Dr. Ing.

Michael Böhm

Wissenschaftlicher Mitarbeiter
Institut für Systemdynamik

Kontakt

+49 711 685-66291
E-Mail

Waldburgstr. 19
70563 Stuttgart
Deutschland

Fachgebiet

Beteiligt an Teilprojekten, inklusive Position:

A06 Bautechnische Integration von aktiven Elementen in die Gebäudestruktur,
Bearbeiter

B04 Steuerungs- und Regelungskonzepte für adaptive Bauwerke, Bearbeiter

Publikationen

2020
1. M. Böhm et al., “Input modeling for active structural elements – extending the established FE-Workflow for modeling of adaptive structures,” 2020.
  - BibTeX
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  @inproceedings{bohm_input_2020, author = {Böhm, Michael and Steffen, Simon and Gade, Jan and Geiger, Florian and Sobek, Werner and Bischoff, Manfred and Sawodny, Oliver}, booktitle = {{IEEE} {Int}. {Conf}. on {Advanced} {Intelligent} {Mechatronics}}, title = {Input modeling for active structural elements – extending the established {FE}-{Workflow} for modeling of adaptive structures}, year = 2020 }
2. M. Böhm et al., “Modellierung aktiver Strukturelemente als Erweiterung zum klassischen Workflow der FE-Analyse,” 2020.
  - BibTeX
  BibTeX
  @inproceedings{bohm_modellierung_2020, author = {Böhm, Michael and Steffen, Simon and Gade, Jan and Geiger, Florian and Sobek, Werner and Bischoff, Manfred and Sawodny, Oliver}, booktitle = {Tagungsband zur {Fachtagung} {Baustatik}-{Baupraxis}}, title = {Modellierung aktiver {Strukturelemente} als {Erweiterung} zum klassischen {Workflow} der {FE}-{Analyse}}, year = 2020 }
3. M. Oei, J. Guenther, M. Böhm, S. Park, and O. Sawodny, “A Bilinear Approach to Model Predictive Control for Thermal Conditioning of Adaptive Buildings,” 2020.
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  @inproceedings{oei_bilinear_2020, annote = {(akzeptiert)}, author = {Oei, Marius and Guenther, Janine and Böhm, Michael and Park, Sumee and Sawodny, Oliver}, booktitle = {Proc. of the {IFAC} {World} {Congress}}, title = {A {Bilinear} {Approach} to {Model} {Predictive} {Control} for {Thermal} {Conditioning} of {Adaptive} {Buildings}}, year = 2020 }
4. S. Steffen, M. Böhm, W. Haase, O. Sawodny, and W. Sobek, “Masseneinsparungspotential beim Einsatz adaptiver Strukturelemente in Hochhaustragwerken,” 2020.
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  @inproceedings{steffen_masseneinsparungspotential_2020, author = {Steffen, Simon and Böhm, Michael and Haase, Walter and Sawodny, Oliver and Sobek, Werner}, booktitle = {Tagungsband zur {Fachtagung} {Baustatik}-{Baupraxis}}, title = {Masseneinsparungspotential beim {Einsatz} adaptiver {Strukturelemente} in {Hochhaustragwerken}}, year = 2020 }
5. J. L. Wagner et al., “Optimal Static Load Compensation with Fault Tolerance in Nonlinear Adaptive Structures under Input and State Constraints,” Frontiers in Built Environment, 2020.
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  @article{wagner_optimal_2020, annote = {(akzeptiert)}, author = {Wagner, Julia L. and Gienger, Andreas and Stein, Charlotte and Arnold, Philipp and Tarín, Cristina and Sawodny, Oliver and Böhm, Michael}, journal = {Frontiers in Built Environment}, title = {Optimal {Static} {Load} {Compensation} with {Fault} {Tolerance} in {Nonlinear} {Adaptive} {Structures} under {Input} and {State} {Constraints}}, year = 2020 }
6. J. L. Wagner, M. Bohm, and O. Sawodny, “Decentralized structural control using Craig-Bampton reduction and local controller design,” in 2020 IEEE International Conference on Industrial Technology (ICIT), Buenos Aires, Argentina, 2020, pp. 41--46, doi: 10.1109/ICIT45562.2020.9067158.
  - BibTeX
  - Link
  BibTeX
  @inproceedings{wagner_decentralized_2020, author = {Wagner, Julia L. and Bohm, Michael and Sawodny, Oliver}, booktitle = {2020 {IEEE} International Conference on Industrial Technology ({ICIT})}, doi = {10.1109/ICIT45562.2020.9067158}, eventtitle = {2020 {IEEE} International Conference on Industrial Technology ({ICIT})}, isbn = {978-1-72815-754-2}, location = {Buenos Aires, Argentina}, pages = {41--46}, publisher = {{IEEE}}, title = {Decentralized structural control using Craig-Bampton reduction and local controller design}, url = {https://ieeexplore.ieee.org/document/9067158/}, urldate = {2020-05-08}, year = 2020 }
  Link
  https://ieeexplore.ieee.org/document/9067158/
7. J. L. Wagner, M. Böhm, and O. Sawodny, “Decentralized Control Design for Adaptive Structures with Tension-only Elements,” 2020.
  - BibTeX
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  @inproceedings{wagner_decentralized_2020, annote = {(akzeptiert)}, author = {Wagner, Julia Laura and Böhm, Michael and Sawodny, Oliver}, booktitle = {Proc. of the {IFAC} {World} {Congress}}, title = {Decentralized {Control} {Design} for {Adaptive} {Structures} with {Tension}-only {Elements}}, year = 2020 }
8. A. Warsewa, J. L. Wagner, M. Böhm, O. Sawodny, and C. Tarín, “Networked Decentralized Control for Adaptive Structures,” Journal of Communications, 2020.
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  @article{warsewa_networked_2020, author = {Warsewa, Alexander and Wagner, Julia Laura and Böhm, Michael and Sawodny, Oliver and Tarín, Cristina}, journal = {Journal of Communications}, title = {Networked {Decentralized} {Control} for {Adaptive} {Structures}}, year = 2020 }
9. A. Warsewa et al., “Self-tuning state estimation for adaptive truss structures using strain gauges and camera-based position measurements,” Mechanical Systems and Signal Processing, 2020, doi: 10.1016/j.ymssp.2020.106822.
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  @article{warsewa_self-tuning_2020, author = {Warsewa, Alexander and Böhm, Michael and Guerra, Flavio and Wagner, Julia L. and Haist, Tobias and Tarín, Cristina and Sawodny, Oliver}, doi = {10.1016/j.ymssp.2020.106822}, journal = {Mechanical Systems and Signal Processing}, title = {Self-tuning state estimation for adaptive truss structures using strain gauges and camera-based position measurements}, year = 2020 }
10. A. Warsewa, J. L. Wagner, M. Böhm, O. Sawodny, and C. Tarìn, “Networked Decentralized Control for Adaptive Structures,” 2020.
  - BibTeX
  BibTeX
  @inproceedings{warsewa_networked_2020, author = {Warsewa, Alexander and Wagner, Julia Laura and Böhm, Michael and Sawodny, Oliver and Tarìn, Cristina}, booktitle = {The 5th {International} {Conference} on {Control} and {Robotics} {Engineering}}, note = {B02, B03}, title = {Networked {Decentralized} {Control} for {Adaptive} {Structures}}, year = 2020 }
2019
1. M. Böhm, J. Wagner, S. Steffen, W. Sobek, and O. Sawodny, “Homogenizability of Element Utilization in Adaptive Structures,” 2019.
  - BibTeX
  BibTeX
  @inproceedings{bohm_homogenizability_2019, author = {Böhm, Michael and Wagner, Julia and Steffen, Simon and Sobek, Werner and Sawodny, Oliver}, booktitle = {{IEEE} {Int}. {Conf}. on {Automation} {Science} and {Engineering} ({CASE})}, title = {Homogenizability of {Element} {Utilization} in {Adaptive} {Structures}}, year = 2019 }
2. B. Fröhlich, J. Wagner, M. Böhm, O. Sawodny, and P. Eberhard, “Combining Optimal Control and Shape Optimization for an Adaptive Engineering Structure with Parameterized Reduced Order Finite Element Models,” 2019.
  - BibTeX
  BibTeX
  @inproceedings{frohlich_combining_2019, author = {Fröhlich, Benjamin and Wagner, Julia and Böhm, Michael and Sawodny, Oliver and Eberhard, Peter}, booktitle = {Proceedings of the {ECCOMAS} {Thematic} {Conference} on {Smart} {Structures} and {Materials} ({SMART2019}), {Paris}, {France}}, note = {B01, A06}, title = {Combining {Optimal} {Control} and {Shape} {Optimization} for an {Adaptive} {Engineering} {Structure} with {Parameterized} {Reduced} {Order} {Finite} {Element} {Models}}, year = 2019 }
3. B. Fröhlich, J. L. Wagner, M. Böhm, O. Sawodny, and P. Eberhard, “Combining Optimal Control and Shape Optimization for an Adaptive Engineering Structure with Parametrized Reduced Order Finite Element Models,” 2019.
  - BibTeX
  BibTeX
  @inproceedings{frohlich_combining_2019, author = {Fröhlich, Benjamin and Wagner, Julia Laura and Böhm, Michael and Sawodny, Oliver and Eberhard, Peter}, booktitle = {{ECCOMAS} {Conf}. on {Smart} {Structures} and {Materials}}, title = {Combining {Optimal} {Control} and {Shape} {Optimization} for an {Adaptive} {Engineering} {Structure} with {Parametrized} {Reduced} {Order} {Finite} {Element} {Models}}, year = 2019 }
4. J. L. Wagner, M. Böhm, and O. Sawodny, “Nonlinear Modeling and control of Tension-only Elements in Adaptive Structures,” 2019.
  - BibTeX
  BibTeX
  @inproceedings{wagner_nonlinear_2019, author = {Wagner, Julia Laura and Böhm, Michael and Sawodny, Oliver}, booktitle = {{ECCOMAS} {Thematic} {Conf}. on {Smart} {Structures} and {Materials}}, title = {Nonlinear {Modeling} and control of {Tension}-only {Elements} in {Adaptive} {Structures}}, year = 2019 }
5. J. L. Wagner, K. Schmidt, M. Böhm, and O. Sawodny, “Optimal Actuator Placement and Static Load Compensation for Euler-Bernoulli Beams with Spatially Distributed Inputs,” 2019.
  - BibTeX
  BibTeX
  @inproceedings{wagner_optimal_2019, author = {Wagner, Julia Laura and Schmidt, Kevin and Böhm, Michael and Sawodny, Oliver}, booktitle = {{IFAC} {Symposium} on {Mechatronic} {Systems}}, title = {Optimal {Actuator} {Placement} and {Static} {Load} {Compensation} for {Euler}-{Bernoulli} {Beams} with {Spatially} {Distributed} {Inputs}}, year = 2019 }
6. A. Warsewa, M. Böhm, P. Rapp, O. Sawodny, and C. Tarín, “Decentralized and Distributed Observer Design for Large-Scale Structures using Dynamic Condensation,” 2019.
  - BibTeX
  BibTeX
  @inproceedings{warsewa_decentralized_2019, author = {Warsewa, Alexander and Böhm, Michael and Rapp, Philipp and Sawodny, Oliver and Tarín, Cristina}, booktitle = {{IEEE} {Int}. {Conf}. on {Automation} {Science} and {Engineering} ({CASE})}, title = {Decentralized and {Distributed} {Observer} {Design} for {Large}-{Scale} {Structures} using {Dynamic} {Condensation}}, year = 2019 }
7. A. Warsewa, M. Böhm, P. Rapp, O. Sawodny, and C. Tarın, “Decentralized and Distributed Observer Design for Large-Scale Structures using Dynamic Condensation,” in 2019 IEEE 15th International Conference on Automation Science and Engineering (CASE), 2019, pp. 1256--1262.
  - BibTeX
  BibTeX
  @inproceedings{warsewa_decentralized_2019, author = {Warsewa, Alexander and Böhm, Michael and Rapp, Philipp and Sawodny, Oliver and Tarın, Cristina}, booktitle = {2019 {IEEE} 15th {International} {Conference} on {Automation} {Science} and {Engineering} ({CASE})}, note = {B02, A06}, pages = {1256--1262}, publisher = {IEEE}, title = {Decentralized and {Distributed} {Observer} {Design} for {Large}-{Scale} {Structures} using {Dynamic} {Condensation}}, year = 2019 }
8. S. Weidner et al., “The integration of actuation concepts and adaptive elements into an experimental high-rise building,” 2019.
  - BibTeX
  BibTeX
  @inproceedings{weidner_integration_2019, author = {Weidner, Stefanie and Steffen, Simon and Haase, Walter and Sobek, Werner and Honold, Clemena and Burghardt, Timon and Binz, Hansgeorg and Böhm, Michael and Wagner, Julia and Sawodny, Oliver}, booktitle = {Int. {Conf}. on {Structural} {Engineering}, {Mechanics} and {Computation} ({SEMC})}, title = {The integration of actuation concepts and adaptive elements into an experimental high-rise building}, year = 2019 }
2018
1. M. Böhm and O. Sawodny, “Towards integration of active elements into finite element models of adaptive structures,” 2018.
  - BibTeX
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  @inproceedings{bohm_towards_2018, abstract = {Adaptive structures present a completely new approach in structural engineering. Actuators are included betweentwo nodes each to control the structure’s state. Different actuation principles are possible, some unknown yet.Examples for state of the art actuators include hydraulic cylinders, pneumatic actuators and even electric motors.The control input has to be modeled depending on the actuation principle. While passive structures are commonlystudied using FE-analysis, where mass and stiffness matrices are calculated in the usual way that is largelyautomated, the input has to be included manually. Some FE-tools offer the possibility to include simple actuators,such as the LINK11 element in ANSYS. However, it is not possible to define forces depending on the actual state ofthe structure, i.e. including the control algorithm in the analysis. Overall, this only allows for a limited analysis ofadaptive structures with active structural elements. Commonly, when working with adaptive structures, otheranalysis tools have to be used to manually integrate the active elements in the analysis afterwards. As a first steptowards a better integration of these elements and towards a more user-friendly and seamless analysis of adaptivestructures, we present here a methodology to calculate an additional input matrix automatically for active elements,simplifying the subsequent analysis. In order to do this, we present possible actuation principles and compare themwith respect to their suitability for different tasks, revealing fundamental pros and cons leading to different usecases for each principle. Specifically, we will study parallel actuation and serial actuation. The former meansintegrating the actuator in parallel to an existing passive support element, while the latter describes anin-series-integration of the actuator into a passive support element. Combinations of these principles are alsopossible and considered. As a third actuation principle, we briefly discuss changing a structural element’s stiffness,as well.}, author = {Böhm, Michael and Sawodny, Oliver}, booktitle = {13th {World} {Congress} on {Computational} {Mechanics} ({WCCM}), {July} 22-27, 2018, {New} {York}, {NY}, {USA}}, title = {Towards integration of active elements into finite element models of adaptive structures}, year = 2018 }
2. J. Wagner et al., “On steady-state disturbance compensability for actuator placement in adaptive structures,” at - Automatisierungstechnik, 2018.
  - BibTeX
  BibTeX
  @article{wagner_steady-state_2018, author = {Wagner, Julia and Gade, Jan and Geiger, Florian and Heidingsfeld, Michael and Böhm, Michael and Scheven, Malte von and Bischoff, Manfred and Sawodny, Oliver}, journal = {at - Automatisierungstechnik}, title = {On steady-state disturbance compensability for actuator placement in adaptive structures}, year = 2018 }
3. J. L. Wagner, M. Böhm, and O. Sawodny, “Model-based control of integrated fluidic actuators for adaptive structures,” 2018.
  - BibTeX
  BibTeX
  @inproceedings{wagner_model-based_2018, abstract = {Adaptive structures in structural engineering include sensors and actuators to influence the systems’ responseunder stationary and dynamic loads. The induced structural stresses and displacements can be compensated bystationary adaption and dynamic control [1]. To provide a high integration level of the active elements, a new kind offluidic actuator is developed. As proof of concept, a concrete beam is equipped with hydraulic pressure chamberswhich are arranged asymmetrical regarding the neutral axis. Thus the beam’s deflection can be changed actively toreduce load induced displacements and achieve a more homogeneous stress distribution. In this work, acontinuous model of the integrated fluidic actuator is formulated by means of a partial differential equation, basedon the Euler-Bernoulli beam theory. The right hand side of the equation is realized using spatial characteristics incombination with time-dependent inputs. For this actuator, a control law is derived based on the equations ofmotion with the aim of controlling the deflection curve or the boundary forces and torques. We show that thederived model can also be used to find optimal actuator configurations in terms of geometry and position of theintegrated pressure chambers [2]. Furthermore, both the controller design and actuator design problem can becombined in a holistic approach. The controller’s effectiveness and the systems performance are shown by meansof numerical results. [1] W: Sobek and P. Teuffel, “Adaptive systems in architecture and structural engineering,”Proceedings of SPIE, vol. 4330, 2001, pp. 36–45. [2] M. Heidingsfeld, P. Rapp, M. Böhm, and O. Sawodny,“Gramian-based actuator placement with spillover reduction for active damping of adaptive structures,”Proceedings of the 2017 IEEE/ASME International Conference on Advanced Intelligent Mechatronics (AIM 2017),2017.}, author = {Wagner, Julia Laura and Böhm, Michael and Sawodny, Oliver}, booktitle = {13th {World} {Congress} on {Computational} {Mechanics} ({WCCM}), {July} 22-27, 2018, {New} {York}, {NY}, {USA}}, title = {Model-based control of integrated fluidic actuators for adaptive structures}, year = 2018 }
4. S. Weidner et al., “The implementation of adaptive elements into an experimental high-rise building,” Steel Construction, 2018.
  - BibTeX
  BibTeX
  @article{weidner_implementation_2018, author = {Weidner, Stefanie and Kelleter, Christian and Sternberg, Paula and Haase, Walter and Geiger, Florian and Burghardt, Timon and Honold, Clemens and Wagner, Julia and Böhm, Michael and Bischoff, Manfred and Sawodny, Oliver and Binz, Hansgeorg}, journal = {Steel Construction}, title = {The implementation of adaptive elements into an experimental high-rise building}, year = 2018 }
2017
1. M. Heidingsfeld, P. Rapp, M. Böhm, and O. Sawodny, “Gramian-based Actuator Placement with Spillover Reduction for Active Damping of Adaptive Structures,” 2017.
  - BibTeX
  BibTeX
  @inproceedings{heidingsfeld_gramian-based_2017, author = {Heidingsfeld, Michael and Rapp, Philipp and Böhm, Michael and Sawodny, Oliver}, booktitle = {{IEEE} {Int}. {Conf}. on {Advanced} {Intelligent} {Mechatronics}}, title = {Gramian-based {Actuator} {Placement} with {Spillover} {Reduction} for {Active} {Damping} of {Adaptive} {Structures}}, year = 2017 }
2. P. Rapp, M. Heidingsfeld, M. Böhm, O. Sawodny, and C. Tarín, “Multimodal sensor fusion of inertial, strain, and distance data for state estimation of adaptive structures using particle filtering,” in 2017 IEEE International Conference on Advanced Intelligent Mechatronics (AIM), July 3-7, 2017, Munich, 2017, pp. 921--928, doi: 10.1109/AIM.2017.8014136.
  - BibTeX
  BibTeX
  @inproceedings{rapp_multimodal_2017, abstract = {This contribution depicts an evaluation of the potential of state estimation techniques in the context of adaptive structures. Those techniques are necessary, as the control algorithms acting on the actuators of the adaptive structures need to know the system's state, but not all states are accessible for measurement. We model and simulate a truss structure, which is equipped with inertial sensors, strain gauges, and an optical scanning system. The latter performs a point-wise scan of the truss structure's surface, which renders the measurement equation time-varying. The truss structure is excited by wind in the simulation. We implement a particle filter in order to perform the multimodal sensor fusion and state estimation. The particle filter shows good results for both an unexcited scenario as well as for a wind excitation scenario. We discuss the results as well as the implications for the active control of adaptive structures.}, author = {Rapp, Philipp and Heidingsfeld, Michael and Böhm, Michael and Sawodny, Oliver and Tarín, Cristina}, booktitle = {2017 {IEEE} {International} {Conference} on {Advanced} {Intelligent} {Mechatronics} ({AIM}), {July} 3-7, 2017, {Munich}}, doi = {10.1109/AIM.2017.8014136}, note = {B02, A06, B04, ISYS}, pages = {921--928}, title = {Multimodal sensor fusion of inertial, strain, and distance data for state estimation of adaptive structures using particle filtering}, year = 2017 }
3. J. Wagner, M. Heidingsfeld, M. Böhm, and O. Sawodny, “Gramian-based actuator placement for static load compensation in adaptive structures,” 2017.
  - BibTeX
  BibTeX
  @inproceedings{wagner_gramian-based_2017, abstract = {The compensation of static loads aims at reducing stresses or displacements by applying energy to anadaptive structure. The performance in static adaption significantly depends on the location of theactuators. We present a method for optimal actuator placement regarding static adaption using aGramian-based cost function. The method is demonstrated by means of a numerical model of anadaptive truss structure. Results indicate the method’s effectiveness to promote actuator placement.}, author = {Wagner, Julia and Heidingsfeld, Michael and Böhm, Michael and Sawodny, Oliver}, booktitle = {7th {GACM} {Colloquium} on {Computational} {Mechanics} for {Young} {Scientists} from {Academia} and {Industry}, {October} 11-13, 2017, {Stuttgart}}, title = {Gramian-based actuator placement for static load compensation in adaptive structures}, year = 2017 }

Akademische Ausbildung mit Abschluss

Oktober 2017, Promotion zum Dr.-Ing., Dissertationsthema: "Strategies for Disturbance Compensation at Large Telescopes"

Technische Kybernetik (2006 – 2011), Anwendungsfach „Automatisierung in der Energietechnik“ im Hauptstudium, Univ. Stuttgart, Abschluss: Dipl.-Ing.

Beruflicher Werdegang nach Studienabschluss

2011 – heute Wissenschaftlicher Mitarbeiter am Institut für Systemdynamik, Universität Stuttgart

Michael Böhm

Kontakt

Fachgebiet

Publikationen

2020

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2019

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2018

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2017

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Akademische Ausbildung mit Abschluss

Beruflicher Werdegang nach Studienabschluss