8 research outputs found
Comparative Study of Different Methods in Vibration-Based Terrain Classification for Wheeled Robots with Shock Absorbers
Get PDFopen access articleAutonomous robots that operate in the field can enhance their security and efficiency by
accurate terrain classification, which can be realized by means of robot-terrain interaction-generated
vibration signals. In this paper, we explore the vibration-based terrain classification (VTC),
in particular for a wheeled robot with shock absorbers. Because the vibration sensors are
usually mounted on the main body of the robot, the vibration signals are dampened significantly,
which results in the vibration signals collected on different terrains being more difficult to
discriminate. Hence, the existing VTC methods applied to a robot with shock absorbers may degrade.
The contributions are two-fold: (1) Several experiments are conducted to exhibit the performance of
the existing feature-engineering and feature-learning classification methods; and (2) According to
the long short-term memory (LSTM) network, we propose a one-dimensional convolutional LSTM
(1DCL)-based VTC method to learn both spatial and temporal characteristics of the dampened
vibration signals. The experiment results demonstrate that: (1) The feature-engineering methods,
which are efficient in VTC of the robot without shock absorbers, are not so accurate in our project;
meanwhile, the feature-learning methods are better choices; and (2) The 1DCL-based VTC method
outperforms the conventional methods with an accuracy of 80.18%, which exceeds the second method
(LSTM) by 8.23%
Tapered whisker reservoir computing for real-time terrain identification-based navigation
Get PDFThis paper proposes a new method for real-time terrain recognition-based navigation for mobile robots. Mobile robots performing tasks in unstructured environments need to adapt their trajectories in real-time to achieve safe and efficient navigation in complex terrains. However, current methods largely depend on visual and IMU (inertial measurement units) that demand high computational resources for real-time applications. In this paper, a real-time terrain identification-based navigation method is proposed using an on-board tapered whisker-based reservoir computing system. The nonlinear dynamic response of the tapered whisker was investigated in various analytical and Finite Element Analysis frameworks to demonstrate its reservoir computing capabilities. Numerical simulations and experiments were cross-checked with each other to verify that whisker sensors can separate different frequency signals directly in the time domain and demonstrate the computational superiority of the proposed system, and that different whisker axis locations and motion velocities provide variable dynamical response information. Terrain surface-following experiments demonstrated that our system could accurately identify changes in the terrain in real-time and adjust its trajectory to stay on specific terrain
Π Π°Π·ΡΠ°Π±ΠΎΡΠΊΠ° ΠΌΠΎΠ΄Π΅Π»ΠΈ Π΄Π»Ρ ΠΏΡΠ΅Π΄ΡΠΊΠ°Π·Π°Π½ΠΈΡ ΠΊΠ»Π°ΡΡΠ° Π΄ΠΎΡΠΎΠΆΠ½ΠΎΠΉ ΠΏΠΎΠ²Π΅ΡΡ Π½ΠΎΡΡΠΈ Π½Π° ΠΎΡΠ½ΠΎΠ²Π΅ ΠΏΠΎΠΊΠ°Π·Π°Π½ΠΈΠΉ Π΄Π°ΡΡΠΈΠΊΠΎΠ² ΠΌΠΎΠ±ΠΈΠ»ΡΠ½ΠΎΠ³ΠΎ ΡΠΎΠ±ΠΎΡΠ°
Get PDFΠ¦Π΅Π»ΡΡ ΡΠ°Π±ΠΎΡΡ ΡΠ²Π»ΡΠ΅ΡΡΡ ΡΠ°Π·ΡΠ°Π±ΠΎΡΠΊΠ° ΠΊΠ»Π°ΡΡΠΈΡΠΈΠΊΠ°ΡΠΎΡΠ° Π΄Π»Ρ ΠΎΠΏΡΠ΅Π΄Π΅Π»Π΅Π½ΠΈΡ ΡΠΈΠΏΠ° ΠΏΠΎΠ²Π΅ΡΡ
Π½ΠΎΡΡΠΈ, ΠΏΠΎ ΠΊΠΎΡΠΎΡΠΎΠΉ Π΄Π²ΠΈΠΆΠ΅ΡΡΡ ΡΠΎΠ±ΠΎΡ. Π ΠΊΠ°ΡΠ΅ΡΡΠ²Π΅ ΠΏΡΠΈΠ·Π½Π°ΠΊΠΎΠ² Π΄Π»Ρ ΠΌΠΎΠ΄Π΅Π»ΠΈ ΠΈΡΠΏΠΎΠ»ΡΠ·ΡΡΡΡΡ Π°ΠΊΡΠ΅Π»Π΅ΡΠΎΠΌΠ΅ΡΡ ΠΈ Π΄Π°ΡΡΠΈΠΊΠΈ ΡΠΎΠΊΠ°. Π Π°Π·ΡΠ°Π±ΠΎΡΠ°Π½Π½Π°Ρ ΠΌΠΎΠ΄Π΅Π»Ρ ΠΎΡΠ½ΠΎΠ²Π°Π½Π° Π½Π° Π»Π΅ΡΠ΅ Π΄Π΅ΡΠ΅Π²ΡΠ΅Π² ΡΠ΅ΡΠ΅Π½ΠΈΠΉ, ΡΠΎΡΠ½ΠΎΡΡΡ ΠΊΠ»Π°ΡΡΠΈΡΠΈΠΊΠ°ΡΠΈΠΈ ΡΠΎΡΡΠ°Π²Π»ΡΠ΅Ρ 76%.The goal of the work is to develop a terrain classifier. The features used in model are accelerometer and current sensors. The developed model use random forest tree algrithm and have accuracy of 76%
Ground Robot Energy Prediction and Reachability in Off-Road Environments Through Spatial Terrain Mapping
Full text linkFor robotic applications, energy is a key resource that can both enable and limit the tasks that a robot can perform in an environment. In off-road environments, ground robots may traverse numerous different terrains with significantly and spatially varying energy costs. The cost of a particular robot moving through such an environment is likely to be uncertain, making mission planning and decision-making challenging. In this dissertation, we develop methods that use information on terrain traversal energy costs, collected during robot operation, so that future energy costs for the robot can be more accurately and confidently predicted. The foundation of these methods is to build a spatial map of the energy costs in an environment, while characterizing the uncertainty in those costs, using a technique known as Gaussian process regression (GPR). This map can be used to improve performance in important robotic applications, including path and mission planning.
First, we present a 2-dimensional energy mapping formulation, based on GPR, that properly considers the correlation in path energy costs for computing the uncertainty in the predicted energy cost of a path through the environment. With this formulation, we define a robot's chance constrained reachability as the set of locations that the robot can reach, under a user-defined confidence level, without depleting its energy budget. Simulation results show that as a robot collects more data on the environment, the reachable set becomes more accurately known, making it a useful tool for mission planning applications. Next, we extend the spatial mapping formulation to 3-dimensional environments by considering both data-driven and vehicle modeling strategies. Experimental testing is performed on ground robot platforms in an environment with varied terrains. The results show that the predictive accuracy of the spatial mapping methodology is significantly improved over baseline approaches. Finally, we explore information sharing between heterogeneous robot platforms. Two different robots are likely to have different spatial maps, however, useful information may still be shared between the robots. We present a framework, based multi-task Gaussian process regression (MTGP), for learning the scaling and correlation in costs between different robots, and provide simulation and experimental results demonstrating its effectiveness. Using the framework, robot heterogeneity can be leveraged to improve performance in planning applications.PHDMechanical EngineeringUniversity of Michigan, Horace H. Rackham School of Graduate Studieshttps://deepblue.lib.umich.edu/bitstream/2027.42/153361/1/maquann_1.pd
