A new laser-pointing platform developed at MIT may help launch miniature satellites into the high-rate data game.
Since 1998, almost 2,000 shoebox-sized satellites known as CubeSats have been launched into space. Due to their petite frame and the fact that they can be made from off-the-shelf parts, CubeSats are significantly more affordable to build and launch than traditional behemoths that cost hundreds of millions of dollars.
CubeSats have become game-changers in satellite technology, as they can be sent up in flocks to cheaply monitor large swaths of the Earth’s surface. But as increasingly capable miniaturized instruments enable CubeSats to take highly detailed images, the tiny spacecraft struggle to efficiently transmit large amounts of data down to Earth, due to power and size constraints.
The new laser-pointing platform for CubeSats, which is detailed in the journal Optical Engineering , enables CubeSats to downlink data using fewer onboard resources at significantly higher rates than is currently possible. Rather than send down only a few images each time a CubeSat passes over a ground station, the satellites should be able to downlink thousands of high-resolution images with each flyby.
“To obtain valuable insights from Earth observations, hyperspectral images, which take images at many wavelengths and create terabytes of data, and which are really hard for CubeSats to get down, can be used,” says Kerri Cahoy, associate professor of aeronautics and astronautics at MIT. “But with a high-rate lasercom system you’d be able to send these detailed images down quickly. And I think this capability will make the whole CubeSat approach, using a lot of satellites in orbit so you can get global and real-time coverage, more of a reality.”
Cahoy, who is the Rockwell International Career Development Associate Professor at MIT, is a co-author on the paper, along with graduate student Ondrej Cierny, who is the lead author.
Satellites typically downlink data via radio waves, which for higher rate-links are sent to large ground antennas. Every major satellite in space communicates within high-frequency radio bands that enable them to transmit large amounts of data quickly. But bigger satellites can accommodate the larger antenna dishes or arrays needed to support a high rate downlink. CubeSats are too small, and also have limited access to frequency bands that could support high-rate links.
“Small satellites can’t use these bands, because it requires clearing a lot of regulatory hurdles, and allocation typically goes to big players like huge geostationary satellites,” Cahoy says.
What’s more, the transmitters required for high-rate data downlinks can use more power than miniature satellites can accommodate while still supporting a payload. For these reasons, researchers have looked to lasers as an alternative form of communication for CubeSats, as they are significantly more compact in size and are more power efficient, packing much more data in their tightly focused beams.
But laser communications also present a significant challenge: Because the beams are much more narrow than the beams from radio waves, it takes far more precision to point the beams at a receiver on the ground.
NASA’s Optical Communications and Sensor Demonstration uses a CubeSat laser communications system that essentially tips and tilts the entire satellite to align its laser beam with a ground station. But this steering system requires time and resources, and to achieve a higher data rate, a more powerful laser — which can use a large fraction of the satellite’s power and generate significant amounts of heat onboard — is needed.
Cahoy and her team looked to develop a precise laser-pointing system that would minimize the amount of energy and time required for a downlink, and enable the use of lower-power, narrower lasers yet still achieve higher data transmission rates.
The team developed a laser-pointing platform, slightly larger than a Rubik’s Cube, that incorporates a small, off-the-shelf, steerable MEMS mirror. The mirror, which is smaller than a single key on a computer keyboard, faces a small laser and is angled so that the laser can bounce off the mirror, into space, and down toward a ground receiver.
“Even if the whole satellite is a bit misaligned, you can still correct for that with this mirror,” Cierny says. “But these MEMS mirrors don’t give you feedback about where they’re pointing. Say the mirror is misaligned in your system, which can happen after some vibrations during launch. How can we correct for this, and know exactly where we’re pointing?”
As a solution, Cierny developed a calibration technique that determines by how much a laser is misaligned from its ground station target, and automatically corrects the mirror’s angle to precisely point the laser at its receiver.
The technique incorporates an additional laser color, or wavelength, into the optical system. So instead of just the data beam going through, a second calibration beam of a different color is sent through with it. Both beams bounce off the mirror, and the calibration beam passes through a “dichroic beam splitter,” a type of optical element that diverts a specific wavelength of light — in this case, the additional color — away from the main beam. As the rest of the laser light travels out toward a ground station, the diverted beam is directed back into an onboard camera. This camera can also receive an uplinked laser beam, or beacon, directly from the ground station; this is used to enable the satellite to point at the right ground target.