TY - JOUR
T1 - Evaluation of 3D LiDAR Sensor Setup for Heterogeneous Robot Team
AU - Haddeler, Garen
AU - Aybakan, Abdulbaki
AU - Akay, M. Caner
AU - Temeltas, Hakan
N1 - Publisher Copyright:
© 2020, Springer Nature B.V.
PY - 2020/11/1
Y1 - 2020/11/1
N2 - We encounter a world where the role of robots has increased in society. Day by day, we can observe that problems related to autonomous vehicles are being solved. The focused problem that we have recently confronted is based on collaborative mapping with multi-robots since collaboratively generated map provides more information about the environment than with a single robot. Moreover, the mapping framework for robot team can be more efficient if 3D laser sensors are placed to cover wider area. However, laser sensors are commonly positioned intuitively and depended mostly on the designer’s choice. To overcome designer-independent laser sensor setup for efficient collaborative mapping, a subjective evaluation of laser sensor placement is developed as another key aspect. This paper proposed a collaborative mapping framework for heterogeneous robot teams to make full use of collected information from different viewpoints and explore large areas more efficiently. It’s comprised of two modules, localization of multi-robots and collaborative map construction. In addition, to avoid arbitrary setup of laser sensors in existing methods whose performance is heavily affected by designers’ experience, a metric evaluation system was defined to determine the optimal placements of laser sensors and achieve maximum sweep area. The proposed methods were verified on both simulation and experiments which were carried out on a heterogeneous robot team (including an unmanned aerial vehicle and a ground vehicle). According to the metric evaluation, best placements were chosen for the laser sensors, and presented collaborative mapping technique was shown to work more efficiently compared with existing methods.
AB - We encounter a world where the role of robots has increased in society. Day by day, we can observe that problems related to autonomous vehicles are being solved. The focused problem that we have recently confronted is based on collaborative mapping with multi-robots since collaboratively generated map provides more information about the environment than with a single robot. Moreover, the mapping framework for robot team can be more efficient if 3D laser sensors are placed to cover wider area. However, laser sensors are commonly positioned intuitively and depended mostly on the designer’s choice. To overcome designer-independent laser sensor setup for efficient collaborative mapping, a subjective evaluation of laser sensor placement is developed as another key aspect. This paper proposed a collaborative mapping framework for heterogeneous robot teams to make full use of collected information from different viewpoints and explore large areas more efficiently. It’s comprised of two modules, localization of multi-robots and collaborative map construction. In addition, to avoid arbitrary setup of laser sensors in existing methods whose performance is heavily affected by designers’ experience, a metric evaluation system was defined to determine the optimal placements of laser sensors and achieve maximum sweep area. The proposed methods were verified on both simulation and experiments which were carried out on a heterogeneous robot team (including an unmanned aerial vehicle and a ground vehicle). According to the metric evaluation, best placements were chosen for the laser sensors, and presented collaborative mapping technique was shown to work more efficiently compared with existing methods.
KW - 3D laser sensor positioning
KW - Collaborative mapping
KW - Heterogeneous robot team
KW - ICP
KW - LiDAR configurations for multi agent robot systems
KW - LiDAR sensor setup
KW - Localization for multi-robots
KW - Map merging from different sources
KW - Occupancy metrics for point clouds
KW - OctoMap
KW - Performance metrics for point clouds
KW - ROS
UR - http://www.scopus.com/inward/record.url?scp=85089369209&partnerID=8YFLogxK
U2 - 10.1007/s10846-020-01207-y
DO - 10.1007/s10846-020-01207-y
M3 - Article
AN - SCOPUS:85089369209
SN - 0921-0296
VL - 100
SP - 689
EP - 709
JO - Journal of Intelligent and Robotic Systems: Theory and Applications
JF - Journal of Intelligent and Robotic Systems: Theory and Applications
IS - 2
ER -