This past month I've been working on another project outside of my Arctic radar thesis work: my first planetary mission experience! I've had the pleasure to be involved a 2-week imaging campaign for HiRISE - the highest resolution imager in Mars orbit. Many of you have heard me mention that I've been working on HiRISE lately, so here is some explanation of what that means.
HiRISE (High Resolution Imaging Science Experiment) is an instrument on the Mars Reconaissance Orbiter (MRO), which has been in orbit since 2006. As the MRO orbits Mars, HiRISE takes very high resolution images (~25-30cm/pixel) of the surface of Mars. These images are used for geological mapping, interpreting surface features, and even exploring both the science and safety of candidate landing sites for future Mars missions.
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| Artist rendition of the Mars Reconnaissance Orbiter. Credit: NASA |
HiRISE imaging cycles are two weeks long, but before the actual imaging happens, we need to do a lot of prep work. Planning of this cycle (#259) was led by Dr. Livio Tornabene at University of Western Ontario (a science team member of, and a former targeting specialist for HiRISE) and included a team consisting of post-doc Eric Pilles, fellow M.Sc candidate Arya Bina, and myself (Elise Harrington, if you need reminding of who's blog you are reading). In essence, we performed the role of CIPP during this cycle. CIPP stands for "Co-I of the Pay Period" and is the person responsible for the scientific priorities of the mission. Together, we decided what types of features on Mars we wanted to image, where the images should be placed (mostly based on previous science team and public targeted suggestions), how big the images should be, and what image settings or resolution would be most effective for the objective outlined by the suggestor. For a given cycle, we work in conjunction with the HiTS (i.e. a HiRISE Targeting Specialist) to maximize and optimize the images we take within data, orbit, and instrument health constraints. The HiTS is responsible for making sure our science plan is both viable and achievable with respect to our restrictions (e.g. instrument health, orbit path, flight rules, data volume that can be sent back to Earth, etc.) and generates the final commands that are sent to NASA/JPL to radiate to the spacecraft.
Oh man, did we ever have a lot of constraints this mission! We had quite a few challenges placed before us right from the start. First of all, we were not able to roll the spacecraft most of the time. When I write "roll" I literally mean that the Mars Reconnaissance Orbiter would be performing a partial barrel roll in space. Without this capability we can't turn to take images off our orbital track, and are only able to plan a few images that were not directly below MRO. Images taken directly below spacecrafts are referred to as nadir. Google eloquently defines nadir as "the point on the celestial sphere directly below an observer". Remember that term, because it applies to radar imaging, too!
So, why were we roll-restricted? Because of the present position of Mars, the Sun, and Earth, the solar panels and communication antenna are arranged in such a way, that rotating would cause the antenna to hit the solar panels. "Stop hitting yourself, MRO!"
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| The coloured patch in the centre of the map, and the right image is an example of what CRISM data look like. The different colours show possible relative abundances of different minerals. This example shows relative abundances of phyllosilicate clay minerals in Mawrth Vallis. Clays are water-bearing minerals, and are important in studying the past habitability of Mars. Because of this clay abundance, Mawrth Vallis is one of many candidate landing sites for the upcoming ExoMars mission. Credit: NASA/JPL/JHUAPL |
Finally, each cycle HiRISE has an allotted amount of downlink. This is the amount of data we are able to send back to Earth during our cycle. We need to share total downlink with the other instruments. This cycle we have ~200 GB, which is about half of what we originally expect. Remember that odd configuration that would cause MRO to hit itself if it rolled? Well, it was a specifically unique time in which it also impacted our data volume. Oh well, c'est la vie.
To make matters worse, it was also the peak of dust storm season on Mars. We were careful to monitor the global dust activity to makesure we don't accidentally take pictures that are hazy. Fortunately, no serious dust storms have kicked up so far.
Despite all these restrictions, we've been doing really well! Below are more of the images we have taken thus far. Bare in mind that these are not true-colour images, i.e. the colours aren't what you would see if you were looking down at the surface of Mars with your own eyes. Instead, they are false-colour infrared images, meaning we are using infrared wavelengths to highlight some distinct rocks or sediments that you wouldn't see as clearly otherwise. We've taken a lot of great images so far, with many more to come this week!
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| This is the first image I planned, and was the second image we took this cycle. Here there is two or more types of exposed bedrock in Terra Sabaea. NASA/JPL/University of Arizona. |
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| The second image that I personally planned, this time north of Hellas Planitia. It captures contacts between different types of bedrock, overlain by sand dunes. We are far enough north of Hellas Planitia to not be affected by the dust storms. NASA/JPL/University of Arizona. |
All the images we have acquired this cycle will be publicly available on the HiRISE website in the next couple weeks. You can see a few more that we've taken on the CPSX Twitter and Facebook.
I wonder if we could use HiRISE colour images and/or CRISM data to make the same band ratios of Mars as Maria made of Axel Heiberg...? Are the wavelengths at all similar? It could be a new way to look for salt on Mars.
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