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Frequency-distributed representation of irrational linear systems

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Published/Copyright: January 13, 2019
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Fractional Calculus and Applied Analysis
From the journal Fractional Calculus and Applied Analysis Volume 21 Issue 5

Abstract

The present work extends and generalizes the notion of frequency-distributed (FD) representation to a broad class of linear, stationary, continuous-time systems. On one hand, the proposed FD representation can be seen as a generalization of the diffusive representation, which is primarily utilized in the context of fractional order systems. Alternatively, it can also be seen as an extension to the Jordan canonical form, which is used as one of the main theoretical tools when analyzing finite-dimensional systems. Sufficient conditions under which FD representation can be achieved are derived. The proposed approach ensures real-valued state functions and output weights even when applied to oscillatory systems, and in a wast majority of cases manages to avoid utilization of generalized functions. Potential applications include simulation, representation theory and stability analysis, control synthesis, etc. All considerations have been illustrated by numerical examples.

MSC 2010: Primary 93B15; Secondary 93B10; 47A99; 47G10; 47G30
Key Words and Phrases: fractional order systems; frequency-distributed realization; infinite dimensional systems; generalized Jordan form; generalized Heaviside expansion

Acknowledgments

The authors kindly acknowledge the support of Ministry of Education, Science and Technological Development under grants TR32018 and TR33013 (MRR) and TR33020 (TBŠ).

The author’ work is also in frames of the working program on bilateral agreement between Serbian and Bulgarian Academies of Sciences, SASA – BAS, 2017-2019.

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Received: 2018-01-25
Published Online: 2019-01-13
Published in Print: 2018-10-25

© 2018 Diogenes Co., Sofia

Articles in the same Issue

  1. Editorial Note
  2. FCAA related news, events and books (FCAA–volume 21–5–2018)
  3. Discussion Paper
  4. Fractional calculus’s adventures in Wonderland (Round table held at ICFDA 2018)
  5. Survey Paper
  6. On modifications of the exponential integral with the Mittag-Leffler function
  7. Research Paper
  8. Global solutions to stochastic Volterra equations driven by Lévy noise
  9. Chernoff approximation for semigroups generated by killed Feller processes and Feynman formulae for time-fractional Fokker–Planck–Kolmogorov equations
  10. Fractional derivatives of convex Lyapunov functions and control problems in fractional order systems
  11. Regularity of solutions to space–time fractional wave equations: A PDE approach
  12. Asymptotically periodic solutions for Caputo type fractional evolution equations
  13. Complex fractional Zener model of wave propagation in ℝ
  14. Maximum principles for time-fractional Cauchy problems with spatially non-local components
  15. An extension of the multiple Erdélyi-Kober operator and representations of the generalized hypergeometric functions
  16. A further extension of Mittag-Leffler function
  17. Frequency-distributed representation of irrational linear systems
  18. Centre-of-mass like superposition of Ornstein–Uhlenbeck processes: A pathway to non-autonomous stochastic differential equations and to fractional diffusion
https://doi.org/10.1515/fca-2018-0073
Keywords for this article
fractional order systems; frequency-distributed realization; infinite dimensional systems; generalized Jordan form; generalized Heaviside expansion

Articles in the same Issue

  1. Editorial Note
  2. FCAA related news, events and books (FCAA–volume 21–5–2018)
  3. Discussion Paper
  4. Fractional calculus’s adventures in Wonderland (Round table held at ICFDA 2018)
  5. Survey Paper
  6. On modifications of the exponential integral with the Mittag-Leffler function
  7. Research Paper
  8. Global solutions to stochastic Volterra equations driven by Lévy noise
  9. Chernoff approximation for semigroups generated by killed Feller processes and Feynman formulae for time-fractional Fokker–Planck–Kolmogorov equations
  10. Fractional derivatives of convex Lyapunov functions and control problems in fractional order systems
  11. Regularity of solutions to space–time fractional wave equations: A PDE approach
  12. Asymptotically periodic solutions for Caputo type fractional evolution equations
  13. Complex fractional Zener model of wave propagation in ℝ
  14. Maximum principles for time-fractional Cauchy problems with spatially non-local components
  15. An extension of the multiple Erdélyi-Kober operator and representations of the generalized hypergeometric functions
  16. A further extension of Mittag-Leffler function
  17. Frequency-distributed representation of irrational linear systems
  18. Centre-of-mass like superposition of Ornstein–Uhlenbeck processes: A pathway to non-autonomous stochastic differential equations and to fractional diffusion
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