Tag Archives: Square Kilometre Array (SKA)

square kilometre array

Groundwork laid for world’s largest radio telescope: the Square Kilometre Array

Main image: An artist’s impression of the future Square Kilometre Array (SKA) in Australia. Up to 132,000 low frequency antennas (resembling metal Christmas trees) will be built. (Image: CSIRO)

Designs for the Square Kilometre Array (SKA) facility in Western Australia received the tick of approval this week during its critical design review, and can now move on to the final steps before construction starts in 2020.

Once completed, the multi-billion dollar SKA project will probe the corners of the universe to expand our understanding of its origins — and it will do so hundreds of times faster and in more detail than any existing facility.

Laying the groundwork

Australia’s Square Kilometre Array will be a web of more than 130,000 low-frequency antennas located in the Murchison Radio-astronomy Observatory in Western Australia (South Africa will host the other SKA facility).

The SKA’s success hinges on signals from thousands of antennas spread over many kilometres aligning with extreme precision. Infrastructure Australia Project Manager and Aurecon telecommunications infrastructure engineer Rebecca Wheadon said many of the challenges in ensuring this stem from the vastness and remote location of the site.

“We are working out in the middle of the desert, and we need to protect the radio quiet nature of the site,” Wheadon said.

“There’s a significant amount of engineering smarts that go into achieving that.”

For completion of this most recent phase, engineers were tasked with designing onsite support infrastructure, including a low central processing facility (CPF), a 1500-square-metre supercomputing centre.

“The CPF building is effectively a fully welded box within a box; all of the computing equipment goes within the inner shield of the building, with specially designed RFI [radio frequency interference] doors to ensure we do not pollute the air with RFI,” Wheadon said.

Square Kilometre Array

Artist’s impression of the supercomputing facility for the future Square Kilometre Array – the world’s largest radio telescope. (Image: Aurecon)

This includes any emissions from cooling equipment, pumps and lights. Hundreds of kilometres of access tracks and trenching for power supply and cables are also required to connect the sprawling network.

“Data flows will be on the scale of petabits, or a million billion bits, per second — more than the global internet rate today, all flowing into a single building in the Murchison,” said CSIRO’s SKA Infrastructure Consortium Director Antony Schinckel in a statement.

“To get this data from the antennas to the telescope’s custom supercomputing facilities, we need to lay 65,000 fibre optic cables.”

Coming into focus

Senior Electrical Engineer James Massoud, also from Aurecon, likened the electrical fitout to a “scaled-down version” of the east-coast transmission network, with long distances between demand centres and generation points.

“The scale of the site led to a significant electrical power distribution network, characterised as a long, low-density network,” said Massoud, who served as the power distribution lead engineer for the Infrastructure Australia consortium.

The team also had to “look back in time for mechanical or analogue ways of doing things”, he said, as digital technologies would disturb the radio quietness of the site.

The Murchison region, about 800 km north of Perth, has a legislated quiet zone of up to 260 km to limit interference. Keeping the ‘noise’ to a minimum is important, as the SKA antennas will be receiving extremely weak signals from the far reaches of the universe. Experts including CSIRO principal engineer and RFI specialist Carol Wilson advised on how to prevent the faint signals from being drowned out by the sites own equipment, like the CPF.

“One of the challenges is that the infrastructure equipment is not well characterised in terms of radio emissions, unlike radiocommunications equipment where the frequency power level and other technical qualifications are clearly identified,” she said.

Square Kilometre Array

Some of the SKA team, from left: Antony Schinckel, CSIRO; SKA Infrastructure Consortium Director, Rebecca Wheadon Aurecon; SKA Infrastructure Australia Project Manager, David Luchetti; and Australian SKA Director Shandip Abeywickrema, Aurecon Senior Project Engineer. (Image: CSIRO)

This milestone is the culmination of nearly a decade’s worth of work by an Infrastructure Australia industry partnership comprising experts from CSIRO and Aurecon.

Although the SKA project will physically reside in Australia and South Africa, in all more than 12 international engineering consortia, representing 500 engineers and scientists from 20 countries, are contributing to the telescope’s design, construction and eventual operation.

A critical design review for the entire SKA system will take place later this year or early next year, and construction is set to begin in 2020.

– Rachael Brown

This article was originally published by create digital as “Engineers lay the groundwork for the world’s largest radio telescope: the Square Kilometre Array”.

Telescope project funding boost

Featured photo above by Rob Millenaar

The Curtin University-led Murchison Widefield Array (MWA) radio telescope project has been awarded an Australian Research Council (ARC) grant to upgrade its performance by a factor of ten.

The $1,000,000 grant, part of the ARC Linkage Infrastructure, Equipment and Facilities (LIEF) scheme, announced today by the Minister for Education and Training, Senator the Hon Simon Birmingham, will double the number of telescope antennas to 256 and quadruple the footprint of the MWA to 28 square kilometres.

Professor Steven Tingay, Director of the MWA at Curtin University, says the upgrades would make the telescope ten times more powerful in its exploration of the evolution of the Universe.

“By increasing the number of telescope antennas and the surface area of the MWA, the telescope will strengthen tenfold, like a weightlifter capable of lifting 100 kg suddenly being able to lift 1000 kg,” says Tingay.

Tingay described the MWA as a ‘time machine’ designed to look back in time more than 12 billion years, to watch the formation of the first stars and galaxies in the Universe, less than one billion years after the Big Bang.

“The MWA has been operating for almost three years and has collected over seven petabytes of data already, the equivalent of almost half a million High Definition movies,” he says.

“With the upgrade that this grant provides, we will able to collect even more and better data, helping to advance our understanding of the last unstudied phase of cosmic evolution.”

An international consortium of 15 organisations from Australia, USA, India and New Zealand built and operate the MWA, led by Curtin University.

As a result of the new funding, two new organisations will be added to the MWA consortium; Western Sydney University and the University of Toronto, Canada, increasing the MWA’s national and international reach.

The MWA is one of three official precursor telescopes for the much larger, billion-dollar scale Square Kilometre Array (SKA) and is the only SKA precursor to be fully operational for science. Half of the SKA will be built at the same site as the MWA, the CSIRO’s Murchison Radio-astronomy Observatory, over the next decade.

Key science, engineering and computing developments for the SKA are being tested and verified by the MWA, providing critical expertise to the SKA project. This includes working closely with key national initiatives such as the Pawsey Supercomputing Centre.

In the last two years, more than 70 scientific publications have been developed from MWA data. The MWA team also recently won a prestigious award for the telescope’s scientific impact from Thomson Reuters.

– April Kleer

This article was first published on 30 October by Curtin University. Read the original article here.