RU2127892C1 - Television wide-angle lens with remote entrance pupil and extended rear focal length - Google Patents

Abstract

FIELD: television. SUBSTANCE: television wide-angle lens with remote entrance pupil and extended rear focal length is related to field of optical instrumentation and is used in miniature black-and-white and color cameras on CCD matrixes. Lens with remote entrance pupil has three components: first component is fabricated in the form of negative meniscus facing space of objects with concavity which absolute value of second radius amounts to summary thickness of meniscus along axis and distance to entrance pupil as minimum, second component is positive biconvex lens and third component presents cemented meniscus facing space of objects with convexity that can have both positive and negative focal power. Besides that first negative meniscus can be cemented together from two positive and negative meniscuses with radii of same sign or can be cemented together from two lenses, biconcave and biconvex. EFFECT: possibility to increase rear focal length and uniformity of field illumination. 9 cl, 4 dwg, 2 tbl

Description

 The present invention relates to the field of optical instrumentation, and in particular to lenses for miniature television cameras operating on CCDs. The perfection of the manufacturing technology of CCDs made it possible to obtain a whole line of standard sizes for these receivers. For miniature television cameras, the most common are 1/2 ", 1/3", 1/4 "matrices. They have an average pixel size of several microns, which places high demands on resolution lenses. Recently, miniature cameras with color matrices have appeared where color-correcting filters must be installed, so the lenses must be fast, wide-angle and have a back section sufficient to accommodate a color-correcting filter.

 Known fast lens (RU, patent, 2053531, class G 02 B 9/60, 1993) with a remote entrance pupil containing five components. The first is a positive biconvex lens, the second and third are positive and negative menisci, respectively, convex to the space of objects, the fourth is a biconvex lens, and the fifth is a biconcave lens. The lens has a fairly large rear focal segment, in which a 15 mm thick plate is placed, however it is multi-component and in size is not suitable for a miniature television camera.

 The closest in technical essence to the invention is a wide-angle lens with a remote entrance pupil (RU, patent, 2094833, class G 02 B 9/20, 13/02, 1996). The lens contains three lens components, the first of which is a positive meniscus facing concavity to the space of objects, which can be glued. The second component is a positive biconvex lens, the third is glued from a biconvex and biconcave lens.

 The lens has dimensions that are suitable for a miniature television camera, however, the small rear focal length does not allow you to place a color correction filter in it when installed on a color camera. In addition, a large projection of the entrance pupil at such a large angle of field of view will undoubtedly entail a strong vignetting of the extreme field beams of the rays and, as a result, irregular illumination across the field, which is unacceptable for color cameras.

 An object of the invention is to increase the back focal length in a television wide-angle lens with a remote entrance pupil and increase the uniformity of illumination in the field.

 The problem is solved in that in the lens with a remote entrance pupil containing three components, the first of which is the meniscus, facing concavity to the space of objects, which can be glued; the second is a positive biconvex lens, the third component is a glued meniscus convex to the space of objects, the first component is negative, and the second radius of the first component in absolute value is not less than the total meniscus thickness along the axis and the distance to the entrance pupil.

 In the particular case, the first component can be glued from two menisci with radii of the same sign, the first of which is negative and the second is positive, and also glued from two lenses - biconcave - negative and biconvex - positive. Such gluing allows you to fix the chromaticity of the increase in the lens, and increase the rear focal segment.

In special cases, the third component can be performed with both negative and positive optical power. The following condition is fulfilled:
0.01 <F _rev / | F ₃ | <0.25
where F _about - the focal length of the entire lens;
F ₃ is the focal length of the third component.

 In the particular case, the focal lengths of the lenses of the third component are equal in absolute value.

To reduce the vignetting of extreme inclined beams of rays, which allows to increase the uniformity of illumination along the field by permissible reduction of the thickness of the lenses along the axis and along the following relations between the thicknesses of the components along the axis and their focal lengths:
0,1> D ₁ / | F ₁ | > 0.001,
D ₂ <0.3F ₂ ,
D ₃ <0.1 | F ₃ |,
where: D ₁ , D ₂ , D ₃ - the thickness of the components;
F ₁ , F ₂ , F ₃ are the focal lengths of the components.

A small lens can be obtained if the following condition is fulfilled: the lens length should not exceed 2F _rev , where F _rev is the focal length of the lens.

 To maintain a large relative aperture, the first component is made of superheavy optical crown glass.

 As a rule, the difference in the refractive indices of a pair of glasses in the bonded components is at least 0.05 for a wavelength of 546.07 nm.

 In FIG. 1 is a schematic diagram of a lens according to claim 1 of the formula. In FIG. 2 is a schematic diagram of a lens according to claim 2 of the formula. In FIG. 3 is a schematic diagram of a lens according to claim 3 of the formula. In FIG. 4 shows graphs of aberrations.

 A wide-angle lens with a remote entrance pupil and an elongated posterior focal segment in FIG. 1 contains a negative meniscus 1, a positive biconvex lens 2, a glued meniscus 3 or 4, as well as a color correction filter 5 and a CCD matrix 6.

 In FIG. 2 shows a lens in which the first component is a negative meniscus glued from two menisci 1 and 2 with radii of the same sign. The second component is a biconvex lens 3, the third is a glued meniscus 4 and 5, as well as a color correction filter 6 and matrix 7.

 In FIG. 3 shows a lens in which the first component is a negative meniscus glued from a biconcave lens 1 and a biconvex lens 2.

 The second component is a biconvex lens 3, the third is a glued meniscus 4 and 5, as well as a color correction filter 6 and matrix 7.

 Calculation achieves the creation of inclined beams of rays within the third component of the parallel stroke, as a result of which the main rays have small angles of inclination, which reduces higher order aberrations.

 The use of super-heavy crowns in positive lenses and heavy flints in negative lenses is one of the conditions for maintaining a large relative aperture. However, in the first component — the negative, non-glued meniscus — superheavy crowns can also be used. When the first component is made glued for it and for the third glued component, most often identical pairs of glasses are selected. The second component is made of lighter glasses. This is done in order to preserve the structural symmetry of the lens. The difference in refractive indices between the glass of the second component and the glass of positive lenses of the first or third component adjacent to it is desirable to have no more than 0.15. An example of a lens with a remote entrance pupil is shown in table 1.

The design parameters of such a lens have the following characteristics:
focal length, mm - 4.75
relative aperture - 1/2
resolution, lin / mm in the center not less than - 125
at the edge of the field no less than - 60
maximum angular field of view, degrees - 93
minimum back focal segment when focusing on infinity, mm - 6.5
thickness of the correction filter, mm - 4.0
the lens is flavored for the range of dyne waves, microns - 0.434 - 0.800
the maximum extension of the entrance pupil, mm - 1.0
According to this scheme, lenses can be created with field of view angles from 80 degrees to 110 degrees, depending on the need to install a certain size on a camera with a matrix.

 Table 2 presents the results of correction of lens aberrations in the meridional and sagittal sections according to the criterion of the scattering spot.

 The analysis of the structure of the optical image in the geometric approximation showed that the obtained values can be comparable, and at some tilt angles, they are significantly smaller than the pixel sizes of the CCD matrices with which the lens can work. This means that this lens has a high resolution in a wide range of spatial frequencies, which allows it to work with various CCD arrays.

 The rms dimensions of the scattering spot over the image field are given in table 2.

Claims (10)

 1. A wide-angle lens with projection by the entrance pupil, consisting of three components, the first of which is made in the form of a meniscus facing concavity to the space of objects, the second is a biconvex lens, the third is a glued meniscus, convex to the space of objects, characterized in that the first component made by a negative meniscus, while the second radius in absolute value is not less than the sum of the meniscus thickness along the axis and the distance to the entrance pupil.  2. The lens according to claim 1, characterized in that the first component is glued from two menisci with radii of the same sign, the first of the menisci being negative and the second positive.  3. The lens according to claim 1, characterized in that the first component is glued from a negative biconcave lens and a positive biconvex lens. 4. The lens according to claim 1, characterized in that the third component is made with positive optical power, while the following condition is met:

where F _about - the focal length of the entire lens;
P ₃ is the focal length of the third component. 5. The lens according to claim 1, characterized in that the third component — the glued meniscus — is made with negative optical power, and the following condition is fulfilled:

where F _about - the focal length of the lens;
P ₃ is the focal length of the third component.  6. The lens according to claim 4 or 5, characterized in that the focal lengths of the lenses of the third component are equal in absolute value. 7. The lens according to claim 1, characterized in that between the thicknesses of the components along the axis and their focal lengths, the following relationships are observed:

D2 <0.3F2,

where D ₁ , D ₂ , D ₃ - the thickness of the components;
F ₁ , F ₂ , F ₃ are the focal lengths of the components. 8. The lens according to claim 1, characterized in that the length of the entire lens does not exceed 2F _about , where F _about - the focal length of the lens.  9. The lens according to claim 1, characterized in that the first component is made of super heavy optical glass crown.  10. The lens according to claims 1 to 3, characterized in that the difference in the refractive indices of a pair of glasses in the bonded components is at least 0.05 for a wavelength of 546.07 nm.

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