Enhanced flyby science with onboard computer vision: Tracking and surface feature detection at small bodies

Fuchs, Thomas J.; Thompson, David R.; Bue, Brian D.; Castillo‐Rogez, Julie; Chien, Steve; Gharibian, Dero; Wagstaff, Kiri L.

doi:10.1002/2014ea000042

Cited by 10 publications

(5 citation statements)

References 35 publications

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“…So, it is important that the navigation system (and strategy) is robust to that uncertainties. Many techniques have been investigated or are under current investigation, from more traditional centerof-brightness and geometric centering [11,22], to brand-new deep-learning and neural network based [23,24]. Indeed, the fast growth in neural-networks based navigation will characterize the next years of small bodies exploration.…”

Section: Autonomous Navigationmentioning

confidence: 99%

Novel 3U Stand-Alone CubeSat Architecture for Autonomous Near Earth Asteroid Fly-By

Casini

Fodde

Monna³

et al. 2020

Aerospace

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The purpose of this work is to present a novel CubeSat architecture, aimed to explore Near Earth Asteroids. The fast growth in small satellite commercial-off-the-shelf technologies, which characterized the last decade of space industry, is exploited to design a 3U CubeSat able to provide a basic scientific return sufficient to improve the target asteroid dataset. An overview of the current available technologies for each subsystem is presented, followed by a component selection driven by the mission constraints. First a typical asteroid fly-by mission is introduced together with the system and performance requirements. Then each characterizing subsystem is critically analyzed, and the proposed configuration is presented, showing the mission feasibility within only 3.9 kg of wet mass and 385 m/s of total ΔV.

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Section: Autonomous Navigationmentioning

confidence: 99%

Novel 3U Stand-Alone CubeSat Architecture for Autonomous Near Earth Asteroid Fly-By

Casini

Fodde

Monna³

et al. 2020

Aerospace

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“…Due to this advantage, FIGGRA may be an advanced and reliable alternative algorithm for Earth imagery classification and the associated diverse studies or practices [Jiang and Shekhar, 2017;Rauniyar et al, 2017;Schwenk et al, 2017]. In addition, FIGGRA-based spatial/temporal heterogeneity analysis may facilitate improvement of various quantitative analysis approaches for investigating many problems in Earth and space sciences, e.g., monitoring network design [Mishra et al, 2016;Gleason et al, 2017], urban ecology [Bardhan et al, 2016], representative-days selection [Rife et al, 2013], O 3 distribution detection [Parrish et al, 2016], spatial tracking or navigation [Fuchs et al, 2015;Palmer et al, 2016], tsunamis modeling [Grawe and Makela, 2015], atmospheric process analyses [Weisz et al, 2015], seafloor venting detection [Smart et al, 2017], sporadic E propagation [Ghosh and Berkey, 2015], or eco-system analysis [Zhang et al, 2017]. The potentiality of FIGGRA in addressing the abovementioned problems would be assessed in the future studies.…”

Section: Potential Extensionsmentioning

confidence: 99%

Factorial inferential grid grouping and representativeness analysis for a systematic selection of representative grids

Cheng

Huang

Dong

et al. 2017

Earth and Space Science

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A factorial inferential grid grouping and representativeness analysis (FIGGRA) approach is developed to achieve a systematic selection of representative grids in large‐scale climate change impact assessment and adaptation (LSCCIAA) studies and other fields of Earth and space sciences. FIGGRA is applied to representative‐grid selection for temperature (Tas) and precipitation (Pr) over the Loess Plateau (LP) to verify methodological effectiveness. FIGGRA is effective at and outperforms existing grid‐selection approaches (e.g., self‐organizing maps) in multiple aspects such as clustering similar grids, differentiating dissimilar grids, and identifying representative grids for both Tas and Pr over LP. In comparison with Pr, the lower spatial heterogeneity and higher spatial discontinuity of Tas over LP lead to higher within‐group similarity, lower between‐group dissimilarity, lower grid grouping effectiveness, and higher grid representativeness; the lower interannual variability of the spatial distributions of Tas results in lower impacts of the interannual variability on the effectiveness of FIGGRA. For LP, the spatial climatic heterogeneity is the highest in January for Pr and in October for Tas; it decreases from spring, autumn, summer to winter for Tas and from summer, spring, autumn to winter for Pr. Two parameters, i.e., the statistical significance level (α) and the minimum number of grids in every climate zone (Nmin), and their joint effects are significant for the effectiveness of FIGGRA; normalization of a nonnormal climate‐variable distribution is helpful for the effectiveness only for Pr. For FIGGRA‐based LSCCIAA studies, a low value of Nmin is recommended for both Pr and Tas, and a high and medium value of α for Pr and Tas, respectively.

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“…Their research automatically detects and tracks plumes on the 67P/Churyumov-Gerasimenko comet using OSIRIS/Rosetta image sequences. Additionally, there have been studies on surface feature detection and tracking on small bodies using onboard computer vision techniques [29], [30]. These studies provide insights for tracking dust devils on other celestial bodies.…”

Section: Introductionmentioning

confidence: 99%

Martian Dust Devil Detection Based on Improved Faster R-CNN

Guo,

Xu,

et al. 2024

IEEE J. Sel. Top. Appl. Earth Observations Remote Sensing

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Dust devil is an important part of the Martian climate system, which can help us better understand scientific questions of the climate, surface-atmosphere interactions, aeolian processes, and regolith on Mars. Therefore, automatic detection of dust devils from Mars Orbiter images is becoming increasingly important for the scientific study and the planning of future robotic and manned missions. To improve the generalization, detection efficiency and accuracy of traditional approach in automatically detecting dust devils, we made several modifications to the faster region-based convolution neural network (Faster R-CNN). Based on the characteristics of the dust devil, we proposed a Martian Dust Devil Detection Network (MDDD Net). The network uses the feature pyramid network (FPN) to obtain a feature fusion map with rich location information and semantic information. The k-means++ algorithm is used to design reasonable anchor boxes to adapt to vary sized dust devils. Region of interest align (RoI Align) unit is introduced to eliminate the mapping deviation between the feature map and the original image. Finally, the soft non-maximum suppression (Soft-NMS) algorithm is used to complete the screening of bounding box. It can reduce missing detections caused by the overlapping between adjacent dust devil bounding boxes in the same image. The average precision and recall of MDDD Net on the dust devil dataset built in this paper reaches 90.1% and 96.5%, respectively.

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Enhanced flyby science with onboard computer vision: Tracking and surface feature detection at small bodies

Cited by 10 publications

References 35 publications

Novel 3U Stand-Alone CubeSat Architecture for Autonomous Near Earth Asteroid Fly-By

Novel 3U Stand-Alone CubeSat Architecture for Autonomous Near Earth Asteroid Fly-By

Factorial inferential grid grouping and representativeness analysis for a systematic selection of representative grids

Martian Dust Devil Detection Based on Improved Faster R-CNN

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