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2020 – today
- 2022
[c24]Wiebke Frenkel, Julia Kersten, Ricus Husmann, Harald Aschemann:
Design of Robust PID Controllers for SOFC Stacks. CCTA 2022: 510-515- [c23]Julia Kersten, Wiebke Frenkel, Harald Aschemann:
LMI-based Observer Approach For an Industrial Application of a Solid Oxide Fuel Cell. CCTA 2022: 1153-1158 - 2021
- [j17]Andreas Rauh
, Julia Kersten:
Transformation of Uncertain Linear Systems with Real Eigenvalues into Cooperative Form: The Case of Constant and Time-Varying Bounded Parameters. Algorithms 14(3): 85 (2021) - [j16]Julia Kersten, Andreas Rauh, Harald Aschemann:
Analyzing Uncertain Dynamical Systems after State-Space Transformations into Cooperative Form: Verification of Control and Fault Diagnosis. Axioms 10(2): 88 (2021) - [c22]Andreas Rauh, Auguste Bourgois, Luc Jaulin, Julia Kersten:
Ellipsoidal Enclosure Techniques for a Verified Simulation of Initial Value Problems for Ordinary Differential Equations. ICCAD 2021: 1-6 - [c21]Julia Kersten, Harald Aschemann, Andreas Rauh:
Application-Based Analysis of Transformations of Uncertain Dynamical Systems Into a Cooperative Form. MMAR 2021: 162-167 - [c20]Wiebke Frenkel, Julia Kersten, Harald Aschemann, Andreas Rauh:
Model Predictive Control as an Industrially Applicable Approach for Power Control of Solid Oxide Fuel Cells. MMAR 2021: 251-256 - 2020
- [j15]Ekaterina Auer, Julia Kersten, Andreas Rauh:
Preface. Acta Cybern. 24(3): 265-266 (2020) - [j14]Julia Kersten, Andreas Rauh, Harald Aschemann:
Verified Interval Enclosure Techniques for Robust Gain Scheduling Controllers. Acta Cybern. 24(3): 467-491 (2020) - [j13]Andreas Rauh, Julia Kersten:
From Verified Parameter Identification to the Design of Interval Observers and Cooperativity-Preserving Controllers. Acta Cybern. 24(3): 509-537 (2020) - [j12]Andreas Rauh, Julia Kersten:
Toward the Development of Iteration Procedures for the Interval-Based Simulation of Fractional-Order Systems. Acta Cybern. 25(1): 21-48 (2020) - [j11]Andreas Rauh, Wiebke Frenkel, Julia Kersten:
Kalman Filter-Based Online Identification of the Electric Power Characteristic of Solid Oxide Fuel Cells Aiming at Maximum Power Point Tracking. Algorithms 13(3): 58 (2020) - [j10]Wiebke Frenkel, Andreas Rauh, Julia Kersten, Harald Aschemann:
Experiments-Based Comparison of Different Power Controllers for a Solid Oxide Fuel Cell Against Model Imperfections and Delay Phenomena. Algorithms 13(4): 76 (2020) - [j9]Andreas Rauh, Julia Kersten, Ekaterina Auer, Harald Aschemann:
Intervallmethoden zur Berechnung exponentieller Zustandseinschlüsse für die Erreichbarkeitsanalyse unsicherer Systeme. Autom. 68(10): 826-839 (2020) - [j8]Andreas Rauh, Julia Kersten, Harald Aschemann:
Interval and linear matrix inequality techniques for reliable control of linear continuous-time cooperative systems with applications to heat transfer. Int. J. Control 93(11): 2771-2788 (2020) - [j7]Andreas Rauh, Julia Kersten, Harald Aschemann:
Interval methods and contractor-based branch-and-bound procedures for verified parameter identification of quasi-linear cooperative system models. J. Comput. Appl. Math. 367 (2020) - [j6]Ekaterina Auer, Andreas Rauh, Julia Kersten:
Experiments-based parameter identification on the GPU for cooperative systems. J. Comput. Appl. Math. 371: 112657 (2020) - [c19]Andreas Rauh, Julia Kersten, Harald Aschemann:
Interval-Based Verification Techniques for the Analysis of Uncertain Fractional-Order System Models. ECC 2020: 1853-1858 - [c18]Andreas Rauh, Julia Kersten:
Verification and Reachability Analysis of Fractional-Order Differential Equations Using Interval Analysis. SNR 2020: 18-32
2010 – 2019
- 2019
- [j5]Julia Kersten, Harald Aschemann:
Aktive Schwingungsdämpfung einer Windkraftanlage mit hydrostatischem Getriebe und permanenterregtem Synchrongenerator. Autom. 67(2): 113-123 (2019) - [c17]Andreas Rauh, Julia Kersten, Harald Aschemann:
Techniques for Verified Reachability Analysis of Quasi-Linear Continuous-Time Systems. MMAR 2019: 18-23 - [c16]Julia Kersten, Andreas Rauh, Harald Aschemann:
Application-Based Discussion of Verified Simulations of Interval Enclosure Techniques. MMAR 2019: 209-214 - [c15]Sara Ifqir, Andreas Rauh, Julia Kersten, Dalil Ichalal, Naima Ait Oufroukh, Saïd Mammar:
Interval Observer-Based Controller Design for Systems with State Constraints: Application to Solid Oxide Fuel Cells Stacks. MMAR 2019: 372-377 - [c14]Wiebke Frenkel, Andreas Rauh, Julia Kersten, Harald Aschemann:
Optimization Techniques for the Design of Identification Procedures for the Electro-Chemical Dynamics of High-Temperature Fuel Cells. MMAR 2019: 490-495 - 2018
- [j4]Andreas Rauh, Julia Kersten, Harald Aschemann:
Intervallmethoden für Identifikation, Beobachter- und Reglersynthese von Finite-Volumen-Modellen thermischer Prozesse. Autom. 66(8): 633-646 (2018) - [c13]Andreas Rauh, Julia Kersten, Harald Aschemann:
An Interval Observer Approach for the Online Temperature Estimation in Solid Oxide Fuel Cell Stacks. ECC 2018: 1596-1601 - [c12]Andreas Rauh, Julia Kersten, Harald Aschemann:
Linear Matrix Inequality Techniques for the Optimization of Interval Observers for Spatially Distributed Heating Systems. MMAR 2018: 138-143 - [c11]Dmitri Knyazkov, Harald Aschemann, Julia Kersten, Georgy V. Kostin, Andreas Rauh:
Modeling and Identification of Cylindrical Bodies with Free Convection and Peltier Elements as Sources for Active Heating. MMAR 2018: 424-429 - [c10]Julia Kersten, Andreas Rauh, Harald Aschemann:
State-Space Transformations of Uncertain Systems with Purely Real and Conjugate-Complex Eigenvalues into a Cooperative Form. MMAR 2018: 797-802 - 2017
- [c9]Julia Kersten, Andreas Rauh, Harald Aschemann:
Interval methods for the implementation and verification of robust gain scheduling controllers. MMAR 2017: 791-796 - 2016
- [j3]Andreas Rauh, Luise Senkel, Julia Kersten, Harald Aschemann:
Reliable control of high-temperature fuel cell systems using interval-based sliding mode techniques. IMA J. Math. Control. Inf. 33(2): 457-484 (2016) - [c8]Julia Kersten, Harald Aschemann:
LMI approaches for a robust control of a wind turbine with a hydrostatic transmission. ECC 2016: 1475-1480 - [c7]Harald Aschemann, Julia Kersten:
Control and robust tower oscillation damping for a wind turbine equipped with a hydrostatic drive train and a synchronous generator. MMAR 2016: 1051-1056 - 2015
- [c6]Harald Aschemann, Julia Kersten:
Active tower damping for an innovative wind turbine with a hydrostatic transmission. IECON 2015: 3314-3319 - [c5]Andreas Rauh, Julia Kersten, Harald Aschemann:
Experimental validation of LMI approaches for robust control design of a spatially three-dimensional heat transfer process. MMAR 2015: 11-16 - [c4]Harald Aschemann, Julia Kersten:
Observer-based decentralised control of a wind turbine with a hydrostatic transmission. MMAR 2015: 868-873 - 2014
- [c3]Julia Kersten, Andreas Rauh, Harald Aschemann:
Finite element modeling for heat transfer processes using the method of integro-differential relations with applications in control engineering. MMAR 2014: 606-611 - 2013
- [j2]Andreas Rauh, Luise Senkel, Julia Kersten, Harald Aschemann:
Interval Methods for Sensitivity-Based Model-Predictive Control of Solid Oxide Fuel Cell Systems. Reliab. Comput. 19(4): 361-384 (2013) - [c2]Andreas Rauh, Luise Senkel, Julia Kersten, Harald Aschemann:
Verified Stability Analysis for Interval-Based Sliding Mode and Predictive Control Procedures with Applications to High-Temperature Fuel Cell Systems. NOLCOS 2013: 570-575 - 2012
- [j1]Andreas Rauh, Julia Kersten, Ekaterina Auer, Harald Aschemann:
Sensitivity-based feedforward and feedback control for uncertain systems. Computing 94(2-4): 357-367 (2012) - [c1]Andreas Rauh, Julia Kersten, Harald Aschemann:
Modeling, simulation and control for optimized operating strategies of combustion engine-based power trains. MMAR 2012: 102-107
Coauthor Index
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