An Active Learning Framework for Constructing High-fidelity Mobility Maps

A mobility map, which provides maximum achievable speed on a given terrain, is essential for path planning of autonomous ground vehicles in off-road settings. While physics-based simulations play a central role in creating next-generation, high-fidelity mobility maps, they are cumbersome and expensive. For instance, a typical simulation can take weeks to run on a supercomputer and each map requires thousands of such simulations. Recent work at the U.S. Army CCDC Ground Vehicle Systems Center has shown that trained machine learning classifiers can greatly improve the efficiency of this process. However, deciding which simulations to run in order to train the classifier efficiently is still an open problem. According to PAC learning theory, data that can be separated by a classifier is expected to require $\mathcal{O}(1/\epsilon)$ randomly selected points (simulations) to train the classifier with error less than $\epsilon$. In this paper, building on existing algorithms, we introduce an active learning paradigm that substantially reduces the number of simulations needed to train a machine learning classifier without sacrificing accuracy. Experimental results suggest that our sampling algorithm can train a neural network, with higher accuracy, using less than half the number of simulations when compared to random sampling.

[1]  Gisbert Schneider,et al.  Active-learning strategies in computer-assisted drug discovery. , 2015, Drug discovery today.

[2]  Rong Jin,et al.  Batch mode active learning and its application to medical image classification , 2006, ICML.

[3]  Leo Breiman,et al.  Bagging Predictors , 1996, Machine Learning.

[4]  Hiroyuki Sugiyama,et al.  Hierarchical Multiscale Modeling of Tire–Soil Interaction for Off-Road Mobility Simulation , 2019, Journal of Computational and Nonlinear Dynamics.

[5]  David Cohn,et al.  Active Learning , 2010, Encyclopedia of Machine Learning.

[6]  Geoffrey E. Hinton,et al.  Rectified Linear Units Improve Restricted Boltzmann Machines , 2010, ICML.

[7]  Daphne Koller,et al.  Support Vector Machine Active Learning with Applications to Text Classification , 2000, J. Mach. Learn. Res..

[8]  H. Sebastian Seung,et al.  Query by committee , 1992, COLT '92.

[9]  Anneleen Van Assche,et al.  Ensemble Methods for Noise Elimination in Classification Problems , 2003, Multiple Classifier Systems.

[10]  Tom M. Mitchell,et al.  Generalization as Search , 2002 .

[11]  William A. Gale,et al.  A sequential algorithm for training text classifiers , 1994, SIGIR '94.

[12]  H. Sebastian Seung,et al.  Selective Sampling Using the Query by Committee Algorithm , 1997, Machine Learning.

[13]  Paramsothy Jayakumar,et al.  Scalable Solvers for Cone Complementarity Problems in Frictional Multibody Dynamics , 2019, 2019 IEEE High Performance Extreme Computing Conference (HPEC).

[14]  Peter W Haley,et al.  NATO Reference Mobility Model, Edition 1, Users Guide. Volume 2. Obstacle Module , 1979 .

[15]  Raymond J. Mooney,et al.  Active Learning for Natural Language Parsing and Information Extraction , 1999, ICML.

[16]  Nello Cristianini,et al.  Query Learning with Large Margin Classi ersColin , 2000 .

[17]  Edward Y. Chang,et al.  Support vector machine active learning for image retrieval , 2001, MULTIMEDIA '01.

[18]  David Gorsich,et al.  Tensor Train Accelerated Solvers for Nonsmooth Rigid Body Dynamics , 2018, Applied Mechanics Reviews.

[19]  Mihai Anitescu,et al.  Solving Large Multibody Dynamics Problems on the GPU , 2012 .

[20]  P. Jayakumar,et al.  Efficient generation of accurate mobility maps using machine learning algorithms , 2020 .

[21]  John Langford,et al.  Agnostic active learning , 2006, J. Comput. Syst. Sci..

[22]  Tamer M. Wasfy,et al.  Understanding the Effects of a Discrete Element Soil Model's Parameters on Ground Vehicle Mobility , 2019, Journal of Computational and Nonlinear Dynamics.

[23]  Naoki Abe,et al.  Query Learning Strategies Using Boosting and Bagging , 1998, ICML.

[24]  André Stumpf,et al.  Active Learning in the Spatial Domain for Remote Sensing Image Classification , 2014, IEEE Transactions on Geoscience and Remote Sensing.