The new equipment is a receiver, a ‘bionic ear’ for the cosmos which catches radio waves and turns them into electrical signals for astronomers to analyse.
The $2.5 million instrument was developed by CSIRO and a consortium of Australian universities led by Swinburne University of Technology, with funding from the Australian Research Council, Germany’s Max Planck Institute for Radioastronomy and the Chinese Academy of Sciences.
The CSIRO and Swinburne each designed and built parts of the system.
A receiver determines which radio frequencies the telescope can hear.
“Until now we’ve had receivers that heard just one part of the choir at a time,” Dr Hobbs said. “This new one lets us listen to the whole choir at once.”
He said the new receiver covers a very wide frequency range, 700 MHz to 4 GHz, and it does the work of several existing receivers and also covers extra frequencies that they don’t.
The CSIRO says Parkes has been continually upgraded throughout its lifetime and is already one of the world’s most productive radio telescopes.
The telescope is now 10,000 times more sensitive than when it was built in 1961 and has found most of the known pulsars and most of the "fast radio bursts" that still mystify astronomers.
It also helped reveal the nature of bright sources called quasars and discovered a new spiral arm in our Galaxy.
"Most of the projects the new system will be used for are forefront astronomical science," Swinburne’s Professor Matthew Bailes, who led the university consortium, said.
The projects include searching for gravitational waves from black holes in the early Universe, studying the insides of neutron stars, and mapping the magnetic fields that run through our Galaxy – and the new receiver will let the telescope do different projects at the same time.
“While some of us are timing a pulsar, other astronomers could be looking for the signs of newborn stars,” Dr Hobbs said.
“The expertise built up in these technologies will enable Australia to compete effectively into the era of the Square Kilometre Array, the world’s largest radio telescope.”
Swinburne engineers designed the data processor for the Parkes receiver using experience gained through work for the Square Kilometre Array.
The CSIRO is recognised as a world leader in receiver design, and CSIRO and recently worked together with engineers from the Chinese Academy of Sciences to develop a receiver for China’s Five-hundred-meter Aperture Spherical radio Telescope.