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Main Authors: Gulewicz, Demetrius, Inyang-Udoh, Uduak, Bird, Trevor, Jain, Neera
Format: Preprint
Published: 2024
Subjects:
Online Access:https://arxiv.org/abs/2411.15929
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author Gulewicz, Demetrius
Inyang-Udoh, Uduak
Bird, Trevor
Jain, Neera
author_facet Gulewicz, Demetrius
Inyang-Udoh, Uduak
Bird, Trevor
Jain, Neera
contents Model predictive control has gained popularity for its ability to satisfy constraints and guarantee robustness for certain classes of systems. However, for systems whose dynamics are characterized by a high state dimension, substantial nonlinearities, and stiffness, suitable methods for online nonlinear MPC are lacking. One example of such a system is a vehicle thermal management system (TMS) with integrated thermal energy storage (TES), also referred to as a hybrid TMS. Here, hybrid refers to the ability to achieve cooling through a conventional heat exchanger or via melting of a phase change material, or both. Given increased electrification in vehicle platforms, more stringent performance specifications are being placed on TMS, in turn requiring more advanced control methods. In this paper, we present the design and real-time implementation of a nonlinear model predictive controller with 77 states on an experimental hybrid TMS testbed. We show how, in spite of high-dimension and stiff dynamics, an explicit integration method can be obtained by linearizing the dynamics at each time step within the MPC horizon. This integration method further allows the first-order gradients to be calculated with minimal additional computational cost. Through simulated and experimental results, we demonstrate the utility of the proposed solution method and the benefits of TES for mitigating highly transient heat loads achieved by actively controlling its charging and discharging behavior.
format Preprint
id arxiv_https___arxiv_org_abs_2411_15929
institution arXiv
publishDate 2024
record_format arxiv
spellingShingle Nonlinear Model Predictive Control of a Hybrid Thermal Management System
Gulewicz, Demetrius
Inyang-Udoh, Uduak
Bird, Trevor
Jain, Neera
Systems and Control
Model predictive control has gained popularity for its ability to satisfy constraints and guarantee robustness for certain classes of systems. However, for systems whose dynamics are characterized by a high state dimension, substantial nonlinearities, and stiffness, suitable methods for online nonlinear MPC are lacking. One example of such a system is a vehicle thermal management system (TMS) with integrated thermal energy storage (TES), also referred to as a hybrid TMS. Here, hybrid refers to the ability to achieve cooling through a conventional heat exchanger or via melting of a phase change material, or both. Given increased electrification in vehicle platforms, more stringent performance specifications are being placed on TMS, in turn requiring more advanced control methods. In this paper, we present the design and real-time implementation of a nonlinear model predictive controller with 77 states on an experimental hybrid TMS testbed. We show how, in spite of high-dimension and stiff dynamics, an explicit integration method can be obtained by linearizing the dynamics at each time step within the MPC horizon. This integration method further allows the first-order gradients to be calculated with minimal additional computational cost. Through simulated and experimental results, we demonstrate the utility of the proposed solution method and the benefits of TES for mitigating highly transient heat loads achieved by actively controlling its charging and discharging behavior.
title Nonlinear Model Predictive Control of a Hybrid Thermal Management System
topic Systems and Control
url https://arxiv.org/abs/2411.15929