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Target acquisition

Target acquisition is one of the most tricky aspects of multi-fibre spectroscopy. In AF2, fibre diameters project to 1.6 arcsec on the sky, which is just below twice the median seeing at ORM. Such small fibres provide a S/N advantage at source flux levels fainter than the sky, as they minimise the amount of sky light that makes it into the fibre. However, whenever seeing is worse than median, aperture losses start to be significant. Additionally, aperture losses are easily aggravated by positional errors: the requirements on positional accuracy are more stringent with smaller fibres.

These effects are quantified for point sources in Figure 1, which shows the flux fraction inside the fibre for different seeing values and, for each seeing, the flux drop when increasing the fibre offset from the target position. The plots assume a point source with PSF following a Moffat profile with β = 3.0, which is appropriate to the ORM sky. Figure 1 shows that, for a seeing of 0.9 arcsec FWHM, a perfectly centered fibre captures only 69% of the stellar flux, while, with an off-centering of 0.5 arcsec, the in-fibre flux fraction drops to 54%, ~20% below that of the centered fibre.

Sketch of fibres and CCD layout
Figure 1. The fractional flux from a point source that makes it into the 1.6-arcsec AF2 fibres decreases with the offset between target and fibre centre. Curves are shown for seeing values ranging from 0.5 to 1.7 arcsec FWHM (labeled on the plot). The PSF is modeled with a Moffat profile with β = 3.0, appropriate to the ORM.

The goodness of the target positioning on the fibres depends on five main sources of errors, which contribute to the final error at different levels:

1. Astrometry errors
2. Differential refraction
3. Acquisition + guiding errors
4. Errors in the field distortion map
5. Mechanical robot precision


We discuss each in turn in the following subsections.

Astrometry errors


AF2 has 1.6-arcsec fibres over a 1-degree field, which makes it imperative that the astrometry is of the highest accuracy to avoid important positioning errors.

Astrometric catalogues such as UCAC3 and SDSS have proved to provide good results. However, when doing spectroscopy of faint targets such as distant galaxies, the coordinate system of the target catalog may present offsets from that of the fiducial stars. It is the observer's responsibility to ensure that the coordinate system of targets and fiducial stars is on the same reference.

Astrometry errors affect field acquisition in often unpredictable ways, and, especially when using few fiducial stars, astrometry errors in the fiducials can entirely bias the acquisition solution. The astrometry should account for proper motions of the fiducial and science target stars. Even those stars with small proper motions, e.g. 20 mas/year, will have coordinate differences of 0.3 arcsec after 13 years. In a 1.6 arcsec diameter fiber, a 0.3 arcsec offset yields a flux drop of ~5% when the seeing is 0.9 arcsec. This drop is small when considered alone, but users should recall that such error adds to other sources of errors listed above.

Differential refraction


Due to atmospheric refraction the positions of objects in the field can slowly shift, as a function of zenith distance, with respect to the field centre. The effect is a differential plate scale stretch in the vertical direction.

This effect can be minimized by reconfiguring the AF2 fibres to new apparent positions, according to the hour angle of the field. Over the 1 degree AF2 field, this is not a serious problem for objects close to the zenith, but it should be considered when observing at elevations below 50 degrees. A field at an elevation above 60 degrees can be tracked for 3-4 hours without needing reconfiguration, if the fibres have been configured for the hour angle in the middle point of the range (e.g. if the field HA = -1h at the start and HA = 3h at the end, we should configure the fibres for HA = 1h; in the case of AF2 we provide the sidereal time instead of the hour angle).

For lower elevations, the reconfigurations should be more frequent depending on the zenithal distance.

Acquisition + guiding errors


The process of field acquisition is another important source of error. Traditionally the acquisition was carried out by the telescope operator, who estimated visually the best offsets to apply to the telescope, by checking the fiducial stars. This is a very subjective, non-repetitive and time-consuming task that can contribute significantly to the acquisition error.

From semester 2013B on, an Acquisition Tool is available, which automates the acquisition process by finding, and applying to the telescope control system (TCS), the optimum translation and rotation offsets to centre the guide stars on the fiducial fibres. It also provides the possibility of guiding with all the fiducial stars, or with the selected ones, which reduces the guiding errors throughout the AF2 field of view.

With the new procedure, the acquisition errors can be reduced to ~0.15 arcsec in translation, and are negligible in rotation, as measured on the fiducial stars.
As well as optimising the acquisition, the tool greatly reduces the acquisition overheads, from typically ~15 min when doing it manually to ~5 min with the tool.

As well as the field-acquisition process, which has been improved, the accuracy of the target-acquisition strongly depends on other considerations that should be taken into account by the observers when preparing the configuration files, namely:

  1. The astrometry of the fiducial stars and the science targets used in the configuration files should be from the same astrometric source. If they are from different catalogues, there is a risk that although the acquisition is very good and fiducial stars are well centred in the fiducial fibres, the relative offset in the astrometry of the science target can make that these are not well centred in the science fibres.
  2. At least 3 acquisition (fiducial) stars are required for an acceptable acquisition, the more the better, but to be safe we suggest more than 4. They should be well distributed over the AF2 field of view, e.g. some fiducial stars in the centre of the field, and some in the outer areas around 20 arcminutes from the centre.
    E.g. fiducial star distributions in which all the stars are in only one half of the field of view can bias the field acquisition to be good only in the half part of the field of view where the fiducial stars are placed.
  3. The fiducial stars should all be bright enough (V < 15), if possible, they should be of similar brightness and in the range 13 < V < 14.

Field distortion errors


The current AF2 focal-plane distortion map is described by the equation:

rtrue = k1 rfp (1 + q rfpr2)

k1 = 17.643 arcsec/mm
q = 320 arcsec2/rad2

where rtrue is the distance of an object from the optical axis, as measured on the sky (in arcsec), and rfp and rfpr are its distance from the optical axis in millimetres, and radians, respectively.
k1 is the linear scale (in arcsec/mm) and q corresponds to the pincushion coefficient, which accounts for the radial distortions.

Errors in fibre positioning due to uncertainties in the distortion map can be up to 0.4 arcsec at a 20 arcmin radius field-of-view. In the central 10 arcmin the errors are small, less than 0.1 arcsec. These error estimations were measured on sky using rastered observations over different configuration fields.

Mechanical robot precision


The errors in the fibre positioning by the AF2 robot is better than 20 micron (~0.35 arcsec on the sky), with a typical rms of 6-8 micron (0.1-0.15 arcsec).

Putting it all together


Acquisition accuracy tests were carried out in commissioning nights during 2013A. We selected targets from different stellar astrometric fields, using configuration with 7-10 stars as fiducials and 70-90 as targets. Focal plane geometry was assumed as described above, with a pincushion coefficient q=320. The automatic acquisition tool was used for acquisition and guiding. To characterise the acquisition accuracy, a spiral raster was performed around the initial acquisition, with steps of 0.4 arcsec. Atmospheric seeing and transmission was controlled and deemed to be stable. The acquisition error for each fibre were derived from measurements of the raw flux at each raster position.

Figure 2 shows the fibre offset distribution over the central 20 arcmin radius field of view for the above experiment. The rms of the error distribution is 0.25 arcsec, and the 90 percentile is 0.4 arcsec.

This result indicates that AF2 is capable of acquiring fields to a high degree of accuracy. Users should note that the conditions for acquisition were close to ideal in this experiment. Acquisition errors increase when decreasing the number of fiducial stars, when the distribution of fiducials does not uniformly cover the field of view, or due to astrometric errors.

Histogram of fibre offset errors
Figure 2. Fibre offset distribution over the central 20 arcmin radius field of view, in an acquisition test with near-ideal astrometry, differential refraction and acquisition+guiding conditions.



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Contact:  (AF2 Instrument Specialist)
Last modified: 16 August 2013