Wednesday, August 17, 2022

What’s Next: The Future of NASA’s Laser Communications - SPACE TECH


NASA uses lasers to send information to and from Earth, employing invisible beams to traverse the skies, sending terabytes of data – pictures and videos – to increase our knowledge of the universe. This capability is known as laser, or optical, communications, even though these eye-safe, infrared beams can’t be seen by human eyes.

“We are thrilled by the promise laser communications will offer in the coming years,” says Badri Younes, deputy associate administrator and program manager for Space Communications and Navigation (SCaN) at NASA Headquarters in Washington. “These missions and demonstrations usher in NASA's new Decade of Light in which NASA will work with other government agencies and the commercial sector to dramatically expand future communications capabilities for space exploration and enable vibrant and robust economic opportunities.”

Laser communications systems provide missions with increased data rates, meaning they can send and receive more information in a single transmission compared to traditional radio waves. Additionally, the systems are lighter, more flexible, and more secure. Laser communications can supplement radio frequency communications, which most NASA missions use today.

Illustration of TBIRD downlinking data over lasers links to Optical Ground Station 1 in California. Credits: NASA's Goddard Space Flight Center/Dave Ryan

Laser Communications Relay Demonstration (LCRD)

On Dec. 7, 2021, the Laser Communications Relay Demonstration (LCRD) launched into orbit, about 22,000 miles from Earth to test the capabilities of laser communications. LCRD is the agency’s first technology demonstration of a two-way laser relay system. Now that LCRD is in orbit, NASA’s laser communications advancements continue.

LCRD Experimenters Program

In May 2022, NASA certified that LCRD is ready to conduct experiments. These experiments are testing and refining laser systems — the mission’s overall goal. Experiments provided by NASA, other government agencies, academia, and industry are measuring the long-term effects of the atmosphere on laser communications signals; assessing the technology’s applicability for future missions; and testing on-orbit laser relay capabilities.

“We will start receiving some experiment results almost immediately, while others are long-term and will take time for trends to emerge during LCRD’s two-year experiment period,” said Rick Butler, project lead for the LCRD experimenters program at NASA’s Goddard Space Flight Center in Greenbelt, Maryland. “LCRD will answer the aerospace industry’s questions about laser communications as an operational option for high bandwidth applications.”

“The program is still looking for new experiments, and anyone who is interested should reach out,” said Butler. “We are tapping into the laser communications community and these experiments will show how optical will work for international organizations, industry, and academia.”

NASA is continuing to accept proposals for new experiments to help refine optical technologies, increase knowledge, and identify future applications.

LCRD will even relay data submitted by the public shortly after its launch in the form of New Year's resolutions shared with NASA social media accounts. These resolutions will be transmitted from a ground station in California and relayed through LCRD to another ground station located in Hawaii as yet another demonstration of LCRD’s capabilities.

Illustration of TBIRD downlinking data over lasers links to Optical Ground Station 1 in California. Credits: NASA's Goddard Space Flight Center/Dave Ryan

TeraByte InfraRed Delivery (TBIRD)

Recently following LCRD, the TeraByte InfraRed Delivery (TBIRD) payload launched on May 25, 2022, as part of the Pathfinder Technology Demonstrator 3 (PTD-3) mission, from Cape Canaveral Space Force Station on SpaceX’s Transporter-5 rideshare mission. TBIRD will showcase 200-gigabit-per-second data downlinks – the highest optical rate ever achieved by NASA.

TBIRD is continuing NASA’s optical communications infusion by demonstrating the benefits lasers communications could have for near-Earth science missions that capture important data and large detailed images. TBIRD is sending back terabytes of data in a single pass, demonstrating the benefits of higher bandwidth, and giving NASA more insight into the capabilities of laser communications on small satellites. TBIRD is the size of a tissue box!

“In the past, we’ve designed our instruments and spacecraft around the constraint of how much data we can get down or back from space to Earth,” said TBIRD Project Manager Beth Keer. “With optical communications, we’re blowing that out of the water as far as the amount of data we can bring back. It is truly a game-changing capability.”

Illustration of ILLUMA-T communicating science and exploration data from the International Space Station to LCRD. Credits: NASA's Goddard Space Flight Center/Dave Ryan

Integrated LCRD Low-Earth Orbit User Modem and Amplifier Terminal (ILLUMA-T)

Launching in early 2023 in the Dragon trunk of SpaceX’s 27th commercial resupply services mission to the International Space Station, the Integrated LCRD Low-Earth Orbit User Modem and Amplifier Terminal (ILLUMA-T) will bring laser communications to the orbiting laboratory and empower astronauts living and working there with enhanced data capabilities.

ILLUMA-T will gather information from experiments aboard the station and send the data to LCRD at 1.2 gigabits per second. At this rate, a feature-length movie could be downloaded in under a minute. LCRD will then relay this information down to ground stations in Hawaii or California.

“ILLUMA-T and LCRD will work together to become the first laser system to demonstrate low-Earth orbit to geosynchronous orbit to ground communications links,” said Chetan Sayal, project manager for ILLUMA-T at NASA Goddard.

Illustration of NASA's O2O laser communications terminal sending high-resolution data from the Artemis II mission. Credits: NASA

Orion Artemis II Optical Communications System (O2O)

The Orion Artemis II Optical Communications System (O2O) will bring laser communications to the Moon aboard NASA’s Orion spacecraft during the Artemis II mission. O2O will be capable of transmitting high-resolution images and video when astronauts return to the lunar region for the first time in over 50 years. Artemis II will be the first crewed lunar flight to demonstrate laser communications technologies, sending data to Earth with a downlink rate of up to 260 megabits per second.

“By infusing new laser communications technologies into the Artemis missions, we’re empowering our astronauts with more access to data than ever before,” said O2O Project Manager Steve Horowitz. “The higher the data rates, the more information our instruments can send home to Earth, and the more science our lunar explorers can perform.”

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NASA’s laser communications endeavors extend into deep space as well. Currently, NASA is working on a future terminal that could test laser communications against extreme distances and challenging pointing constraints.

Whether bringing laser communications to near-Earth missions, the Moon, or deep space, the infusion of optical systems will be integral for future NASA missions. Laser communications’ higher data rates will enable exploration and science missions to send more data back to Earth and discover more about the universe. NASA will be able to use information from images, video, and experiments to explore not just the near-Earth region, but to also prepare for future missions to Mars and beyond.

NASA's laser communications mission timeline. Credits: NASA's Goddard Space Flight Center/Dave Ryan

By Kendall Murphy
NASA's Goddard Space Flight Center, Greenbelt, Md.

Source: What’s Next: The Future of NASA’s Laser Communications | NASA


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