Modeling, gait sequence design, and control architecture of BADGER underground robot

Abstract

This letter presents the dynamic modeling, the gait sequence design, and the control architecture of the BADGER autonomous underground robot. BADGER is a modular and articulated robotic mechanism which employs inchworm biomimetic motion to drill and propel within the soil. It is used to drill and manoeuvre in the subsurface for building curved tunnels of small diameter in underground spaces, without the need for open-cut excavation. In order to design efficient motion control strategies, a model-based approach is followed. To this end, the kinematic and the lagrangian dynamic models are derived, which take into account the physical interaction of the robot drill-head with the environment, and are used for designing the inchworm gait sequence and for calculating the actuation torques and forces required to realise the trajectory profiles of the gait sequence. The motion control is executed on a simulation platform or on the actual robot hardware using a Robot Operating System (ROS) control architecture. The gait sequence and the motion controller are validated though an experiment where the BADGER is commanded to drill and follow a straight line path in the underground. The gait sequence for following a generic 3D curvilinear path in the underground is demonstrated in a simulation environment. © 2016 IEEE.