DE3119273A1 - Telephoto lens - Google Patents

Abstract

A description is given of a telephoto lens with a small f-number, which has a positive first lens cluster, a negative second lens cluster, a negative third lens cluster and a positive fourth lens cluster. The focusing operation is carried out by moving the third lens cluster in the direction of the optical axis. Assuming that the resulting focal length of the first, second and third lens clusters f (I, II, III), and the focal length of the total system is fT, the lens fulfils the condition 2fT < f (I, II, III) < 2.6fT for correcting the aberrations, the lens being focused on an object located at infinity. Furthermore, the third lens cluster is assembled from a positive and negative lens cemented together, and the lenses are produced from glass materials which are suitable for preventing the production of the secondary spectrum.

Description

Telephoto lens The invention relates to a photographic lens with a large aperture ratio of the so-called "partial focus type" which is designed so that the focusing operation by moving part of an optical System, the total length of the optical system (length of the first lens surface to the image surface) is kept unchanged.

Of the telephoto lenses, the rear focus type lenses are which are designed so that the focusing process by moving at least one of the lens groups is carried out, which are arranged on the image side of the front element are known from DE-OS 25 18 457. With these camera lenses, the heavy one remains Front part of the lens system stationary during the focusing process. Therefore postpones the center of gravity of the lens system changes to a lesser extent during the focusing process. Regardless of this kanll, as a lightweight lens group must be moved, a focusing operation is performed with a light touch will.

When a lens group is moved to focus, the movement is created the lens group changes the aberrations. However, if the lens system is so designed is that the overall length is short, there is a tendency that artifacts caused by a long lens are not essential, reducing the quality of the recorded image is reduced.

It is the object of the invention to determine the changes in the various image errors, which are generated when the lens groups are aligned along the optical axis for focusing be moved to push to a very small size and reduce the chromatic aberration and especially to reduce the secondary spectrum.

This object is achieved according to the invention by the in the characterizing part of claim 1 specified features solved.

The invention is described below using an exemplary embodiment Described in more detail with reference to the drawing. 1 shows a first exemplary embodiment of the invention in section, FIG. 2 shows the aberration curves of the objective according to FIG. 1, FIG. 3 shows a second exemplary embodiment in section, Fig. 4 the Aberration curves of the objective according to FIG. 3, FIG. 5, a third exemplary embodiment in section, FIG. 6 shows the aberration curves of the objective according to FIGS. 5, 7 fourth exemplary embodiment in section, FIG. 8 the aberration curves of the objective 7, and FIGS. 9A, B, C, D show the longitudinal chromatic aberration.

As shown in FIGS. 1, 3 and 5, the lens according to the invention has, from front to back, a positive first lens group 1, a negative second lens group II, a negative third lens group III and a positive fourth lens group 1V; the third lens group is movable for focusing. Assuming that in the infinitely focused optical structure, the focal length of the optical system including the first, second and third lens groups is f (I II III) and the focal length of the entire system is fT, the objective satisfies the condition : (l) 2fT <<f (I II III) <2.6fT Assume further that the third lens group is a cemented lens, which consists of a positive and a negative lens, and that the positive lens and the negative lens of the third Lens groups have refractive indices n5 and n6, Abbe's numbers v 5 and # 6, and partial dispersion ratios 95 (# = ng-nd) and # 6, and that the radius of curvature of the nF-nC of the backward convex cemented surface is riO , then the lens fulfills the conditions: The first lens group constitutes a so-called telephoto-type front assembly, and the second, third and fourth lens groups constitute a so-called telephoto-type rear assembly. With this structure and arrangement, the range of variation in aberrations in the focusing operation can be suppressed to a minimum.

Of the aberrations generated by the first lens group, the spherical aberration through the second lens group and the astigmatism through corrects the fourth lens group; these groups remain during the focusing process stationary so that those of the third lens group that are used for focusing are movable generated aberrations can be made small.

The I3condition (1) serves to shorten the total length of the optical System and to reduce the aberration change in the focusing process to one Minimum.

When the lower limit is exceeded, the focusing operation is effected a large change in the diameter of a light beam passing through the third lens group which in turn causes a large change in artifacts. If the If the upper limit is exceeded, the shortening of the overall length gets a great deal Refractive power of each group, so that the aberration correction difficult is to be carried out.

Condition (2) is to prevent changes in the artifacts when focusing by means of the third lens group. When the third lens group axial. moves, the spherical aberration4 the astigmatism and the Coma. The change range is reduced by this condition. When the refractive power the putty surface is lowered so that it exceeds the upper limit, change spherical aberration and astigmatism change to a great extent. if the refractive power of the cement surface is increased so that it exceeds the lower limit, spherical aberration and higher order coma are generated.

In order to get a good picture quality with the telephoto lens, it is essential, the chromatic aberration and especially the secondary spectrum to push to a minimum. According to the state of the art, the secondary Spectrum corrected by a suitable combination of glass materials from which the positive and negative lenses in the so-called front structure of the telephoto lens, which has positive refractive power.

According to the invention, the technique becomes a suitable combination of glass materials to be used also in the positive and negative lenses of the third lens group applied, creating a telephoto lens with an extraordinarily minimized secondary Spectrum is realized.

If the upper limit of condition (3) is exceeded, this becomes secondary spectrum unacceptably increased. When the lower limit is exceeded the correction of chromatic aberrations becomes difficult because within the range of currently commercially available glass materials makes the difference between Abbe's numbers of combined glass materials is small.

Also in the fourth lens group can if the shape one of one negative and positive lens existing cemented lens is chosen, a suitable one Combination of glass materials result in a high quality telephoto lens realized with a further minimized secondary spectrum.

Here the condition has to be fulfilled: where 2 7 and # 8 are the Abbe's numbers of the negative and positive lenses in the fourth lens group, and # 7 and Q8 are the partial dispersion ratios.

If the lower limit of condition (4) is exceeded, will the secondary spectrum is large. If the upper limit is exceeded, enabled the range of currently commercially available glass materials is so small Difference between the Abbe's numbers of the combined glass materials that there is it becomes difficult to obtain good chromatic aberration correction.

After the above conditions have been met, if a further improvement in image quality is desired, advantageously the first lens group made up of two positive lenses and one negative lens, the second lens group a low power meniscus lens which is convex forward, and the third To build up a lens group from a doublet, that from a positive one Lens, the rear surface of which is convex to the rear and a biconcave lens, and the following Conditions met: (5) 0.35fT <| fIII | <0.58fT, and fIII <0 (6) 0.125fT <r8 <0.15fT (7) 0.24fT <r11 <O.3fT where ri is the radius of curvature the i-th area in the overall system, i.e. the axial thickness or the axial air gap between the i-th and (i + l) -th area of the overall system in the overall system, ni the Refractive index of the glass material of the i-th lens element in the overall system and fIII is the focal length of the positive third lens group.

The conditions (5) serves to determine the size of the movement of the third Lens group for focusing and the range of changes in aberrations when Focus to a minimum press. If the upper limit is exceeded, the changes in the aberrations become very large, since the diameter of the through the light beam passing through the third lens group to a large extent The focus fluctuates. If the lower limit is exceeded, it will be large Aberrations with the similar result are generated as the changes in the aberrations become very large during the focusing process.

Condition (6) serves to correct the spherical aberration part of the first lens group passed through the second lens group in such a way that that the range of changes in spherical aberration when shifting the third Lens group is minimized. If the upper limit is exceeded, the Size of the corrected spherical aberrations tiori so small that the change in spherical aberration becomes large. When the lower limit is exceeded becomes higher order spherical aberration, coma and astigmatism great.

The condition (7) serves to prevent a change in aberration during the focusing operation the third lens group to prevent. This condition is particularly important in the variation of the spherical aberration.

When the upper limit is exceeded, the spherical aberration becomes undercorrected for shorter object distances. When the lower limit is exceeded becomes, the higher order spherical aberration changes to a great extent focus on overcorrection.

In the following, exemplary embodiments are explained which meet the conditions Fulfill (1) to (7). The chromatic aberration of each of the embodiments is shown in Figure 9; It should be noted here that the secondary spectrum is extreme is small. It should also be noted that in the graphs of astigmatism the meridional image area and S means the sagital image area.

Embodiment 1 (Fig. 1, Fig. 2) focal length f = 100 f-number = 1: 2.8 angle of view 2 # = 8.240 rd nd #d #g, d 1 42.819 6.123 1.49700 81.60 2 -165.112 0.170 L 3 35,799 5,783 1,43387 95.10 4 -163.269 0.980 1. 5 -119,601 1,700 1,72047 34.60 6 89,689 10,915 L. 7 15,878 2,041 1,58913 61.10 8 13,799 5,532 1. 9 -71,830 2,041 1.80518 25.40 1.3229 10 -24,673 0.850 1.61340 43.80 1.2626 11 2 & 817 1L588 L 12 60.563 0.850 1.69680 55.50 1.2385 13 19.768 27.21 1.61800 63.40 1.2401 14 -90,954 bf = 38,595 total length: 89,894 example 2 (Fig. 3, Fig. 4) focal length f = 100 f-number = 1: 2.8 angle of view 2 # = 6.180 rd nd #d #g, d 1 43,787 5.84 1,497 81.6 2 -169.35 0.13 1. 3 37,296 5.58 1,497 81.6 4 -155.24 0.97 1. 5 -115.08 1.63 1.72047 34.6 6 74,556 10.99 1. 7 15,672 2.13 1.58913 61.1 8 13,767 6.27 1. 9 -77,692 2.01 1.7552 27.5 1.3156 10 -21,975 0.88 1.6134 43.8 1.2626 11 28,891 9.59 1. 12 56.621 0.75 1.7725 49.6 1.2502 13 19,999 2.33 1.6175 55.1.2480 14 -81,517 1.

bf = 38.55 total length: 87.65 embodiment 3 (Fig. 5 and Fi.6) focal length f = 100 f-number = angle of view 2 «J - 6.180 rd nd #d #g, d 1 44.980 5.392 1.49700 81.60 2 -166,553 0.125 1. 3 37.715 5.556 1.49700 81.60 4 -156,611 1,035 1. 5 -115.267 16.25 1.72047 34.70 6 78,877 12,243 1. 7 15,977 2,125 1,58913 61.00 8 13,989 6,648 1. 9 -80,934 2,014 1.78472 25.70 1.3275 10 -20,879 0.875 1.65412 39.70 1.2726 11 26,949 9,834 1. 12 55.810 0.750 1.72916 54.70 1.2407 13 20,592 2,270 1.61272 58.70 1.2415 14 -70,248 1.

bf = 37.33 total length: 87.82 embodiment 4 (Fig. 7, Fig. 8) focal length f = 100 f-number = 1: 2.8 angle of view 2 @@ = 8.240 rd nd #d #g, d 1 44,710 5,792 1,43387 95.10 2 -157,835 0.235 1. 3 37.266 5.773 1.49700 81.60 4 -156.600 11.68 1. 5 -116,909 1,891 1,72047 34.70 6 89,317 9,890 1. 7 16,001 2,078 1,58913 61.00 8 14,231 6,529 1. 9 -73.909 17.41 1.80518 25.40 1.3229 10 -25.100 0.852 1.61340 43.80 1.2626 11 29,334 7,027 1. 12 99.290 0.852 1.64000 60.10 1.2296 13 15,689 2,976 1,61800 63.40 12,401 14 -69,680 1.

bf = 42.96 total length: 89.76 The values of the various sizes for the execution examples (fT = 100) Embodiment Size 1 2 3 4 f (III) 231.03 213.11 25.93 253.6 fI -40.11 -40.48 -35.773 -41.09 r @ 13,799 13,767 123,989 14,231 r11 28,817 28,891 26,949 29,334 n8-n9 0.00773 0.00645 0.00625 0.00764 r10 # 6- # 5 -0.00328 -0.00325 -0.00392 -0.00328 # 6- # 5 # 6- # 7 0.000203 -0.000407 0.000200 0.003182 # 6- # 7 A telephoto lens is described with: a small f-number, which has a positive first lens group, a negative second lens group, a negative third lens group and a positive fourth lens group. The focusing operation is carried out by moving the third lens group in the direction of the optical axis. If one assumes that the resulting focal length of the first, second and third lens groups is f (I, II, III) and uie the focal length of the overall system fT, the objective fulfills the condition 2fT <f (I, II, III) <2.6 fT to correct the aberrations, whereby the lens is focused on an object located in infinity.

Furthermore, the third lens group is made up of an assembled positive lens group and negative lens and the lenses are made of glass materials, which are suitable to prevent the generation of the secondary spectrum.

Claims (1)

Claims 1. Telephoto lens, characterized by a positive first lens group (I), a negative second lens group (II), a negative third lens group (III) and a positive fourth lens group (IV) when counting from the front, the third lens group being axially through of focusing is moved, and if f (I II III) denotes the resulting focal length of the first, the second and the third lens group when focusing at infinity and fT denotes the focal length of the entire system in the same state, the condition 2fT (f (I II III) <2.6fT is fulfilled, and the third lens group is a cemented lens, which consists of a positive lens and a negative lens whose refractive indices are n5 and n6, their Abbe's numbers are 5 or # 6 and their Partial dispersion ratios are denoted by 85 and 8, respectively, and in which r10 denotes the radius of the curvature of the putty surface, which is convex to the front, which fulfills aie condition: 2. Telephoto lens according to claim 1, characterized in that the condition is met where # 7 and # 8 are the Abbe's numbers of the negative and positive lenses in the fourth lens group, and # 7 and 08 are their partial dispersion ratios. 3. Telephoto lens according to claim 2, characterized in that the first lens group consists of two positive and one negative lens that the second lens group consisting of a mensicus lens of low refractive power, the convex after is in front, and that the third lens group consists of a positive lens, whose rear surface is convex to the rear, and a putty lens consisting of a biconcave lens where the following conditions are met: 0.35fT <| f @ | <0.58 f T where f @ <0 0.125ft <r @ <0.15 f T 0.24fT <r11 <0.3 f T whereby ri is the radius of curvature of the ith surface when counting from the front through the entire System, d. the axial thickness or the axial air gap between the i-th and (i + 1) -th Surface, n. The refractive index of the i-th lens element and fIII the focal length of the positive third lens group. 4. Telephoto lens according to claim 3, characterized by the following data: Embodiment 1 (Fig.l, Fig.2) focal length f = 100 f-number = 1: 2.8 angle of view 2 # = 8.24 ° rd nd #d #g, d 1 42.819 6.123 1.49700 81.60 2 -165.112 0.170 1. 3 35,799 5,783 1,43387 95.10 4 -163.269 0.980 1. 5 -119,601 1,700 1,72047 34.60 6 89.689 1.0915 1. 7 15,878 2,041 1,58913 61.10 8 13,799 5,532 1. 9 -71.830 20.41 1.80518 25.40 1.3229 10 -24,673 0.850 1.61340 43.80 1.2626 11 28,817 11,588 1. 12 60.563 0.850 1.69680 55.50 1.2385 13 19.768 27.21 1.61800 63.40 12.401 14 -90,954 bf = 38,595 total length: 89,894 5. telephoto lens according to claim 3, characterized by the following data: embodiment 2 (Fig.3, Fig.4) focal length f -. 100 f-number = 1: 2.8 angle of view 2 # = 6.180 rd nd #d ##, d 1 43,787 5.84 1,497 81.6 2 - 1 6 0.13 L 3 37,296 5.58 1,497 81.6 4 -155.24 0.97 1 5 -115.08 1.63 1.72047 34.6 6 74556 1099 L. 7 15,672 2.13 1.58913 61.1 8 13,767 6.27 1. 9 -27,692 2.02 1.7552 27.5 1.3156 10 -21,975 0.88 1.6134 43.8 1.2626 11 28,891 9.59 1. 12 56.621 0.75 1.7725 49.6 1.2502 13 19,999 2.33 1.6175 55.1.2480 14 -81,517 1. bf = 38.55 total length: 87.65 6. telephoto lens according to claim 3, characterized by the following data: embodiment 3 (Fig. 5 and 6) focal length f = 100 f-number = 1: 2.8 angle of view 2 # = 6.18 ° rd nd #d ##, d 1 44.980 5.392 1.49700 81.60 2 -1665.553 0.125 1. 3 37.715 5.556 1.49700 81.60 4 -155,611 11 LO 3 5 L 5 | -115.267 | 1.625 | 1.72047 | 34.70 6 7 78 877 77 | 12,243 1. 7 15,977 2,125 1,58913 61.00 8 13,989 6,648 1. 9 -80,934 2,014 1.78472 25.70 1.3275 10 -20,879 0.875 1.65412 39.70 1.2726 11 26,949 9,834 1. 12 55.810 0.750 1.72916 54.70 1.2407 13 21592 2.270 L61272 5 & 70 L24 15 14 -7W248 L bf = 37.33 total length = 87.82 7. telephoto lens according to claim 3, characterized by the following data: embodiment 4 (Fig. 7, Fig. 8) focal length f = 100 f-number = 1: 2.8 angle of view 2 # = 8.240 rd nd #d #g, d 1 44,710 5,792 1,43387 95.10 2 - 1 5 7.8 3 5 0.2 3 5 L. 3 3 7.2 6 6 5.7 7 3 L4 97 0 0 8 1.6 0 4 - 1 5 & 6 0 0 1.1 6 8 L. 5 -116,909 18.91 1.72047 34.70 6 89.317 98.90 1. 7 16,001 2,078 1,58913 61.00 8 14,231 6,529 1. 9 -73,909 1,741 1.80518 25.40 1.3229 10 -25.100 0.852 1.61340 43.80 1.2626 11 29,334 7,027 1. 12 99.290 0.852 1.64000 60.10 1.2296 13 15,689 2,976 1,61800 63.40 1.2401 14 -69,680 1. b.f. = 42.96 total length = 89.76