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Higher order discretisation methods for a class of 2-D continuous-discrete linear systems

Higher order discretisation methods for a class of 2-D continuous-discrete linear systems

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  • Author(s): K. Galkowski 1 ; E. Rogers 2 ; A. Gramacki 3 ; J. Gramacki 3 ; D.H. Owens 4
    • View affiliations
    • Affiliations: 1: Department of Robotics and Software Engineering, Technical University of Zielona Gora, Zielona Gora, Poland
      2: Department of Electronics and Computer Science, University of Southampton, Southampton, United Kingdom
      3: Department of Electronics and Informatics, Technical University of Zielona Gora, Zielona Gora, Poland
      4: Department of Automatic Control and Systems Engineering, University of Sheffield, Sheffield, United Kingdom
  • Source: Volume 146, Issue 6, December 1999, p. 315 – 320
    DOI:  10.1049/ip-cds:19990726 , Print ISSN 1350-2409, Online ISSN 1359-7000
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Differential linear repetitive processes are a distinct class of two-dimensional linear systems which can be used, for example, to model industrial processes such as long-wall coal cutting operations. Also, they can be used to study key properties of classes of linear iterative learning schemes. The key feature of interest in the paper is the fact that information propagation in one of the two separate directions in such processes evolves continuously over a finite fixed duration and in the other direction it is, in effect, discrete. The paper develops discrete approximations for the dynamics of these processes and examines the effects of the approximation techniques used on two key systems-related properties. These are stability and the structure of the resulting discrete state-space models. Some ongoing work and areas for further development are also briefly noted.

Inspec keywords: industrial control; continuous time systems; discrete time systems; linear systems; state-space methods

Other keywords: higher order discretisation methods; industrial processes; approximation techniques; systems-related properties; information propagation; finite fixed duration; iterative learning schemes; discrete state-space models; 2D continuous-discrete linear systems; differential linear repetitive processes; long-wall coal cutting operations

Subjects: Discrete control systems; Industrial applications of IT; Control engineering computing; Control in industrial production systems; Control technology and theory (production); Control system analysis and synthesis methods

References

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      • E. Rogers , D.H. Owens . Output feedback control of discrete linear repetitive processes. IMA J. Math. Control Inf. , 177 - 193
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      • Galkowski, K., Rogers, E., Gramacki, A., Gramacki, J., Owens, D.H.: `Higher order discretization of differential linear repetitive processes', Proceedings of 14th IFAC World Congress, 1999, D, p. 333-338.
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