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Published byMarvin Willis Modified over 9 years ago
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August 2 and 3, 2010 KOSMOS Design Considerations Jay Elias
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2 References: –Science Requirements Document –Preliminary Operations Concept Document –SDN 1.01-1.04 on science requirements –SDN 2.02 & 2.03 on SW requirements –Functional Performance Requirements Document
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3 KOSMOS Design Basic principles: –Modify as little as possible consistent with requirements –Above all, avoid “scope creep”
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4 KOSMOS Design Focus on two areas: –Differences between MDM 2.4-m and KPNO 4-m –Differences between science needs of NOAO user base Derive input from ReSTAR, KPNO staff, NOAO Users’ Committee
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5 KOSMOS Design – Facility Issues Larger telescope requires faster camera to preserve pixel scale –0.3 arcsec/pixel (or slightly coarser) is a good match to seeing at both telescopes. –Finer scale plus binning is not a good solution because 4k pixels then provide fewer resolution elements; in this case a larger CCD could be used but require more $$, new dewar, etc.
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6 KOSMOS Design – Facility Issues Larger telescope requires faster camera to preserve pixel scale –Field of view size a related issue, see later
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7 KOSMOS Design – Facility Issues Want to use NOAO standard CCD system (dewar + Torrent controller) –Easier to support –Existing dewars save money –Interchangeable with other instruments/telescopes –Considerations reinforced if we implement 2 CCDs (as we did)
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8 KOSMOS Design – Facility Issues Software interfaces different –Telescope, CCD system, data archive –Only instrument controls common to OSMOS –Choice of adapting existing top-level OSU software or NOAO software Adopt NOAO software (NOCS) after evaluation; see later presentation for more on the NOCS We spent time trying to make this decision rationally
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9 KOSMOS Design – Science Issues User community differences –Not much (not surprising) –Less emphasis on the low-resolution prism mode –More interest in higher spectral resolution –Initial disperser complement 2 moderate resolution grisms; prism remains an option for the future
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10 KOSMOS Design – Science Issues Field of view –Physical field of view of OSMOS only 10 arcmin on 4-m; with faster camera could (probably) provide a larger field on CCD –This requires (at least) a larger collimator and makes the slit wheel, probably the whole instrument much larger A lot of re-design Doesn’t fit in the cass cage any more without fold(s)
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11 KOSMOS Design – Science Issues Field of view (cont’d) –ReSTAR did not identify maximum field as a strong science driver A lot of the science programs involved single objects KOSMOS AΩ already as good as GMOS Science value added not considered enough to offset added cost, delivery delays, and performance risk
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12 KOSMOS Design – Science Issues Higher resolution –Resolution R>2300 (4000 goal) –RC Spec will go higher (about 10,000) but demand is limited –A requirement for higher max resolution requires larger beam size, hence a larger instrument; similar issues as larger FOV –Fixed-angle layout limits coverage at higher resolution
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13 KOSMOS Design – Science Issues Wavelength coverage –OSMOS does well in the UV down to ~365 nm –Desirable to keep this level of performance for KOSMOS Performance likely to be limited not by design (which is good) but by differences between design and actual materials; mitigate by index measurement (see later discussion) but don’t put in the maximum possible effort (blank selection via testing) because of time and cost
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14 KOSMOS Design – Science Issues Wavelength coverage (cont’d) –OSMOS performance in the red limited by CCD –Option to acquire a thick LBNL chip appeared, took advantage of this –LBNL CCD is not the commissioning CCD and probably will not be the most-used CCD on KOSMOS; purchasing e2v CCD for that purpose Need to define scheduling policy for these CCDs
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15 KOSMOS Design – Science Issues Flexure –OSMOS worst-case performance about 1/pixel hour Flexure is along direction of changing gravity so it’s simple to understand Flexure leads to need for more night-time calibration (fringing could be a serious problem but not with CCDs selected) OSMOS performance acceptable but not desirable
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16 KOSMOS Design – Science Issues Flexure (cont’d) –Greater stiffness possible in 2 areas: Higher-grade focus stages – modest cost increase, otherwise no impact Stiffer enclosure – reduce aggressive light-weighting needed for MDM 2.4-m; don’t pursue extensive re- design & analysis effort Requirement is to meet OSMOS performance; goal is factor of 2 improvement
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