SU1262439A1 - Optical anamorphotic system - Google Patents

Description

The invention relates to film optics, in particular to anamorphic whale-shooting blocks, intended for shooting holographic films by direct recording of holograms of a subject, and can be used for film shooting in pavilions with monochromatic lighting.

The purpose of the invention is to increase aperture ratio and image quality.

In FIG. 1 shows an optical diagram in a sagittal section; in FIG. 2 - the same in the meridional section. fifteen

The optical system is designed for shooting holographic films on a 70 mm film and consists of a cylindrical component 1, a spherical six-lens lens ²⁰ and 2, and a cylindrical component 3.

The first cylindrical component 1 contains a cylindrical negative meniscus glued from menisci 4 and 5, a biconcave lens 6 and a positive meniscus 7, convex to the image.

The spherical lens 2 consists of a positive meniscus 8, a negative meniscus glued from lenses 9 and 30 10, a negative meniscus glued from biconcave 11 and biconvex 12 lenses, and a positive lens 13.

The second cylindrical component 35 3 consists of a cylindrical biconcave lens 14, a meniscus 15, convex to the object, a positive meniscus 16, convex towards the spherical 40 of the lens, a positive meniscus 17, convex to the object, a biconcave cylindrical lens 18 and two menisci 19 and 20, convex to the object and glued 45 to the positive meniscus.

The length of the optical system is 487.7 mm.

The maximum light size of the front cylindrical lens is 215 x x 28 mm, and the outer size of the output 50 cylindrical lens is 86 x 20 mm, the length of the back focal length is 13.4 mm.

Thus, the proposed anamorphic system is a complex multi-lens design with 55 focal lengths F = 33 mm and a relative aperture of 1: 2.2 in the meridional section with a focal length of F = 250 mm and a relative aperture of 1: 1.3 in the sagittal section. ''

The angular field of view of the optical unit in the sagittal plane is 15 ° 20 ^/ , in the meridional plane 8 ° 20 ^/ . The linear field in the image space is 48 x 4.75 mm.

The complexity of the optical system of the block allows for a high anamorphic coefficient. The anamorphic coefficient of the proposed optical system is 7.5.

The system is corrected for a wavelength of Ά = 546.4 nm (e), achromatized for 3 = 434.1 nm (G ¹ ) and Ά = 636.3 nm (C).

The proposed optical system is not inferior to the existing ones in the quality of the optical image in the meridional section and has a satisfactory correction of monochromatic aberrations. Spherical aberration does not exceed 0.01 mm, system distortion does not exceed 3%. The largest diameter of the effective scattering circle for the edge of the linear field is 0.07 mm.

A feature of the proposed anamorphic system is that the correction of aberrations in the sagittal section is performed not by the full entrance pupil of the lens, but by small elements of the pupil, somewhat larger than the pupil of the human eye (6 mm). This is a feature of holographic lenses and is explained by the fact that the viewer perceives with the eye due to the mirror properties of the screen a three-dimensional image formed by a narrow

I beam passing through a small element of the entrance pupil of the lens.

Under these conditions, in the proposed anamorphic optical system, the residual spherical aberration does not exceed 2 in angular measure. The aberrations of oblique beams of rays do not exceed 3 for the middle of the field of view, the distortion is 0.1%.

Claims (2)

The invention relates to motion picture production, in particular, anamorphic motion picture recording units intended for shooting holographic films by directly recording the holograms of the subject, and can be used for filming video cameras with monochromatic illumination. The purpose of the invention is to increase the aperture and image quality. FIG. 1 shows an optical scheme in sagittal section; in fig. 2 - the same, in the meridional section, the optical system is intended for shooting holographic films on a 70-mm film and consists of a cylindrical component 1 of a spherical six-lens objective 2 and a cylindrical component 3. The first cylindrical component 1 contains a cylindrical negative ny meniscus glued from meniscus 4 and 5, a double-cocked lens 6 and a positive meniscus 7 facing the image. The spherical lens 2 consists of a positive meniscus 8, a negative meniscus stitched from lenses 9 and 10, a negative meniscus glued together with a bent 11 and a two-convex 12 lenses, and a positive lens 1 3. The second cylindrical component 3 consists of cylindrical two-bent lenses 14, meniscus 15 facing the object, positive meniscus 16 convex towards the spherical lens, positive meniscus 1 convex facing the object, two-concave cylindrical lens 18 and two menus claims 19 and 20, convex convexity to the subject and glued into a positive meniscus. The length of the optical system is 487.7 mm. The maximum light size of the front cylindrical lens is 215 x X 28 mm, and the outer size of the output cylindrical lens is 86 x 20 mm, the rear focal length is 13.4 m. Thus, the proposed anamorphic system is a complex multi-lens. a design with a focal length F 33 mm and a relative aperture of 1: 2.2 in the meridian section with a focal length 950 of F 250 mm and a relative aperture of 1: 1.3 in the sagittal section. . The angular field of view of the optical unit in the sagittal plane is 15 ° 20, in the meridional 8 ° 20. The linear field in the image space is 48 x 4.75 mm. The complexity of the optical system of the unit allows for a high anamorphic ratio. The anamorphization ratio of the proposed optical system is 7.5. The system is corrected for the wavelength L 546.4 them (e), achromatized for - 434.1 nm (G) and i 636.3 nm (C). The proposed optical system is not inferior to the existing optical image quality in the meridional section and has a satisfactory correction of monochromatic aberrations. The spherical aberration does not exceed 0.01 mm, the distosis of the system does not exceed 3%. The largest diameter effective scattering circle for the edge of a linear field is 0.07 mm. The peculiarity of the proposed anamorphic system is that the correction of aberrations in the sagittal section is made not by the full entrance pupil of the lens, but by the small elements of the pupil, somewhat larger pupil of the human eye (6 mm). This is a feature of holographic lenses and is due to the fact that the viewer perceives with the eye, due to the mirror properties of the screen, a three-dimensional image formed by a narrow beam, the passage through the small element of the entrance pupil of the lens. Under these conditions, in the proposed anamorphic optical system, the residual spherical aberration does not exceed in angular measure 2. The aberrations of oblique beams of the rays do not exceed 3 in the middle of the field of vision, the distortion is 0.1%. The invention is an optical anamorphic system comprising a first cylindrical component, a spherical lens and a second cylindrical component, which form parallel cylindrical components parallel to each other, and a spherical lens contains three meniscus, of which the first is positive and the second negative glued convexity to the object, the third negative convexity to the image, and a positive lens, characterized in that, in order to improve luminosity and image quality, the first cylindrical component is made of a negative glued meniscus convex to the image, two . YU the second lens and the positive meniscus convex to the image, the second cylindrical component is made of a double-curved lens, three positive menisci, the first and third of which are convex to the object, the second - the image, a double-bent lens and a positive glued meniscus facing convexity to the object, and in the spherical lens the third meniscus and two convex lenses and a positive lens are double convex. made of glued double bonded 456 FIG. 2 16/7 f8 / 9 th