An approximately four-week-long rotation of the Sun, as seen by the SWAP imager on ESA's Proba-2 microsatellite. The rotation is 'approximate' because, as a ball of plasma, different latitudes and layers of the Sun rotate at different rates. Victorian astronomer Richard Carrington developed a system for tracking solar features known as the 'Carrington rotation', which arrives at an approximately 27-day periodicity for solar features - those features nearer the equator rotating faster than those at the poles.
Credits: ROB/ESA
Credits: ESA
Less than a cubic metre, Proba-2 was launched on 2 November 2009 as a technology demonstrator but is now working as a science mission, having exceeded its two-year design life.
Proba-2 science data are also useful for space weather monitoring: two instruments watch the Sun, with two more studying the Sun’s influence on Earth’s topmost ionosphere.
The mission is keeping busy: it has gathered upwards of 400 000 images of the Sun and made almost 20 million in-situ ionospheric observations.
This year’s European Space Weather Week, taking place in the Palais des Congres in Namur, Belgium, from 28 November to 2 December included presentations by users of Proba-2 data from all over Europe.
“Proba-2 science data are also distributed to scientific teams worldwide, from the US to India,” noted Marie Dominique of the Royal Observatory of Brussels, responsible for Proba-2’s Sun-watching sensors.
Sampling space
Rather than being trained on the Sun, some 150 million km away, Proba’s two other main sensors are investigating the immediate vicinity of the microsatellite, circling the poles at an altitude of 700 km.
“Next year, we plan to release the complete processed archive of our results so far,” said Stepan Stverak, of the Czech Republic’s Astronomical Institute.
“This dataset will then be available to the scientific community for statistical study, to help identify how ionospheric plasma can be perturbed by solar and space weather events.”
Results will also be cross-checked with France’s Demeter satellite, which sought ionospheric disturbance caused by seismic activity – a potential method of predicting earthquakes.
Proba-2 and Demeter flew in similar orbits before the French satellite ended its mission last year.
New technology taking flight
ESA’s ‘Project for Onboard Autonomy’ family of demonstration satellites allows European companies to test new technologies in space.
Credits: GKN/TNO/APP
Proba-2’s 17 technology payloads include: a flight computer built around ESA’s latest-generation chip (yet to require a single reset), a fibre sensor ‘nervous system’ monitoring temperatures and fuel tank pressure, and nitrogen gas generators to repressurise the resistojet thruster used for orbit maintenance – giving the mission a new lease of life each time they are triggered.
“The idea behind Proba is to test advanced technologies in a way that the scientific community also finds useful,” remarked Frederic Teston of ESA’s In-Orbit Demonstration Programme.
This is Proba-2's detailed view of an extraordinary event on 7 June 2011 where a massive amount of dark, cool plasma was blown away from the solar surface then fell back down on the Sun. Proba-2's SWAP telescope (Sun Watcher using Active Pixel System detector and Image Processing)provides images of the solar corona at a temperature of roughly one million degrees, acquiring a new image every 1-2 minutes, with a field of view (FOV) of 54 arcmin.
Credits: ESA/ROB
“Gaining the interest of users represents the best proof our technologies work well.”
Proba-2 is designed for maximum autonomy. It is operated by a small team keeping standard office hours, based at ESA’s ground station in Redu, Belgium.
“We work with Redu on a very flexible basis,” Ms Dominique added. “We can easily react if solar activity suddenly changes – in a few hours we change the settings of our instruments, or even the pointing direction of the satellite, for instance, to track coronal mass ejections.”
Contacts and sources:
ESA
Credits: ROB/ESA
Researchers gathered for European Space Weather Week have been presented with the latest results from ESA’s own space weather station: the Proba-2 microsatellite.
The unpredictably stormy Sun drives space weather: surges of charged particles can damage satellites, impede space-based services and affect terrestrial power networks.
The unpredictably stormy Sun drives space weather: surges of charged particles can damage satellites, impede space-based services and affect terrestrial power networks.
Small satellite technology demonstrator Proba-2 went into orbit on 2 November 2009.
Less than a cubic metre, Proba-2 was launched on 2 November 2009 as a technology demonstrator but is now working as a science mission, having exceeded its two-year design life.
Proba-2 science data are also useful for space weather monitoring: two instruments watch the Sun, with two more studying the Sun’s influence on Earth’s topmost ionosphere.
The mission is keeping busy: it has gathered upwards of 400 000 images of the Sun and made almost 20 million in-situ ionospheric observations.
This year’s European Space Weather Week, taking place in the Palais des Congres in Namur, Belgium, from 28 November to 2 December included presentations by users of Proba-2 data from all over Europe.
“Proba-2 science data are also distributed to scientific teams worldwide, from the US to India,” noted Marie Dominique of the Royal Observatory of Brussels, responsible for Proba-2’s Sun-watching sensors.
Rather than being trained on the Sun, some 150 million km away, Proba’s two other main sensors are investigating the immediate vicinity of the microsatellite, circling the poles at an altitude of 700 km.
“Next year, we plan to release the complete processed archive of our results so far,” said Stepan Stverak, of the Czech Republic’s Astronomical Institute.
“This dataset will then be available to the scientific community for statistical study, to help identify how ionospheric plasma can be perturbed by solar and space weather events.”
Results will also be cross-checked with France’s Demeter satellite, which sought ionospheric disturbance caused by seismic activity – a potential method of predicting earthquakes.
Proba-2 and Demeter flew in similar orbits before the French satellite ended its mission last year.
ESA’s ‘Project for Onboard Autonomy’ family of demonstration satellites allows European companies to test new technologies in space.
A demonstration of how Proba-2's cool gas generator works. Nitrogen is produced from a solid material stored at ambient temperature, used to repressurise the microsatellite's 'resistojet' thruster used to maintain its orbit. The bottle-shaped cool-gas generators are filled with a rigid solid material that, once triggered, produces more than 250 times its own volume in pure nitrogen gas. Proba-2 has a total of four cold gas generators on board - one of which was used in August 2011.
Credits: GKN/TNO/APP
Proba-2’s 17 technology payloads include: a flight computer built around ESA’s latest-generation chip (yet to require a single reset), a fibre sensor ‘nervous system’ monitoring temperatures and fuel tank pressure, and nitrogen gas generators to repressurise the resistojet thruster used for orbit maintenance – giving the mission a new lease of life each time they are triggered.
“The idea behind Proba is to test advanced technologies in a way that the scientific community also finds useful,” remarked Frederic Teston of ESA’s In-Orbit Demonstration Programme.
“Gaining the interest of users represents the best proof our technologies work well.”
Proba-2 is designed for maximum autonomy. It is operated by a small team keeping standard office hours, based at ESA’s ground station in Redu, Belgium.
“We work with Redu on a very flexible basis,” Ms Dominique added. “We can easily react if solar activity suddenly changes – in a few hours we change the settings of our instruments, or even the pointing direction of the satellite, for instance, to track coronal mass ejections.”
Contacts and sources:
ESA
0 comments:
Post a Comment