Scheme of the architecture for the planned Deep Space Optical Communications (DSOC) prototype

Deep Space Optical Communications (DSOC) is a laser space communication system in operation that improved communications performance 10 to 100 times over radio frequency technology without incurring increases in mass, volume or power.[1] DSOC is capable of providing high bandwidth downlinks from beyond cislunar space.

The project is led by NASA's Jet Propulsion Laboratory (JPL) in Pasadena, California.

Overview

Future human expeditions may require a steady stream of high-definition imagery, live video feeds, and real-time data transmission across deep space to enable timely guidance and updates during the long-distance journeys.[1] Even at its maximum data rate of 5.2 megabits per second (Mb/s), the Mars Reconnaissance Orbiter (MRO) requires 7.5 hours to transmit all of its onboard recorder, and 1.5 hours to send a single HiRISE image to be processed back on Earth. New high-resolution hyperspectral imagers put further demands on their communications system, requiring even higher data rates.[2]

The precursor technology demonstration for this optical transceiver was launched in 2023 on board NASA's robotic Psyche mission to study the giant metal asteroid known as 16 Psyche. The laser beams from the spacecraft will be received by the 200 inch (5 m) Hale Telescope at Palomar Observatory in California.[3] Laser beams to the spacecraft will be sent from a smaller telescope at the Table Mountain Observatory in California.

First light was achieved on 14 November 2023.[4]

The first video successfully beamed from space using the technology occurred on 11 December, 2023 from a record-setting 19 million miles away (31 million kilometers, or about 80 times the Earth-Moon distance).[5]

Design

This new technology will employ advanced lasers in the near-infrared region (1.55 µm[6]) of the electromagnetic spectrum.[1] The architecture is based on transmitting a laser beacon from Earth to assist line-of-sight stabilization and pointing back of the downlink laser beam. In addition, efficient codes are used for error free communications. The system must correct for background noise (scattered light) from Earth's atmosphere and the Sun.[7] Given the current hardware (1 m ground transmit, 5 m ground receive, 22 cm spacecraft telescope), the uplink is expected to reach 292 kbit/s at a distance of 0.4 astronomical units (60,000,000 km; 37,000,000 mi), with the downlink reaching 100 Mbit/s at the same distance.[8] The transmitted beam-width is inversely proportional to the frequency used, so the shorter the wavelength used, the narrower and more focused a beam can be made.[2] The downlink bandwidth will depend on the ground telescope diameter and will be less during daytime.[8]

Three key DSOC technologies developed for the project include:[6][7]

  • a low-mass spacecraft disturbance isolation and pointing assembly for operating in the presence of spacecraft vibrational disturbance.
  • a high-efficiency flight laser transmitter;
  • a pair of high-efficiency photon counting detector arrays for the flight optical transceiver and the ground-based receiver (a telescope).[7]
Data rates required for deep space missions in the coming decades
Flight laser transmitterGround systems
Laser: 4 W
Wavelength: 1550 nm
Uplink:
• Telescope (1 m)
• 5 kW power
• Wavelength 1064 nm
Telescope: 22 cm aperture
Capable of pointing up to 3 degrees of Sun
Downlink:
• 5 m telescope
• Operates day or night
• Can point within 12 degrees of Sun
Mass: <29 kg[8]
Power: <100 W

Psyche mission

A Deep Space Optical Communication demonstration is included with NASA's Psyche mission, launched on October 13, 2023. The Psyche spacecraft will explore the metal asteroid 16 Psyche, reaching the asteroid belt in 2029.[9][10][11]

DSOC first light was achieved on November 14, 2023. The experiment successfully transmitted a 15-second ultra-high definition video on December 11 from a location 19 million miles away from Earth (31 million kilometers, or about 80 times the Earth-Moon distance). The pre-loaded video of a cat named Taters was sent at the system’s maximum bit rate of 267 megabits per second (Mbps) and took 101 seconds to reach Earth.[12]

See also

References

  1. 1 2 3 Deep Space Optical Communications (DSOC). Jennifer Harbaugh, NASA News 24 October 2017.
  2. 1 2 Deep Space Communications. NASA, 2017.
  3. Hall, Loura, ed. (October 18, 2017). ""Lighten Up" – Deep Space Communications via Faraway Photons". NASA. Public Domain This article incorporates text from this source, which is in the public domain.
  4. "Earth Just Received a Laser-Beamed Message from 16 Million Kilometers Away". 20 November 2023.
  5. "NASA's Tech Demo Streams First Video from Deep Space via Laser". Jet Propulsion Laboratory.
  6. 1 2 Deep Space Optical Communications (PDF). Tom Glavich, NASA. 28 July 2015.
  7. 1 2 3 Game Changing Development: Deep Space Optical Communications (DSOC) (PDF). Jet Propulsion Laboratory, NASA.
  8. 1 2 3 Deep Space Optical Communications (DSOC) (PDF). Overview Poster. Biswas NASA July 2014.
  9. David, Leonard (18 October 2017). "Deep Space Communications via Faraway Photons". NASA / Jet Propulsion Laboratory. Retrieved 4 November 2017.
  10. Greicius, Tony (14 September 2017). "Psyche Overview". NASA. Retrieved 18 September 2017.
  11. "NASA's Psyche Mission on Track for Liftoff Next Month". NASA. 6 September 2023. Retrieved 19 September 2023.
  12. "NASA's Tech Demo Streams First Video From Deep Space via Laser". NASA/JPL-Caltech. December 18, 2023.
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