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ORCIDJohannes Schiffer
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2020 – today
- 2024
[j24]Ismael Jaramillo-Cajica, Johannes Schiffer:
A dwell-time approach for decentralized grid-aware operation of islanded DC microgrids. Autom. 160: 111461 (2024)- [j23]Riya Mathew, Juan G. Rueda-Escobedo, Johannes Schiffer:
Robust design of phase-locked loops in grid-connected power converters. Eur. J. Control 80: 101055 (2024) - [c36]Wasif H. Syed, Juan E. Machado, Johannes Schiffer:
Distributed Adaptive Control for a DC Power Distribution System of a Series-Hybrid-Electric Propulsion System of a Commuter Aircraft. ACC 2024: 2598-2603 - [c35]Oscar Texis-Loaiza, Eric William Zurita-Bustamante, Johannes Schiffer:
A BL-Homogeneous Observer for Inter-Turn Short-Circuit Fault Detection in PMSMs. CCTA 2024: 248-253 - [c34]Ulrike Herrmann, Anton Plietzsch
, Max Rose, Hannes Gernandt, Johannes Schiffer:
A Predictive Operation Management Scheme for Hydrogen Networks based on the Method of Characteristics. ECC 2024: 1084-1089 - [c33]Max Rose, Hannes Gernandt, Juan E. Machado, Johannes Schiffer:
Model Predictive Control of District Heating Grids Using Stabilizing Terminal Ingredients. ECC 2024: 1090-1096 - [i15]Max Rose, Hannes Gernandt, Juan E. Machado, Johannes Schiffer:
Model Predictive Control of District Heating Grids Using Stabilizing Terminal Ingredients. CoRR abs/2404.01820 (2024) - [i14]M. Nicolai L. Lorenz-Meyer, Hans Würfel, Johannes Schiffer:
Consensus + Innovations Approach for Online Distributed Multi-Area Inertia Estimation. CoRR abs/2404.19569 (2024) - [i13]Anna Büttner, Hans Würfel, Sebastian Liemann, Johannes Schiffer, Frank Hellmann:
Complex-Phase, Data-Driven Identification of Grid-Forming Inverter Dynamics. CoRR abs/2409.17132 (2024) - [i12]Alexey A. Bobtsov, Romeo Ortega, M. Nicolai L. Lorenz-Meyer, Johannes Schiffer:
State Observer for the Fourth-order Model of a Salient Pole Synchronous Generator with Stator Losses: Known and Partially Unknown Input Cases. CoRR abs/2410.04854 (2024) - 2023
- [j22]Juan G. Rueda-Escobedo, René Metzkow, Johannes Schiffer:
Robust current control of IPMSM drives under uncertain and varying inductances. Autom. 152: 110998 (2023) - [j21]Johannes Schiffer, Denis V. Efimov:
Strong and Weak Leonov Functions for Global Boundedness of State Periodic Systems. IEEE Trans. Autom. Control. 68(12): 7958-7965 (2023) - [c32]Angel Mercado-Uribe, Jesús Mendoza-Ávila, Denis V. Efimov, Johannes Schiffer:
A Control Leonov Function Guaranteeing Global ISS of Two Coupled Synchronverters. CDC 2023: 4580-4585 - [c31]Jesus Mendoza-Avila, Denis V. Efimov, Angel Mercado-Uribe, Johannes Schiffer:
Design of Controls for Boundedness of Trajectories of Multistable State Periodic Systems. CDC 2023: 6647-6652 - [c30]Ismael Jaramillo-Cajica, Angel Mercado-Uribe, Johannes Schiffer:
Coordinated Control of Load Tap Changer Transformers for Voltage Regulation and Voltage Hunting Prevention: A Switched Systems Approach. CDC 2023: 8553-8558 - [c29]Eric William Zurita-Bustamante, Juan G. Rueda-Escobedo, Johannes Schiffer:
Passivity-Based Conditions for Asymptotic Stability of Speed Control for Three-Phase and Dual Three-Phase Permanent Magnet Synchronous Motors. CDC 2023: 8882-8887 - 2022
- [j20]Ajay Krishna, Ismael Jaramillo-Cajica, Sabine Auer, Johannes Schiffer:
A power-hardware-in-the-loop testbed for intelligent operation and control of low-inertia power systems. Autom. 70(12): 1084-1095 (2022) - [j19]Handong Bai, Hongwei Zhang, He Cai, Johannes Schiffer:
Voltage regulation and current sharing for multi-bus DC microgrids: A compromised design approach. Autom. 142: 110340 (2022) - [j18]Alexey A. Bobtsov, Romeo Ortega, Nikolay A. Nikolaev, M. Nicolai L. Lorenz-Meyer, Johannes Schiffer:
State Observation of Power Systems Equipped With Phasor Measurement Units: The Case of Fourth-Order Flux-Decay Model. IEEE Trans. Autom. Control. 67(4): 2123-2130 (2022) - [j17]Juan G. Rueda-Escobedo, Emilia Fridman, Johannes Schiffer:
Data-Driven Control for Linear Discrete-Time Delay Systems. IEEE Trans. Autom. Control. 67(7): 3321-3336 (2022) - [c28]Juan G. Rueda-Escobedo, Jaime A. Moreno, Johannes Schiffer:
Design and Tuning of the Super-Twisting-Based Synchronous Reference Frame Phase-Locked-Loop. CDC 2022: 4300-4306 - [c27]Jesus Mendoza-Avila, Denis V. Efimov, Angel Mercado-Uribe, Johannes Schiffer:
On Relaxed Conditions of Integral ISS for Multistable Periodic Systems. CDC 2022: 7072-7077 - [c26]Ismael Jaramillo-Cajica, Johannes Schiffer:
A Dwell-Time Approach for Grid-Aware Operation of a Distributed Generator in an Islanded DC Microgrid. ECC 2022: 1079-1084 - [c25]Juan G. Rueda-Escobedo, Jaime A. Moreno, Johannes Schiffer:
$\mathcal{L}_{2}$-Gain Tuning for the Gradient Descent Algorithm in the Presence of Disturbances. ECC 2022: 1610-1616 - [i11]M. Nicolai L. Lorenz-Meyer, René Suchantke, Johannes Schiffer:
Dynamic state and parameter estimation in multi-machine power systems - Experimental demonstration using real-world PMU-measurements. CoRR abs/2203.14623 (2022) - [i10]M. Nicolai L. Lorenz-Meyer, René Suchantke, Johannes Schiffer:
PMU-based dynamic state and parameter estimation for dynamic security assessment in power systems - Ultimate boundedness in the presence of measurement noise. CoRR abs/2208.14511 (2022) - [i9]Max Rose, Christian A. Hans, Johannes Schiffer:
A Predictive Operation Controller for an Electro-Thermal Microgrid Utilizing Variable Flow Temperatures. CoRR abs/2212.07078 (2022) - 2021
- [j16]Romeo Ortega, Alexey A. Bobtsov, Nikolay A. Nikolaev, Johannes Schiffer, Denis Dochain:
Generalized parameter estimation-based observers: Application to power systems and chemical-biological reactors. Autom. 129: 109635 (2021) - [j15]Sultan M. Alghamdi, Johannes Schiffer, Emilia Fridman:
Synthesizing Sparse and Delay-Robust Distributed Secondary Frequency Controllers for Microgrids. IEEE Trans. Control. Syst. Technol. 29(2): 691-703 (2021) - 2020
- [j14]Ajay Krishna, Johannes Schiffer, Jörg Raisch:
Distributed secondary frequency control in microgrids: Robustness and steady-state performance in the presence of clock drifts. Eur. J. Control 51: 135-145 (2020) - [j13]Alexey S. Matveev, Juan E. Machado, Romeo Ortega, Johannes Schiffer, Anton A. Pyrkin:
A Tool for Analysis of Existence of Equilibria and Voltage Stability in Power Systems With Constant Power Loads. IEEE Trans. Autom. Control. 65(11): 4726-4740 (2020) - [c24]Juan E. Machado, Johannes Schiffer:
A passivity-inspired design of power-voltage droop controllers for DC microgrids with electrical network dynamics. CDC 2020: 3060-3065 - [c23]Michael Rojas, Juan G. Rueda-Escobedo, Gerardo Espinosa-Pérez, Johannes Schiffer:
Observer-Based Excitation Control for Transient Stabilization of the Single Machine Infinite Bus System. CDC 2020: 3377-3382 - [c22]Juan G. Rueda-Escobedo, Johannes Schiffer:
Data-Driven Internal Model Control of Second-Order Discrete Volterra Systems. CDC 2020: 4572-4579 - [c21]Johannes Schiffer:
Synthesizing Delay-Robust Controllers for Low-Inertia Power Systems. ECC 2020: 331 - [i8]M. Nicolai L. Lorenz-Meyer, Alexey A. Bobtsov, Romeo Ortega, Nikolay A. Nikolaev, Johannes Schiffer:
PMU-Based Decentralized Mixed Algebraic and Dynamic State Observation in Multi-Machine Power Systems. CoRR abs/2003.13996 (2020) - [i7]Juan G. Rueda-Escobedo, Johannes Schiffer:
Data-Driven Internal Model Control of Second-Order Discrete Volterra Systems. CoRR abs/2003.14158 (2020) - [i6]Alexey A. Bobtsov, Romeo Ortega, Nikolay A. Nikolaev, Johannes Schiffer, M. Nicolai L. Lorenz-Meyer:
State Observation of Power Systems Equipped with Phasor Measurement Units: The Case of Fourth Order Flux-Decay Model. CoRR abs/2004.06903 (2020) - [i5]Alexey A. Bobtsov, Romeo Ortega, Nikolay A. Nikolaev, Johannes Schiffer:
A Globally Convergent State Observer for Multimachine Power Systems with Lossy Lines. CoRR abs/2005.01482 (2020)
2010 – 2019
- 2019
- [j12]Johannes Schiffer, Denis V. Efimov, Romeo Ortega:
Global synchronization analysis of droop-controlled microgrids - A multivariable cell structure approach. Autom. 109 (2019) - [j11]Denis V. Efimov, Johannes Schiffer:
On Boundedness of Solutions of State Periodic Systems: A Multivariable Cell Structure Approach. IEEE Trans. Autom. Control. 64(10): 4094-4104 (2019) - [c20]Ajay Krishna, Johannes Schiffer, Nima Monshizadeh, Jörg Raisch:
A consensus-based voltage control for reactive power sharing and PCC voltage regulation in microgrids with parallel-connected inverters. ECC 2019: 542-547 - [c19]Juan G. Rueda-Escobedo, Jaime A. Moreno, Johannes Schiffer:
Finite-Time Estimation of Time-Varying Frequency Signals in Low-Inertia Power Systems. ECC 2019: 2108-2114 - 2018
- [j10]Daniele Zonetti, Romeo Ortega, Johannes Schiffer:
A Tool for Stability and Power-Sharing Analysis of a Generalized Class of Droop Controllers for High-Voltage Direct-Current Transmission Systems. IEEE Trans. Control. Netw. Syst. 5(3): 1110-1119 (2018) - [c18]Sultan M. Alghamdi, Johannes Schiffer, Emilia Fridman:
Conditions for Delay-Robust Consensus-Based Frequency Control in Power Systems with Second-Order Turbine-Governor Dynamics. CDC 2018: 786-793 - [c17]Johannes Schiffer, Denis V. Efimov, Romeo Ortega:
Almost Global Synchronization in Radial Multi-Machine Power Systems. CDC 2018: 800-805 - [c16]Sultan M. Alghamdi, Johannes Schiffer, Emilia Fridman:
Distributed Secondary Frequency Control Design for Microgrids: Trading Off L2-Gain Performance and Communication Efforts under Time-Varying Delays. ECC 2018: 758-763 - [c15]Denis V. Efimov, Johannes Schiffer:
A new criterion for boundedness of solutions for a class of periodic systems. ECC 2018: 1642-1647 - [c14]Ajay Krishna, Johannes Schiffer, Jörg Raisch:
A Consensus-Based Control Law for Accurate Frequency Restoration and Power Sharing in Microgrids in the Presence of Clock Drifts. ECC 2018: 2575-2580 - [i4]Alexey S. Matveev, Juan E. Machado, Romeo Ortega, Johannes Schiffer, Anton A. Pyrkin:
On the Existence and Long-Term Stability of Voltage Equilibria in Power Systems with Constant Power Loads. CoRR abs/1809.08127 (2018) - [i3]Johannes Schiffer, Petros Aristidou, Romeo Ortega:
Online Estimation of Power System Inertia Using Dynamic Regressor Extension and Mixing. CoRR abs/1812.00201 (2018) - 2017
- [j9]Johannes Schiffer, Florian Dörfler, Emilia Fridman:
Robustness of distributed averaging control in power systems: Time delays & dynamic communication topology. Autom. 80: 261-271 (2017) - [j8]Denis V. Efimov, Johannes Schiffer, Nikita E. Barabanov, Romeo Ortega:
A relaxed characterization of ISS for periodic systems with multiple invariant sets. Eur. J. Control 37: 1-7 (2017) - [j7]Nikita E. Barabanov, Johannes Schiffer, Romeo Ortega, Denis V. Efimov:
Conditions for Almost Global Attractivity of a Synchronous Generator Connected to an Infinite Bus. IEEE Trans. Autom. Control. 62(10): 4905-4916 (2017) - [j6]Johannes Schiffer, Christian A. Hans, Thomas Kral, Romeo Ortega, Jörg Raisch:
Modeling, Analysis, and Experimental Validation of Clock Drift Effects in Low-Inertia Power Systems. IEEE Trans. Ind. Electron. 64(7): 5942-5951 (2017) - [c13]Valentin G. Ivanov, Michael Ruderman, Johannes Schiffer, Martin Horn:
Interdisciplinary design methodology for systems of mechatronic systems focus on highly dynamic environmental applications. IECON 2017: 4062-4067 - [c12]Ajay Krishna, Christian A. Hans, Johannes Schiffer, Jörg Raisch, Thomas Kral:
Steady state evaluation of distributed secondary frequency control strategies for microgrids in the presence of clock drifts. MED 2017: 508-515 - 2016
- [j5]Johannes Schiffer, Emilia Fridman, Romeo Ortega, Jörg Raisch:
Stability of a class of delayed port-Hamiltonian systems with application to microgrids with distributed rotational and electronic generation. Autom. 74: 71-79 (2016) - [j4]Johannes Schiffer, Daniele Zonetti, Romeo Ortega, Aleksandar M. Stankovic, Tevfik Sezi, Jörg Raisch:
A survey on modeling of microgrids - From fundamental physics to phasors and voltage sources. Autom. 74: 135-150 (2016) - [j3]Denis V. Efimov, Johannes Schiffer, Romeo Ortega:
Robustness of delayed multistable systems with application to droop-controlled inverter-based microgrids. Int. J. Control 89(5): 909-918 (2016) - [j2]Johannes Schiffer, Thomas Seel, Jörg Raisch, Tevfik Sezi:
Voltage Stability and Reactive Power Sharing in Inverter-Based Microgrids With Consensus-Based Distributed Voltage Control. IEEE Trans. Control. Syst. Technol. 24(1): 96-109 (2016) - [c11]Daniele Zonetti, Romeo Ortega, Johannes Schiffer:
A tool for power flow analysis of a generalized class of droop controllers for high-voltage direct-current transmission systems. CDC 2016: 1564-1569 - [c10]Claudio De Persis, Nima Monshizadeh, Johannes Schiffer, Florian Dörfler:
A Lyapunov approach to control of microgrids with a network-preserved differential-algebraic model. CDC 2016: 2595-2600 - [c9]Nikita E. Barabanov, Johannes Schiffer, Romeo Ortega, Denis V. Efimov:
Almost global attractivity of a synchronous generator connected to an infinite bus. CDC 2016: 4130-4135 - [c8]Johannes Schiffer, Florian Dörfler:
On stability of a distributed averaging PI frequency and active power controlled differential-algebraic power system model. ECC 2016: 1487-1492 - [i2]Daniele Zonetti, Romeo Ortega, Johannes Schiffer:
A tool for stability and power sharing analysis of a generalized class of droop controllers for high-voltage direct-current transmission systems. CoRR abs/1609.03149 (2016) - 2015
- [c7]Johannes Schiffer, Romeo Ortega, Christian A. Hans, Jörg Raisch:
Droop-controlled inverter-based microgrids are robust to clock drifts. ACC 2015: 2341-2346 - [c6]Denis V. Efimov, Romeo Ortega, Johannes Schiffer:
ISS of multistable systems with delays: Application to droop-controlled inverter-based microgrids. ACC 2015: 4664-4669 - [c5]Johannes Schiffer, Emilia Fridman, Romeo Ortega:
Stability of a class of delayed port-Hamiltonian systems with application to droop-controlled microgrids. CDC 2015: 6391-6396 - [i1]Johannes Schiffer, Daniele Zonetti, Romeo Ortega, Aleksandar M. Stankovic, Tevfik Sezi, Jörg Raisch:
Modeling of microgrids - from fundamental physics to phasors and voltage sources. CoRR abs/1505.00136 (2015) - 2014
- [j1]Johannes Schiffer, Romeo Ortega, Alessandro Astolfi, Jörg Raisch, Tevfik Sezi:
Conditions for stability of droop-controlled inverter-based microgrids. Autom. 50(10): 2457-2469 (2014) - [c4]Johannes Schiffer, Thomas Seel, Jörg Raisch, Tevfik Sezi:
A consensus-based distributed voltage control for reactive power sharing in microgrids. ECC 2014: 1299-1305 - 2013
- [c3]Johannes Schiffer, Darina Goldin, Jörg Raisch, Tevfik Sezi:
Synchronization of droop-controlled microgrids with distributed rotational and electronic generation. CDC 2013: 2334-2339 - 2012
- [c2]Johannes Schiffer, Adolfo Anta Martinez, Truong Duc Trung, Jörg Raisch, Tevfik Sezi:
On power sharing and stability in autonomous inverter-based microgrids. CDC 2012: 1105-1110 - 2010
- [c1]Sven Gestegard Robertz, Lorenz Halt, Sameer Kelkar, Klas Nilsson, Anders Robertsson, Dominique Schar, Johannes Schiffer:
Precise robot motions using dual motor control. ICRA 2010: 5613-5620
Coauthor Index
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