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Update on the SKA

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Title: Update on the SKA

1
Update on the SKA

Richard Schilizzi
International SKA Project Office
SKA Wide-Field Imaging Workshop, Dwingeloo, 22
June 2005

2
Square Kilometre Array

extremely powerful survey telescope at radio
wavelengths - capability to follow up
individual objects with high angular and time
resolution
1 km2 collecting area sensitivity 50 x EVLA

- survey speed is 10000 x faster than EVLA
wide frequency range 0.1 25 GHz (goal)
wide field of view 1 sq. degree at 1.4 GHz (5
x area of moon) -
goal many tens of sq. deg.

3
Square Kilometre Array

goal of multi-beam instrument at lower
frequencies
construction cost 1000 M operating cost 100 M
per year
born global gt50 institutes in 17 countries
actively involved

4
Key Science Projects

probing the dark ages before the universe lit up
the evolution of galaxies and large scale
structure in the universe (equation of state of
dark energy)
strong field tests of gravity using pulsars and
black holes
the origin and evolution of cosmic magnetism
the cradle of life movies of planetary
formation ETI
exploration of the unknown
SKA science case (eds C. Carilli, S Rawlings)
published by Elsevier in New Astronomy Reviews,
vol 48, pp989-1163, December 2004
(see also www.skatelescope.org)

5
Equation of state of dark energy via HI surveys
with SKA

dark energy alters distance measures in cosmology
power spectrum of the clustering of galaxies
likely to contain a signature of acoustic
oscillations seen in the CMB at time of
recombination
use scale of acoustic oscillations as a
cosmological standard ruler to measure equation
of state of dark energy at intermediate redshift
and possibly its evolution. 0.5ltzlt1.5 optimal
evolution of the HI content of the universe.

CMB
SKA HI surveys
from C. Blake, S. Rawlings et al
6
SKA pulsar survey
expect 20000 psrs incl. 1000 MSPs and
BH-pulsar binaries
7
Cosmic Magnetism
From Rainer Beck and Bryan Gaensler
8
Science requirements on FoV

Contiguous imaging FoV
1 square degree within half power points at 1.4
GHz, scaling as ?2
200 sq. deg. within half power points at 0.7 GHz,
scaling as ?2 between 0.5-1.0 GHz
Note The 1 square degree FoV is required by all
key science projects. The 200 square degree FoV
for 0.5-1.0 GHz is required by the dark energy
key science project.
Number of separated FoV
1 with full sensitivity Goal 4 with full
sensitivity
10 simultaneous sub-arrays
Note One FoV is required for all projects
(obviously). None require more than a single FoV,
but most would benefit from this (especially the
large surveys) and it would dramatically increase
the general observational flexibility of the SKA.

9
Science requirements on data processing

Correlator and post- correlation processing
Imaging of 1 sq. degree at 1.4 GHz with 0.1
arcsec angular resolution
Imaging of 200 sq. degrees at 0.7 GHz with 0.2
arcsec angular resolution
Note Full field (but not full resolution)
imaging requirements needed for
pulsars, galaxy origins, magnetic universe, and
dark energy
Imaging of 104 separate regions within the FoV,
each covering at least 105 beam areas at full
(maximum baseline) angular resolution
Note High angular resolution requirement
needed for
pulsars, galaxy origins, and cradle of life
( AGN/jets, astrometry, and imaging of stars,
solar system objects, and maser sources)
Spectral resolution of 104 channels per observing
band per baseline
Requirement for 104 spectral channels
adequate velocity resolution over wide
bandwidths for dark energy

10
Large Mosaics (Robert Braun)

Historically interferometric imaging was
constrained to a single primary beam, but large
WSRT mosaics are now routine.
eg. WSRT HI mosiac of M31
163 pointings on 15 arcmin
Nyquist-sampled grid
350 hours observing
Aug. 2001 Jan. 2002
50 pc x 2 km/s res. over the 80 kpc disk
s 1.4 mJy/Beam (at DV 2 km/s)
DNHI 1.0, 3.5, 11 and 24 x 1018cm-2
_at_ 120, 60, 30 and 20 (DV20 km/s)
extended rotation curve / warping
outer HI edge / UV radiation field
CNM / WNM in disk
circum-galactic HI clouds and streams

11
SKA Concept
up to at least 3000 km from inner array
100-150
Software controlmonitoringcorrelation
calibration image formation archiving
scheduling
2000 antennas
12
SKA in Australia
20 of total collecting area within 1 km diameter
50 of total collecting area within 5 km
diameter 75 of total collecting area
within 150 km from core
maximum baselines at least 3000 km from array
core
13
SKA in Argentina
14
(Landsat)
SKA in China
15
(No Transcript)
16
RFI equipment
ASTRON
Australia
China
South Africa
Argentina
17
Antenna concepts

Small diameter dishes ( Focal Plane Arrays)
Aperture phased arrays
Large diameter reflecting flux concentrators

Aperture array tiles
Small dishesFPAs in the focus
Small dishes
Spherical telescopes
Large adaptive reflectors
Major technical challenge for the SKA
reduce cost/m2
by a factor of 10 compared with current telescopes
18
Antenna innovations

Low-cost dense arrays for aperture and focal
planes
Active surfaces for large reflectors
Broadband feeds
Suspended or airborne inertial feed platform
Cheap, accurate 12m dishes using hydroforming or
preloading

19
SKA development funds

50 M spent or committed to SKA development
around the world since 1995.
Recent initiatives xNTD (Australia), KAT (South
Africa)
In negotiation
SKADS EMBRACE 2PAD (EU FP6 (10.4M)
matching total 35-40M, 2005-9)
Current proposals for funds
Small Dishes SKA Technology Development Program
(NSF US 31M, 2005-9)
Large Adaptive Reflector - LAR Technical
Development (NRC CA 12M, 2005-9)
Development via SKA pathfinders comes for free
telescopes
that are precursors to the SKA and will prove
major technology components for the SKA, eg
LOFAR, EVLA, Allen Telescope Array, eMERLIN,
eEVN,