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One of the most powerful supercomputers in the world
has now been fully installed and tested
at its remote, high altitude site
in the Andes of northern Chile.
This marks one of the major remaining milestones
toward completion of ALMA,
the Atacama Large Millimeter/submillimeter Array.
The ALMA correlator turns ALMA's
many antennas into one giant telescope.
This is the ESOcast!
Cutting-edge science and life behind the scenes
at ESO, the European Southern Observatory.
ALMA is the most elaborate ground-based telescope in history
and is composed of an array of 66 dish-shaped antennas.
Its supercomputer, or correlator,
is a component of crucial importance.
For ALMA to work, the faint celestial signals
collected by each antenna must be combined
with those from every other antenna.
The correlator's processors will continually combine and compare
the data from up to 64 of the antennas in the ALMA array,
which are separated by up to 16 kilometres,
enabling the antennas to work together
as a single, enormous, telescope.
The ALMA correlator has over
134 million processors, and performs up to an unbelievable
17 quadrillion operations per second.
That is 17 thousand million million!
The correlator was built specifically for this task,
but the number of calculations per second is comparable
to the performance of the fastest general-purpose
supercomputers in the world.
This unique processing challenge needed innovative design,
both for the individual components and for the overall
architecture of the correlator.
The initial design of the correlator,
as well as its construction and installation,
was led by the US National Radio Astronomy Observatory,
the lead North American partner in ALMA.
The correlator project was funded by the US National Science Foundation,
with contributions from ESO.
As the European partner in ALMA, ESO
also provided a key part of the correlator:
an entirely new and versatile digital filtering system,
conceived and built in Europe,
was incorporated into the initial NRAO design.
The University of Bordeaux designed and built a set
of 550 state-of-the-art digital filter circuit boards for ESO.
With these filters, the light that ALMA sees
can be split up into 32 times more wavelength ranges
than in the initial design,
allowing astronomers to flexibly "slice and dice" the spectrum of light.
As well as enormous technical challenges in building the correlator,
the extreme location of the system was also a factor.
The correlator is housed in the ALMA
Array Operations Site Technical Building,
the highest-altitude high-tech building in the world.
At 5000 metres altitude, the air is thin, meaning that
twice the normal airflow is necessary to cool the supercomputer.
The thin air also makes it impossible to use spinning computer disk drives,
as their read/write heads rely on
a cushion of air to stop them crashing into their platters.
Furthermore, the correlator had to be designed to withstand
earthquakes, which are common in this region.
ALMA began science observations in 2011
with a partial array of antennas.
A section of the correlator was already in use
to combine the signals from these antennas,
but now the full system is complete,
ready for ALMA to begin observations with a larger number of antennas.
The successful installation of the new supercomputer
marks an important step toward the completion of ALMA in the near future.
By using the array's unparalleled observational power,
scientists will gain new insights into the hidden wonders of the Universe.
ESOcast is produced by ESO, the European Southern Observatory www.eso.org
ESO, the European Southern Observatory, is the pre-eminent intergovernmental science and technology organisation in astronomy,
designing, constructing and operating the world’s most advanced ground-based telescopes.
Transcription by ESO ; translation by —