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What is EXPReS?
• EXPReS = Express Production Real-time e-VLBI Service
• Three year project (March 2006-2009) funded by the European Commission
(DG-INFSO), Sixth Framework Programme, Contract #026642 EXPReS
• Funded at 3.9 million EUR
• International collaboration: 19 radioastronomy institutes and research and
education networks (NRENs) representing 14 countries on 6 continents
• Objective: to create a distributed, large-scale astronomical instrument of
continental and inter-continental dimensions
• Means: high-speed communication networks operating in real-time and
connecting some of the largest and most sensitive radio telescopes on the
planet to the central correlator in the Netherlands
PRESENTATION DATE
EXPReS- TITLE OF YOUR PRESENTATION
Slide #1
EXPReS Partners
14 Countries, 6 Continents
Radio Astronomy Institutes
• Joint Institute for VLBI in Europe (Coordinator), The Netherlands
• Arecibo Observatory, National Astronomy and Ionosphere Center, Cornell University, USA
• Australia Telescope National Facility, a Division of CSIRO, Australia
• Institute of Radioastronomy, National Institute for Astrophysics (INAF), Italy
• Jodrell Bank Observatory, University of Manchester, United Kingdom
• Max Planck Institute for Radio Astronomy (MPIfR), Germany
• Metsähovi Radio Observatory, Helsinki University of Technology (TKK), Finland
• National Center of Geographical Information, National Geographic Institute (CNIG-IGN), Spain
• Hartebeesthoek Radio Astronomy Observatory, National Research Foundation, South Africa
• Netherlands Foundation for Research in Astronomy (ASTRON), NWO, The Netherlands
• Onsala Space Observatory, Chalmers University of Technology, Sweden
• Shanghai Astronomical Observatory, Chinese Academy of Sciences, China
• Torun Centre for Astronomy, Nicolaus Copernicus University, Poland
• Transportable Integrated Geodetic Observatory (TIGO), University of Concepción, Chile
• Ventspils International Radio Astronomy Center, Ventspils University College, Latvia
National Research and Education Networks (NRENs)
• AARNet, Australia
• DANTE, United Kingdom
• Poznan Supercomputing and Networking Center, Poland
• SURFnet, The Netherlands
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Slide #2
Participating Telescopes and Network Paths*
Image created by Paul Boven, JIVE. Satellite image: Blue Marble Next Generation courtesy of NASA Visible
Earth (visibleearth.nasa.gov). *Logical network paths.
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Slide #3
EXPReS Network Diagram
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Slide #4
Activities
#
PC
NA1
NA2
NA3
NA4
SA1
SA2
JRA1
Description
Project Coordinator
Management of I3
EVN-NREN Forum
eVLBI Science Forum
Public Outreach
Production Services
Network Provisioning
FABRIC
PRESENTATION DATE
Leader
Huib Jan van Langevelde, JIVE
T. Charles Yun, JIVE
John Chevers, DANTE
John Conway, Chalmers
Kristine Yun, JIVE
Arpad Szomoru, JIVE
Francisco Colomer, CNIG-IGN
Huib Jan van Langevelde, JIVE
EXPReS- TITLE OF YOUR PRESENTATION
Slide #5
What is VLBI?
• Astronomy technique: Very Long Baseline Interferometry
• A radio telescope looks at an object in the sky and collects data to create an
“image” of the source.
• Multiple telescopes can view the same object simultaneously. The distance
between the telescopes is the baseline. The baseline can be compared to
building a single telescope with the diameter of this distance (sort of).
• The resolution increases with additional telescopes and longer baselines.
• The sensitivity of the image increases with the data collection rate at the
telescope.
• A central processor decodes, aligns and correlates the data for every possible
telescope combination.
• Result: images of cosmic radio sources with up to a hundred times better
resolution than images from the best optical telescopes
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Slide #6
The science of e-VLBI
Aperture Synthesis Imaging
Image Credits: Avruch and Pogrebenko
• A technique that uses a number of telescopes to simulate a much larger one.
A larger dish, real or simulated, improves image clarity and brightness. This
requires coordination between the telescopes and a supercomputer. Consider
the examples displaying aperture size, aperture distribution and image quality.
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Slide #7
Interferometry Makes a Virtual Telescope
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Slide #8
What is the correlator?
• Dedicated, purpose-designed and purpose-built hardware
• Synthesis imaging simulates a very large telescope by measuring
Fourier components of sky brightness on each baseline pair
• Decodes, aligns and correlates the data for every possible
telescope combination
• EVN MkIV data processor at JIVE
• custom silicon, 1024 chips
• Input data is 1 Gb/s max
• Around 100 T-operations/sec
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Slide #9
Interferometry
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Slide #10
What is e-VLBI?
• Electronic VLBI
• Instead of recording data and shipping disks to the central
processor, immediately transport data over networks and
correlate it in real-time.
• Benefits:
- eliminate weeks from the observation & correlation schedule
- monitor problems in data collection
- detect transient events and schedule near-immediate followon observations
- automate observation
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Slide #11
Traditional VLBI vs. e-VLBI
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Slide #12