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Sydney, Australia - 24 Jul 2012: IBM (NYSE: IBM) announced today that the Victoria University of Wellington, on behalf of the Murchison Widefield Array (MWA) Consortium, has selected IBM systems technology to help scientists probe the origins of the universe.
The result of an international collaboration between 13 institutions from Australia, New Zealand, U.S. and India, the MWA is a new type of radio telescope designed to capture low frequency radio waves from deep space as well as the volatile atmospheric conditions of the Sun. The signals will be captured by the telescope’s 4,096 dipole antennas positioned in the Australian Outback in a continuous stream and processed by an IBM iDataPlex dx360 M3 computing cluster that will convert the radio waves into wide-field images of the sky that are unprecedented in clarity and detail.
The IBM iDataPlex cluster replaces MWA’s existing custom-made hardware systems and will enable greater flexibility and increased signal processing. The cluster is expected to process approximately 50 terabytes of data per day at full data rate at a speed of 8 gigabytes per second, the equivalent to over 2,000 digital songs per second, allowing scientists to study more of the sky faster than ever before, and with greater detail.
“The MWA project is dependent on the massive computer power offered by IBM’s iDataPlex to create real-time wide-field images of the radio sky,” said Professor Steven Tingay, MWA Project Director from the International Centre for Radio Astronomy Research at Curtin University in Perth. “The combination of the MWA, IBM technology and the radio-quiet environment of the Murchison will allow us to search for the incredibly weak signals that come from the early stages in the evolution of the Universe, some 13 billion years ago.”
The ultimate goal of the revolutionary $51 million MWA telescope is to observe the early Universe, when stars and galaxies were first born. By detecting and studying the weak radio signals emitted from when the Universe consisted of only a dark void of Hydrogen gas – the cosmic Dark Age - scientists hope to understand how stars, planets and galaxies were formed. The telescope will also be used by scientists to study the sun’s heliosphere during periods of strong solar activity and time-varying astronomical objects such as pulsars.
"Victoria University was delighted to work with the IBM team to find a solution for the compute challenges of the MWA,” said Dr Melanie Johnston-Hollitt, Senior Lecturer in Physics, Victoria University of Wellington. “The IBM iDataPlex cluster provides an elegant resource to handle the processing and imaging requirements of the telescope, allowing us to do cutting-edge radio astronomy."
“IBM is delighted to have been selected by the MWA consortium in this significant global scientific endeavour,” said Glenn Wightwick, Chief Technologist, IBM Australia. “’High performance processing capabilities are essential to facilitating world-class science. The IBM iDataPlex cluster will be used to digitally process incoming signals and produce image data in a standard astronomical format, ready for use by scientists.”
The IBM iDataPlex cluster will be housed on-site in the Murchison Radio Observatory (MRO) site around 700 km north of Perth, near the radio telescope antennas. With a 10 Gbps communications link to Perth, it will allow the images to be transferred and stored and made available for research. The MRO site will also be the Australian location for a significant portion of the Square Kilometre Array (SKA), which will be the world's most powerful radio telescope and is being co-hosted by Australia and South Africa.
The MWA project is led by the International Centre for Radio Astronomy Research at Curtin University and is one of three SKA precursor telescopes.
For more information on MWA, please visit: http://www.mwatelescope.org
For more information on IBM iDataplex, please visit: http://www-03.ibm.com/systems/info/x/idataplex/
Watch a fly-through animation of the radio telescope on YouTube: http://www.youtube.com/watch?v=SLri0HFC3qg
An MWA image of our own Milky Way galaxy, showing exploded stars in the disk and filamentary structures extending far off the disk. Credit: Murchison Widefield Array
A fraction of the MWA antenna "tiles", as they will be built in the final configuration. Credit: Murchison Widefield Array
An MWA image of the galaxy Centaurus A, one of the nearest galaxies to us at a distance of approximately 10 million light years. Credit: Murchison Widefield Array