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Advanced Calibration Techniques Michael Bietenholz Based on a lecture by Mark Claussen (NRAO) at the NRAO Synthesis Imaging Workshop.

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Presentation on theme: "Advanced Calibration Techniques Michael Bietenholz Based on a lecture by Mark Claussen (NRAO) at the NRAO Synthesis Imaging Workshop."— Presentation transcript:

1 Advanced Calibration Techniques Michael Bietenholz Based on a lecture by Mark Claussen (NRAO) at the NRAO Synthesis Imaging Workshop

2 Calibration vs Self-Calibration: Phase-referencing: solving for phase (usually along with amplitude) part of complex antenna gains for a target source using visibilities only from a calibrator source. –Position of target source is obtained with respect to that of calibrator –Requires a model of the calibrator source (usually a point) –Target visibilities are un-biased Self-Calibration: determining (or improving) complex gains by using the visibilities from the target source itself –Absolute position information is lost for phase self-calibration –Flux density scale is lost for amplitude self-calibration –Requires having a model of the target source, usually a CLEAN image. Since self-calibration will change target source visibilities used, and thus the model of the targe source, iteration is required. –Target visibilities can become biased

3 3 Self-calibration of a Snapshot (VLA) Original Image Final image Initial image Peak brightness = 14.mJy/beam; lowest contour = 0.20 mJy/bm Peak brightness = 4.9 mJy/beam; lowest contour = 0.65 mJy/bm

4 4 Fundamental calibration equation Calibration Equation Note: g i is equivalent to the J i used in the previous lecture

5 5 Calibration equation becomes Standard Calibration Using a Point-Source Calibrator Where S is the flux density of the source – assumed to be a point source These are calibrator visibilities; given a point source can solve for the complex antenna gains (g i and g j ) Works well - lots of redundancy –N-1 baselines contribute to gain estimate for any given antenna

6 Why Isn’t Using our Calibrator Source Good Enough? Initial calibration based on calibrator observed before/after target Gains were derived at a different time –Troposphere and ionosphere are variable –Electronics may be variable Gains were derived for a different direction –Troposphere and ionosphere are not uniform Observation might have been scheduled poorly for the existing conditions Calibrator may have structure and may not be as strong as expected

7 7 What is the Troposphere Doing? Neutral atmosphere contains water vapor Index of refraction differs from “dry” air Variety of moving spatial structures

8 8 Movie of Point Source at 22 GHz

9 Self-Calibration Use target visibilities and allow the antenna gains to be free parameters. If all baselines correlated, there are N complex gain errors corrupting the N * (N – 1) / 2 complex visibility measurements for a given time. Therefore there are N * (N – 1) / 2 - N complex numbers that can be used to constrain the true sky brightness distribution. Even after adding the degrees of freedom from the antenna gains, the estimation of an adequate model of the target brightness is still overdetermined.

10 10 So begin by using a model of the source visibilities: Self-Calibration Using a Model of a Complex Source One can form a sum of squares of residuals between the observed visibilities and the product of gains and model visibilities and do some kind of minimization by adjusting the gains.

11 11 We can relate this to using a point source for calibration Made a fake point source by dividing by model visibilities Relationship to Calibration With a Point Source

12 12 How to Self-Calibrate 1.Create an initial source model, typically from an initial image (or else a point source) Use full resolution information from the clean components or MEM image NOT the restored (smoothed with ‘Clean Beam”) image 2.Find antenna gains Using “least squares” (L1 or L2) fit to visibility data 3.Apply gains to correct the observed data 4.Create a new model from the corrected data Using for example Clean or Maximum Entropy 5.Go to (2), unless current model is satisfactory shorter solution interval, different u-v limits/weighting phase  amplitude & phase

13 13 Closure phase Self-calibration preserves the Closure Phase which is a good observable even in the presence of antenna- based phase errors Closure Phase is depends only on the source structure, not on the antenna gains A Closure Amplitude can also be formed, which involves four antennas, and which is depends only on the source structure

14 14 Sub-Millimetre Array Closure- Phase Measurements at 682 GHz

15 15 Advantages and Disadvantages of Self-Calibration Advantages –Gains derived for correct time --- no interpolation –Gains derived for correct position --- no atmospheric assumptions –Solution is fairly robust if there are many baselines –More time on-source Disadvantages –Requires a sufficiently bright source –Introduces more degrees of freedom into the imaging: results might not be robust and stable –Absolute position and flux density information lost

16 16 When to and When Not to Self- Calibrate Calibration errors may be present if one or both of the following are true: –The background noise is considerably higher than expected –There are convolutional artifacts around objects, especially point sources Don’t bother self-calibrating if these signatures are not present Don’t confuse calibration errors with effects of poor Fourier plane sampling such as: –Low spatial frequency errors (woofly blobs) due to lack of short spacings –Multiplicative fringes (due to deconvolution errors) –Deconvolution errors around moderately resolved sources

17 17 Choices in Self-Calibration Initial model? –Point source often works well –Simple fit (e.g., Gaussian) for barely-resolved sources –Clean components from initial image Don’t go too deep! –Simple model-fitting in (u,v) plane Self-calibrate phases or amplitudes? –Usually phases first Phase errors cause anti-symmetric structures in images –For VLA and VLBA, amplitude errors tend to be relatively unimportant at dynamic ranges < 1000 or so

18 18 More Choices…. Which baselines? –For a simple source, all baselines can be used –For a complex source, with structure on various scales, start with a model that includes the most compact components, and use only the longer baselines What solution interval should be used? –Generally speaking, use the shortest solution interval that gives “sufficient” signal/noise ratio (SNR) –If solution interval is too long, data will lose coherence Solutions will not track the atmosphere optimally

19 19 Sensitivity limit Can self-calibrate if SNR on most baselines is greater than one For a point source, the error in the gain solution is If error in gain is much less than 1, then the noise in the final image will be close to theoretical

20 20 You can Self-Calibrate on Weak Sources! For the VLA at 8 GHz, the noise in 10 seconds for a single 50 MHz IF is about 13 mJy on 1 baseline –Average 4 IFs (2 RR and 2 LL) for 60 seconds to decrease this by (4 * 60/10) 1/2 to 2.7 mJy –If you have a source of flux density about 5 mJy, you can get a very good self-cal solution if you set the SNR threshold to 1.5. For 5 min, 1.2 mJy gives SNR = 1 For the EVLA at 8 GHz and up, the noise in 10 seconds for an 8 GHz baseband will be about 1 mJy on 1 baseline! MeerKAT will be approximately similar to the VLA (gains: N larger; losses: dishes smaller)

21 21 Hard example: VLA Snapshot, 8 GHz, B Array LINER galaxy NGC 5322 Data taken in October 1995 Poorly designed observation –One calibrator in 15 minutes Can self-cal help?

22 22 Initial NGC 5322 Imaging Cleaned Image Synthesized Beam Dirty Beam Image After best editing and normal calibration

23 23 First Pass Used 4 (merged) clean components in model 1.10-sec solutions, no averaging, SNR > 5 CALIB1: Found 3238 good solutions CALIB1: Failed on 2437 solutions CALIB1: 2473 solutions had insufficient data 2.30-sec solutions, no averaging, SNR > 5 CALIB1: Found 2554 good solutions CALIB1: Failed on 109 solutions CALIB1: 125 solutions had insufficient data 3.30-sec solutions, average all IFs, SNR > 2 CALIB1: Found 2788 good solutions

24 24 Phase Solutions from 1 st Self-Cal Reference antenna has zero phase correction  No absolute position info. Corrections up to 150° in 14 minutes Typical coherence time is a few minutes

25 25 Image After First Pass Original ImageSelf-Calibrated Image Peak brightness = 12.4 mJy/beam; lowest contour = 0.65 mJy/bm Peak brightness = 4.9 mJy/beam; lowest contour = 0.65 mJy/bm

26 Useful Book Keeping Is my image getting better? Keep track of –1) Image total CLEAN flux density –2) Image peak brightness (AIPS from IMHEAD) –3) Image negative extremum (AIPS from IMHEAD) –4) Background rms brightness (AIPS TVSTAT, IMEAN or IMSTAT) For phase-only self-calibration, we expect that 1) and 2) should stay the same or increase, while 3) and 4) should stay the same or decrease For amplitude & phase self-calibration, we generally expect the same, although its possible that 1) and 2) might decrease slightly

27 27 Phase Solutions from 2 nd Self-Cal Used 3 components Corrections are reduced to 40° in 14 minutes Observation now quasi-coherent Next: shorten solution interval to follow troposphere even better

28 28 Image after 2 nd Self-Calibration Original Contour LevelDeeper Contouring Lowest contour = 0.17 mJy/beam Lowest contour = 0.65 mJy/beam

29 29 Result after Second Self- Calibration Image noise is now 47 microJy/beam –Theoretical noise in 10 minutes is 45 μJy/beam for natural weighting –For 14 minutes, reduce by (1.4) 1/2 to 38 μJy/beam –For robust=0, increase by 1.19, back to 45 μJy/beam Image residuals look “noise-like” –Expect little improvement from further self-calibration –Dynamic range is 14.1/0.047 = 300 Amplitude errors typically come in at dynamic range ~ 1000 Concern: Source “jet” is in direction of sidelobes

30 30 Phase Solutions from 3 rd Self-Cal 11-component model used 10-second solution intervals Corrections look noise-dominated Expect little improvement in resulting image

31 31 Image Comparison 2 nd Self-Calibration3 rd Self-Calibration Peak brightness = 14.6 mJy/beam; lowest contour = 0.20 mJy/bm Peak brightness = 14.1 mJy/beam; lowest contour = 0.20 mJy/bm 2 nd self-cal3 d self-cal

32 32 When Self-Calibration Fails Astrometry (actually it just doesn’t help) Variable sources Incorrect model –barely-resolved sources –self-cal can embed mistakes in the data Bad data Images dominated by deconvolution errors –poor boxing –insufficient uv-coverage Not enough flux density –fast-changing atmosphere Errors which are not antenna-based & uniform across the image –baseline-based (closure) errors (e.g., bandpass mismatches) –imaging over areas larger than the isoplanatic patch –antenna pointing and primary beam errors

33 33 How Well it Works Can be unstable for complex sources and poor Fourier plane coverage –VLA snapshots, sparse arrays (VLBA, MERLIN) –Basic requirement is that the total number of degrees of freedom (number of gains plus the number of free parameters in the model) should not be greater than the number of independent vis. measurements. Quite stable for well sampled VLA observations and appropriately complex sources Should be even better for MeerKAT because of larger number of antennae Standard step in most non-detection experiments Bad idea for detection experiments –Will manufacture source from noise –Use in-beam calibration for detection experiments

34 34 Recommendations Edit (flag) your data carefully before self-cal Expect to self-calibrate most experiments (other than detection checks) For VLA observations, expect convergence in 3 - 5 iterations. Full MeerKAT should also converge quickly. Monitor off-source noise, peak brightness, “unbelievable” features to determine convergence Few antennas (VLBI) or poor (u,v) coverage can require many more iterations of self-cal

35 35 Recommendations Be careful with the initial model –Don’t go too deep into your clean components! don’t embed junk in your calibration –False symmetrization in phase self-cal (using, e.g., a point source model) –If it’s important, leave it out: is this feature required by the data? –If desperate, try a model from a different configuration or a different band Experiment with tradeoffs on solution interval –Average IFs –Shorter intervals follow the atmosphere better

36 36 More Calibration Techniques Water vapor radiometers 22 GHz (EVLA) and 180 GHz (ALMA) Ionospheric measurements (TEC) Dual-frequency observations – calibration transfer Use self-cal to transfer phase solutions from narrow-band to broad-band (strong-line, weak continuum) Baseline-based calibration (removal of closure errors) antenna delay errors, antenna IF bandpasses

37 37 Easy example 8.4GHz observations of Cygnus A VLA C configuration Deconvolved using multi-scale CLEAN Calibration using AIPS++ calibrater tool

38 38 Image Without Self-Calibration Phase calibration using nearby source observed every 20 minutes Peak ~ 22Jy/beam Display shows - 0.05Jy to 0.5Jy

39 39 After 1 Phase-Only Self- Calibration Phase solution every 10s

40 40 After 1 Amplitude and Phase Self- Calibration

41 41 After 2 Amplitude and Phase Self- Calibrations

42 42 After 3 Amplitude and Phase Self- Calibrations

43 43 After 4 Amplitude and Phase Self- Calibrations

44 44 Summary of Cygnus A Example Factor of ~three reduction in off source error levels Peak increases slightly as array phases up Off source noise is less structured Still not noise limited - we don’t know why

45 45 Final Image Showing All Emission > 3σ

46 ‘Isoplanatic patch’ = few deg. = few km Phase variation proportional to λ 2 74MHz Ionosphere – Position Dependent Effects Travelling Ionospheric disturbances (TID) Carilli 2007

47 Calibration Regimes Lonsdale 2005

48 Peeling: Subtract Sources and Calibrate What is Left 3C343 & 3C343.1 WSRT L band selfcal on entire field 1 degree subtract “central” sources  only off-axis source left Define central field; strong source outside central field. Peeling slides: Tom Oosterloo

49 Subtract “central” sources  only off-axis source left Selfcal on off-axis source gives extra gains for off-axis patch so off-axis errors disappear Errors due to central sources unchanged ! Peeling slides: Tom Oosterloo

50 Peeling: 1.apply extra gains to data 2.subtract off-axis source 3.undo extra gains  Off-axis source (+ its errors!!!) gone Peeling slides: Tom Oosterloo

51 Off-axis source (+ errors!!!) goneSelfcal centre again  good calibration for central field Peeling slides: Tom Oosterloo

52 By solving for extra gains for off-axis source  off-axis errors gone; dynamic range > 10,000 Peeling slides: Tom Oosterloo Standard self-calAfter Peeling

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