Zoom lens and photographing apparatus having the same

BACKGROUND OF THE INVENTION

[0001] 1. Field of the Invention

[0002] The present invention relates to a zoom lens having fluctuation prevention function and a photographing apparatus provided with the zoom lens. In particular, the present invention relates to a zoom lens having fluctuation prevention function and a photographing apparatus, which can be preferably applied to a still camera, a video camera, a digital camera, etc., and which is designed to allow a lens group, i.e., a part of the zoom lens, to be moved in a direction perpendicular to an optical axis so as to optically correct a blur of a photographed still image caused by fluctuating motion (inclined motion) of the zoom lens due to hand fluctuation or the like, thereby obtaining a stabilized photographed image.

[0003] 2. Related Background Art

[0004] The blur is caused on a photographed image due to hand fluctuation transmitted to a photographing system. Various attempts have been made to provide fluctuation preventive optical systems which can prevent the blur on the photographed image.

[0005] Recently, for a still camera, a video camera, a digital camera, etc., a zoom lens having fluctuation prevention function has been required to correct the image blur caused due to hand fluctuation or the like for the purpose of obtaining a higher quality image and enlarging applicable photographing conditions.

[0006] As a zoom lens having fluctuation prevention function, for example, Japanese Patent Application Laid-Open No. 9-230236 discloses a four-lens-group zoom lens in which positive, negative, positive and positive refractive power lens groups are arranged in this order from an object side, and in which the third lens group is divided into a positive refractive power front lens group and a positive refractive power rear lens group, and the rear lens group is moved perpendicularly to an optical axis to correct the image blur. Japanese Patent Application Laid-Open No. 10-232420 discloses a four-lens-group zoom lens, primarily applied to a video camera, in which positive, negative, positive and positive refractive power, four lens groups are arranged with the first and third lens groups to be fixed, and in which the third lens group is divided into a positive refractive power lens group and a negative refractive power lens group, and either one of these lens groups is moved in a direction perpendicular to an optical axis to correct the image blur.

[0007] Japanese Patent Application Laid-Open No. 7-128619 discloses a magnification changeable optical system having a four lens groups, which is provided, sequentially from an object side, with a first group having a positive refractive power fixed during the change of magnification and the in-focusing condition, a second group with a negative refractive power, having magnification changing function, an aperture diaphragm, a third group with a positive refractive power, and a fourth group with a positive refractive power, that has both correction function for correcting an image plane varying depending on the change of magnification, and in-focusing function. In the system, the third group is constructed of two lens groups, i.e., a third-1 group with a negative refractive power, and a third-2 group with a positive refractive power, and the third-2 group is moved in a direction perpendicular to an optical axis to correct a blur of the photographed image caused by fluctuation of the magnification changeable optical system.

[0008] Japanese Patent Application Laid-Open No. 7-199124 discloses a magnification changeable optical system constructed of four groups, i.e., positive, negative, positive and positive refractive power lens groups, in which the third lens group entirely is fluctuated perpendicularly to an optical axis for the purpose of fluctuation prevention.

[0009] In general, an optical system, which is designed to parallelly offset a part of lens of a photographing system in a direction perpendicular to an optical axis to correct the image blur, can advantageously realize the correction of the image blur in a relatively simple fashion, but requires driving means for driving the lens to be moved. Further, the system provides the result in an increased amount of offset aberration occurring during fluctuation prevention.

[0010] For example, if a correction lens group for correcting the image blur is large in number of constituting lenses and weight, a large torque is required when electrically driving the same. Further, if the correction lens group for correcting the image blur is set inappropriately, the correction optical system requires a large amount of its movement in order to obtain image blur correcting effect of a certain degree, making the entire optical system large in size.

SUMMARY OF THE INVENTION

[0011] An object of the present invention is to provide a zoom lens and a photographing apparatus using the zoom lens, in which a relatively small and light-weight lens group forming a part of the zoom lens is moved in a direction perpendicular to an optical axis to correct an image blur caused due to fluctuation (inclination) of the zoom lens, and in which the lens arrangement for the zoom lens is optimized to realize the zoom lens that is compact in size, simple in mechanism, small in load applied to driving means, and that can effectively correct certain image blur with a small amount of displacement of the lens group.

[0012] To attain the above-noted object, the present invention provides, as one form thereof, a zoom lens which includes;

[0013] a first lens unit with a positive refractive power;

[0014] a second lens unit with a negative refractive power;

[0015] a third lens unit with a positive refractive power; and

[0016] a fourth lens unit with a positive refractive power,

[0017] in which at least the first, third and fourth lens units are moved along an optical axis to vary spatial distances of the lens units to thereby change magnification,

[0018] and the third lens unit includes a first lens subunit with a positive refractive power, and a second lens subunit with a negative refractive power, and the second lens subunit is moved to have at least a perpendicular vector component with respect to the optical axis to thereby displace an image.

[0019] As a preferable form, the following conditions are satisfied:

0.35<F3/Fm<1

−0.9<F3/F32<−0.18

[0020] where focal lengths of the entire system at a wide angle end and a telephoto end are respectively represented by Fw and Ft, a focal length of the third lens unit is represented by F3, a focal length of the second lens subunit is represented by F32, and Fm=(Fw×Ft)½.

[0021] As a preferable form, the second lens subunit is moved to have the perpendicular vector component with respect to the optical axis to thereby correct an image blur caused by fluctuation of the zoom lens.

[0022] As a preferable form, the following condition is satisfied:

−0.2<(Ra+Rb)/(Ra−Rb)<0.7

[0023] where a radius of curvature of a lens plane located closest to an image plane side within the first lens subunit is represented by Ra, and a radius of curvature of a lens plane located closest to the object side within the second lens subunit is represented by Rb.

[0024] As a preferable form, the following conditions are satisfied:

0.7<F1/Fm<2.8

0.15<|F2/Fm|<0.7

0.5<F4/Fm<2.0

[0025] where a focal length of an i-th lens unit of the lens units is represented by Fi.

[0026] As a preferable form, the second lens subunit includes one positive lens and one negative lens.

[0027] As a preferable form, the first lens subunit includes, from the object side, a composite lens with a positive refractive power, in which a meniscus-like negative lens having a concave surface on an image plane side is adhered to a positive lens, and a composite lens with a positive single lens or a positive refractive power, in which a positive lens is adhered to a negative lens.

[0028] As a preferable form, the second lens subunit includes a composite lens with a negative refractive power, in which a positive lens having a convex surface oriented to an image plane side is adhered to a negative lens having a concave surface oriented to the object side.

[0029] As a preferable form, the third lens unit further includes a third lens subunit having a negative or positive refractive power on an image plane side of the second lens subunit.

[0030] To attain the above-noted object, the present invention provides, as another form, a photographing apparatus which includes:

[0031] a first lens unit with a positive refractive power;

[0032] a second lens unit with a negative refractive power;

[0033] a third lens unit with a positive refractive power;

[0034] a fourth lens unit with a positive refractive power; and

[0035] a casing holding a zoom lens,

[0036] in which at least the first, third and fourth lens units are moved along an optical axis to vary spatial distances of the lens units to thereby change magnification,

[0037] and the third lens unit includes a first lens subunit with a positive refractive power, and a second lens subunit with a negative refractive power, and the second lens subunit is moved to have at least a perpendicular vector component with respect to the optical axis to thereby displace an image.

[0038] As a preferable form, the following conditions are satisfied:

0.35<F3/Fm<1

−0.9<F3/F32<−0.18

[0039] where focal lengths of the entire system at a wide angle end and a telephoto end are respectively represented by Fw and Ft, a focal length of the third lens unit is represented by F3, a focal length of the second lens subunit is represented by F32, and Fm=(Fw×Ft)½.

[0040] As a preferable form, the second lens subunit is moved to have the perpendicular vector component with respect to the optical axis to thereby correct an image blur caused due to fluctuation of the zoom lens.

[0041] As a preferable form, the following condition is satisfied:

−0.2<(Ra+Rb)/(Ra−Rb)<0.7

[0042] where a radius of curvature of a lens plane located closest to an image plane side within the first lens subunit is represented by Ra, and a radius of curvature of a lens plane located closest to the object side within the second lens subunit is represented by Rb.

[0043] As a preferable form, the following conditions are satisfied:

0.7<F1/Fm<2.8

0.15<|F2/Fm|<0.7

0.5<F4/Fm<2.0

[0044] where a focal length of an i-th lens unit of the lens units is represented by Fi.

BRIEF DESCRIPTION OF THE DRAWINGS

[0045]
FIG. 1 is a sectional view showing a lens of a wide angle end according to a numerical first embodiment of the present invention;

[0046]
FIG. 2 is a view showing aberration at the wide angle end in a normal condition according to the numerical first embodiment of the present invention;

[0047]
FIG. 3 is a view showing aberration at a middle in a normal condition according to the numerical first embodiment of the present invention;

[0048]
FIG. 4 is a view showing aberration at a telephoto end in a normal condition according to the numerical first embodiment of the present invention;

[0049]
FIG. 5 is a view showing aberration at the wide angle end with correction for image blur corresponding to 0.3 degrees of field angle according to the numerical first embodiment of the present invention;

[0050]
FIG. 6 is a view showing aberration at the middle with correction for image blur corresponding to 0.3 degrees of field angle according to the numerical first embodiment of the present invention;

[0051]
FIG. 7 is a view showing aberration at the telephoto end with correction for an image blur corresponding to 0.3 degrees of field angle according to the numerical first embodiment of the present invention;

[0052]
FIG. 8 is a sectional view showing a lens of a wide angle end according to a numerical second embodiment of the present invention;

[0053]
FIG. 9 is a view showing aberration at the wide angle end in a normal condition according to the numerical second embodiment of the present invention;

[0054]
FIG. 10 is a view showing aberration at a middle in a normal condition according to the numerical second embodiment of the present invention;

[0055]
FIG. 11 is a view showing aberration at a telephoto end in a normal condition according to the numerical second embodiment of the present invention;

[0056]
FIG. 12 is a view showing aberration at the wide angle end with correction for an image blur corresponding to 0.3 degrees of field angle according to the numerical second embodiment of the present invention;

[0057]
FIG. 13 is a view showing aberration at the middle with correction for an image blur corresponding to 0.3 degrees of field angle according to the numerical second embodiment of the present invention;

[0058]
FIG. 14 is a view showing aberration at the telephoto end with correction for an image blur corresponding to 0.3 degrees of field angle according to the numerical second embodiment of the present invention;

[0059]
FIG. 15 is a sectional view showing a lens of a wide angle end according to a numerical third embodiment of the present invention;

[0060]
FIG. 16 is a view showing aberration at the wide angle end in a normal condition according to the numerical third embodiment of the present invention;

[0061]
FIG. 17 is a view showing aberration at a middle in a normal condition according to the numerical third embodiment of the present invention;

[0062]
FIG. 18 is a view showing aberration at a telephoto end in a normal condition according to the numerical third embodiment of the present invention;

[0063]
FIG. 19 is a view showing aberration at the wide angle end with correction for an image blur corresponding to 0.3 degrees of field angle according to the numerical third embodiment of the present invention;

[0064]
FIG. 20 is a view showing aberration at the middle with correction for an image blur corresponding to 0.3 degrees of field angle according to the numerical third embodiment of the present invention;

[0065]
FIG. 21 is a view showing aberration at the telephoto end with correction for an image blur corresponding to 0.3 degrees of field angle according to the numerical third embodiment of the present invention;

[0066]
FIG. 22 is a sectional view showing a lens of a wide angle end according to a numerical fourth embodiment of the present invention;

[0067]
FIG. 23 is a view showing aberration at the wide angle end in a normal condition according to the numerical fourth embodiment of the present invention;

[0068]
FIG. 24 is a view showing aberration at a middle in a normal condition according to the numerical fourth embodiment of the present invention;

[0069]
FIG. 25 is a view showing aberration at a telephoto end in a normal condition according to the numerical fourth embodiment of the present invention;

[0070]
FIG. 26 is a view showing aberration at the wide angle end with correction for an image blur corresponding to 0.3 degrees of field angle according to the numerical fourth embodiment of the present invention;

[0071]
FIG. 27 is a view showing aberration at the middle with correction for an image blur corresponding to 0.3 degrees of field angle according to the numerical fourth embodiment of the present invention;

[0072]
FIG. 28 is a view showing aberration at the telephoto end with correction for an image blur corresponding to 0.3 degrees of field angle according to the numerical fourth embodiment of the present invention;

[0073]
FIG. 29 is a sectional view showing a lens of a wide angle end according to a numerical fifth embodiment of the present invention;

[0074]
FIG. 30 is a view showing aberration at the wide angle end in a normal condition according to the numerical fifth embodiment of the present invention;

[0075]
FIG. 31 is a view showing aberration at a middle in a normal condition according to the numerical fifth embodiment of the present invention;

[0076]
FIG. 32 is a view showing aberration at a telephoto end in a normal condition according to the numerical fifth embodiment of the present invention;

[0077]
FIG. 33 is a view showing aberration at the wide angle end with correction for an image blur corresponding to 0.3 degrees of field angle according to the numerical fifth embodiment of the present invention;

[0078]
FIG. 34 is a view showing aberration at the middle with correction for an image blur corresponding to 0.3 degrees of field angle according to the numerical fifth embodiment of the present invention;

[0079]
FIG. 35 is a view showing aberration at the telephoto end with correction for an image blur corresponding to 0.3 degrees of field angle according to the numerical fifth embodiment of the present invention; and

[0080]
FIG. 36 is a schematic view showing major portions of a single reflex camera to which a zoom lens according to the present invention is applied.

DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0081]
FIGS. 1, 8, 15, 22 and 29 are sectional views respectively showing lenses of wide angle ends according to numerical first to fifth embodiments of the present invention. FIGS. 2 to 4 are views respectively showing aberration at the wide angle end, a middle, and a telephoto end in a normal condition according to the numerical first embodiment of the present invention. FIGS. 5 to 7 are views respectively showing aberration at the wide angle end, the middle, and the telephoto end in a fluctuation compensation state (correction for image blur corresponding to 0.3 degrees of field angle) according to the numerical first embodiment of the present invention. FIGS. 9 to 11 are views respectively showing aberration at the wide angle end, the middle, and the telephoto end according to the numerical second embodiment of the present invention. FIGS. 12 to 14 are views respectively showing aberration at the wide angle end, the middle, and the telephoto end in a fluctuation compensation state (correction for image blur corresponding to 0.3 degrees of field angle) according to the numerical second embodiment of the present invention. FIGS. 16 to 18 are views respectively showing aberration at the wide angle end, the middle, and the telephoto end in a normal condition according to the numerical third embodiment of the present invention. FIGS. 19 to 21 are views showing aberration at the wide angle end, the middle, and the telephoto end in a fluctuation compensation state (correction for image blur corresponding to 0.3 degrees of field angle) according to the numerical third embodiment of the present invention. FIGS. 23 to 25 are views respectively showing aberration at the wide angle end, the middle and the telephoto end in a normal condition according to the numerical fourth embodiment of the present invention. FIGS. 26 to 28 are views respectively showing aberration at the wide angle end, the middle, and the telephoto end in a fluctuation compensation state (correction for image blur corresponding to 0.3 degrees of field angle) according to the numerical fourth embodiment of the present invention. FIGS. 30 to 32 are views respectively showing aberration at the wide angle end, the middle, and the telephoto end in a normal condition according to the numerical fifth embodiment of the present invention. FIGS. 33 to 35 are views respectively showing aberration at the wide angle end, the middle, and the telephoto end in a fluctuation compensation state (correction for image blur corresponding to 0.3 degrees of field angle) according to the numerical fifth embodiment of the present invention.

[0082] In the drawings, L1, L2, L3, and L4 respectively designate a first lens group with a positive refractive power, a second lens group with a negative refractive power, a third lens group with a positive refractive power, and a fourth lens group with a positive refractive power. Each arrow in the drawings shows a direction in which a respective lens group is moved when the magnification is changed from the wide angle side to the telephoto side. SP designates a diaphragm (stop) which is provided between the second and third lens groups. IP designates an image plane.

[0083] In each of FIGS. 1, 8, and 15, the third lens group includes a positive refractive power, third-first lens group L31, and a fluctuation-preventive, third-second lens group L32 with a negative refractive power. In each of FIGS. 22 and 29, the third lens group includes a third-first lens group L31 with a positive refractive power, a fluctuation-preventive third-second lens group L32 with a negative refractive power, and a third-third lens group L33 with a negative refractive power.

[0084] Each of the zoom lenses according to the numerical embodiments of the present invention includes the first lens group with positive refractive power, the second lens group with the negative refractive power, the third lens group with the positive refractive power, and the fourth lens group with the positive refractive power arranged in this order from the object side, in which at least the first, third and fourth lens groups are moved along the optical axis to vary spatial distances therebetween for the magnification change, while the third-second lens group L32 with the negative refractive power in the third lens group are moved perpendicular to the optical axis to change the imaging position.

[0085] In magnification change, the spatial distance between the first lens group and the second lens group is varied so that the second lens group mainly performs the magnification changing operation, and the third lens group is moved to mainly perform the correcting operation for the image plane varied in association with the magnification change, and concurrently the spatial distance between the third lens group and the fourth lens group is varied to correct variation in decentered aberration in association with the magnification change. In this case, the second lens group may be fixed with respect to the optical axis to simplify the mechanism. By disposing the third-second lens group with the negative refractive power within the third lens group with the positive refractive power, the negative refractive function of the third-second lens group cancels the various aberration caused by a lens group having the positive refractive function, which is located as a lens system, other than the third-second lens group, within the third lens group. This also serves to provide a larger displacement of the image position with a smaller amount of movement.

[0086] In this case, the third lens group includes, from the object side, the third-first lens group L31 with the positive refractive power, and the third-second lens group with the negative refractive power, or the third-first lens group L31 with the positive refractive power, the third-second lens group with the negative refractive power, and the third-third lens group with the negative refractive power, and the third-second lens group is moved perpendicular to the optical axis to displace or vary the imaging position. With this arrangement, the converging effect of the third-first lens group renders a lens system of the third-second lens group small in size and allows a moving mechanism for the third-second lens group to be simplified.

[0087] Although a zoom lens aimed at the present invention can be realized by satisfying the above-noted conditions, it is preferable to satisfy at least one of the following conditions in order that the zoom lens exhibits more excellent optical performance and the entire optical system is made smaller.

[0088] (A) If focal lengths of the entire system at the wide angle end and the telephoto end are respectively represented by Fw and Ft, a focal length of the third lens group is represented by F3, and a focal length of the third-second lens group is represented by F32, and if

Fm={square root}{square root over (Fw·Ft)},

[0089] then the following conditions are satisfied:

0.35<F3/Fm<1 (1)

−0.9<F3/F32<−0.18 (2)

[0090] In a case where the refractive power of the third lens group is weakened beyond the upper limit of the formula (1), the amount of the movement of the lens group for securing certain focal length and magnification changing ratio becomes large, and thus, the entire length of the lens system becomes disadvantageously large.

[0091] On the other hand, if the lower limit is exceeded, the refractive power of the third lens group becomes excessively strong to generate the strong negative spherical aberration, making it difficult to appropriately correct the aberration over the entire range of the magnification by other lens groups.

[0092] The formula (2) relates to the refractive power of the third-second lens group performing the operation of displacing the imaging position within the third lens group, and should be satisfied in order to maintain high quality image while suppressing the movement of the third-second lens group.

[0093] In a case where the negative refractive power of the third-second lens group is weakened beyond the upper limit of the formula (2), the amount of the movement of the third-second lens group required for performing certain image position displacement operation is large, and further the lens diameter of the third-second lens group is increased in order to obtain certain peripheral optical intensity. Thus, it is not preferable.

[0094] On the other hand, in a case where the lower limit is exceeded, the negative refractive power of the third-second lens group is large, and then the lens system, other than the third-second lens group, within the third lens group must have larger positive refractive power, and therefore high-ordered spherical aberration or coma aberration is largely generated, making it difficult to correct the aberration when the image position is displaced.

[0095] In addition, it is more preferable to modify the conditions (1) and (2) as follows:

0.4<F3/Fm<0.8 (1a)

−0.8<F3/F32<−0.2 (2a)

[0096] (B) If a radius of curvature of a lens plane located the closest to the image plane side within the third-first lens group is represented by Ra, and a radius of curvature of a lens plane located the closest to the object side within the third-second lens group is represented by Rb,

[0097] then the following condition is satisfied:

−0.2<(Ra+Rb)/(Ra−Rb)<0.7 (3)

[0098] The formula (3) should be satisfied in order that the lens surface configurations are appropriately arranged within the third lens group for the purpose of obtaining a high quality image. Outside the numerical range defined by the formula (3), an appropriate canceling relationship is not established in spherical aberration and coma aberration by mutual lens surfaces when the image position is changed and not changed, and therefore is not preferable.

[0099] In addition, it is more preferable to modify the formula (3) as follows:

−0.15<(Ra+Rb)/(Ra−Rb)<0.6 (3a)

[0100] (C) If a focal length of an i-th lens group of the above-noted lens group is represented by Fi,

[0101] then the following conditions are satisfied:

0.7<F1/Fm<2.8 (4)

0.15<|F2/Fm|<0.7 (5)

0.5<F4/Fm<2.0 (6)

[0102] The formulae (4) to (6) are for the purpose of mainly realizing a compact optical system with high image quality.

[0103] If outside the upper limit of the formula (4), the refractive power of the first lens group becomes excessively weak so that lens diameter and the lens entire length become large, which is not preferable.

[0104] On the other hand, if outside the lower limit, the refractive power of the first lens group becomes excessively strong so that high-ordered spherical aberration is largely generated, making it difficult to correct the aberration.

[0105] If outside the upper limit of the formula (5), the refractive power of the second lens group is weakened, so that the amount of the movement of each lens group is large in order to obtain certain magnification changing ratio, and consequently it is difficult to make the lens system compact in size.

[0106] If outside the lower limit, the negative refractive power function becomes large, so that the Petzval sum becomes a large negative value, and thus an image surface curvature is large, which is not preferable.

[0107] If outside the upper limit of the formula (6), the refractive power of the fourth lens group, becomes too weak, so that the back focus is long, and thus the lens entire length is large which is not preferable.

[0108] On the other hand, if outside the lower limit, the back focus of the entire lens system becomes too short, so that in a case where the lens system is, for instance, applied to a single reflex lens, the interference with a quick return mirror occurs. Further, decentered, high-ordered aberration such as image plane curvature, is largely generated.

[0109] In addition, it is more preferable to modify the conditions (4), (5) and (6) as follows:

0.9<F1/Fm<2.3 (4a)

0.18<|F2/Fm|<0.6 (5a)

0.6<F4/Fm<1.8 (6a)

[0110] (D) The third-second lens group is preferably constituted by one positive lens and one negative lens. This is effective in suppressing aberration variation when the lens is moved to displace the image position.

[0111] (E) It is preferable that the focusing is carried out by moving the first lens group or the second lens group toward the object side. In particular, the system in which the second lens group is moved is preferable because the lens diameter of the first lens group is not increased. Both of the first and second lens groups may be moved to the object side carry out the focusing.

[0112] (F) The first lens group is preferably constituted, from the object side, by a negative lens having a concave surface on the image plane side, which lens surface is stronger in refractive power than the that on the object side (hereafter, simply referred to as “the lens surface is stronger on the image plane side”, when applicable), a positive lens, and a positive lens having a convex surface on the object side, which lens surface is stronger in refractive power than that on the image plane side (hereafter, simply referred to as “the lens surface is stronger on the object side”, when applicable).

[0113] (G) The second lens group is preferably constituted, from the object side, by a negative lens having a concave surface which lens surface is stronger on the image plane side, a negative lens having concave surfaces on both sides, a positive lens having a convex surface which lens surface is stronger on the object side, and a negative lens having a concave surface which lens surface is stronger on the object side. Further, the negative lens located closest to the image plane side is preferably constructed as a composite lens of a negative lens and a positive lens to realize the higher image quality.

[0114] (H) The third-first lens group is preferably constituted, from the object side, by a composite lens in which a meniscus-like, negative lens having a concave surface which lens surface is stronger on the image plane side is adhered to a positive lens to constitute a lens group as being positive entirely, and a positive single lens or a composite lens in which a positive lens is adhered to a negative lens to constitute a lens group as being positive entirely.

[0115] (I) The third-second lens group is preferably constituted by a composite lens group in which a positive lens having a convex surface oriented to the image plane side is adhered to a negative lens having a concave surface which lens surface is stronger on the object side to constitute a lens group as being negative entirely.

[0116] (J) It is preferable to dispose, on the image plane side of the third-second lens group, a third-third lens group having a negative or positive refractive power, which is stationary during fluctuation prevention. With this arrangement, a further aberration correcting effect can be expected.

[0117] (K) The fourth lens group is preferably constituted, from the object side, by a positive lens having a convex surface stronger on the image plane side, a positive lens having convex surfaces on both sides, and a meniscus-like negative lens having a concave surface stronger on the object side.

[0118] (L) In order to improve the optical performance, a non-spherical surface, a grading optical element, and/or a gradient index optical element are preferably introduced into the lens system.

[0119] Next, specific numerical embodiments will be described.

[0120] In the numerical embodiments, Ri and Di respectively represent a thickness and a spatial distance of an i-th lens counted from the object side, and Ni and νi respectively represent a refractive power and an abbe number of the material of the i-th lens counted from the object side.

[0121] Non-spherical surface constants K, A, B, C, and D are defined by the following condition:

X = \frac{H^{2} / R}{1 + \sqrt{1 - (1 + K) {(H / R)}^{2}}} + A \cdot H^{2} + B \cdot H^{4} + C \cdot H^{6} + D \cdot H^{8} + E \cdot H^{10}

[0122] where X denotes an amount of displacement in a direction from an optical axis to a lens apex, H denotes a distance from an optical axis, and R denotes a radius of curvature. Further, “e-X” means “x10−x”.

[0123] Relationships of numerical values of the numerical embodiments to aforementioned formulae are shown in Table 1.

1Numerical Value Embodiment 1f = 29.00˜101.37 Fno = 4.54˜5.75 2ω = 73.5°˜24.1°R1 = 86.687D1 = 1.50N1 = 1.846660ν1 = 23.9R2 = 42.162D2 = 8.70N2 = 1.603112ν2 = 60.6R3 = 467.815D3 = 0.15R4 = 36.727D4 = 6.40N3 = 1.733997ν3 = 51.5R5 = 125.386D5 = variableR6 = 64.747D6 = 1.20N4 = 1.834807ν4 = 42.7R7 = 11.848D7 = 5.34R8 = −38.336D8 = 1.00N5 = 1.804000ν5 = 46.6R9 = 29.098D9 = 0.20R10 = 21.706D10 = 3.10N6 = 1.846660ν6 = 23.9R11 = −41.601D11 = 0.60R12 = −22.294D12 = 1.00N7 = 1.804000ν7 = 46.6R13 = −120.841D13 = variableR14 = stopD14 = 0.15R15 = 37.070D15 = 0.90N8 = 1.805181ν8 = 25.4R16 = 24.498D16 = 3.00N9 = 1.639300ν9 = 44.9R17 = −39.035D17 = 0.20R18 = 40.272D18 = 3.30N10 = 1.570989ν10 = 50.8R19 = −15.064D19 = 0.90N11 = 1.846660ν11 = 23.9R20 = −36.396D20 = 1.73R21 = −40.584D21 = 2.00N12 = 1.846660ν12 = 23.9R22 = −13.785D22 = 0.90N13 = 1.749497ν13 = 35.3R23 = 83.142D23 = variableR24 = −132.327D24 = 3.80N14 = 1.487490ν14 = 70.2R25 = −22.027D25 = 0.20R26 = 110.113D26 = 4.00N15 = 1.487490ν15 = 70.2R27 = −41.738D27 = 2.38R28 = −19.597D28 = 1.40N16 = 1.846660ν16 = 23.9R29 = −33.679focal distancevariable range29.0054.74101.37D51.8910.9422.39D1312.996.281.45D2311.528.247.12

[0124]

2

Numerical Value Embodiment 2

f = 29.00˜101.30 Fno = 4.39˜5.75 2ω = 73.5°˜24.1°

R1 = 83.702
D1 = 1.50
N1 = 1.846660
ν1 = 23.9

R2 = 41.079
D2 = 8.40
N2 = 1.603112
ν2 = 60.6

R3 = 359.634
D3 = 0.15

R4 = 38.654
D4 = 6.40
N3 = 1.719995
ν3 = 50.2

R5 = 150.065
D5 = variable

R6 = 64.696
D6 = 1.20
N4 = 1.834807
ν4 = 42.7

R7 = 12.027
D7 = 5.00

R8 = −37.123
D8 = 1.00
N5 = 1.804000
ν5 = 46.6

R9 = 28.835
D9 = 0.20

R10 = 21.702
D10 = 3.10
N6 = 1.846660
ν6 = 23.9

R11 = −39.022
D11 = 0.60

R12 = −22.580
D12 = 1.00
N7 = 1.804000
ν7 = 46.6

R13 = −120.841
D13 = variable

R14 = stop
D14 = 0.15

R15 = 37.553
D15 = 0.90
N8 = 1.805181
ν8 = 25.4

R16 = 25.970
D16 = 3.00
N9 = 1.639300
ν9 = 44.9

R17 = −45.144
D17 = 0.20

R18 = 41.663
D18 = 3.30
N10 = 1.570989
ν10 = 50.8

R19 = −14.860
D19 = 0.90
N11 = 1.846660
ν11 = 23.9

R20 = −38.349
D20 = 1.50

R21 = −42.901
D21 = 2.20
N12 = 1.846660
ν12 = 23.9

R22 = −13.652
D22 = 0.90
N13 = 1.749497
ν13 = 35.3

R23 = 91.409
D23 = variable

R24 = −133.590
D24 = 3.80
N14 = 1.487490
ν14 = 70.2

R25 = −21.523
D25 = 0.20

R26 = 107.117
D26 = 3.80
N15 = 1.487490
ν15 = 70.2

R27 = −42.147
D27 = 2.60

R28 = −19.781
D28 = 1.40
N16 = 1.846660
ν16 = 23.9

R29 = −33.679

focal distance

variable range
29.00
55.00
101.30

D5
2.00
10.87
22.39

D13
13.51
6.31
1.45

D23
11.52
8.30
7.12

[0125]

3

Numerical Value Embodiment 3

f = 29.00˜101.50 Fno = 4.10˜5.75 2ω = 73.5°˜24.1°

R1 = 141.446
D1 = 1.80
N1 = 1.846660
ν1 = 23.8

R2 = 65.548
D2 = 8.00
N2 = 1.603112
ν2 = 60.6

R3 = −1920.275
D3 = 0.15

R4 = 41.278
D4 = 5.00
N3 = 1.733997
ν3 = 51.5

R5 = 69.266
D5 = variable

R6 = 26.753
D6 = 1.20
N4 = 1.834807
ν4 = 42.7

R7 = 12.779
D7 = 6.97

R8 = −111.739
D8 = 1.00
N5 = 1.804000
ν5 = 46.6

R9 = 27.679
D9 = 0.20

R10 = 20.183
D10 = 4.20
N6 = 1.846660
ν6 = 23.8

R11 = −229.709
D11 = 1.20

R12 = −34.939
D12 = 1.00
N7 = 1.804000
ν7 = 46.6

R13 = 343.160
D13 = variable

R14 = stop
D14 = 1.00

R15 = 382.311
D15 = 0.90
N8 = 1.805181
ν8 = 25.4

R16 = 13.917
D16 = 3.20
N9 = 1.639300
ν9 = 44.9

R17 = −70.454
D17 = 0.20

R18 = 26.018
D18 = 2.50
N10 = 1.720000
ν10 = 43.7

R19 = −51.100
D19 = 1.50

R20 = −45.633
D20 = 2.40
N11 = 1.846660
ν11 = 23.8

R21 = −15.099
D21 = 0.90
N12 = 1.749497
ν12 = 35.3

R22 = 225.399
D22 = variable

R23 = −25.512
D23 = 3.00
N13 = 1.487490
ν13 = 70.2

R24 = −17.904
D24 = 0.20

R25 = 65.171
D25 = 4.00
N14 = 1.487490
ν14 = 70.2

R26 = −43.800
D26 = 3.14

R27 = −18.241
D27 = 1.40
N15 = 1.846660
ν15 = 23.8

R28 = −31.177

focal distance

variable range
29.00
54.00
101.50

D5
1.80
15.36
29.97

D13
20.13
8.98
1.29

D22
14.01
10.76
9.85

[0126]

4

Numerical Value Embodiment 4

f = 29.01˜101.35 Fno = 3.77˜5.80 2ω = 73.4°˜24.1°

R1 = 126.261
D1 = 1.80
N1 = 1.846660
ν1 = 23.8

R2 = 66.940
D2 = 8.00
N2 = 1.603112
ν2 = 60.6

R3 = −282.096
D3 = 0.15

R4 = 37.686
D4 = 3.00
N3 = 1.670000
ν3 = 57.3

R5 = 46.991
D5 = variable

R6 = 33.243
D6 = 1.20
N4 = 1.873996
ν4 = 35.3

R7 = 14.216
D7 = 6.40

R8 = −47.453
D8 = 1.00
N5 = 1.743198
ν5 = 49.3

R9 = 42.606
D9 = 0.20

R10 = 25.841
D10 = 4.20
N6 = 1.846660
ν6 = 23.8

R11 = −62.181
D11 = 1.02

R12 = −28.083
D12 = 1.00
N7 = 1.804000
ν7 = 46.6

R13 = −274.061
D13 = variable

R14 = stop
D14 = 1.00

R15 = 89.494
D15 = 0.90
N8 = 1.784723
ν8 = 25.7

R16 = 14.136
D16 = 4.00
N9 = 1.670000
ν9 = 57.3

R17 = −236.326
D17 = 0.20

R18 = 24.385
D18 = 3.30
N10 = 1.647689
ν10 = 33.8

R19 = −46.622
D19 = 1.00

R20 = −47.442
D20 = 2.40
N11 = 1.846660
ν11 = 23.8

R21 = −16.552
D21 = 0.90
N12 = 1.739997
ν12 = 31.7

R22 = −615.178
D22 = 1.80

R23 = −58.954
D23 = 1.80
N13 = 1.740999
ν13 = 52.6

*R24 = −211.512
D24 = variable

R25 = −30.176
D25 = 3.00
N14 = 1.548141
ν14 = 45.8

R26 = −20.181
D26 = 0.20

R27 = 62.613
D27 = 5.00
N15 = 1.510091
ν15 = 63.6

R28 = −33.511
D28 = 2.07

R29 = −20.285
D29 = 1.40
N16 = 1.846660
ν16 = 23.8

R30 = −49.470

focal distance

variable range
29.01
53.97
101.35

D5
1.80
14.59
29.63

D13
21.08
8.91
1.00

D24
11.12
9.28
9.18

aspherical coefficient

24 surfaces: k = −5.62727e+02

A = 0 B = 1.89300e−06 C = 3.98391e−08

D = −7.41272e−11 E = 0.00000e+00

[0127]

5

Numerical Value Embodiment 5

f = 29.00˜101.50 Fno = 3.86˜5.75 2ω = 73.5°˜24.1°

R1 = 233.840
D1 = 1.80
N1 = 1.846660
ν1 = 23.8

R2 = 98.856
D2 = 6.00
N2 = 1.658296
ν2 = 57.3

R3 = −305.171
D3 = 0.15

R4 = 51.919
D4 = 3.00
N3 = 1.603112
ν3 = 60.7

R5 = 80.974
D5 = variable

R6 = 33.135
D6 = 1.20
N4 = 1.850259
ν4 = 32.3

R7 = 14.698
D7 = 6.73

R8 = −66.153
D8 = 1.00
N5 = 1.712995
ν5 = 53.9

R9 = 34.324
D9 = 0.20

R10 = 24.112
D10 = 4.20
N6 = 1.846660
ν6 = 23.8

R11 = −131.824
D11 = 1.35

R12 = −32.019
D12 = 1.00
N7 = 1.743198
ν7 = 49.3

R13 = −263.558
D13 = variable

R14 = stop
D14 = 1.00

R15 = 47.410
D15 = 0.90
N8 = 1.800999
ν8 = 35.0

R16 = 12.758
D16 = 4.30
N9 = 1.677900
ν9 = 55.3

R17 = 114.951
D17 = 0.20

R18 = 26.510
D18 = 3.00
N10 = 1.677900
ν10 = 55.3

R19 = −125.081
D19 = 1.30

R20 = −47.415
D20 = 3.00
N11 = 1.846660
ν11 = 23.8

R21 = −18.117
D21 = 0.90
N12 = 1.717362
ν12 = 29.5

R22 = −311.396
D22 = 1.80

R23 = 195.852
D23 = 1.80
N13 = 1.670000
ν13 = 57.3

*R24 = 7619.687
D24 = variable

R25 = −30.835
D25 = 2.50
N14 = 1.568728
ν14 = 63.2

R26 = −21.996
D26 = 0.20

R27 = 72.912
D27 = 4.80
N15 = 1.518206
ν15 = 65.0

R28 = −28.835
D28 = 2.18

R29 = −18.744
D29 = 1.40
N16 = 1.850259
ν16 = 32.3

R30 = −51.138

focal distance

variable range
29.00
54.00
101.50

D5
1.80
17.95
36.60

D13
23.15
10.02
1.35

D24
10.14
8.31
8.09

aspherical coefficient

24 surfaces: k = 1.81112e+04

A = 0 B = 1.77443e−06 C = −2.39986e−08

D = −5.47733e−11 E = 0.00000e+00

[0128]

6

TABLE 1

Condition
Numerical Value Embodiment

expression
1
2
3
4
5

F3/Fm
0.594
0.650
0.445
0.700
0.586

F3/F32
−0.739
−0.736
−0.372
−0.380
−0.258

(Ra + Rb)/
−0.054
−0.056
0.057
−0.009
0.450

(Ra − Rb)

F1/Fm
1.087
1.126
1.794
2.005
2.249

|F2/Fm|
0.226
0.234
0.342
0.370
0.413

F4/Fm
0.991
0.939
0.678
1.680
0.697

[0129] Next, an embodiment in which the zoom lens described above is applied to a photographing apparatus will be described with reference to FIG. 36.

[0130]
FIG. 36 is a schematic diagram showing major portions of a single reflex camera. In FIG. 36, reference numeral 10 designates a photographing lens having the zoom lens 1 described above. The zoom lens 1 is held by a barrel 2, i.e. a holding member. Reference numeral 20 designates a camera main body which includes a quick return mirror 3 for reflecting rays of light from the photographing lens 10 upwardly, a focusing glass 4 disposed at a imaging forming position of the photographing lens 10, a pentadahaprism 5 for converting an inverted image formed on the focusing glass 4 into an erect image, and an eyepiece lens 6 or the like for observing the erect image. Reference numeral 7 designates a film plane. During photographing, the quick return mirror 3 is retracted from the optical path so that an image is formed on the film plane 7 by the photographing lens 10.

[0131] The zoom lens described above can be effectively applied to the photographing apparatus as described with reference to this embodiment.

[0132] According to the present invention, a relatively small and light-weight lens group forming a part of a zoom lens is moved in a direction perpendicular to an optical axis to correct an image blur cause due to fluctuation (inclination) of the zoom lens. In this system, the lens arrangement for the zoom lens is optimized to realize the zoom lens which is compact in size, simple in mechanism, small in load when applied to driving means, and which can effectively correct certain image blur with small amount of displacement of the lens group.

Zoom lens and photographing apparatus having the same

Information

Publication Number

Date Filed

Date Published

Inventors

CPC

US Classifications

International Classifications

Abstract

Description

Claims

Priority Claims (1)