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Figure 1: Two views of the SOI mounted at one of the bent Cassegrain foci of the SOAR telescope. The smaller blue cylinder is the CCD mosaic dewar and is flanked by the two rectangular Leach controllers, the round black part is the cable wrap, and the large blue tube bolted onto the telescope is the main body of the instrument holding the linear ADC prisms, one of which can move over a distance of nearly one meter. The drawing shows the basic lay-out of the instrument in a cut-out view. From left to right the light encounters: ADC prisms, optics module, two filter slides, the shutter, and finally the CCD mosaic.
Optics: The SOI optics consist of a 6 element focal reducer and field corrector, that converts the f/16.63 beam of the SOAR Telescope to f/9.82, preceeded by a linear, "trombone style", Atmospheric Dispersion Corrector (ADC). These optics were designed to deliver images of < 0.18 arcsec FWHM (equivalent to 80% encircled energy within D80 < 0.27 arcsec) at the zenith and <0.34 arcsec FWHM (D80 < 0.51 arcsec) at 70deg. zenith distance, in each of the U, B, V, R, I broad band filters, and over the entire field. The glasses selected, and the use of SOLGEL over MgF2 coatings on all external surfaces ensure high transmission over the entire 310nm-1050nm passband. The measured transmission curve is shown below in Figure 2. Note that the transmission below 400nm is an underestimate of the true transmission due to limitations of the measuring device, and should be considered a lower limit.
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Figure 2: SOI measured optical transmission. See note in text.
Filters: Filters are mounted in two filter cartrides each with space for 4 filters, plus one blank position, so that up to 8 filters can be installed in the instrument at any time. Although the cartridges were designed to be easily removeable, the process of changing them out still requires at least 30 minutes, and we currently have no spare cartridges. Thus it is strongly recommened that users design their programs to avoid filter changes during the night. Filters may be up to100mm square and up to 10mm thick. Smaller filters may be accommodated with special adapters but must be at least 64mm square to avoid vignetting. A list of the currently available filters, together with transmission curves when available, will be found here. The available filters are: UBVRI, Sloan, Wing set, any CTIO 4"filter from the list at http://www.ctio.noao.edu/instruments/optical_instruments.html.
CCDs: The SOI focal plane is imaged ontoa mini-mosaic of two CCD's with the following properties.
| Detector Type | E2V technologies CCD-44-82 thinned, back Illuminated | |||||||||||||||||||||||
| Image Size | 4096 x 4096 @ 16bits/pixel plus overscan and header 32 Mb per image | |||||||||||||||||||||||
| Pixel Size | 15 microns/pixel = 0.077 arcsec/pixel | |||||||||||||||||||||||
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| Read Out Noise | 2.5e in normal readout mode (100s), 4.5e in fast readout mode (20s) | |||||||||||||||||||||||
| Dark Current | 2e/hr | |||||||||||||||||||||||
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| Read Out Times | slow 100s, fast 20s. | |||||||||||||||||||||||
| Gain | Settable at 0.4e/ADU or 2e/ADU | |||||||||||||||||||||||
| Charge transfer efficiency | 99.9995 |
Read-out: The chips are read out by two amplifiers each giving a read-out time for an unbinned frame of about 18s with a RON of 2.5e. Various read-out and binning modes will be available. Note that a seeing disk of 0.45" is still well-sampled by 2x2 binned pixels, so that only for the very best seeing and using the tip-tilt mode should the CCDs be used in unbinned mode. At present, the tip-tilt mode is not yet offered.
Focusing: of the SOI is done by charge shifting on the CCD, and moving the telescope focus between steps by automatic software. The number of steps, step size, and exposure time per subexposure can be chosen by the observer.
Guider: The instrument incorporates a fast readout CCD guide camera which can be used to drive the telescope's tertiary mirror in order to partially compensate atmospheric Tip and Tilt, and correct telescope tracking jitter. The actual performance of this system has yet to be determined, but it is expected that Tip-Tilt correction will be possible with guide stars as faint as R=14, with useful guiding performance down to R=19. The field of view of the guide camera is only 7" square, however, the probe can be placed anywhere within a 12 arcmin diameter patrol field. Normally the probe should be kept outside the central 6x6 arcmin to avoid blocking part of the science field. However, when the best possible Tip-Tilt correction is required it may be desireable to select a guide star close to the science target accepting the obstruction of parts of the field.