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M.Sc. Simon Kerschbaum

Department of Electrical-Electronic-Communication Engineering
Chair of Automatic Control (Prof. Dr.-Ing. Graichen)

Room: Room 04.025
Cauerstr. 7
91058 Erlangen

Research Interests

Journal articles

  • Kerschbaum, S. and Deutscher, J.:
    Backstepping control of coupled linear parabolic PDEs with space and time dependent coefficients.
    Conditionally accepted for IEEE Trans. Autom. Control, 2019.
  • Deutscher, J. and Kerschbaum, S.:
    Robust output regulation by state feedback control for coupled linear parabolic PIDEs.
    Submitted to IEEE Trans. Autom. Control, 2018.
  • Deutscher, J. and Kerschbaum, S.:
    Output regulation for coupled linear parabolic PIDEs.
    Automatica 100 (2019), pp. 360-370. [DOI]
  • Deutscher, J. and Kerschbaum, S.:
    Backstepping control of coupled linear parabolic PIDEs with spatially varying coefficients.
    IEEE Trans. Autom. Control 63 (2018), pp. 4218-4233. [DOI]
  • Deutscher, J. and Kerschbaum, S.:
    Backstepping for coupled parabolic systems with spatially varying coefficients (in German).
    at-Automatisierungstechnik 66 (2018), pp. 558-572. [DOI]
  • Kerschbaum, S. and Deutscher, J.:
    Backstepping-based output regulation for systems with infinite-dimensional actuator and sensor dynamics.
    PAMM 16 (2016), pp. 43-46. [DOI]

Konferenzbeiträge

  • Deutscher, J. and Kerschbaum, S.:
    Backstepping control of coupled diffusion-reaction systems with spatially-varying reaction and Neumann boundary conditions.
    CDC 2017 in Melbourne, Australia, pp. 2504-2510.
  • Deutscher, J. and Kerschbaum, S.:
    Backstepping design of robust state feedback regulators for second order hyperbolic PIDEs.
    Proc. CPDE 2016 in Bertinoro, Italy, pp. 81-86.

Open thesis/projects

  • Currently no available thesis/projects

Current and completed student thesis/projects

  • Führungs- und Störgrößenaufschaltung für verkoppelte parabolische PIDEs (FP)
  • Modelling and Backstepping-Based Control of a Tubular Reactor (MA)
  • Modellierung und Regelung von Raumheizungen (BA)
  • Optimierung von Raumheizung, Lüftung und Verschattung mittels MPC (BA)
  • Praxisnahe Regelung von Raumheizung, -lüftung und Verschattung (FP)
  • Simulation eines Drei-Wege-Katalysators (FP)
  • „Backstepping“-basierte Führungs- und Störgrößenaufschaltung für zweidimensionale hyperbolische Systeme (MA)