Celebrations in the mission control room at JPL in Pasadena, CA after confirmation of InSight's successful landing came through. |
InSight uses updated versions of technology that was first included on the Phoenix Mars lander, which successfully landed on Mars a decade ago (2008). To reduce the risks of future missions, NASA likes to select missions that make use of any instrument or mission piece that has already flown on a mission and worked. These missions components are called heritage pieces because they have been inherited down to a newer mission from an older one. The instruments are never exactly the same, even if scientists and engineers want them to be--manufacturers discontinue electronics, technologies improve, etc. Engineers are responsible for extensively testing every single mechanical aspect of the mission in a number of ways--extreme heat, extreme cold, and high radiation are only a few of the environmental factors that a space mission will experience in its lifetime. Of course, the instruments must not only survive, they need to work too, and it's much better to work out issues ahead of time than after launch.
Testing the robotic arm that will deploy the SEIS instrument. Photo credit: NASA/JPL/Caltech |
InSight launched on May 5, 2018 from Vandenberg Air Force Base in California, a location on the coast in between San Francisco and Los Angeles. Most NASA missions launch from Cape Canaveral in Florida, though some launch from the Wallops Island Flight Facility in Maryland, so InSight is unusual in this regard. Vandenberg was selected because of its good positioning to aim the spacecraft to enter the Mars atmosphere at the correct angle of 12 degrees. Any steeper and the mission would burn up. Any shallower and the mission would "bounce" off the top of the atmosphere and continue off into deep space, lost forever. It was 12 degrees, or failure. If anything, this illustrates to me that there are many precise calculations that go into making every single decision on a NASA mission, and one miscalculation could cost the whole mission.
After 6 months and 301 million miles, InSight finally entered Mars' atmosphere at a perfect 12 degree angle. Much has been written and said about what happened during the landing, so we'll point you to one of our favorites instead of rehashing it here. In about 3 month InSight will deploy its own instruments, including the seismometer and an instrument that will drill 16 feet down into Mars' crust to study the thermal environment of Mars beneath the surface.
Just to prove that it made it to the surface, InSight was programmed to take a couple of pictures at the surface and send them back to us here on Earth. Its relay system is the Mars Cube One (MarCO), an important first for this mission as well. MarCO are two 6U cube sat missions that was designed to relay messages back and forth between Earth and InSight on Mars while it was going through its landing process. What is a cube sat? Generally the larger a mission is, the more expensive it is. A cube sat is a mission that is roughly the size of a shoebox, and it's a type of mission that has become more popular in the past 5 years because they are small, quick and easy to build, and inexpensive. A "U" is a shorthand to refer to the size of a cube sat mission, where a U is a cube with 10 cm sides. A 6U cube sat, therefore, is one that is 30 cm long, 20 cm wide, and 10 cm tall. MarCO was a test to see how well cube sats would work in a deep space environment, one that it passed with flying colors. This will pave the way for future cube sat add-on components to larger missions and even individual cube sat missions (see LunaH-Map here).
All of these accomplishments were the results of years of hard work by its team members and the mission failures that happened before. We thank all the scientists and engineers who have study and do study Mars, and all the people who support them, and wish them all many congratulations! Here's to future breakthroughs on Mars!