- The MOC is body-fixed to the spacecraft
- It has no independent pointing capability. It makes pictures the
same way a fax machine does (i.e., the scene is moved past the single
line detector).
- The MOC has a limited cross-track Field of View (FOV)
- The MOC has a very small field of view (0.44 degrees), which is about 3 km from the 400 km orbital altitude. It typically takes very small images at very high resolution (lots of data). Anything wider than 3 km cannot be imaged in its entirety.
- The MOC has a large but not "infinite" along-track Field of View
- The MOC's downtrack field of view is limited by the amount of data that will fit in its buffer (about 10 MB). If one uses the entire buffer (which is not likely to be completely empty unless it's planned to be) and 2:1 realtime predictive compression, this translates to a downtrack image length of about 15 km. The camera has been designed to be able to average pixels together to synthesize poorer resolution, which frees up data. Under the best case buffer availability, an 8X summed image would be 3 km wide (but only 256 pixels across) by about 78,000 pixels long which, at 12 m/pxl (8 X 1.5) would be over 800 km long. One of the big uncertainties in taking pictures of specific places on Mars is the uncertainty in when the spacecraft will pass over that place: the timing uncertainty of 40-120 seconds translates to 120 to 360 km uncertainty in position.
- The spacecraft has limited pointing control
- The spacecraft uses infra-red horizon sensors for in-orbit pointing control. Owing to variations in the IR flux of the horizon with latitude, season, surface topography, atmospheric dust content, cloudiness, and other meteorological and climatological conditions, the control capability is about 10 mrad (0.6 degrees = 4 km), which is larger than the MOC field of view.
- There will be a substantial uncertainty in the predicted
- The position of the spacecraft is determined by radio tracking for 8 hours (roughly 4.5 hours of actually seeing the spacecraft) a day, and by computing the position of the Earth, Mars, and the spacecraft in an inertial coordinate system. It takes a few days to do this, and to use it to determine where the spacecraft will be a few days later. By that time, gravity perturbations, atmospheric drag, and autonomous momentum unloadings will have changed the orbit. Error studies suggest that the uncertainty seven days after the end of a given period of tracking can be represented as (at best)a 40 second uncertainty in the time the spacecraft will be at a specific point in its orbit. This translates (at the orbital rate of the spacecraft projected on the ground of 3 km/s) to 120 km downtrack and (because Mars rotates at 0.24 km/s at the equator) 9.6 km crosstrack. At 40 degrees latitude, the crosstrack uncertainty is 7.4 km, over twice the size of the MOC field of view. At some times in the mission, when the orbit geometry is unfavorable, predictions will be worse.
- The
- The position of the spacecraft is determined inertially. As noted above, the position of the longitude/latitude grid is also uncertain to about 5-10 km.
- The spacing of orbits will be uncertain
- If, in spite of the preceding, orbits were equally spaced, then the average spacing of orbits at the equator for the 687 day mission would be about 2.5 km, which means that each spot on the equator would fall within the MOC field of view in (possibly) two images. In fact, the repeat distance is just over 3.1 km, again assuming equal spacing, and it is more than likely that each spot on the equator will only be seen once. At 40 degrees latitude, the spacing is roughly 2.4 km, and any location will be seen, at most, twice. Given Items 1-6 (above), it is most likely that some places will be overflown twice, and others not at all, and that our ability to predict this is very limited.
This discussion doesn't address the variability of the martian atmosphere, which is very dynamic. Given the occurrence of dust storms during some seasons, and polar clouds during others, there is no guarantee that, even when the spacecraft flies over a specific area, the ground will actually be visible.
Plans for Observing the "Face on Mars"
Despite providing a number of people involved with the "private" studies of the "Face of Mars" with exactly the same information presented above, there appears to be a continuing view that MOC will purposefully avoid taking pictures of the "Face" and other features. Much of their focus is on "conspiracies" they feel exist to keep information from the public. This, of course, isn't the case: if an image of the "Face" is acquired, it will most definitely be released. The "Face on Mars," "City," "Fortress," "Cliff," "Tholus," "D&M Pyramid," etc. are in the MOC target database. Image acquisitions will be scheduled each time the spacecraft is predicted to pass over each target. This is done automatically. Given the factors noted above, however, there is no certainty that the images will actually include the features of interest.
Output from planning software showing Cydonia "targets" (GIF = 252 KBytes)
Bottom Line
It is planned to try to acquire images of the "Face" and other features in Cydonia. Contrary to what some people have said and written, this has been the plan for some time. This plan was not established in response to outside pressure; rather, there are two reasons for acquiring these images. First, given the interest in the general public about the "Face," it is appropriate to acquire such images for public relations purposes, especially since the public interest has been generated in no small way by the people who claim there is a conspiracy at NASA to withhold information from the public. Second, there are valid scientific reasons to examine landforms in the area (which, after all, is why the Viking spacecraft were photographing the area in the first place).
Mars