Binospec has acquisition and calibration overheads that add up to nominally 30 minutes per spectroscopic target (often a bit less in practice). This makes it less efficient at acquiring spectra of large numbers of single bright objects needing eg 10-15 minute exposures, or at survey tiling fields of a degree scale or more.
Additionally, the catalog software breaks requested observations into observing blocks of at most 2 hours exposure time, for scheduling practicality. This means that for example, if you assign a lot of targets each 2.5 hours of exposure time, your program will look inefficient. You could, for example, give some of them 2 hours and some of them 3 hours, and lose less to overhead. In practice, if we do manage to integrate for over 2 hours consecutively on a target, your program would only be charged for one acquisition.
Exposures shorter than 60 sec or so are inefficient due to readout and only recommended for bright objects like standard stars. If you are doing a long time series like a planetary transit, 120 sec has been used in the past.
Add your standard stars as priority 3 so the queue scheduler doesn't try
to schedule them as normal observations. You must update standard star
coordinates to the current epoch using Gaia. Many standard stars
are white dwarfs with high proper motions, and many popular lists of
standards are horribly out of date. For more information see the MMT
spectro standards page.
The Binospec
pipeline doesn't reduce imaging data, so you should download the
raw *proc.fits data, and reduce those with
IRAF, ccdproc, or any other typical method for reducing
imaging. Note that the imaging internal flatfields will show in your
catalog as type "comp" and sometimes are filed under a different
object in your catalog than the nighttime science data.
Spectrophotometric standards for current or past observations
We frequently take standard stars during a run as general observatory
calibrations. These are most commonly in the G270/6500 setting but
others can be done. These observations are taken in an observatory
(director's time) catalog, not charged to an individual program. So
they don't appear in your catalog, but we can give individual PIs
access to the data. If you need standard star data, contact Ben Weiner
and specify the grating, central wavelength, and date. We don't have
data in all settings from all runs but the throughput is generally
stable.
Pseudo-IFU mode
It's possible to build up an integral-field-like spatially resolved
spectrum by taking a series of exposures stepping the longslit (or
slitmask) in the perpendicular to slit direction. This step is
controlled by the observer in instrument coordinates, so you need to
specify the step size across the slit, not in compass directions.
For example, say "use PA=45 and step by 2 arcsec perpendicular to the
slit, doing 5 positions at -4, -2, 0, +2, +4 arcsec." Don't say
"use PA=45 and do 5 positions stepping by 2.8 arcsec north."
Afternoon "sky" flats for spectroscopy
Sky flats aren't part of the normal Binospec reduction
process. However, some programs that need very good knowledge of the
instrumental profile can benefit from afternoon spectroscopic flats
using the solar spectrum. These are used to measure the instrumental
profile by comparison with model spectra. You probably don't need
these unless you are measuring velocity dispersions or doing precision
radial velocity work. They are time-consuming to take and require
coordination between TO and queue observer, so please contact your MMT
instrument scientist if you think you might need them.
Avoiding rotator limits for slitmasks
The instrument rotator has limits near +180/-180 degrees. These
can prevent observing slitmasks at certain PAs and certain times.
In practice, the limits mean that to avoid hitting the limit at
transit,
for masks that are north of the MMT
(Dec > +33), you should avoid designing masks with position angles near 0, and for masks
south of the MMT (Dec < +33), you should avoid PAs near +180 or
-180.
Imaging
Imaging exposure lengths
Individual direct imaging exposures should be kept pretty short, especially if you are
working in a field with a lot of stars (lower Galactic latitude) or
near the peak of detector sensitivity (r or i band). If so, direct
imaging exposures should be no more than 60 seconds, or you will
saturate a lot of stars. Probably in
all fields and filters, imaging exposures should be less than about
240-300 seconds. Saturated stars cause persistence problems that can
damage data on faint targets taken after your field.
Imaging flatfields
Flatfields for imaging are taken in the afternoon
with an internal lamp, and we have to
use one of the arc comparison lamps because the spectroscopic continuum lamp is
too bright. This means that imaging flatfields will show up in your
raw data package with image type 'comp'. Flatfields can be shared
between targets, so you might get a notification about data being
available for a target, even though only the afternoon flats have been
taken so far.
Imaging dithers
It's not currently possible to make really large dithers while imaging
because the guide stars would go off the subarray (region of interest)
of the guide cameras. The detectors are pretty clean so modest
dithers should take care of most detector artifacts.
Data products
Raw and reduced data
Raw data will typically show up in your catalog the next morning,
copied over around 9 am MST. These include *.fits and *proc.fits files
- the proc files have been overscan and bias subtracted and trimmed.
Spectroscopic data can be reduced by the Binospec IDL pipeline. SAO staff
will reduce the data when time is available. The data package also
includes a file with an auto-generated reduction script, so you can
download the pipeline and try reducing the raw data yourself. Several
of our users have reduced the longslit data with the conventional IRAF
cookbook workflow (Massey et al) that they've used for other longslit
instruments.
How do I look at the data?
The reduced data files include a 2-D FITS image that has 1-d spectra, one per
row; and a FITS file with many extensions, each the 2-d spectrum of one
slit. See a description at the Binospec
pipeline repository wiki. To inspect spectra and fit redshifts, you can try the Specpro
software in the version adapted for Binospec, see the Using Specpro to inspect
Binospec data page.
Taking spectra of a non-sidereal target will be more involved because acquiring it onto the slit will not use the RA/Dec and Gaia stars. If you plan to do such an observation, please get in touch with MMT staff so we can coordinate with the Binospec instrument team.