Space Exploration Technologies

A Pair of CubeSats Using Ground Penetrating Radar Could Map The Interior of Near Earth Asteroids

Characterizing near-Earths asteroids (NEAs) is critical if we hope to eventually stop one from hitting us. But so far, missions to do so have been expensive, which is never good for space exploration. So a team led by Patrick Bambach of the Max Planck Institute for Solar System Research in Germany developed a mission concept that utilizes a relatively inexpensive 6U CubeSat (or, more accurately, two of them) to characterize the interior of NEAs that would cost only a fraction of the price of previous missions. 

The mission, known as the Deep Interior Scanning CubeSat mission to a rubble pile near-Earth asteroid, or DISCUS, was initially floated in 2018. Its central architecture involves two separate 6U CubeSats equipped with a powerful radar. They would travel to opposite sides of an NEA and direct a radar to pass through the NEA’s interior.

To understand more about the mission architecture, it’s best to look at the type of asteroid best suited to being visited by DISCUS. The authors suggest one about the size of Itokawa, the target of the first Hayabusa mission. It’s about 330 meters in diameter, right in the size range the mission planners were looking for, and is designated as a “rubble pile,” meaning the interior is relatively sparse.

Understanding how to stop an asteroid strike is one of DISCUS’s primary mission drivers. Fraser discusses how we can do it.

A sparse interior is critical to the mission objectives, as an asteroid’s density can dramatically impact the scientific toolkit needed to characterize it. For DISCUS, the mission team plans a radar antenna known as a half-dipole. This would transmit at a relatively low frequency, which is more likely to pass through larger objects. Additionally, they plan to use a radar technique known as stepped-frequency modulation, which changes the radar’s frequency to allow for the broadest range of characterizations.

The opposing spacecraft on the other side of the asteroid would then receive these radar signals, analyze whatever waveform deformations occurred, and correlate that to the materials the radar had to pass through. Calculations show that this technique should enable a resolution of a few tens of meters for the interior of an asteroid about the size of Itokawa.

However, they also have to be run through another spectral analysis technique called computed radar tomography. This technique is often used in radiology diagnoses on Earth—the name CT scan comes from—but it can also be used to analyze the interiors of solid objects in the solar system.

The radar techniques DISCUS uses are also used on Earth, as described in this video on bistatic radar.
Credit – Nicole Bienert YouTube Channel

However, the science payload is only one part of the DISCUS package and would ideally only take up 1U of the 6U allotted on each probe. The other five would be taken up by a series of off-the-shelf components, including a propulsion system (2U), communication system (1U), and avionics suite (1U). The dipole antenna and solar panels would deploy outside the standard CubeSat housing, allowing for better power collection and signal strength.

One of the most critical selections is the propulsion system, which would enable an acceleration of around 3.2 km/s, allowing DISCUS to match speeds with at least some NEAs. Alternatively, the mission plans to slingshot the craft around the Moon to get a boost of up to 4 km/s and gain access to even more asteroids.

A particular asteroid stood out to the team as they developed the mission design in 2018. Asteroid 1993 BX3 came within 18.4 times the distance to the Moon back in 2021 and was traveling at a speed that DISCUS could match, so the mission design team was hoping to have a prototype up and running to allow for a launch to that particular asteroid.

Unfortunately, that didn’t happen, and there hasn’t been much work on the mission concept since the paperback in 2018. However, more and more missions are targeting NEAs, and CubeSats are becoming increasingly popular. Eventually, a CubeSat mission will visit one of these objects and likely will be based at least partially on some ideas from DISCUS.

Learn More:
Bambach et al. – DISCUS – The Deep Interior Scanning CubeSat mission to a rubble pile near-Earth asteroid
UT – Swarms of Orbiting Sensors Could Map An Asteroid’s Surface
UT – Swarming Satellites Could Autonomous Characterize an Asteroid
UT – Asteroid Samples Were Once Part of a Wetter World

Lead Image:
This illustration shows the ESA’s Hera spacecraft and its two CubeSats at the binary asteroid Didymos. Image Credit: ESA

Andy Tomaswick

Recent Posts

James Webb Confirms Hubble’s Calculation of Hubble’s Constant

We have been spoiled over recent years with first the Hubble Space Telescope (HST) and…

9 hours ago

What Should Light Sails Be Made Out Of?

The Breakthrough Starshot program aims to cross the immense distances to the nearest star in…

9 hours ago

A Giant Meteorite Impact 3.26 Billion Years Ago Helped Push Life Forward

The Earth has always been bombarded with rocks from space. It’s true to say though…

10 hours ago

America’s Particle Physics Plan Spans the Globe — and the Cosmos

RALEIGH, N.C. — Particle physicist Hitoshi Murayama admits that he used to worry about being…

21 hours ago

Millions of Phones Could Map the Earth’s Ionosphere

We are all familiar with the atmosphere of the Earth and part of this, the…

22 hours ago

Detecting Primordial Black Hole Mergers Might be Within Our Grasp

One explanation for dark matter is that it's made out of primordial black holes, formed…

1 day ago