DE4032051A1 - Zoom lens system for camera - has fixed front group of lenses and rear group which is moved to focus object - Google Patents

Abstract

The middle lenses, of a zoom lens system for a camera, consist of a front group (GF) and a rear group (GR). The first group (GF), starting from the object side, consists of at least two convergent lenses with their pronounced convex sides facing the object. The group (GF) also includes a divergent lens with a pronounced concave side facing towards the image. The combined group (GF) of lenses has a resultant convergent refractive power. The lens of the rear group (GR) which is closest to the object has a convex face on the side facing the object. The group (GR) has a resultant convergent refractive power and only this rear group is moved along the optical axis in order to focus the object. USE - Zoom cameras.

Description

The present invention relates to a Imaging lens system for use in cameras such as e.g. B. an SLR camera. More precisely, this concerns Invention of a medium telephoto lens system that is a large one Opening ratio and a comparatively wide Has perspective and where the focus is carried out by moving some lenses in the system.

The imaging lens system used in the latest models from SLR cameras used not only require a high level optical functionality, but also a large one Opening ratio and lightness and speed, with that can be focused.

High quality medium telephoto lens systems with large Opening ratio and a wide viewing angle are in the unexamined published Japanese Patent Applications No. 48 723/1984, 205 625/1988 and others described.

Because an increasing number of modern cameras with the Ability to be equipped with auto focus  Lens systems of the types "inner focus" and "Rear focus" has been developed to the Focus by moving only a few of the lenses to realize in the lens system. For example, in the unexamined published Japanese patent applications No. 1 54 111/1989 and 1 54 112/1989 an "interior Focus "model with a focusing lens group in a Gaussian lens system and in the unexamined published Japanese Patent application No. 78 208/1989 a "rear Focus "model in which the rear group has a Gaussian lens system is moved to focus.

However, if an "inner focus" system in one Telephoto lens with a large aperture ratio and a comparatively wide viewing angle is installed, increases the need to provide free space, which allows the focusing lens group to to move within the lens system, the total length of the lens. Furthermore, the lens diameter be increased to the necessary proportion of Allow marginal rays of light. This has the result. that the entire lens system becomes bulky.

In contrast, the "rear Focus "model in which the rear lens group is one Gaussian lens system is moved to focus, the advantage of a relatively compact structure, however it was on the other hand difficult to get a high quality system realize because of the movement of the Focus group significant aberration changes occur.

The present invention has been made to accomplish the foregoing  solve the problems of the prior art mentioned and it is the main object of the invention, an intermediate To create telephoto system with a large aperture, in which focusing by moving only the rear ones Lens group is performed that is compact and that nevertheless has a high functionality in that there are smaller portions of aberration changes than Has effects of the focusing process.

In order to achieve this object, the medium-sized, large-aperture telephoto system according to the present invention is composed of a front group G _F which, starting on the object side, has at least two collecting (positive) lens elements with a strongly convex surface directed towards the object and a diverging one (negative) lens element with a highly concave surface facing the image and having an overall refractive power, and a rear group G _R with a surface S _R1 which is closest to the object and which is convex towards the object, which has an overall collecting power wherein only the rear group G _{R is moved} along the optical axis to perform the focusing operation, this lens system fulfilling the following conditions:

0.5 <f / r _R1 <3.5 (1)

0.6 <f _R / F <1.1 (2)

It is
f: the focal length of the overall system;
f _R : the focal length of the rear group G _R : and
r _R1 : the radius of curvature of S _R1 or the surface of the rear group G _R that is closest to the object.

Preferably, the lens system also fulfills the following Condition:

0.7 <f _R / f <1.0 (2 ′)

In one embodiment of the present invention, the rear group G _R , beginning on the object side, comprises at least one collecting lens element, a diffusing lens L _Rn , in which the surface on the image side is concave towards the image, and at least one collecting lens element, the Lens system also meets the following conditions:

0.8 <f / r _R4 <3.0 (3)

It is
r _R4 : the radius of curvature of the image side surface of the diverging lens L _Rn .

Such a lens system can be in one Overall system movement type are used, in which the front and rear lens group together to Focus can be moved. An overall movement type is preferred for cameras other than autofocus cameras used.

The invention is based on Embodiments and with reference to the figures explained in which show:

Fig. 1, 3, 5, 7, 9 and 11 schematic sectional views of lens systems in Examples 1 to 6 of the present invention are constructed in accordance with invention;

Fig. 2, 4, 6, 8, 10 and 12 are graphs showing the aberration curves that are obtained with the lens systems of Examples 1 to 6, wherein (A) relates to the case in which the lens system is focused at infinity, and (B) the case for a magnification of 1/10;

FIG. 13 is a simple schematic view of the present invention showing the basic structure of the lens system; and

Fig. 14 is a simple schematic view showing the basic structure of a known Gaussian lens system.

Fig. 13 is a simple schematic view showing the basic structure of the lens system according to the present invention. The main feature of this system is that the surface S _R1 closest to the object from all surfaces of the rear group G _R that is moved to achieve focus is convex toward the object (this surface of the rear group that closest to the object is abbreviated as S _R1 ) _below .

In contrast, S _{R1 of} a conventional Gaussian lens system in which the rear group G _{R is moved} to focus is characterized in that it is concave toward the object as shown in FIG. 14. In other words, it is a constitutional property of the conventional Gaussian lens system to achieve good operability by eliminating the aberrations that arise in the front and rear lens groups, which are arranged in a symmetrical configuration. However, if the rear lens group is moved in the Gaussian system to achieve focusing, the symmetry of the front and rear lens groups will be disturbed, causing aberration changes. Specifically, as a result of the focusing movement of the rear lens group G _R , as shown in FIG. 14, the height at which an off-axis edge beam of light S _R1 intersects changes. In other words, the angle that the off-axis marginal ray makes to the direction perpendicular to S _R1 , which is concave towards the object, changes largely due to the movement of G _R , which causes substantial aberration changes. If the lens system is focused from infinity to a near distance, the off-axis beam causes an internal asymmetry error.

In the lens system according to the present invention, S _R1 is designed to be convex toward the object, so that, as shown in Fig. 13, the angle that an off-axis edge beam makes with the normal direction perpendicular to S _R1 is small is as shown in Fig. 13. Accordingly, even if the rear group G _{R is moved} to focus, with the resultant change in height at which the off-axis edge ray S _R1 intersects, the change in the angle that this ray has with the direction perpendicular to S _R1 is small enough to reduce the aberration changes that might occur as an effect of the focusing process.

Condition (1) shows the appropriate radius of curvature to be applied to S _R1 . If r _R1 or the radius of curvature of S _{R1 is} extremely small, the angle that an off-axis marginal ray forms with the line perpendicular to S _R1 changes greatly when the rear group G _{R is moved} to focus with the one that arises Changes in the height of the beam intersection and accordingly large aberration changes occur, even if S _{R1 is} convex towards the object. If the lens system is focused from infinity to a close distance, the off-axis beam generates an external asymmetry error (coma). Accordingly, from the point of view of aberration changes, r _{R1 must} not be reduced to such an extent that the upper limit of condition (1) is exceeded.

On the other hand, if r _R1 or the radius of curvature of S _{R1 is increased} so much that S _R1 becomes almost flat, the aberration changes that occur as a result of focusing can be reduced. However, as described by equation (2) or (2 ') as described below, the rear group G _{R is} required to have a sufficiently strong refractive power. If r _R1 alone is increased so that the necessary collecting refractive power is provided by the collecting surfaces other than S _R1 , the aberrations cannot be compensated for in a balanced manner and the possibility of negative spherical aberration occurring increases. Furthermore, the rear group itself must be compact to ensure the clearance required for the movement of the rear group G _R in the lens system to achieve the focus. Accordingly, S _R1 preferably has a strong collecting refractive power. Thus, from the standpoint of aberration compensation and the compact construction of the rear group G _R , R _r1 must not be increased so much that the lower limit of condition (1) cannot be reached.

The conditions (2) and (2 ') describe the requirements that must be met by the refractive power of the rear lens group G _R. Since the rear group G _{R is moved} in the lens system to achieve focusing, the lens system must be provided with the space required for the movement of the rear lens group G _R. If f _R or the focal length of the rear lens group G _{R is increased} so much that the upper limit of condition (2) or (2 ') is exceeded, the mechanical constraints of the limited space for movement make it impossible to get the closest distance from Downsize object. Furthermore, a bulky lens system results if a larger space is provided for the movement of the rear lens group G _R with the aim of reducing the closest distance from the object. Accordingly, from the point of view of the shortest distance of the object and the compactness of the entire lens system, f _R or the focal length of the rear group G _{R must} not be enlarged so much that the upper limit of condition (2) or (2 ') is exceeded.

Reducing f _R to such an extent that the lower limit of condition (2) or (2 ′) is not reached is preferable for the purpose of shortening the closest distance from the object and reducing the overall size of the lens system. However, a certain length of the focal distance from the back of the lens must be ensured in lens systems of the type proposed by the present invention, which are used in SLR cameras. Accordingly, to ensure the necessary focal distance from the back of the lens, the focal length of the rear group G _{R must} also be reasonably long. Accordingly, it is not desirable to reduce f _R to such an extent that the lower limit of condition (2) or (2 ') is not reached.

It is desirable that the rear group G _R combined with the front group G _{F have} a structure which satisfies the conditions (1) and (2) or (2 ') and which allows aberrations to be compensated for in an effective and balanced manner will. In order to meet these requirements, it is desirable for the purpose of the present invention that the rear group G _{R has} a triplet configuration or a modification of this structure and that it also fulfills condition (3) in order to achieve an even better functionality. Even if r _R1 fulfills condition (1), the converging refractive power has the effect of producing a negative spherical aberration. It is therefore necessary for the rear group G _{R to be provided} with a surface which compensates for the negative spherical aberration in order to maintain the high functionality of G _R. This need is expressed mathematically by condition (3). If r _{R is increased} to such an extent that the lower limit of this condition is not reached, the negative spherical aberration generated by S _R1 remains partially uncompensated. On the other hand, if r _R4 is reduced to such an extent that the upper limit of condition (3) is exceeded, higher-order spherical aberrations occur, which is also undesirable.

Examples

Examples 1 to 6 of the present invention are described below with reference to the data sheets in which:
f: the focal length of the overall system;
F _NO : the opening ratio or F number;
ω: half the viewing angle;
r: the radius of curvature of a single lens surface;
d: the thickness of a single lens or the spatial distance between adjacent lenses;
n: the refractive index of a single lens on the d line;
ν: the Abbe number of a single lens; and
f _B : the focal distance from the back of the lens.

example 1

Example 2

Example 3

Example 4

Example 5

Example 6

As described on the previous pages, the large aperture central telephoto lens system of the present invention, which is of the "rear focus" type in which only the rear group G _{R is moved} to perform focusing, is constructed so that both condition (1) as well as condition (2) and possibly condition (3) can be fulfilled. This ensures that the overall lens system is compact and has high functionality without undesirably large aberration changes occurring as a result of the focusing process. As can be seen from the accompanying FIGS. 2, 4, 6, 8, 10 and 12, the lens system works satisfactorily, regardless of whether it is at infinity (see in each of the figures under A) or at a close distance of the object (see under B ) is focused.

Claims (17)

1. Medium-sized telephoto lens system with a large aperture, which is composed of a front group G _F which, starting on the object side, comprises at least two collecting lens elements with a highly convex surface directed towards the object and a diverging lens element with a strongly concave surface directed towards the image, and which has an overall refractive power and a rear group G _R with a surface S _R1 which is closest to the object and which is convex toward the object, which has a total collecting power, only the rear group being moved along the optical axis, to perform the focusing operation, whereby the lens system fulfills the following condition: 0.5 <f / r _R1 <3.5 (1)
f: the focal length of the overall system; and
r _R1 : the radius of curvature of S _R1 or the surface of the rear group G _R that is closest to the object. 2. Lens system according to claim 1, characterized in that it further fulfills the following conditions: 0.6 <f _R / F <1.1 (2)
f _R : the focal length of the rear group G _R. 3. Lens system according to claim 2, characterized in that it further fulfills the following condition: 0.7 <f _R / f <1.0 (2 ') is there
f _R : the focal length of the rear group G _R. 4. Medium telephoto lens system with a large aperture, which is composed of a front group G _F which, starting on the object side, comprises at least two collecting lens elements with a highly convex surface directed towards the object and a diverging lens element with a strongly concave surface directed towards the image and which has an aggregate refractive power, and a rear group G _R with a surface S _R1 which is closest to the object and which is convex towards the object, which has an aggregate refractive power, the front group G _F and the rear group G _R are moved together to perform the focusing operation, the rear group comprising G _R , beginning on the object side, at least one collecting lens element, a diffusing lens L _Rn , in which the surface on the image side is concave towards the image, and at least one collecting lens element, the lens system the following n Conditions met: 0.5 <f / r _Rl <3.5 (1) 0.6 <f _R / F <1.1 (2) 0.8 <f / r _R4 <3.0 (3) is
f: the focal length of the overall system;
f _R : the focal length of the rear group G _R ; and
r _R1 : the radius of curvature of S _R1 or the surface of the rear group G _R which is closest to the object and
r _R4 : the radius of curvature of the image side surface of the diverging lens L _Rn . 5. Lens system according to claim 1, characterized in that the rear group comprises G _R , starting on the object side at least one collecting lens element, a diffusing lens L _Rn , in which the surface on the image side is concave towards the image, and at least one collecting Lens element, wherein the lens system further fulfills the following condition: 0.8 <f / r _R4 <3.0 (3)
r _R4 : the radius of curvature of the image side surface of the diverging lens L _Rn . 6. Lens system according to claim 5, characterized in that it fulfills the following table: there is:
f: the focal length of the overall system;
F _NO : the opening ratio of the F number;
ω: half the viewing angle;
r: the radius of curvature of a single lens surface;
d: the thickness of a single lens or the spatial distance between adjacent lenses;
n: the refractive index of a single lens on the d line;
ν: the Abbe number of a single lens; and
f _B : the focal distance from the back of the lens. 7. Lens system according to claim 5, characterized in that it further fulfills the following table: is there
f: the focal length of the overall system;
F _NO : the opening ratio of the F number;
ω: half the viewing angle;
r: the radius of curvature of a single lens surface;
d: the thickness of a single lens or the spatial distance between adjacent lenses;
n: the refractive index of a single lens on the d line;
ν: the Abbe number of a single lens; and
f _B : the focal distance from the back of the lens. 8. Lens system according to claim 5, characterized in that it further fulfills the following table: is there
f: the focal length of the overall system;
F _NO : the opening ratio of the F number;
ω: half the viewing angle;
r: the radius of curvature of a single lens surface;
d: the thickness of a single lens or the spatial distance between adjacent lenses;
n: the refractive index of a single lens on the d line;
ν: the Abbe number of a single lens; and
f _B : the focal distance from the back of the lens. 9. Lens system according to claim 5, characterized in that it further fulfills the following table: is there
f: the focal length of the overall system;
F _NO : the opening ratio of the F number;
ω: half the viewing angle;
r: the radius of curvature of a single lens surface;
d: the thickness of a single lens or the spatial distance between adjacent lenses;
n: the refractive index of a single lens on the d line;
ν: the Abbe number of a single lens; and
f _B : the focal distance from the back of the lens. 10. Lens system according to claim 5, characterized in that it further fulfills the following table: is there
f: the focal length of the overall system;
F _NO : the opening ratio of the F number;
ω: half the viewing angle;
r: the radius of curvature of a single lens surface;
d: the thickness of a single lens or the spatial distance between adjacent lenses;
n: the refractive index of a single lens on the d line;
ν: the Abbe number of a single lens; and
f _B : the focal distance from the back of the lens. 11. Lens system according to claim 5, characterized in that it further fulfills the following table: is there
f: the focal length of the overall system;
F _NO : the opening ratio of the F number;
ω: half the viewing angle;
r: the radius of curvature of a single lens surface;
d: the thickness of a single lens or the spatial distance between adjacent lenses;
n: the refractive index of a single lens on the d line;
ν: the Abbe number of a single lens; and
f _B : the focal distance from the back of the lens.