mmVLBI in the Future: technical/experimental Shep Doeleman Haystack Observatory In Defense of Theory Do I contradict myself? Very well then I contradict myself, (I am large,
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mmVLBI in the Future: technical/experimental Shep Doeleman Haystack Observatory In Defense of Theory Do I contradict myself? Very well then I contradict myself, (I am large, I contain multitudes.) --Walt Whitman, "Song of Myself" High Frequency VLBI Challenges • Sensitivity: limited by atmospheric coherence, telescope apertures, bandwidth, weather (opacity and coherence). – Past observations limited to brightest sources. • Baseline coverage: limited by relatively small number of high demand sub/mm telescopes. • LO quality: phase noise in electronics increases – loss of fringe amplitude. – First VLBI at new mm sites requires effort. Challenges cont’d • Scheduling: mm/submm telescopes difficult to schedule. • Array phasing: all antennas must be phased prior to summing (you only get one chance). • Hydrogen masers: if atmosphere is good, maser should not limit coherence time. • Amplitude calibration is difficult: array phasing, pointing, atmosphere, gain curves. • BBCs have limited Bandwidth • Major improvements can be expected in some of these areas. Sensitivity: a solution. • Old conventional wisdom: collecting area. • New technical developments – new wisdom – 1983 VLBI BW: 224Mb/s, – 2004 VLBA BW: 512Mb/s. – New disk based VLBI recording systems will allow multi Gb/s data rates Mark 5A VLBI Data System Mk5 cost ~ $15K 700 GB disks expected ~2005 – 24 hours @ 1 Gbps unattended (comparable to ~19 VLBA tapes) Sensitivity: a solution. • Old conventional wisdom: collecting area. • New technical developments – new wisdom – 1983 VLBI BW: 224Mb/s, – 2004 VLBA BW: 512Mb/s. – New disk based VLBI recording systems will allow multi Gb/s data rates. – Leverages COTS technology and industry demand for affordable, high capacity, high speed hard disks. – Units can be used in parallel for N Gb/s. Tape vs. Disc Price Comparison 7 6 5 Disc Drive Street Prices log($/GB) 4 1998 IBM Disc Projection 3 c Computer Tape Media 2 1998 NSIC Disc Projection 1 LTO Media Projection Mark IV/VLBA/K4 Media 0 S2, S3 Media Disc industry Projections -1 -2 1980 1985 1990 1995 Year 2000 2005 2010 mmVLBI at Haystack • 2001-present: focus on 1-2mm VLBI • 2002: Carried out successful 129, 147GHZ VLBI on Pico Veleta, KittPeak12m, SMTO triangle: – High resolution: Pico-SMTO fringes – 49mas – SiO Masers – Collaborators: MPIfR, IRAM, Onsala, Metsahovi, Arizona Radio Observatory mmVLBI In the News v=1 J=3-2 SiO Masers in VY CMa • First 129GHz VLBI image using all phase and amp information. •Relative astrometry small fraction of beam. 30 AU mmVLBI at Haystack • 2001-present: focus on 1-2mm VLBI • 2002: Carried out successful 129, 147GHZ VLBI on Pico Veleta, KittPeak12m, SMTO triangle: – High resolution: Pico-SMTO fringes – 49mas – SiO Masers • 2003: Carried out 129, 230GHz VLBI using Pico, KittPeak, SMTO, Plateau de Bure – Detected Pico-SMTO 1.3mm fringes – 34mas on 3C279 – World Record: equivalent to 5 RSCH of SgrA* MBH – Used new generation of VLBI recorders. • Very promising, but future depends on funding. Evolution of 3mm Capability Present: 256Mb/s 3-5 years: 1Gb/s Antenna Antenna SEFD (Jy) Antenna GBT 500 ALMA VLBA SEFD (Jy) 5170 5-10yrs: 10Gb/s PicoVeleta 1700 Apex (Chile) 5000 P. de Bure 1700 CARMA 1700 Onsala 4000 LMT 350 Effelsberg 2000 Nobeyama 3000 VLBA-VLBA = 0.8Jy PicoV-PdeB = 0.25Jy PicoV-PdeB = 0.13Jy* PicoV-VLBA = 0.5Jy VLBA-VLBA = 0.4Jy GBT-LMT = 0.032Jy GBT-LMT = 0.016Jy* LMT-VLBA = 0.1Jy SEFD (Jy) 60 VLBA-VLBA = 0.13Jy ALMA-LMT = 0.004Jy ALMA-VLBA = 0.014Jy Resolution (8000km)=90mas Tcoh = 20 seconds Higher recording rates. Evolution of 1mm Capability Present: 0.5Gb/s 3-5 years: 4Gb/s Antenna Antenna SEFD (Jy) Antenna JCMT 7800 ALMA KittPeak SEFD (Jy) 22000 5-10yrs: 10Gb/s PicoVeleta 2500 APEX-Chile 5500 P. de Bure 2500 CARMA 2500 SMT 15000 LMT 500 SMA 2500 CSO 15000 PicoV-PdeB = 0.4Jy PicoV-KittPeak = 1.15Jy LMT-CARMA = 0.06Jy LMT-SMT= 0.15Jy SEFD (Jy) 100 ALMA-LMT = 0.008Jy ALMA-SMT = 0.042Jy Resolution (8000km)=34mas Tcoh = 10 seconds UltraVLBI Proposal • Submitted to ATI program at NSF • Outfit largest cm antennas (Effelsberg, Arecibo, GBT, WSRT, Jodrell bank) with 4Gb/s recording systems: <1mJy/beam rms. • Outfit best mm sites with 4Gb/s systems: JCMT, SMTO (CARMA, LMT, SMA, ALMA, APEX) • Target science requiring sensitivity: SNR in Galactic mergers, GRBs, Grav. Lenses, Stellar VLBI, SgrA*!! • Waiting to hear … 230GHz VLBI Observations Proposed VLBI on JCMT-HHT baseline. Just a detection will provide a firm upper size limit. Next Generation VLBI System • Multiple Digital BBC units (500MHz each). – Cost: 20K each. • Multiple MK5b units (1Gb/s each). – Cost: 16K each. • H-maser with sy(10sec)<=3e-14. – Cost: 175K. • Rack with power supplies, backplane, GPS clock, – Cost: 20K • Total: $270K/new station, much less if maser is already available. Summary • Over next decade: BW x40, Element area x25, means capable 230GHz imaging arrays. • Phase stability of mm/submm arrays is very important: CARMA, ALMA, PdeBure. • Creating low phase noise LO systems for submm VLBI is necessary. • VLBI arrays up to 345 and 450GHz are possible. • ‘Widebanding’ IFs and receivers will be a requirement. • Scheduling: need turn-key operation from single dish to VLBI. • Current proposed work: 4Gb/s VLBI on SgrA* in 3 years. END