23.4.15 Terrain Analysis of Mars, Craters, Minerals

Chapter Contents (Back)
Mars. Martian Terrain.
See also Mars, Martian Atmosphere Measurements, Mars Analysis, Other Planets.
See also Crater Detection, Impact Craters, Depressions.
See also Moon, Lunar Treeain, Lunar Analysis, Martian Terrain.

Ansar, A.[Adnan], Cheng, Y.[Yang],
An Analysis of Spacecraft Localization from Descent Image Data for Pinpoint Landing on Mars and Other Cratered Bodies,
PhEngRS(71), No. 10, October 2005, pp. 1197-1204.
WWW Link. 0602
The feasibility of pinpoint landing on Mars using crater features extracted from decent imagery. BibRef

Li, R.X.[Rong-Xing], Squyres, S.W.[Steven W.], Arvidson, R.E.[Raymond E.], Archinal, B.A.[Brent A.], Bell, J.[Jim], Cheng, Y.[Yang], Crumpler, L.[Larry], Marais, D.J.D.[David J. Des], Di, K.C.[Kai-Chang], Ely, T.A.[Todd A.], Golombek, M.[Matt], Graat, E.[Eric], Grant, J.[John], Guinn, J.[Joe], Johnson, A.[Andrew], Greeley, R.[Ron], Kirk, R.L.[Randolph L.], Maimone, M.W.[Mark W.], Matthies, L.H.[Larry H.], Malin, M.[Mike], Parker, T.[Tim], Sims, M.[Mike], Soderblom, L.A.[Larry A.], Thompson, S.[Shane], Wang, J.[Jue], Whelley, P.[Patrick], Xu, F.L.[Feng-Liang],
Initial Results of Rover Localization and Topographic Mapping for the 2003 Mars Exploration Rover Mission,
PhEngRS(71), No. 10, October 2005, pp. 1129-1144.
WWW Link. Photogrammetric analysis of images from the surface and from orbit is vital to operating to rovers and interpreting their scientific results. 0602

Kim, J.R.[Jung Rack], Muller, J.P.[Jan-Peter], van Gasselt, S.[Stephan], Morley, J.G.[Jeremy G.], Neukum, G.[Gerhard], Team, t.H.C.[the HRSC CoI],
Automated Crater Detection, A New Tool for Mars Cartography and Chronology,
PhEngRS(71), No. 10, October 2005, pp. 1205-1217.
WWW Link. 0602
An automated crater detection algorithm exploiting image data with potential for chronological research and geological analysis.
See also HRSC on Mars Express: Photogrammetric and Cartographic Research. BibRef

Yoon, J.S.[Jong-Suk], Shan, J.[Jie],
Combined Adjustment of MOC Stereo Imagery and MOLA Altimetry Data,
PhEngRS(71), No. 10, October 2005, pp. 1179-1186.
WWW Link. The combined adjustment refines the Mars Global Surveyor trajectory data and provides accurate registration of various mapping data. 0602

Rosiek, M.R.[Mark R.], Kirk, R.L.[Randolph L.], Archinal, B.A.[Brent A.], Howington-Kraus, E.[Eliptha], Hare, T.[Trent], Galuszka, D.[Donna], Redding, B.[Bonnie],
Utility of Viking Orbiter Images and Products for Mars Mapping,
PhEngRS(71), No. 10, October 2005, pp. 1187-1196.
WWW Link. 0602
The usefulness of Viking Orbiter images for mapping Mars 30 years after the mission using a combination of public domain and commercial software. BibRef

Olson, C.F.[Clark F.], Matthies, L.H.[Larry H.], Wright, J.R.[John R.], Li, R.X.[Rong-Xing], Di, K.C.[Kai-Chang],
Visual terrain mapping for Mars exploration,
CVIU(105), No. 1, January 2007, pp. 73-85.
Elsevier DOI 0701
Terrain mapping; Structure-from-motion; Stereo vision; Mars; Robot navigation; Localization BibRef

Li, R.X.[Rong-Xing], Di, K.C.[Kai-Chang], Wang, J.[Jue], Niu, X.T.[Xu-Tong], Agarwal, S.[Sanchit], Brodyagina, E.[Evgenia], Oberg, E.[Erik], Hwangbo, J.W.[Ju Won],
A WebGIS for Spatial Data Processing, Analysis, and Distribution for the MER 2003 Mission,
PhEngRS(73), No. 6, June 2007, pp. 671-680.
WWW Link. 0709
Web-based GIS technology is effectively employed to support rover operations and science experiments during the Mars Exploration Rover 2003 mission BibRef

Bue, B.D., Stepinski, T.F.,
Machine Detection of Martian Impact Craters From Digital Topography Data,
GeoRS(45), No. 1, January 2007, pp. 265-274.

Bandeira, L.P.C.[Lourenço P. C.], Saraiva, J.[José], Pina, P.[Pedro],
Impact Crater Recognition on Mars Based on a Probability Volume Created by Template Matching,
GeoRS(45), No. 12, December 2007, pp. 4008-4015.
Development of a Methodology for Automated Crater Detection on Planetary Images,
IbPRIA07(I: 193-200).
Springer DOI 0706

Marques, J.S.[Jorge S.], Pina, P.[Pedro],
Delineation of Martian Craters Based on Edge Maps and Dynamic Programming,
ICIAR14(I: 433-440).
Springer DOI 1410

Pina, P.[Pedro], Marques, J.S.[Jorge S.],
Delineation of Impact Craters by a Mathematical Morphology Based Approach,
Springer DOI 1307
And: A2, A1:
An Algorithm for the Delineation of Craters in Very High Resolution Images of Mars Surface,
Springer DOI 1307

Gwinner, K.[Klaus], Scholten, F.[Frank], Spiegel, M.[Michael], Schmidt, R.[Ralph], Giese, B.[Bernd], Oberst, J.[Jürgen], Heipke, C.[Christian], Jaumann, R.[Ralf], Neukum, G.[Gerhard],
Derivation and Validation of High-Resolution Digital Terrain Models from Mars Express HRSC-Data,
PhEngRS(75), No. 9, September 2009, pp. 1127-1142.
WWW Link. 0910
The methodology and procedures for the derivation of highresolution DTMs from data of the Mars Express High Resolution Stereo Camera (HRSC) by the experiment team, and report on related processing test series and quality assessment.
See also Mars Express HRSC Data Processing: Methods and Operational Aspects.
See also HRSC on Mars Express: Photogrammetric and Cartographic Research. BibRef

Salamuniccar, G., Loncaric, S.,
Method for Crater Detection From Martian Digital Topography Data Using Gradient Value/Orientation, Morphometry, Vote Analysis, Slip Tuning, and Calibration,
GeoRS(48), No. 5, May 2010, pp. 2317-2329.

Jagert, F.[Felix], Hauber, E.[Ernst],
Age Determination of Martian Low Shield Volcanoes by Crater Size-Frequency Measurements,
PFG(2012), No. 2, 2012, pp. 177-185.
WWW Link. 1211

Wang, Y.[Yexin], Di, K.C.[Kai-Chang], Xin, X.[Xin], Wan, W.H.[Wen-Hui],
Automatic detection of Martian dark slope streaks by machine learning using HiRISE images,
PandRS(129), No. 1, 2017, pp. 12-20.
Elsevier DOI 1706
Dark slope streak. BibRef

Jiang, C.[Cheng], Douté, S.[Sylvain], Luo, B.[Bin], Zhang, L.P.[Liang-Pei],
Fusion of photogrammetric and photoclinometric information for high-resolution DEMs from Mars in-orbit imagery,
PandRS(130), No. 1, 2017, pp. 418-430.
Elsevier DOI 1708

Solarna, D., Gotelli, A., Le Moigne, J., Moser, G., Serpico, S.B.,
Crater Detection and Registration of Planetary Images Through Marked Point Processes, Multiscale Decomposition, and Region-Based Analysis,
GeoRS(58), No. 9, September 2020, pp. 6039-6058.
Feature extraction, Image registration, Mars, Image edge detection, Moon, Support vector machines, Remote sensing, Crater detection, wavelets BibRef

Douté, S., Jiang, C.,
Small-Scale Topographical Characterization of the Martian Surface With In-Orbit Imagery,
GeoRS(58), No. 1, January 2020, pp. 447-460.
Mars, Surface topography, Spatial resolution, Mathematical model, Cameras, Planetary orbits, Mars, image processing, surface processes, topography BibRef

Wilhelm, T.[Thorsten], Geis, M.[Melina], Püttschneider, J.[Jens], Sievernich, T.[Timo], Weber, T.[Tobias], Wohlfarth, K.[Kay], Wöhler, C.[Christian],
DoMars16k: A Diverse Dataset for Weakly Supervised Geomorphologic Analysis on Mars,
RS(12), No. 23, 2020, pp. xx-yy.
DOI Link 2012

Chen, L.[Lu], Xu, Y.[Yi], Li, B.[Bo],
Comparitive Study of the Geomorphological Characteristics of Valley Networks between Mars and the Qaidam Basin,
RS(13), No. 21, 2021, pp. xx-yy.
DOI Link 2112

Hsu, C.Y.[Chia-Yu], Li, W.W.[Wen-Wen], Wang, S.[Sizhe],
Knowledge-Driven GeoAI: Integrating Spatial Knowledge into Multi-Scale Deep Learning for Mars Crater Detection,
RS(13), No. 11, 2021, pp. xx-yy.
DOI Link 2106

Kirk, R.L.[Randolph L.], Mayer, D.P.[David P.], Fergason, R.L.[Robin L.], Redding, B.L.[Bonnie L.], Galuszka, D.M.[Donna M.], Hare, T.M.[Trent M.], Gwinner, K.[Klaus],
Evaluating Stereo Digital Terrain Model Quality at Mars Rover Landing Sites with HRSC, CTX, and HiRISE Images,
RS(13), No. 17, 2021, pp. xx-yy.
DOI Link 2109

Sutton, S.S.[Sarah S.], Chojnacki, M.[Matthew], McEwen, A.S.[Alfred S.], Kirk, R.L.[Randolph L.], Dundas, C.M.[Colin M.], Schaefer, E.I.[Ethan I.], Conway, S.J.[Susan J.], Diniega, S.[Serina], Portyankina, G.[Ganna], Landis, M.E.[Margaret E.], Baugh, N.F.[Nicole F.], Heyd, R.[Rodney], Byrne, S.[Shane], Tornabene, L.L.[Livio L.], Ojha, L.[Lujendra], Hamilton, C.W.[Christopher W.],
Revealing Active Mars with HiRISE Digital Terrain Models,
RS(14), No. 10, 2022, pp. xx-yy.
DOI Link 2206

Kirk, R.L.[Randolph L.], Fergason, R.L.[Robin L.], Redding, B.L.[Bonnie L.], Galuszka, D.M.[Donna M.], Smith, E., Mayer, D.P.[David P.], Hare, T.M.[Trent M.], Gwinner, K.[Klaus],
Evaluating Stereo DTM Quality At Jezero Crater, Mars with Hrsc, Ctx, And Hirise Images,
DOI Link 2012

Wu, X.[Xing], Zhang, X.[Xia], Mustard, J.[John], Tarnas, J.[Jesse], Lin, H.L.[Hong-Lei], Liu, Y.[Yang],
Joint Hapke Model and Spatial Adaptive Sparse Representation with Iterative Background Purification for Martian Serpentine Detection,
RS(13), No. 3, 2021, pp. xx-yy.
DOI Link 2102

Liu, J.[Jia], Yue, Z.[Zongyu], Di, K.C.[Kai-Chang], Gou, S.[Sheng], Niu, S.L.[Sheng-Li],
A Study about the Temporal Constraints on the Martian Yardangs' Development in Medusae Fossae Formation,
RS(13), No. 7, 2021, pp. xx-yy.
DOI Link 2104

Wang, Y.[Ying], Feng, X.[Xuan], Zhou, H.Q.[Hao-Qiu], Dong, Z.[Zejun], Liang, W.J.[Wen-Jing], Xue, C.[Cewen], Li, X.T.[Xiao-Tian],
Water Ice Detection Research in Utopia Planitia Based on Simulation of Mars Rover Full-Polarimetric Subsurface Penetrating Radar,
RS(13), No. 14, 2021, pp. xx-yy.
DOI Link 2107

Shozaki, H.[Hiroki], Sekine, Y.[Yasuhito], Guttenberg, N.[Nicholas], Komatsu, G.[Goro],
Recognition and Classification of Martian Chaos Terrains Using Imagery Machine Learning: A Global Distribution of Chaos Linked to Groundwater Circulation, Catastrophic Flooding, and Magmatism on Mars,
RS(14), No. 16, 2022, pp. xx-yy.
DOI Link 2208

Xiao, H.F.[Hai-Feng], Stark, A.[Alexander], Chen, H.[Hao], Oberst, J.[Jürgen],
Recomputation and Updating of MOLA Geolocation,
RS(14), No. 9, 2022, pp. xx-yy.
DOI Link 2205
MOLA: Mars Orbiter Laser Altimeter. BibRef

Han, S.T.[Song-Tao], Man, H.J.[Hai-Jun], Wang, M.[Mei], Zhou, Z.J.[Zhi-Jin], Cao, J.F.[Jian-Feng], Gao, W.[Wei], Chen, L.[Lue], Ping, J.S.[Jin-Song],
Analysis and Demonstration of First Cross-Support Interferometry Tracking in China Mars Mission,
RS(14), No. 16, 2022, pp. xx-yy.
DOI Link 2208

Dai, Y.Q.[Yu-Qi], Zheng, T.[Tie], Xue, C.B.[Chang-Bin], Zhou, L.[Li],
SegMarsViT: Lightweight Mars Terrain Segmentation Network for Autonomous Driving in Planetary Exploration,
RS(14), No. 24, 2022, pp. xx-yy.
DOI Link 2212

Oliva, F.[Fabrizio], d'Aversa, E.[Emiliano], Bellucci, G.[Giancarlo], Carrozzo, F.G.[Filippo Giacomo], Lozano, L.R.[Luca Ruiz], Karatekin, Ö.[Özgür], Daerden, F.[Frank], Thomas, I.R.[Ian R.], Ristic, B.[Bojan], Patel, M.R.[Manish R.], Lopez-Moreno, J.J.[José Juan], Vandaele, A.C.[Ann Carine], Sindoni, G.[Giuseppe],
Minimum Noise Fraction Analysis of TGO/NOMAD LNO Channel High-Resolution Nadir Spectra of Mars,
RS(15), No. 24, 2023, pp. 5741.
DOI Link 2401

Koßmann, D.[Dominik], Matei, A.[Arthur], Wilhelm, T.[Thorsten], Fink, G.A.[Gernot A.],
Image Augmentations in Planetary Science: Implications in Self-Supervised Learning and Weakly-Supervised Segmentation on Mars,
Mars, Image segmentation, Self-supervised learning, Task analysis, Remote sensing BibRef

Panambur, T.[Tejas], Chakraborty, D.[Deep], Meyer, M.[Melissa], Milliken, R.[Ralph], Learned-Miller, E.G.[Erik G.], Parente, M.[Mario],
Self-Supervised Learning to Guide Scientifically Relevant Categorization of Martian Terrain Images,
Space vehicles, Mars, Image recognition, Navigation, Databases, Taxonomy, Self-supervised learning BibRef

Kirk, R.L., Mayer, D., Redding, B.L., Galuszka, D.M., Fergason, R.L., Hare, T.M., Gwinner, K.,
Further Adventures in Mars DTM Quality: Smoothing Errors, Sharpening Details,
ISPRS21(B3-2021: 659-666).
DOI Link 2201

Muller, J.P., Tao, Y., Putri, A.R.D., Conway, S.J.,
3d Multi-resolution Mapping of Mars Using CASP-GO on HRSC, CRISM, CTX and HIRISE,
ISPRS21(B3-2021: 667-671).
DOI Link 2201

Hess, M., Wohlfarth, K., Grumpe, A., Wöhler, C., Ruesch, O., Wu, B.,
Atmospherically Compensated Shape From Shading On The Martian Surface: Towards The Perfect Digital Terrain Model of Mars,
DOI Link 1912

Christoff, N.[Nicole], Manolova, A.[Agata], Jorda, L.[Laurent], Viseur, S.[Sophie], Bouley, S.[Sylvain], Mari, J.L.[Jean-Luc],
Level-Set Based Algorithm for Automatic Feature Extraction on 3D Meshes: Application to Crater Detection on Mars,
Springer DOI 1810

Muller, J.P.[Jan-Peter], Tao, Y.[Yu], Sidiropoulos, P.[Panagiotis], Gwinner, K.[Klaus], Willner, K.[Konrad], Fanara, L.[Lida], Waehlisch, M.[Marita], van Gasselt, S.[Stephan], Walter, S.[Sebastian], Steikert, R.[Ralf], Schreiner, B.[Bjoern], Ivanov, A.[Anton], Cantini, F.[Federico], Wardlaw, J.[Jessica], Morley, J.[Jeremy], Sprinks, J.[James], Giordano, M.[Michele], Marsh, S.[Stuart], Kim, J.[Jungrack], Houghton, R.[Robert], Bamford, S.[Steven],
EU-FP7-Imars: Analysis Of Mars Multi-resolution Images Using Auto-coregistration, Data Mining And Crowd Source Techniques: Processed Results: A First Look,
ISPRS16(B4: 453-458).
DOI Link 1610

Campbell, J.[Jacqueline], Sidiropoulos, P.[Panagiotis], Muller, J.P.[Jan-Peter],
IR Spectral Mapping Of The Martian South Polar Residual Cap Using Crism,
ISPRS16(B7: 71-75).
DOI Link 1610
Detecion of Polycyclic aromatic hydrocarbons. BibRef

Barata, T.[Teresa], Alves, E.I.[E. Ivo], Saraiva, J.[José], Pina, P.[Pedro],
Automatic Recognition of Impact Craters on the Surface of Mars,
ICIAR04(II: 489-496).
Springer DOI 0409

Chapter on Cartography, Aerial Images, Buildings, Roads, Terrain, Forests, Trees, ATR continues in
Moon, Lunar Treeain, Lunar Analysis, Martian Terrain .

Last update:Jan 30, 2024 at 20:33:16