DE2334056C2 - Wide angle lens - Google Patents

Description

ν - + RY ⁴ * * CY ⁶ 4- oy ^s 4- ev ¹⁰ +

_{Ä / + Ä} , l / ia- ^v ""

where Ri is the paraxial radius of curvature at the apex of the aspherical surface, the Y-axis is assumed in the direction of light and in the direction of the optical axis and the K-axis perpendicular thereto.

B = 0.25436 χ ΙΟ " ⁶ Y «V C = 0.28784 χ ΙΟ " ¹⁰ D = -0.29419 χ ΙΟ " ¹⁴ 0 0 E = 0.52488 χ 10- " 5 0.08747 10 0.34820 15th 0.77727 20th 1.36583 25th 2.10073 30th 2.96355 35 3.93004 40 4,96971 45 6.04567 50 7.Π539 fi <= -199.694 55 8.13220 ßl = 190.669 60 9,04792 /HI = 322.702 65 9.81657 69 10.29951 Back focus 148,980

The invention relates to a wide-angle lens according to it can be seen that the aberration of a lens of

the preamble of the claims. Lens members with aspherical surface, their

Wide-angle lenses are used, among other things, to decrease the curvature from the apex to the edge of the lens

Photographing used indoors Since the corrected is regardless of whether the aspherical

In many cases, the overall lighting there is insufficient. The surface is convex and concave

If you want to use a lens, you also want to use a wide-angle lens

A wide-angle, aspherical surface of a lens element is known to be as large as possible

jective, which in a single-lens reflex camera 6O (Jenaer Rundschau, Volume 12 [19671 issue 1. Pages 9 to

is used, a large back focus must still be 12). their curvature from the vertex to the edge of the lens

to have. Therefore one uses lenses of the type decreases

inverted telephoto lenses. A conventional, such- Finally, a wide-angle lens is also the

term wide-angle lens with an image field of the type mentioned above known (DE-AS

However, 80 ° has a maximum relative opening of 65 14 97 543), which, however, is also insufficient

1: 2.8; this light intensity is often not sufficient. Has luminous intensity

In addition, an objective with a convex asphere is the object on which the invention is based

already known (US-PS 6 97 959). This document therefore consists in a wide-angle lens of the

raced "iyps with a large opening with a field of view of 84 ", a relative aperture of 1: 1.4 or more and a focal length on the image side that 1.4 times the focal length achieved, but the shorter overall length, but sufficient image aberration correction having.

This object is achieved by the characterizing features of one of claims 1 and 4 in each case.

12th

In this case, a lenticular surface of a lens body behind the diaphragm of the objective is designed as an aspherical surface. Let Ri be the radius of the vertex curvature. The X-axis is assumed to be in the direction of light and in the direction of the optical axis, while the V-axis runs in a direction perpendicular thereto. The equation for the aspherical surface .'duvet then:

X =

Ri + Ri

/ KY

~ \ kl)

BY * + CY "

+ EY ¹

The refractive index of the medium in front of and behind the spherical surface is expressed by Ni and Ni ', respectively. The objective according to the invention must then meet the following conditions:

B (Ni'- Ni) <0 C (Ni'- Ni) < 0

a lens element of group I or group II formed as a cemented element. It would also be conceivable; that several such cement members can be provided. Between group II and group (II is an aperture is provided. Finally, the following conditions must be met:

In order to effect the correction of the aberrations satisfactorily, the following conditions must also be met will be sufficient.

The lens consists of three groups. Group I is a lens group with an overall negative refractive power. It consists of a negative meniscus lens, a positive lens and a negative Meniskuslin- L ienglied which are arranged in this order. The 30 / group II is a lens group with an overall positive / ι refractive power. It consists of a lenticular lens and / jt a negative lens, which are in this order fm • ngeordnet. It can also consist of a negative lens and a biconvex lens, which are arranged one behind the other in this order. Group III is a lens group with an overall positive refractive power. It consists of a negative meniscus lens member comprising a minus lens and a plus lens, and two positive lenses arranged in the order named. It is

(1) 2.3 f <L < 3.5 /

(3) \, 2f < / ii <3.0 /
(4) 1.0 / </ in <2.5 /

the length of the lens
the lens focal length
the focal length of group I.
the group II focal length is the group III focal length.

Furthermore, a lens surface of group III is designed as an aspherical surface. If the radius of curvature at the vertex of the aspherical surface is expressed by Ri , the X-axis runs in the direction of light and in the direction of the optical axis and the Y-axis runs perpendicular to this direction, the equation applies to the aspherical surface:

Y ²

Ri + Ri

BY * + CY "+ DY ^% + EY ^W

When the refractive index of the medium in front of and behind the non-spherical surface is expressed by Λ7 and M ', respectively the following conditions must be met:

5 (Λ7'-Λί) <0 (5)

0.001

ψ-, C (, VV -Λ /) <Ο (6)

The inverted telephoto type lens with one negative front lens group and one positive posterior lens group is in terms of Power distribution built up asymmetrically, what the Makes correcting artifacts difficult, especially correcting negative distortion and des negative coma generated by the negative front lens group. When the correction of the If errors are made in such a way that they become small, other image errors, in particular aspherical aberration, greater.

Since it is also necessary, the ratio of the image-side focal length to the focal length is large make to ensure the required focal length, and since the field of view is large and the focal length of the If the objective is small, the objective must have a strongly asymmetrical structure. Since the If there is a need to make the refractive power of the lens members large, that of the lens members decreases generated artifacts, so that it is difficult to obtain a lens with a large aperture. While it the refractive power of the lens members is necessary

IB

reduce, necessary to comply with the preceding conveying ung in a lens which consists of only spherical surfaces, the overall length of the lens becomes large, resulting in that the diameter of the front lens becomes very large by ¹ it is thus difficult to obtain a lens with in to create usable size in practice.

The above condition (1), ie the condition 2.3 f <L < 3.5 / for the overall length of the objective according to the invention, was established in order to keep the diameter of the front lens in the range of a practically feasible size and to make the entire objective space-saving . The aspherical surface serves to solve the correction problems that arise for the reasons mentioned above. If the upper limit of this condition is exceeded, the diameter of the front nose is too large. If a value below the lower limit is reached, good image aberration correction cannot be carried out even if an aspherical surface is used as described below.

According to the invention, it is also required that conditions (2), (3), (4) are satisfied ^; rd and a surface is designed as an aspherical surface. The refractive power of each lens group must be determined. If the upper limit of condition (2), namely \ 2f <\ f \ < 33 f, is exceeded, it becomes difficult to keep the overall length of the lens within reasonable limits. while the value is lower than the lower limit, the aberrations produced by the group 1 increase, so that the possibility of obtaining a lens having a large aperture is lost. When the refractive power of the group II exceeds the upper limit of the condition (3) , namely 1.2 f <f \\ < 3.0 f. , the group III refractive power must become extremely large, and aberration correction becomes difficult. When the value is lower than the lower limit, the negative spherical aberration generated in the group II decreases. to. so that it is difficult. Obtain a lens with a large relative aperture. Condition (4), namely 1.0 f < / in <2.5 f, means that group III, based on group I and group II, has a comparatively strong refractive power so that a large focal length on the image side is achieved. When the upper limit of this condition is exceeded. a sufficient focal length on the image side cannot be obtained. If the lower limit is exceeded, the negative spherical aberration generated in the group UI increases, so that it is difficult to create a lens with a large relative aperture.

According to the invention, the required image defect correction should for a lens with a large relative aperture can be caused by the fact that a surface is called aspherical Surface is formed. Although a bigger one

ι »Effect can be achieved if many outer surfaces are designed as aspherical surfaces, since the The number of degrees of freedom for image aberration correction increases, in the present case only one is aspherical Area used as the manufacture of

ii aspherical surfaces are difficult and costly. According to the invention, taking the above statements into account, a sufficient we kung can be guaranteed, although the use of aspherical surfaces only on one such surface Area is limited.

When using an aspherical surface you must the negative spherical aberration and the off-axis circle of confusion, especially the negative asymmetry errors that remain as a result are effectively corrected at the same time. But when The aspherical surface used in Group I or Group II performs the correction of the distortion and the Asymrm 'error to an enlargement of the Circle of confusion outside the axis, so that this Arrangement for a lens with a large relative aperture is not suitable. On the other hand, if you use the aspherical surface in group III behind the diaphragm, so it is possible to rest the aforementioned Correcting aberrations sufficiently. This is especially possible when the aspherical Area for an image-side convex surface of a cemented link is provided. The correction compensation the longitudinal color defect and the color magnification defect becomes satisfactory. If the shape of the aspheric

AO see area is such that it satisfies the following conditions in connection with the fourth and sixth coefficients of the aspherical area equations according to the conditions (5), (6), so e. in this case one considers the best results:

0. (101

I '

\ (ΊΜ ·

-ί-f. sow - / ν / χη

~, C (Ni ¹ - NiXO

The fourth and sixth coefficients influence the image error and are dependent on one another. If the fourth coefficient is lower than the lower limit of the Condition (">). Can correct the negative spherical aberration in the center of the image, the negative The asymmetry error at medium image angles and the negative distortion are not satisfactory be guided. If the upper limit is exceeded, the asymmetry errors are at average image wm none and the astigmatism overcorrects what is undesirable. When the sixth coefficient is lower is considered the lower limit of condition (6), can correct the negative spherical aberration for the Edge rays, the negative asymmetry error for the outer areas of the image field and the circle of confusion can not be carried out satisfactorily off-axis. If the upper limit is over- (5)

is stepped, the spherical aberration at the edge of the image field is overcorrected, which is not desirable. If the above conditions are satisfied, it is possible to obtain a wide-angle lens of the type mentioned which has a field of view of 84 °. has a luminous intensity of I: 1.4 or more, an image-side focal length of 1.4 f or more and small dimensions. However, the various image errors are corrected satisfactorily = Furthermore , the following points must be taken into account in order to ensure very good image error correction. The radius of curvature ßi.posiiiv on the image side of a positive lens in group I must satisfy the following condition:

"l-poiili"

This is intended to correct the distortion at this point to a certain extent, which is in group I can occur. If the upper limit of this condition is exceeded, the corrective effect will be applied low in the drawing, while the rays near the lens mount are excessively deflected there if the value is lower than the lower limit. It also becomes the diameter of the front lens big, which is not wanted. On the other hand, the image-side radius of curvature of the positive lens must be Lens group II meet the following condition:

Wed p ..

This condition is used to reduce the negative distortion and distortion at this point to a certain extent to correct the negative asymmetry error. If this condition falls below the lower limit the correction effect of the distortion and the asymmetry error is lost, while the spherical Aberration becomes larger, which is not the case for the creation of a lens with a large relative aperture is advantageous. Besides these conditions, the mean value of the refractive indices of the positive lenses must be in Group III must be greater than 1.65. This is to correct the spherical aberration contained in the Group III can become larger, and that the Petzval sum is improved, which with this arrangement can also be great.

The invention is explained in more detail with the aid of the drawings. It shows

Fig. 1 schematically the objective according to claim 1, F i g. 2 shows the aberrations of the lens of FIG. 1,
F i g. 3 schematically the objective according to claim 2, F i g. 4 shows the aberrations of the lens of FIG. 3,
F i g. 5 the objective according to claim 3.
ίο F i g. 6 shows the aberrations of the lens of FIG. 5,
F i g. 7 the objective according to claim 4,
F i g. 8 shows the aberrations of the lens of FIG. 7th
The letters used in the following examples and in the drawings with the assignment of consecutive indices have the following meanings:

R = the radius of curvature, where the asterisk indicates the paraxial radius of curvature at the apex of the aspherical surface.

D = the lens thickness or the air gap between the lenses.

N = the index of refraction.

V = the Abbe number.

F i g. 2, 4, 6 and 8 show the aberration correction for each of the four exemplary embodiments. You can see that The field of view is 84 °, the light intensity is 1: 1.4 or 1: 1.2 is achieved and the state of correction is satisfactory, while the image-side focal length is 1.4 / or more amounts to

Here / u 8 sheets of drawings

230 225/122

Claims (4)

Patent claims: 1. Wide angle lens of the inverted> telephoto type, consisting of your first, negative Lens group with a negative meniscus lens member, a positive lens member, a negative Meniscus lens member, a second, positive lens group that has at least one biconvex lens in member contains and a third, positive lens group with a negative lens member and two positive lens members, characterized in that the design data of the Objective according to the construction data given below in so far as the area sub-coefficients correspond according to Seidel of the corresponding Seidel coefficients by no more than about 10% and the sums of the Seidel coefficients deviate from the corresponding sums by a maximum of 1%: R ₁ = 204.869 R ₂ = 92.118 R ₃ = 1747.92 K ₄ = - 418.490 K ₅ = 181.975 R _b = 621,535 R ₁ = 74.645 P = 117,531 Ä "= - 16VJ.26I R _1n = - 481.102 A ₁₁ = 144.367 R ₁₂ = - 64,710 R ₁₃ = 404,465 R _{1 4} = - 136,682 » A ₁ , = - 545.114 R ₁₆ = - 104,204 R ₁₁ = - 326.200 R _lt = - 113.535 / = 100 1: 1.4 »'= ± 42 D ₁ = 6.122 / V; = 1.58913 D ₂ = 44.898, N ₁ = 1.58913 D ₃ = 16.327 D, = 8.163 D ₅ = 16.660 D ₆ = 6.122 D ₇ = 42,600 D ₈ = 28.571 D ₉ = 0.816 D _1n = 6.122 D ₁₁ = 43.596 D _n = 4.082 D _n = 18.367 D ₁₄ = 0.612 D ₁ , = 20,408 D ₁₆ = 0.612 D _v = 24.490 / V ₃ = 1.80518 N, = 1.58913 N ₅ = 1.71300 N ₆ = 1.58913 / V ₇ = 1.80518 W ₈ = 1.77250 / V ₉ = 1.77250 / V ₁₀ = 1.77250 = 61.1 V ₁ = 61.1 K ₃ = 4/25 V _t = 61.1 = 54.0 K ₆ = 41.1 ^v i = 25.4 K ₈ = 49.6 K ₉ = 49.6 K ₁₀ = 49.6 where the surface with the radius λ14 is designed as an asphere, which satisfies the following equation: Rl + Ri / 1- 4- + BY * + CY " + DK * + EY ¹⁰ + ..., where Ri is the paraxial radius of curvature at the apex of the aspheric surface, the X-axis is assumed in the direction of light and in the direction of the optical axis and the J ^ axis is assumed to be perpendicular to it. B = C = D = E = 0.30364 χ ΙΟ- ⁶ 0.32524 χ ΙΟ " ¹⁰ -0.70817 χ 10 ^π 0.16736 χ ΙΟ " ¹⁸ fi = -178.016 ßl = 182.457 fill = 137.029 Back focus 148,980 10 15 20 25 30 35 40 45 50 55 60 0.09131 0.36322 0.80984 1.42057 2.17983 3.06592 4.05078 5.09947 6.17057 7.21722 8.1887S 9.03327 2. Wide angle lens of the inverted telephoto type, consisting of a first, negative Lens group with a negative me. a positive lens element, a negative meniscus lens element, a second, positive line group, which contains at least one biconvex lens element and a third, positive lens group with one negative lens member and two positive lens members, characterized. that the construction data of the lens according to the following KoßStruktionsdaten insofar than the area coefficients according to Seidel of the corresponding Seidel coefficients by no more than about 10% and the sums of the Seidel coefficients of the corresponding The sums differ by a maximum of 1%: = 209.792 A. / = 100 1: 1.4 W = ± 42 ° ■■ 1.58913 V ₁ = 61.1 97.914 D ₁ = 6.122 / V ₁ = R: = 596,914 D ₃ = 42,857 1.58913 V ₂ = 61.1 R ₃ = - 503.469 D ₄ = 16,327 / V ₂ = K ₄ = 147,927 D ₅ = 8,163 1.80518 y = 25.4 K ₅ = 731,335 A. = 12.245 / Vj = 1.58913 γ = 61.1 κ _Α = 69.249 D ₇ = 6.122 / V ₄ = K, = - 154.580 A. = 33,865 1.59270 V, = 35.6 R _t = 410,808 D, = 6.122 / V ₅ = K ₉ = 129.804 Ao = 0.816 1.71300 V ₆ = 54.0 ^ ₁₀ = - 160.110 A, = 22,449 / V ₆ = K _n = - 64.204 Dn = 48,865 1.80518 V ₁ = 25.4 Ru = 536,465 A. = 4.082 / V ₇ = 1.77250 v _% = 49.6 K ₁ , = - 139,494 » 0.4 = 23,437 N _% = «14 = - 652.371 D ₁₅ = 0.612 1.77250 V ₉ = - 104.429 D | _6th = 20.408 N ₉ = AI6 = - 248.902 Dn = 0.612 1.77250 Vw = 49.6 Ait = -! 10.751 - 22,449 / V ₁₀ = 5 6 where the surface with the radius Λ14 is designed as an asphere, which satisfies the following equation: Y ¹ X = Ri + Ri \ 1 Y \ ² - (JL) \ RiJ + CY ^b + DY * + EY ¹ " + .... where Ri is the paraxial radius of curvature at the apex of the aspherical surface, the .Y-axis in the direction of light and in the direction of the optical axis and the K-axis is assumed perpendicular thereto. B = 0.31911 χ 10- * Y 0 C = 0.31177 χ ΙΟ ^'10 0.08943 D = -0.49118XlO- ¹⁴ 0 0.35567 E = 0.19671 χ 10- ^{| p} 5 0.79233 10 1.38824 15th Z, i269S 20th 2,98600 25th 3.93653 30th 4.94347 35 5.96612 40 6.95988 /1 = - 246,555 45 7,87873 / If = 206.359 50 8,67877 /in = 138.412 55 60 Back focus 148,980 3. Wide angle lens of the inverted telephoto type, consisting of a first, negative Lens group with a negative meniscus lens member, a positive lens member, a negative Meniscus lens member, a second, positive lens group, the at least one biconvex lens member and a third, positive lens nib with one negative lens element and two positive lens elements, characterized in that the construction data of the objective according to The construction data given below correspond to the extent to which the surface sub-coefficients according to Seidel of the corresponding Seidel coefficient by no more than about 10% and the Sums of the Seidel coefficients from the corresponding sums by a maximum of the order of magnitude Deviate 1%: A ₁ = 238.273
R ₇ = 91.857
R ₁ = 347.980
Rt = - 415.498
Λ, = 249.318
R ₆ = 79.992
R ₁ = 108.448
R ₁ = 256.355
R _q = - 148,396
K ₁₀ = - 723,685
R _u = 147302
R ₁₇ = - 59,918
A _n = 175,780
R ₁₄ = - 140.061 * / = 100 1: 1.4 D _x = 6.122 D ₇ = 40.816 D ₃ = 18.367 D ₄ = 8.163 D ₅ = 6.122 D ₆ = 33.220 D ₁ = 12.245 D _s = 32.490 D, = 0.816 Ao = 6.122 D ₁₁ = 39.465 D _n = 4.082 Z) ₁₃ = 22.449 D ₁₄ = 0.612 W = ± 42 ° / V ₁ = 1.58913 / V ₂ = 1.58913 jV ₃ = 1.58913 N ₄ = 1.80518 / Z ₅ = 1.58913 N ₆ = 1.60562 Λ ' ₇ = 1.80518 iV _s = 1.77250 K ₁ = 61.1 V ₇ = 61.1 V ₃ = 61.1 V ₄ = 25.4 K ₅ = 61.1 K ₆ = 43.7 K ₇ = 25.4 V _s = 49.6 R _ls = - 351.473 Λ _{| 6} = - 111.702 R ₁₁ = -1289.98 Ru = - 112.110 D, _s = 18.367 At = 0.612 D ₁₇ = 24.490 / V, = 1.77250 / V ₁₀ = 1.77250 V ₉ = 49.6 ('.ο = 49.6 where the surface with the radius Λ14 is designed as an asphere, which satisfies the following equation: Y ¹ Ri + Ri - (XY \ Ri) BY '+ CY ^b + DY * + EY ^W + ..., where Ri is the paraxial radius of curvature at the apex of the aspiiian surface, the A'-axis is assumed to be in the direction of light and in the direction of the optical axis, and the K-axis is assumed to be perpendicular to this. B = G, 275ü5 χ ΊΪΓ · C = 0.29632 χ 10- '° D = 0.24732 χ IO E = 0.73959x10- " fl = -164.678 / II = 166.351 / III = 130.122 Back focus 148,980 4. Wide angle lens of the inverted telephoto type, consisting of a first, negative Lens group with a negative meniscus lens member, a positive lens member, a negative Meniscus lens member, a second, positive lens group, the at least one biconvex lens member and a third, positive lens group with one negative lens element and two positive lens members, characterized in that / = 100 1: 1.4 D ₁ = 6.122 D ₂ = 46.939 D ₁ = 16.327 O ₄ = 8.163 D ₅ = 12.245 D ₆ = 6.122 D ₁ = 41.535 D ₈ = 34.694 D ₉ = 0.816 D ₁₀ = 6.122 Y A " 0 0 5 0.08910 10 0.35465 15th 0.79127 20th 1,38947 25th 2.13490 30th 3.00780 35 3.98171 40 5.02318 45 6.09094 50 7.13601 55 8.10192 60 8.92584 R ₁ = 214.645 R ₂ = 94.910 Ri = 1059.03 R ₄ = - 466.286 R ₅ = 253.212 R ₆ = -2706.15 R ₁ = 89.878 / J ₈ = 122.482 A ₉ = - 180.106 IO - ~ OJi ₁ JJi that the design data of the lens according to the following design data to the extent that than the area sub-coefficients according to Seidel of the corresponding Seidel coefficients by no more than about 10% and the sums of the Seidel coefficients of the corresponding The sums differ by a maximum of 1%: = + 42 * N ₁ = 1.58913 N ₂ = 1.58913 N _} = 1.80518 JV ₄ = 1.58913 JV ₅ = 1.71300 N ₆ = 1.60342 K ₁ = 61.1 V ₂ = 61.1 V ₃ = 25.4 V _A = 61.1 V _s = 54.0 V ₆ = 38.0 9 10 Λ ,, = 147.657 D _n = 44.314, R ₁₂ = -65.184 O ₁₂ = 4.082 / V ₇ = 1.80518 V ₁ = 25.4 Λ ₁₃ = 252,273 0.3 = 24.490 .V ₈ = 1.77250 K ₈ = 49.6 /! μ = - 142.718 » D _u = 0.612 R ₁₅ = - 451.380 D ₁₅ = 24.490 N ₉ = 1.77250 V ₉ = 49.6 Λ ₁₆ = - 116.767 O ₁₆ = 0.612 R ₁₁ = - 703.677 D ₁₇ = 28.571 / V ₁₀ = 1.77250 K ₁₀ = 49.6 Λ _{| 8} = - 122.616
where the surface with the radius R 14 is designed as an asphere, which satisfies the following equation: