DE4447946C2 - Zoom lens with several lens groups - Google Patents

Abstract

During the focal length change, two lens groups are simultaneously moved with mutually constant spacing. One group is of small importance for the magnifying change, and both have a sharpness adjustment sensitivity with different signs. The sharpness adjustment sensitivities meet the specified formulae related to the sharpness adjustment sensitivities of both lens groups during the tele-limit adjustment. Such that 12 \!K~b\!. Pref. the two groups also meet a further formula related to their sharpness adjustment sensitivities, where -0.5\ K~a/K~b-0.1.

Description

The invention relates to a zoom lens according to the Oberbe handle of claim 1. This lens has a high Focal length ratio of more than 3 and is physical small. It can be advantageously used in a compact camera that has a limited focal length.

In a known zoom lens for a compact camera with a large image scale and a small overall length the focus sensitivity (ratio of publishers focal point to a misalignment of the lenses groups in the direction of the optical axis) when setting a very long focal length. This means that the Focal point substantially from the film level through a small Errors in the adjustment of the lens groups may differ, causing deterioration in image quality. To avoid this, a zoom lens with three lens groups,  with a first, positive lens group, a second positive lens group and one third, negative lens group proposed, in which the first and third lens groups are moved together (see e.g. JP-A Hei 2-256015). The variable performance (Magnification) of this zoom lens is about 2.5 and therefore needs an increase.

It is an object of the invention to be a physically small Specify high performance zoom lens, its imaging Scale (magnification) is above 3, but a ge rings has focus sensitivity and is for a Compact camera suitable in which the entire lens length long focal lengths should be small.

The invention solves this problem by the features of Claim 1. Advantageous further developments are counter stood the subclaims.

In the invention, "focus sensitivity" means the ratio of the displacement (or deviation) of the focal point to a setting error of the assigned lenses group in the direction of the optical axis. If the keen sensitivity is large, there is a large Ver storage of the focal point with small adjustment of the Lin scorching roup. The "degree of influence" on the change in magnification tion denotes a variation in lateral magnification per adjustment unit of the lens group. In the invention becomes the lens group with a small degree of influence as lenses group α and the lens group with great influence as Lens group called β.

In the development of the invention according to claim 2, the lens groups α and β fulfill the following relationship:

9 <| Kα + Kβ | <20 (3)

In the case of a physically smaller zoom lens, the formulas (1) and (3) according to claim 1 are replaced by the following formulas:

14 <| Kβ | (1')

10 <| Kα + Kβ | <20 (3 ')

In this development, the lens group β has a large one Performance and is preferably designed as an aspherical lens leads.

To simplify the mechanical construction of the zoom lens Chen, the focus is preferably with one the lens group as the lens groups α and β leads.

The invention is based on the drawings explained here. In it show:

Fig. 1 is a schematic representation of the lens arrangement of a zoom lens as a first embodiment,

Fig. 2, 3 and 4, various aberration diagrams of the zoom lens of FIG. 1,

Fig. 5 is an example representation of the Ver position of lens groups in a zoom lens of FIG. 1 at the focal length change,

Fig. 6 is a schematic representation of the lens arrangement of a zoom lens as two tes embodiment,

Fig. 7, 8 and 9, various aberration diagrams of the zoom lens of FIG. 6,

Fig. 10 is an example representation of the Ver position of lens groups in a zoom lens of FIG. 6 during the focal length change,

Fig. 11 is a schematic representation of the lens arrangement of a zoom lens as drit tes embodiment,

Fig. 12, 13 and 14, various aberration diagrams of the zoom lens of FIG. 11,

Fig. 15 is an example representation of Stel development of lens groups in a Varioob objectively according to Fig. 11 tenänderung during Brennwei,

Fig. 16 is a schematic representation of the lens arrangement of a zoom lens as four tes embodiment,

Fig. 17, 18 and 19, various aberration diagrams of the zoom lens of FIG. 16 and

Fig. 20 is an example representation of the Ver position of lens groups in a zoom lens of FIG. 16 at the focal length change.

When miniaturizing a high performance zoom lens, takes the focus sensitivity of one or more Lens groups mainly used to change the magnification contributes to dramatically with enlargement. To do this prevent two lens groups according to the invention with different signs of the focus sensitivity mechanically assigned to each other so that they are in the Focal length change can be moved together, causing the Focus sensitivity is optically reduced. This can be achieved using a simple mechanism become, and the impact of such a measure takes increasing magnification.

Formula (1) gives the focus sensitivity of the Lens group β, which mainly changes the magnification, for long focal lengths. If the value of formula (1) un is below the lower limit, the two requirements  increasing magnification and miniaturization tion of the zoom lens cannot be met. In previous Varifocal lenses, the value of formula (1) is below the un lower limit.

Formula (2) gives the degree of sharpness reduction setting sensitivity when the lens groups α and β be moved as a unit. If the value of the formula (2) is greater than the upper limit, the focus is setting sensitivity at most 10%. If the value of the Formula (2) is less than the lower limit, the Focus sensitivity can be effectively reduced, however, not only does the performance of the lens group decrease β, but also that of the lens group α, so that a Correcting the resulting aberration is difficult.

Formulas (3), (4) and (5) specify the requirements to a zoom lens for a compact camera whose Vario ratio is over 3. If the value of formula (3) is above the upper limit, an undesirable occurs Relocation of the focal point in the lens barrel of a norma len compact camera, even if the lens groups α and β be moved together. This results in a large ab softening between the film plane and the image plane. This leads to a deterioration in the image quality. If the Value of formula (3) is below the lower limit the focus sensitivity effectively reduced who den, however the vario ratio is less than 3.

The formulas (4) and (5) give the lateral magnification and the vario ratio of the lens group β for the telephoto limit position. If the values of formulas (4) and (5) above the respective upper limit, the armed takes setting sensitivity too high. The values are below the respective lower limit, there is an increase in variable performance of the entire lens system difficult.  

First embodiment

Fig. 1 shows the lens arrangement of a zoom lens with large variable power as a first embodiment of the invention.

The zoom lens consists of three lens groups, in which the first and the third are labeled α and β. , During an adjustment of the Fig. 5 shows on which lines the three lens groups WIDE extremity position W to the telephoto limit position T to be moved. The focus is done here with the second lens group.

The numerical data of the zoom lens shown in FIG. 1 are shown in Table 1 below. Various aberrations at different focal lengths are shown in FIGS. 2, 3 and 4. In Fig. 2 to 4 SA are the spherical aberration, SC the sine condition, the d line, the g line and the c line the chromatic aberration, represented by the spherical aberration for the respective wavelengths, S the sagital beam and M the meridional beam.

In the tables and the figures, F _NO denotes the f number, F the focal length, ω half the viewing angle, FB the focal length, ri the radius of curvature of each lens surface, ie the lens thickness or the distance between the lenses, N the refractive index and ν the Abbe number.

The shape of the aspherical surface can generally be expressed as follows

X = CY ² / {1 + [1 - (1 + K) C ² Y ² ] ^½ } + A4Y ⁴ + A6Y ⁶ + A8Y ⁸ + A10Y ¹⁰ +. , ,

where Y is a height above the axis, X is a distance to a tangential plane at an aspherical vertex,
C is a curvature at the aspherical vertex (1 / r),
K is a taper constant,
A4 is a fourth order aspherical aberration factor,
A6 is a sixth-order aspherical aberration factor,
A8 an eighth-order aspherical aberration factor and
A10 is a tenth-order aspherical aberration factor.

Table 1

In the first exemplary embodiment, the focusing sensitivities K ₁ , K ₂ and K _{3 of} the first, the second and the third lens group are specified using the following equations:

K ₁ = (m _T2 .m _T3 ) ² = 4.1 = Kα

K ₂ = m _T3 ² - K1 = 13.3

K ₃ = 1 - m _T3 ² = -16.4 = Kβ

Kα / Kβ = -0.25

| Kα + Kβ | = 12.3

m _T2 = 0.48

m _T3 = 4.17 = m _T β

M _W3 = 1.48 = m _W β

m _T β / m _W β = 2.82

M _{T2 is} the lateral enlargement of the second lens group in the telephoto limit position,
m _T3 the lateral enlargement of the third lens group in the telephoto limit position,
m _W3 the lateral enlargement of the third lens group in the wide-angle limit position.

Second embodiment

Fig. 6 shows the lens arrangement of a zoom lens of high performance as a second embodiment of the invention.

The zoom lens consists of three lens groups, the first and the third of which are labeled α and β. Fig. 10 shows the lines on which the lens system is moved during the focal length change. In the second embodiment, focusing with the second lens group is similar to that in the first embodiment.

The numerical data of the lens shown in Fig. 6 are shown in Table 2 below. Diagrams of various aberrations are shown in FIGS . 7, 8 and 9.

Table 2

In the second embodiment, the focus sensitivities K ₁ , K ₂ and K _{3 of} the first, the second and the third lens group are given by the following equations:

K ₁ = (m _T2 .m _T3 ) ² = 4.6 = Kα

K ₂ = m _T3 ² - K ₁ = 13.2

K ₃ = 1 - m _T3 ² = -16.8 = Kβ

Kα / Kβ = -0.27

| Kα + Kβ | = 12.2

m _T2 = 0.51

m _T3 = 4.22 = m _T β

m _W3 = 1.51 = m _W β

m _T β / m _W β = 2.80

Third embodiment

Fig. 11 shows the lens arrangement of a high-performance zoom lens as a third embodiment of the invention. The zoom lens consists of four lens groups, the first and the third of which are labeled α and β. FIG. 5 shows lines on which the lens system is moved between the wide-angle limit position W and the telephoto limit position T when the focal length changes. The second lens group focuses.

The numerical data of the lens shown in Fig. 11 are shown in Table 3 below. Different aberrations at different focal lengths are shown in FIGS. 12, 13 and 14.

Table 3

In the third embodiment, the sharpness sensitivity K ₁ , K ₂ , K ₃ and K _{4 of} the four lens groups are given by the following equations:

K ₁ = (m _T2 .m _T3 .m _T4 ) ² = 4.1 = Kα

K ₂ = (m _T3 .m _T4 ) ² - K ₁ = 12.2

K ₃ = m _T4 ² - (m _T3 .m _T4 ) ² = -15.5 = Kβ

K ₄ = 1 - m _T4 ² = 0.3

Kα / Kβ = -0.26

| Kα + Kβ | = 11.4

m _T2 = 0.50

m _T3 = 4.73 = m _T β

m _T4 = 0.85

m _W3 = 1.50 = m _W β

m _T β / m _W β = 3.15

Fourth embodiment

Fig. 16 shows the lens arrangement of a zoom lens of high performance as a fourth embodiment of the invention.

The zoom lens consists of four lens groups, the first and the fourth of which are labeled α and β. Fig. 20 shows the lines of movement of the lens system at the focal length change from the wide-angle limit position W and the tele position T. The focus adjustment is carried out with the second and third lens groups which are moved together. The numerical data of the lens shown in FIG. 16 are shown in Table 4. Different aberrations for different focal lengths are shown in FIGS. 17, 18 and 19.

Table 4

In the fourth embodiment, the focus sensitivity K ₁ , K ₂ , K ₃ and K _{4 of} the four lens groups are given by the following equations:

K ₁ = (m _T2 .m _T3 .m _T4 ) ² = 3.5 = Kα

K ₂ = (m _T3 .m _T4 ) ² - K ₁ = -3.4

K ₃ = m _T4 ² - (m _T3 .m _T4 ) ² = 13.9

K ₄ = 1 - m _T4 ² = -13.0 = Kβ

Kα / Kβ = -0.27

| Kα + Kβ | = 9.5

m _T2 = -5.50

m _T3 = -0.097

m _T4 = 3.75 = m _T β

m _W4 = 1.42 = m _W β

m _T β / m _W β = 2.64

The values of formulas (1) to (5) described above benen four embodiments are in the following Table 5 given.

Table 5

As shown in Table 5, all four meet tion examples provided by formulas (1) to (5) Conditions. According to the invention, the vario ratio about 3, and the aberrations are correctly compensated.

The invention thus leads to a physically small one High performance zoom lens made up of three or more Lens groups exist.  

The following relationships preferably apply:

3.3 <m _T β <6 (4)

2.5 <m _T β / m _W β <4 (5)

where m _T β is the lateral enlargement of the lens group β at the telephoto limit position and m _W β is the lateral enlargement of the lens group β at the wide angle limit position.

Claims (1)

Varifocal lens with at least three lens groups, whereby viewed from the object, a first positive lens group with a positive refractive power, a second positive lens group with a positive refractive power and a negative lens group with a negative refractive power are provided, the three lens groups for focal length adjustment from a short position Focal length to a long focal length position toward the object, and the negative lens group fulfills the following relationships:
3.3 <m _T β <6 (4)
2.5 <m _T β / m _W β <4, (5)
where m _T β is the lateral enlargement of the lens group β at the telephoto limit position and m _W β is the lateral enlargement of the lens group β in the wide-angle limit position.