Machine Learning Based Path Planning for Improved Rover Navigation

Abcouwer, Neil; Daftry, Shreyansh; Sesto, Tyler Del; Toupet, Olivier; Ono, Masahiro; Venkatraman, Siddarth; Lanka, Ravi; Song, Jialin; Yue, Yisong

doi:10.1109/aero50100.2021.9438337

Cited by 17 publications

(7 citation statements)

References 11 publications

(10 reference statements)

Supporting

Mentioning

Contrasting

Order By: Relevance

“…In a nutshell, MLNav is a search-based path planner that uses learned heuristics, where the safety of the chosen path is guaranteed by running a model-based collision checker. The use of learned heuristics within search-based robotic planning has previously been studied [7]- [11], including showing favorable comparisons versus hand-craft heuristics for rover path planning [12]. Our main contribution is proposing a general system design principle for effectively integrating ML-based approaches into existing navigation pipelines of safety-critical robotic systems, as well as a concrete instantiation for Mars rover navigation.…”

Section: Arxiv:220304563v1 [Csro] 9 Mar 2022mentioning

confidence: 99%

MLNav: Learning to Safely Navigate on Martian Terrains

Daftry

Abcouwer

Sesto

et al. 2022

IEEE Robot. Autom. Lett.

Self Cite

View full text Add to dashboard Cite

We present MLNav, a learning-enhanced path planning framework for safety-critical and resource-limited systems operating in complex environments, such as rovers navigating on Mars. MLNav makes judicious use of machine learning to enhance the efficiency of path planning while fully respecting safety constraints. In particular, the dominant computational cost in such safety-critical settings is running a model-based safety checker on the proposed paths. Our learned search heuristic can simultaneously predict the feasibility for all path options in a single run, and the model-based safety checker is only invoked on the top-scoring paths. We validate in high-fidelity simulations using both real Martian terrain data collected by the Perseverance rover, as well as a suite of challenging synthetic terrains. Our experiments show that: (i) compared to the baseline ENav path planner on board the Perserverance rover, MLNav can provide a significant improvement in multiple key metrics, such as a 10x reduction in collision checks when navigating real Martian terrains, despite being trained with synthetic terrains; and (ii) MLNav can successfully navigate highly challenging terrains where the baseline ENav fails to find a feasible path before timing out.

show abstract

Section: Arxiv:220304563v1 [Csro] 9 Mar 2022mentioning

confidence: 99%

MLNav: Learning to Safely Navigate on Martian Terrains

Daftry

Abcouwer

Sesto

et al. 2022

IEEE Robot. Autom. Lett.

Self Cite

View full text Add to dashboard Cite

show abstract

“…The Opportunistic Rover Science (OASIS) framework uses machine learning algorithms to identify terrain features [8,20], dust devils, and clouds [7]. For rover navigation, Abcouwer et al [1] presented two heuristics to rank candidate paths, where a machine learning model is applied to predict untraversable areas. For ex-situ methods, machine learning can help scientists analyze data and notify noteworthy findings.…”

Section: Machine Learning In Mars Explorationmentioning

confidence: 99%

Semi-Supervised Learning for Mars Imagery Classification and Segmentation

Wang¹,

Lin²,

Fan³

et al. 2022

Preprint

View full text Add to dashboard Cite

With the progress of Mars exploration, numerous Mars image data are collected and need to be analyzed. However, due to the imbalance and distortion of Martian data, the performance of existing computer vision models is unsatisfactory. In this paper, we introduce a semi-supervised framework for machine vision on Mars and try to resolve two specific tasks: classification and segmentation.Contrastive learning is a powerful representation learning technique. However, there is too much information overlap between Martian data samples, leading to a contradiction between contrastive learning and Martian data. Our key idea is to reconcile this contradiction with the help of annotations and further take advantage of unlabeled data to improve performance. For classification, we propose to ignore inner-class pairs on labeled data as well as neglect negative pairs on unlabeled data, forming supervised inter-class contrastive learning and unsupervised similarity learning. For segmentation, we extend supervised inter-class contrastive learning into an element-wise mode and use online pseudo labels for supervision on unlabeled areas. Experimental results show that our learning strategies can improve the classification and segmentation models by a large margin and outperform state-of-the-art approaches.

show abstract

“…As a result they are unable to handle texture-less objects like sample-tubes. More recently, with the advent of deep learning, CNNs by comparison, have made significant progress in object classification [25], detection [26], [27], semantic segmentation [28] and instance segmentation [29], including their application to Mars rover autonomy [30], [31].…”

Section: Image-based Object Detection and Localizationmentioning

confidence: 99%

Machine Vision based Sample-Tube Localization for Mars Sample Return

Daftry¹,

Ridge²,

Seto³

et al. 2021

Preprint

Self Cite

View full text Add to dashboard Cite

A potential Mars Sample Return (MSR) architecture is being jointly studied by NASA and ESA. As currently envisioned, the MSR campaign consists of a series of 3 missions: sample cache, fetch and return to Earth. In this paper, we focus on the fetch part of the MSR, and more specifically the problem of autonomously detecting and localizing sample tubes deposited on the Martian surface. Towards this end, we study two machine-vision based approaches: First, a geometrydriven approach based on template matching that uses hardcoded filters and a 3D shape model of the tube; and second, a data-driven approach based on convolutional neural networks (CNNs) and learned features. Furthermore, we present a large benchmark dataset of sample-tube images, collected in representative outdoor environments and annotated with ground truth segmentation masks and locations. The dataset was acquired systematically across different terrain, illumination conditions and dust-coverage; and benchmarking was performed to study the feasibility of each approach, their relative strengths and weaknesses, and robustness in the presence of adverse environmental conditions.

show abstract

Machine Learning Based Path Planning for Improved Rover Navigation

Cited by 17 publications

References 11 publications

MLNav: Learning to Safely Navigate on Martian Terrains

MLNav: Learning to Safely Navigate on Martian Terrains

Semi-Supervised Learning for Mars Imagery Classification and Segmentation

Machine Vision based Sample-Tube Localization for Mars Sample Return

Contact Info

Product

Resources

About