Collaborative Robotic Arm and Humanoid Interaction for Kitting Tasks in Simulated Factory Environment: A Simulation-Based Evaluation of Motion Planning Methods for Automated Kitting in Dynamic Industrial Environments
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Författare
Typ
Examensarbete för masterexamen
Master's Thesis
Master's Thesis
Modellbyggare
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Sammanfattning
Future industrial automation requires robotic systems that can operate in workspaces
where objects, equipment, and humans may be present. This thesis presents the development
and evaluation of a simulation-based system for motion planning in a
kitting task. The system was built around a gantry-mounted UR10e robot arm with
a Robotiq gripper in a simulated factory environment containing a flow rack, crates,
static and dynamic obstacles.
The work integrated ROS 2, Isaac Sim, MoveIt 2, and several motion-planning
frameworks in a containerised software architecture. Sampling-based planning with
OMPL, GPU-accelerated planning with cuMotion and cuRobo, and a hybrid planner
based on cuRobo MotionGen and MPC were implemented and evaluated. The
planners were tested in simple motion cases, complete pick-and-place workflows, and
a dynamic obstacle benchmark where the robot had to react to a newly introduced
obstacle during execution.
The results showed that cuRobo provided the strongest overall balance between
planning speed, success rate, and motion efficiency in the static benchmark cases.
cuMotion also achieved high success rates, but generally required longer planning
times. The OMPL planners were computationally cheap and could be fast in successful
cases, but showed lower robustness in several scenarios. The hybrid planner
was able to react to dynamic changes in the environment, but its success depended
on how close the obstacle appeared to the robot. When enough clearance was available,
the hybrid planner recovered reliably, while recovery became less likely when
the obstacle was inserted very close to the robot.
The thesis shows that simulation is a useful tool for evaluating motion-planning
methods for constrained industrial tasks before real-world deployment. It also shows
that GPU-accelerated and hybrid planning methods are promising for robotic operation
in dynamic environments, but that further work is needed before the system
can fully represent realistic human-robot collaboration.
Beskrivning
Ämne/nyckelord
robotics, motion planning, kitting, ROS 2, Isaac Sim, MoveIt 2, cuRobo, cuMotion, OMPL, human-robot collaboration
