Deep Space Atomic Clock

The miniaturized Deep Space Atomic Clock, for precise and real-time radio navigation in deep-space

The Deep Space Atomic Clock (DSAC) is a miniaturized, ultra-precise mercury-ion atomic clock for precise radio navigation in deep-space. It is orders of magnitude more stable than existing navigation clocks, and has been refined to limit drift of no more than 1 nanosecond in 10 days.^[1] It is expected that a DSAC would incur no more than 1 microsecond of error in 10 years of operations.^[2] It is expected to improve the precision of deep-space navigation, and enable more efficient use of tracking networks. The project is managed by NASA's Jet Propulsion Laboratory.

Overview

Current ground-based atomic clocks are fundamental to deep space navigation; however, they are too large to be flown in space. This results in tracking data being collected and processed here on Earth (a two-way link) for most deep-space navigation applications.^[2] The Deep Space Atomic Clock (DSAC) is a miniaturized and stable mercury ion atomic clock that is as stable as a ground clock. ^[2] The technology could enable autonomous radio navigation for spacecraft's time-critical events such as orbit insertion or landing, promising new savings on mission operations costs.^[1] It is expected to improve the precision of deep-space navigation, enable more efficient use of tracking networks, and yield a significant reduction in ground support operations.^[1]^[3]

Its applications in deep space include:^[2]

Simultaneously track two spacecraft on a downlink with the Deep Space Network (DSN)
Improve tracking data precision by an order of magnitude using the DSN's Ka-band downlink tracking capability.
Mitigate Ka-band's weather sensitivity (as compared to two-way X band) by being able to switch from a weather-impacted receiving antenna to one in a different location with no tracking outages.
Track longer by using a ground antenna's entire spacecraft viewing period. At Jupiter, this yields a 10 to 15 percent increase in tracking; at Saturn, it grows to 15 to 25%, with the percentage increasing the farther a spacecraft travels.
Make new discoveries as a Ka-band—capable radio science instrument with a 10 times improvement in data precision for both gravity and occultation science and deliver more data because of one-way tracking's operational flexibility.
Explore deep space as a key element of a real-time autonomous navigation system that tracks one-way radio signals on the uplink and, coupled with optical navigation, provides for robust absolute and relative navigation.
Fundamental to human explorers requiring real-time navigation data.

Principle and development

Over 20 years, engineers at NASA's Jet Propulsion Laboratory have been steadily improving and miniaturizing the mercury-ion trap atomic clock.^[4] The DSAC technology uses the property of mercury ions' hyperfine transition frequency at 40.50 GHz to effectively "steer" the frequency output of a quartz oscillator to a near-constant value. DSAC does this by confining the mercury ions with electric fields in a trap and protecting them by applying magnetic fields and shielding.^[2]^[5]

Approximate dimensions: 29 cm × 26 cm × 23 cm ^[5]
Mass: 17.5 kg
Power: 44 W

Its development will include a test flight in low-Earth orbit in March 2017,^[6]^[7] while using GPS signals to demonstrate precision orbit determination and confirm its performance in radio navigation. It will be deployed as part of the U.S. Air Force's Space Test Program 2 (STP-2) mission aboard a Space X Falcon Heavy rocket.^[8]

References

1 2 3 Boen, Brooke (January 16, 2015). "Deep Space Atomic Clock (DSAC)". NASA. Retrieved 2015-10-27.
1 2 3 4 5 "Deep Space Atomic Clock" (PDF). NASA. 2014. Retrieved 2015-10-27.
↑ "NASA to test atomic clock to keep space missions on time". NASA (Gizmag). 30 April 2015. Retrieved 2015-10-28.
↑ "Technology Demonstration Missions: Deep Space Atomic Clock (DSAC)". Jet Propulsion Laboratory. NASA. 16 January 2015. Retrieved 2015-10-28.
1 2 "DSAC (Deep Space Atomic Clock)". NASA (Earth Observation Resources). 2014. Retrieved 2015-10-28.
↑ Stephen Clark [StephenClark1] (2016-03-01). "Payload officials with satellites aboard STP-2 mission (second Falcon Heavy) say launch has slipped from Oct. 2016 to March 2017." (Tweet).
↑ David, Leonard (April 13, 2016). "Spacecraft Powered by 'Green' Propellant to Launch in 2017". Space. Retrieved 2016-04-15.
↑ "Deep Space Atomic Clock". NASA's Jet Propulsion Laboratory (NASA). 27 April 2015. Retrieved 2015-10-28.

External links

DSAC: Description and Nominal Mission Operations

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