Your search keyword '"Boris Lohman"' showing total 8 results

1. Extension of a Simulation Model of the Freeform Bending Process as Part of a Soft Sensor for a Property Control

Author

Sophie Charlotte Stebner, Daniel Maier, Ahmed Ismail, Michael Dölz, Boris Lohman, Wolfram Volk, and Sebastian Münstermann

Subjects

ddc:670, Mechanics of Materials, Mechanical Engineering, General Materials Science

Abstract

[25th International Conference on Material Forming, ESAFORM 2022, 2022-04-27 - 2022-04-29, Braga, Portugal] 25th International Conference on Material Forming, ESAFORM 2022, Braga, Portugal, 27 Apr 2022 - 29 Apr 2022; Uetikon a.S. : Trans Tech Publications, Key engineering materials 926, 2137-2145 (2022). doi:10.4028/p-d17700, Published by Trans Tech Publications, Uetikon a.S.

Published

2022

2. A Rosenbrock framework for tangential interpolation of port-Hamiltonian descriptor systems

Author

Tim Moser and Boris Lohmann

Subjects

Port-Hamiltonian systems, differential-algebraic systems, structure-preserving model reduction, Mathematics, QA1-939, Applied mathematics. Quantitative methods, T57-57.97

Abstract

ABSTRACTWe present a new structure-preserving model order reduction (MOR) framework for large-scale port-Hamiltonian descriptor systems (pH-DAEs). Our method exploits the structural properties of the Rosenbrock system matrix for this system class and utilizes condensed forms which often arise in applications and reveal the solution behaviour of a system. Provided that the original system has such a form, our method produces reduced-order models (ROMs) of minimal dimension, which tangentially interpolate the original model’s transfer function and are guaranteed to be again in pH-DAE form. This allows the ROM to be safely coupled with other dynamical systems when modelling large system networks, which is useful, for instance, in electric circuit simulation.

Published

2023

3. Control System Design for a Semi-Finished Product Considering Over- and Underbending

Author

Ahmed Ismail, Daniel Maier, Sophie Stebner, Wolfram Volk, Sebastian Münstermann, and Boris Lohmann

Subjects

freeform bending, automatic control, over- and underbending of tubes, finite element method (FEM), modelling, computerized numerically controlled machines (CNC-Machines), Engineering machinery, tools, and implements, TA213-215

Abstract

In the last decades, the application of automatic control techniques in freeform bending processes was limited to the motion control of the bending die, i.e., the workpiece itself was not considered inside the closed-loop control system. In a previous work, a simple preliminary model for the workpiece was used as a foundation for developing a closed-loop system for freeform bending that includes both the geometry and the mechanical properties of the semi-finished product. However, this approach did not consider the fact that the same geometry can be reached by either over- or underbending the tube. In this work, the previously developed system model is extended to include this physical property of the system.

Published

2022

4. Smooth Trajectory Planning at the Handling Limits for Oval Racing

Author

Levent Ögretmen, Matthias Rowold, Marvin Ochsenius, and Boris Lohmann

Subjects

motion planning, autonomous vehicles, racing, sampling, dynamic obstacles, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

In motion planning for autonomous racing, the challenge arises in planning smooth trajectories close to the handling limits of the vehicle with a sufficient planning horizon. Graph-based trajectory planning methods can find the global discrete-optimal solution, but they suffer from the curse of dimensionality. Therefore, to achieve low computation times despite a long planning horizon, coarse discretization and simple edges that are efficient to generate must be used. However, the resulting rough trajectories cannot reach the handling limits of the vehicle and are also difficult to track by the controller, which can lead to unstable driving behavior. In this paper, we show that the initial edges connecting the vehicle’s estimated state with the actual graph are crucial for vehicle stability and race performance. We therefore propose a sampling-based approach that relies on jerk-optimal curves to generate these initial edges. The concept is introduced using a layer-based graph, but it can be applied to other graph structures as well. We describe the integration of the curves within the graph and the required adaptation to racing scenarios. Our approach enables stable driving at the handling limits and fully autonomous operation on the race track. While simulations show the comparison of our concept with an alternative approach based on uniform acceleration, we also present experimental results of a dynamic overtake with speeds up to 74 m/s on a full-size vehicle.

Published

2022

5. Efficient Spatiotemporal Graph Search for Local Trajectory Planning on Oval Race Tracks

Author

Matthias Rowold, Levent Ögretmen, Tobias Kerbl, and Boris Lohmann

Subjects

autonomous vehicles, motion planning, spatiotemporal planning, graph search, Materials of engineering and construction. Mechanics of materials, TA401-492, Production of electric energy or power. Powerplants. Central stations, TK1001-1841

Abstract

Autonomous racing has increasingly become a research subject as it provides insights into dynamic, high-speed situations. One crucial aspect of handling these situations, especially in the presence of dynamic obstacles, is the generation of a collision-free trajectory that represents a safe behavior and is also competitive in the case of racing. We propose a local planning approach that generates such trajectories for a racing car on an oval race track by searching a spatiotemporal graph. A considerable challenge of search-based methods in a spatiotemporal domain is the curse of dimensionality. Therefore, we propose how a previously presented graph structure that is based on intervals instead of discrete values can be searched more efficiently without losing optimality by using a uniform-cost search strategy. We extend the search method to make it anytime-capable so that it can provide a suboptimal trajectory even if the search has to be terminated early. The graph-based planning approach allows us to apply a flexible cost function so that our approach can operate fully autonomously on an oval race track, including the pit lane. We present a cost function for oval racing and explain how the terms contribute to the desired behaviors. This is supported by results with a full-scale prototype.

Published

2022

6. The influence of freeform bending process parameters on residual stresses for steel tubes

Author

Daniel Maier, Sophie Stebner, Ahmed Ismail, Michael Dölz, Boris Lohmann, Sebastian Münstermann, and Wolfram Volk

Subjects

Freeform bending, Softsensor, Residual stresses, Metal forming, Control-loop, Model-based design, Industrial engineering. Management engineering, T55.4-60.8

Abstract

The superordinate goal of this study is to develop a closed-loop control for a property-controlled freeform bending process based on the prediction of the residual stresses and further mechanical properties by a soft sensor. Therefore, it is hypothesized that different combinations of freeform bending process parameters lead to matching geometry pairs with different residual stresses that can be influenced by the bending die position. A novel correlation between the bending die position, residual stresses and hardness provides the basis for the soft sensor and for closed-loop control design.This paper focuses on freeform bending with movable die, for which a novel bending strategy is developed that results in a set geometry while also providing various residual stress states in the tube. A numerical simulation model for freeform bending with movable die successfully models the variation in degrees of freedom of the machine and provides high qualitative and quantitative results regarding the identification of geometry and residual stresses. Real freeform bent validation experiments and HV 10 Vickers hardness measurements were carried out. HV 10 Vickers hardness tests were identified as a suitable parameter for preliminary system identification and validation, hence making it an appropriate parameter for soft sensor development.

Published

2021

7. A System Identification and Implementation of a Soft Sensor for Freeform Bending

Author

Sophie Charlotte Stebner, Daniel Maier, Ahmed Ismail, Shubham Balyan, Michael Dölz, Boris Lohmann, Wolfram Volk, and Sebastian Münstermann

Subjects

soft sensor, extended Kalman filter, freeform bending, residual hoop stresses, hardness, control-loop, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

The primary goal of this study is the formulation of a soft sensor that predicts industrially relevant mechanical properties for freeform bending. This serves as the foundation of a closed-loop property control. It is hypothesized that by inline measurement of hardness, predictions regarding residual hoop stresses, local strength and strain level can be achieved. A novel hardness-based correlation scheme is introduced, which is implemented into an extended Kalman filter (EKF) and allows an inline prediction of local strength, residual hoop stresses and plasticity. Furthermore, the ultrasonic contact impedance (UCI) method is validated as a suitable inline measuring solution.

Published

2021

8. Adjustable and Adaptive Control for an Unstable Mobile Robot Using Imitation Learning with Trajectory Optimization

Author

Christian Dengler and Boris Lohmann

Subjects

imitation learning, adaptive control, machine learning, mobile robot, Mechanical engineering and machinery, TJ1-1570

Abstract

In this contribution, we develop a feedback controller in the form of a parametric function for a mobile inverted pendulum. The control both stabilizes the system and drives it to target positions with target orientations. A design of the controller based only on a cost function is difficult for this task, which is why we choose to train the controller using imitation learning on optimized trajectories. In contrast to popular approaches like policy gradient methods, this approach allows us to shape the behavior of the system by including equality constraints. When transferring the parametric controller from simulation to the real mobile inverted pendulum, the control performance is degraded due to the reality gap. A robust control design can reduce the degradation. However, for the framework of imitation learning on optimized trajectories, methods that explicitly consider robustness do not yet exist to the knowledge of the authors. We tackle this research gap by presenting a method to design a robust controller in the form of a recurrent neural network, to improve the transferability of the trained controller to the real system. As a last step, we make the behavior of the parametric controller adjustable to allow for the fine tuning of the behavior of the real system. We design the controller for our system and show in the application that the recurrent neural network has increased performance compared to a static neural network without robustness considerations.

Published

2020