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Introducing the EVLA NRAO Postdoctoral Symposium, 29 April-1 May 2009 Michael P. Rupen Project Scientist for WIDAR.

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Presentation on theme: "Introducing the EVLA NRAO Postdoctoral Symposium, 29 April-1 May 2009 Michael P. Rupen Project Scientist for WIDAR."— Presentation transcript:

1 Introducing the EVLA NRAO Postdoctoral Symposium, 29 April-1 May 2009 Michael P. Rupen Project Scientist for WIDAR

2 2 The promise of the EVLA

3 3 Living in the past: the VLA 1970s technology Amazing at the time – Order-of-magnitude improvement in sensitivity, resolution, flexibility Still the premier radio telescope in the world

4 4 Living in the past: the VLA 1970s technology Amazing at the time – Order-of-magnitude improvement in sensitivity, resolution, flexibility Still the premier radio telescope in the world

5 5 Enter the EVLA Fibers New receivers New correlator Bandwidth x80 Sensitivity x10

6 6 Continuous Frequency Coverage 1-50 GHz --> Observations defined by science, not hardware

7 7 Wide Bandwidths 2:1 bandwidth ratios … with LOTS of channels Sensitivity 1- , 12-hours Red: Current VLA Black: EVLA Goals

8 8 Wide Bandwidths 2:1 bandwidth ratios … with LOTS of channels Sensitivity UV-coverage Rau, Owen, Cornwell, Eilek 1.702 GHz1.302 - 2.102 GHz

9 9 Wide Bandwidths 2:1 bandwidth ratios … with LOTS of channels Sensitivity UV-coverage Spectral index & curvature Spectral index Spectral curvature Rau, Owen, Cornwell, Eilek Stokes I VLA/C 1.18-1.86 GHz (16x30 mins)

10 10 Wide Bandwidths 2:1 bandwidth ratios … with LOTS of channels Sensitivity UV-coverage Spectral index & curvature Polarization & rotation measures Spectral lines & redshifts TA*TA* Kaifu et al., 2004. 8 GHz 0.1 GHz

11 11 Wide Bandwidths 2:1 bandwidth ratios … with LOTS of channels Sensitivity UV-coverage Spectral index & curvature Polarization & rotation measures Spectral lines & redshifts … all the time! H1743-322 (McClintock et al. 2007) Radio Soft X-ray

12 12 Status & schedule

13 13 Current status All fiber laid 21 EVLA antennas now in use -- account for >70% of ant-hours All feed horns fabricated for L, C, Ka; S and Ku underway 9 Ka-band, 2 S-band receivers deployed – L-band prod’n begins 2009 – Ku-band prototype under development OMTs meet specifications (L, C, S); X-band design almost complete LO/IF ahead of schedule 8-bit (1 GHz) samplers installed; first 3-bit (2 GHz) due in June Real-time software on track (migrated from Modcomps; Proposal, ObsPrep, Scheduler, Archive Tools; WIDAR systems integration) Post-processing software looking good (CASA; algorithms; cluster) WIDAR correlator – Data cables & all racks installed – final hardware ordered – 10-station, 4 subband, single pol’n WIDAR-0 fringing nicely (March 6)

14 14 Schedule: Growth of New Capability Interim receivers not shown

15 15 Summary Project is going well Financial health of the project is good Technical issues largely resolved Project is on schedule: – Antenna retrofits will be complete in Q3 CY2010 – Receiver installation complete in Q4 CY2012 – Correlator scheduled for completion in Q1 CY2010 – Software development on track to support commissioning and early science

16 16 Will it work?

17 17 Efficiency and Tsys Results Band (GHz) TsysAperture Effic. Req’dActual # Req’dActual # L1 – 226TBD.450.40 – 0.45 S2 – 42624 – 28*.62~0.52* C4 – 82624 -- 31.56.53 --.61 X8 -- 1230TBD.56TBD Ku12 -- 1837TBD.54TBD K18 -- 26.55936 -- 42.51.57 --.48 Ka26.5 -- 405340 -- 50.39.48 --.36 Q40 -- 5074 -- 11655 -- 100.34.37 --.28 Blue = System tested and in place, or under installation. Red = Prototypes to be tested in 2009 * Preliminary result # Range over the band

18 18 C and Ka Band Sensitivity Detail Sensitivity as a function of frequency: Colored lines are derived via correlation coefficients Black line with dots are from direct antenna measurements. Ka-Band C-Band Project Requirement

19 19 C and Ka-Band Cross-Polarization Antenna ‘D-Term’ polarization with the new OMT design close to the specs at C-band. Ka-band polarization, with waveguide OMT meets specs, except at the band edges.

20 20 Pol’n stability: C-Band I V Q U N7027 is a planetary nebula – no polarization is expected. D-Configuration. 4885 MHz. Data taken in pieces over 16 days. Phase self-calibration, flat amplitude calibration. Single polarization solution. Peak 4637 mJy 3.6 mJy 1.01 mJy 1.02 mJy Pk/I.07 %.025%.025% Polarization images are (nearly) noise-limited!

21 21 Pol’n stability: L-Band (1485 MHz) Peak = 21241 mJy,  = 0.21 mJy Max background object = 24 mJy Peak = 4 mJy,  = 0.8 mJy Peak at 0.02% level – but not noise limited! IQ 3C147 is unpolarized 6 hours’ continuum data with interim L-band polarizers Single pol’n solution

22 22 Bandpass Phase and Amplitude Stability From the prototype WIDAR correlator, observations at 6cm of 3C84 – a strong calibrator – with four antennas. Residual ripple in vector sum meets requirements. Observations made hourly, each 20 minutes long. Bandpass calibration done each 10 minutes. Vector averaged spectrum shown. Edge channels not shown.

23 23 3C84 @ 1.5 GHz 1244-1756 MHz 8192 x 62.5 kHz (13 km/s for local HI) 512 MHz

24 24 3C84 @ 1.5 GHz 1244-1756 MHz 8192 x 62.5 kHz (13 km/s for local HI) HI VLA polarizer satellites ABQ radars 512 MHz

25 25 3C84 @ 1.5 GHz 1244-1756 MHz 8192 x 62.5 kHz (13 km/s for local HI) HI VLA polarizer satellites ABQ radars Current VLA: 6.25 MHz @ 98 kHz 512 MHz

26 26 3C84 @ 1.5 GHz 1244-1756 MHz 8192 x 62.5 kHz (13 km/s for local HI) Final EVLA: – 512 MHz (z=0-0.3) – @ 7.8 kHz (1.7 km/s) HI VLA polarizer satellites ABQ radars Current VLA: 6.25 MHz @ 98 kHz 512 MHz

27 27 3C84 @ 1.5 GHz 1376-1384 MHz (one 8 MHz subband) 4096 x 1.95 kHz (0.4 km/s)

28 28 3C84 @ 1.5 GHz 8 x 8 MHz subbands 8 x 4096 channels – Avg’d x2 (3.9 kHz) – or x64 (470 kHz) Zoomed in here! Tau~ 0.15 1382.95 MHz Tau~ 0.21 1420.35 MHz 32 km/s17 km/s Tau~ 0.003 1395.5 MHz 430 km/s

29 29 3C84 @ 1.5 GHz 8 x 8 MHz subbands 8 x 4096 channels – Avg’d x2 (3.9 kHz) – or x64 (470 kHz) Zoomed in here! Full EVLA: – 64 independently tunable subband pairs – Different bandwidth & resolution for each subband pair Tau~ 0.15 1382.95 MHz Tau~ 0.21 1420.35 MHz 32 km/s17 km/s Tau~ 0.003 1395.5 MHz 430 km/s

30 30 3C84 @ 22 GHz 21988-23012 MHz 8192 x 125 kHz (1.7 km/s) Full EVLA: – 8 GHz (BWR 1.5:1) – Full pol’n – 8192 x 1 MHz (14 km/s) 1 GHz

31 31 Recirculation: Orion water masers 64 MHz, x2 recirc. – 31.25 kHz/channel 1.4% shown here

32 32 Image not limited by closure errors 0217+738 – 4 Jy “dot” – 2hr10min on-source 4588-5612 MHz Self-cal’d image Peak:rms= 72,800:1

33 33 Deep image of a blank field J1900+2815 9012-7988 MHz 2.3 hours on-source Rms in 125 kHz: 2.84 mJy/beam Rms in 103 MHz (825 channels): 0.11 mJy/bm Rms in 825 MHz (825x8 channels): 0.052 mJy/bm

34 34 WIDAR-0 first fringes with 8 antennas Fringes with 8 antennas, 4 subbands: 19mar09 (3C273 5 GHz) Example: Antenna 2, subband 1 1-22-52-92-19 2-242-252-28

35 35 Backup slides

36 36 RSRO capabilities: per subband, no recirculation In the end WIDAR will provide 64 completely independent subband pairs (independent tuning, bandwidth, pol’n products, etc.) Sub-band BW (MHz) Number of poln. products Number of channels/poln product Channel width (kHz) Channel width (kms -1 at 1 GHz) Total velocity coverage (kms -1 at 1 GHz) 1284642000 600/ (GHz)38,400/ (GHz) 644 100030019,200 324645001509,600 16464250754,800 846412537.52,400 446462.5191,200 246431.259.4600 146415.6254.7300 0.54647.8132.3150 0.254643.9061.275 0.1254641.9530.5937.5 0.06254640.9770.2918.75 0.031254640.4880.159.375

37 37 RSRO capabilities: per subband, with recirculation In the end WIDAR will provide 64 completely independent subband pairs (independent tuning, bandwidth, pol’n products, numbers of channels, etc.) Sub-band BW (MHz)00 Number of poln. products Number of channels/poln product Channel width (kHz) Channel width (kms -1 at 1 GHz) Total velocity coverage (kms -1 at 1 GHz) 1284642000 600/ (GHz)38,400/ (GHz) 64412850015019,200 32425612537.59,600 16451231.259.44,800 8410247.8132.32,400 4420481.9530.591,200 2440960.4880.15600 1481920.1220.037300 0.54163840.0310.0092150 0.254163840.0150.004675 0.1254163840.00760.002337.5 0.06254163840.00380.001118.75 0.031254163840.00190.000579.375

38 38 EVLA Review March 200938 Correlator Rack Installation, Aug 2008

39 39 EVLA Review March 200939 Correlator Room Infrastructure

40 40 RFI: correlator linearity WIDAR designed to provide more than 50 dB linearity. Early tests with the PTC are very encouraging Left: Scalar averaged spectrum of 3C84, showing INMARSAT Right: Closeup, showing astronomical signal between emissions. There is no sign of correlator saturation, at a level 40 dB below the peak signal strength.

41 41 1-2 GHz: continuum + RFI 1 GHz

42 42 Cygnus A: MS-MFS Rau, Owen, Cornwell, Eilek Stokes ISpectral Index

43 43 Cygnus A: MS-MFS Rau, Owen, Cornwell, Eilek Stokes ISpectral Index Carilli et al. 1991: VLA A+B+C+D, 1.4+4.8 GHz 1 arcsec resolution)

44 44 Data Rates and Volumes Driver Target Date % time Max rate (Mby/s) Mean rate (Mby/s) Volume (Tby/yr) Now100.06.020.5 PTCAug08small8n/a WIDAR0Mar09small200.14 256 MHz bandwidth; 1024 channels max; 1 sec min dump (OSRO) Mar10900.230.082 2 GHz bandwidth; 8096 channels max; 0.1 sec min dump (RSRO) Mar101020.62 8 GHz bandwidth; 32384 channels max; 0.1 sec min dump; ~10 antennas with 3-bit samplers (RSRO) Jun1010165 8 GHz bandwidth; 1048576 channels max; 0.1 sec min dump (RSRO) Oct1010752060 2 GHz bandwidth; 8096 channels max; 0.1 sec min dump (OSRO) Jun119020.620 8 GHz bandwidth; 1048576 channels max; 0.1 sec min dump (End of construction) Jan131007520600 Early testing indicates we should have no trouble supporting these data rates

45 45 Wide Bandwidths 2:1 bandwidth ratios … with LOTS of channels Sensitivity UV-coverage Spectral index & curvature Polarization & rotation measures Spectral lines & redshifts … all the time! EVLA ALMA 10  in 10min. 4U0614-091 (Migliari)

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