BRITE-Constellation: Two low-cost Canadian nanosatellites launched

Nanosatellites will form a unique "constellation" aimed at understanding the ecology of the Universe. 

Together, the satellites are known as the BRITE-Constellation, standing for BRIght Target Explorer.

Credit: UTIAS - Space Flight Laboratory.

Two nanosatellites were launched from Yasny, Russia, at 15:11:11 Eastern Daylight Time today by Anthony Moffat, of the University of Montreal and the Centre for Research in Astrophysics of Quebec (CRAQ), and UTIAS, the Canadian research and technology team he leads.

Costing a fraction of conventional space telescopes and similar in size and weight to a car battery, the satellites are two of six that will work together to shed light on the structures and life stories of some of the brightest stars in the sky, uncovering unique clues as to the origins of our own Sun and Earth.

Together, the satellites are known as the BRITE-Constellation, standing for BRIght Target Explorer.

"BRITE-Constellation will monitor for long stretches of time the brightness and colour variations of most of the brightest stars visible to the eye in the night sky. These stars include some of the most massive and luminous stars in the Galaxy, many of which are precursors to supernova explosions."

"This project will contribute to unprecedented advances in our understanding of such stars and the life cycles of the current and future generations of stars," said Professor Moffat, who is the scientific mission lead for the Canadian contribution to BRITE and current chair of the international executive science team.

Luminous stars dominate the ecology of the Universe. "During their relatively brief lives, massive luminous stars gradually eject enriched gas into the interstellar medium, adding heavy elements critical to the formation of future stars, terrestrial planets and organics."

"In their spectacular deaths as supernova explosions, massive stars violently inject even more crucial ingredients into the mix."

"The first generation of massive stars in the history of the Universe may have laid the imprint for all future stellar history," Moffat explained.

"Yet, massive stars, rapidly spinning and with radiation fields whose pressure resists gravity itself - are arguably the least understood, despite being the brightest members of the familiar constellations of the night sky."

Other less-massive stars, including stars similar to our own Sun, also contribute to the ecology of the Universe, but only at the end of their lives, when they brighten by factors of a thousand and shed off their tenuous outer layers.

Nanosatellites will form a unique "constellation" aimed at understanding the ecology of the Universe. 

Together, the satellites are known as the BRITE-Constellation, standing for BRIght Target Explorer. 

Credit: UTIAS - Space Flight Laboratory

BRITE-Constellation is in fact a multinational effort that relies on pioneering Canadian space technology and a partnership with Austrian and Polish space researchers – the three countries act as equal partners.

Canada's participation was made possible thanks to an investment of $4.07 million by the Canadian Space Agency.

The two new Canadian satellites are joining two Austrian satellites and a Polish satellite already in orbit; the final Polish satellite will be launched in August.

All six satellites were designed by the University of Toronto Institute for Aerospace Studies - Space Flight Laboratory, who also built the Canadian pair.

The satellites are were in fact named "BRITE Toronto" and "BRITE Montreal" after the University of Toronto and the University of Montreal, who play a major role in the mission.

"BRITE-Constellation will exploit and enhance recent Canadian advances in precise attitude control that have opened up for space science the domain of very low cost, miniature spacecraft, allowing a scientific return that otherwise would have had price tags 10 to 100 times higher," Moffat said.

"This will actually be the first network of satellites devoted to a fundamental problem in astrophysics."

The nanosatellites will be able to explore a wide range of astrophysical questions. "The constellation could detect exoplanetary transits around other stars, putting our own planetary system in context, or the pulsations of red giants, which will enable us to test and refine our models regarding the eventual fate of our Sun," Moffatt explained.

BRITE: World's smallest space telescope launched

BRITE, the smallest astronomical satellite was launched Monday as part of a mission to prove that even a very small telescope can push the boundaries of astronomy.

The satellite was designed and assembled at the Space Flight Laboratory (SFL) of the University of Toronto Institute for Aerospace Studies (UTIAS).

It will be launched from the Satish Dhawan Space Centre in Sriharikota, India, along with its twin, also designed in Canada, but assembled in Austria.

Each nano-satellite in the BRIght Target Explorer (BRITE) mission is a cube 20 cms per side, and weighing less than 7 kilograms.

The BRITE satellites are part of the new wave of nano-satellites that can be designed, assembled and deployed fast and relatively cheaply.

"SFL has demonstrated that nano-satellites can be developed quickly, by a small team and at a cost that is within reach of many universities, small companies and other organizations," says Cordell Grant, Manager of Satellite Systems for the Space Flight Laboratory at UTIAS.

"A nano-satellite can take anywhere from six months to a few years to develop and test, but we typically aim for two years or less."

Up to now, such nano-satellites had been used only to monitor the earth and experiment with new technologies.

"Researchers, scientists and companies worldwide, who have great ideas for space-borne experiments, but do not have the means to fund a large spacecraft, can now see their ideas realized," said Grant.

"BRITE has the potential to open an entirely new market for low-cost high-performance satellites."

BRITE is the first nano-satellite mission intended for astronomy, and the first-ever astronomy constellation -more than one satellite working toward a common objective- of any size.

The previous world-record holder for small astronomy satellites was the MOST satellite, designed and assembled in part by SFL at UTIAS.

Launched in 2003 and still operating, MOST was the first entirely Canadian satellite for astronomy, weighing in at 53 kilograms. Compared to the 11 metric tons of the Hubble Space Telescope, MOST was aptly called a micro-satellite.

"BRITE is expected to demonstrate that nano-satellites are now capable of performance that was once thought impossible for such small spacecraft," says Grant. But only small telescopes can fit within a 20 centimetre cube.

Therefore, BRITE is not intended to take pretty pictures, but will simply observe stars and record changes in their brightness over time.

Such changes could be caused by spots on the star, a planet or other star orbiting the star, or by oscillations and reverberations within the star itself -the analogue of earthquakes on stars.

The study of these so-called "starquakes" is called astero-seismology.