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Tracking model predictive control and moving horizon estimation design of distributed parameter pipeline systems

Lu Zhang, Junyao Xie, Stevan Dubljević

2023Computers & Chemical Engineering10 citationsDOIOpen Access PDF

Abstract

This manuscript proposes moving horizon control and state/parameter estimation designs for pipeline networks modelled by partial differential equations (PDEs) with boundary actuation. The spatial–temporal pressure and velocity model dynamics within the pipelines are described by a system of six coupled one-dimensional first-order nonlinear hyperbolic PDEs. To address the discrete-time modelling challenge and preserve the infinite-dimensional nature of the pipeline system, the Cayley-Tustin transformation is deployed for model time discretization without any spatial discretization or model reduction. Considering the lack of full state information across the entire pipeline manifold, unknown states and uncertain parameters are estimated using moving horizon estimation (MHE). Based on the estimated states and parameters, a tracking model predictive control (MPC) strategy for the discrete-time infinite-dimensional pipeline system is proposed, which enables specific operation while ensuring physical constraint satisfaction. The effectiveness of the proposed controller and estimator designs is demonstrated via numerical examples.

Topics & Concepts

Model predictive controlDiscretizationControl theory (sociology)Pipeline (software)Nonlinear systemEstimatorPartial differential equationMathematical optimizationHorizonTracking (education)Computer scienceApplied mathematicsMathematicsControl (management)Artificial intelligenceMathematical analysisPhysicsGeometryProgramming languagePsychologyQuantum mechanicsPedagogyStatisticsAdvanced Control Systems OptimizationStability and Controllability of Differential Equations
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