JuergensSandbox: Difference between revisions
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<TABLE CELLPADDING=4 BORDER="1"> | <TABLE CELLPADDING=4 BORDER="1"> | ||
<tr><td><b>Rest Frame Name</b></td><td><b>Rest Frame</b></td><td><b>Correct for</b></td><td><b>Max amplitude [km/s]</b | <tr><td><b>Rest Frame Name</b></td><td><b>Rest Frame</b></td><td><b>Correct for</b></td><td><b>Max amplitude [km/s]</b> | ||
<tr><td>Topocentric</td><td>Telescope</td><td>Nothing</td><td>0</td></tr> | <tr><td>Topocentric</td><td>Telescope</td><td>Nothing</td><td>0</td></tr> | ||
<tr><td>Geocentric</td><td>Earth Center</td><td>Earth rotation</td><td>0.5</td></tr> | <tr><td>Geocentric</td><td>Earth Center</td><td>Earth rotation</td><td>0.5</td></tr> |
Revision as of 01:12, 1 March 2012
The new EVLA correlator is extremely powerful in its spectral capabilities. Up to 4 million channels can be observed with a spectral resolution in the Hz regime. Here is a guide to access that spectral line power.
Observation Planning
The wide bands of the EVLA allow users to observe up to 8GHz spectral bandwidth at a time. This will result in extreme continuum sensitivity. In addition, it opens up the possibility to observe one or more spectral lines at a given time. So the first to is to carefully plan the observations.
There are a number of online tools available that help spectral line observers. To start with, the rest frequency of the sopectral line needs to be determined. This can be done with Splatalogue which contains data from the Lovas catalog, the JPL/NASA molecular database], the Cologne Database for Molecular Spectroscopy and others. Note that in addition to molecular line transitions, splatalogue also contains radio recombination lines.
Observing Frequency and Velocity Definitions
The first step is to determine the observing frequency of the spectral line. This is derived from the radial velocity of the source and the rest frequency of the spectral line.
A full relativistic calculation shows that the velocity is determined via . This is called the relativistic velocity. This equation is a bit cumbersome to use and in astronomy to different approximations are typically used instead:
- Optical Velocity ( is the redshift of the source)
- Radio Velocity
The radio and optical velocities are not identical. At low velocities that difference is small but and diverge more and more for large values.
At significant redshifts, it is possible to place the zero point of the velocity frame into the source via
The redshifted can now be used as the input rest frequency for the observations. The velocites that are derived based on such a redshifted rest frequency will then also be correctly scaled for the spread of the velocity scale that is due to the redshift.
Velocity Frames
The earth rotates, revolves around the sun, rotates around the galaxy, moves within the Local Group, and shows motion against the cosmic microwave background. If one measures a veloocity is is therefore necessary to correct for such motions and define the frame to which the velocities are measured to.
There are various rest frames which might be appropriate. The following table lists their name, the motion for which one has to correct in order to reduce an observed velocity to that particular rest frame, and the magnitude of the velocity correction. Each subsequent rest frame is obtained by adding the effects of the preceding ones:
Rest Frame Name | Rest Frame | Correct for | Max amplitude [km/s] |
Topocentric | Telescope | Nothing | 0 |
Geocentric | Earth Center | Earth rotation | 0.5 |
Earth-Moon Barycentric | Earth+Moon center of mass | Motion around Earth+Moon center of mass | 0.013 |
Heliocentric | Center of the Sun | Earth oribtal motion | 30 |
Barycentric | Earth+Sun center of mass | Earth+Sun center of mass | 0.012 |
Local Standard of Rest (LSR) | Center of Mass of local stars | Solar motion relative to nearby stars | 20 |
Galactocentric | Center of Milky Way | Milky Way Rotation | 230 |
Local Group Barycentric | Local Group center of mass | Milky Way Motion | 100 |
Virgocentric | Center of the Local Virgo supercluster | Local Group motion | 300 |
Cosmic Microwave Background | CMB | Local Supercluster Motion | 600 |
The velocity frame should be chosen to what is appropriate for the science. Three frames are commonly used:
- Topocentric this is the frame that the sky (observing frequency) uses. It is also the standard for visibilities in the measurement set
- Local Standard of Rest is the native output of images in CASA. Note that there are two varieties of LSR: the kinematic LSR (LSRK) and the dynamic (LSRD) definitions for the kinematic and dynamic centers, respectively. The standard used in almost all cases is LSRK and most likely the older LSR naming is identical to the mode modern LSRK definition.
- Barycentric is a common frame, too and has virtually replaced the older heliocentric standard. Given the small difference between them, they were frequently used interchangeably.
A full list of reference frames that CASA supports is provided in the CASA reference Manual and Cookbook and also on the casaguides.nrao.edu webpage
The most commonly used rest frames are heliocentric (to be precise, barycentric is used at the VLA) and local standard of rest (LSR). LSR is generally used in Galactic astronomy and heliocentric in extragalactic astronomy, although the latter is often reduced to galactocentric.
Doppler Correction
Gibbs Phenomenon and Hanning smoothing
Setting up Correlator Modes
The OPT
spectral line setup
- planning
- PST
- OPT
- exposure calculator
- OPT preparation and setup
. suckouts . filters . tuneability of subbands . channels full/dual/single pol . baselineboard stacking . recirculation . gapfree setups . data rate considerations . setups with variable bandwidths
- bandpass
- post processing - hanning smoothing - velocity systems - continuum subtraction
Spectral Line Observing
Current->Revised OSS Guidelines
- An Overview of the EVLA
(last paragraph) The EVLA correlator will be extremely powerful and flexible. Details of the correlator configurations being offered for EVLA early science during the period Sep 2011 - Dec 012 (a full D→A configuration cycle) are described in Correlator Configurations. It is important to realise that the EVLA correlator is fundamentally a spectral line correlator. The days of separate “continuum” and “spectral line” modes of the VLA correlator are over, and all observations with the EVLA will be “spectral line.” This has implications for how observations are set up, and users who may be used to continuum observing with the VLA are strongly advised to consult Correlator Configurations.
- Limitations on Imaging Performance
(Sidelobes from Strong Sources) An extension of the previous section is to very strong sources located anywhere in the sky, such as the Sun (especially when a flare is active), or when observing with a few tens of degrees of the very strong sources Cygnus A and Casseopeia A. Image degradation is especially notable at lower frequencies, shorter configurations, and when using narrow-bandwidth observations (especially in spectral line work) where chromatic aberration cannot be utilized to reduce the disturbances. In general, the only relief is to include the disturbing sources in the imaging, or to observe when these objects are not in the viewable hemisphere.
- Correlator Configurations
All observations with the EVLA correlator should be treated as traditional VLA spectral line observations, in that they will require observation of a bandpass calibrator. They may also require observation of a delay calibrator. Users should contact NRAO staff for advice on setting up observations with the EVLA correlator.
Detailed Guidelines
Observing Preparation Recommendations
Scheduling
Calibration Strategy
- Bandpass Setup
All observations with the EVLA---even those with the goal of observing continuum---require bandpass calibration. A bandpass calibrator should be bright enough, or observed long enough, so that the bandpass calibration does not significantly contribute to the noise in the image. This implies that, for a bandpass calibrator with flux density Scal observed for a time tcal and a science target with flux density Sobj observed for a time tobj, should be greater than . How many times greater will be determined by one's science goals and the practicalities of the observations, but should be greater by at least a factor of two.
The bandpass calibrator should also be a point source or have a well-known model. At low frequencies, the absolute flux density calibrators (3C48, 3C147, or 3C286) are quite bright and in many cases can double as the bandpass calibrator. However, at high frequencies, these sources have only moderate flux densities of ~0.5--3 Jy, translating into a potentially noisy bandpass solution.
The stability of bandpasses as a function of time is of concern for high-dynamic-range spectral work. We have found that most antennas show bandpasses that are stable to a few (~2--4) parts in a thousand over a period of several (~4--8) hours [L BAND?].
Dramatic jumps in the bandpass structure (of order a few parts in a hundred) can occur at attenuator changes. The observer can track down such attenuator changes in their data using the switched power information; the On - Off power ('PDIF' in AIPS) wil show a clear discontinuity. For this reason, it behooves the spectral line observer to observe a bandpass calibrator at least twice during their observations. Multiple observations will provide a check that all is well on most antennas and a mechanism for identifying any "problem" antennas. However, we do not expect that interpolating in time between consecutive bandpass solutions will bear much fruit for the observer. The low-level variations observed on some antennas tend to not be smooth functions of time and will likely not be corrected with interpolation.
If there is only one observation of the bandpass calibrator, the observer should be careful to minimize the number of shadowed antennas, as an antenna without a bandpass determined for it will essentially be flagged for the rest of the observation.