Publication
Sensor-fault tolerance using robust MPC with set-based state estimation and active fault isolation
Journal Article (2017)
Journal
International Journal of Robust and Nonlinear Control
Pages
1260–1283
Volume
27
Number
8
Doc link
http://dx.doi.org/10.1002/rnc.3627
File
Authors
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Xu, Feng
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Olaru, Sorin
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Puig Cayuela, Vicenç
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Ocampo Martínez, Carlos A.
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Niculescu, Silviu-Iulian
Abstract
In this paper, a sensor fault-tolerant control scheme using robust model predictive control (MPC) and set-theoretic fault detection and isolation (FDI) is proposed. The robust MPC controller is used to control the plant in the presence of process disturbances and measurement noises while implementing a mechanism to tolerate faults. In the proposed scheme, fault detection (FD) is passive based on interval observers, while fault isolation (FI) is active by means of MPC and set manipulations. The basic idea is that for a healthy or faulty mode, one can construct the corresponding output set. The size and location of the output set can be manipulated by adjusting the size and center of the set of plant inputs. Furthermore, the inputs can be adjusted on-line by changing the input-constraint set of the MPC controller. In this way, one can design an input set able to separate all output sets corresponding to all considered healthy and faulty modes from each other. Consequently, all the considered healthy and faulty modes can be isolated after detecting a mode changing while preserving feasibility of MPC controller. As a case study, an electric circuit is used to illustrate the effectiveness of the proposed scheme.
Categories
automation, control theory, optimisation.
Author keywords
Fault detection and isolation, Fault-tolerant control, Set-theoretic methods, Model predictive control, Sensor faults
Scientific reference
F. Xu, S. Olaru, V. Puig, C. Ocampo-Martínez and S. Niculescu. Sensor-fault tolerance using robust MPC with set-based state estimation and active fault isolation. International Journal of Robust and Nonlinear Control, 27(8): 1260–1283, 2017.
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