OSIRIS-REx spacecraft keeps its eyes on the prize

  • OSIRIS-REx's PolyCam has a focus mechanism that allows it to refocus from infinity to about 150 metres. Image credit: University of Arizona/Symeon Platts
  • The spacecraft will store the images captured by OCAMS and send them to the OSIRIS-REx team every few days. Image credit: University of Arizona/Symeon Platts
  • Scientists housed the cameras in a suit of armour made from solid titanium and aluminium. Image credit: University of Arizona/Symeon Platts
  • The OSIRIS-REx Camera Suite, responsible for most of the visible light images that will be taken by the spacecraft. Image credit: University of Arizona/Symeon Platts
Date:24 August 2017 Tags:, , , ,

Retrieving an asteroid sample is no easy task. Doing the job blindfolded is even more challenging. That’s why scientists equipped the OSIRIS-REx spacecraft with a set of eyes to watch it all unfold.

By Sarah Schleider, NASA Goddard Space Flight Centre

NASA’s Origins, Spectral Interpretation, Resource Identification, Security-Regolith Explorer (OSIRIS-REx) launched on 8 September 2016, and is travelling to a near-Earth asteroid known as Bennu, to harvest a sample of surface material, and return it to Earth for study. A trio ofcameras will capture it all.

The OSIRIS-REx Camera Suite, or OCAMS, consists of three cameras. PolyCam is a high-resolution camera that will acquire the first images of Bennu. It will also perform an initial mapping of the asteroid. MapCam is a medium-resolution camera that will map the asteroid in colour and search for satellites and dust plumes. SamCam will document the sampling process. The spacecraft will store the images captured by OCAMS and send them to the OSIRIS-REx team every few days.

Scientists designed the camera suite to be functionally redundant, meaning that if one of the cameras fails during the mission, the other two cameras can stand in.

“When you have a critical mission like this, you want redundancy,” said Christian d’Aubigny, OCAMS deputy instrument scientist at the University of Arizona, Tucson. “The cameras have some amount of overlap in their capabilities. They’re not exact copies of each other, but if one fails, they can still get the job done.”

The first camera to see Bennu is called PolyCam. Similar to a polymath PolyCam can perform a wide range of optical tasks. (A polymath is a human skilled at doing several different things. Leonardo da Vinci is one of the more famous polymaths.)

Once PolyCam performs an initial mapping of the asteroid. Thereafter scientists can use the camera to identify a site where the spacecraft might collect a sample of Bennu’s surface that is as free of hazards as possible, such as boulders and dramatic slopes.

“Already, at about three kilometres, we’re dividing the surface of the asteroid into ‘go’ and ‘no go’ places,” said Bashar Rizk, OCAMS instrument scientist at the University of Arizona. “If a place is covered with hazards, we’re just not going to go there because we don’t want to risk damaging the spacecraft.”

The second camera to get a glimpse of Bennu is called MapCam. This camera has a wider field of view than PolyCam and is equipped with a number of colour filters in its wheel. This will help the scientists identify locations on the asteroid where specific minerals of interest may be present. They are particularly looking for those those that may have once been in contact with liquid water.

MapCam will also look for satellites and dust plumes, which may present a hazard to the spacecraft. There are a number of suspected mechanisms for plume formation. These include:

  • sublimation, in which a frozen substance transitions directly to a gas without first passing through the liquid phase,
  • and electromagnetic levitation due to electrical charging from solar wind as the asteroid gets closer to the sun.

“Asteroids are exposed to a lot of solar radiation because they have no atmosphere,” Rizk said. “They’re just mercilessly tortured by the sun every time they go around it.”

Due to a lack of water on the surface, the scientists predict that Bennu’s regolith – a layer of loose material, including dust, soil and broken rock – is very dry, similar to the surface of the moon. The surface material can easily stick to things, increasing the risk of contaminating the OSIRIS-REx spacecraft during sampling.

Dust contamination is of particular concern to the spacecraft’s third camera; SamCam. This camera is a low-resolution, wide-angle camera designed to get up close and personal with the asteroid to document the sampling acquisition. SamCam must be able to retain its sample functionality for up to three attempts.

To combat this potential threat, the team at the University of Arizona furnished SamCam with multiple copies of the same filter, which are placed in front of the camera optics to act as a cover. The filters help ensure that the camera has a dust-free, unobstructed viewing of the sampling event in case sampling needs to be repeated.

The team also had to account for radiation from gamma rays and X-rays when designing OCAMS. Scientists housed the cameras in a suit of armour made from solid titanium and aluminium. These materials can block the radiation OSIRIS-REx will encounter during the mission. The lenses are made of materials, such as silicon dioxide, that are radiation resistant, as well as a number of other types of glass that are infused with cerium, which prevents the glass from turning opaque when exposed to high levels of radiation.

“We tried to think of everything that the spacecraft might be subjected to and account for that,” Rizk said. “It’s a multi-step process of simulations, testing and design to ensure that the cameras work properly and that we get the best images we can.”

OSIRIS-REx’s eyes are a critical part of retrieving an asteroid sample. Samples enable scientists to investigate how planets formed and how life began. It could also improve our understanding of asteroids that might impact Earth.

More about OSIRIS-REx

– It has a focus mechanism that allows it to refocus from infinity to about 150 m. This provides PolyCam with the ability to switch from detecting stars and asteroids from far away to resolving small pebbles on the surface of the asteroid.

– It has better visual acuity, or sharpness of vision, than an eagle. Several eagle species can see small objects such as prey from as far as 3 km away. But with its high resolution, PolyCam can acquire images of similarly sized objects on Bennu. At a range of between 48,2 to 96,5 kilometres can determine its shape. This will help scientists figure out how to manoeuver the spacecraft around the asteroid.

– A collaborative team of engineers and scientists at the University of Arizona’s Lunar and Planetary Laboratory and the College of Optical Sciences and the Utah State University’s Space Dynamics Laboratory spent four and a half years designing and building OCAMS.

Find out more about OSIRIS-REx’s asteroid sample return mission: