NASA’s Optical Comms Demo Transmits Data Over 140 Million Miles

NASA’s Optical Comms Demo Transmits Data Over 140 Million Miles

6 min read

Preparations for Next Moonwalk Simulations Underway (and Underwater)

NASA’s Psyche spacecraft is shown in a clean room
NASA’s Psyche spacecraft is shown in a clean room at the Astrotech Space Operations facility near the agency’s Kennedy Space Center in Florida on Dec. 8, 2022. DSOC’s gold-capped flight laser transceiver can be seen, near center, attached to the spacecraft.
NASA/Ben Smegelsky

NASA’s Deep Space Optical Communications experiment also interfaced with the Psyche spacecraft’s communication system for the first time, transmitting engineering data to Earth.

Riding aboard NASA’s Psyche spacecraft, the agency’s Deep Space Optical Communications technology demonstration continues to break records. While the asteroid-bound spacecraft doesn’t rely on optical communications to send data, the new technology has proven that it’s up to the task. After interfacing with the Psyche’s radio frequency transmitter, the laser communications demo sent a copy of engineering data from over 140 million miles (226 million kilometers) away, 1½ times the distance between Earth and the Sun.

This achievement provides a glimpse into how spacecraft could use optical communications in the future, enabling higher-data-rate communications of complex scientific information as well as high-definition imagery and video in support of humanity’s next giant leap: sending humans to Mars.

“We downlinked about 10 minutes of duplicated spacecraft data during a pass on April 8,” said Meera Srinivasan, the project’s operations lead at NASA’s Jet Propulsion Laboratory in Southern California. “Until then, we’d been sending test and diagnostic data in our downlinks from Psyche. This represents a significant milestone for the project by showing how optical communications can interface with a spacecraft’s radio frequency comms system.”

This visualization shows the Psyche spacecraft’s position on April 8
This visualization shows the Psyche spacecraft’s position on April 8 when the DSOC flight laser transceiver transmitted data at a rate of 25 Mbps over 140 million miles to a downlink station on Earth.
NASA/JPL-Caltech

The laser communications technology in this demo is designed to transmit data from deep space at rates 10 to 100 times faster than the state-of-the-art radio frequency systems used by deep space missions today.

After launching on Oct. 13, 2023, the spacecraft remains healthy and stable as it journeys to the main asteroid belt between Mars and Jupiter to visit the asteroid Psyche.

Surpassing Expectations

NASA’s optical communications demonstration has shown that it can transmit test data at a maximum rate of 267 megabits per second (Mbps) from the flight laser transceiver’s near-infrared downlink laser — a bit rate comparable to broadband internet download speeds.

That was achieved on Dec. 11, 2023, when the experiment beamed a 15-second ultra-high-definition video to Earth from 19 million miles away (31 million kilometers, or about 80 times the Earth-Moon distance). The video, along with other test data, including digital versions of Arizona State University’s Psyche Inspired artwork, had been loaded onto the flight laser transceiver before Psyche launched last year.

Now that the spacecraft is more than seven times farther away, the rate at which it can send and receive data is reduced, as expected. During the April 8 test, the spacecraft transmitted test data at a maximum rate of 25 Mbps, which far surpasses the project’s goal of proving at least 1 Mbps was possible at that distance.

The project team also commanded the transceiver to transmit Psyche-generated data optically. While Psyche was transmitting data over its radio frequency channel to NASA’s Deep Space Network (DSN), the optical communications system simultaneously transmitted a portion of the same data to the Hale Telescope at Caltech’s Palomar Observatory in San Diego County, California — the tech demo’s primary downlink ground station.

“After receiving the data from the DSN and Palomar, we verified the optically downlinked data at JPL,” said Ken Andrews, project flight operations lead at JPL. “It was a small amount of data downlinked over a short time frame, but the fact we’re doing this now has surpassed all of our expectations.”

Fun With Lasers

After Psyche launched, the optical communications demo was initially used to downlink pre-loaded data, including the Taters the cat video. Since then, the project has proven that the transceiver can receive data from the high-power uplink laser at JPL’s Table Mountain facility, near Wrightwood, California. Data can even be sent to the transceiver and then downlinked back to Earth on the same night, as the project proved in a recent “turnaround experiment.”

This experiment relayed test data — as well as digital pet photographs — to Psyche and back again, a round trip of up to 280 million miles (450 million kilometers). It also downlinked large amounts of the tech demo’s own engineering data to study the characteristics of the optical communications link.

“We’ve learned a great deal about how far we can push the system when we do have clear skies, although storms have interrupted operations at both Table Mountain and Palomar on occasion,” said Ryan Rogalin, the project’s receiver electronics lead at JPL. (Whereas radio frequency communications can operate in most weather conditions, optical communications require relatively clear skies to transmit high-bandwidth data.)

JPL recently led an experiment to combine Palomar, the experimental radio frequency-optical antenna at the DSN’s Goldstone Deep Space Communications Complex in Barstow, California, and a detector at Table Mountain to receive the same signal in concert. “Arraying” multiple ground stations to mimic one large receiver can help boost the deep space signal. This strategy can also be useful if one ground station is forced offline due to weather conditions; other stations can still receive the signal.

More About the Mission

Managed by JPL, this demonstration is the latest in a series of optical communication experiments funded by the Technology Demonstration Missions (TDM) program under NASA’s Space Technology Mission Directorate and the agency’s SCaN (Space Communications and Navigation) program within the Space Operations Mission Directorate. Development of the flight laser transceiver is supported by MIT Lincoln Laboratory, L3 Harris, CACI, First Mode, and Controlled Dynamics Inc., and Fibertek, Coherent, and Dotfast support the ground systems. Some of the technology was developed through NASA’s Small Business Innovation Research program.

Arizona State University leads the Psyche mission. JPL is responsible for the mission’s overall management, system engineering, integration and test, and mission operations. Psyche is the 14th mission selected as part of NASA’s Discovery Program under the Science Mission Directorate, managed by the agency’s Marshall Space Flight Center in Huntsville, Alabama. NASA’s Launch Services Program, based at the agency’s Kennedy Space Center in Florida, managed the launch service. Maxar Technologies provided the high-power solar electric propulsion spacecraft chassis from Palo Alto, California.

For more information about the laser communications demo, visit:

https://www.jpl.nasa.gov/missions/dsoc

News Media Contacts

Ian J. O’Neill
Jet Propulsion Laboratory, Pasadena, Calif.
818-354-2649
ian.j.oneill@jpl.nasa.gov

2024-049      

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Anthony Greicius

Navigating the Moon with Art

Navigating the Moon with Art

In this black-and-white photo, a man in a white shirt and dark tie uses an airbrush to paint on a large model that looks like the surface of the Moon. A crater is in the foreground, emphasizing the large size of the Moon model.
NASA

An artist uses an airbrush to recreate the lunar surface on one of the four models comprising the LOLA, or Lunar Orbit and Landing Approach, simulator in this November 12, 1964, photo. Project LOLA was a simulator built at Langley to study problems related to landing on the lunar surface.

In “Spaceflight Revolution: NASA Langley Research Center From Sputnik to Apollo,” James Hansen wrote: “This simulator was designed to provide a pilot with a detailed visual encounter with the lunar surface; the machine consisted primarily of a cockpit, a closed-circuit TV system, and four large murals or scale models representing portions of the lunar surface as seen from various altitudes. The pilot in the cockpit moved along a track past these murals which would accustom him to the visual cues for controlling a spacecraft in the vicinity of the moon. Unfortunately, such a simulation–although great fun and quite aesthetic–was not helpful because flight in lunar orbit posed no special problems other than the rendezvous with the LEM, which the device did not simulate. Not long after the end of Apollo, the expensive machine was dismantled.”

Image Credit: NASA

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Monika Luabeya

Cosmonauts Begin Spacewalk for Hardware, Science Work

Cosmonauts Begin Spacewalk for Hardware, Science Work

Cosmonauts Oleg Kononenko (left) and Nikolai Chub (right) are pictured during a spacewalk on Oct.25, 2023, working on the Nauka science module.
Cosmonauts Oleg Kononenko (left) and Nikolai Chub (right) are pictured during a spacewalk on Oct.25, 2023, working on the Nauka science module.

Roscosmos cosmonauts Oleg Kononenko and Nikolai Chub began a spacewalk at 10:57 a.m. EDT to complete the deployment of one panel on a synthetic radar communications system on the Russian segment of the complex and install equipment and experiments to analyze the level of corrosion on station surfaces and modules.

NASA’s coverage will continue on NASA+, NASA Television, YouTube, the NASA app, and the agency’s website. Learn how to stream NASA TV through a variety of platforms including social media.

Kononenko is wearing an Orlan spacesuit with red stripes, while Chub is wearing the suit with blue stripes. This is the seventh spacewalk in Kononenko’s career, and the second for Chub. It is the 270th spacewalk for space station assembly, maintenance, and upgrades.


Learn more about station activities by following the space station blog@space_station and @ISS_Research on X, as well as the ISS Facebook and ISS Instagram accounts.

Get weekly video highlights at: https://roundupreads.jsc.nasa.gov/videoupdate/

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Mark Garcia

Roscosmos Spacewalkers Exiting Station Soon Live on NASA TV

Roscosmos Spacewalkers Exiting Station Soon Live on NASA TV

Cosmonauts Oleg Kononenko (left) and Nikolai Chub (right) are pictured during a spacewalk on Oct.25, 2023, to install and inspect hardware.
Cosmonauts Oleg Kononenko (left) and Nikolai Chub (right) are pictured during a spacewalk on Oct.25, 2023, to install and inspect hardware.

NASA Television coverage is underway for today’s spacewalk with Roscosmos cosmonauts Oleg Kononenko and Nikolai Chub. The duo will venture outside the station’s Poisk airlock to complete the deployment of one panel on a synthetic radar system on the Nauka module and install equipment and experiments on the Poisk module to analyze the level of corrosion on station surfaces and modules.

NASA’s coverage is on NASA+, NASA Television, YouTube, the NASA app, and the agency’s website. Learn how to stream NASA TV through a variety of platforms including social media.

Kononenko and Chub will exit at about 10:55 a.m. EDT. Kononenko is wearing the Orlan spacesuit with red stripes, while Chub is wearing the suit with blue stripes. This is the seventh spacewalk in Kononenko’s career, and the second for Chub. It is the 270th spacewalk for space station assembly, maintenance, and upgrades.


Learn more about station activities by following the space station blog@space_station and @ISS_Research on X, as well as the ISS Facebook and ISS Instagram accounts.

Get weekly video highlights at: https://roundupreads.jsc.nasa.gov/videoupdate/

Get the latest from NASA delivered every week. Subscribe here: www.nasa.gov/subscribe

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Mark Garcia

NASA, Boeing Crew Fly Jet to Florida for Starliner Launch

NASA, Boeing Crew Fly Jet to Florida for Starliner Launch

Photo of NASA, Boeing Crew Test astronauts Butch Wilmore and Suni Williams
Boeing Crew Flight Test astronauts Butch Wilmore and Suni Williams in T-38 pre-flight activities at Ellington Field on Tuesday, August 16, 2022. Photo credit: NASA/Robert Markowitz

The two NASA astronauts that will fly aboard a new spacecraft for the first time to the International Space Station are on their way on Thursday to the agency’s Kennedy Space Center in Florida to begin final launch preparations. 

NASA astronauts Butch Wilmore and Suni Williams are targeting 10:34 p.m. EDT Monday, May 6, for launch of the agency’s Boeing Crew Flight Test from Space Launch Complex-41 at Cape Canaveral Space Force Station in Florida. 

As retired U.S. Navy captains, Wilmore and Williams are flying on a T-38 jet from Ellington Field near NASA’s Johnson Space Center in Houston for the short flight to Kennedy’s Launch and Landing Facility. 

At 1 p.m., NASA will host a crew arrival event at the agency’s Kennedy Space Center in Florida, with the following participants:

  • Jennifer Kunz, associate director, NASA Kennedy 
  • Dana Hutcherson, deputy manager, NASA’s Commercial Crew Program 
  • NASA astronaut Butch Wilmore 
  • NASA astronaut Suni Williams

The arrival will air live on NASA+, NASA Television, the NASA app, YouTube, and the agency’s website. Learn how to stream NASA TV through a variety of platforms including social media. 

Following launch, the astronauts will spend about a week at the orbiting laboratory before the crew capsule makes a parachute and airbag-assisted landing in the southwestern United States. 

Learn more about NASA’s Boeing Crew Flight Test by following the mission blog, the commercial crew blog, @commercial_crew on X, and commercial crew on Facebook.

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Elyna Niles-Carnes