Zoom lens

Abstract

The invention relates to a compact zoom lens system which can be applied to a relatively large image pickup device and can maintain sufficient image-formation capability even at a wide-angle end of 70° or greater and a zoom ratio of about 10 or greater. The zoom lens system comprises a first lens group G1 having positive refracting power, a second lens group G2 having negative refracting power, a third lens group G3 having positive refracting power, a fourth lens group G4 having negative refracting power and a fifth lens group G5. During zooming from the wide-angle end to the telephoto end of the system, the lens groups G1 to G5 are all moving. The first lens group G1 and the third lens group G3 move toward the object side in the process of zooming in such a way that-the spacings between the first and second lens groups G1 and G2 and the third and fourth lens groups G3 and G4 become wide, and at least the fourth lens group G4 or the fifth lens group G5 moves nonlinearly, so that fluctuations of an image plane position with zooming can be compensated for. Conditions for defining the power profiles of the first to fifth lens groups G1 to G5 are satisfied.

Description

BACKGROUND OF THE INVENTION

The present invention relates generally to a zoom lens, and more particularly to a wide-angle yet high-magnification zoom lens system best suited for use on cameras, etc.

From relatively old times, high-magnification zoom lenses for use with cameras have been developed in TV camera and chine camera applications. On video cameras, on the other hand, innovation has been spurred for both commercial and consumer purposes since their widespread use. For a zoom lens having high magnification and a field angle of 70° or greater on its wide-angle side, a very high level of optical design is known to be required. one commonly used old type of zoom lens system comprises, in order from its object side, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power and a fourth lens group having positive refracting power, as typically shown in JP-B 2-48087. A great feature of this system is that both the first and fourth lens groups remain fixed during zooming.

There is a version stemming from this type, which is based on the concept of locating a front converter in the first lens group, as typically set forth in U.S. Pat. No. 3,682,534. This version is of large size due to an increased number of lenses, and is used in a focusing mode relying chiefly on the first lens group of the basic arrangement.

There is also proposed a wide-angle yet high-magnification zoom lens system comprising, from its object side, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power and a fourth lens group having positive refracting power, wherein the second to fourth lens groups are movable during zooming and focusing is carried out with the fourth lens group, as typically set forth in JP-A 6-148520. So far, this system has been used in video applications.

For instance, JP-A 9-5628 shows a zoom lens of the type comprising, in order from its object side, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having negative refracting power and a fourth lens group having positive refracting power. This type is one predecessor of the wide-angle yet high-magnification zoom lens system according to the present invention as will be described later. In this type, too, the same focusing mode as mentioned above is used.

For instance, JP-A 7-20381 shows a zoom lens of the type comprising, in order from its object side, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power and a fourth lens group having positive refracting power, wherein all the lens groups are movable during zooming.

The aforesaid zoom lens systems are found to have difficulty in accommodating to future image pick devices expected to increase in the number of pixels, although their lens arrangement is simple. In other words, these zoom lens systems have been originally developed for conventional silver salt film cameras. For instance, U.S. Pat. No. 4,299,454 shows a zoom lens system comprising, in order from its object side, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power and a fourth lens group having positive refracting power which are all movable for zooming, and having a field angle of 80° or greater at its wide-angle end.

JP-B 58-33531 has already showed a zoom lens system having a field angle of about 74° to about 19° and a zoom ratio of about 5 and comprising, in order from its object side, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power. A great feature of this system is that the first and second lens groups are moved as an integral unit for focusing.

U.S. Pat. No. 4,896,950 shows a zoom lens system encompassing a field angle range of about 74° to about 8.3°, and comprising, in order from its object side, a first lens group having positive refracting power, a second lens group negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, with the fifth lens group remaining fixed during zooming. Focusing is carried out with the second lens group having large power, as typically shown in JP-A 9-184982.

How to move the third lens group for focusing is typically disclosed in JP-A 10-133109, and the lens system disclosed therein is characterized by its large size and power profile. How to move back the fourth lens group for focusing is typically disclosed in JP-A 11-133303.

A high-magnification zoom lens system having a wide angle layout with its telephoto end including even a super-telephoto range such as one contemplated herein is susceptible to shakes during camera manipulation, which may otherwise cause a deterioration in image-formation capability. To this end, some compensation mechanism is needed. How to move an image in such a direction as to counteract an image movement on an image-formation plane due to shakes, etc. has been proposed in the prior art. For instance, JP-A 63-202714 shows a method of moving a part of image pickup lenses as a correction lens system in a direction vertical with respect to an optical axis which an optical system is assumed to have.

A primary purpose of the present invention is to develop a wide-angle yet high-magnification zoom lens system best suited for use on cameras, etc.

Some wide-angle yet high-magnification zoom lens systems have been proposed for conventional video cameras; however, never until now is any optical system having optical performance enough to fit for image pickup devices having more pixels than ever before proposed. In addition, much is still left to be desired in terms of the optical performance, and affinity for CCDs or the like, of silver salt cameras.

In view of an image pickup device having a microlens and influences of aliasing due to chromatic aberrations, etc., there is still growing demand for a zoom lens system, which is suitable for conventional video cameras and provides an optical system having a certain degree of telecentric nature. optical design based on a zoom lens for conventional video cameras makes a zoom lens system very large, and so offers a practically grave problem.

SUMMARY OF THE INVENTION

In view of such states of the prior art as explained above, one object of the present invention is to provide a zoom lens system of reduced size, which is applicable to a relatively large image pickup device and can keep sufficient image-formation capability even with a zoom ratio of about 10 or greater at a wide-angle end of 70° or greater.

Another object of the present invention is to provide a zoom lens system of reduced size, which can be operated in a proper focusing mode.

Yet another object of the present invention is to provide a zoom lens system of reduced size, which can compensate for the movement of an image by moving lens groups in a proper manner.

According to one aspect of the present invention, these objects are achievable by the provision of a zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, characterized in that:

for zooming from a wide-angle end to a telephoto end of said zoom lens system, a spacing between said first lens group and said second lens group and a spacing between said third lens group and said fourth lens group become wide and a spacing between said second lens group and said third lens group and a spacing between said fourth lens group and said fifth lens group become narrow, and

the following conditions are satisfied:

2.0 <f 1 /f w <8.0  (1)

0.4 <|f 2 /f w |<1.0  (2)

0.3 <f 3 /f T345 <1.2  (3)

0.6 <|f 4 |/f T345 <5.0  (4)

0.5 <f 5 /f T345 <4.0  (5)

where f w is the focal length of said zoom lens system at said wide-angle end, f 1 is the focal length of said first lens group, f 2 is the focal length of said second lens group, f 3 is the focal length of said third lens group, f 4 is the focal length of said fourth lens group, f 5 is the focal length of said fifth lens group, and f T345 is the focal length of said third lens group to said fifth lens group at said telephoto end.

According to another aspect of the present invention, there is provided a zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, characterized in that:

for zooming from a wide-angle end to a telephoto end of said zoom lens system, a spacing between said first lens group and said second lens group and a spacing between said third lens group and said fourth lens group become wide and a spacing between said second lens group and said third lens group and a spacing between said fourth lens group and said fifth lens group become narrow, and

said zoom lens system is focused on a finite object by moving said third lens group or a lens or lenses therein.

According to yet another aspect of the present invention, there is provided a zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, characterized in that:

for zooming from a wide-angle end to a telephoto end of said zoom lens system, a spacing between said first lens group and said second lens group and a spacing between said third lens group and said fourth lens group become wide and a spacing between said second lens group and said third lens group and a spacing between said fourth lens group and said fifth lens group become narrow, and

said zoom lens system is focused on a finite object by moving said fourth lens group or a lens or lenses therein.

According to a further aspect of the present invention, there is provided a zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, characterized in that:

for zooming from a wide-angle end to a telephoto end of said zoom lens system, a spacing between said first lens group and said second lens group and a spacing between said third lens group and said fourth lens group become wide and a spacing between said second lens group and said third lens group and a spacing between said fourth lens group and said fifth lens group become narrow, and

said zoom lens system is focused on a finite object by moving said fifth lens group or a lens or lenses therein.

According to a further aspect of the present invention, there is provided a zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, characterized in that:

for zooming from a wide-angle end to a telephoto end of said zoom lens system, each of said first lens group to said fifth lens group moves while said first lens group and said third lens group move toward said object side during said zooming in such a way that spacings between said first lens group and said second lens group and between said third lens group and said fourth lens group become wide,

a fluctuation of an image plane position with said zooming is compensated for by non-linear movement of at least said third lens group, said fourth lens group or said fifth lens group, and

the following conditions are are satisfied:

2.0 <f 1 /f w <8.0  (1)

0.4 <|f 2 /f w |<1.0  (2)

0.3 <f 3 /f T345 <1.2  (3)

0.6 <|f 4 |/f T345 <5.0  (4)

0.5 <f 5 /f T345 <4.0  (5)

where f w is the focal length of said zoom lens system at said wide-angle end, f 1 is the focal length of said first lens group, f 2 is the focal length of said second lens group, f 3 is the focal length of said third lens group, f 4 is the focal length of said fourth lens group, f 5 is the focal length of said fifth lens group, and f T345 is the focal length of said third lens group to said fifth lens group at said telephoto end.

Still other objects and advantages of the invention will in part be obvious and will in part be apparent from the specification.

The invention accordingly comprises the features of construction, combinations of elements, and arrangement of parts which will be exemplified in the construction hereinafter set forth, and the scope of the invention will be indicated in the claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is illustrative in section of Example 1 of the present zoom lens system at its wide-angle end (a), its intermediate setting (b) and its telephoto end (c).

FIG. 2 is illustrative in section of Example 2 of the present zoom lens system in similar states as in FIG. 1 .

FIG. 3 is illustrative in section of Example 3 of the present zoom lens system in similar states as in FIG. 1 .

FIG. 4 is illustrative in section of Example 4 of the present zoom lens system in similar states as in FIG. 1 .

FIG. 5 is illustrative in section of Example 5 of the present zoom lens system in similar states as in FIG. 1 .

FIG. 6 is illustrative in section of Example 6 of the present zoom lens system in similar states as in FIG. 1 .

FIG. 7 is illustrative in section of Example 7 of the present zoom lens system in similar states as in FIG. 1 .

FIG. 8 is illustrative in section of Example 8 of the present zoom lens system in similar states as in FIG. 1 .

FIG. 9 is illustrative in section of Example 9 of the present zoom lens system in similar states as in FIG. 1 .

FIG. 10 is illustrative in section of Example 10 of the present zoom lens system in similar states as in FIG. 1 .

FIG. 11 is illustrative in section of Example 11 of the present zoom lens system in similar states as in FIG. 1 .

FIG. 12 is illustrative in section of Example 12 of the present zoom lens system in similar states as in FIG. 1 .

FIG. 13 is illustrative in section of Example 13 of the present zoom lens system in similar states as in FIG. 1 .

FIG. 14 is illustrative in section of Example 14 of the present zoom lens system in similar states as in FIG. 1 .

FIG. 15 is illustrative in section of Example 15 of the present zoom lens system in similar states as in FIG. 1 .

FIG. 16 is illustrative in section of Example 16 of the present zoom lens system in similar states as in FIG. 1 .

FIG. 17 is illustrative in section of Example 17 of the present zoom lens system in similar states as in FIG. 1 .

FIG. 18 is an aberration diagram for Example 1 upon focused at infinity.

FIG. 19 is an aberration diagram for Example 2 upon focused at infinity.

FIG. 20 is an aberration diagram for Example 3 upon focused at infinity.

FIG. 21 is an aberration diagram for Example 4 upon focused at infinity.

FIG. 22 is an aberration diagram for Example 5 upon focused at infinity.

FIG. 23 is an aberration diagram for Example 6 upon focused at infinity.

FIG. 24 is an aberration diagram for Example 7 upon focused at infinity.

FIG. 25 is an aberration diagram for Example 8 upon focused at infinity.

FIG. 26 is an aberration diagram for Example 9 upon focused at infinity.

FIG. 27 is an aberration diagram for Example 10 upon focused at infinity.

FIG. 28 is an aberration diagram for Example 10 upon focused on a finite point (1.5 m).

FIG. 29 is an aberration diagram for Example 11 upon focused at infinity.

FIG. 30 is an aberration diagram for Example 11 upon focused on a finite point (1.5 m).

FIG. 31 is an aberration diagram for Example 12 upon focused at infinity.

FIG. 32 is an aberration diagram for Example 12 upon focused on a finite point (2.0 m).

FIG. 33 is an aberration diagram for Example 13 upon focused at infinity.

FIG. 34 is an aberration diagram for Example 13 upon focused on a finite point (2.0 m).

FIG. 35 is a front perspective view of the appearance of a digital camera.

FIG. 36 is a rear perspective view of the FIG. 35 digital camera.

FIG. 37 is a sectional view of the construction of a digital camera.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

An account is first given of why the aforesaid arrangements are used and how they act.

As mentioned above, the present invention provides a high-performance, wide-angle yet high-magnification zoom lens system of reduced size.

For silver salt film cameras, a zoom lens system comprising, in order from its object side, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power and a fourth lens group having positive refracting power has so far gone mainstream. In a high-magnification zoom lens system, it is common that the first to fifth lens groups are movable. For correction of a fluctuation of field curvature with zooming it is required to move the third and fourth lens groups. In an extreme case, these lens groups may possibly be thought of as one single unit. To achieve a larger wide angle with a higher zoom ratio, however, it is favorable to move one negative lens group added to the positive lens groups from the standpoints of correction of aberrations as well as zooming. This is particularly preferable for a zoom lens system having a zoom ratio of about 10 or greater such as one contemplated herein. According to a generally accepted idea, correction of chromatic aberrations must be carried out at each lens group with an increasing number of lens groups, and so the number of lenses in each lens increases unavoidably. According to the present invention, however, effective use is made of aspherical surfaces in such a way as to correct distortion at the second lens group and make correction for coma, etc. at the following lens groups.

The principal object of the present invention is to provide a zoom lens optical system which can well accommodate to a field angle of about 70° or greater at its wide-angle end and has high image-formation capability. For this reason, the optical system is constructed of, in order from an object side thereof, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, wherein the proper power profile conforming to the aforesaid conditions (1) to (5) is provided together with the lens arrangement best suited therefor. According to the present invention, size and performance problems, as is often the case with a wide-angle yet high-magnification zoom lens system, can be solved.

Condition (1) gives a definition of the power profile of the first lens group. For the first lens group designed to move during zooming according to the zooming mode of the present invention, it is of importance to maintain image-formation capability while care is taken of the amount of its movement and an increase in the diameter of the front lens.

Exceeding the upper limit of 8.0 to condition (1) may be preferable for correction of aberrations because of a decrease in the amount of aberrations remaining in the first lens group. However, this is not desirable because the amount of zooming movement and diameter of the first lens group increase, and so the whole size of the first lens group tends to increase. When the lower limit of 2.0 is not reached, some size reductions may be achieved because the diameter and amount of movement of the first lens group tend to decrease. However, this is not preferable in view of correction of aberrations.

Condition (2) gives a definition of the power profile of the second lens group having negative refracting power. The second lens group also takes part in the determination of the power of the first lens group. In other words, the power of the first lens group decreases with a decrease in the power of the second lens group, again resulting unavoidably in size increases.

Exceeding the upper limit of 1.0 to condition (2) may possibly be preferable in view of the number of lenses and correction of aberrations as well. However, this offers many other problems, e.g., decreases in the power of the second lens group as well as the power of the first lens group, an increase in the diameter of the front lens in the first lens group, and an increase in the amount of zooming movement. When the lower limit of 0.4 is not re ached, on the other hand, it is difficult to make correction for aberrations although the diameter of the lens arrangement may be reduced. In particular, considerable distortion and off-axis coma occur. Within the range defined by this condition, it is also possible to achieve an appropriate lens arrangement, thereby reducing the diameter of the lens arrangement and obtaining high image-formation capability.

Condition (3) is provided to determine the power of the third lens group. In t he zoom lens system contemplated herein, the third, fourth and fifth lens groups define an image-formation unit. From the viewpoint of how to zoom, this unit may be thought of as comprising three independent groups. This zooming mode is quite different from many conventional zooming modes relying on the third lens group having positive refracting power and the fourth lens group having positive refracting power. In the present invention, the third lens group plays one role of converging a light beam from the second lens group having strongly divergent power, thereby making correction for spherical aberrations and off-axis aberrations, and another role of making satisfactory correction for longitudinal spherical aberration.

Exceeding the upper limit of 1.2 to condition (3) is not preferable because of an increase in the amount of zooming movement of the third lens group, al though this is very favorable for correction of aberrations at the third lens group. Falling below the lower limit of 0.3 may possibly be favorable for size reductions because of a decrease in the amount of zooming movement. Still, this incurs undesired results because of difficulty in making correction for not only spherical aberrations but also off-axis coma.

Condition (4) is provided to determine the power of the fourth lens group having negative refracting power. When the upper limit of 5.0 to condition (4) is exceeded, the amount of movement of the fourth lens group between the third lens group and the fifth lens group increases, making it difficult to obtain a high zoom ratio. When the lower limit of 0.6 is not reached, the amount of zooming movement decreases. Still, this is not desired from the viewpoint of correction of aberrations; it is difficult to make correction for the aberrations. It is here noted that a substantially afocal light beam is obtained at the first to fourth lens groups, especially in the vicinity of the wide-angle end.

Condition (5) is provided to determine the power of the fifth lens group that plays an important role in controlling the principal ray of an off-axis light beam. Especially when used with a CCD image pickup device or the like, the fifth lens group plays a great role in imparting a certain degree of telecentric nature to the off-axis principal ray. Exceeding the upper limit of 4.0 to this condition is not preferable because of an increase in the amount of zooming movement of the fifth lens group, although aberrations at the fifth lens group may easily be corrected. When the lower limit of 0.5 is not reached, it is difficult to make correction for off-axis aberrations and, at the same time, it is difficult to make correction for aberrations without using an increased number of lenses. In addition, this lens group, if it increases in the number of lenses, often leads to an increase in the size of the zoom lens system, and so makes it impossible to obtain any desired results.

One purport of the present invention is to provide a zoom lens system which is reduced in size by simplifying its lens arrangement as much as possible. In this case, the refracting power profile of each lens group is of importance. This refracting power profile correlates with not only the lens arrangement of each lens group but also the amount of zooming movement of each lens group.

Another purport of the present invention is to provide an optical system which encompasses a field angle of about 70° or greater at its wide-angle end albeit having high magnification, and is simpler in construction than those according to prior inventions.

In the parlance of focal length, it is desired that the focal length of the zoom lens system at its wide-angle end be shorter than the effective diagonal length of its image-formation plane or an image pickup device.

According to the present invention, an optical system wherein a certain degree of telecentric nature can be maintained irrespective of a longer effective diagonal length than ever before is provided while chromatic problems such as aliasing and shading on the image-formation plane are taken in consideration on the assumption that CCDs are used as image pickup devices, as will be understood from the examples given later.

In other words, it is desired that the principal ray emerging from the optical system be determined on the basis of the following condition:

10 <|expdw x Y|/Lw   (6)

Here Expdw is the optical axis distance from an image-formation plane position to an exit pupil, Y is an actual maximum image height on an image-formation plane, and Lw is an optical axis distance at the wide-angle end from an apex of a surface located nearest to the object side in the first lens group to the image-formation plane.

If this condition is satisfied, it is then possible to meet a condition that enables a clear image to be obtained.

It is also desired that the following conditions be satisfied upon zooming from the wide-angle end to the telephoto end:

1.6 <Δ 1T /f w <5.0  (7)

1.0 <Δ 3 T/f w <4.0  (8)

Here Δ 1T is the amount of zooming movement of the first lens group to the telephoto end, as measured on the basis of the wide angle end, and Δ 3T is the amount of zooming movement of the third lens group to the telephoto end, as measured on the basis of the wide-angle end.

Condition (7) is provided to control the amount of zooming movement of the first lens group from the wide-angle end to the telephoto end, and condition (8) is provided to control the amount of zooming movement of the third lens group from the wide-angle end to the telephoto end.

Condition (7) is to gain proper control of the amount of zooming movement of the first lens group, thereby achieving significant size reductions. When the upper limit of 5.0 to condition (7) is exceeded, it is difficult to reduce the size of the zoom lens system including a lens barrel structure because even when the overall length of the zoom lens system is short at the wide-angle end, the amount of movement of the first lens group to the telephoto end increases. Falling below the lower limit of 1.6 is not desired because the amount of movement of the first lens group becomes too small to obtain any desired high zoom ratio.

Exceeding the upper limit of 4.0 to condition (8) is not desired because the amount of movement of the third lens group increases, resulting in size increases. At a value less than the lower limit of 1.0, the present zooming mode cannot be used; other zooming modes may be used.

The image-formation magnification is now explained. The features of the zoom lens system according to the invention are that the first to fifth lens groups are all moving during zooming. When these lens groups move from the wide-angle end to the telephoto end, the second lens group have a great zooming action, as can be seen from the following condition. The second lens group itself may also be fixed during zooming.

To be more specific, the second lens group should preferably have a paraxial transverse magnification capable of satisfying the following relation:

2.5<β 2T /β 2W <7  (9)

Here β 2W is the image-formation magnification of the second lens group at the wide-angle end, and β 2T is the image-formation magnification of the second lens group at the telephoto end.

Given the paraxial arrangement determined by the aforesaid condition, it is then possible to determine a thick lens arrangement. First of all, it desired that the first lens group be made up of at least one negative lens and a positive lens.

According to the present invention, the first lens group is basically made up of a set of cemented lens or air-spaced doublet, to which one positive lens is added. Where the telephoto end is set in the telephoto range of the high-magnification zoom lens, it is preferable to use glass having anomalous dispersion because of ease of accommodation to an image pickup device having much more pixels than ever before.

It is desired that the second lens group be made up of at least two negative lenses and one positive lens.

According to the present invention, it is intended to achieve significant size reductions by increasing the power of the second lens group, as can be seen from condition (2). It is thus desired that the second lens group be made up of, in order from its object side, a negative meniscus lens, a double-concave negative lens, a positive lens and a negative lens.

According to the characteristic lens arrangement of the present invention, the constructions of the third and fourth lens groups are simplified to significantly reduce the size of the zoom lens system. That is, the third lens group may be constructed of one positive lens; the simpler the lens arrangement, the more favorably significant size reductions are achieved. It is here understood that the lens arrangement becomes more complicated with increasing magnification. The third lens group having positive refracting power should be a positive lens if it is composed of one lens. When an aperture stop is located adjacent to the third lens group, a deeper significance is attached to correction of axial aberrations rather than off-axis aberrations. Spherical aberrations are susceptible to undercorrection only by use of one positive lens. To correct them, it is effective to use one or two aspherical surfaces on the positive lens. It is here important to understand the fact that the action of the aspherical surface varies depending on the balance of correction of aberrations rather than to define the shape thereof, because the aspherical surface is regarded as one element of the zoom lens system. If, in this case, importance is placed on correction of longitudinal spherical aberration, the aspherical surface should then be designed in such a way that the power of the lens decreases gradually from its center to its periphery. In some cases, the aspherical surface may have a point of inflection although depending on the balance of off-axis aberrations. Alternatively, the third lens group may be made up of two positive lenses or a cemented lens.

The fourth lens group is constructed of one negative lens. Since the fourth lens group is a negative group, it is desired to use a single lens therein if size reductions are intended. This lens plays a particularly important role in correction of off-axis aberrations rather than in zooming. This will be apparent from in what state light rays pass through the lens system. Alternatively, the fourth lens group may be made up of one negative lens and a negative lens having extremely limited power.

It is desired that the fifth lens group be made up of at least one positive lens and one negative lens.

It is also desired that the fifth lens group be made up of a cemented lens or air-spaced doublet consisting of at least one positive lens and a negative lens.

Preferably, at least one aspherical surface should be used in the second lens group.

By using at least one aspherical surface in the second lens group, distortion and coma can be easily corrected. It is particularly preferable to use the aspherical surface at the first surface of the negative meniscus lens because the balance between distortion and coma can be corrected in a relatively easy manner.

Preferably, at least one aspherical surface should be used in the third lens group.

When at least one aspherical surface is used in the third lens group, spherical aberrations can be very easily corrected.

Preferably, at least one aspherical surface should be used in the fourth lens group.

If at least one aspherical surface is used in the fourth lens group, it is then possible to make correction for delicate field curvature.

Preferably, at least one aspherical surface should be used in the fifth lens group.

If at least one aspherical surface is used in the fifth lens group, it is then possible to achieve an optical system wherein the quantity of ambient light is maintained while a certain degree of telecentric nature is kept.

In the present invention, the first to fifth lens groups are all moving during zooming. The first and third lens groups move toward the object side in the process of zooming from the wide-angle end to the telephoto end. At least the fourth lens group or the fifth lens group is so designed to move nonlinearly that fluctuations of an image plane position with zooming can be compensated for.

In the present invention, the first and third lens groups move almost linearly for zooming. Referring here to the magnification of other lens groups except for the fourth lens group, the absolute value of the magnification increases in the direction of a doubling, generally in terms of movement from the wide-angle end to the telephoto end. This in turn makes more efficient zooming possible.

Focusing is now explained. In view of size, fluctuations of aberrations, etc., it is not practical to apply to a wide-angle yet high-magnification zoom lens system such as one contemplated herein a first lens group-moving focusing mode used for past zoom lenses. In other words, it is preferable to rely on a focusing mode wherein both the first lens group and the second lens group are moved. In view of the fluctuations of aberrations, it is acceptable to move the second lens group or the like for close-up purposes. Focusing may also be carried out by the movement of at least one lens group located in the rear of the third lens group.

According to the first embodiment of the present invention, there is provided a zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, characterized in that:

for zooming from a wide-angle end to a telephoto end of said zoom lens system, a spacing between said first lens group and said second lens group and a spacing between said third lens group and said fourth lens group become wide and a spacing between said second lens group and said third lens group and a spacing between said fourth lens group and said fifth lens group become narrow, and

said zoom lens system is focused on a finite object by moving said third lens group or a lens or lenses therein.

In this focusing mode wherein the third lens group is moved, the paraxial layout of the focusing group changes depending on the zooming position, and varies in the amount of focusing with respect to the same distance. In the third lens group having positive refracting power, both the third-order spherical aberration coefficient and the third-order astigmatism coefficient are under, and so fluctuations of aberrations at each lens group with focusing on a finite object correlate substantially with changes in the aberration coefficients. For instance, when the third lens group in the present invention is focused from infinity on a 1.5 m point, such third-order aberration coefficients as set out below are obtained with respect to the lens groups of Example 10 given later.

OBJECT AT INFINITY
Lens Group	SA3	CM3	AS3	DT3	PZ3
G1	−0.1397	0.6038	−0.3400	0.6179	−0.04904
G2	0.2336	−0.1638	0.3705	−0.3128	0.2480
G3	−0.2532	−0.8800	−0.2133	−0.0434	−0.1390
G4	0.0764	0.2352	0.1973	0.3777	0.0697
G5	0.0357	0.2906	0.0031	−0.3438	−0.1419
Σ	−0.0472	0.0858	0.0175	0.2956	−0.01226
	Lens Group	PAC	PLC
	G1	−0.0424	0.03902
	G2	0.0771	−0.0706
	G3	−0.1909	−0.0106
	G4	0.1400	0.0993
	G5	0.0069	−0.0240
	Σ	−0.0093	0.0333
1.5 m
Lens Group	SA3	CM3	AS3	DT3	PZ3
G1	−0.0379	0.2277	−0.2165	0.7106	−0.0466
G2	0.1120	0.1272	0.3001	−0.3842	0.2355
G3	−0.2032	−0.8444	−0.2697	−0.1496	−0.1320
G4	0.0654	0.2185	0.1921	0.3984	0.0662
G5	0.03062	0.2651	0.0087	−0.3476	−0.1348
Σ	−0.0330	−0.0059	0.0146	0.2276	−0.0116
	Lens Group	PAC	PLC
	G1	−0.0232	0.0345
	G2	0.0424	−0.0620
	G3	−0.1762	−0.0326
	G4	0.1329	0.1037
	G5	0.0065	−0.0237
	Σ	−0.0176	0.0199

Here SA3, CM3, AS3, DT3, PZ3, PAC, and PLC represent the spherical aberration coefficient, coma coefficient, astigmatism coefficient, distortion coefficient, field curvature coefficient, chromatic-aberration-of-magnification coefficient, and longitudinal chromatic aberration coefficient, respectively.

In this embodiment of the present invention, the fluctuations of aberrations with focusing are greatly stabilized even when the third lens group is composed of a single lens.

The above aberration coefficients imply that the change in performance during focusing is as a whole reduced, although there is a slightly large fluctuation of chromatic aberrations due to the fact that the focusing lens group is composed of a single lens.

According to this first embodiment, it is possible to provide not only a simple high-magnification zoom lens system but also a wide-angle yet high-magnification zoom lens system having a field angle of 70° or greater. It is thus possible to achieve a proper zooming mode together with a suitable power profile and a proper lens arrangement as well as effective use of aspherical surfaces.

According to the second embodiment of the present invention, there is provided a zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, characterized in that:

for zooming from a wide-angle end to a telephoto end of said zoom lens system, a spacing between said first lens group and said second lens group and a spacing between said third lens group and said fourth lens group become wide and a spacing between said second lens group and said third lens group and a spacing between said fourth lens group and said fifth lens group become narrow, and

said zoom lens system is focused on a finite object by moving said fourth lens group or a lens or lenses therein.

For instance, when the fourth lens group in this embodiment is focused from infinity on a 2.0 m point, such third-order aberration coefficients as set out below are obtained with respect to the lens groups of Example 13 given later.

OBJECT AT INFINITY
Lens Group	SA3	CM3	AS3	DT3	PZ3
G1	−0.1240	0.5024	−0.2849	0.5325	−0.0495
G2	0.4562	−0.2930	0.3107	−0.3128	0.2334
G3	−0.8298	−1.0553	−0.2102	−0.0322	−0.1382
G4	0.7088	1.9160	0.8415	1.2460	0.1546
G5	−0.2163	−0.9878	−0.6405	−1.2929	−0.2128
−0.0050	0.0823	0.0166	0.1406	−0.0126
	Lens Group	PAC	PLC
	G1	−0.0278	0.0227
	G2	0.0325	−0.0865
	G3	−0.1913	−0.0081
	G4	0.2890	0.2218
	G5	−0.1059	−0.1036
	Σ	−0.0035	0.0464
2.0
Lens Group	SA3	CM3	AS3	DT3	PZ3
G1	−0.0699	0.3286	−0.2542	0.6878	−0.0587
G2	0.3550	−0.0786	0.3210	−0.4226	0.2766
G3	−0.8092	−1.2274	−0.2547	−0.0451	−0.1638
G4	0.8766	2.6300	1.1624	1.6708	0.1832
G5	−0.3601	−1.5939	−0.9490	−1.8293	−0.2522
Σ	−0.0075	0.0587	0.0255	0.0615	−0.0149
	Lens Group	PAC	PLC
	G1	−0.0195	0.0212
	G2	0.0126	−0.0797
	G3	−0.1621	−0.0079
	G4	0.2902	0.2250
	G5	−0.1255	−0.1275
	Σ	−0.0042	0.0311

Set out in the above tables are the third-order aberration coefficients for Example 13 at its telephoto end at infinity and a finite point (2.0 m) when focusing is carried out by the movement of the fourth lens group. In this focusing mode, the fourth lens group is moved out, as mentioned just above. The movement of the fourth lens group produces a large benefit since the fourth and fifth lens groups are close to each other at the telephoto end. With this embodiment of the present invention, a very favorable focusing mechanism is achieved because the fourth lens group is composed of a single lens. The fluctuations of the third-order aberration coefficients with focusing are in such a direction as to reduce pin-cushion distortion at a finite distance. The fluctuations of aberrations are also very limited. In addition, the fluctuations of aberrations must be evaluated because there is actually some margin in the axial spacing between the third lens group and the fourth lens group. With this focusing mode, however, the near-by distance can be reduced.

For the focusing mode using a single lens, however, it is necessary to make evaluation of actual aberrations because the chromatic aberration of magnification actually includes higher-order components. To make better correction of the chromatic aberration of magnification, indeed, it is preferable to correct chromatic aberrations in the fourth lens group and construct the fourth lens group of a cemented lens, a doublet having an air space or the like.

According to the third embodiment of the present invention, there is provided a zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, characterized in that:

for zooming from a wide-angle end to a telephoto end of said zoom lens system, a spacing between said first lens group and said second lens group and a spacing between said third lens group and said fourth lens group become wide and a spacing between said second lens group and said third lens group and a spacing between said fourth lens group and said fifth lens group become narrow, and

said zoom lens system is focused on a finite object by moving said fifth lens group or a lens or lenses therein.

For instance, when the fifth lens group in this embodiment is focused from infinity on a 2.0 m point, such third-order aberration coefficients as set out below are obtained.

OBJECT AT INFINITY
Lens Group	SA3	CM3	AS3	DT3	PZ3
G1	−0.0995	0.4560	−0.2811	0.5593	−0.0461
G2	0.2809	−0.2434	0.2636	−0.2942	0.2226
G3	−0.5379	−1.0011	−0.2182	−0.0392	−0.1444
G4	0.4549	1.3168	0.6370	0.9433	0.1365
G5	−0.1193	−0.4822	−0.3941	−0.9673	−0.1812
Σ	−0.0209	0.0462	0.0082	0.2019	−0.0126
	Lens Group	PAC	PLC
	G1	−0.0362	0.0344
	G2	0.0636	−0.0910
	G3	−0.2321	−0.0118
	G4	0.2342	0.1634
	G5	−0.0428	−0.0616
	Σ	−0.0132	0.0334
2.0 m
Lens Group	SA3	CM3	AS3	DT3	PZ3
G1	−0.0522	0.2881	−0.2525	0.7518	−0.0559
G2	0.2070	−0.0721	0.2774	−0.4170	0.2697
G3	−0.5439	−1.1729	−0.2713	−0.0577	−0.1749
G4	0.5360	1.8997	0.9671	1.5058	0.1655
G5	−0.1851	−0.9374	−0.7176	−1.7262	−0.2196
Σ	−0.0381	0.0055	0.0031	0.0567	−0.0152
	Lens Group	PAC	PLC
	G1	−0.0242	0.0315
	G2	0.0375	−0.0832
	G3	−0.1922	−0.0116
	G4	0.2202	0.1752
	G5	−0.0528	−0.0720
	Σ	−0.0114	0.03882

The aforesaid tables show the case where focusing is carried out by moving the fifth lens group. However, this focusing mode, when carried out by the fifth lens group alone, is not suitable for a long exit pupil distance. In this case, the fifth lens group is divided into two subgroups. During zooming, these subgroups are floating with respect to each other, so that actual correction of aberrations can be more effectively made at each zooming position. In this embodiment, some fluctuations of spherical aberrations are found, and the third-order spherical aberration coefficients and coma coefficients are slightly larger as compared with the former two embodiments. However, if these subgroups are made up of a cemented lens, chromatic aberrations can then be corrected at the fifth lens group itself, and so no significant problem arises.

The mechanism for compensating for an image movement by camera shake or movement is now explained.

According to the present invention, the displacement of the image-formation point of the zoom lens system may be compensated for by moving the second lens group in a direction almost vertical to the optical axis, moving the third lens group in a direction almost vertical to the optical axis, moving the fourth lens group in a direction almost vertical to the optical axis, or moving the fifth lens group in a direction almost vertical to the optical axis.

In any case, the magnification of each moving lens group varies at each zooming point with a variation in the amount of vertical movement of each lens group with respect to the optical axis for the purpose of compensating for an image movement on an image-formation plane. It is here understood that for control of movement of each lens group, that movement should preferably be as simple as possible. There is also proposed a method for compensating for the image movement by providing an additional lens element to the zoom lens system. However, this method is not preferred because the size of the optical system becomes large. In the examples given later, the third or fourth lens group is composed of a single lens, so that the amount of aberrations remaining in the lens group can be further reduced, thereby inhibiting fluctuations of aberrations with the movement of the lens group. When chromatic aberrations out of off-axis aberrations should be corrected as much as possible, it is often desired to make correction for aberrations with a plurality of lens groups.

In the present invention, the second lens group has large power and high image-formation magnification. Accordingly, when the image moves on the image plane by camera movement or the like, the amount of shifting of the second lens group to compensate for this becomes small. On the other hand, the fourth lens group has large power and relatively low magnification. In this case, the amount of shifting of the lens group becomes large. In consideration of image-formation magnification, the longer the focal length, the larger the amount of image movement on the telephoto side becomes even at the same amount of camera movement, resulting in an increase in the amount of shifting.

In the examples given later, when the whole camera shakes with the zoom lens system, a specific lens group is allowed to move in a direction almost vertical with respect to the optical axis, thereby compensating for the resulting image deterioration. It is here noted that the amount of this compensation should be properly preset. Care must be taken to be sure that this amount does not exceed the required amount, because the image-formation capability in the standard state may otherwise become low. In most of the examples given later, the amount of shifting with respect to camera movement assumed to be about 0.5° is referred to.

In the zoom lens system of the present invention, too, it is desired to satisfy the aforesaid conditions (1) to (9).

Examples 1 to 17 of the zoom lens system according to the present invention are now explained. FIGS. 1 to 17 are illustrative in section of the lens arrangements of Examples 1 to 17 at their wide-angle ends (a), intermediate settings (b) and telephoto ends (c). Numerical data on each example will be set out later.

EXAMPLE 1

Example 1 is directed to a wide-angle zoom lens system having a focal length of 14.36 to 140.5 mm and an F-number of 3.85 to 4.53. For zooming from the wide-angle end to the telephoto end of the system, the first lens group G 1 moves toward the object side of the system, as shown in FIG. 1 . The second lens group G 2 moves slightly. The third lens group G 3 moves together with an aperture stop toward the object side. The fourth lens group G 4 moves back toward the image side of the system with respect to the wide-angle end position. The fifth lens group G 5 moves nonlinearly, unlike that of a conventional zoom lens system for silver salt film cameras.

The first lens group G 1 is made up of a cemented lens consisting of a negative meniscus lens having a strong curvature on an image side thereof and a double-convex lens having a strong curvature on an object side thereof, and a positive meniscus lens having a strong curvature on an object side thereof. No aspherical surface is used in the first lens group G 1 . The second lens group G 2 is made up of a negative meniscus lens having a very strong curvature on an image side thereof rather than on an object side thereof, a double-concave lens, a slight air lens, a double-convex lens and a double-concave lens. The third lens group G 3 is made up of an aperture stop and a double-convex lens contiguous thereto. The fourth lens group G 4 is made up of a cemented lens consisting of two negative lenses; one being a negative meniscus lens having a strong curvature on an object side thereof and another being a double-concave lens. The fifth lens group G 5 is made up of a cemented lens consisting of a double-convex lens and a negative meniscus lens and a double-convex lens.

By use of two aspherical surfaces, one at the first surface of the first lens in the second lens group G 2 and another at the object-side surface of the second lens therein, correction of distortion can be well balanced with respect to correction of coma. The use of such aspherical surfaces produces a marked effect especially because the wider the wide-angle arrangement of the system, the more difficult it is to correct distortion. An aspherical surface used at the object-side surface of the double-convex lens in the third lens group G 3 enables spherical aberrations to be well corrected. Aspherical surfaces used at both surfaces of the double-convex lens located nearest to the image side in the fifth lens group G 5 produce an effect so marked that off-axis aberrations can be corrected while a telecentric nature is imparted to the system. Upon zooming from the wide-angle end to the telephoto end, the first lens group G 1 and the third lens group G 3 move almost linearly toward the object side. The second lens group G 2 , too, moves toward the object side although its amount of movement is small. On the other hand, the fourth lens group G 4 and the fifth lens group G 5 move nonlinearly.

EXAMPLE 2

Example 2 is directed to a wide-angle zoom lens system having a focal length of 14.36 to 140.5 mm and an F-number of 3.58 to 4.63. The specification is much the same as in Example 1 except that the fourth lens group G 4 is made up of a single lens. For zooming from the wide-angle end to the telephoto end of the system, the first lens group G 1 moves toward the object side of the system, as shown in FIG. 2 . The second lens group G 2 moves slightly. The third lens group G 3 moves together with an aperture stop toward the object side. The fourth lens group G 4 moves back toward the image side of the system with respect to the wide-angle end position. The fifth lens group G 5 moves nonlinearly.

The first lens group G 1 is made up of a cemented lens consisting of a negative meniscus lens having a strong curvature on an image side thereof and a double-convex lens having a strong curvature on an object side thereof, and a positive meniscus lens having a strong curvature on an object side thereof. No aspherical surface is used in the first lens group G 1 . The second lens group G 2 is made up of a negative meniscus lens having a very strong curvature on an image side thereof rather than on an object side thereof, a double-concave lens, a slight air lens, a double-convex lens and a double-concave lens. The third lens group G 3 is made up of an aperture stop and a double-convex lens contiguous thereto. The fourth lens group G 4 is made up of one double-concave lens. The fifth lens group G 5 is made up of a cemented lens consisting of a double-convex lens and a negative meniscus lens and a double-convex lens.

Five aspherical surfaces are used; one at the first surface of the first lens in the second lens group G 2 , one at the object-side surface of the second lens in the second lens group G 2 , one at the object-side surface of the double-convex lens in the third lens group G 3 , and two at both surfaces of the double-convex lens located nearest to the image side in the fifth lens group G 5 .

Upon zooming from the wide-angle end to the telephoto end, the first lens group G 1 and the third lens group G 3 move almost linearly toward the object side. The second lens group G 2 , too, moves toward the object side although its amount of movement is small. On the other hand, the fourth lens group G 4 and the fifth lens group G 5 move nonlinearly.

The zoom lens system according to Example 1, and Example 2 has a field angle of 70° or greater at the wide-angle end and a zoom ratio of about 10 while a certain telecentric nature is imparted thereto. The potential image-formation capability of these systems is very excellent. If the focal length on the telephoto end side is increased, the zoom ratio can then be enlarged with relative ease.

EXAMPLE 3

Example 3 is directed to a wide-angle zoom lens system having a focal length of 14.36 to 140.5 mm and an F-number of 3.67 to 4.4. For zooming from the wide-angle end to the telephoto end of the system, the first lens group G 1 moves toward the object side of the system, as shown in FIG. 3 . The second lens group G 2 moves slightly. The third lens group G 3 moves together with an aperture stop toward the object side. The fourth lens group G 4 moves back toward the image side of the system with respect to the wide-angle end position. Th e fifth lens group G 5 moves nonlinearly. In the instant example, the third and fourth lenses in the second lens group G 2 are defined by a double-convex lens and a double-concave lens, respectively, which are cemented together

The first lens group G 1 is made up of a cemented lens consisting of a negative meniscus lens having a strong curvature on an image side thereof and a double-convex lens having a strong curvature on an object side thereof, and a positive meniscus lens having a strong curvature on an object side thereof. No aspherical surface is used in the first lens group G 1 . The second lens group G 2 is made up of a double-concave lens having a very strong curvature on an image side thereof, a double-concave lens, a slight air lens, and a cemented lens consisting of a double-convex lens and a double-concave lens. The third lens group G 3 is made up of an aperture stop and a double-convex lens contiguous thereto. The fourth lens group G 4 is made up of one double-concave lens. The fifth lens group G 5 is made up of a cemented lens consisting of a double-convex lens and a negative meniscus lens and a double-convex lens.

Five aspherical surfaces are used; one at the first surface of the first lens in the second lens group G 2 , one at the object-side surface of the second lens in the second lens group G 2 , one at the object-side surface of the double-convex lens in the third lens group G 3 , and two at both surfaces of the double-convex lens located nearest to the image side in the fifth lens group G 5 .

Upon zooming from the wide-angle end to the telephoto end, the first lens group G 1 and the third lens group G 3 move almost linearly toward the object side. The second lens group G 2 , too, moves toward the object side although its amount of movement is small. On the other hand, the fourth lens group G 4 and the fifth lens group G 5 move nonlinearly.

EXAMPLE 4

Example 4 is directed to a wide-angle zoom lens system having a focal length of 14.36 to 140.5 mm and an F-number of 3.66 to 4.42. This example is constructed as in Example 3. For zooming from the wide-angle end to the telephoto end of the system, the first lens group G 1 moves toward the object side of the system, as shown in FIG. 4 . The second lens group G 2 moves slightly. The third lens group G 3 moves together with an aperture stop toward the object side. The fourth lens group G 4 moves back toward the image side of the system with respect to the wide-angle end position. The fifth lens group G 5 moves nonlinearly.

The first lens group G 1 is made up of a cemented lens consisting of a negative meniscus lens having a strong curvature on an image side thereof and a double-convex lens having a strong curvature on an object side thereof, and a positive meniscus lens having a strong curvature on an object side thereof. No aspherical surface is used in the first lens group G 1 . The second lens group G 2 is made up of a double-concave lens having a very strong curvature on an image side thereof, a double-concave lens, a slight air lens, and a cemented lens consisting of a double-convex lens and a double-concave lens. The third lens group G 3 is made up of an aperture stop and a double-convex lens contiguous thereto. The fourth lens group G 4 is made up of one double-concave lens. The fifth lens group G 5 is made up of a cemented lens consisting of a double-convex lens and a negative meniscus lens and a double-convex lens.

Five aspherical surfaces are used; one at the first surface of the first lens in the second lens group G 2 , one at the object-side surface of the second lens in the second lens group G 2 , one at the object-side surface of the double-convex lens in the third lens group G 3 , and two at both surfaces of the double-convex lens located nearest to the image side in the fifth lens group G 5 .

Upon zooming from the wide-angle end to the telephoto end, the first lens group G 1 and the third lens group G 3 move almost linearly toward the object side. The second lens group G 2 , too, moves toward the object side although its amount of movement is small. On the other hand, the fourth lens group G 4 and the fifth lens group G 5 move nonlinearly.

In Examples 3 and 4, the zooming movements of the respective lens groups are relatively limited. By the provision of the cemented lens in the second lens group G 2 , it is possible to reduce an error in the fabrication and assembly of the air lens. On the other hand, the degree of freedom in Petzval sum control may rather decrease, resulting often in an increase in the thickness of the double-convex lens. The air lens between the second lens and the third lens provides a surface at which high-order aberrations are produced.

EXAMPLE 5

Example 5 is directed to a wide-angle zoom lens system having a focal length of 14.38 to 140.9 mm and an F-number of 3.79 to 4.45. As shown in FIG. 5 , the instant lens system is characterized by the construction of the fifth lens group G 5 , wherein the lens located nearest to an image side thereof is a positive meniscus lens convex on the image side, with aspherical surfaces applied to both its surfaces.

The first lens group G 1 is made up of a cemented lens consisting of a negative meniscus lens having a strong curvature on an image side thereof and a double-convex lens having a strong curvature on an object side thereof, and a positive meniscus lens having a strong curvature on an object side thereof. No aspherical surface is used in the first lens group G 1 . The second lens group G 2 is made up of a negative meniscus lens having a very strong curvature on an image side thereof rather than an object side thereof, a double-concave lens, a slight air lens, and a cemented lens consisting of a double-convex lens and a double-concave lens. The third lens group G 3 is made up of an aperture stop and a double-convex lens contiguous thereto. The fourth lens group G 4 is made up of one double-concave lens. The fifth lens group G 5 is made up of a cemented lens consisting of a double-convex lens and a negative meniscus lens and a positive meniscus lens convex on an image side thereof.

Five aspherical surfaces are used; one at the first surface of the first lens in the second lens group G 2 , one at the object-side surface of the second lens in the second lens group G 2 , one at the object-side surface of the double-convex lens in the third lens group G 3 , and two at both surfaces of the positive meniscus lens located nearest to the image side in the fifth lens group G 5 .

Upon zooming from the wide-angle end to the telephoto end, the first lens group G 1 and the third lens group G 3 move almost linearly toward the object side. The second lens group G 2 , too, moves toward the object side although its amount of movement is small. On the other hand, the fourth lens group G 4 and the fifth lens group G 5 move nonlinearly.

EXAMPLE 6

Example 6 is directed to a wide-angle zoom lens system having a focal length of 14.36 to 140.5 mm and an F-number of 3.97 to 4.47. As shown in FIG. 6 , the feature of this lens system is that the second, third and fourth lenses in the second lens group G 2 are cemented together to form a triplet.

The first lens group G 1 is made up of a cemented lens consisting of a negative meniscus lens having a strong curvature on an image side thereof and a double-convex lens having a strong curvature on an object side thereof, and a positive meniscus lens having a strong curvature on an object side thereof. No aspherical surface is used in the first lens group G 1 . The second lens group G 2 is made up of a negative meniscus lens having a very strong curvature on an image side thereof rather than an object side thereof, and a triplet consisting of a double-concave lens, a double-convex lens and a double-concave lens. The third lens group G 3 is made up of an aperture stop and a double-convex lens contiguous thereto. The fourth lens group G 4 is made up of one double-concave lens. The fifth lens group G 5 is made up of a cemented lens consisting of a double-convex lens and a negative meniscus lens and a double-convex lens.

Five aspherical surfaces are used; one at the first surface of the first lens in the second lens group G 2 , one at the object-side surface of the second lens in the second lens group G 2 , one at the object-side surface of the double-convex lens in the third lens group G 3 , and two at both surfaces of the double-convex lens located nearest to the image side in the fifth lens group G 5 .

Upon zooming from the wide-angle end to the telephoto end, the first lens group G 1 and the third lens group G 3 move almost linearly toward the object side. The second lens group G 2 , too, moves toward the object side although its amount of movement is small. On the other hand, the fourth lens group G 4 and the fifth lens group G 5 move nonlinearly.

EXAMPLE 7

Example 7 is directed to a wide-angle yet high-magnification zoom lens system having a focal length of 14.36 to 140.5 mm and an F-number of 3.8 to 4.5. As shown in FIG. 7 , this lens system is made up as in Example 6.

The first lens group G 1 is made up of a cemented lens consisting of a negative meniscus lens having a strong curvature on an image side thereof and a double-convex lens having a strong curvature on an object side thereof, and a positive meniscus lens having a strong curvature on an object side thereof. No aspherical surface is used in the first lens group G 1 . The second lens group G 2 is made up of a double-concave lens having a very strong curvature on an image side thereof, and a triplet consisting of a double-concave lens, a double-convex lens and a double-concave lens. The third lens group G 3 is made up of an aperture stop and a double-convex lens contiguous thereto. The fourth lens group G 4 is made up of one double-concave lens. The fifth lens group G 5 is made up of a cemented lens consisting of a double-convex lens and a negative meniscus lens and a double-convex lens.

Five aspherical surfaces are used; one at the first surface of the first lens in the second lens group G 2 , one at the object-side surface of the second lens in the second lens group G 2 , one at the object-side surface of the double-convex lens in the third lens group G 3 , and two at both surfaces of the double-convex lens located nearest to the image side in the fifth lens group G 5 .

Upon zooming from the wide-angle end to the telephoto end, the first lens group G 1 and the third lens group G 3 move almost linearly toward the object side. The second lens group G 2 , too, moves toward the object side although its amount of movement is small. On the other hand, the fourth lens group G 4 and the fifth lens group G 5 move nonlinearly.

EXAMPLE 8

Example 8 is directed to a wide-angle yet high-magnification zoom lens system having a focal length of 14.78 to 147.78 mm and an F-number of 3.63 to 4.55.

As shown in FIG. 8 , the first lens group G 1 is made up of a cemented lens consisting of a negative meniscus lens having a strong curvature on an image side thereof and a double-convex lens having a strong curvature on an object side thereof, and a positive meniscus lens having a strong curvature on an object side thereof. No aspherical surface is used in the first lens group G 1 . The second lens group G 2 is made up of a negative meniscus lens having a very strong curvature on an image side thereof rather than an object side thereof, a double-concave lens, a slight air lens, a double-convex lens and a double-concave lens. The third lens group G 3 is made up of an aperture stop and a double-convex lens contiguous thereto. The fourth lens group G 4 is made up of a cemented lens consisting of two negative lenses; one being a negative meniscus lens having a strong curvature on an object side thereof and another being a double-concave lens. The fifth lens group G 5 is made up of a cemented lens consisting of a double-convex lens and a negative meniscus lens and a double-convex lens.

Five aspherical surfaces are used; one at the first surface of the first lens in the second lens group G 2 , one at the object-side surface of the second lens in the second lens group G 2 , one at the object-side surface of the double-convex lens in the third lens group G 3 , and two at both surfaces of the double-convex lens located nearest to the image side in the fifth lens group G 5 .

Upon zooming from the wide-angle end to the telephoto end, the first lens group G 1 and the third lens group G 3 move almost linearly toward the object side. The second lens group G 2 , too, moves toward the object side although its amount of movement is small. On the other hand, the fourth lens group G 4 and the fifth lens group G 5 move nonlinearly.

EXAMPLE 9

Example 9 is directed to a wide-angle yet high-magnification zoom lens system having a focal length of 14.78 to 150.6 mm and an F-number of 3.64 to 4.94. In this example, an aspherical surface is added to the fourth lens group G 4 . As shown in FIG. 9 , much the same lens arrangement as in Example 1 is used, but with a higher magnification.

The first lens group G 1 is made up of a cemented lens consisting of a negative meniscus lens having a strong curvature on an image side thereof and a double-convex lens having a strong curvature on an object side thereof, and a positive meniscus lens having a strong curvature on an object side thereof. No aspherical surface is used in the first lens group G 1 . The second lens group G 2 is made up of a negative meniscus lens having a very strong curvature on an image side thereof rather than an object side thereof, a double-concave lens, a slight air lens, a double-convex lens and a double-concave lens. The third lens group G 3 is made up of an aperture stop and a double-convex lens contiguous thereto. The fourth lens group G 4 is made up of a cemented lens consisting of two negative lenses; one being a negative meniscus lens having a strong curvature on an object side thereof and another being a double-concave lens. The fifth lens group G 5 is made up of a cemented lens consisting of a double-convex lens and a negative meniscus lens and a double-convex lens.

Five aspherical surfaces are used; one at the first surface of the first lens in the second lens group G 2 , one at the object-side surface of the second lens in the second lens group G 2 , one at the object-side surface of the double-convex lens in the third lens group G 3 , and two at both surfaces of the double-convex lens located nearest to the image side in the fifth lens group G 5 .

Upon zooming from the wide-angle end to the telephoto end, the first lens group G 1 and the third lens group G 3 move almost linearly toward the object side. The second lens group G 2 , too, moves toward the object side although its amount of movement is small. On the other hand, the fourth lens group G 4 and the fifth lens group G 5 move nonlinearly.

Upon zooming from the wide-angle end to the telephoto end, the magnification of the second lens group G 2 changes from −0.2445 to −0.8156, the magnification of the third lens group G 3 changes from −1.1549 to −4.2082, the magnification of the fourth lens group G 4 changes from −4.8661 to −0.8128, and the magnification of the fifth lens group G 5 changes from −0.15027 to −0.7544.

EXAMPLE 10

Example 10 is directed to a wide-angle yet high-magnification zoom lens system having a focal length of 14.55 to 140.01 mm and an F-number of 3.6 to 4.41. For zooming from the wide-angle end to the telephoto end of the zoom lens system, the first lens group G 1 moves toward the object side of the system, as shown in FIG. 10 . The second lens group G 2 moves slightly. The third lens group G 3 moves together with an aperture stop toward the object side. The fourth and fifth lens groups G 4 and G 5 move nonlinearly in such a way that the spacing between the third and fourth lens groups G 3 and G 4 becomes wide and the spacing between the fourth and fifth lens groups G 4 and G 5 becomes narrow.

The first lens group G 1 is made up of a cemented lens consisting of a negative meniscus lens having a strong curvature on an image side thereof and a double-convex lens having a strong curvature on an object side thereof, and a positive meniscus lens having a strong curvature on an object side thereof. The second lens group G 2 is made up of a negative meniscus lens having a very strong curvature on an image side thereof, a double-concave lens, a double-convex lens and a negative meniscus lens having a strong curvature on an object side thereof. The third lens group G 3 is made up of an aperture stop S and one double-convex lens contiguous thereto. The fourth lens group G 4 is made up of one double-concave lens. The fifth lens group G 5 is made up of a cemented lens consisting of a double-convex lens and a negative meniscus lens and a double-convex lens.

Five aspherical surfaces are used; one at the first surface of the first lens in the second lens group G 2 , one at the object-side surface of the second lens in the second lens group G 2 , one at the object-side surface of the double-convex lens in the third lens group G 3 , and two at both surfaces of the double-convex lens located nearest to the image side in the fifth lens group G 5 .

In this example, the double-convex lens in the third lens group G 3 is designed as a focusing unit F to move back.

FIG. 27 is an aberration diagram for this example upon focused at infinity, and FIG. 28 is an aberration diagram for this example when the third lens group G 3 is focused to 1.5 m. In these aberration diagrams, (a), (b) and (c) represent the wide-angle end, intermediate settings and telephoto end, respectively, and SA, AS, DT and CC stand for spherical aberrations, astigmatism, distortion and chromatic aberration of magnification, respectively, with “IH” representing an image height.

As can be seen from the drawings, fluctuations of aberrations with focusing from infinity to 1.5 m are gentle. Generally preferable results are obtained, although slight fluctuations of spherical aberrations and chromatic aberration of magnification are observed at the telephoto end.

EXAMPLE 11

Example 11 is directed to a wide-angle yet high-magnification zoom lens system having a focal length of 14.55 to 140.01 mm and an F-number of 3.67 to 4.13. This is a reference example wherein the first and second lens groups G 1 and G 2 are designed as an integral focusing unit F.

For zooming from the wide-angle end to the telephoto end of the zoom lens system, the first lens group G 1 moves toward the object side of the system, as shown in FIG. 11 . The second lens group G 2 moves slightly. The third lens group G 3 moves together with an aperture stop toward the object side. The fourth and fifth lens groups G 4 and G 5 move nonlinearly in such a way that the spacing between the third and fourth lens groups G 3 and G 4 becomes wide and the spacing between the fourth and fifth lens groups G 4 and G 5 becomes narrow.

The first lens group G 1 is made up of a cemented lens consisting of a negative meniscus lens having a strong curvature on an image side thereof and a double-convex lens having a strong curvature on an object side thereof, and a positive meniscus lens having a strong curvature on an object side thereof. The second lens group G 2 is made up of a negative meniscus lens having a very strong curvature on an image side thereof, a double-concave lens, a double-convex lens and a negative meniscus lens having a strong curvature on an object side thereof. The third lens group G 3 is made up of an aperture stop S and one double-convex lens contiguous thereto. The fourth lens group G 4 is made up of one double-concave lens. The fifth lens group G 5 is made up of a cemented lens consisting of a double-convex lens and a negative meniscus lens and a positive meniscus lens having a strong curvature on an object side thereof.

Five aspherical surfaces are used; one at the first surface of the first lens in the second lens group G 2 , one at the object-side surface of the second lens in the second lens group G 2 , one at the object-side surface of the double-convex lens in the third lens group G 3 , and two at both surfaces of the positive meniscus lens located nearest to the image side in the fifth lens group G 5 .

FIG. 29 is an aberration diagram for this example upon focused at infinity, and FIG. 30 is an aberration diagram for this example when focusing to 1.5 m is carried out by the intergral movement of the first and second lens groups G 1 and G 2 .

Fluctuations of aberrations are stabilized to some extents. Still, much is left to be desired in connection with the first and second lens groups G 1 and G 2 that are both relatively heavy.

EXAMPLE 12

Example 12 is directed to a wide-angle yet high-magnification zoom lens system having a focal length of 14.55 to 140.01 mm and an F-number of 3.77 to 4.61. For zooming from the wide-angle end to the telephoto end of the zoom lens system, the first lens group G 1 moves toward the object side of the system, as shown in FIG. 12 . The second lens group G 2 moves slightly. The third lens group G 3 moves together with an aperture stop toward the object side. The fourth lens group G 4 moves nonlinearly in such a way that the spacing between the third and fourth lens groups G 3 and G 4 becomes wide. Divided into a front subgroup G 5 F and a rear subgroup G 5 R, the fifth lens group G 5 moves nonlinearly in such a way that the spacing between the fourth lens group G 4 and the front subgroup G 5 F of the fifth lens group G 5 becomes narrow, while th e spacing between the front subgroup G 5 F and rear subgroup G 5 R becomes narrow.

The first lens group G 1 is made up of a cemented lens consisting of a negative meniscus lens having a strong curvature on an image side thereof and a double-convex lens having a strong curvature on an object side thereof, and a positive meniscus lens having a strong curvature on an object side thereof. The second lens group G 2 is made up of a negative meniscus lens having a very strong curvature on an image side thereof, a double-concave lens, a double-convex lens and a negative meniscus lens having a strong curvature on an object side thereof. The third lens group G 3 is made up of an aperture stop S and one double-convex lens contiguous thereto. The fourth lens group G 4 is made up of one double-concave lens. The front subgroup G 5 F of the fifth lens group G 5 is made up of a cemented lens consisting of a double-con vex lens and a negative meniscus lens, and the rear subgroup G 5 R is made up of a positive meniscus lens having a strong curvature on an object side thereof.

Five aspherical surfaces are used; one at the first surface of the first lens in the second lens group G 2 , one at the object-side surface of the second lens in the second lens group G 2 , one at the object-side surface of the double-convex lens in the third lens group G 3 , and two at both surfaces of the positive meniscus lens in the rear subgroups G 5 R of the fifth lens group G 5 .

This example is figured out to provide a solution to the problem that when the fifth lens group G 5 itself is a telecentric optical system, it has difficulty in focusing. Focusing is carried out with the front subgroup G 5 F of the fifth lens group G 5 . The rear subgroup G 5 R or, in another parlance, a field flattener functions to vary the mutual spacing between the front subgroup G 5 F and the rear subgroup G 5 R, thereby reducing fluctuations of aberrations with focusing and zooming.

FIG. 31 is an aberration diagram for this example upon focused at infinity, and FIG. 32 is an aberration diagram for this example upon focused on a finite point of 2.0 m.

Excepting somewhat prominent fluctuations of coma at the telephoto end, the instant zoom lens system is found to be satisfactory and stable.

EXAMPLE 13

Example 13 is directed to a wide-angle yet high-magnification zoom lens system having a focal length of 14.55 to 140.01 mm and an F-number of 3.78 to 4.49. For zooming from the wide-angle end to the telephoto end of the zoom lens system, the first lens group G 1 moves toward the object side of the system, as shown in FIG. 13 . The second lens group G 2 moves slightly. The third lens group G 3 moves together with an aperture stop toward the object side. The fourth lens group G 4 moves nonlinearly in such a way that the spacing between the third and fourth lens groups G 3 and G 4 becomes wide. Divided into a front subgroup G 5 F and a rear subgroup G 5 R, the fifth lens group G 5 moves nonlinearly in such a way that the spacing between the fourth lens group G 4 and the front subgroup G 5 F of the fifth lens group G 5 becomes narrow, while the spacing between the front subgroup G 5 F and rear subgroup G 5 R becomes narrow.

The first lens group G 1 is made up of a cemented lens consisting of a negative meniscus lens having a strong curvature on an image side thereof and a double-convex lens having a strong curvature on an object side thereof, and a positive meniscus lens having a strong curvature on an object side thereof. The second lens group G 2 is made up of a negative meniscus lens having a very strong curvature on an image side thereof, a double-concave lens, a double-convex lens and a negative meniscus lens having a strong curvature on an object side thereof. The third lens group G 3 is made up of an aperture stop S and one double-convex lens contiguous thereto. The fourth lens group G 4 is made up of one double-concave lens. The front subgroup G 5 F of the fifth lens group G 5 is made up of a cemented lens consisting of a double-convex lens and a negative meniscus lens, and the rear subgroup G 5 R is made up of a double-convex lens.

Five aspherical surfaces are used; one at the first surface of the first lens in the second lens group G 2 , one at the object-side surface of the second lens in the second lens group G 2 , one at the object-side surface of the double-convex lens in the third lens group G 3 , and two at both surfaces of the double-convex lens in the rear subgroups G 5 R of the fifth lens group G 5 .

This example makes use of a focusing mode of moving the fourth lens group G 4 .

FIG. 33 is an aberration diagram for this example upon focused at infinity, and FIG. 34 is an aberration diagram for this example upon focused on a finite point of 2.0 m.

According to the instant embodiment wherein there is some considerable margin in the space for moving the third and fourth lens groups G 3 and G 4 , it is possible to reduce a close-up distance to considerable degrees if fluctuations of aberrations with focusing can be corrected to some extents.

EXAMPLE 14

Example 14 is directed to a wide-angle yet high-magnification zoom lens system having a focal length of 14.36 to 140.5 mm and an F-number of 3.6 to 4.4. For zooming from the wide-angle end to the telephoto end of the system, the first lens group G 1 moves toward the object side of the system, as shown in FIG. 14 . The second lens group G 2 moves slightly. The third lens group G 3 moves together with an aperture stop toward the object side. The fourth lens group G 4 moves back toward the image side of the system with respect to the wide-angle end position. The fifth lens group G 5 moves nonlinearly.

The first lens group G 1 is made up of a cemented lens consisting of a negative meniscus lens having a strong curvature on an image side thereof and a double-convex lens having a strong curvature on an object side thereof, and a positive meniscus lens having a strong curvature on an object side thereof. No aspherical surface is used in the first lens group G 1 . The second lens group G 2 is made up of a negative meniscus lens having a very strong curvature on an image side thereof rather than on an object side thereof, a double-concave lens, a slight air lens, a double-convex lens and a double-concave lens. The third lens group G 3 is made up of an aperture stop and a double-convex lens contiguous thereto. The fourth lens group G 4 is made up of one double-concave lens.

The fifth lens group G 5 is made up of a cemented lens consisting of a double-convex lens and a double-concave lens, and a double-convex lens.

By use of two aspherical surfaces, one at the first surface of the first lens in the second lens group G 2 and another at the object-side surface of the second lens therein, correction of distortion can be well balanced with respect to correction of coma. The use of such aspherical surfaces produces a marked effect especially because the wider the wide-angle arrangement of the system, the more difficult it is to correct distortion. An aspherical surface used at the object-side surface of the double-convex lens in the third lens group G 3 enables spherical aberrations to be well corrected. Aspherical surfaces used at both surfaces of the double-convex lens located nearest to the image side in the fifth lens group G 5 produce an effect so marked that off-axis aberrations can be corrected while a telecentric nature is imparted to the system.

Upon zooming from the wide-angle end to the telephoto end, the first lens group G 1 and the third lens group G 3 move almost linearly toward the object side. The second lens group G 2 , too, moves toward the object side although its amount of movement is small. On the other hand, the fourth lens group G 4 and the fifth lens group G 5 move nonlinearly.

This example is figured out to compensate for an image movement on an image plane, which may otherwise be caused by some camera movement or the like. For instance, an image movement on the image plane due to a camera movement of about 0.5° can be corrected by making a shift δi of the second lens group G 2 vertically with respect to the optical axis.

EXAMPLE 15

Example 15 is directed to a wide-angle yet high-magnification zoom lens system having a focal length of 14.36 to 140.5 mm and an F-number of 3.5 to 4.1. The specification is much the same as in Example 14. For zooming from the wide-angle end to the telephoto end of the system, the first lens group G 1 moves toward the object side of the system, as shown in FIG. 15 . The second lens group G 2 moves slightly. The third lens group G 3 moves together with an aperture stop toward the object side. The fourth lens group G 4 moves back toward the image side of the system with respect to the wide-angle end position. The fifth lens group G 5 moves nonlinearly.

The first lens group G 1 is made up of a cemented lens consisting of a negative meniscus lens having a strong curvature on an image side thereof and a double-convex lens having a strong curvature on an object side thereof, and a positive meniscus lens having a strong curvature on an object side thereof. No aspherical surface is used in the first lens group G 1 . The second lens group G 2 is made up of a negative meniscus lens having a very strong curvature on an image side thereof rather than on an object side thereof, a double-concave lens, a slight air lens, a double-convex lens and a double-concave lens. The third lens group G 3 is made up of an aperture stop and a double-convex lens contiguous thereto. The fourth lens group G 4 is made up of one double-concave lens.

The fifth lens group G 5 is made up of a cemented lens consisting of a double-convex lens and a double-concave lens, and a double-convex lens.

Six aspherical surfaces are used; one at the first surface of the first lens in the second lens group G 2 , one at the object-side surface of the second lens in the second lens group G 2 , two at both surfaces of the double-convex lens in the third lens group G 3 , and two at both surfaces of the double-convex lens located nearest to the image side in the fifth lens group G 5 .

Upon zooming from the wide-angle end to the telephoto end, the first lens group G 1 and the third lens group G 3 move almost linearly toward the object side. The second lens group G 2 , too, moves toward the object side although its amount of movement is small. On the other hand, the fourth lens group G 4 and the fifth lens group G 5 move nonlinearly.

This example is figured out to compensate for an image movement on an image plane, which may otherwise be caused by some camera movement or the like. For instance, an image movement on the image plane due to a camera movement of about 0.5° can be corrected by making a shift δi of the fourth lens group G 4 vertically with respect to the optical axis.

The zoom lens system according to Example 14, and Example 15 has a field angle of 70° or greater at the wide-angle end and a zoom ratio of about 10 while a certain telecentric nature is imparted thereto. The potential image-formation capability of these systems is very excellent. If the focal length on the telephoto end side is increased, the zoom ratio can then be enlarged with relative ease.

EXAMPLE 16

Example 16 is directed to a wide-angle yet high-magnification zoom lens system having a focal length of 14.36 to 140.5 mm and an F-number of 3.5 to 4.36. The specification is much the same as in Example 14. For zooming from the wide-angle end to the telephoto end of the system, the first lens group G 1 moves toward the object side of the system, as shown in FIG. 16 . The second lens group G 2 moves slightly. The third lens group G 3 moves together with an aperture stop toward the object side. The fourth lens group G 4 moves back toward the image side of the system with respect to the wide-angle end position. The fifth lens group G 5 moves nonlinearly.

The first lens group G 1 is made up of a cemented lens consisting of a negative meniscus lens having a strong curvature on an image side thereof and a double-convex lens having a strong curvature on an object side thereof, and a positive meniscus lens having a strong curvature on an object side thereof. No aspherical surface is used in the first lens group G 1 . The second lens group G 2 is made up of a negative meniscus lens having a very strong curvature on an image side thereof rather than on an object side thereof, a double-concave lens, a slight air lens, a double-convex lens and a double-concave lens. The third lens group G 3 is made up of an aperture stop and a double-convex lens contiguous thereto. The fourth lens group G 4 is made up of one double-concave lens.

The fifth lens group G 5 vertically with respect to the optical axis is made up of a cemented lens consisting of a double-convex lens and a negative meniscus lens having a strong curvature on object side thereof, and a double-convex lens.

Six aspherical surfaces are used; one at the first surface of the first lens in the second lens group G 2 , one at the object-side surface of the second lens in the second lens group G 2 , two at both surfaces of the double-convex lens in the third lens group G 3 , and two at both surfaces of the double-convex lens located nearest to the image side in the fifth lens group G 5 .

Upon zooming from the wide-angle end to the telephoto end, the first lens group G 1 and the third lens group G 3 move almost linearly toward the object side. The second lens group G 2 , too, moves toward the object side although its amount of movement is small. On the other hand, the fourth lens group G 4 and the fifth lens group G 5 move nonlinearly.

This example is figured out to compensate for an image movement on an image plane, which may otherwise be caused by some camera movement or the like. For instance, an image movement on the image plane due to a camera movement of about 0.5° can be corrected by making a shift δi of the fourth lens group G 4 vertically with respect to the optical axis.

EXAMPLE 17

Example 17 is directed to a wide-angle yet high-magnification zoom lens system having a focal length of 14.36 to 140.5 mm and an F-number of 3.25 to 4.43. The specification is much the same as in Example 14. For zooming from the wide-angle end to the telephoto end of the system, the first lens group G 1 moves toward the object side of the system, as shown in FIG. 17 . The second lens group G 2 moves slightly. The third lens group G 3 moves together with an aperture stop toward the object side. The fourth lens group G 4 moves back toward the image side of the system with respect to the wide-angle end position. The fifth lens group G 5 moves nonlinearly.

The first lens group G 1 is made up of a cemented lens consisting of a negative meniscus lens having a strong curvature on an image side thereof and a double-convex lens having a strong curvature on an object side thereof, and a positive meniscus lens having a strong curvature on an object side thereof. No aspherical surface is used in the first lens group G 1 . The second lens group G 2 is made up of a negative meniscus lens having a very strong curvature on an image side thereof rather than on an object side thereof, a double-concave lens, a slight air lens, a double-convex lens and a double-concave lens. The third lens group G 3 is made up of an aperture stop and a double-convex lens contiguous thereto. The fourth lens group G 4 is made up of one double-concave lens.

The fifth lens group G 5 is made up of a cemented lens consisting of a double-convex lens and a negative meniscus lens having a strong curvature on object side thereof, and a double-convex lens.

Six aspherical surfaces are used; one at the first surface of the first lens in the second lens group G 2 , one at the object-side surface of the second lens in the second lens group G 2 , two at both surfaces of the double-convex lens in the third lens group G 3 , and two at both surfaces of the double-convex lens located nearest to the image side in the fifth lens group G 5 .

Upon zooming from the wide-angle end to the telephoto end, the first lens group G 1 and the third lens group G 3 vertically with respect to the optical axis move almost linearly toward the object side. The second lens group G 2 , too, moves toward the object side although its amount of movement is small. On the other hand, the fourth lens group G 4 and the fifth lens group G 5 move nonlinearly.

This example is figured out to compensate for an image movement on an image plane, which may otherwise be caused by some camera movement or the like. For instance, an image movement on the image plane due to a camera movement of about 0.5° can be corrected by making a shift δi of the fourth lens group G 4 vertically with respect to the optical axis.

Set out below are numerical data on each example. Symbols used hereinafter but not hereinbefore have the following meanings.

f: the focal length of a zoom lens system,

2ω: a field angle,

F NO : an F-number,

FB: a back focus,

WE: a wide-angle end,

ST: intermediate settings,

TE: a telephoto end,

r 1 , r 2 , . . . : the radius of curvature of each lens,

d 1 , d 2 , . . . : the spacing between adjacent lens surfaces,

n d1 , n d2 , . . . : the d-line refractive index of each lens, and

V d1 , V d2 , . . . : the Abbe number of each lens.

Here let x represent an optical axis where the direction of propagation of light is assumed to be positive, and y stand for a direction perpendicular with respect to the optical axis. Then, aspherical shape is given by

x =( y 2 /r )/[1+{1−( K +1)( y/r ) 2 } ½ ]+A 4 y 4 +A 6 y 6 +A 8 y 8 +A 10 y 10

Here r is a paraxial radius of curvature, K is a conical coefficient, and A 4 , A 6 , A 8 and A 10 are the fourth, sixth, eighth and tenth aspherical coefficients, respectively.

EXAMPLE 1

r 1 = 91.994	d 1 = 1.500	n d1 = 1.84666	ν d1 = 23.78
r 2 = 46.027	d 2 = 8.600	n d2 = 1.60311	ν d2 = 60.64
r 3 = −477.912	d 3 = 0.100
r 4 = 38.093	d 4 = 5.000	n d3 = 1.49700	ν d3 = 81.54
r 5 = 147.554	d 5 = D1
r 6 = 90.488 (Aspheric)	d 6 = 0.850	n d4 = 1.77250	ν d4 = 49.60
r 7 = 14.432	d 7 = 5.378
r 8 = −29.591 (Aspheric)	d 8 = 0.850	n d5 = 1.78386	ν d5 = 38.09
r 9 = 33.478	d 9 = 0.100
r 10 = 32.890	d 10 = 4.700	n d6 = 1.84666	ν d6 = 23.78
r 11 = −22.731	d 11 = 0.536
r 12 = −18.454	d 12 = 0.750	n d7 = 1.74100	ν d7 = 52.64
r 13 = 164.135	d 13 = D2
r 14 = ∞ (Stop)	d 14 = 0.850
r 15 = 21.823 (Aspheric)	d 15 = 3.750	n d8 = 1.48749	ν d8 = 70.23
r 16 = −25.687	d 16 = D3
r 17 = −34.785	d 17 = 0.800	n d9 = 1.84666	ν d9 = 23.78
r 18 = −39.906	d 18 = 0.800	n d10 = 1.69680	ν d10 = 55.53
r 19 = 304.185	d 19 = D4
r 20 = 31.932	d 20 = 5.823	n d11 = 1.49700	ν d11 = 81.54
r 21 = −34.866	d 21 = 0.700	nd 12 = 1.80518	ν d12 = 25.42
r 22 = −358.865	d 22 = 0.100
r 23 = 72.193 (Aspheric)	d 23 = 3.533	n d13 = 1.60311	ν d13 = 60.64
r 24 = −45.125 (Aspheric)
Aspherical Coefficients
6th surface
K = 0.0000
A 4 = 8.0531 × 10 −6
A 6 = 3.6708 × 10 −9
A 8 = 1.9100 × 10 −10
A 10 = 0.0000
8th surface
K = 0.0000
A 4 = −8.4129 × 10 −6
A 6 = −3.0713 × 10 −8
A 8 = −1.5671 × 10 −9
A 10 = 1.3072 × 10 −11
15th surface
K = 0.0000
A 4 = −2.6090 × 10 −5
A 6 = −2.5338 × 10 −8
A 8 = 1.9102 × 10 −10
A 10 = −1.7629 × 10 −12
23th surface
K = 0.0000
A 4 = −6.2426 × 10 −6
A 6 = −9.1416 × 10 −9
A 8 = −1.1515 × 10 −10
A 10 = −2.3728 × 10 −14
24th surface
K = 0.0000
A 4 = 9.5538 × 10 −6
A 6 = −6.6795 × 10 −9
A 8 = −1.3701 × 10 −10
A 10 = 0.0000
Zooming Data
	WE	ST	TE
f (mm)	14.360	45.500	140.500
F NO	3.851	3.911	4.533
2ω (°)	74.1	24.9	8.2
FB (mm)	34.028	47.777	48.075
D1	1.200	21.358	34.134
D2	23.400	7.889	1.122
D3	2.969	11.179	37.599
D4	18.964	13.077	1.900

EXAMPLE 2

r 1 = 94.952	d 1 = 1.500	n d1 = 1.84666	ν d1 = 23.78
r 2 = 48.267	d 2 = 8.600	n d2 = 1.60311	ν d2 = 60.64
r 3 = −472.579	d 3 = 0.177
r 4 = 41.087	d 4 = 5.000	n d3 = 1.49700	ν d3 = 81.54
r 5 = 191.554	d 5 = D1
r 6 = 162.811 (Aspheric)	d 6 = 0.850	n d4 = 1.80100	ν d4 = 34.97
r 7 = 16.166	d 7 = 5.378
r 8 = −30.360 (Aspheric)	d 8 = 0.850	n d5 = 1.70154	ν d5 = 41.24
r 9 = 20.369	d 9 = 0.100
r 10 = 21.075	d 10 = 4.700	n d6 = 1.84666	ν d6 = 23.78
r 11 = −25.650	d 11 = 0.622
r 12 = −19.420	d 12 = 0.750	n d7 = 1.74100	ν d7 = 52.64
r 13 = 102.719	d 13 = D2
r 14 = ∞ (Stop)	d 14 = 0.850
r 15 = 21.768 (Aspheric)	d 15 = 3.750	n d8 = 1.48749	ν d8 = 70.23
r 16 = −29.026	d 16 = D3
r 17 = −50.167	d 17 = 0.800	n d9 = 1.77250	ν d9 = 49.60
r 18 = 227.025	d 18 = D4
r 19 = 40.619	d 19 = 4.980	n d10 = 1.49700	ν d10 = 81.54
r 20 = −26.501	d 20 = 0.700	n d11 = 1.80518	ν d11 = 25.42
r 21 = −95.736	d 21 = 0.142
r 22 = 80.181 (Aspheric)	d 22 = 3.390	n d12 = 1.60311	vd 12 = 60.64
r 23 = −46.877 (Aspheric)
Aspherical Coefficients
6th surface
K = 0.0000
A 4 = 1.2942 × 10 −5
A 6 = 3.8064 × 10 −9
A 8 = 1.2125 × 10 −10
A10 = 0.0000
8th surface
K = 0.0000
A 4 = −1.0616 × 10 −5
A 6 = −7.6137 × 10 −8
A 8 = −6.0911 × 10 −10
A 10 = 9.2537 × 10 −12
15th surface
K = 0.0000
A 4 = −2.6708 × 10 −5
A 6 = −1.8778 × 10 −8
A 8 = 2.8164 × 10 −10
A 10 = −2.7393 × 10 −12
22th surface
K = 0.0000
A 4 = 2.9174 × 10 −6
A 6 = −5.7765 × 10 −8
A 8 = 2.4722 × 10 −10
A 10 = −1.26781× 10 −13
23th surface
K = 0.0000
A 4 = 1.4258 × 10 −5
A 6 = −5.4401 × 10 −8
A 8 = 1.9960 × 10 −10
A 10 = 0.0000
Zooming Data
	WE	ST	TE
f (mm)	14.360	45.501	140.499
F NO	3.583	3.936	4.626
2ω0 (°)	71.8	25.2	8.1
FB (mm)	34.473	47.674	48.942
D1	1.200	21.663	35.000
D2	23.400	8.012	1.122
D3	1.389	11.694	41.595
D4	21.085	13.246	0.100

EXAMPLE 3

r 1 = 89.318	d 1 = 1.500	n d1 = 1.84666	ν d1 = 23.78
r 2 = 45.943	d 2 = 8.600	n d2 = 1.60311	ν d2 = 60.64
r 3 = −421.790	d 3 = 0.100
r 4 = 38.485	d 4 = 5.000	n d3 = 1.49700	ν d3 = 81.54
r 5 = 159.848	d 5 = D1
r 6 = −1925.623 (Aspheric)	d 6 = 0.850	n d4 = 1.77250	ν d4 = 49.60
r 7 = 18.057	d 7 = 5.976
r 8 = −27.494 (Aspheric)	d 8 = 0.800	n d5 = 1.76200	ν d5 = 40.10
r 9 = 26.944	d 9 = 0.222
r 10 = 29.107	d 10 = 5.678	n d6 = 1.84666	ν d6 = 23.78
r 11 = −14.567	d 11 = 0.850	n d7 = −1.80100	ν d7 = 34.97
r 12 = 81.707	d 12 = D2
r 13 = (Stop)	d 13 = 0.850
r 14 = 20.470 (Aspheric)	d 14 = 3.750	n d8 = 1.48749	ν d8 = 70.23
r 15 = −30.742	d 15 = D3
r 16 = −50.500	d 16 = 0.850	n d9 = 1.78590	ν d9 = 44.20
r 17 = 179.821	d 17 = D4
r 18 = 37.947	d 18 = 6.017	n d10 = 1.49700	νd 10 = 81.54
r 19 = −27.466	d 19 = 0.700	n d11 = 1.80518	ν d11 = 25.42
r 20 = −78.435	d 20 = 0.100
r 21 = 54.447 (Aspheric)	d 21 = 2.974	n d12 = 1.60311	ν d12 = 60.64
r 22 = −106.590 (Aspheric)
Aspherical Coefficients
6th surface
K = 0.0000
A 4 = 2.0650 × 10 −5
A 6 = −3.5562 × 10 −9
A 8 = 1.0752 × 10 −10
A10 = 9.2537 × 10 −12
8th surface
K = 0.0000
A 4 = −2.7627 × 10 −5
A 6 = −1.3305 × 10 −7
A 8 = −2.4215 × 10 −10
A 10 = 9.0912 × 10 −12
14th surface
K = 0.0000
A 4 = −2.5925 × 10 −5
A 6 = −4.5685 × 10 −8
A 8 = 4.1569 × 10 −10
A 10 = −3.7206 × 10 −12
21th surface
K = 0.0000
A 4 = 7.8335 × 10 −6
A 6 = −2.1504 × 10 −8
A 8 = 1.1794 × 10 −10
A 10 = −6.0983 × 10 −15
22th surface
K = 0.0000
A 4 = 1.8613 × 10 −5
A 6 = −2.3916 × 10 −8
A 8 = 1.1243 × 10 −10
A 10 = 0.0000
Zooming Data
	WE	ST	TE
f (mm)	14.360	45.500	140.500
F NO	3.673	3.897	4.392
2ω (°)	51.6	24.9	8.2
FB (mm)	34.751	47.054	45.988
D1	1.200	21.150	33.259
D2	23.400	8.306	1.122
D3	1.634	11.062	38.777
D4	22.958	15.281	1.900

EXAMPLE 4

r 1 = 89.152	d 1 = 1.500	n d1 = 1.84666	ν d1 = 23.78
r 2 = 45.882	d 2 = 8.600	n d2 = 1.60311	ν d2 = 60.64
r 3 = −419.179	d 3 = 0.100
r 4 = 38.411	d 4 = 5.000	n d3 = 1.49700	ν d3 = 81.54
r 5 = 158.939	d 5 = D1
r 6 = −2307.270 (Aspheric)	d 6 = 0.850	n d4 = 1.77250	ν d4 = 49.60
r 7 = 17.969	d 7 = 5.912
r 8 = −27.885 (Aspheric)	d 8 = 0.800	n d5 = 1.76200	ν d5 = 40.10
r 9 = 26.513	d 9 = 0.222
r 10 = 28.519	d 10 = 5.678	n d6 = 1.84666	ν d6 = 23.78
r 11 = −14.662	d 11 = 0.850	n d7 = 1.80100	ν d7 = 34.97
r 12 = 78.835	d 12 = D2
r 13 = ∞ (Stop)	d 13 = 0.850
r 14 = 20.371 (Aspheric)	d 14 = 3.750	n d8 = 1.48749	ν d8 = 70.23
r 15 = −31.030	d 15 = D3
r 16 = −50.500	d 16 = 0.850	n d9 = 1.78590	ν d9 = 44.20
r 17 = 181.728	d 17 = D4
r 18 = 38.678	d 18 = 6.128	n d10 = 1.49700	ν d10 = 81.54
r 19 = −26.037	d 19 = 0.700	n d11 = 1.80518	ν d11 = 25.42
r 20 = −66.745	d 20 = 0.145
r 21 = 41.819 (Aspheric)	d 21 = 4.045	n d12 = 1.60311	ν d12 = 60.64
r 22 = −457.095 (Aspheric)
Aspherical Coefficients
6th surface
K = 0.0000
A 4 = 2.0699 × 10 −5
A 6 = −4.1251 × 10 −9
A 8 = 1.1112 × 10 −10
A 10 = 0.0000
8th surface
K = 0.0000
A 4 = −2.8114 × 10 −5
A 6 = −1.2893 × 10 −7
A 8 = −2.8298 × 10 −10
A 10 = 9.1108 × 10 −12
14th surface
K = = 0.0000
A 4 = −2.5544 × 10 −5
A 6 = −5.1169 × 10 −8
A 8 = 4.6979 × 10 −10
A 10 = −4.1023 × 10 −12
21th surface
K = 0.0000
A 4 = 1.2216 × 10 −5
A 6 = −2.1992 × 10 −9
A 8 = 1.2702 × 10 −10
A 10 = 1.8308 × 10 −14
22th surface
K = 0.0000
A 4 = 2.4188 × 10 −5
A 6 = −4.6120 × 10 −9
A 8 = 1.4094 × 10 −10
A 10 = 0.0000
Zooming Data
	WE	ST	TE
f (mm)	14.360	45.500	140.500
F NO	3.660	3.921	4.423
2ω (°)	74.1	24.9	8.2
FB (mm)	33.715	45.952	44.789
D1	1.200	21.143	33.231
D2	23.400	8.330	1.122
D3	1.673	11.054	38.777
D4	22.806	15.264	1.900

EXAMPLE 5

r 1 = 91.941	d 1 = 1.500	n d1 = 1.84666	ν d1 = 23.78
r 2 = 47.142	d 2 = 8.600	n d2 = 1.60311	ν d2 = 60.64
r 3 = −403.678	d 3 = 0.178
r 4 = 40.752	d 4 = 5.000	n d3 = 1.49700	ν d3 = 81.54
r 5 = 197.015	d 5 = D1
r 6 = 103.184 (Aspheric)	d 6 = 0.850	n d4 = 1.77250	ν d4 = 49.60
r 7 = 14.488	d 7 = 5 563
r 8 = −22.871 (Aspheric)	d 8 = 0.800	n d5 = 1.79952	ν d5 = 42.22
r 9 = 44.615	d 9 = 0.222
r 10 = 46.819	d 10 = 5.678	n d6 = 1.84666	ν d6 = 23.78
r 11 = −14.396	d 11 = 0.800	n d7 = 1.80100	ν d7 = 34.97
r 12 = 356.669	d 12 = D2
r 13 = ∞ (Stop)	d 13 = 0.800
r 14 = 21.174 (Aspheric)	d 14 = 3.750	n d8 = 1.48749	ν d8 = 70.23
r 15 = −29.161	d 15 = D3
r 16 = −50.500	d 16 = 1.853	n d9 = 1.78590	ν d9 = 44.20
r 17 = 258.833	d 17 = D4
r 18 = 27.025	d 18 = 9.415	n d10 = 1.49700	ν d10 = 81.54
r 19 = −22.418	d 19 = 0.800	nd 11 = 1.84666	ν d11 = 23.78
r 20 = −40.505	d 20 = 1.200
r 21 = −59.684 (Aspheric)	d 21 = 1.864	n d12 = 1.48749	ν d12 = 70.23
r 22 = −39.294 (Aspheric)
Aspherical Coefficients
6th surface
K = 0.0000
A 4 = 1.0707 × 10 −5
A 6 = 5.1530 × 10 −9
A 8 = 2.9734 × 10 −10
A 10 = 0.0000
8th surface
K = 0.0000
A 4 = −2.2546 × 10 −5
A 6 = −9.6101 × 10 −8
A 8 = −2.4231 × 10 −9
A 10 = 2.2900 × 10 −11
14th surface
K = = 0.0000
A 4 = −2.3976 × 10 −5
A 6 = −3.0360 × 10 −8
A 8 = 1.5643 × 10 −10
A 10 = −1.8061 × 10 −12
21th surface
K = 0.0000
A 4 = −8.4196 × 10 −5
A 6 = −1.0340 × 10 −7
A 8 = 1.6480 × 10 −9
A 10 = −5.3645 × 10 −13
22th surface
K = 0.0000
A 4 = −6.2003 × 10 −5
A 6 = −4.4676 × 10 −8
A 8 = 1.1900 × 10 −9
A 10 = 0.0000
Zooming Data
	WE	ST	TE
f (mm)	14.380	45.601	140.892
F NO	3.788	4.113	4.448
2ω (°)	74.0	24.3	8.0
FB (mm)	32.049	45.198	41.570
D1	1.200	21.673	35.000
D2	23.400	8.401	1.122
D3	1.255	9.983	38.777
D4	18.979	12.957	1.900

EXAMPLE 6

r 1 = 88.508	d 1 = 1.500	n d1 = 1.84666	ν d1 = 23.78
r 2 = 46.109	d 2 = 8.600	n d2 = 1.60311	ν d2 = 60.64
r 3 = −437.067	d 3 = 1.140
r 4 = 38.017	d 4 = 5.000	n d3 = 1.49700	ν d3 = 81.54
r 5 = 152.472	d 5 = D1
r 6 = −175.257 (Aspheric)	d 6 = 0.850	n d4 = 1.77250	ν d4 = 49.60
r 7 = 17.553	d 7 = 5.848
r 8 = −27.666 (Aspheric)	d 8 = 0.800	n d5 = 1.80100	ν d5 = 34.97
r 9 = 30.014	d 9 = 5.678	n d6 = 1.84666	ν d6 = 23.78
r 10 = −12.706	d 10 = 0.800	n d7 = 1.80100	ν d7 = 34.97
r 11 = 126.853	d 11 = D2
r 12 = (Stop)	d 12 = 0.850
r 13 = 20.210 (Aspheric)	d 13 = 3.750	n d8 = 1.48749	ν d8 = 70.23
r 14 = −29.530	d 14 = D3
r 15 = −50.500	d 15 = 0.800	n d9 = 1.78590	ν d9 = 44.20
r 16 = 154.049	d 16 = D4
r 17 = 34.452	d 17 = 6.197	n d10 = 1.49700	ν d10 = 81.54
r 18 = −27.657	d 18 = 0.700	n d11 = 1.80518	ν d11 = 25.42
r 19 = −90.725	d 19 = 1.090
r 20 = 49.917 (Aspheric)	d 20 = 2.821	n d12 = 1.62299	ν d12 = 58.16
r 21 = −141.675 (Aspheric)
Aspherical Coefficients
6th surface
K = 0.0000
A 4 = 3.1081 × 10 −5
A 6 = −3.3915 × 10 −8
A 8 = 1.7112 × 10 −10
A 10 = 0.0000
8th surface
K = 0.0000
A 4 = −3.6433 × 10 −5
A 6 = −1.6965 × 10 −7
A 8 = −3.4629 × 10 −10
A 10 = 9.9705 × 10 −12
13th surface
K = 0.0000
A 4 = −2.7823 × 10 −5
A 6 = −4.7812 × 10 −8
A 8 = 3.7430 × 10 −10
A 10 = −3.5612 × 10 −12
20th surface
K = 0.0000
A 4 = 7.6500 × 10 −6
A 6 = −1.6751 × 10 −8
A 8 = 5.3713 × 10 −11
A 10 = −6.4434 × 10 −15
21th surface
K = 0.0000
A 4 = 1.9595 × 10 −5
A 6 = −2.0028 × 10 −8
A 8 = 4.6375 × 10 −11
A 10 = 0.0000
Zooming Data
	WE	ST	TE
f (mm)	14.360	45.500	140.500
F NO	3.970	3.989	4.474
2ω (°)	74.0	24.9	8.2
FB (mm)	33.268	45.349	43.632
D1	1.200	21.354	33.390
D2	23.400	8.452	1.122
D3	2.599	11.782	38.777
D4	21.882	14.642	1.900

EXAMPLE 7

r 1 = 89.102	d 1 = 1.500	n d1 = 1.84666	ν d1 = 23.78
r 2 = 47.111	d 2 = 8.600	n d2 = 1.60311	ν d2 = 60.64
r 3 = −447.391	d 3 = 0.968
r 4 = 38.258	d 4 = 5.000	n d3 = 1.49700	ν d3 = 81.54
r 5 = 149.662	d 5 = D1
r 6 = −310.882 (Aspheric)	d 6 = 0.850	n d4 = 1.77250	ν d4 = 49.60
r 7 = 16.872	d 7 = 6.042
r 8 = −26.266 (Aspheric)	d 8 = 0.850	n d5 = 1.80100	ν d5 = 34.97
r 9 = 28.453	d 9 = 5.678	n d6 = 1.84666	ν d6 = 23.78
r 10 = −13.008	d 10 = 0.850	n d7 = 1.80100	ν d7 = 34.97
r 11 = 134.521	d 11 = D2
r 12 = ∞ (Stop)	d 12 = 0.850
r 13 = 20.478 (Aspheric)	d 13 = 3.750	n d8 = 1.49700	ν d8 = 81.54
r 14 = −28.953	d 14 = D3
r 15 = −50.500	d 15 = 0.850	n d9 = 1.75500	ν d9 = 52.32
r 16 = 150.427	d 16 = D4
r 17 = 32.214	d 17 = 6.185	n d10 = 1.48749	ν d10 = 70.23
r 18 = −27.079	d 18 = 0.700	n d11 = 1.76182	ν d11 = 26.52
r 19 = −174.172	d 19 = 1.495
r 20 = 46.901 (Aspheric)	d 20 = 3.139	n d12 = 1.60300	ν d12 = 65.44
r 21 = −100.331 (Aspheric)
Aspherical Coefficients
6th surface
K = 0.0000
A 4 = 2.7938 × 10 −5
A 6 = −3.2330 × 10 −8
A 8 = 1.9137 × 10 −10
A 10 = 0.0000
8th surface
K = 0.0000
A 4 = −3.5625 × 10 −5
A 6 = −1.4933 × 10 −7
A 8 = −7.6603 × 10 −10
A 10 = 1.1474 × 10 −11
13th surface
K = 0.0000
A 4 = −2.7661 × 10 −5
A 6 = −4.5255 × 10 −8
A 8 = 3.6206 × 10 −10
A 10 = −3.3238 × 10 −12
20th surface
K = 0.0000
A 4 = 5.8681 × 10 −6
A 6 = −1.8134 × 10 −8
A 8 = 3.3269 × 10 −11
A 10 = 1.7867 × 10 −14
21th surface
K = 0.0000
A 4 = 1.9918 × 10 −5
A 6 = −2.1955 × 10 −8
A 8 = 2.9455 × 10 −11
A 10 = 0.0000
Zooming Data
	WE	ST	TE
f (mm)	14.360	45.500	140.500
F NO	3.807	4.059	4.499
2ω (°)	74.1	24.8	8.1
FB (mm)	32.153	44.633	42.874
D1	1.200	21.539	33.781
D2	23.400	8.505	1.122
D3	2.547	11.478	38.777
D4	21.178	14.365	1.900

EXAMPLE 8

r 1 = 93.344	d 1 = 1.500	n d1 = 1.84666	ν d1 = 23.78
r 2 = 46.744	d 2 = 7.922	n d2 = 1.60311	ν d2 = 60.64
r 3 = −524.234	d 3 = 0.100
r 4 = 39.015	d 4 = 6.758	n d3 = 1.49700	ν d3 = 81.54
r 5 = 149.122	d 5 = D1
r 6 = 255.748 (Aspheric)	d 6 = 0.850	n d4 = 1.77250	ν d4 = 49.60
r 7 = 15.824	d 7 = 5.378
r 8 = −31.116 (Aspheric)	d 8 = 0.850	n d5 = 1.80100	ν d5 = 34.97
r 9 = 30.906	d 9 = 0.100
r 10 = 29.966	d 10 = 4.700	n d6 = 1.84666	ν d6 = 23.78
r 11 = −20.823	d 11 = 0.299
r 12 = −18.374	d 12 = 0.800	n d7 = 1.74100	ν d7 = 52.64
r 13 = 92.055	d 13 = D2
r 14 = ∞ (Stop)	d 14 = 0.850
r 15 = 20.681 (Aspheric)	d 15 = 3.712	n d8 = 1.48749	ν d8 = 70.23
r 16 = −25.987	d 16 = D3
r 17 = −34.514	d 17 = 0.800	n d9 = 1.84666	ν d9 = 23.78
r 18 = −52.760	d 18 = 0.800	n d10 = 1.69680	ν d10 = 55.53
r 19 = 243.654	d 19 = D4
r 20 = 29.515	d 20 = 6.403	n d11 = 1.49700	ν d11 = 81.54
r 21 = −36.176	d 21 = 0.700	n d12 = 1.80518	ν d12 = 25.42
r 22 = −224.727	d 22 = 0.100
r 23 = 64.418 (Aspheric)	d 23 = 3.306	n d13 = 1.60311	ν d13 = 60.64
r 24 = −58.349 (Aspheric)
Aspherical Coefficients
6th surface
K = 0.0000
A 4 = 1.4207 × 10 −5
A 6 = 4.9259 × 10 −9
A 8 = 1.6629 × 10 −10
A 10 = 0.0000
8th surface
K = 0.0000
A 4 = −1.6351 × 10 −6
A 6 = −6.4256 × 10 −8
A 8 = −1.4843 × 10 −9
A 10 = 1.3925 × 10 −11
15th surface
K = 0.0000
A 4 = −2.9609 × 10 −5
A 6 = −3.5786 × 10 −8
A 8 = 2.9034 × 10 −10
A 10 = −2.7109 × 10 −12
23th surface
K = 0.0000
A 4 = −5.7466 × 10 −6
A 6 = −7.3847 × 10 −9
A 8 = −1.4914 × 10 −10
A 10 = −7.3752 × 10 −14
24th surface
K = 0.0000
A 4 = 1.0931 × 10 −5
A 6 = −4.7066 × 10 −9
A 8 = −1.8045 × 10 −10
A 10 = 0.0000
Zooming Data
	WE	ST	TE
f (mm)	14.779	45.772	147.778
F NO	3.626	3.917	4.546
2ω (°)	72.5	24.9	7.8
FB (mm)	31.999	45.239	43.572
D1	1.200	21.675	35.000
D2	23.400	8.285	1.122
D3	5.051	12.705	38.777
D4	18.868	12.942	1.900

EXAMPLE 9

r 1 = 94.424	d 1 = 1.500	n d1 = 1.84666	ν d1 = 23.78
r 2 = 47.356	d 2 = 7.922	n d2 = 1.60311	νd d2 = 60.64
r 3 = −742.088	d 3 = 0.100
r 4 = 40.057	d 4 = 6.758	n d3 = 1.49700	ν d3 = 81.54
r 5 = 162.073	d 5 = D1
r 6 = 159.491 (Aspheric)	d 6 = 0.850	n d4 = 1.77250	ν d4 = 49.60
r 7 = 15.691	d 7 = 5.378
r 8 = −32.417 (Aspheric)	d 8 = 0.850	n d5 = 1.80100	ν d5 = 34.97
r 9 = 24.145	d 9 = 0.100
r 10 = 24.714	d 10 = 4.700	n d6 = 1.84666	ν d6 = 23.78
r 11 = −22.131	d 11 = 0.386
r 12 = −19.147	d 12 = 0.800	n d7 = 1.74100	ν d7 = 52.64
r 13 = 103.786	d 13 = D2
r 14 = ∞ (Stop)	d 14 = 0.850
r 15 = 20.649 (Aspheric)	d 15 = 3.985	n d8 = 1.48749	ν d8 = 70.23
r 16 = −27.135	d 16 = D3
r 17 = −40.322 (Aspheric)	d 17 = 0.800	n d9 = 1.84666	ν d9 = 23.78
r 18 = −47.342	d 18 = 0.800	n d10 = 1.69680	ν d10 = 55.53
r19 = 104.936	d 19 = D4
r20 = 32.117	d 20 = 6.314	n d11 = 1.49700	ν d11 = 81.54
r21 = −33.356	d 21 = 0.700	n d12 = 1.80518	ν d12 = 25.42
r22 = −188.199	d 22 = 0.100
r23 = 70.676 (Aspheric)	d 23 = 3.245	n d13 = 1.60311	ν d13 = 60.64
r24 = −51.964 (Aspheric)
Aspherical Coefficients
6th surface
K = 0.0000
A 4 = 1.2395 × 10 −5
A 8 = 6.5047 × 10 −9
A 8 = 1.6230 × 10 −10
A 10 = 0.0000
8th surface
K = 0.0000
A 4 = −1.2587 × 10 −5
A 6 = −6.5323 × 10 −8
A 8 = −1.2827 × 10 −9
A 10 = 1.1688 × 10 −11
15th surface
K = 0.0000
A 4 = −2.8214 × 10 −5
A 6 = −3.8761 × 10 −8
A 8 = 3.6238 × 10 −10
A 10 = −2.8253 × 10 −12
17th surface
K = 0.0000
A 4 = 0.0000
A 6 = 3.7342 × 10 −8
A 8 = −7.4920 × 10 −10
A 10 = 3.6220 × 10 −12
23th surface
K = 0.0000
A 4 = −5.8598 × 10 −6
A 6 = −1.1898 × 10 −8
A 8 = −1.0512 × 10 −10
A 10 = −8.2744 × 10 −14
24th surface
K = 0.0000
A 4 = 8.6207 × 10 −6
A 6 = −8.5201 × 10 −9
A 8 = −1.4232 × 10 −10
A 10 = 0.0000
Zooming Data
	WE	ST	TE
f (mm)	14.778	46.770	150.600
F NO	3.640	4.014	4.937
2ω (°)	72.7	24.4	7.6
FB (mm)	35.808	50.476	56.542
D1	1.200	21.921	35.000
D2	23.400	7.912	1.122
D3	2.451	10.698	36.234
D4	19.769	13.712	1.900

EXAMPLE 10

r 1 = 96.148	d 1 = 1.500	n d1 = 1.84666	ν d1 = 23.78
r 2 = 58.919	d 2 = 8.600	n d2 = 1.60300	ν d2 = 65.44
r 3 = −485.689	d 3 = 0.100
r 4 = 51.466	d 4 = 5.000	n d3 = 1.49700	ν d3 = 81.54
r 5 = 154.194	d 5 =
	(Variable)
r 6 = 181.666 (Aspheric)	d 6 = 0.850	n d4 = 1.80100	ν d4 = 34.97
r 7 = 17.710	d 7 = 5.989
r 8 = −35.508 (Aspheric)	d 8 = 0.850	n d5 = 1.67003	ν d5 = 47.23
r 9 = 19.375	d 9 = 0.100
r 10 = 19.051	d 10 = 4.700	n d6 = 1.84666	ν d6 = 23.78
r 11 = −46.161	d 11 = 1.830
r 12 = −17.851	d 12 = 0.750	n d7 = 1.74100	ν d7 = 52.64
r 13 = −234.238	d 13 =
	(Variable)
r 14 = ∞ (Stop)	d 14 = 1.021
r 15 = 27.177 (Aspheric)	d 15 = 3.750	n d8 = 1.48749	ν d8 = 70.23
r 16 = −27.602	d 16 =
	(Variable)
r 17 = −50.167	d 17 = 0.650	n d9 = 1.77250	ν d9 = 49.60
r 18 = 131.563	d 18 =
	(Variable)
r 19 = 94.372	d 19 = 4.115	n d10 = 1.49700	ν d10 = 81.54
r 20 = −15.230	d 20 = 0.600	n d11 = 1.80518	ν d11 = 25.42
r 21 = −23.459	d 21 = 10.508
r 22 = 43.472 (Aspheric)	d 22 = 5.483	n d12 = 1.60311	ν d12 = 60.64
r 23 = −511.216 (Aspheric)
Aspherical Coefficients
6th surface
K = 0.0000
A 4 = 1.1577 × 10 −5
A 6 = 2.5463 × 10 −8
A 8 = 8.1116 × 10 −11
A 10 = 0.0000
8th surface
K = 0.0000
A 4 = −4.4549 × 10 −6
A 6 = −9.6370 × 10 −8
A 8 = −1.2314 × 10 −9
A 10 = 1.2357 × 10 −11
15th surface
K = 0.0000
A 4 = −2.7369 × 10 −5
A 6 = 1.2966 × 10 −8
A 8 = 4.7574 × 10 −10
A 10 = −4.4510 × 10 −12
22th surface
K = 0.0000
A 4 = 1.0579 × 10 −5
A 6 = 1.8428 × 10 −8
A 8 = 3.1382 × 10 −10
A 10 = −1.4942 × 10 −13
23th surface
K = 0.0000
A 4 = 1.6674 × 10 −5
A 6 = 1.5129 × 10 −8
A 8 = 4.1935 × 10 −10
A 10 = 0.0000
Zooming Data (∞)
	WE	ST	TE
f (mm)	14.550	46.770	140.010
F NO	3.600	4.151	4.412
2ω (°)	73.7	24.1	8.0
FB (mm)	28.650	50.381	50.955
d 5	0.778	22.603	45.158
d 13	23.682	6.989	0.100
d 16	7.181	13.277	21.412
d 18	12.118	3.325	0.100
Focusing Data (1.5 m)
	WE	ST	TE
d 14	1.391	1.577	4.477
d 16	6.811	12.721	17.956

EXAMPLE 11

r 1 = 91.054	d 1 = 1.500	n d1 = 1.84666	ν d1 = 23.78
r 2 = 54.532	d 2 = 8.600	n d2 = 1.60311	ν d2 = 60.64
r 3 = −661.853	d 3 = 0.100
r 4 = 46.573	d 4 = 5.000	n d3 = 1.49700	ν d3 = 81.54
r 5 = 142.871	d 5 =
	(Variable)
r 6 = 95.771 (Aspheric)	d 6 = 0.850	n d4 = 1.80100	ν d4 = 34.97
r 7 = 15.110	d 7 = 6.363
r 8 = −35.351 (Aspheric)	d 8 = 0.850	n d5 = 1.74400	ν d5 = 44.78
r 9 = 18.436	d 9 = 0.100
r 10 = 18.410	d 10 = 4.700	n d6 = 1.84666	ν d6 = 23.78
r 11 = −41.901	d 11 = 1.510
r 12 = −19.590	d 12 = 0.750	n d7 = 1.74100	ν d7 = 52.64
r 13 = −80.542	d 13 =
	(Variable)
r 14 = ∞ (Stop)	d 14 = 0.282
r 15 = 24.082 (Aspheric)	d 15 = 3.750	n d8 = 1.48749	ν d8 = 70.23
r 16 = −35.766	d 16 =
	(Variable)
r 17 = −51.102	d 17 = 0.750	n d9 = 1.77250	ν d9 = 49.60
r 18 = 81.248	d 18 =
	(Variable)
r 19 = 68.833	d 19 = 4.215	n d10 = 1.49700	ν d10 = 81.54
r 20 = −14.308	d 20 = 0.600	n d11 = 1.80518	ν d11 = 25.42
r 21 = −20.792	d 21 = 14.798
r 22 = 19.914 (Aspberic)	d 22 = 1.972	n d12 = 1.60311	νd 12 = 60.64
r 23 = 30.732 (Aspheric)
Aspherical Coefficients
6th surface
K = 0.0000
A 4 = 3.8600 × 10 −6
A 8 = 1.8443 × 10 −8
A 8 = 3.8163 × 10 −11
A 10 = 0.0000
8th surface
K = 0.0000
A 4 = 4.7757 × 10 −6
A 6 = −4.2943 × 10 −8
A 8 = −9.0332 × 10 −10
A 10 = 5.7484 × 10 −12
15th surface
K = 0.0000
A 4 = −2.4127 × 10 −5
A 6 = −5.6179 × 10 −8
A 8 = 1.9592 × 10 −9
A 10 = −1.7954 × 10 −11
22th surface
K = 0.0000
A 4 = −4.2522 × 10 −7
A 6 = −7.5812 × 10 −9
A 8 = 4.7213 × 10 −11
A 10 = 1.3999 × 10 −13
23th surface
K = 0.0000
A 4 = 1.2987 × 10 −5
A 6 = −5.1984 × 10 −10
A 8 = 1.2972 × 10 −10
A 10 = 0.0000
Zooming Data (∞)
	WE	ST	TE
f (mm)	14.550	46.770	140.010
F NO	3.672	4.171	4.133
2ω (°)	73.7	24.2	8.2
FB (mm)	27.005	41.973	52.142
d 5	0.778	25.830	41.824
d 13	28.150	10.799	0.100
d 16	7.647	12.713	20.000
d 18	8.506	4.515	1.068
Focusing Data (1.5m)
	WE	ST	TE
d 13	28.399	11.627	3.701

EXAMPLE 12

r 1 = 95.816	d 1 = 1.500	n d1 = 1.84666	ν d1 = 23.78
r 2 = 57.080	d 2 = 8.600	n d2 = 1.60311	ν d2 = 60.64
r 3 = −595.877	d 3 = 0.100
r 4 = 51.891	d 4 = 5.000	n d3 = 1.49700	ν d3 = 81.54
r 5 = 159.655	d 5 =
	(Variable)
r 6 = 60.918 (Aspheric)	d 6 = 0.850	n d4 = 1.80100	νd 4 = 34.97
r 7 = 13.633	d 7 = 6.759
r 8 = −30.855 (Aspheric)	d 8 = 0.850	n d5 = 1.74400	ν d5 = 44.78
r 9 = 22.170	d 9 = 0.100
r 10 = 21.443	d 10 = 4.700	n d6 = 1.84666	ν d6 = 23.78
r 11 = −37.460	d 11 = 1.540
r 12 = −18.028	d 12 = 0.750	n d7 = 1.74100	ν d7 = 52.64
r 13 = −51.094	d 13 =
	(Variable)
r 14 = ∞ (Stop)	d 14 = 1.132
r 15 = 21.530 (Aspheric)	d 15 = 3.750	n d5 = 1.48749	ν d5 = 70.23
r 16 = −30.476	d 16 =
	(Variable)
r 17 = −33.630	d 17 = 0.750	n d9 = 1.77250	ν d9 = 49.60
r 18 = 37.540	d 18 =
	(Variable)
r 19 = 34.660	d 19 = 4.369	n d10 = 1.49700	ν d10 = 81.54
r 20 = −13.974	d 20 = 0.600	n d11 = 1.80518	ν d11 = 25.42
r21 = −20.668	d 21 =
	(Variable)
r22 = 24.634 (Aspheric)	d 22 = 2.383	n d12 = 1.60311	ν d12 = 60.64
r23 = 66.482 (Aspheric)
Aspherical Coefficients
6th surface
K = 0.0000
A 4 = 8.1433 × 10 −7
A 6 = 1.0353 × 10 −8
A 8 = 5.3072 × 10 −11
A 10 = 0.0000
8th surface
K = 0.0000
A 4 = 9.3299 × 10 −6
A 6 = −3.4823 × 10 −8
A 8 = −7.3408 × 10 −10
A 10 = 4.7042 × 10 −12
15th surface
K = 0.0000
A 4 = −2.8541 × 10 −5
A 6 = −1.0861 × 10 −8
A 8 = 5.2954 × 10 −10
A 10 = −5.5308 × 10 −12
22th surface
K = 0.0000
A 4 = 8.4723 × 10 −6
A 6 = 1.4247 × 10 −8
A 8 = −7.7053 × 10 −11
A 10 = −3.9331 × 10 −14
23th surface
K = 0.0000
A 4 = 2.3171 × 10 −5
A 6 = 1.9749 × 10 −8
A 8 = −9.1947 × 10 −11
A 10 = 0.0000
Zooming Data (∞)
	WE	ST	TE
f (mm)	14.552	46.776	140.007
F NO	3.774	4.390	4.610
2ω (°)	73.7	24.1	8.1
FB (mm)	26.992	47.883	50.064
d 5	0.778	24.541	46.406
d 13	29.032	8.977	0.100
d 16	10.019	13.654	20.000
d 18	4.093	2.113	1.089
d 21	14.116	13.418	11.011
Focusing Data (2.0 m)
	WE	ST	TE
d 18	6.347	2.677	4.707
d 21	11.862	12.855	7.393

EXAMPLE 13

r 1 = 92.253	d 1 = 1.500	n d1 = 1.84666	ν d1 = 23.78
r 2 = 54.366	d 2 = 8.600	n d2 = 1.60311	ν d2 = 60.64
r 3 = −726.787	d 3 = 0.100
r 4 = 48.804	d 4 = 5.000	n d3 = 1.49700	ν d3 = 81.54
r 5 = 157.176	d 5 = (Variable)
r 6 = 92.290 (Aspheric)	d 6 = 0.850	n d4 = 1.80100	ν d4 = 34.97
r 7 = 15.216	d 7 = 6.827
r 8 = −29.675 (Aspheric)	d 8 = 0.850	n d5 = 1.74400	ν d5 = 44.78
r 9 = 20.119	d 9 = 0.100
r 10 = 20.429	d 10 = 4.700	n d6 = 1.84666	ν d6 = 23.78
r 11 = −31.752	d 11 = 1.748
r 12 = −17.416	d 12 = 0.750	n d7 = 1.74100	ν d7 = 52.64
r 13 = −63.633	d 13 = (Variable)
r 14 = ∞ (Stop)	d 14 = 0.862
r 15 = 23.893 (Aspheric)	d 15 = 3.750	n d8 = 1.49700	ν d8 = 81.54
r 16 = −32.227	d 16 = (Variable)
r 17 = −20.715	d 17 = 0.700	n d9 = 1.77250	ν d9 = 49.60
r 18 = 72.399	d 18 = (Variable)
r 19 = 34.516	d 19 = 4.000	n d10 = 1.49700	ν d10 = 81.54
r 20 = −15.986	d 20 = 0.600	n d11 = 1.80518	ν d11 = 25.42
r 21 = −21.973	d 21 = (Variable)
r 22 = 30.431 (Aspheric)	d 22 = 3.605	n d12 = 1.49700	ν d12 = 81.54
r 23 = −93.324 (Aspheric)
Aspherical Coefficients
6th surface
K = 0.0000
A 4 = 3.5498 × 10 −6
A 6 = 2.1901 × 10 −8
A 8 = 3.7413 × 10 −11
A 10 = 0.0000
8th surface
K = 0.0000
A 4 = 5.7125 × 10 −6
A 6 = −1.8826 × 10 −8
A 8 = −1.2043 × 10 −9
A 10 = 8.1735 × 10 −12
15th surface
K = 0.0000
A 4 = −1.5544 × 10 −5
A 6 = −1.2826 × 10 −8
A 8 = 4.4582 × 10 −10
A 10 = −4.6850 × 10 −12
22th surface
K = 0.0000
A 4 = 3.1293 × 10 −6
A 6 = 1.3890 × 10 −8
A 8 = 1.2058 × 10 −10
A 10 = 1.5944 × 10 −13
23th surface
K = 0.0000
A 4 = 2.6066 × 10 −5
A 6 = 2.1615 × 10 −8
A 8 = 1.9517 × 10 −10
A 10 = 0.0000
	WE	ST	TE
Zooming Data (∞)
f (mm)	14.550	46.780	140.010
F NO	3.777	3.995	4.486
2ω (°)	73.7	24.2	8.2
FB (mm)	32.496	56.263	56.430
d 5	0.778	22.488	43.818
d 13	27.986	5.791	0.100
d 16	10.827	15.345	24.345
d 18	2.034	2.114	0.330
d 21	10.101	7.132	4.676
Focusing Data (2.0 m)
d 16	10.480	15.058	22.299
d 18	2.381	2.400	2.376

EXAMPLE 14

r 1 = 92.732	d 1 = 1.000	n d1 = 1.84666	ν d1 = 23.78
r 2 = 47.739	d 2 = 8.300	n d2 = 1.60311	ν d2 = 60.64
r 3 = −488.337	d 3 = 0.100
r 4 = 42.637	d 4 = 4.700	n d3 = 1.49700	ν d3 = 81.54
r 5 = 227.099	d 5 = D1
r 6 = 96.419 (Aspheric)	d 6 = 0.850	n d4 = 1.80440	ν d4 = 39.59
r 7 = 14.529	d 7 = 5.956
r 8 = −26.923 (Aspheric)	d 8 = 0.850	n d5 = 1.56384	ν d5 = 60.67
r 9 = 39.191	d 9 = 0.100
r 10 = 24.863	d 10 = 4.700	n d6 = 1.84666	ν d6 = 23.78
r 11 = −37.221	d 11 = 1.721
r 12 = −20.880	d 12 = 0.750	n d7 = 1.77250	ν d7 = 49.60
r 13 = 49.565	d 13 = D2
r 14 = ∞ (Stop)	d 14 = 0.850
r 15 = 21.783 (Aspheric)	d 15 = 3.750	n d8 = 1.48749	ν d8 = 70.23
r 16 = −23.450	d 16 = D3
r 17 = −38.194	d 17 = 0.800	n d9 = 1.77250	ν d9 = 49.60
r 18 = 221.672	d 18 = D4
r 19 = 41.619	d 19 = 4.980	n d10 = 1.49700	ν d10 = 81.54
r 20 = −20.464	d 20 = 0.700	n d11 = 1.72047	ν d11 = 34.71
r 21 = 187.998	d 21 = 0.100
r 22 = 47.492 (Aspheric)	d 22 = 4.200	n d12 = 1.60311	ν d12 = 60.64
r 23 = −26.561 (Aspheric)
Aspherical Coefficients
6th surface
K = 0.0000
A 4 = 6.7898 × 10 −6
A 6 = −9.2108 × 10 −9
A 8 = 1.4640 × 10 −10
A 10 = 0.0000
8th surface
K = 0.0000
A 4 = −8.2805 × 10 −6
A 6 = −5.3194 × 10 −8
A 8 = −2.6611 × 10 −10
A 10 = 1.0752 × 10 −12
15th surface
K = 0.0000
A 4 = −3.4825 × 10 −5
A 6 = −1.6376 × 10 −8
A 8 = 2.1716 × 10 −10
A 10 = −1.6667 × 10 −12
22th surface
K = 0.0000
A 4 = −1.3153 × 10 −5
A 6 = 2.2004 × 10 −9
A 8 = −2.3448 × 10 −11
A 10 = −3.2741 × 10 −14
23th surface
K = 0.0000
A 4 = 8.3246 × 10 −6
A 6 = −3.4485 × 10 −9
A 8 = −4.3878 × 10 −11
A 10 = 0.0000
Zooming Data
	WE	ST	TE
f (mm)	14.360	45.500	140.500
F NO	3.610	3.856	4.412
2ω (°)	74.3	24.5	8.0
FB (mm)	36.325	51.559	54.452
D1	0.900	20.817	35.000
D2	19.062	6.427	1.122
D3	1.926	10.865	35.040
D4	15.928	9.416	0.200

EXAMPLE 15

r 1 = 91.455	d 1 = 1.000	n d1 = 1.84666	ν d1 = 23.78
r 2 = 48.394	d 2 = 8.300	n d2 = 1.60311	ν d2 = 60.64
r 3 = −475.695	d 3 = 0.100
r 4 = 39.058	d 4 = 4.700	n d3 = 1.49700	ν d3 = 81.54
r 5 = 173.878	d 5 = D1
r 6 = 249.686 (Aspheric)	d 6 = 0.850	n d4 = 1.80440	ν d4 = 39.59
r 7 = 15.550	d 7 = 5.378
r 8 = −37.130 (Aspheric)	d 8 = 0.850	n d5 = 1.77250	ν d5 = 49.60
r 9 = 27.693	d 9 = 0.100
r 10 = 25.326	d 10 = 4.700	n d6 = 1.84666	ν d6 = 23.78
r 11 = −33.814	d 11 = 3.393
r 12 = −20.408	d 12 = 0.750	n d7 = 1.69680	ν d7 = 55.53
r 13 = 47.449	d 13 = D2
r 14 = ∞ (Stop)	d 14 = 0.850
r 15 = 18.878 (Aspheric)	d 15 = 3.750	n d8 = 1.49700	ν d8 = 81.54
r 16 = −22.392 (Aspheric)	d 16 = D3
r 17 = −50.167	d 17 = 0.750	n d9 = 1.65160	ν d9 = 58.55
r 18 = 81.160	d 18 = D4
r 19 = 26.650	d 19 = 4.980	n d10 = 1.49700	ν d10 = 81.54
r 20 = −36.101	d 20 = 0.700	n d11 = 1.72151	ν d11 = 29.23
r 21 = 167.248	d 21 = 0.100
r 22 = 38.733 (Aspheric)	d 22 = 3.299	n d12 = 1.49700	ν d12 = 81.54
r 23 = −43.922 (Aspheric)
Aspherical Coefficients
6th surface
K = 0.0000
A 4 = 1.3560 × 10 −5
A 6 = −2.7838 × 10 −8
A 8 = 2.7765 × 10 −10
A 10 = 0.0000
8th surface
K = 0.0000
A 4 = −1.8704 × 10 −5
A 6 = −4.2196 × 10 −8
A 8 = −1.5662 × 10 −9
A 10 = 5.1874 × 10 −12
15th surface
K = 0.0000
A 4 = −5.0036 × 10 −5
A 6 = −7.7701 × 10 −8
A 8 = 3.3163 × 10 −10
A 10 = −8.6465 × 10 −13
16th surface
K = 0.0000
A 4 = −3.6933 × 10 −6
A 6 = −1.6996 × 10 −8
A 8 = −4.5515 × 10 −10
A 10 = 2.6501 × 10 −12
22th surface
K = 0.0000
A 4 = −1.4727 × 10 −5
A 6 = 1.8739 × 10 −8
A 8 = −8.4912 × 10 −10
A 10 = −3.0859 × 10 −13
23th surface
K = 0.0000
A 4 = 1.5156 × 10 −5
A 6 = 2.1860 × 10 −8
A 8 = −9.3080 × 10 −10
A 10 = 0.0000
Zooming Data
	WE	ST	TE
f (mm)	14.360	40.287	140.500
F NO	3.500	3.715	4.150
2ω (°)	74.8	27.5	8.0
FB (mm)	32.549	41.368	39.987
D1	0.900	21.625	35.000
D2	14.169	6.440	1.122
D3	1.140	9.500	43.063
D4	18.000	12.253	0.150

EXAMPLE 16

r 1 = 85.330	d 1 = 1.000	n d1 = 1.84666	ν d1 = 23.78
r 2 = 46.980	d 2 = 8.300	n d2 = 1.60311	ν d2 = 60.64
r 3 = −1063.508	d 3 = 0.100
r 4 = 41.824	d 4 = 4.700	n d3 = 1.49700	ν d3 = 81.54
r 5 = 249.075	d 5 = D1
r 6 = 135.180 (Aspheric)	d 6 = 0.850	n d4 = 1.80440	ν d4 = 39.59
r 7 = 14.859	d 7 = 5.446
r 8 = −33.108 (Aspheric)	d 8 = 0.850	n d5 = 1.77250	ν d5 = 49.60
r 9 = 27.342	d 9 = 0.100
r 10 = 25.241	d 10 = 4.700	n d6 = 1.84666	ν d6 = 23.78
r 11 = −32.138	d 11 = 4.430
r 12 = −20.508	d 12 = 0.750	n d7 = 1.69680	ν d7 = 55.53
r 13 = 51.683	d 13 = D2
r 14 = ∞ (Stop)	d 14 = 0.850
r 15 = 19.422 (Aspheric)	d 15 = 3.750	n d8 = 1.49700	ν d8 = 81.54
r 16 = −22.918 (Aspheric)	d 16 = D3
r 17 = −50.167	d 17 = 0.750	n d9 = 1.65160	ν d9 = 58.55
r 18 = 65.609	d 18 = D4
r 19 = 38.189	d 19 = 4.980	n d10 = 1.49700	ν d10 = 81.54
r 20 = −20.431	d 20 = 0.700	n d11 = 1.72151	ν d11 = 29.23
r 21 = −49.533	d 21 = 0.100
r 22 = 37.598 (Aspheric)	d 22 = 8.681	n d12 = 1.49700	ν d12 = 81.54
r 23 = −148.010 (Aspheric)
Aspherical Coefficients
6th surface
K = 0.0000
A 4 = 3.9431 × 10 −6
A 6 = −1.6805 × 10 −8
A 8 = 2.9386 × 10 −10
A 10 = 0.0000
8th surface
K = 0.0000
A 4 = −8.8064 × 10 −6
A 6 = −3.8046 × 10 −8
A 8 = −1.6882 × 10 −9
A 10 = 4.4823 × 10 −12
15th surface
K = 0.0000
A 4 = −5.0081 × 10 −5
A 6 = −6.4167 × 10 −8
A 8 = 1.8107 × 10 −10
A 10 = 3.7880 × 10 −12
16th surface
K = 0.0000
A 4 = −7.1882 × 10 −6
A 6 = −2.3229 × 10 −8
A 8 = −6.0073 × 10 −10
A 10 = 3.7880 × 10 −12
22th surface
K = 0.0000
A 4 = −2.0848 × 10 −6
A 6 = −6.4374 × 10 −9
A 8 = 3.8678 × 10 −11
A 10 = 1.6757 × 10 −13
23th surface
K = 0.0000
A 4 = 1.4490 × 10 −5
A 6 = −1.0858 × 10 −8
A 8 = 9.0082 × 10 −11
A 10 = 0.0000
Zooming Data
	WE	ST	TE
f (mm)	14.360	39.998	140.500
F NO	3.517	3.640	4.363
2ω (°)	74.9	27.8	8.0
FB (mm)	32.026	43.978	47.577
D1	0.900	20.182	35.000
D2	13.829	5.713	1.122
D3	1.140	9.817	38.094
D4	17.013	11.229	0.150

EXAMPLE 17

r 1 = 70.826	d 1 = 1.000	n d1 = 1.84666	ν d1 = 23.78
r 2 = 43.617	d 2 = 8.300	n d2 = 1.49700	ν d2 = 81.54
r 3 = −510.138	d 3 = 0.100
r 4 = 40.870	d 4 = 4.700	n d3 = 1.49700	ν d3 = 81.54
r 5 = 254.034	d 5 = D1
r 6 = 54.673 (Aspheric)	d 6 = 0.850	n d4 = 1.72916	ν d4 = 54.68
r 7 = 13.132	d 7 = 5.378
r 8 = −25.077 (Aspheric)	d 8 = 0.850	n d5 = 1.77250	ν d5 = 49.60
r 9 = 24.387	d 9 = 0.100
r 10 = 25.057	d 10 = 4.700	n d6 = 1.84666	ν d6 = 23.78
r 11 = −28.485	d 11 = 3.498
r 12 = −17.701	d 12 = 0.750	n d7 = 1.77250	ν d7 = 49.60
r 13 = 464.466	d 13 = D2
r 14 = ∞ (Stop)	d 14 = 0.850
r 15 = 23.510 (Aspheric)	d 15 = 3.750	n d8 = 1.49700	ν d8 = 81.54
r 16 = −19.292 (Aspheric)	d 16 = D3
r 17 = −26.953	d 17 = 0.800	n d9 = 1.77250	ν d9 = 49.60
r 18 = 337.402	d 18 = D4
r 19 = 33.463	d 19 = 4.980	n d10 = 1.48749	ν d10 = 70.23
r 20 = −22.760	d 20 = 0.700	n d11 = 1.66680	ν d11 = 33.05
r 21 = −174.710	d 21 = 0.100
r 22 = 66.809 (Aspheric)	d 22 = 4.048	n d12 = 1.49700	ν d12 = 81.54
r 23 = −23.806 (Aspheric)
Aspherical Coefficients
6th surface
K = 0.0000
A 4 = −3.2997 × 10 −6
A 6 = 6.1402 × 10 −9
A 8 = 3.5468 × 10 −10
A 10 = 0.0000
8th surface
K = 0.0000
A 4 = 3.7305 × 10 −6
A 6 = 3.2973 × 10 −9
A 8 = −3.1950 × 10 −9
A 10 = 1.8754 × 10 −11
15th surface
K = 0.0000
A 4 = −3.9222 × 10 −5
A 6 = 1.5884 × 10 −8
A 8 = 1.0595 × 10 −10
A 10 = −8.3897 × 10 −13
16th surface
K = 0.0000
A 4 = −7.1882 × 10 −6
A 6 = −2.3229 × 10 −8
A 8 = −6.0073 × 10 −10
A 10 = 3.7880 × 10 −12
22th surface
K = 0.0000
A 4 = −2.2483 × 10 −5
A 6 = −3.5594 × 10 −9
A 8 = −9.0793 × 10 −11
A 10 = −4.0807 × 10 −15
23th surface
K = 0.0000
A 4 = 8.5333 × 10 −6
A 6 = −5.0694 × 10 −9
A 8 = −1.0354 × 10 −10
A 10 = 0.0000
Zooming Data
	WE	ST	TE
f (mm)	14.360	44.216	140.500
F NO	3.244	3.675	4.435
2ω (°)	74.3	25.2	8.0
FB (mm)	38.840	52.619	52.237
D1	0.900	20.777	35.000
D2	12.237	4.382	1.122
D3	1.140	11.256	36.032
D4	13.750	7.615	0.150

FIGS. 18-26 are aberration diagrams for Examples 1-9 upon focused at infinity, FIGS. 27 , 29 , 31 and 33 are aberration diagrams for Examples 10-13 upon focused at infinity, and FIGS. 28 , 30 , 32 and 34 are aberration diagrams for Examples 10-13 upon focused on a finite point In these aberration diagrams, (a), (b) and (c) represent the wide-angle end, intermediate settings and telephoto end, respectively, and SA, AS, DT and CC stand for spherical aberrations, astigmatism, distortion and chromatic aberration of magnification, respectively, with “IH” representing an image height.

Enumerated below are the values of conditions (1) to (9) in the respective examples.

	(1)	(2)	(3)	(4)	(5)
Example 1	4.713	0.8112	0.6711	3.0433	2.3866
Example 2	4.7963	0.8290	0.8217	1.4078	0.9391
Example 3	4.5528	0.8007	0.6936	1.3452	2.5083
Example 4	4.5528	0.8007	0.6936	1.3452	0.9673
Example 5	4.5464	0.8000	0.6936	1.3451	0.9673
Example 6	4.5494	0.7891	0.6850	1.3113	0.9794
Example 7	4.5494	0.7891	0.685	1.3113	0.9794
Example 8	4.6889	0.7834	0.6658	1.1169	0.9154
Example 9	4.8424	0.7988	0.7073	1.1646	0.9817
Example 10	5.5936	0.8477	0.8288	1.3538	0.9289
Example 11	5.3362	0.8928	0.9010	1.2109	0.9357
Example 12	5.7316	0.9159	0.7348	0.6337	0.7045
Example 13	5.5056	0.8894	0.8395	0.6180	0.6660
Example 14	4.7735	0.7553	0.8162	1.4436	1.0996
Example 15	4.5699	0.6463	0.6327	1.4135	0.9675
Example 16	4.6404	0.6414	0.6853	1.3684	0.9988
Example 17	4.6593	0.6673	0.6590	0.9687	0.8219
	(6)	(7)	(8)	(9)
Example 1	18.2945	2.9436	2.2015	3.5584
Example 2	17.4949	3.1484	2.3460	3.6099
Example 3	21.4960	2.5389	1.9028	3.7708
Example 4	20.6438	2.5784	1.8914	3.7708
Example 5	11.6154	2.8850	1.7807	3.7708
Example 6	21.4107	2.5398	1.8496	3.7798
Example 7	17.4466	2.6445	1.8745	3.7798
Example 8	27.2847	2.6967	1.9171	3.6999
Example 9	19.3228	4.7581	2.4800	3.3351
Example 10	13.4069	1.7400	1.6851	4.4130
Example 11	12.1372	2.9586	2.0654	4.2023
Example 12	12.5236	2.9989	1.5855	4.3006
Example 13	11.6802	3.1256	2.0841	4.2529
Example 14	14.8712	3.5984	2.4800	3.6144
Example 15	14.8712	1.2623	2.9388	4.0074
Example 16	13.6554	3.9717	2.4819	3.8190
Example 17	15.3941	4.0162	2.4156	3.8034

The zoom lens system according to the present invention may be used in the form of a phototaking optical system for image pickup equipment. FIGS. 35 to 37 are illustrative of the concept of a digital camera that is one embodiment of the image pickup system according to the present invention. FIG. 35 is a front perspective view showing the appearance of a digital camera 10 , FIG. 36 is a rear perspective view of the digital camera 10 , and FIG. 37 is a sectional view illustrative of the construction of the digital camera 10 . The illustrated digital camera 10 comprises a phototaking optical system 11 having a phototaking optical path 12 , a finder optical system 13 having a finder optical path 14 , a shutter button 15 , a flash 16 and a liquid crystal monitor 17 . As the shutter button 15 located on the upper portion of camera 10 is pressed down, an object is phototaken through the phototaking optical system 11 , for instance, the zoom lens system embodied by Example 1 ( FIG. 1 ) of the present invention. An object image is formed on the image pickup plane of an electronic image pickup device (CCD) 19 via a phototaking optical system 11 , and filters F 1 , F 2 , etc. such as a low-pass filter and an infrared cut filter. The object image sensed by CCD 19 is displayed as an electronic image on the liquid crystal monitor 17 mounted on the back side of camera 10 via processing means 21 . The processing means 21 may be connected with recording means 22 for recording the phototaken electronic image. It is here noted that the recording means 22 may be provided separately from the processing means 21 or, alternatively, the electronic image may be electronically written onto a floppy disk, a memory card, a MO or the like. The camera 10 may be designed as a silver salt camera having a silver salt film in place of CCD 19 .

Moreover, a finder objective optical system 23 is positioned on the finder optical path 14 . An object image formed by the finder objective optical system 23 is then formed on a field frame 24 of a Porro prism 25 that is an image erecting member. In the rear of Porro prism 25 , there is provided an eyepiece optical system 29 for guiding the erected image to the eyeball E of an observer. Three cover members 20 are provided; one on the emergent side of the eyepiece optical system 29 and two on the incident sides of the phototaking optical system 11 and finder objective optical system 23 .

In the thus constructed digital camera 10 , the phototaking optical system 11 is a compact zoom lens system having a wide field angle and a high zoom ratio with well-corrected aberrations. It is thus possible to achieve high performance as well as significant cost reductions.

According to the present invention as detailed above, it is possible to provide not only a simple high-magnification zoom lens system but also a wide-angle yet high-magnification zoom lens system encompassing a field angle of about 70° or greater. For this reason, it is possible to achieve a proper zooming mode and power profile, proper lens arrangements and effective use of aspherical surfaces.

According to the present invention, there can also be provided a zoom lens system comprising, in order from its object side, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, wherein focusing is carried out using the third, the fourth, and the fifth lens group, respectively. The present focusing method wherein only a single or cemented lens is moved with the power profile according to the present invention is so effective for reducing fluctuations of aberrations as well as for other purposes that it will find use as a variety of future wide-angle yet high-magnification zoom lens systems for videos or still video purposes.

Moreover, there can be provided a method of compensating for an image movement due to the movement of an optimum lens group in such a zoom lens system.

Claims

1. A zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, wherein:for zooming from a wide-angle end to a telephoto end of said zoom lens system, a spacing between said first lens group and said second lens group and a spacing between said third lens group and said fourth lens group becomes wider and a spacing between said second lens group and said third lens group and a spacing between said fourth lens group and said fifth lens group becomes narrower, and the following conditions are satisfied: 4.5464≦f1/fw<8.0  (1) 0.4<|f2/fw|<1.0  (2) 0.3<f3/fT345<1.2  (3) 0.6<|f4|/fT345<5.0  (4) 0.5<f5/fT345<4.0  (5) where fw is a focal length of said zoom lens system at said wide-angle end, f1 is a focal length of said first lens group, f2 is a focal length of said second lens group, f3 is a focal length of said third lens group, f4 is a focal length of said fourth lens group, f5 is a focal length of said fifth lens group, and fT345 is a focal length of said third lens group to said fifth lens group at said telephoto end.

2. A zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, wherein:for zooming from a wide-angle end to a telephoto end of said zoom lens system, a spacing between said first lens group and said second lens group and a spacing between said third lens group and said fourth lens group becomes wider and a spacing between said second lens group and said third lens group and a spacing between said fourth lens group and said fifth lens group becomes narrower, and the following conditions are satisfied: 4.5464≦f1/fw<8.0  (1) 0.4<|f2/fW|<1.0  (2) 0.3<f3/fT345<1.2  (3) 0.6<|f4|/fT345<5.0  (4) 0.5<f5/fT345<4.0  (5) where fw is a focal length of said zoom lens system at said wide-angle end, f1 is a focal length of said first lens group, f2 is a focal length of said second lens group, f3 is a focal length of said third lens group, f4 is a focal length of said fourth lens group, f5 is a focal length of said fifth lens group, and fT345 is a focal length of said third lens group to said fifth lens group at said telephoto end,wherein the focal length of said zoom lens system at said wide-angle end is shorter than an effective diagonal length of an image plane of an optical system or an image pickup device.

3. A zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, wherein:for zooming from a wide-angle end to a telephoto end of said zoom lens system, a spacing between said first lens group and said second lens group and a spacing between said third lens group and said fourth lens group becomes wider and a spacing between said second lens group and said third lens group and a spacing between said fourth lens group and said fifth lens group becomes narrower, and the following conditions are satisfied: 4.5464≦f1/fw<8.0  (1) 0.4<|f2/fW|<1.0  (2) 0.3<f3/fT345<1.2  (3) 0.6<|f4|/fT345<5.0  (4) 0.5<f5/fT345<4.0  (5) where fw is a focal length of said zoom lens system at said wide-angle end, f1 is a focal length of said first lens group, f2 is a focal length of said second lens group, f3 is a focal length of said third lens group, f4 is a focal length of said fourth lens group, f5 is a focal length of said fifth lens group, and fT345 is a focal length of said third lens group to said fifth lens group at said telephoto end,wherein a principal ray emerging from an optical system is determined on the basis of the following condition: 10<|Expdw×Y|/Lw  (6) where Expdw is an optical axis distance from an image-formation plane position to an exit pupil, Y is an actual maximum image height on said image-formation plane, and Lw is an optical axis distance at said wide-angle end from an apex of a surface located nearest to said object side in said first lens group to said image-formation plane.

4. A zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, wherein:for zooming from a wide-angle end to a telephoto end of said zoom lens system, a spacing between said first lens group and said second lens group and a spacing between said third lens group and said fourth lens group becomes wider and a spacing between said second lens group and said third lens group and a spacing between said fourth lens group and said fifth lens group becomes narrower, and the following conditions are satisfied: 4.5464≦f1/fw<8.0  (1) 0.4<|f2/fW|1.0  (2) 0.3<f3/fT345<1.2  (3) 0.6<|f4|/fT345<5.0  (4) 0.5<f5/fT345<4.0  (5) where fw is a focal length of said zoom lens system at said wide-angle end, f1 is a focal length of said first lens group, f2 is a focal length of said second lens group, f3 is a focal length of said third lens group, f4 is a focal length of said fourth lens group, f5 is a focal length of said fifth lens group, and fT345 is a focal length of said third lens group to said fifth lens group at said telephoto end,wherein the following conditions upon zooming from said wide-angle end to said telephoto end: 1.6<Δ1T/fw<5.0  (7)  1.0<Δ3T/fw<4.0  (8)where Δ1T is an amount of zooming movement of said first lens group to said telephoto end, as measured on the basis of said wide angle end, and Δ3T is an amount of zooming movement of said third lens group to said telephoto end, as measured on the basis of said wide-angle end.

5. A zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, wherein:for zooming from a wide-angle end to a telephoto end of said zoom lens system, a spacing between said first lens group and said second lens group and a spacing between said third lens group and said fourth lens group becomes wider and a spacing between said second lens group and said third lens group and a spacing between said fourth lens group and said fifth lens group becomes narrower, and the following conditions are satisfied: 4.5464<f1/fW<8.0  (1) 0.4<|f2/fw|<1.0  (2) 0.3<f3/fT345<1.2  (3) 0.6<|f4|/fT345<5.0  (4) 0.5<f5/fT345<4.0  (5) where fw is a focal length of said zoom lens system at said wide-angle end, f1 is a focal length of said first lens group, f2 is a focal length of said second lens group, f3 is a focal length of said third lens group, f4 is a focal length of said fourth lens group, f5 is a focal length of said fifth lens group, and fT345 is a focal length of said third lens group to said fifth lens group at said telephoto end,wherein said second lens group has a paraxial transverse magnification satisfying the following condition: 2.5<β2T/β2W<7  (9) where β2W is an image-formation magnification of said second lens group at said wide-angle end, and β2T is an image-formation magnification of said second lens group at said telephoto end.

6. The zoom lens system according to claim 1, characterized in that said first lens group comprises at least one negative lens and a positive lens.

7. The zoom lens system according to claim 1, characterized in that said second lens group comprises at least two negative lens and one positive lens.

8. The zoom lens system according to claim 1, characterized in that said third lens group comprises at least one positive lens.

9. The zoom lens system according to claim 1, characterized in that said fourth lens group comprises at least one negative lens.

10. The zoom lens system according to claim 1, characterized in that said fifth lens group comprises at least one negative positive lens and one negative lens.

11. A zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, wherein:for zooming from a wide-angle end to a telephoto end of said zoom lens system, a spacing between said first lens group and said second lens group and a spacing between said third lens group and said fourth lens group becomes wider and a spacing between said second lens group and said third lens group and a spacing between said fourth lens group and said fifth lens group becomes narrower, and said zoom lens system is focused on a finite object by moving said third lens group or a lens or lenses therein the first lens group moves along the optical axis during zooming from the wide-angle to the telephoto end, and the system is focused on a finite object by movement of only the third lens group or only a lens or lenses in the third lens group.

12. A zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, wherein:for zooming from a wide-angle end to a telephoto end of said zoom lens system, a spacing between said first lens group and said second lens group and a spacing between said third lens group and said fourth lens group becomes wider and a spacing between said second lens group and said third lens group and a spacing between said fourth lens group and said fifth lens group becomes narrower, and said zoom lens system is focused on a finite object by moving said fourth lens group or a lens or lenses therein, the system is focused on a finite object by movement of only the fourth lens group or only a lens or lenses in the fourth lens group.

13. A zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, wherein:for zooming from a wide-angle end to a telephoto end of said zoom lens system, a spacing between said first lens group and said second lens group and a spacing between said third lens group and said fourth lens group becomes wider and spacing between said second lens group and said third lens group and a spacing between said fourth lens group and said fifth lens group becomes narrower, and said zoom lens system is focused on a finite object by moving said fifth lens group or a lens or lenses therein, the first lens group moves along the optical axis during zooming from the wide-angle to the telephoto end, and the system is focused on a finite object by movement of only the fifth lens group or only a lens or lenses in the fifth lens group.

14. A zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, wherein:for zooming from a wide-angle end to a telephoto end of said zoom lens system, each of said first lens group to said fifth lens group moves while said first lens group and said third lens group move toward said object side during said zooming in such a way that spacing between said first lens group and said second lens group and between said third lens group and said fourth lens group becomes wider, a fluctuation of an image plane position with said zooming is compensated for by nonlinear movement of at least one of said third lens group, said fourth lens group and said fifth lens group, and the following conditions are satisfied: 4.5464≦f1/fW<8.0  (1) 0.4<|f2/fw<1.0  (2) 0.3<f3/fT345<1.2  (3) 0.6<|f4|/fT345<5.0  (4) 0.5<f5/fT345<4.0  (5) where fw is a focal length of said zoom lens system at said wide-angle end, f1 is a focal length of said first lens group, f2 is a focal length of said second lens group, f3 is a focal length of said third lens group, f4 is a focal length of said fourth lens group, f5 is a focal length of said fifth lens group, and fT345 is a focal length of said third lens group to said fifth lens group at said telephoto end.

15. A zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, wherein:for zooming from a wide-angle end to a telephoto end of said zoom lens system, each of said first lens group to said fifth lens group moves while said first lens group and said third lens group move toward said object side during said zooming in such a way that spacing between said first lens group and said second lens group and between said third lens group and said fourth lens group becomes wider, a fluctuation of an image plane position with said zooming is compensated for by nonlinear movement of at least one of said third lens group, said fourth lens group and said fifth lens group, and the following conditions are satisfied: 2.0<f1/fW<8.0  (1) 0.4<|f2/fw|<1.0  (2) 0.3<f3/fT345<1.2  (3) 0.6<|f4|/fT345<5.0  (4) 0.5<f5/fT345<4.0  (5) where fw is a focal length of said zoom lens system at said wide-angle end, f1 is a focal length of said first lens group, f2 is a focal length of said second lens group, f3 is a focal length of said third lens group, f4 is a focal length of said fourth lens group, f5 is a focal length of said fifth lens group, and fT345 is a focal length of said third lens group to said fifth lens group at said telephoto endwherein an image movement occurring by movement of said zoom lens system is corrected by moving said third lens group substantially vertically with respect to an optical axis of said zoom lens system.

16. A zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, wherein:for zooming from a wide-angle end to a telephoto end of said zoom lens system, each of said first lens group to said fifth lens group moves while said first lens group and said third lens group move toward said object side during said zooming in such a way that spacing between said first lens group and said second lens group and between said third lens group and said fourth lens group becomes wider, a fluctuation of an image plane position with said zooming is compensated for by nonlinear movement of at least one of said third lens group, said fourth lens group and said fifth lens group, and the following conditions are satisfied: 2.0<f1/fW<8.0  (1) 0.4<|f2/fw|<1.0  (2) 0.3<f3/fT345<1.2  (3) 0.6<|f4|/fT345<5.0  (4) 0.5<f5/fT345<4.0  (5) where fw is a focal length of said zoom lens system at said wide-angle end, f1 is a focal length of said first lens group, f2 is a focal length of said second lens group, f3 is a focal length of said third lens group, f4 is a focal length of said fourth lens group, f5 is a focal length of said fifth lens group, and fT345 is a focal length of said third lens group to said fifth lens group at said telephoto end,wherein an image movement occurring by movement of said zoom lens system is corrected by moving said fourth lens group substantially vertically with respect to an optical axis of said zoom lens system.

17. A zoom lens system comprising, in order from an object of the zoom lens system, a first lens group having positive refracting power, a second lens group having negative refracting power, a third lens group having positive refracting power, a fourth lens group having negative refracting power and a fifth lens group having positive refracting power, wherein:for zooming from a wide-angle end to a telephoto end of said zoom lens system, each of said first lens group to said fifth lens group moves while said first lens group and said third lens group move toward said object side during said zooming in such a way that spacing between said first lens group and said second lens group and between said third lens group and said fourth lens group becomes wider, a fluctuation of an image plane position with said zooming is compensated for by nonlinear movement of at least one of said third lens group, said fourth lens group and said fifth lens group, and the following conditions are satisfied: 2.0<f1/fW<8.0  (1) 0.4<|f2/fw|<1.0  (2) 0.3<f3/fT345<1.2  (3) 0.6<|f4|/fT345<5.0  (4) 0.5<f5/fT345<4.0  (5) where fw is a focal length of said zoom lens system at said wide-angle end, f1 is a focal length of said first lens group, f2 is a focal length of said second lens group, f3 is a focal length of said third lens group, f4 is a focal length of said fourth lens group, f5 is a focal length of said fifth lens group, and fT345 is a focal length of said third lens group to said fifth lens group at said telephoto end,wherein an image movement occurring by movement of said zoom lens system is corrected by moving said fifth lens group substantially vertically with respect to an optical axis said zoom lens system.