Charles Gorrie Wynne
Bibliography
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Charles Gorrie Wynne—Bibliography
In addition to more than 40 lens patents Charles Wynne has the following academic publications.
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1981
Proc.Phys.Soc., 56, p366, Vignetting.
Nature,158, p584, An extention of the lens-mirror system of Maksutov.
B.I.O.S. Report 574, Computing and Testing Methods in the German Optical Industry, H.M.S.O.
Mon.Not.R.Ast.Soc.,107, p316, New wide-aperture catadioptric systems.
Nature, 160, p91, Chromatic correction of wide aperture catadioptric system.
Rev. d’Opt, 27, p185, New wide-aperture catadioptric systems.
Proc. Phys. Soc., 52, p772, Field correctors for parabolic mirrors.
Journ.Sci.Instrum., 28, p172, A new form of f/0.71 lens for 35mm cine-radiography.
Proc.Phys.Soc., 55, p429, Primary aberrations and conjugate change.
Proc.Phys.Soc., 57, p529, The primary aberrations of anamorphotic lens systems.
Rep.Prog.In Phys., 19, p298. New lens systems.
Proc.Phys.Soc., 73, p777, Lens designing by electronic digital computer, I.
Proc.Phys.Soc., 74, p316 ( Nunn & Wynne). Lens designing by electronic digital computer II.
Journ.Sci.Instrum., 38, p92, Flat-field microscope objectives.
Opt.Acta., 8, p255,. Thin lens aberration theory.
Proc. Conf. on Optical Inst., 1961, The relevance of aberration theory to computing machine methods.
Chapman & Hall.
App.Opt., 2, p1233, Lens design by computer (C.G.Wynne & P.M.J.H. Wormell).
Marine research,1, p23-24,. (H.M.S.O.) Undersea photography in marine research.
Opt, Acta., 11, p107. Spherical aberrations of monocentric doublet lenses (C.G. Wynne & W.B.
King).
App.Opt., 4, p1185. Field correctors for large telescopes.
Jap.Journ. App.Physics, 4, Suppl. 1., p81 Some examples of lens designing by computer.
Proc. Conf. Lens design with large computers – Univ. of Rochester. Eight years of lens designing
with large computers.
I.A.U. Symposium No. 27, 1965. “The construction of large telescopes”, Academic Press, p.A15-17.
App.Opt., 6, p1227. Afocal correctors for parabolic mirrors.
App.Opt., 6, p553. The design of double Gauss systems using digital computers (with M.J. Kidger).
Opt.Acta.,14, p279, Experiments with lens optimisation procedures (with M.J. Kidger).
Astrophys.J.,152, p675. Ritchey-Chretien telescopes and extended field systems.
J.Opt.Soc.Am., 59, p572. Two-mirror anastigmats.
Optical Instruments and Techniques. 1969 (Oriel Press), p429. A unit-power telescope for projection
copying.
Advances in electronics and electron physics, 28 (Academic Press). Optical systems for use with
image tubes (with M.J. Kidger)
Mon.Not.R.Astr.Soc.,153, p261. Maksutov spectrograph cameras.
Mon.Not.R.Astr.Soc., 157, p403. Five spectrograph camera designs.
Mon.Not.R.Astr.Soc.,160, p13. Improved three-lens field correctors for paraboloids.
Progress in optics Vol. X (North Holland), p139. Field correctors for astronomical telescopes.
Proc. ESO conference on auxiliary instruments for large telescopes (ESO-CERN) Ed. Laustsen and
Reiz, Spectrograph cameras, p141-148.
Mon.Not.R.Astr.Soc.,163,p357. Wide field Cassegrain telescopes.
Mon.Not.R.Astr.Soc., 165, p1. Data for some four-lens paraboloid field correctors.
Mon.Not.R.Astr.Soc.,176,p189. A new wide-field triple lens paraboloid field corrector.
Opt.Commun.,12, p266. Simple Fourier transform lenses – I.
Opt.Commun.,12, p270. Simple Fourier transform lenses – II.
Opt. Acta., 21, p615. Some experiments on precision lens centering and mounting ( 7 authors).
Mon.Not.R.Astr.Soc.,177, p25. A simple wide-field Cassegrain telescope (with C.W.F. Harmer).
The observatory, 96, p239. A single-lens small-field paraboloid field corrector (with D.L. Harmer).
SPIE/USA vol 74 (Image processing) An interactive hybrid processing facility (4 authors)
Opt.Commun.,21, p419. Secondary spectrum correction with normal glasses.
Mon.Not.R.Astr.Soc.,180, p485. Shorter than a Schmidt.
Opt.Acta.,12, p627. A comprehensive first-order theory of chromatic aberration.
Report on a scientific visit to China – The Royal Society (F.G. Smith & C.G. Wynne).
The Observatory,98, p275, Field correctors of very high performance.
Opt.Commun.,28, p21. Extending the bandwidth of speckle interferometry.
Mon.Not.R. Astr.Soc.,189, p279. Field correctors for telescopes at better observing sites.
Mon.Not.R.Astr.Soc.,193, pp7–13. Field correction of a Ritchey-Chretien telescope at several focal
ratios.
Q.J.Astr.Soc., 22, p146, The optics of the achromatised UK Schmidt telescope.
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The Observatory,101, p54, Distortion of field correctors.
Opt.Acta., 29, p137, An efficient faint object spectrograph.
Opt.Acta., 29, p1557, A more efficient faint object spectrograph.
The Observatory,103, p12. Spectrograph efficiency at high dispersions. (C.G. Wynne and S.P.
Worswick).
The Observatory,103, p23, Ghost images on C.C.D’s. (C.G. Wynne, S.P. Worswick, C.M. Lowne &
P.R. Jorden).
The Observatory,104, p140, Correction of atmospheric dispersion in a converging beam.
Mon.Not.R.Astr.Soc.,210, p463, A dedicated Echelle spectrometer for the Anglo-Australian
telescope. (J. Meaburn, B. Blundell, R. Carling, D.F. Gregory & C.G. Wynne)
The Observatory,105, p95, A fast relay lens for the next generation of photon- counting systems. (S.P.
Worswick & C.G. Wynne).
Mon.Not.R.Astr.Soc.,220, p657, Atmospheric dispersion correctors at the Cassegrain focus. (C.G.
Wynne & S.P. Worswick).
The Observatory,106, p163, Atmospheric dispersion correction at prime focus.
The Observatory,107, p31, Field correctors for short telescopes.
Optical Engineering,26, p300, Monocentric telescopes for microlithography,
Mon.Not.R.Astr.Soc.,227, p909, The faint object spectrograph for the 2.5m Isaac Newton telescope.
17 al. & C.G. Wynne.
Mon.Not.R.Astr.Soc.,230, p457, Atmospheric dispersion at prime focus. (C.G. Wynne & S.P.
Worswick).
Q.J.R.Astr.Soc.,29, p39, Some British advances optics for astronomy.
The Observatory,108, p161, A low dispersion survey spectrograph. (C.G. Wynne & S.P. Worswick).
Mon.Not.R.Astr.Soc.,238, p603, A faint object spectrograph for the William Herschel telescope. J.R.
Allington-Smith, 16 al. & C.G. Wynne.
Mon.Not.R.Astr.Soc.,236, pp47–50, Wide-field imaging.
Mon.Not.R.Astr.Soc.,237, p239, Fitting spectrographs to telescopes.
Optics Commun.,73, p419, Immersed gratings and associated phenomena – I
Modern technology and it’s influence on astronomy. Ed. Wall & Boksenberg, C.U.P. pp. 2411-2419
Correction of atmospheric dispersion. C.G. Wynne & S.P. Worswick.
Optics Commun.,75, p1. Immersed gratings of associated phenomena – II.
Optics Commun., 77, p355. Immersed gratings of associated phenomena –III.
Mon.Not.R.Astr.Soc.,247, p173, A new form of spectrograph camera.
Mon.Not.R.Astr.Soc.,248, p328, Wide-field collimators for spectrographs. C.G. Wynne & I.
Escudero-Sanz.
Mon.Not.R.Astr.Soc.,250, p796, Doubling spectral resolution.
Mon.Not.R.Astr.Soc.,252, p171, New fast high-performance single mirror spectrograph camera.
Mon.Not.R.Astr.Soc.,253, p160, Achromatised Bowen-Vaughan Telescope.
Mon.Not.R.Astr.Soc.,254, p7, Redoubling spectral resolution.
Journal of the European Optical Society, Part A. Pure Appl.Opt.,1, p185, Systematic losses in fibrefed spectrographs.
Mon.Not.R.Astr.Soc.,260, p307, Telecentricity in fibre-fed spectrographs.
Mon.Not.R.Astr.Soc.,264, p741, A new form of atmospheric dispersion corrector.
Herstmonceux conference, R.G.O. 1990 , Invited paper “Increasing the efficiency and range of
spectrographs”, (C.U.P.), p103 – 113.
Mon.Not.R.Astr.Soc.,263, p641, The three-lens combined field and dispersion corrector giving
telecentric imagery on optical fibres.
Mon.Not.R.Astr.Soc.,265, p747, A four-lens combined field and dispersion corrector giving
telecentric imagery over a field diameter of 1.5
Mon.Not.R.Astr.Soc.,269, p L37 – L40, Field imaging in very large telescopes.
Mon.Not.R.Astr.Soc.,273, p L45 – L46, Field correction in very large telescopes.
The Observatory,115, p258-261, A high-resolution spectrograph for Gemini.
Mon.Not.R.Astr.Soc.,280, p555 – 558, Field correctors for very large telescopes.
Mon.Not.R.Astr.Soc.,282, p863 – 867, Correction for atmospheric dispersion in the infrared.
Mon.Not.R.Astr.Soc.,285, p130 – 134, Atmospheric dispersion in very large telescopes with adaptive
optics.
Mon.Not.R. Astr.Soc., in press about Gemini.
Mon.Not.R.Astr.Soc., Paper on Gemini field curvature.
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