SU679910A1 - Wide-angle high-power lens - Google Patents

Description

The invention relates to otping systems and can be used for aerial photography, as well as in projection systems for the playback of transparencies on a screen with high magnification.

Wide-angle aperture lenses of the asymmetrical type are known, containing the front component, which is realized from a negative meniscus, convex to the plane of the lens, and a positive single or glued lens, as well as the objective 1 located behind this component.

Also known is a lens containing an anterior component, made of a negative meniscus convex to the plane of the object, and a single positive lens that is close in shape to a plane-convex, as well as the lens itself closely adjacent to this component. At the same time, the latter is a known Tessar lens with an additional positive meniscus in front of it, facing its concavity towards the diaphragm 2.

The closest to the invention to the technical essence is a lens containing a single head negative meniscus, a single lens, a first doublet and second and third doublets located behind the diaphragm, glued together from positive and negative lenses, and two single negative meniscus with the aperture facing the diaphragm { 3

The specified lens has insufficient correction of aberrations, as well as insufficient luminosity.

The aim of the invention is to increase the relative aperture while improving image quality.

Claims (3)

This is achieved by the fact that in a wide-aperture objective lens a single lens has a positive optical power, and the first doublet is made of single negative and positive menisci facing concavity to the diaphragm, while the second and third doublets face the drute by negative lenses, and the difference of the dispersion coefficients is negative lenses of the second and third doublets are not less than 20, and the difference in dispersion coefficients in the lenses of the third doublet is not more than 10, and in a negative lens the dispersion coefficient is b Longer than the positive, and the magnitude less than 50. The optical scheme of the proposed lens is shown in the drawing. The lens consists of an anterior component I, made of a head negative meniscus 2, convex toward the flat surface of the object, and a positive lens 3, and the lens 4 itself, located on the basis of a concentric system, located behind this component. At the same time, objective 4 itself consists of three doublets 5–7, of which the first 5 is made of a negative 8 and a positive 9 single menisci facing with a concavity to the diaphragm 10 located between the first 5 and second 6 doublets. The second 6 to third 7 doublets are glued together from positive II and negative 12 lenses and facing each other with negative lenses 12. The distances between the lenses of the first doublet 5 and between BTOphSM 6 and the third 7 doublets do not exceed 0.5% of the focal length of the entire lens . The outer surface 13 and the glued surfaces 14 of the first doublet-5, as well as the glueing surface 15 of the second doublet 6 are concentric to the diaphragm 10. Behind the actual lens there are two negative menons 16 and 17, which are convex to the image, and plane-parallel glass 18 in the focal plane . This lens design makes it much better to correct all monochromatic aberrations and increase the field of view while maintaining a large relative aperture. To correct chromatic aberrations, in particular, to reduce chromatism zones of magnification, a special selection of the dispersion coefficients in the second 6 and third 7 doublets of objective 4 itself was required. Thus, the difference in the coefficients of dispersions in negative lenses 12 of the second and third doublets should be no less than 20, and the difference between the coefficients of dispersion in the lenses of the third doublet 7 is not more than 10, and the coefficient of dispersion in the negative lens 12 is greater than in the positive; 11, and not less than 50. Below are the design data of one of the variants of a projection high-aperture wide-angle lens designed to project transparencies onto a screen with high magnification V, namely:. At the same time, if the focal length of the lens fQrlOOMM is about four megapses from the lens to the screen, i.e. almost equally infinite. Therefore, for convenience of comparison, other wide-aperture lenses, in particular, with aerial surveys that work with a backward-long distance, the lens is shown in the reverse direction. Lens aberration taksmé tribute; in the reverse direction from the screen to the slide, which during pro- cess: work is pressed against the outer skin; “With / Hscoscope parallel stekgga 13. Thus, the lens“ MCST follows the main characteristics: focal paccTOHHJie fo 100 mm; field of view angle 2/80 °; Relative hole D S-f J: 3; F (), the light distribution of the light at the edge of the field of view is 7% of the light at the center; average inter-lens gap d8 8.3 mm; paccTOHtffle from the first surface of the lens on the screen S -4020 mm; image distance from the last surface of pressure glass S 0.0 mm. The spherical aberra: the qi dp point of the axis is within ± 0.07 mm, the astigmatism and the curvature of the field are no more than 0.1 mm, the geometric circles of the assortment of inclined beams within the effective part of the pupil are 0.03-0.05 mm hro. Mach magnification across the field + 0.03 mm for Lt-Fy C and C, Despite. clearly asymmetrical objective of the lens, the question of correcting diotorsc has been resolved. In some variants of the calculation, it does not exceed ± 0.02 mm. This allows the use of a similar construction for aerial surveying objects, especially since the transition from a finite distance of four meters to an infinite can be made with little or no change in the aberrations. The effectiveness of the proposed technical pemeyflB is determined by a large luminosity, improved image quality and uniform Hbifv light distribution over the field. When implementing the proposed lens in the projection system, it is possible to ensure good quality of the projects: transparencies on the screen of considerable size in fewer darkened rooms. -The creation of the same aperture x. Wide-angle lenses for aerial photography will allow the use of photographic material.: 1s with less light intensity, but with higher resolution, so that the overall resolution of the system volume; -: the seam layer will increase. Claims of Invention A wide-aperture lens containing a single head negative meniscus, a single lens, the first doublet, and second and third doublets located behind the diaphragm, glued together. from positive and negative lenses, and two single negative meniscus, concavity facing the diaphragm, characterized in that, in order to increase the relative aperture with simultaneous image quality improvement, the single lens is positive, and the first doublet is made of single negative and positive meniscus, facing concavity to the diaphragm, while the second and third hypotheses are doublets facing each other with negative lenses. 2. Lens according to claim 1, characterized in that the difference in the dispersion coefficients in the negative lenses of the second and third doublets not less than 20, and the difference in dispersion coefficients in the lenses of the third doublet is not more than 10, and in the negative lens the dispersion coefficient 1 is greater than in the positive one, and not less than 50 in size. Sources of information taken into account in the examination 1. The patent of Germany No. 2157160, cl. 42 h 4/20, 1971. 2. The patent of Germany No. 2102600, cl. 42 h 4/2, 1971. 3. US patent N 3700312, cl. 350-215,1972 (npoTonio).