13.05.2023
Juice’s RIME antenna breaks free
More than three weeks after efforts began to deploy Juice’s ice-penetrating Radar for Icy Moons Exploration (RIME) antenna, the 16-metre-long boom has finally escaped its mounting bracket.
During the first attempt to extend the folded-up antenna, only the first segments of each half were deployed. Flight controllers suspected that a tiny stuck pin jammed the other segments in place.
Fortunately, the flight control teams at ESA’s mission control centre in Darmstadt had lots of ideas up their sleeves.
To try to shift the pin, they shook Juice using its thrusters, then they warmed Juice with sunlight. Every day the RIME antenna was showing signs of movement, but no full release.
On 12 May RIME was finally jolted into life when the flight control team fired a mechanical device called a ‘non-explosive actuator’ (NEA), located in the jammed bracket. This delivered a shock that moved the pin by a matter of millimetres and allowed the antenna to unfold.
The image below shows the mechanical shock delivered by the firing of the actuator in the mounting bracket. The actuator was fired at the moment labelled ‘NEA 6 Release’. The resulting damping oscillation indicates that the antenna is released and then wobbles back and forth before stabilising into an extended, locked position.
But a final part of the antenna remained folded. Confirmation that the RIME antenna was successfully deployed came only when the flight control team fired another actuator in the bracket, causing RIME to fully stretch itself out after months spent folded up for launch.
The second stuck part of the RIME antenna deploys
Once ESA’s Jupiter Icy Moons Explorer (Juice) arrives at Jupiter, it will use RIME to study the surface and subsurface structure of Jupiter’s icy moons down to a depth of 9 km. RIME is one of ten instruments on board Juice set to investigate the emergence of habitable worlds around gas giants and the formation of our Solar System.
Quelle: ESA
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Update: 17.05.2023
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JUICE Jupiter probe spotted 1 million miles from Earth (video, image)
JUICE launched last month on an eight-year journey to Jupiter.
Airbus Space's Airbus Robotic Telescope captured this view of Europe's JUICE Jupiter probe on April 20, 2023, when the spacecraft was nearly 1 million miles (1.5 million kilometers) from Earth. (Image credit: Airbus Space)
Europe's Jupiter Icy Moons Explorer (JUICE) spacecraft has been spotted as it zooms away from Earth toward the solar system's largest planet.
JUICE launched on April 14, kicking off an eight-year journey to the Jupiter system. Once it gets there, JUICE will investigate the Jovian atmosphere and its physics. It will also study the Jupiter ocean moons Ganymede, Callisto, andEuropa, helping to assess their potential to host life as we know it.
The new JUICE footage was captured by the Airbus Robotic Telescope (ART), a ground-based instrument in Spain designed to aid in space surveillance and tracking. The telescope, which is owned and operated by Airbus Space, captured the Jupiter probe between 6:52 p.m. EDT (2252 GMT) and 8:41 p.m. EDT (00:41 GMT) on April 20.
he footage, which consists of 20 five-minute-long exposures, shows JUICE at its center surrounded by bright specks, which are background stars. At the time it was spotted by ART, JUICE was around 1 million miles (1.5 million kilometers) from Earth.
Airbus Space posted the footage on its Twitter feed(opens in new tab) on Monday (May 15), writing: "Spotted! Our ground-based telescope captured #ESAJuice more than 1.5 million km from Earth, on its way to Jupiter and its icy moons."
JUICE won't arrive at the Jovian system until July 2031. The journey takes around eight years because the spacecraft will need several gravity boosts from Earth, the moon and Venus to reach the fifth planet from the sun.
JUICE will be back near Earth in August 2024 to get a gravity assist from the Earth-moon system, the first time such a maneuver, officially called a lunar-Earth gravity assist (LEGA), has been performed.
The European Space Agency (ESA) spacecraft will get a boost from "Earth's twin," Venus, a year later, in August 2025. After this, the next two gravity assists for JUICE will come from Earth, with the craft returning to the vicinity of our planet in September 2026 and January 2029, finally collecting enough energy to catapult out of the inner solar system and on to Jupiter.
JUICE won't stay in orbit around Jupiter forever, however. The mission plan calls for the probe to go into orbit around Ganymede in December 2034. If that maneuver succeeds, JUICE will become the first spacecraft ever to orbit a moon of a planet other than Earth.
At least three of the gravity assists JUICE engages in will give telescopes like ART the opportunity to visually document the spacecraft's extraordinary mission.
Quelle: SC
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Update: 21.05.2023
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Jammed radar boom on Jupiter-bound JUICE probe finally freed
Artist’s concept of the Jupiter Icy Moons Explorer with all its antenna deployed. Credit: European Space Agency
After three weeks of intense analysis and troubleshooting, European Space Agency flight controllers have finally succeeded in freeing a jammed 52-foot (16-meter) boom critical to the Jupiter-bound JUICE probe’s ice-penetrating radar instrument.
The Jupiter Icy Moons mission – JUICE – was launched April 14 atop an Ariane 5 rocket. On its way to the first of several gravity assist flybys, the spacecraft successfully deployed its over-size solar arrays and a 10.6-meter (35-foot) magnetometer boom.
But a long antenna boom needed by the Radar for Icy Moons Exploration, or RIME, instrument, designed to peer beneath the frozen crusts of Ganymede, Callisto and Europa, failed to unfurl when first commanded, raising concerns a major element of the long-awaited mission could be in jeopardy.
Engineers at ESA’s mission control center in Darmstadt, Germany, concluded the jammed boom was being held by a small pin. They attempted to shift the pin slightly by re-orienting the spacecraft so the mechanism could warm in the sun. They also fired thrusters to rock the probe back to add a bit of force. Engineers noted increased movement, but the boom remained held in place.
On May 12, commands were sent to fire a non-explosive actuator, or NEA, located near the jammed bracket assembly. The resulting shake apparently moved the pin by a few millimeters, just enough to allow the antenna boom to unfold and lock in place.
“The Flight Control Team then commanded the release of the final remaining part of the RIME antenna boom, which extends in the opposite direction,” ESA tweeted. “Confirmation of a successful deployment arrived shortly after.”
The news prompted widespread relief among JUICE scientists and engineers, along with a bit of now-relaxed tweeting.
“We thought about celebrating with a rhyme, but it’s Friday evening, who’s got the time?” the operations team tweeted. Added Daniel Scuka, a control center communications officer: “T’was happy hour time, so having a little juice – when I heard the good news that rime was loose!”
Good news indeed.
Quelle: SN
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Update: 28.05.2023
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Juice deployments complete: final form for Jupiter
Flight controllers at ESA’s mission control centre in Germany have been busy this week, working with instrument teams on the final deployments to prepare ESA’s Jupiter Icy Moons Explorer (Juice) for exploring Jupiter.
It has been six weeks since Juice began its journey, and in that time the Flight Control Team have deployed all the solar panels, antennas, probes and booms that were tucked away safely during launch. The last step has been the swinging out and locking into place of the probes and antennas that make up Juice’s Radio & Plasma Wave Investigation (RPWI).
“It’s been an exhausting but very exciting six weeks,” says Angela Dietz, deputy spacecraft operations manager for the mission. “We have faced and overcome various challenges to get Juice into the right shape for getting the best science out of its trip to Jupiter.”
We’ve had regular snapshots of the entire deployment process thanks to Juice’s two onboard monitoring cameras, each with a different field of view. In the hours after launch, these cameras took Juice’s first ‘selfies’ from space, and ever since, they have been vital for checking that all parts of the spacecraft deployed correctly.
Juice’s antennas and booms each carry part or all of some of Juice’s 10 instruments. By placing them far from Juice, the instruments that need to be separated from the spacecraft’s own electric and magnetic fields are kept at a distance.
This powerful instrument package will collect data that helps us answer questions like: What are Jupiter’s ocean worlds like? Why is Ganymede so unique? Could there be – or ever have been – life in the Jupiter system? How has Jupiter’s complex environment shaped its moons, and vice versa? What is a typical gas giant planet like – how did it form, and how does it work?
Accompanying our views from the monitoring cameras, confirmation that everything deployed as planned also came from the instruments themselves. The teams behind some of the instruments have been switching them on and making measurements to check that everything is working well. Teams have already confirmed that Juice’s RPWI, JANUS, J-MAG and GALA instruments, as well as the RADEM radiation monitor, are ready for Jupiter.
RPWI: five days, seven deployments
This week, the four Langmuir Probes and three Radio Wave Instrument antennas of the Radio & Plasma Wave Investigation (RPWI) were successfully deployed. Altogether these make up seven of the 10 RPWI sensors that will measure the variations in the electric and magnetic fields around Jupiter, as well as radio waves and cold plasma.
After seeing the last boom deploy successfully this afternoon, principal investigator of RPWI, Jan-Erik Wahlund from the Swedish Institute of Space Physics said: “Fantastic, after more than 10 years of intensive work, we are finally ready for science discoveries!”
RPWI will be the first ever device to generate a 3D map of the electric fields around Jupiter. It will give us valuable information on how energy is transferred between Jupiter’s enormous rotating magnetosphere and the large icy moons Ganymede, Callisto and Europa. This energy transfer drives, for example, the auroras on Ganymede and in Jupiter's upper atmosphere. The special sensitivity of RPWI to low frequencies means that it will be able to detect very weak electromagnetic signals from tides and currents within the sub-surface oceans of the icy moons.
Before and after each deployment, the RPWI team switched on the instrument to measure the difference made by each newly deployed sensor. Each one now collects data and delivers it to RPWI’s onboard data processing unit, which sends the data down to Earth.
“Our 3D design strategy makes it possible to measure true physical observables, such as energy and momentum, without resorting to theories or simulations to interpret the data,” says Jan Bergman, a researcher at the Swedish Institute of Space Physics and technical manager for RPWI.
For more details on RPWI deployments, see the Swedish National Space Agency website (scroll down for English).
JANUS: first images taken in space
Last week, when Juice was about 8 million km from Earth, engineers switched the JANUS optical camera instrument on for the first time. Unlike the RPWI sensors mounted on booms far from Juice’s main body, JANUS is fixed to an optical bench; this means that it is kept stable when pointing towards its targets – like using a tripod here on Earth. JANUS also points in the same direction as Juice’s other ‘remote sensing’ instruments.
At Jupiter, the JANUS camera will take images in 13 different colours, from violet light to near infrared. These images will allow scientists to investigate the moons Ganymede, Callisto and Europa, including studying whether life could exist below their icy crusts. JANUS will also collect data on other parts of the Jovian system, including the intense volcanic activity on Io, the many smaller moons, and Jupiter’s faint ring system. Last but not least, JANUS will image processes taking place in Jupiter’s atmosphere.
During last week’s commissioning, a full hardware check was undertaken, with all subsystems activated and monitored. The performance of the instrument was checked by taking images of stars.
“The acquired data demonstrate that everything was nominal. After this intense on-ground session, we can say: we have a (fully commissioned) instrument!” says Pasquale Palumbo (IAPS-INAF), principal investigator of JANUS.
For more details see the website of the Italian National Institute for Astrophysics.
RIME: a sticky situation, finally unstuck
The journey to full deployment has not been entirely smooth sailing. Just a few days after launch, flight controllers attempted to unfurl the Radar for Icy Moon Exploration (RIME) instrument antenna. The first segments of the antennas unfolded as planned, but the next segments refused to budge.
Controllers suspected that a tiny stuck pin jammed the segments in place. They put their heads together to figure out a solution. They shook Juice using its thrusters. They warmed Juice using sunlight. Every day the antenna showed signs of movement, but stayed stuck in its bracket. Finally, RIME was jolted into life almost three weeks later, when the team fired a mechanical device inside the bracket. The shock moved the pin by a matter of millimetres. To the relief of ESA operations and project teams as well as industry, the antenna fully unfolded.
Commissioning of RIME is still ongoing, but the team has already made some measurements with the instrument.
What’s next for Juice?
In the next weeks, more of Juice’s 10 instruments will be switched on and checked, with the hope that by mid-July, all instruments will be working perfectly, ready for cruising to Jupiter.
In August 2024, Juice will carry out the world’s first ever lunar-Earth gravity assist. By performing this manoeuvre – a gravity assist flyby of the Moon followed just 1.5 days later by one of Earth – Juice will be able to save a significant amount of propellant on its journey.
Quelle: ESA