It’s been quite a year for laser communications in space. In October and November, NASA launched two pioneering demonstrations to test high-bandwidth optical communication links, and these tech demos are now showing some initial results.
On December 11, a laser communications terminal aboard NASA’s Psyche spacecraft on the way to an asteroid linked up with a receiver in Southern California. The near-infrared laser beam contained an encoded message in the form of a 15-second ultra-high-definition video showing a cat bouncing around a sofa, chasing the light of a store-bought laser toy.
Laser communications offer the benefit of transmitting data at a higher rate than achievable with conventional radio links. In fact, the Deep Space Optical Communications (DSOC) experiment on the Psyche spacecraft is testing technologies capable of sending data at rates 10 to 100 times greater than possible on prior missions.
“We’re looking to increase the amount of data we can get down to Earth, and that has a lot of advantages to us,” said Jeff Volosin, acting deputy associate administrator for NASA space communications and navigation program, before the launch of Psyche earlier this year.
Now, DSOC has set a record for the farthest distance a high-definition video has streamed from space. At the time, Psyche was traveling 19 million miles (31 kilometers) from Earth, about 80 times the distance between Earth and the Moon. Traveling at the speed of light, the video signal took 101 seconds to reach Earth, sent at the system’s maximum bit rate of 267 megabits per second, NASA said.
A playful experiment
After reaching the receiver at Palomar Observatory in San Diego County, each video frame was transmitted “live” to NASA’s Jet Propulsion Laboratory in Pasadena, California, where it was played in real time, according to NASA.
“One of the goals is to demonstrate the ability to transmit broadband video across millions of miles. Nothing on Psyche generates video data, so we usually send packets of randomly generated test data,” said Bill Klipstein, the tech demo’s project manager at JPL, in a statement. “But to make this significant event more memorable, we decided to work with designers at JPL to create a fun video, which captures the essence of the demo as part of the Psyche mission.”
The video of Taters, the orange tabby cat of a JPL employee, was recorded before the launch of Psyche and stored on the spacecraft for this demonstration. The robotic probe launched on October 13 aboard a SpaceX Falcon Heavy rocket, with the primary goal of flying to the asteroid Psyche, a metal-rich world in the asteroid belt between the orbits of Mars and Jupiter.
It will take six years for the Psyche probe to reach its destination, and NASA tacked on a laser communications experiment to help keep the spacecraft busy during the cruise. Since the launch in October, ground teams at JPL switched on the Deep Space Optical Communications (DSOC) experiment and ran it through some early tests.
One of the most significant technical challenges involved in the DSOC experiment was aligning the 8.6-inch (22-centimeter) optical telescope aboard Psyche with a transmitter and receiver fitted to ground-based telescopes in California and vice versa. Because Psyche is speeding through deep space, this problem is akin to trying to hit a dime from a mile away while the dime is moving, according to Abi Biswas, DSOC’s project technologist at JPL.
Once you achieve that feat, the signal that is received is still very weak and therefore requires very sensitive detectors and processing electronics which can take that signal and extract information that’s encoded in it,” Biswas said.
The telescope aboard Psyche is mounted on an isolation-and-pointing assembly to stabilize the optics and isolate them from spacecraft vibrations, according to NASA. This is necessary to eliminate jitters that could prevent a stable laser lock between Earth and the Psyche spacecraft.
“What optical or laser communications allows you is to achieve very high data rates, but on the downside, it’s a very narrow laser beam that requires very accurate pointing control,” Biswas told reporters before the launch. “For example, the platform disturbance from a typical spacecraft would throw off the pointing, so you need to actively isolate from it or control against it.
“For near-Earth missions, you can just control against it because you have enough control bandwidth,” he said. “From deep space, where the signals received are very weak, you don’t have that much control bandwidth, so you have to isolate from the disturbance.”
There’s another drawback of direct-to-Earth laser communications from space. Cloud cover over transmitting and receiving telescopes on Earth could block signals, so an operational optical communications network will require several ground nodes at different locations worldwide, ideally positioned in areas known for clear skies.