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Laser Communications Relay Demonstration (LCRD) Overview


The Laser Communications Relay Demonstration payload is attached to the LCRD Support Assembly Flight (LSAF),
The Laser Communications Relay Demonstration payload is attached to the LCRD Support Assembly Flight (LSAF), which can be seen in this image. The LSAF serves as the backbone for the LCRD components. Attached to the LSAF are the two optical modules, which generate the infrared lasers that transmit data to and from Earth. A star tracker is also attached here. These components are visible on the left side of this image. Other LCRD components, such as the modems that encode data into laser signals, are attached to the back of the LSAF. u003cstrongu003eCredits: NASA’s Goddard Space Flight Centeru003c/strongu003e

The Laser Communications Relay Demonstration (LCRD) aims to showcase the unique capabilities of optical communications. Currently, most NASA missions use radio frequency communications to send data to and from spacecraft. Radio waves have been used in space communications since the beginning of space exploration and have a proven track record of success. However, as space missions generate and collect more data, the need for enhanced communications capabilities becomes paramount.

Optical communications is one of these enhancements and will provide significant benefits for missions, including bandwidth increases of 10 to 100 times more than radio frequency systems. Additionally, optical communications provides decreased size, weight, and power requirements. A smaller size means more room for science instruments. Less weight means a less expensive launch. Less power means less drain on the spacecraft’s batteries. With optical communications supplementing radio, missions will have unparalleled communications capabilities.

The LCRD payload is hosted aboard the U.S. Department of Defense’s Space Test Program Satellite 6 (STPSat-6). After launch Dec. 7, 2021, engineers at LCRD’s mission operations center in Las Cruces, New Mexico, turned the payload on and prepared it to start transmitting data over infrared lasers. Until its first user is launched, LCRD will practice sending test data to and from its ground stations. This test data will be sent up through radio frequency signals from the mission operations center and then the LCRD spacecraft will reply over optical signals. This test data will include spacecraft health data; tracking, telemetry, and command data; and sample user data to ensure LCRD is properly operating.

Future missions in space will send data to LCRD, which will then relay the data down to designated ground stations on Earth. NASA has been leveraging communications relay satellites since 1983 when the first Tracking and Data Relay Satellite launched. With relays, missions are not required to have direct line-of-sight to antennas on Earth, increasing communications coverage. LCRD creates a continuous path for data flowing from missions in space to ground stations on Earth, making a complete end-to-end system. Additionally, LCRD’s ability to both send and receive data from missions and the ground stations makes the system two-way. Together, these capabilities make LCRD NASA’s first two-way, end-to-end optical relay.

Unlike radio frequency communications, optical signals cannot penetrate cloud coverage, so NASA must build a system flexible enough to avoid interruptions due to weather. LCRD will transmit data received from missions to two ground stations, located in Table Mountain, California, and Haleakalā, Hawaii. These locations were chosen for their minimal cloud coverage. LCRD will test different cloud coverage scenarios, gathering valuable information about the flexibility of optical communications.

LCRD is a technology demonstration that will pave the way for future optical communications missions. Future missions that decide to use optical communications could potentially use LCRD as their relay. One of LCRD’s first operational users will be the Integrated LCRD Low-Earth Orbit User Modem and Amplifier Terminal (ILLUMA-T), a payload that will be hosted on the International Space Station. The terminal will receive high-resolution science data from experiments and instruments onboard the space station and then transfer this data to LCRD, which will then transmit it to a ground station. After the data arrives on Earth, it will be delivered to mission operation centers and mission scientists.


  • On Dec. 7, 2021, LCRD launched from the Cape Canaveral Space Force Station in Florida. The payload, hosted on the U.S. Department of Defense’s STPSat-6 spacecraft, launched aboard a United Launch Alliance Atlas V 551 rocket.
  • On Jan. 22, 2020, the LCRD flight payload was delivered to Northrop Grumman’s facility in Sterling, Virginia, for integration onto the U.S. Department of Defense Space Test Program Satellite 6 (STPSat-6).
  • On July 7, 2020, the LCRD payload was fully integrated with U.S. Department of Defense’s STPSat-6 and the entire spacecraft entered into the final environmental testing phase.

Fast facts

LCRD in space.
  • With LCRD relaying data for ILLUMA-T, this will be the first operational optical communications system for human spaceflight. ILLUMA-T will send data to LCRD at rates of 1.2 gigabits per second over optical links, allowing for more high-resolution experiment data to be transmitted back to Earth.
  • LCRD will be able to downlink data over optical signals at a rate of 1.2 gigabits per second. This is almost double the rates of the 2013 Lunar Laser Communications Demonstration, which downlinked data from the Moon over an optical signal of 622 megabits per second.
  • Although optical communications systems reduce size, weight, and power requirements, the entire LCRD payload is actually the size of a standard king-sized mattress!


LCRD is funded and managed through NASA’s Technology Demonstration Missions program, part of the Space Technology Mission Directorate, and the Space Communications and Navigation (SCaN) program at NASA Headquarters.

LCRD was developed by NASA’s Goddard Space Flight Center and is flying aboard a U.S. Department of Defense Space Force spacecraft. Throughout the development process, the NASA LCRD team worked closely with the Space Force as well as commercial partners like Northrop Grumman and the Massachusetts Institute of Technology (MIT) Lincoln Laboratory, a Federally Funded Research and Development Center. Northrop Grumman performed integration and testing of the payload and spacecraft, while MIT Lincoln Laboratory provided the instrument designs for LCRD and verified all of the NASA-developed builds.

More information

STEM Launch Kit

Multimedia Resources

NASA Launch Photos


For Researchers:

Through the LCRD experiment proposal process, the LCRD project seeks supplemental experiments to help test the functionality of optical communications links. Researchers interested in LCRD and the LCRD guest experimenter program can learn more here.

For news media:

Members of the news media interested in covering this topic should get in touch with the Space Communications and Navigation (SCaN) media contact at NASA’s Goddard Space Flight Center, listed here.

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