Robert Schirmer
Ph.D. Student Contact:Email: Robert.Schirmer@nullde.bosch.com
Tel: +49 – 228 – 73 – 27 13
Fax: +49 – 228 – 73 – 27 12
Office: Nussallee 15, 1. OG, room 1.005
Address:
University of Bonn
Photogrammetry, IGG
Nussallee 15
53115 Bonn
Research Interests
- Robotics
Publications
2024
- R. Schirmer, N. Vaskevicius, P. Biber, and C. Stachniss, “Fast Global Point Cloud Registration using Semantic NDT,” in Proc. of the ieee/rsj intl. conf. on intelligent robots and systems (iros), 2024.
[BibTeX] [PDF]@inproceedings{schirmer2024iros, author = {R. Schirmer and N. Vaskevicius and P. Biber and C. Stachniss}, title = {{Fast Global Point Cloud Registration using Semantic NDT}}, booktitle = iros, year = 2024, }
2019
- R. Schirmer, P. Bieber, and C. Stachniss, “Coverage Path Planning in Belief Space ,” in Proc. of the IEEE Intl. Conf. on Robotics & Automation (ICRA), 2019.
[BibTeX] [PDF]@InProceedings{schirmer2019icra, author = {R. Schirmer and P. Bieber and C. Stachniss}, title = {{Coverage Path Planning in Belief Space }}, booktitle = icra, year = 2019, }
2017
- R. Schirmer, P. Biber, and C. Stachniss, “Efficient path planning in belief space for safe navigation,” in Proc. of the ieee/rsj intl. conf. on intelligent robots and systems (iros), 2017.
[BibTeX] [PDF]
Robotic lawn-mowers are required to stay within a predefined working area, otherwise they may drive into a pond or on the street. This turns navigation and path planning into safety critical components. If we consider using SLAM techniques in that context, we must be able to provide safety guarantees in the presence of sensor/actuator noise and featureless areas in the environment. In this paper, we tackle the problem of planning a path that maximizes robot safety while navigating inside the working area and under the constraints of limited computing resources and cheap sensors. Our approach uses a map of the environment to estimate localizability at all locations, and it uses these estimates to search for a path from start to goal in belief space using an extended heuristic search algorithm. We implemented our approach using C++ and ROS and thoroughly tested it on simulation data recorded on eight different gardens, as well as on a real robot. The experiments presented in this paper show that our approach leads to short computation times and short paths while maximizing robot safety under certain assumptions.
@InProceedings{schirmer2017iros, author = {R. Schirmer and P. Biber and C. Stachniss}, title = {Efficient Path Planning in Belief Space for Safe Navigation}, booktitle = iros, year = {2017}, abstract = {Robotic lawn-mowers are required to stay within a predefined working area, otherwise they may drive into a pond or on the street. This turns navigation and path planning into safety critical components. If we consider using SLAM techniques in that context, we must be able to provide safety guarantees in the presence of sensor/actuator noise and featureless areas in the environment. In this paper, we tackle the problem of planning a path that maximizes robot safety while navigating inside the working area and under the constraints of limited computing resources and cheap sensors. Our approach uses a map of the environment to estimate localizability at all locations, and it uses these estimates to search for a path from start to goal in belief space using an extended heuristic search algorithm. We implemented our approach using C++ and ROS and thoroughly tested it on simulation data recorded on eight different gardens, as well as on a real robot. The experiments presented in this paper show that our approach leads to short computation times and short paths while maximizing robot safety under certain assumptions.}, url = {https://www.ipb.uni-bonn.de/pdfs/schirmer17iros.pdf}, }