The laser that transmits between NASA’s Psyche
spacecraft and Earth-based observatories for the Deep Space Optical
Communications experiment successfully reaches its target thanks, in part, to a
vibration isolation platform developed by Controlled Dynamics Inc., and
supported by several Space Technology Mission Directorate programs.
NASA/JPL-Caltech
One year ago today, the future of space communications arrived at Earth as
a beam of light from a NASA spacecraft nearly 10 million miles away. That’s 40
times farther than our Moon. That’s like using a laser pointer to track a
moving dime from a mile away. That’s pretty precise.
That laser — transmitted from
NASA’s DSOC (Deep Space Optical Communications) technology demonstration — has
continued to hit its target on Earth from record-breaking distances.
“NASA’s Deep Space Optical
Communications features many novel technologies that are needed to precisely
point and track the uplink beacon and direct the downlink laser,” said Bill
Klipstein, DSOC project manager at NASA’s Jet Propulsion Laboratory in Southern
California.
One of the technologies aiding that
extremely precise pointing was invented by a small business and fostered by
NASA for more than a decade.
Whole Lotta
Shakin’ Going On (Not!)
Part of the challenge with the
precision pointing needed for DSOC was isolating the laser from the
spacecraft’s vibrations, which would nudge the beam off target. Fortunately for
NASA, Controlled Dynamics Inc. (CDI), in Huntington Beach, California, offered
a solution to this problem.
The company had a platform designed
to isolate orbiting experiments from vibrations caused by their host
spacecraft, other payloads, crew movements, or even their own equipment. Just
as the shocks on a car provide a smoother ride, the struts and actuators on
CDI’s vibration isolation platform created a stable setting for delicate
equipment.
This idea needed to be developed
and tested first to prove successful.
The Path to
Deep Space Success
NASA’s Space Technology Mission
Directorate started supporting the platform’s development in 2012 under
its Game
Changing Development program with follow-on support from the SBIR (Small Business Innovation Research) program.
The technology really began to take off — pun intended — under NASA’s
Flight Opportunities program. Managed out of NASA’s Armstrong Flight Research Center in
Edwards, California, Flight Opportunities rapidly demonstrates promising
technologies aboard suborbital rockets and other vehicles flown by
commercial companies.
Early flight tests in 2013
sufficiently demonstrated the platform’s performance, earning CDI’s
technology a spot on the International Space Station in 2016. But the flight testing didn’t end
there. A rapid series of flights with Blue Origin, UP Aerospace, and Virgin
Galactic put the platform through its paces, including numerous boosts and
thruster firings, pyrotechnic shocks, and the forces of reentry and landing.
“Flight Opportunities was instrumental in our development,” said Dr. Scott Green, CDI’s co-founder and the platform’s principal investigator. “With five separate flight campaigns in just eight months, those tests allowed us to build up flight maturity and readiness so we could transition to deep space.”
The vibration isolation platform developed by
Controlled Dynamics Inc., and used on the Deep Space Optical Communications
experiment conducted numerous tests through NASA’s Flight Opportunities
program, including this flight aboard Virgin Galactic’s VSS Unity in February
2019.
Virgin Galactic
The culmination of NASA’s investments in CDI’s vibration isolation platform
was through its Technology Demonstration Missions program, which along with NASA’s SCaN (Space Communications and Navigation) program supported NASA’s Deep
Space Optical Communications.
On Oct. 13, 2023, DSOC launched
aboard the Psyche
spacecraft, a mission managed by JPL. The CDI isolation platform provided DSOC with
the active stabilization and precision pointing needed to successfully
transmit a high-definition video of Taters the cat and other sample data from record-breaking
distances in deep space.
“Active stabilization of the flight
laser transceiver is required to help the project succeed in its goal to
downlink high bandwidth data from millions of miles,” said Klipstein. “To do
this, we need to measure our pointing and avoid bumping into the spacecraft
while we are floating. The CDI struts
gave us that capability.”
The Deep Space Optical Communications technology
demonstration’s flight laser transceiver is shown at NASA’s Jet Propulsion
Laboratory in Southern California in April 2021. The transceiver is mounted on
an assembly of struts and actuators — developed by Controlled Dynamics Inc. —
that stabilizes the optics from spacecraft vibrations. Several Space Technology
Mission Directorate programs supported the vibration isolation technology’s
development.
NASA/JPL-Caltech
Onward Toward Psyche
The Psyche spacecraft is expected
to reach its namesake metal-rich asteroid located between Mars and Jupiter by
August 2029. In the meantime, the DSOC project team is celebrating recognition
as one of TIME’s Inventions of 2024 and expects the experiment to continue adding to
its long list of goals met and exceeded in its first year.
By Nancy Pekar
NASA’s Flight Opportunities Program
Loura Hall
Source: Precision Pointing Goes the Distance on NASA Experiment
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