Scheiterer, Eduard Sebastian
Eduard S. Scheiterer, M. Sc.
Department of Mechanical Engineering
Institute of Applied Dynamics (LTD, Prof. Leyendecker)
Immerwahrstrasse 1
91058 Erlangen
Germany
- Phone number: +49 9131 85-61003
- Fax number: +49 9131 85-61011
- Email: eduard.s.scheiterer@fau.de
- Website: https://www.ltd.tf.fau.de/eduard-sebastian-scheiterer/
- 2011 -2016 B.Sc. in Mechanical Engineering, Friedrich-Alexander-Universität Erlangen-Nürnberg
- 2016 -2019 M.Sc. in Mechanical Engineering, Friedrich-Alexander-Universität Erlangen-Nürnberg
- 2019 – doctoral candidate, Institute of Applied Dynamics, Friedrich-Alexander-Universität Erlangen-Nürnberg
theses
2019
- :
Simulation of a prosthetic foot modelled by a predeformed geometrically exact beam (Master thesis, 2019)
reviewed journal publications
2024
- , , , , , , , , , , , , , , , , , :
AB0930 Towards Objective Measurement Of Spinal Mobility In Axial Spondyloarthritis – Benchmarking An Inertial Measurement Unit System With An Optical Measurement System
In: Annals of the Rheumatic Diseases (2024), p. 1774-1775
ISSN: 0003-4967
DOI: 10.1136/annrheumdis-2024-eular.5778 - , , , , , , , , , , , , , , , , , :
POS0494 Fear Of Movement Affects Range Of Motion During Repeated Basmi Exercises Assessed By State-Of-The-Art Motion Capture Techniques
In: Annals of the Rheumatic Diseases (2024), p. 936.3-937
ISSN: 0003-4967
DOI: 10.1136/annrheumdis-2024-eular.5298 - , , , :
Marker position uncertainty in joint angle analysis for normal human gait — A new error-modelling approach
In: Biomedical Signal Processing and Control 95 (2024), Article No.: 106474
ISSN: 1746-8094
DOI: 10.1016/j.bspc.2024.106474
2022
- , :
Correction to: Fuzzy forward dynamics of distinct gait phases with a prosthetic foot (Computational Mechanics, (2022), 10.1007/s00466-022-02167-w)
In: Computational Mechanics (2022)
ISSN: 0178-7675
DOI: 10.1007/s00466-022-02211-9 - , :
Fuzzy forward dynamics of distinct gait phases with a prosthetic foot
In: Computational Mechanics (2022)
ISSN: 0178-7675
DOI: 10.1007/s00466-022-02167-w
conferences and proceedings
2023
- , :
Propagation of epistemic uncertainty though a multi-layerd geometrically exact beam
conference, ICIAM 2023 -- 10th International Congress on Industrial and Applied Mathematics (Tokyo, 2023-08-20 - 2023-08-25)
2022
- , , :
Considering epistemic uncertainty in optical marker based joint angle calculation during human gait
conference, WCCM-APCOM 15th World Congress on Computational Mechanics & 8th Asian Pacific Congress on Computational Mechanics (Yokohama, online, 2022-07-31 - 2022-08-05)
2021
- , :
Dynamic analysis of prosthetic structures with polymorphic uncertainty
conference, SPP1886 annual meeting 2021 - , :
Forward dynamics simulation of a human leg model with a geometrically exact beam model as prosthetic foot
GAMM Annual Meeting (Kassel, 2021-03-15 - 2021-03-19)
In: Proc. Appl. Math. Mech. (PAMM) 2021
DOI: 10.1002/pamm.202100096 - , :
Fuzzy forward dynamics of a human leg with a prosthetic foot
conference, GAMM Annual Meeting (Kassel, 2021-03-15 - 2021-03-19) - , :
Predeformed geometrically exact beam model for a dynamic-response prosthesis
GAMM Annual Meeting
In: Proc. Appl. Math. Mech. (PAMM) 2021
DOI: 10.1002/pamm.202000152
2020
- , :
Dynamic analysis of prosthetic structures with polymorphic uncertainty
conference, SPP1886 phase 2 kickoff meeting - , :
Dynamic analysis of prosthetic structures with polymorphic uncertainty
conference, SPP1886 Annual Meeting 2020 (, 2020-10-26 - 2020-10-27)
2019
- , :
Modelling a prosthetic foot as a predeformed geometrically exact beam
conference, SPP1886 Annual Meeting (Hamburg, 2019-10-26 - 2019-10-27)
further publications
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Dynamic analysis of prosthetic structures with polymorphic uncertainty
(Third Party Funds Group – Sub project)
Overall project: Polymorphic uncertainty modelling for the numerical design of structures
Term: 2020-10-01 - 2023-09-30
Funding source: DFG-Einzelförderung / Sachbeihilfe (EIN-SBH)People with joint disorders or lower limb loss require a technical substitute that restores biomechanical function and body integrity. Prothetic structures not only need to fulfil their respective functional requirements (allowing a save and wide range of motion at low energy expenditure and without impairing the person's body) but also the appearance of the resulting motion (including aesthetic properties like natural and symmetric gait patterns) is of high relevance. Since measurement of in vivo joint motion and loading is complicated and the experimental testing of newly developed prostheses under real life conditions is very difficult (in particular for experiments concerning human movements with prostheses, there are hardly appropriate probands available), predictive simulation plays a major role. Biomechanical motion can be simulated as solution of an optimal control problem, with a physiologically motivated objective function. However, polymorphic sources of uncertainty are present resulting from the prostheses itself, the way a patient moves or the environment. The overarching goal of this project (phases I and II) is the development of models and structure preserving solution methods for biomechanical optimal control problems involving uncertainty to enable the reliable prediction of human motion with prostheses and their analysis. -
Dynamic analysis of prosthetic structures with polymorphic uncertainty
(Third Party Funds Group – Sub project)
Overall project: SPP 1886: Polymorphic uncertainty modelling for the numerical design of structures
Term: 2016-01-01 - 2020-09-30
Funding source: DFG / Schwerpunktprogramm (SPP)
URL: https://tu-dresden.de/bu/bauingenieurwesen/sdt/forschung/spp1886?set_language=enThe overarching goal of this project (phases I and II) is the development of models and structure preserving solution methods for biomechanical optimal control problems involving uncertainty to enable the reliable prediction of human motion with prostheses and their analysis. To be able to get close to the consideration of a real world scenario when simulating the uncertain motion with prosthesis, we want to exemplarily focus on one particular foot prosthesis and perform measurements. We will experimentally acquire material properties and model them as uncertain parameters and capture a walking motion to create an uncertain human leg model. The main part of the proposed research work comprises the further development of the fuzzy simulation methods for forward dynamics and optimal control problems to the presence of polymorphic uncertainty for the analysis of prosthetic structures during design and life cycle. This involves in particular the formulation and solution of uncertain optimisation problems. To keep the computational effort manageable, approximations of the uncertain problems are formulated.
Prosthesis models of increasing material complexity and different types of uncertainty are derived from experimental and computational analysis. The investigation of polymorphic uncertainty on the microstructure and its propagation to the macroscale is planned.
Furthermore, using the LTD's motion capture laboratory, uncertain quantities on model and parameter level, will be determined from analysing human gait trials. For the gait cycle simulation to encompass the entire gait cycle, ground contact, heel strike and toe-off have to be modelled for the complex precurved geometrically exact beam model of the carbon spring foot prosthesis.
Being one of the few projects so far in the SPP 1886 dealing with dynamical systems, the other subprojects will profit from the developed methods when focussing on time-dependent parameters and the change of a structure during its life cycle.