A Sparse ADMM-Based Solver for Linear MPC Subject to Terminal Quadratic Constraint

Model predictive control (MPC) typically includes a terminal constraint to guarantee stability of the closed-loop system under nominal conditions. In linear MPC, this constraint is generally taken on a polyhedral set, leading to a quadratic optimization problem. However, the use of an ellipsoidal te...

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Bibliographic Details
Published inIEEE transactions on control systems technology Vol. 32; no. 6; pp. 2376 - 2384
Main Authors Krupa, Pablo, Jaouani, Rim, Limon, Daniel, Alamo, Teodoro
Format Journal Article
LanguageEnglish
Published New York IEEE 01.11.2024
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Algorithms
Artificial intelligence
Closed loops
Complexity theory
Convex functions
Ellipsoids
Embedded optimization
Embedded systems
Feedback control
model predictive control (MPC)
Optimization
Predictive control
Programming
quadratic constraints
second-order cone (SOC) programming
Slack variables
Solvers
Terminal constraints
Vectors
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Summary:Model predictive control (MPC) typically includes a terminal constraint to guarantee stability of the closed-loop system under nominal conditions. In linear MPC, this constraint is generally taken on a polyhedral set, leading to a quadratic optimization problem. However, the use of an ellipsoidal terminal constraint may be desirable, leading to an optimization problem with a quadratic constraint. In this case, the optimization problem can be solved using second-order cone (SOC) programming solvers, since the quadratic constraint can be posed as a SOC constraint, at the expense of adding additional slack variables and possibly compromising the simple structure of the solver ingredients. In this brief, we present a sparse solver for linear MPC subject to a terminal ellipsoidal constraint based on the alternating direction method of multipliers (ADMM) algorithm in which we directly deal with the quadratic constraints without having to resort to the use of a SOC constraint nor the inclusion of additional decision variables. The solver is suitable for its use in embedded systems, since it is sparse, has a small memory footprint, and requires no external libraries. We compare its performance against other approaches from the literature.
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ISSN:1063-6536
1558-0865
DOI:10.1109/TCST.2024.3386062