.industry, Computer science, Systems and Control (eess.SY), Network topology, Topology, Electrical Engineering and Systems Science - Systems and Control, Control and Systems Engineering, Robustness (computer science), Distributed generation, FOS: Electrical engineering, electronic engineering, information engineering, Constant current, RLC circuit, Electrical and Electronic Engineering, business, Voltage
Abstract

In this work, we present a novel consensus-based secondary control scheme for current sharing and voltage balancing in DC microgrids, composed of distributed generation units, dynamic RLC lines, and nonlinear ZIE (constant impedance, constant current, and exponential) loads. Situated atop a primary voltage control layer, our secondary controllers have a distributed structure, and utilize information exchanged over a communication network to compute necessary control actions. Besides showing that the desired objectives are always attained in steady state, we deduce sufficient conditions for the existence and uniqueness of an equilibrium point for constant power loads -- E loads with zero exponent. Our control design hinges only on the local parameters of the generation units, facilitating plug-and-play operations. We provide a voltage stability analysis, and illustrate the performance and robustness of our designs via simulations. All results hold for arbitrary, albeit connected, microgrid and communication network topologies., Comment: arXiv admin note: substantial text overlap with arXiv:2005.00068

Published
2022

47. On Consensusability of Linear Interconnected Multiagent Systems and Simultaneous Stabilization

Author

Mustafa Sahin Turan, Giancarlo Ferrari-Trecate, and Liang Xu

Subjects
0209 industrial biotechnology, Control and Optimization, Linear programming, Computer Networks and Communications, Computer science, Multi-agent system, 020302 automobile design & engineering, 02 engineering and technology, Graph, Computer Science::Multiagent Systems, 020901 industrial engineering & automation, 0203 mechanical engineering, Computer Science::Systems and Control, Control and Systems Engineering, Control theory, Signal Processing, Eigenvalues and eigenvectors
Abstract

Consensusability of multi-agent systems (MASs) certifies the existence of a distributed controller capable of driving the states of each subsystem to a consensus value. We study the consensusability of linear interconnected MASs (LIMASs) where, as in several real-world applications, subsystems are physically coupled. We show that consensusability is related to the simultaneous stabilizability of multiple LTI systems, and present a novel sufficient condition in form of a linear program for verifying this property. We also derive several necessary and sufficient consensusability conditions for LIMASs in terms of parameters of the subsystem matrices and the eigenvalues of the physical and communication graph Laplacians. The results show that weak physical couplings among subsystems and densely-connected physical and communication graphs are favorable for consensusability. Finally, we validate our results through simulations of networks of supercapacitors and DC microgrids.

Published
2022

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