ASPHERIC OPTICAL SYSTEMS

roved For Release 2005/.1 /21 : CI P78BO4770A001 Aspheric Optical Systems Nntt-sherhical lent Srirf;ice. are a to4'1 e/ Thaii~ii l;?n0 t,tt for Deer flit cc tviitrirre.~, rliey only l'ecanu? ccnwonrical to tuaniifcnturn .i leu, ynlr~ Notre they are 111'pearint in htt,'ll-,1)(t'd vi,l It is to I )csc.trtcs that hlstorv itti abut ?s the first Suggestion that the use ofnon-tipil- ri(al lens surfaces ma} reduce optical na- tions. In the publication La I )a 1 ii::4 r f 1638 he discloses the geometrical Construc- tion for a single lens free front sphcrical abberation.'Theconstruction described had one surface a portion of an ellipse, whilst the other surface was spherical having its centre of curvature at one of the loci of the ellipse. The ellipse together with the parabola and the hyperbola arc simple examples of what may be described as-aspheric or non- sphcrical surfaces ofrevolution, each having 4 articular properties when used as refract- ng or reflecting surfaces. They constitute, with the circle, a set of curves described as conic-sections, since` all of them may be produced by cutting across a cone or cylinder. More generally, our aspheric surface can be considered to be a deformation of a, spherical surface of equal vertex radius. The Affect of the deformation on a refract- ing Or reflecting surface is to advance or retarl an incident wave front relative to ti action of the ~phcr e.i stir,.e(c h% itcelL t'eneraI Surf.i( e ,+f rev,d iinoI 1. s\ nlmetrI- I about an optical axis (till, axis bate l,,scn as the x: direction) can be re presented I,%- the equation x a\ bs; c\" t~)r the purpose of calculation. Whilst the conic-sections are more easily ueterniined and perhaps easier to manu- facture and test, them represent a limitation iii the design of aberration-free optical `"'stems. For example, whilst the ellipse nay be shown to produce a point on axis free from spherical aberration, either the in- cident o emergent beans must be parallel to the leis axis. Thus no correction is made for the ob- lique ft+dd aberration of,- say coma and astigmatism. It is therefore'often preferable to utilise more cmnplex surfaces other than conic- sections in designing a system utilising aspheric surfaces. This may.aid_ correction of resid4als From elsewhere in the system and thy' off-axial aberrations.' A good examp " f this point is the Schmidt system (page 8 . Whilst it is over three'hundred  Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060087-6 BEST COPY Available Approved For Release 2005/11/21 : CIA-RDP78BO477OA001500060087-6  roved .For elease 20051 1/21 : CI years since Descarte$ described his aplanatic lens using an elliptical surface, and whilst there appear to be obvious advantages in designing certain systems with aspheric surfaces, there are comparatively few lenses available commercially of photographic quality that utilise aspheric components. The reasons behind this involve design, manufacture and economics, to quote but a few. Perhaps however the single major drawback to progress in this aspect of optics has been the difficulty in evolving methods for producing aspherics consist- ently, and to an equivalent quality of tr#erical surfaces, at similar or competitive st. Prior to this century very little was done by way of either design or manufacture of surfaces other than conic-sections. In the mid-17th century there was a period of activity in which the limitations of the refracting telescopes led to the inception of the reflecting telescopes of Gregory, Casse- grain and Newton. In the same period Sir Christopher Wren suggested an engine for the production of hyperbolic surfaces. At this time little was understood as regards beration of optical systems; however, 4,egorpy suggested that conic-sections could improve a system otherwise em- ploying spherical mirrors. Newton had turned to reflecting systems in his belief that refracting systems could not be cor- iect&d for chromatic abberation. The 'simplicity of his system having a parabolic reffec,tor, a plane mirror and ari eyepiece, is sttchthat today, most amateur telescope makers adopt it. (The partfolc mirror has sir,e ptbptrties to the se in that a ellip~ FM O47 0A001 beam parallel to the axis is reflected to a single focus free from spherical aberration) More recently the development of photographic lenses stimulated a greater desire t,, produce aspheric surficcs. Little is discl,~acd as to attcnipts prior to the appear. tee of the (:Doke l'riplet le I )enn>s Tavlot it the turn of this century, but hetwe: i 1908 and I'+'? ('.irl L.eiss rook ottt several patents with respect to both th, design and manti facturc of lease s usiiw, ashhrr,, surfaces. One of these' ulrscnh~s a triplet characterised bN the fr.ttur ? that the lust surface of the objective is clef Ornr ]. Earlier attempts by Zeus to ni.inutActt.rr asph: Tics were concerned with the muntldl- ing of components. Many attempts since this tithe have been concerned with moulding asphcrtc curves. but little success has resulted her surfaces of photographic lens quality. This process however has an important application in the manufacture of, components for con- densing systems, where the quality of imagery is quite crude compared to the photographic image. Nearly ev&Ymodern projector has some form of aspherie cor- recting surface in the condensing system. Many materials other than glass have been moulded successfully, these include benzyl- cellulose, pheno-plastics, polystyrenc, poly- methyl-methacrylate, and epoxy resins.2.3 THE SCHMIDT SYSTEM When Bernhardt Schmidt introduced the system, that now bears his name, in 1930, he sparked off a new line of thinking in photographic optics. It was simple,' com- prising only a thin aspheric corrector plate and a spherical mirror. His diiscoyety lay in the poaiittioning . of the corrector elate  ve to the mirror. He placed that plate aperture stop at the centre of curva- af the. mirror. The corrector plate is parallel in form having one surface rival to correct not only the axial ical aberration but also tl;c oblique defects. Schmidt's first c.imera ed at f 1.75 having an aperture of 14 s with a focal length of 24 inches, ing a 16? field. focal plane of the earlier Schmidt ns is intermediate between the plate he mirror and is necessarily curved x towards the mirror. Subsequent icatio ave led to the focal plane broc exterior to the mirror udt-Cassegrain system) and attempts been made to flatten the focal plane acing a plano-convex lens at this In essence however the Schmidt n has provided a means of achieving relative apertures with reasonable ngles without the large mass of glass ubsequent absorption and flare of ,rig systems. of interest to exanliiic how Schmidt his first correcting plate. In a simple ous manner he cemented his plane- d glass plate to a drum. By evacuating in the drum he caused the plate to ew h edths of an inch, and then d andshed the distorted plate to Iqw spherical curve in the normal T. On readmitting the air and releas- Strain the plate took on the aspheric D4 one side. e these early days, iniany methods peen attempted in figuring Schmidt ;drs, these include, electromagnetic applied in annular rings, and various ;,kchniques.4 . / "IP78BO4770A Apart from their astronomical uses, Schmidt systems have found ni,anv other applications, anion elst them projection systems for tclevisicni purposes, where the problem, of a curved t