using the rainbow optics star spectroscope for visual observing
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Using the Rainbow Optics Star Spectroscope for Visual Observing. Paul Bakke. Items to discuss:. How Rainbow Optics Star Spectroscope works for visual observing Optics used Objects observed First attempts using a camera with the Rainbow Optics Star Spectroscope. Standard eyepiece. - PowerPoint PPT PresentationTRANSCRIPT
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Using the Rainbow Optics Star Spectroscope for Visual Observing
Paul Bakke
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Items to discuss:How Rainbow Optics Star Spectroscope works for visual observing Optics used Objects observed First attempts using a camera with the Rainbow Optics Star Spectroscope
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Standard eyepieceDiffraction grating cellCylindrical lensGrating cell mounted to eyepiece
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Optical ConsiderationsSpectrum width proportional to Exit PupilBest: 2 to 3 mm (useful range 1.5 to 4 mm)Spectrum length controlled by:Eyepiece magnificationDistance from grating to eyepiece lensExit Pupil = Eyepiece Focal length Telescope f-ratioLonger eyepiece focal lengthShorter spectrumWider spectrum
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Grating mounted to star diagonalIncreases length or dispersion of spectrum
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My setup:10-inch, f = 10 SCT25 mm eyepiece
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Photo taken with hand-held Canon Power Shot at sec, f3.5, 1600 ISO
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Source: Jack Martin, London, England12-inch Dobsonian with Rainbow Optics Star Spectroscope (2-piece model)Photo adapted from http://www.starspectroscope.com/
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Method:Center spectrum in field of viewTurn off siderial driveTake long exposure photo (< 30 sec.), just enough to smear the imageRotate and crop using software
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Bonus:Use graphics software to make intensity vs. color histogramPaint Shop Pro
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What to observeFirst-magnitude stars (using cylindrical lens)Main-sequence (class V) stars are bestGiants & supergiants have less prominent absorption lines, Cooler spectral types are good even at larger luminosity class Spectacular: Vega (A0 V), Sirius (A1 V), Betelguese (M2 I)
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Absorption linesHot (type A, B) stars: Hydrogen beta, gamma (blue) are easyHydrogen alpha (red), delta (violet) are difficultIn type G & cooler stars: G (blue CH molecule), D (orange Na), b (green- Mg)Molecular bands (TiO) in M stars
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More challengingWolf-Rayet stars (type WN, WC)Emission lines (blue)HD 192163 in Cygnus (illuminates Crescent Nebula, NGC 6888), mag. 7.7, type WN6HD 192641 in Cygnus, mag. 8.2, type WC7Fact: ~ of all Wolf-Rayet stars brighter than magnitude 9 are in Cygnus!
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More challengingCarbon stars: absorption bands in blue & violet due to carbon moleculesY Canum Venaticorum (La Superba)U Hydrae19 Piscium
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Rainbow Optics Star SpectroscopeSpectroscopy at its most inexpensive & low techPleasure of visual astronomySimple photographic possibilitiesActivities in light-polluted or moonlit sky
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HAVEFUN!