DE2750571C3 - Varifocal lens - Google Patents

Description

changes, the quality of the image is influenced by other factors additionally adversely affected. On the other hand, the use of additional lenses is known to increase the magnification a Kopierobjeklivs in a copier od. Like. To change without the position of the object and the Change image. However, this method is disadvantageous in that the magnification is not continuous can be changed, and it is difficult to replace the auxiliary lenses every time change the magnification. Furthermore, with this procedure it is necessary if a bitile enlargement range is required, a Use additional lens with high refractive power, which in addition to the significantly increased distortion various aberrations appear to an increased extent.

The object of the invention is therefore to create a varifocal lens of the type mentioned, which as a copier lens in a copier or the like can be used and continuous change allows the enlargement of the image obtained. This varifocal lens should be free from distortion and back focal length change, caused by changing the position of the image field shells, over across the entire magnification range, and should also be built very compactly. This task will according to the invention by a varifocal lens with the characterizing part of claim 1 or the characterizing part of claim 2 contained construction data solved.

With this construction, the distortion is constant, i.e. H. so for any enlargement, on 0% echoed by asymmetrical movement of the movable lens groups.

The invention is explained in more detail below with reference to the exemplary embodiment shown in the drawing explained. In the drawing shows

1 shows a schematic representation of the movement of the lens groups of the zoom lens according to the invention,

Fig. 2 is a graph showing the relationship between the movement of the movable Lens group and the distortion can be seen,

Fig. 3 is a graph showing the relationship between the movement of the displaceable Lens group for eliminating the distortion and the magnifications of the varifocal lens can be seen is,

4 shows a sectional view of the zoom lenses according to the invention and

5 to 9 correction curves of the first zoom lens, A showing the spiral AL * calibration, B showing the astigmatism and C showing the distortion.

The varifocal lens, the one constant, assigned Has spacing, has at least two movable lens groups. Because the magnification range too should capture the reproduction ratio 1: 1, a symmetrical construction of the lens is required, which shows no distortion at a magnification of 1: 1 Hence the distortion over the entire magnification range To avoid this, the two movable lens groups must always be almost symmetrical Position to be brought with respect to the aperture.

Fundamental to the design data is how the refractive power is divided between the lens groups should that form the varifocal lens. When the refractive power of the movable lens groups is made small, the displacements of the lens groups become large, thereby simplifying the structure of the lens. In this case, the zoom lens is large. If on the other hand the refractive power of the movable lens groups is made large, the displacement paths are small, and you get a compact varifocal lens. In this case, however, the refractive power should not be made too large so that the zoom lens does not cause large aberration changes is subjected. In order to obtain a varifocal lens that is sufficient in practice Aperture and a sufficient field of view, the division of the refractive power between the movable lens groups can be appropriately controlled.

The varifocal lens of the type described here should therefore provide a suitable division of the refractive power between allow the movable and the stationary lens groups, with regard to the dimension of the lens as a whole, a compromise is considered. Thus, it becomes a sufficient compactness obtained under the condition formulated below

2.0 <

/■.0

<3.0

In this formula, / i _{0 means} the focal length of the entire lens when the magnification is 1: 1, and /, the focal length of the movable lens groups. If the above value falls below the lower limit, that is, the refractive power of the movable lens becomes too small, the change in aberration becomes small but the size of the lens becomes large. If the above value exceeds the above limit, that is, the refractive power of the movable lens becomes too large, the size of the lens becomes small, but the aberration changes become too large.

It should also be noted that in the case of the zoom lens, in each case on the side facing away from the diaphragm, the movable lens group fixed lens groups are arranged, so that the structure of the lens races simplified, and the handling of the lens is facilitated. In addition, the two are stationary Lens groups correspond completely in their structure, just like in the structure of the two movable lens groups is the case, which significantly reduces the manufacturing costs of the lens system can be.

In Fig. 1, A and D denote fixed lens groups having the same structure and focal length // ;; have, while B and C relate to movable lens groups, which also have the same structure and the same focal length />. The stationary lens groups A and D are arranged symmetrically with respect to an aperture E \ n in the center of the zoom lens. The movable lens groups B and C are also arranged symmetrically with respect to the aperture E when the magnification of the lens is 1: 1 between the first stationary lens group A and the first moving lens group B is denoted by / 1 and similarly the axial distance between B and C is denoted by 11 and that between C and D by / 3. The size of the movement of the zoom lens to change the magnification is designated by DL . The distances ί 1, / 2 and / 3 and DL are designated by / la, tla, tZa and DLa as soon as the magnification of the entire system is changed from 1 to ma . The size of the movement DLa for changing the magnification determines t \ a and t3a. and

/ la is determined by ι ία and / 3 «. With a suitable choice of DLa it is possible to make / la - 13a , which means that the two movable lens groups B and C are moved into the position in which they are symmetrical with respect to the aperture E in the center <5 of the lens lie. In this case, however, the distortion cannot be reduced to 0%, except then ··? when the magnification is 1: 1. It is therefore required that the two movable lens groups be in the symmetrical position only when the magnification is 1: 1.

The varifocal lens of the type described here identifies in that the distortion is always 0 for each magnification.

Fig. 2 shows the relationship between the distortion and the ratio of / \ a to 13a. when the magnification is 0.5. From FIG. 2 it can be seen that the distortion is reduced from 0.3% to 0% by changing the ratio / \ n / l7m from 1.ΠηιιΓ0.ί? 4. This means that the distortion which then appears when the movable lens groups B and C are arranged in a symmetrical position with respect to the diaphragm E can be reduced to 0% by bringing these lens groups into an asymmetrical position will.

3 shows the relationship between the magnification of the objective and the ratio i \ a / i3a , by means of which the distortion can be kept at 0%. The magnification is given by log./? shown (ß is the enlargement). It can be seen from FIG. 3 that the distortion can be kept at 0% by a suitable choice of the ratio ila / l3a.

Another important factor to be considered in the zoom lens is that Change in the position of the image field shells that occurs as soon as the magnification changes. In particular in a copier in which the object is a flat document, the image should be flat.

The best way to make an appropriate correction is to design the lens so that at the same time a correction of the distortion and a shift of the image plane takes place because on this simplifies the construction of the lens.

Therefore, the movement of the second movable lens group, whose primary function is to establish the Gaussian image plane, is also used to remove the combined image shift, so that the / 3r7 values serve a multiple purpose. Thus, infQ! ^D cdcssci! the simple ßcwc "Uii ^and the second movable lens group not only to the correction of the distortion, but also to maintain the image plane in a fixed position, and that in addition to their Iauptaufgabe I, which consists in carrying out zooming.

The following are the design data of the invention Lenses listed, with the radii of curvature of the refracting surfaces, furthermore the axial air spacing of the lenses, furthermore the refractive indices for the Ilelium-d line and the Abbe numbers are specified.

Lens 1 Focal length cover - 2845.8 = 490-550 enlargement = -2, OX ~ -O, 5X 1.78472 'Ί = 25.7 1/8 190.495 R, = «11 = - 146.785 rfi - 6.00 Λ ', = 1.62041 '■ 2 = 60.3 ! 13,337 R ₁ = * n = 304,601 (I ₂ = 20.00 , V ₂ = 1254.7 Ry R _n = - 127.044 rf, = 1.00 1.62041 > \ t = 60.3 154,416 Ra = Ru = - 1013.4 rf ₄ = 10.00 N ₃ = 506.725 R, = R15 = rf, = variable 1.71700 '\ i = 47.9 1013.4 Re = <4 - 3.94 / V ₄ = 127.044 Ri = rf, = 11.80 . ', 51633 r ₅ = 64.0 - 304,601 Rz = d ~ t = 3.94 / V ₅ - 1.68893 ■ 's = 31.1 146.785 R ₉ = rf, = 9.85 'V ₆ = 2845.8 Rio ⁼ d _xo = variable d \ a- = variable 1.68893 = 31.1 d "= 9.85 / V ₇ = 1.51633 ^r s = 64.0 J _n = 3.94 'Vs - dn = 11.80 1.71700 ^r 9 = 47.9 4.4 = 3.94 W- = rf _IS = variable

A ₁₆ = - 506.725

A ₁₇ = - 154.416 Λ is = 1254.7

«" = - 113.337

R ₁₀ = - 190.495

enlargement
Focal length
Object distance
Image distance

conjugate distance

27 - 1.4 50 571 1.62041 JO 9 535.6 'Mo = 60.3 d _u - 10.00 - 829.3 'V ₁₀ = 1.62041 J ₁₇ = 1.00 1200.3 1.78472 ι · ,, = 60.3 J _n = 20.00 11.92 / V ₁₁ = -0.7 -M ₂ = 25.7 ίΤ ,, ι = 6.00 8.97 / V ₁₂ = 535.8 -0.5 - 2.0 10.28 - ι, ο , 6 -1195.8 492.2 491.4 ίΟ, όϊ 551.0 831.6 - 1371.1 - 654.0 2200.0 - 1012, 10.73 656.8 1379.4 1014.8 10.16 14.25 17.21 10.0 9, ii 6.64 3.68 10.89 i ί, 7δ 4.01 6.80 OK, 98 2200.0 16, pp ί4, ΰν y, 9i 2200.0 2200.0 2200.0

Lens 2 Focal length = 330 - 345 magnification " -1.0X ~ 0.65X 1.68893 i-, = 31.3 1 / 5.6 194,211 «, - d \ = 5.03 / V ₁ = 1.62041 '"2 - 60.3 95.877 R ₁ = d ₂ = 16.06 / V ₂ = 12588.9 «3 = d) = 0.60 1.71300 ■ 'J ⁼ 53.9 103.135 R ₄ = d _A = 9.10 / V ₃ = 1150.4 R ₅ = d ₅ = variable 1.70154 • '4 ⁼ 41.1 4085.8 R ₆ = ~ df> = 3.88 / V ₄ = 87.991 Ri = d-, = 9.84 1.51633 ι · ₅ = 64.0 - 580,450 R _t = ~ d% = 3.88 / V ₅ = 1.68893 ^r 6 ⁼ 31.1 111.224 R ₉ = rf. = 8.05 / V ₅ = 572,600 R ₁₀ = = variable cover ^ ₁₀ . = variable 1.68893 r ₇ = 31.1 - 572,600 U ₁₁ = = 8.05 / V ₇ = 1.51633 ^r 8 = 64.0 -111.224 «12 = ~ d _n = 3.88 'Vg = 580,450 Ä, ₃ = you = 9.84 1.70154 r ₉ = 41.1 - 87.991 R _u = you = 3.88 / V, = - 4085.8 R _n = ~ d _n = variable 1.71300 ¹ Mo = 53.9 - 1150.4 R _s6 = = 9.10 / V ₁₀ = - 103.135 R _n = d _l7 = 0.60 1.62041 603 - 12588.9 Rn = rf _{] g} = 16.06 Λ ⁷ ,, = L68893 31.1 - 95.877 R ₁₉ = rf ₁₉ = 5.03 N _n =

A ₂₀ = -194.211

Magnification Focal length Object distance Image distance r / s

Conjugate distance

27 - 1.0 50 571 12th 345.4 - 0.65 - 621.3 -0.74 330.6 622.4 338.1 - 765.5 4.70 - 722.2 478.3 9.61 521.5 5.85 9.66 5.15 8.47 4.66 9.16 7.82 1384.2 8.69 6.50 iJiefzU 4 5.63 1384.2 1384.2 Sheet drawings

Claims (2)

Patent claims: 1. Varifocal lens with a first stationary lens group and a first movable lens group, one second movable lens group and a second stationary lens group, characterized in that that its design data correspond to the following specified design data: R \ - 190.495 R ₂ = 113.337 R ₃ = 1254.7 R, = 154,416 R ₅ = 506.725 R ₆ - 1013.4 Ri = 5 ^ 7,044 «8 = - 304,601 R ₉ = 146.785 «10 = 2845.8 itop «II = - 2845.8 «12 = - 146.785 «13 = 340,601 «14 ⁼ - 127.044 «15 = - 1013.4 «16 = - 506.725 «17 = - 154.416 «! 8 = 1254.7 «1« ⁼ - 113.337 R = - 190.495 d] = 6.00 J ₂ = 20.00 rf, = 1.00 J ₄ = 10.00 J ₅ = variable d ₆ = 3.94 U ₁ - 11.80 J ₈ - 3.94 J ₉ - 9.85 dm = variable Jio = variable you = 9.85 J ₁₂ = 3.94 J ₁₃ = 11.80 d » = 3.94 J ₁₅ = variable J | 6 = 10.00 3], = 1.00 Jl ₈ = 20.00 J ₁₉ = 6.00 W ₁ = 1.78472 N ₂ = 1.62041 N ₃ = 1.62041 N ₄ = 1.71700 N ₅ = 1.51633 / Y ₆ = 1.68893 N ₁ = 1.68893 / V ₈ = 1.51633 / V ₉ = 1.71700 N ₁₀ = 1.62041 AZ ₁₁ = 1.62041 N _n = 1.78472 <·, = 25J 1-2 = 60.3 . • 3 = 60.3 "4 = 47.9 v ₅ = 64.0 v ₆ = 31.1 V ₁ = 31.1 r, = 64.0 , ·, = 47.9 v ₁₀ = 60.3 r "= 60.3 .- _I2 - 25.7 where d ₅ , d _w , d _m , and d _ls 17.21, 3.68, 6.80, and 14.09 are door magnification -2.0;
11.92, 8.97, 10.28 and 10.61 door the magnification - 1.4;
10.0, 10.89, 10.98 and 9.91 for magnification - 1.0;
10.73, 10.16, 9.11 and 11.78 for magnification -0.7;
14.25, 6.64, 4.01 and 16.88 for magnification -0.5, the radius of curvature of the corresponding surfaces with R, the axial air gap of the lenses with J, the refractive indices for the helium-d-line with N and the Abbe numbers with ι ·. 2. Varifocal lens with a first stationary lens group, a first movable lens group, a second movable lens group and a second fixed lens group, characterized in that its Design data correspond to the following specified design data: 194.211 95.877 12588.9 'd \ = 5.03 J ₂ = 16.06 J ₃ = 0.60 / V ₁ = 1.68893 N ₁ = 1.62041 , -, = 31.3 V ₂ = 60.3 Ri = R ₉ = Rio ⁼
stop Ru = Rn = 103.135
1150.4
4085.8 87.991 - 580,450 111.224 572,600 - 572,600 - 111.224
R _n = 580.450
Λ, ₄ = - 87.991
A ₁₅ = -4085.8
A ₁₆ = -1150.4
Λ, 7 = - 103.135
Ria = - 12588.9
Λ, ₉ = - 95.877
Λ ₂₀ = -194.211 ί / ₄ = 9.10 rf ₅ = variable df, = 3.88 I ₁ = 9.84 dg = 3.88 rf ₉ = 8.05 rf _I0 = variable d _t0 , = variable rf ,, = 8.05 d _n = 3.88 d _n = 9.84 rf, 4 = 3.88 rf, j = variable rfi6 = 9.10 rf, τ = 0.60 rf, g = 16.06 rf ,, = 5.03 N ₃ = 1.71300
JY, = 1.70154 / V ₅ = 1.51633
/ V ₆ = 1.68893 N ₇ = 1.68893
N _s = 1.51633 / V _q = 1.70154
/ V ₁₀ = 1.71300 N _n = 1.62041
N _n = 1.68893 . ' ₃ = 53.9 iM = 41.1 • 5 = 64.0 r ₆ - 31.1 V ₁ = 31.1 . ■ ₈ = 64.0 . ·, = 41.1 -, "- 53.9 κ ,, = 60.3 r, j = 31.1 where rf ₅ , rf _I0 , rf ₁₀ , and rf _IS 4.70, 9.61, 9.66, 4.66 when the magnification is -1.0; 5.15, 9.16, 8.69, 5.63 when the magnification is -0.74 and 5.85, 8.4 /, 7.82, 6.50 when the magnification is -0.65, where the radius of curvature of the corresponding surfaces is denoted by R, the air distance of the lenses with d, d ^: e refractive indices for the helium-d-line with N and the Abbe numbers with i-. The invention relates to a zoom lens with a first stationary lens group and a first movable one Lens group, a second movable lens group and a second fixed lens group. Such a varifocal lens is from DE-AS 22 51 574 known. Here, however, the movable lens groups when the focal length is changed with respect to the Aperture moved symmetrically, so that the distortion at a magnification of 1: 1 is 0%, but up to 0.3% at smaller magnifications. In copying machines, the object plane and the image plane are generally very large compared to photo objects. Therefore, the diameter and overall length of the lens are also comparatively large with a given image field and given focal length. From the standpoint of the manufacture and construction of such machines, the lens used in them should be built as compact as possible. In addition, the lens used must be completely free from imaging errors, especially with such lenses, distortions of the image must be excluded Copy lenses are more often symmetrical, so they are free from distortion at a magnification of 1: 1. In this case, at least two of the following ' ^! Three elements are moved in a manner known per se, namely the object plane, the image plane and the lens. In dtv practice, however, it is difficult and undesirable to move two of these elements. Even if these two elements are firmly connected to each other by a mechanism, this means a construction of the copier machine, It should also be noted that it is theoretically inevitable is to enlarge the distance between the object and the picture once the enlargement ratio 1: 1 is left, even if a symmetrical lens that is free VOIi distortion, in the case of a Magnification 1: 1 is used, a Ver = Drawing as soon as the magnification deviates from this ratio, If the magnification is strong