It's difficult to understand the significance of those numbers without some comparisons. Everything about the Curiosity landing site selection process has been so much easier than it was for Spirit and Opportunity. When Spirit and Opportunity landed, we had far inferior understanding of the dynamics of Mars' atmosphere compared to what the subsequent decade of Mars exploration has given us. JPL's navigators could position Spirit and Opportunity's entrance into the top of Mars' atmosphere with high precision. But once the spacecraft penetrated any distance into it, the uncertainty in its density and in its wind speeds and directions produced a large uncertainty in how rapidly the atmosphere would slow the rovers' descent.

That uncertainty, coupled with the fact that the rovers' parachute-assisted descent was entirely ballistic -- meaning there was no steering whatsoever -- meant that at one point during the landing site selection process, the region in which Spirit and Opportunity could possibly land was a very long, skinny ellipse, roughly 15 kilometers wide but a whopping 160 kilometers long. There were very few geologically interesting places on Mars with safe, rock-free, hill-free, dune-free, dust-free areas of that size. Gale crater was actually considered as a landing site but the 150-kilometer crater with its tall central mountain was not big enough; they couldn't guarantee a 400-million-dollar rover wouldn't smash into the central mountain or walls on landing.

The shrinking of Curiosity's landing ellipse puts its center considerably closer to the mountain in the middle of Gale crater than it used to be. Curiosity's handlers estimate that that will reduce the rover's traverse time from landing site to mountain base by about four months -- not bad at all, considering that the nominal mission is one year. Ironically, there's a small number of Mars geologists who are slightly chagrined about this. While it's great to be so much closer to the real target, it means that Curiosity may miss the opportunity to play with one type of rock that would have been interesting to see along the way, the alluvial fans that spilled off of the northern walls of Gale crater. But I think most geologists are happy to pay that price in order to have so much more time at the mountain.

So that was the good news. The bad news: there's a lurking problem with the drilling system, in that there are materials including Teflon and molybdenum disulfide (if I understood John Grotzinger correctly) that wind up getting mixed with the sampled rock and delivered to the science instruments. They're working to understand its nature and develop workarounds; to do so, they've had to build two more drill test facilities in addition to the one they already had. Grotzinger was actually discussing ways to use the scoop only to get uncontaminated samples. I know that journalists like Dick Kerr and Dan Vergano have their hooks into this story, so I'll be looking for their reports later to see what specifics they dig up.

The last bit of bad news: Mars Odyssey is in safe mode, and it has to do with one of its reaction wheels. (Those stupid things cause problems on so many missions.) Like most spacecraft, Odyssey has four reaction wheels to help it control its orientation. Reaction wheels are spinning weights; by slowing or speeding their spin, Odyssey uses electrical power (which is renewable) rather than thrusters (whose fuel is not) to pivot. Three wheels are mounted perpendicular to each other, with a fourth, backup one at a slant to them all. One of the three primary wheels is sticky; in fact, last weekend, as it was going through zero spin (switching from one spin direction to the other), it stuck for several minutes before restarting, and that's what triggered the safe mode.

Clearly, Odyssey has options. They can try to keep using the sticky wheel; they can turn off the sticky wheel and begin using the slanted backup; they can just use thrusters, if need be. So Odyssey will be up and running again in a few days. But it will take them a few days to evaluate which option is best. Until then, Opportunity has no Odyssey data relay capability, which will slow them down, just as they had started driving again. Too bad, but those rocks in Meridiani aren't going anywhere; we'll just have to be patient.

Anyway, as a spacecraft, Curiosity is super healthy, so all looks as good now for landing day as it ever has. I'm anxious, though; landing on Mars is hard. And even after a successful landing, I'm going to be anxious for the mission. This mission has so very many tiny details, so many things to work out and get going before Curiosity can really drive anywhere. I'm worried that the great story of our Martian exploration adventure is going to get lost among those details, and the inevitable setbacks that will happen as Curiosity's mission begins and they try to do new things. Curiosity will be rolling toward the mountain eventually, but it may not be fast enough for an impatient public.

So, rover fans, I'm giving you a responsibility. You need to help with two things after Curiosity's landing. First: don't lose sight of the big picture. We are exploring Mars with the biggest rover ever, following up more than 40 years of discovery; it's one of our greatest adventures. Second: Curiosity's mission will be long, and will start slowly. I plan to describe it like this: Curiosity is going to be scaling Mount Everest. You don't land in India and immediately start walking; you need to set up a base camp first. There will be a base camp phase for Curiosity as she works out all her operational kinks and warms up her instruments. Only then will the driving begin. But, parked or driving, we're exploring Mars!