Add to ORKGThe Juno spacecraft conducted a successful gravity-assist flyby of the Earth on 09 October 2013, putting the spacecraft on a trajectory to reach Jupiter in July 2016. The DSN tracking was supplemented by tracking from two ESA stations, giving us an unprecedented, near continuous level of tracking for an interplanetary spacecraft flyby of Earth. We discuss the process of reconstructing that trajectory, the challenges encountered in that effort, and the results. In particular, no anomalous velocity change was observed at or near perigee as has been observed in some of the previous Earth gravity assist flybys by other spacecraft
This paper presents reconstruction of Voyager 2 trajectory to examine how the mission was optimised ...
The Juno gravity experiment, among the nine instruments onboard the spacecraft, is aimed at studying...
The satellite systems of Saturn and Jupiter are complex dynamical systems, with several interactions...
[EN] In the last decades there have been an increasing interest in improving the accuracy of spacecr...
The Juno spacecraft launched in August 2011 and, following a successful Earth flyby in October 2013,...
Juno has been in a highly elliptical (average eccentricity e=0.95), nearly polar, 53-day orbit aroun...
In 2016 the spacecraft Juno completed its first three perijove passes, respectively on Aug. 27 (PJ-1...
The Juno spacecraft reached the mid-point of its nominal mission in December 2018, after completing ...
The Juno spacecraft reached the mid‐point of its nominal mission in December 2018, after completing ...
The Juno spacecraft has been collecting data to shed light on the planet's origin and characterize i...
discussed the determination of the spacecraft orbits, and Campbell and Anderson2 used data from the ...
[EN] Gravity assist manoeuvres are one of the most successful techniques in astrodynamics. In these ...
The upcoming Juno spacecraft measurements have the potential of improving our knowledge of Jupiter's...
Juno is a NASA space mission to Jupiter, arriving at the planet in July 2016. Through accurate Doppl...
Interplanetary trajectories using the gravity assists are studied for future Korean interplanetary m...
This paper presents reconstruction of Voyager 2 trajectory to examine how the mission was optimised ...
The Juno gravity experiment, among the nine instruments onboard the spacecraft, is aimed at studying...
The satellite systems of Saturn and Jupiter are complex dynamical systems, with several interactions...
[EN] In the last decades there have been an increasing interest in improving the accuracy of spacecr...
The Juno spacecraft launched in August 2011 and, following a successful Earth flyby in October 2013,...
Juno has been in a highly elliptical (average eccentricity e=0.95), nearly polar, 53-day orbit aroun...
In 2016 the spacecraft Juno completed its first three perijove passes, respectively on Aug. 27 (PJ-1...
The Juno spacecraft reached the mid-point of its nominal mission in December 2018, after completing ...
The Juno spacecraft reached the mid‐point of its nominal mission in December 2018, after completing ...
The Juno spacecraft has been collecting data to shed light on the planet's origin and characterize i...
discussed the determination of the spacecraft orbits, and Campbell and Anderson2 used data from the ...
[EN] Gravity assist manoeuvres are one of the most successful techniques in astrodynamics. In these ...
The upcoming Juno spacecraft measurements have the potential of improving our knowledge of Jupiter's...
Juno is a NASA space mission to Jupiter, arriving at the planet in July 2016. Through accurate Doppl...
Interplanetary trajectories using the gravity assists are studied for future Korean interplanetary m...
This paper presents reconstruction of Voyager 2 trajectory to examine how the mission was optimised ...
The Juno gravity experiment, among the nine instruments onboard the spacecraft, is aimed at studying...
The satellite systems of Saturn and Jupiter are complex dynamical systems, with several interactions...