Blue Origin to launch NASA’s new moon-landing technology into space

  • Blue Origin, the rocket company owned by Jeff Bezos, is about to launch a test flight to try out new moon-landing technologies for NASA.
  • NASA developed high-precision sensors, software, and a new computer to help spacecraft land in rocky or shadowy areas of the moon or Mars.
  • It paid Blue Origin $3 million to test those new technologies.
  • If they work as planned, the landing systems should deliver the company’s New Shepard rocket safely back to Earth on Tuesday.
  • You can watch the 12-minute launch and landing live.
  • Visit Business Insider’s homepage for more stories.

Jeff Bezos’s rocket company, Blue Origin, is preparing to launch a suite of new high-precision moon-landing technologies into space for NASA, then test their mettle with a touchdown back on Earth.

The company’s New Shepard rocket is set to lift off from a launchpad in West Texas at 8:35 a.m. CDT on Tuesday. From there, it should rocket 62 miles into the air — reaching the boundary between Earth’s atmosphere and outer space — to briefly expose the NASA hardware to the space environment. The rocket will also release a capsule containing cargo for other companies, then descend back to Earth.

blue origin new shepard rocket booster landing

The New Shepard booster lands after the vehicle’s sixth consecutive flight Dec. 11, 2019.


Blue Origin



If NASA’s sensor systems, computer, and software perform as planned, they should land the rocket safely 12 minutes after launch.

NASA hopes to one day use the new landing systems it’s testing to send human missions to the moon, set up a permanent base there, and eventually land astronauts on the treacherous Martian landscape.

The larger system is called SPLICE, short for Safe and Precise Landing – Integrated Capabilities Evolution. It’s designed to help future moon missions land with better accuracy and safety — no pilot required. It could even enable future spacecraft to land in boulder fields or shadowy craters that thus far have been considered too hazardous for a safe landing. That capability would open up miles of the lunar surface, along with areas on other planets like Mars.

blue origin human lunar landing hls system moon descent national team hires

An illustration of lunar-landing hardware for NASA’s Artemis program conceived of by National Team: a business collaboration led by Blue Origin between Lockheed Martin, Northrop Grumman, and Draper.

Blue Origin/National Team


“Testing SPLICE technologies on a suborbital rocket expands the envelope beyond previous lab tests, helicopter field tests, and lower-altitude suborbital rocket tests,” John Carson, who works on precision landing technology at NASA’s Johnson Space Center, said in a September news release.

The test flight was originally scheduled for September 24, but Blue Origin scrubbed it, citing a power-supply issue. The company also canceled its planned second attempt the following day, saying it needed to “verify a fix on a technical issue.”

This is the first of two flight tests that Blue Origin will conduct through NASA’s Tipping Point program, which awarded six private companies a total of $44 million to help push next-generation technologies over the finish line. Blue Origin got $3 million for the project that’s culminating in Tuesday’s test launch. The company also received $10 million to test a propulsion system that would use ultra-cold liquid fuels to land a robot on the moon.

New sensors and computers to respond to the lunar terrain

nasa blue origin moon landing splice system

NASA’s SPLICE descent and landing computer (foreground) undergoes preparations for a flight test.


Blue Origin



The Blue Origin flight will only test some elements of the SPLICE technology suite: two sensor systems, landing algorithms, and a new computer.

The first set of sensors is meant to help spacecraft navigate the terrain where they might land. The system could enable a moon lander to determine its exact location by comparing real-time data from its camera to a set of surface maps pre-uploaded to the computer.

The other sensor system, a Doppler lidar, is designed to beam lasers to the surface of a planet and use the returning reflections to calculate the spacecraft’s landing speed and altitude. This system is slated to fly on two commercial lunar robotic missions in 2021, including the lander that will carry NASA’s new rover to the moon — the first such landing since the Apollo program ended in 1972.

astrobotic griffin moon lander lunar rover viper

An illustration shows Astrobotic’s Griffin lunar lander deploying a ramp on the moon’s surface.


Astrobotic



NASA designed the new technologies so they could work together or separately, allowing the agency to pick and choose the elements required for particular missions. The Blue Origin flight will test how the elements work together in a new spacecraft.

“The sensor data is all processed via the descent and landing computer,” Carson said. “Lots of other software runs in the background, integrating the different systems, figuring out what needs to run next, and, for this test, synchronizing timing with the Blue Origin flight computer. It’s all crucial so the system can run autonomously and provide us with data that we can analyze post-flight.”

NASA plans to trial a third sensor system — which would scan the surface of a planet to detect hazards and choose safer landing spots — in future testing.

Here is Blue Origin’s live feed of the test flight, which will start broadcasting 30 minutes before launch: 

 

NASA will also air the event on its live broadcast:

Dave Mosher contributed reporting.

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