ACA Calibration Plan
B. Vila-VilaroALMA-J Project Office, NAOJ
SSR Meeting, Charlottesville, 20-21 Nov 2005
12m Array: ALMA-B, baseline array provided by NA/EU ACA (Full Array): (ACA) 7m Array + (ACA) TP Array (ACA) 7m Array: 12 x 7m antennas provided by ALMA-
J. Mainly used as an interferometer (ACA) TP Array: 4 x 12m antennas provided by ALMA-J.
Mainly used as single-dishes for TP (zero spacing) data. Coordinated observations: Observations of a common
program by 12m Array and ACA that are executed separately. No cross-correlations between 12m Array and ACA are taken. Main Mode
Combined Array (Mode): 12m Array + 7m Array (+ TP Array) operated as an interferometer.
Stand-alone Observations/Mode: ACA observing projects that are not included in the 12m Array schedule.
Glossary
The ALMA Site10m 20m 30m 40m 50m
10 7.2 10.7 13.6 16.1 18.3
20 10.2 15.4 19.6 23.3 26.6
30 13.6 20.7 26.5 31.6 36.1
40 17.9 27.4 35.1 41.9 48.0
50 23.7 36.4 46.7 55.7 64.0
60 31.7 48.7 62.5 74.6 85.6
70 43.7 66.7 85.3 101.6 117.0
80 63.6 95.4 120.9 143.0 162.9
90 108.6 154.2 190.6 221.3 248.2
Pathlength error (microns) estimates due to tropospheric PWV fluctuations. Estimated extrapolating the SSF measured on site with the STI data at 300m and 11GHz. Computed at 60 degrees ELV.
In red, conditions that cause 10% decorrelation at 950 GHz (2% at 345GHz)
In blue, conditions that cause 10% decorrelation at 345 GHz
A reminder on Sensitivities
Point-Source Sensitivity comparison ALMA 50 antennas vs. ACA 7m + ACA TP Same Tsys and receivers, different correlators, curr
ent antenna specifications,no decorrelation
5
6
7
8
0 200 400 600 800 1000
Freq(GHz)
Sens
itivi
ty R
atio
ACA Design Properties 2 types of antennas (ACA TP and ACA 7m) Nutators on ACA TP Antennas 2 configurations for ACA 7m Array, ACA TP Array on fixed st
ations Two sub-arrays Very compact configuration (wind crossing times ~few sec) OPT telescopes on all antennas WVR on (at least) the ACA TP Array ACA correlator Rest of Hardware similar/same as ALMA 12m Array Coherence times > 100sec Lower Point-source Sensitivities than ALMA 12m Array
Main Calibrations
Things you want to know at the time of data collect. (ideally): a) Pointing, Focus, Feeds b) Main Reflector Shape, Beam Shape c) Station Location (Baseline) I d) Delay (electronic, atmospheric,structural,source position) I Things that can be corrected offline: a) Amplitude b) Bandpass c) Phase (atmospheric, system) I d) Side-band Ratios e) Polarization
Pointing All-Sky: ~2” RMS. Global positioning of antenna. Includes all str
ucture-related terms and receiver offsets. Key in acquisition of sources separated by large angles.
Offset: ~0.6”RMS. Important for local positioning of antenna. Key role in switching to nearby calibrators. Up to 4deg separat.
Types: Continuum Spectral (TP only) Modes: Interferometry Single-Dish OPT/NIR
ACA 7m
ACA TP ACA full
Interf (X) (X) X
OPT X X (X)
Single-Dish
(X) X
Calibrator Requirements: ACA full, Interferometric: 350 mJy @ 90GHz (15s/point) ACA TP antennas: 510 mJy @ 90GHz (15s/point)
Pointing pattern: TDB5-point, scan, triangle, etc
Pointing(I): All-Sky Normal Operations: Interferometric, ALL ACA ant
ennas, wide AZ and ELV coverage,continuum Full Band 3 + Other Band Offsets Frequency: ~monthly, ACA reconfiguration, etc Duration: 1-2 hours Other Modes: OPT, Single-dish (nutator, PSW) Requirements: Refraction Correction,Model Fit
Pointing
Focusing
Pointing
Pointing
• Tuning
• Initial Pointing + Focus Loop
• Main Pointing Sequence
Pointing:
a) Get next source from
Catalogue
b) Correct to apparent coordinates (refraction)
c) Move antenna(s) to apparent position
d) Execute Pointing Pattern
e) Solve pointing
f) Update antenna pars/Pointing File
Pointing(II): Offset Normal Operations: Interferometric with ALL ACA ante
nnas (spec up to 4 deg separation), single nearby calibrator (self-pointing possible),continuum
Referenced to Band 3 for high frequency bands, up to Band 4 pointing on same Band.
Frequency: ~15 mins (?) Duration: ~1min Requisites: Refraction correction, Band 3 stand-by, Fo
cus Relative Offsets/Relative Pointing Models
•Tuning
•Observing
•RX Change
•Stand-by
•Wake-up + Other set-ups
•Pointing
•Up to 2 bands tuned
(ref pointing band on stand-by)
•At start/after some observing, switch from observing band to pointing band.
•While slewing bring stand-by band up and set-up necessary relative focus positions/update pointing model
•Pointing on Reference Band
•Update Collimation pars of telescope
•While slewing back bring back obs band and set-up adequate focus/pointing/Ref band to stand-by
•Re-start normal observing
Optics Main Dish Surface, Holography: OSF @ 90GHz AOS (TBD) 2 hour map, <1sec/pixel, 128x128 TP ant 68x68 7m ant 90GHz, 10m RMS 20-40Jy sources Beam/Illumination Pattern Measurements (Including Polarization):
ELV dependency, ALL bands Feed alignment procedures: Only required when installing RX back
on telescope Focus (3 axes): TP Antennas, Focus curves 7m Antennas + TP, Interf Focus Frequency: As Needed (once per tuning+tracking?)
Raster Maps/OTF
Phase-retrieval & Interferometric Holography modes
Tuning
BP Calib
Point+Foc Loop
Raster Map
•Tune RX to desired Band
•Bandpass Calibration
•Go to brightest countinuum point-source at desired ELV (can be same as BP)
•Point loop
•Raster Map keeping one of the antennas fixed while scanning others. Switch antennas at some point.
•Output Data to disk for offline processing
Baseline Specification: 33m per antenna location (Takakuwa 2005) Normal Operations: Continuum Interferometry with ALL ACA ant
ennas Band 3, objects distributed to cover wide range in Hour Angle a
nd DEC. All-sky pointing model is enough. Instrumental phase corrected
periodically by observations of single calibrator. Frequency: Once per array re-configuration, antenna addition, s
pecial situations Duration: ~2hr/session Requirements: As for pointing, good weather
Tuning
Pointing
Pointing
Focusing
Gain Calibrator
Calibrator
Calibrator
•Tune RX
•Pointing/Focus Loop
•Execute Loop of short synthesis observations of a Gain calibrator and several baseline calibrator sources
•Loop involves going to next source in catalogue (apparent coordinates) and performing a ~30sec synthesis
•Data output to disk for offline processing
Delay
Source Positions: 1/10 of Max Freq. Synthesized Beam 0.1”, 12m Array 0.7mas
Atmospheric (bulk): Must be calculated per antenna (~130fs at low elevations for the ACA)
Structural: Metrology Electronic (chromatic): bright compact
continuum source. Needs to be done for all bands and polarizations. Should be fairly stable with time once measured. ALL ACA antennas
Electronic Delay Measurement
Tuning
Delay 2
Delay 1
•Tune each RX, both polarizations
•Go to bright continuum point source
•Short synthesis on source
•Setting Band 3 as receiver delay reference one gets the IF terms
•For other Bands, get Receiver delays from measured IF delays
•Fit of phase slope done offline
•Self-pointing/Focus optional (Default values possible)
Amplitude
Relative: Allows comparison of data within observing band and data merging between arrays. Repeatability of observations.
Absolute: Accurate physical quantities. Accurate line ratios. Relative
•3% for up to Band 7, 5% above
•Method: Dual-Load + Tau Measurement in TP mode
•Requires: Atmospheric model, antenna parameters, SBR (TP),f
•Frequency: a few mins
Absolute
•5% for all bands
•Method: Standard Calibrator obs.
•Requires: Boostrapping, good primary calibrators
•Frequency: Once per dataset
Relative Amplitude CalTuning
LD1
LD2
SKY
Observ
Calibration
•Tune to observing frequency
•Initial Set-up Observations (pointing+focus loop)
•Go to Target source
•Start Observing loop that includes amplitude calibration and observations.
•Amplitude calibration is in three steps (TP observation mode):
a) Input Load 1, Set ATTNs (if needed), Integrate 1-2sec, Release Load 1, reset ATTNs (if needed)
b) Input Load 2, Set ATTNs (if needed), Integrate 1-2sec, Release Load 2, reset ATTNs (if needed)
c) Move antenna OFF target source, Observe SKY and return to source
•Data output from the three observations is used to calculate Tcal. Tau calculated/measured too.
TAU
•For Jy/K synthesis observations of known calibrator are used
Bandpass Use of combined modes: (10000:1 spec) Rest of cases: (>1000:1) Frequency: Once per tuning Calibrators: Bright flat-spectrum cont. sources
(compact) Method: Traditional high decorrelation at high freqs. Self-Cal/Phase cal better ALL ACA antennas involved! Required for spectral obse
rvations ONLY
Tuning
Spectral Mode Set-up
Pointing
Pointing
Focus
Synthesis
Observ
•Tune to obs frequency
•Set-up for Spectral Mode
•Pointing/Focus Loop (on Self)
•Synthesis Observations of Calibrator (~1hr)
•Save data to disk for offline reduction
•Proceed with other observations
Phase
Short-Term: scales of a few sec, mostly due to random structural/environment terms and atmospheric PWV fluctuations.
Affect more the sensitivity of the observations (decorrelation)
Long-Term: scales of minutes, mostly due to instrumental fluctuations and long term weather patterns
Affect the quality of the imaging performance
Phase(I): Short Term
WVR on the ACA TP antennas: 10(1.25+w)m Decorrelation: Measuring 1sec average EPL alo
ng line of sight at 4 corners of array. Direct decorrelation for ACA TP, and extrapolated for inner ACA 7m.
Phase Variations: Relative to last long term value. Extrapolated to inner ACA 7m Array.
Asaki(2005), ALMA Memo 535
O
B
S
E
R
V
WVR •TP Antennas MUST point in the general area of the ACA 7m
•During Synthesis with the ACA 7m, the WVR are taking data at 1Hz continuously
•Data from WVR must be labelled with a timestamp and the WVR of origin
•Calibration is done POST-CORRELATION
Phase(II): Long Term Method: Low Frequencies Phase Referencing to
nearby calibrator High Frequencies Phase extrapolation from
Band 3 Frequency: 100sec (coherence time Band 10) Phase Transfer Schemes
“Don’t Rock The Boat” “Controlled Roll-Over”
Don’t move the subref much Track movement of subref
Advantages: Advantages:
You “know” where the tel. structure is You “correct” for the tel. structure
Difficulties: Difficulties:
Loss of Sensitivity Subref tracking must be accurate
Differential Pointing Model Required Longer Switching Time
•Tune up to 2 Bands. Reference Band on Stand-By mode until needed
•Do some observations on Target band (pointing, synthesis, cals, etc)
•While moving to calibrator bring stand-by band up and set additional parameters (pointing model, focus, etc.)
•Synthesis on Calibrator (~a few secs)
•Go back to target, put Reference band on stand-by and bring up Target Band with necessary parameters
•Synthesis on Target
•Cycles will be >100sec for the ACA
Tuning
Obs Stby
Band Switch
Side-Band Ratio
Important issue in DSB receivers and TP observations. Interf. quite time consuming.
Frequency: once per tuning Calibrators: a) SSB standards/Referencing b) Artificial Line Injection c) two ELV method (ALMA Memo 505) d) Skydip + ATM modelling
Polarization Linear vs. Circular Reception: -Circular reception is easier to calibrate -BOTH TP and 7m Array should observe same type -TP is quite more challenging than Interf (Tsys term) -Effects of off-axis polarization on mosaicing need to be studie
d -Scaling of TP to Interf would be advisable Calibrators: currently no good calibrators available for the high
frequency ALMA Bands. Will require surveys.(Planets???) Role of artificial signal injection is currently being studied
ACA Calibration Issues
Refine Calibration Specs & Reqs Detailed Calibration Use Cases Optimization of Cal Techniques Operation Cycles/Scheduling Impact Imaging/TP Simulations Combined Array Issues/Data Merging Array Design Completion Polarization Hardware Issues (Nutators, WVRs, P-Cal)
ACA Operation Concept
Unification with baseline array under JAO
AIV Phase CSV
AIV Phase CSV
ALMA
Partners
Unified
Operation
JAO
Impact of ACA Department of Science Operations: 1) Array Operations: not major 2) Program and Data Management: not major Department of Technical Services: 1) Antenna Group: 20-25% increase, 3-5 turno personnel 2) Electronics Support for FE: 20-25% increase, 3 turno personnel 3) Electronics Support for BE: 1 turno personnel 4) Computing Group: not major 5) Maintenance Group: not major 6) System Enginneering Office: not major 7) Spectrum Management Office: not major 8) Technical Information System Office: not major Others: Antenna Transporters, FE Service Vehicles (cost study), Maintenanc
e Impact
ACA Scientific Operation Unification: IPRC LTQ ACA User Interface: As close as possible to that of 12m
Array Ops Scheme: a) Coordinated Obs (main) b) Combined Mode (BLC) c) Stand-Alone (minor) ACA 7m re-configurations: inner 6 ant fixed 60:40 sky coverage ~bimonthly (TBD) ACA Stand-alone: -TOO -Beam-size Matching Obs (hybrid?) -Absolute Flux Scale Maintenance ACA availability: 95%
Timeline (TBD)
2009 Dec Early Science Obs with TP Array (1)
2010 Q4 Early Science Obs with 7m Array (6)
2012 Q1 Full Science Obs with ACA
Operation Modes
Long-Term: -Short time lags: Symmetric -Long time lags: ACA trailing Short-Term: 7m and TP used during calib independent modes afterwards Combined Mode: -Projects that require high calibration precision -Significant Increase in Sensitivity (Iono) Stand-Alone Mode: Same as coordinated obs higher spectral resolution modes (TBD) Usually 7m + TP Array
ACA Data Rates
12m Array data rate to ALMA archive is ~6MB/s (average) and ~60MB/s (sustained)
Simple scaling by baseline numbers implies:
~0.36 MB/s (average) & 3.6 MB/s (sustained)
Combined Mode: 50 + 16 (init) x 1.06
Schedule Flow
Proposals
Scheduling
Execution
Data
Call
For
Proposals
ACA?
•ACA Necessity Checker
•ACA Sensitivity Calculator
Review+
?
ACA PL
ALMAB PL
Observations
•ACA Priority
•Completion Policy
•ACA Dynamic Scheduler (7m & TP), BALMA for Combined Mode(?)
+
Data Pipeline•Data Delivery
•Data Proprietary period
ALMA arrays
-12m Array ONLY
-TP Array ONLY (minor)
-ACA ONLY (standalone mode)
-12 Array + ACA TP Array (coordinated)
-12m Array + ACA Full Array (coordinated)
-12m Array + ACA @ different frequencies
-Combined Array
-Combination of modes
7m Array Re-Configurations
-Normal: 12 weeks (TBD)
-NS Extension: 8 weeks (TBD)
Summary of Science Deliverables
ACA raw uv and visibility data for targets and calibrators (quality-assured)
ACA processed images and combined images
Off-line reduction software for data combination
Proposal preparation software tools (ACA) ALMA users manual with ACA sections