-
- News
- Books
Featured Books
- smt007 Magazine
Latest Issues
Current IssueThe Rise of Data
Analytics is a given in this industry, but the threshold is changing. If you think you're too small to invest in analytics, you may need to reconsider. So how do you do analytics better? What are the new tools, and how do you get started?
Counterfeit Concerns
The distribution of counterfeit parts has become much more sophisticated in the past decade, and there's no reason to believe that trend is going to be stopping any time soon. What might crop up in the near future?
Solder Printing
In this issue, we turn a discerning eye to solder paste printing. As apertures shrink, and the requirement for multiple thicknesses of paste on the same board becomes more commonplace, consistently and accurately applying paste becomes ever more challenging.
- Articles
- Columns
Search Console
- Links
- Media kit
||| MENU - smt007 Magazine
Danish Instrument Helps NASA’s Juno Spacecraft See Radiation
August 21, 2024 | NASA JPLEstimated reading time: 5 minutes
Using cameras designed for navigation, scientists count ‘fireflies’ to determine the amount of radiation the spacecraft receives during each orbit of Jupiter.
Scientists with NASA’s Juno mission have developed the first complete 3D radiation map of the Jupiter system. Along with characterizing the intensity of the high-energy particles near the orbit of the icy moon Europa, the map shows how the radiation environment is sculpted by the smaller moons orbiting near Jupiter’s rings.
The work relies on data collected by Juno’s Advanced Stellar Compass (ASC), which was designed and built by the Technical University of Denmark, and the spacecraft’s Stellar Reference Unit (SRU), which was built by Leonardo SpA in Florence, Italy. The two datasets complement each other, helping Juno scientists characterize the radiation environment at different energies.
Both the ASC and SRU are low-light cameras designed to assist with deep-space navigation. These types of instruments are on almost all spacecraft. But to get them to operate as radiation detectors, Juno’s science team had to look at the cameras in a whole new light.
Jupiter’s moon Europa was captured by the JunoCam instrument aboard NASA’s Juno spacecraft during the mission’s close flyby on Sept. 29, 2022. The images show the fractures, ridges, and bands that crisscross the moon’s surface.
Jupiter’s moon Europa was captured by the JunoCam instrument aboard NASA’s Juno spacecraft during the mission’s close flyby on Sept. 29, 2022. Credit: Image data: NASA/JPL-Caltech/SwRI/MSSS. Image processing: Björn Jónsson (CC BY 3.0) Full Image Details
“On Juno we try to innovate new ways to use our sensors to learn about nature, and we have used many of our science instruments in ways they were not designed for,” said Scott Bolton, Juno principal investigator from the Southwest Research Institute in San Antonio. “This is the first detailed radiation map of the region at these higher energies, which is a major step in understanding how Jupiter’s radiation environment works. This will help planning observations for the next generation of missions to the Jovian system.”
Counting Fireflies
Consisting of four star cameras on the spacecraft’s magnetometer boom, Juno’s ASC takes images of stars to determine the spacecraft’s orientation in space, which is vital to the success of the mission’s magnetic field experiment. But the instrument has also proved to be a valuable detector of high-energy particle fluxes in Jupiter’s magnetosphere. The cameras record “hard radiation,” or ionizing radiation that impacts a spacecraft with sufficient energy to pass through the ASC’s shielding.
“Every quarter-second, the ASC takes an image of the stars,” said Juno scientist John Leif Jørgensen of the Technical University of Denmark. “Very energetic electrons that penetrate its shielding leave a telltale signature in our images that looks like the trail of a firefly. The instrument is programmed to count the number of these fireflies, giving us an accurate calculation of the amount of radiation.”
Because of Juno’s ever-changing orbit, the spacecraft has traversed practically all regions of space near Jupiter.
ASC data suggests that there is more very high-energy radiation relative to lower-energy radiation near Europa’s orbit than previously thought. The data also confirms that there are more high-energy electrons on the side of Europa facing its orbital direction of motion than on the moon’s trailing side. This is because most of the electrons in Jupiter’s magnetosphere overtake Europa from behind due to the planet’s rotation, whereas the very high-energy electrons drift backward, almost like fish swimming upstream, and slam into Europa’s front side.
Jovian radiation data is not the ASC’s first scientific contribution to the mission. Even before arriving at Jupiter, ASC data was used to determine a measurement of interstellar dust impacting Juno. The imager also discovered a previously uncharted comet using the same dust-detection technique, distinguishing small bits of the spacecraft ejected by microscopic dust impacting Juno at a high velocity.
Dust Rings
Like Juno’s ASC, the SRU has been used as a radiation detector and a low-light imager. Data from both instruments indicates that, like Europa, the small “shepherd moons” that orbit within or close to the edge of Jupiter’s rings (and help to hold the shape of the rings) also appear to interact with the planet’s radiation environment. When the spacecraft flies on magnetic field lines connected to ring moons or dense dust, the radiation count on both the ASC and SRU drops precipitously. The SRU is also collecting rare low-light images of the rings from Juno’s unique vantage point.
“There is still a lot of mystery about how Jupiter’s rings were formed, and very few images have been collected by prior spacecraft,” said Heidi Becker, lead co-investigator for the SRU and a scientist at NASA’s Jet Propulsion Laboratory in Southern California, which manages the mission. “Sometimes we’re lucky and one of the small shepherd moons can be captured in the shot. These images allow us to learn more precisely where the ring moons are currently located and see the distribution of dust relative to their distance from Jupiter.”
More About the Mission
NASA’s Jet Propulsion Laboratory, a division of Caltech in Pasadena, California, manages the Juno mission for the principal investigator, Scott Bolton, of the Southwest Research Institute in San Antonio. Juno is part of NASA’s New Frontiers Program, which is managed at NASA’s Marshall Space Flight Center in Huntsville, Alabama, for the agency’s Science Mission Directorate in Washington. The Technical University of Denmark designed and built the Advanced Stellar Compass. The Stellar Reference Unit was built by Leonardo SpA in Florence, Italy. Lockheed Martin Space in Denver built and operates the spacecraft.
Suggested Items
Spirit Electronics Adds Zero-Error Systems to Provide Ultra-High Reliability Protection from Radiation in Space Applications
10/25/2024 | Spirit ElectronicsSpirit Electronics announces franchised distribution for Zero-Error Systems (ZES) to support ultra-high reliability semiconductors and ICs operating in challenging radiation environments.
Japan’s First Moon Lander Touches Down with Renesas’ Rad-Hard ICs on Board
01/22/2024 | BUSINESS WIRERenesas Electronics Corporation, a premier supplier of advanced semiconductor solutions, announced that its radiation-hardened (rad-hard) ICs were onboard the Smart Lander for Investigating Moon (SLIM) spacecraft that successfully touched down on the Moon’s low latitude area on January 20, Japan Standard Time.
Green Circuits Showcases Cutting-Edge PCB Solutions for Healthcare Innovation at MD&M West
01/15/2024 | Green CircuitsGreen Circuits, a full-service Electronics Manufacturing Services (EMS) partner to leading OEMs, proudly announces its participation in MD&M West, scheduled to take place from Feb. 6-8, 2024 at The Anaheim Convention Center in California.
It All Starts With Sensors
08/30/2023 | Happy Holden, I-Connect007Sensor technology is at the heart of any manufacturing data collection, especially for the digital stream—it all starts with sensors—but there is so much more. Sensors need connections to instruments, and some actions need predictions, the process is sensing, connection, and predicting. Sensing assumes sensors. Connecting can be any intelligent device that provides a program or signal conditioning and then makes that data available to the rest of the organization. Predicting is the difficult step.
Renesas Develops Complete Power Management Solution for AMD Space-Grade Versal Adaptive SoC
07/20/2023 | Business WireRenesas Electronics Corporation, a premier supplier of advanced semiconductor solutions, announced a complete space-ready reference design for the AMD Versal adaptive system-on-chip (SoC) XQRVC1902.