SU1670662A1 - Photographic lens - Google Patents

Abstract

This invention relates to an optical instrument, namely, photographic optics. The purpose of the invention is to improve the image quality while simultaneously increasing the relative aperture. A photographic lens contains a positive meniscus 1 convex to an image, a negative meniscus 2 convex to an image and glued from a positive 3 and negative 4 meniscuses facing a concavity to an image, aperture diaphragm 5, a positive meniscus 6, convex to an image and glued from positive 7 and negative 8 meniscus convex to the image, the first 9, the second 14 and the third 10 two convex lenses, positive meniscus 11, convex to the iso expressions and fused from 12 biconvex and biconcave lenses 13. The focal length of the lens is F = 10 mm, the angular field is 2 ω = 60 °, the chromatic position is ≤ 0.016 mm, the magnification chromatic is ≤ 0.012 mm.

Description

The invention relates to optical instrumentation, namely to photographic optics.

The aim of the invention is to improve image quality while increasing the relative aperture.

The drawing shows an optical diagram of a photographic lens.

The photographic lens contains a positive meniscus 1 facing concavity to the invention, a negative meniscus 2 facing concavity to the image and glued from a positive 3 and negative 4 meniscus facing concavity to the image, an aperture diaphragm 5, a positive meniscus 6 convex to the image and glued from positive 7 and negative 8 menisci convex to the image, the first and third 9, 10 biconvex lenses, respectively, positive meniscus 11, facing concavity and glued to the image 12 of a biconvex lens and a biconcave 13, and a second biconvex lens 14.

The rays pass through the first three lenses 4,1,2, completely fill the aperture diaphragm 5, which determines the aperture ratio of the system. Then the rays pass successively four subsequent lenses 6, 9. 10, 11 (figure 1) and in the focal plane of the lens, located at a distance Sf ¹ = 3 mm from the last surface of the lens, form an image of the lens.

As a specific implementation example, a photographic lens with the following characteristics is calculated: focal length f ¹ = 10 mm: angular field 2 ω = = 60 °; back focal length Sf ¹ = = 3.0 mm: resolution 100 lp / mm with a contrast of 0.2.

In front of the positive meniscus 1, a second biconvex lens 14 is mounted to increase the angular field of the lens. The introduction of this lens facilitates the work of the positive meniscus 1, since the relative aperture of each surface decreases, while the radii of these components get more gentle. In addition, the introduction of the second biconvex lens 1 serves to correct the spherical aberration of wide inclined beams.

To correct astigmatism and chromatic aberrations, especially chromatic aberration, the negative meniscus 2 located in front of the aperture diaphragm is glued from the positive 3 and negative 4 meniscus facing the concavity to the image, the difference in refractive indices of which is not less than 0.2, and the difference in the coefficients of the average dispersions is not less than 30. The choice of optical material is due to the presence of glasses and is done experimentally.

Examining the presence of glasses to correct chromatism, we conclude that in the positive meniscus 6. located behind the aperture diaphragm 5, it is necessary to select glasses with refractive indices of at least 1.45 and 1.75 and average dispersion coefficients of 70 and 27.

In the above calculation, the chromaticity of the position does not exceed 0.01 mm, and the chromaticity of the increase is 0.012 mm.

To increase the relative aperture of the lens, a third biconvex lens 10 and a positive meniscus 11 are placed behind the first biconvex lens 9.

The positive meniscus 11 faces the concavity of the image space, which provides a posterior segment. The back focal length in the proposed photographic lens is 3 mm.

The positive meniscus 11 is glued from biconvex 12 and biconcave 13 lenses made of glass, the same as in the positive meniscus 6, located immediately behind the aperture diaphragm 5, which ensures the manufacturability of the lens. In addition, this provides the correction of aberrations such as image curvature and astigmatism.

The design of the entire lens provides a small amount of dispersion in the lens.

The lens has a high resolution. With a contrast of 0.2, it permits 100 lines / mm across the entire field.

In the above calculation, spherical aberration in the entire spectral range does not exceed 0.057 mm. For the main wavelength, the longitudinal spherical aberration does not exceed 0.046 mm, and the transverse one is 0.017 mm (at the extreme point).

The chromaticity of the position does not exceed 0.016 mm, the chromaticity of the increase is 0.012 mm. The curvature of the image is equal to: ω = 30 °; Zt ¹ = = 0.059 mm; Zs ¹ = - 0.026 mm; ω = 22 ° 12; Zt ¹ = = 0.040 mm; Zs ¹ = - 0.022 mm.

The resolution of the lens: in the center of 100 lines / mm with a contrast of 0.53; in the zone of 100 lines / mm with a contrast of 0.27; at the edge of 100 lines / mm with a contrast of 0.2.

Claims (1)

SUMMARY OF THE INVENTION A photographic lens comprising positive and negative menisci facing concavity to the image space, an aperture diaphragm, a positive two-glued meniscus convex to the image space, and the first biconvex 5 lens, characterized in that. that, in order to improve image quality with a simultaneous increase in the relative aperture, a biconvex lens is introduced in front of the positive meniscus facing the concavity of the image space, a second biconvex lens and a positive meniscus facing the space of 15 images sequentially glued from the biconvex are sequentially mounted behind the first biconvex lens and biconcave lenses, the negative meniscus is made of double-glued from the positive and negative menisci, the positive of two jointing meniscus formed of positive and negative menisci, wherein the aperture diaphragm is set between the negative and positive meniscus dvuskleennymi 10 refractive index difference of the coefficients of materials and secondary dispersions of the positive and negative meniscus negative meniscus dvuskleennogo chosen equal to not less than 0.2 and not less than 30, respectively.