Experten kritisieren: Zu wenig Schutz gegen Luftangriffe
Seit dem Ukraine-Krieg steckt Deutschland viele zusätzliche Milliarden in die Bundeswehr. Doch zentrale Projekte dauerten zu lange, kritisieren Experten. Von Tim Diekmann.
Cathy Quantin-Nataf (Université Lyon1/France) and Alain Herique (Université Grenoble Alpes/France)
Context
The Martian missions have gradually revealed that Mars abounds with evidence of a full ancient hydrological system favorable to life emergence. If so, we can expect ancestral sedimentary deposits in basins or in the Martian lowlands. Recent advances in the analyses of the surface of Mars suggest that buried Noachian deposits may be ubiquitous and locally exhumed. Different dataset can be used to study buried layers including surficial data (optical or hyperspectral), but also orbital low frequency radar data from MARSIS/Mex and SHARAD/MRO. However, penetrating radar data are still little used for subsurface geological investigations while they are crucial complementary dataset to surface data. The main reason is that the surface clutter of the rough surface of Mars is creating many reflectors inducing an ambiguity in radargrams between deep reflectors of interest and slant surface reflectors arriving at the time. The deconvolution of the surface clutter is so crucial to interpret the data in terms of subsurface structures. The classical approach for such deconvolution is to use the global altimetry data set (200m/pix) (Nouvel et al 2003, Carter et al., 2009), but at this low spatial resolution, many clutters are missed. Optical DTMs provide better resolution. However, their use remains limited due to their coverage and the presence of artifacts (Desage et al., 2023).
The goal of this PhD project is to better use higher resolution terrain models (10m/pix) to simulate the surface clutter in the goal to highlight geological reflectors possibly linked to buried layers especially in the region of the Martian dichotomy (transition between Martian low and highlands) and to complementary analyze their 3D geological context.
Methodology and work program
SHARAD (Mars SHAllow RADar sounder, onboard Mars Reconnaissance Orbiter) ground penetrating radar has the ability to sound the first few hundred meters of the subsurface with a vertical resolution of 15m and a horizontal resolution of few hundred meters (Seu et al., 2007).
To better simulate the surface clutter and remove ambiguities, we need elevation data at higher spatial resolution but with a coverage large enough to cover around 50 km on both side of the radar track. CTX Digital Elevation Models (DEMs), obtained by stereo-photogrammetry of CTX images (Beyer et al., 2018; Michael C. Malin et al., 2007), are about 10m/pix and cover about 17% of the surface of Mars allowing in certain places mosaicking of DEMs larger than 100 km. For instance, such mosaic of CTX DEMs has been produced and used to characterize the landing site of ExoMars (Volat et al., 2023).
We have developed a new pipeline allowing the mosaicking CTX images around SHARAD track to simulate the surface clutter of the observed SHARAD data. The pipeline has been delivered but all the tests and use cases in different geological context still need to be done.
The familiarization with methods and pipeline is the first part of the PhD. Geophysical interpretations and/or automated data analysis methods will be developed by the second part. The study of Oxia Planum region will for instance contribute to the characterization of the ExoMars landing site while being a study case for the pipeline validation. Then, key locations of the surfaces of Mars along the Martian dichotomy will then be analyzed and interpreted.
Required skills
The subject is between physics and planetary geosciences. We expect candidate to have solid physical background and knowledge (or at least interest) in Geosciences. Experience with penetrating radar data is not mandatory but is an advantage.
Carter, L. M., Campbell, B. A., Watters, T. R., Phillips, R. J., Putzig, N. E., Safaeinili, A., et al. (2009). Shallow radar (SHARAD) sounding observations of the Medusae Fossae Formation, Mars. Icarus, 199(2), 295–302. https://doi.org/10.1016/j.icarus.2008.10.007
Beyer, R. A., Alexandrov, O., & McMichael, S. (2018). The Ames Stereo Pipeline: NASA’s Open Source Software for Deriving and Processing Terrain Data. Earth and Space Science.
Malin, Michael C., Bell, J. F., Cantor, B. A., Caplinger, M. A., Calvin, W. M., Clancy, R. T., et al. (2007). Context Camera Investigation on board the Mars Reconnaissance Orbiter. Journal of Geophysical Research E: Planets, 112(5), 1–25. https://doi.org/10.1029/2006JE002808
Seu, R., Phillips, R. J., Biccari, D., Orosei, R., Masdea, A., Picardi, G., et al. (2007). SHARAD sounding radar on the Mars Reconnaissance Orbiter. Journal of Geophysical Research E: Planets. https://doi.org/10.1029/2006JE002745
Volat, M; Quantin-Nataf, C; Dehecq, Digital elevation model workflow improvements for the MarsSI platform and resulting orthorectified mosaic of Oxia Planum, the landing site of the ExoMars 2022 rover, PLANETARY AND SPACE SCIENCE, 10.1016/j.pss.2022.105552, 2022
Desage L., Herique A., Douté S., Zine S., Kofman W., Resolving Ambiguities in SHARAD Data Analysis Using High-Resolution Digital Terrain Models, Remote sensing, https://doi.org/10.3390/rs15030764, 2023
The European Space Agency (ESA) ERS-2 satellite re-entered the Earth's atmosphere earlier today over the North Pacific Ocean. I used a lot of radar images from this satellite in years past, but I am happy that they were able to de-orbit it and reduce potential space junk. It was some luck that it fell over the 75% of the Earth that is ocean. #ers2#esa#radar https://www.esa.int/Space_Safety/Space_Debris/ERS-2_reenters_Earth_s_atmosphere_over_Pacific_Ocean
An article from the Gernsback magazine Radio-Craft, 04/1946. It's on Project Diana, an American project to be the first to bounce a radar signal off the Moon.
The author and man on the cover, was John H. DeWitt, asked by the Army if radar could penetrate the ionosphere to detect missiles in space. He went above and beyond, so to speak.
The idea of using the Moon as a reflector eventually led to this 1960 image of USS Hancock sent to D.C. from Honolulu via the lunar surface.
Durch Birkenblätterregen in den #Wald. Ich geb's auf, das wird nichts mehr mit #Pilzen dieses Jahr.
Schön war es trotzdem. Ein aufwallendes Rauschen der Bäume entpuppte sich als riiiiesiger Taubenschwarm.
Wo sind die Leute, die #Vogelschwärme auf #Radar erkennen? Aktuell muß der Himmel voller Vögel sein.
1951's Festival of Britain featured an unusual nod toward both past and future. The only old building on site was a shot tower (an obsolete way of making small lead balls) from 1826, on which they constructed a radio telescope.
The telescope was built by Leland Equipment assisted by Jodrell Bank. The plan was to allow visitors to see signals bouncing off the Moon, but they couldn't get it working during the Festival. It did later accomplish it after moving to Jodrell Bank.
In August, the Defence Forces of the southern part of Ukraine destroyed a Russian mobile coastal radar station for over-the-horizon detection Predel-E, worth $200 million.
IGPSport SR30 to nowoczesne i funkcjonalne urządzenie do poprawy bezpieczeństwa rowerzystów na drodze. Jest to połączenie inteligentnego radaru rowerowego z tylną lampą, które wykrywa zbliżające się pojazdy i ostrzega o nich za pomocą sygnałów wizualnych (z poziomu aplikacji / komputerka rowerowego) i dźwiękowych.
Ukrainian military destroy unique Russian radar station worth $200 million in Kherson Oblast (www.pravda.com.ua)
In August, the Defence Forces of the southern part of Ukraine destroyed a Russian mobile coastal radar station for over-the-horizon detection Predel-E, worth $200 million.