Mobility Evaluation for Hybrid Robot Motion on Deformable Terrain via Physics-Based and Data-Driven Modeling Approach
Navigating an unmapped environment is one of the ten biggest challenges facing the robotics community. A vision-based navigation system embedded in the mobile robot can only help to negotiate obstacles, which are well described by geometrical features, like sharp-edged stones and rocks. Other aspects like sand, snow, and challenging terrains, are challenges for motions that robots cannot avoid during missions. Thus, designing and selecting effective gaits to navigate over terrains that may not be well describable by geometry is crucial for robot exploration. Wheeled robots can move fast on flat surfaces but suffer from loss of traction and immobility on soft ground. However, legged machines have superior mobility over wheeled locomotion when they are in motion over flowable ground or a terrain with obstacles but can only move at relatively low speeds on flat surfaces. A fundamental question is as follows: If legged and wheeled locomotion are combined, can the resulting hybrid leg-wheel locomotion enable fast movement in any terrain condition?
Investigations into vehicle terrain interaction fall in the area of terramechanics. Traditional terra-mechanics theory can help capture large wheel vehicle interaction with the ground. However, legged or hybrid locomotion on a granular substrate is difficult to investigate by using classical empirical terra-mechanics theory due to sharp-edge contact. Recent studies show the continuum simulation can serve as an accurate tool for simulating dynamic interactions with granular material at laboratory and field scales. Therefore, to investigate the rich physics during dynamic interactions between the robot and the granular terrain, a computational framework based on the Smooth particle hydrodynamics (SPH) method has been developed and validated by using experimental results for single robot appendage interaction with the granular system. This framework has been extended and coupled with a multi-body simulator to model different robot configurations. The Graphics Processing Unit (GPU) has been employed to reduce the computational expense. Encouraging agreement is found amongst the numerical, theoretical, and experimental results, for a wide range of robot leg configurations, such as curvature and shape. Parametric studies have been conducted to explore the sensitive dependence of robot performance and different gaits.
The abovementioned physics-based simulation can serve as a high-fidelity tool to uncover clues about the underlying mechanism of dynamic interactions between robots and soft terrain. However, real-time navigation in a challenging terrain requires fast prediction of the dynamic response of the robot, which is useful for terrain identification and robot gait adaption. Therefore, a data-driven modeling framework has also been developed for the fast estimation of the slippage and sinkage of robots. The computational studies generate high-quality data for the training of a deep neural network. A regularization constraint is employed to obtain stable and bounded solutions. An unsupervised learning algorithm is also used to cluster the inputs to generate the least but most important datasets for training the Long short-term memory (LSTM) cells. The results are expected to form a good basis for robot navigation and exploration in unknown and complex terrains.
Mobility Evaluation for Hybrid Robot Motion on Deformable Terrain via Physics-Based and Data-Driven Modeling Approach
Category
Poster Presentation
Description
Session: 16-01-01 National Science Foundation Posters - On Demand
ASME Paper Number: IMECE2020-24960
Session Start Time: ,
Presenting Author: Guanjin Wang
Presenting Author Bio: Guanjin Wang is a Ph.D. candidate at the University ofMaryland, College Park, under the guidance of Dr. Balakumar Balachandran andDr. Amir Riaz. She got her bachelor’s degree in mechanics (2012) and firstmaster’s degree in structural engineering (2014) from Harbin Institute ofTechnology. Then she got her second master’s degree in civil engineering (2016)from the University of Minnesota, Twin Cities, and third master’s degree (2019)in mechanical engineering from the University of Maryland, College Park. Shescheduled to defend her Ph.D. dissertation in November 2020. Her researchfocuses on physics-based and data-driven modeling of hybrid robot motion ondeformable terrain.
Authors: Guanjin Wang University of Maryland, College Park
Amir Riaz University of Maryland, College Park
Balakumar Balachandran University of Maryland, College Park