Robust Nonlinear Reduced-Order Model Predictive Control

Real-world systems are often characterized by high-dimensional nonlinear dynamics, making them challenging to control in real time. While reduced-order models (ROMs) are frequently employed in model-based control schemes, dimensionality reduction introduces model uncertainty which can potentially co...

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Hauptverfasser:	Alora, John Irvin, Pabon, Luis A, Köhler, Johannes, Cenedese, Mattia, Schmerling, Ed, Zeilinger, Melanie N, Haller, George, Pavone, Marco
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Schlagworte:	Computer Science - Robotics Computer Science - Systems and Control Mathematics - Optimization and Control
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creator	Alora, John Irvin Pabon, Luis A Köhler, Johannes Cenedese, Mattia Schmerling, Ed Zeilinger, Melanie N Haller, George Pavone, Marco
description	Real-world systems are often characterized by high-dimensional nonlinear dynamics, making them challenging to control in real time. While reduced-order models (ROMs) are frequently employed in model-based control schemes, dimensionality reduction introduces model uncertainty which can potentially compromise the stability and safety of the original high-dimensional system. In this work, we propose a novel reduced-order model predictive control (ROMPC) scheme to solve constrained optimal control problems for nonlinear, high-dimensional systems. To address the challenges of using ROMs in predictive control schemes, we derive an error bounding system that dynamically accounts for model reduction error. Using these bounds, we design a robust MPC scheme that ensures robust constraint satisfaction, recursive feasibility, and asymptotic stability. We demonstrate the effectiveness of our proposed method in simulations on a high-dimensional soft robot with nearly 10,000 states.
doi_str_mv	10.48550/arxiv.2309.05746
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While reduced-order models (ROMs) are frequently employed in model-based control schemes, dimensionality reduction introduces model uncertainty which can potentially compromise the stability and safety of the original high-dimensional system. In this work, we propose a novel reduced-order model predictive control (ROMPC) scheme to solve constrained optimal control problems for nonlinear, high-dimensional systems. To address the challenges of using ROMs in predictive control schemes, we derive an error bounding system that dynamically accounts for model reduction error. Using these bounds, we design a robust MPC scheme that ensures robust constraint satisfaction, recursive feasibility, and asymptotic stability. 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subjects	Computer Science - Robotics Computer Science - Systems and Control Mathematics - Optimization and Control
title	Robust Nonlinear Reduced-Order Model Predictive Control
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