Variable magnification optical system having image stabilizing function

BACKGROUND OF THE INVENTION

1. Field of the Invention

The present invention relates to variable magnification optical systems having an image stabilizing function and, more particularly, to variable magnification optical systems having an image stabilizing function suited to photographic cameras or video cameras, in which a lens unit constituting part of the variable magnification optical system is moved in a direction perpendicular to an optical axis so as to optically compensate for the shaking of a picked-up image obtained when the variable magnification optical system vibrates (tilts), so that the picked-up image is maintained stable.

2. Description of Related Art

When shooting is performed with a photographing system on a running car, a flying air plane or the like moving vehicle, vibrations propagate to the photographing system, so that shaking would be caused in the picked-up image.

To prevent the occurrence of such image shaking, there have been many previous proposals for stabilizing the image formed in the optical system.

For example, in Japanese Patent Publication No. Sho 56-21133, in accordance with the output signal of a detecting means for detecting a vibration state of an optical apparatus, an optical member constituting part of the optical apparatus is moved in such a direction as to cancel the vibrating displacement of an image caused by the vibration of the optical apparatus, so that the image is maintained stable.

In Japanese Laid-Open Patent Application No. Sho 61-223819, in a photographing system provided with a variable angle prism of the refracting type arranged at the frontmost position thereof, an apex angle of the variable angle prism is varied in correspondence to the vibration of the photographing system so as to deflect an image, thereby stabilizing the image.

In Japanese Patent Publications No. Sho 56-34847 and No. Sho 57-7414, etc., an optical member, which is spatially fixed against the vibration of a photographing system, is disposed in part of the photographing system, and a prism effect produced by the optical member against the vibration is utilized to deflect a picked-up image, thereby stabilizing the image on a focal plane.

In Japanese Laid-Open Patent Applications No. Hei 1-116619 and No. Hei 2-124521, an acceleration sensor or the like is utilized to detect the vibration of a photographing system, and, in response to the detection signal obtained therefrom, a lens unit constituting part of the photographing system is vibrated in a direction perpendicular to an optical axis so as to stabilize a picked-up image.

Also, Japanese Laid-Open Patent Application No. Hei 7-128619 discloses a variable magnification optical system comprising, in order from the object side, a first lens unit of positive refractive power which is stationary during focusing and during zooming, a second lens unit of negative refractive power which has a magnification varying function, an aperture stop, a third lens unit of positive refractive power, and a fourth lens unit of positive refractive power, which has both the function of compensating for the shifting of the image with the variation of the magnification and the focusing function, wherein the third lens unit is composed of two lens sub-units, i.e., a first lens sub-unit of negative refractive power and a second lens sub-unit of positive refractive power, and the second lens sub-unit is moved in a direction perpendicular to an optical axis so as to compensate for the shaking of a picked-up image when the variable magnification optical system vibrates.

In Japanese Laid-Open Patent Application No. Hei 7-199124, in a 4-unit-type variable magnification optical system of a plus-minus-plus-plus refractive power arrangement, the entirety of the third lens unit is vibrated in a direction perpendicular to an optical axis so as to stabilize a picked-up image.

Meanwhile, Japanese Laid-Open Patent Application No. Hei 5-60974 discloses another 4-unit-type variable magnification optical system of a plus-minus-plus-plus refractive power arrangement, wherein the third lens unit is composed of a positive lens and a negative lens of meniscus form in the form of the telephoto type, thereby producing the advantage of reducing the total length of the entire system.

In general, the use of the method of stabilizing a picked-up image by disposing the image stabilizing optical system in front of the photographing system and vibrating a movable lens unit constituting part of the image stabilizing optical system so as to compensate for the shaking of the picked-up image causes a problem to arise in that the entire apparatus becomes larger in size and that an operating mechanism for moving the movable lens unit becomes complicated in structure.

Further, there is even a more serious problem, too, that when the movable lens unit is vibrated, a great amount of decentering aberrations would be produced with the result of a large deterioration of the optical performance.

In an optical system using the variable angle prism in stabilizing a picked-up image, there is a problem that the amount of decentering lateral chromatic aberrations produced during the image stabilization would increase, particularly, on the side of long focal lengths (telephoto side).

On the other hand, in an optical system in which a lens unit constituting part of the photographing system is vibrated in a direction perpendicular to the optical axis so as to stabilize a picked-up image, there is, an advantage that any additional optical unit dedicated to the image stabilization is unnecessary. However, there are problems that a surplus space has to be provided in the optical system so as to move the vibrating lens unit and that the amount of decentering aberrations produced during the image stabilization would increase greatly.

Further, in the 4-unit type variable magnification optical system described above which comprises positive, negative, positive and positive lens units, if the third lens unit is composed of a positive lens and a negative meniscus lens in the form of telephoto type for the purpose of shortening of the total length of the entire system, large decentering aberrations, particularly, distortional aberrations, are produced when the whole third lens unit is moved in a direction perpendicular to the optical axis to stabilize a picked-up image. In the case of applying such a variable magnification optical system to the apparatus for taking motion pictures, such as video cameras, there is a problem that the deformation of a picked-up image during the image stabilization becomes conspicuous.

BRIEF SUMMARY OF THE INVENTION

In accordance with the present invention, a relatively small-sized, light-weight lens unit constituting part of a variable magnification optical system is moved in a direction perpendicular to an optical axis so as to compensate for the shaking of an image when the variable magnification optical system vibrates (tilts). By setting forth proper rules of design for the construction and arrangement of constituent lenses of the lens unit, the size of the entire system is minimized, the structure of an operating mechanism is simplified, and the load on a driving means is reduced, while still permitting the amount of decentering aberrations produced during the movement of the lens unit to be suppressed to a minimum. It is, therefore, an object of the invention to provide a variable magnification optical system having an image stabilizing function that is corrected well for decentering aberrations.

To attain the above object, in accordance with an aspect to the invention, there is provided a variable magnification optical system having an image stabilizing function, which comprises, in order from an object side to an image side, a fixed first lens unit of positive refractive power, a second lens unit of negative refractive power, a third lens unit of positive refractive power and a fourth lens unit of positive refractive power, the second lens unit and the fourth lens unit being moved to effect a variation of magnification, wherein the third lens unit has a negative lens of meniscus form concave toward the image side and an aspheric surface, and the third lens unit is movable in a direction perpendicular to an optical axis to stabilize an image.

In accordance with another aspect of the invention, there is provided a variable magnification optical system having an image stabilizing function, which comprises, in order from an object side to an image side, a fixed first lens unit of positive refractive power, a second lens unit of negative refractive power, a third lens unit of positive refractive power and a fourth lens unit of positive refractive power, the second lens unit and the fourth lens unit being moved to effect a variation of magnification, wherein the third lens unit has two lens sub-units of positive refractive power, one of which is fixed, and the other of which is movable in a direction perpendicular to an optical axis to stabilize an image.

The above and further objects and features of the invention will become apparent from the following detailed description of preferred embodiments thereof taken in conjunction with the accompanying drawings.

BRIEF DESCRIPTION OF THE SEVERAL VIEWS OF THE DRAWING

FIG. 1

is a schematic diagram of the paraxial refractive power arrangement of a variable magnification optical system according to the invention.

FIG. 2

is a lens block diagram of a numerical example 1 of the invention in the wide-angle end.

FIG. 3A

is a lens block diagram of a numerical example 2 of the invention at the wide-angle end.

FIG. 3B

is a diagram of geometry for explaining the distortional aberration.

FIG. 4

is a lens block diagram of a numerical example 3 of the invention at the wide-angle end.

FIGS. 5A

to

5

D are graphic representations of the aberrations of the numerical example 1 of the invention at the wide-angle end.

FIGS. 6A

to

6

D are graphic representations of the aberrations of the numerical example 1 of the invention in a middle focal length position.

FIGS. 7A

to

7

D are graphic representations of the aberrations of the numerical example 1 of the invention at the telephoto end.

FIGS. 8A

to

8

D are graphic representations of the aberrations of the numerical example 2 of the invention at the wide-angle end.

FIGS. 9A

to

9

D are graphic representations of the aberrations of the numerical example 2 of the invention in a middle focal length position.

FIGS. 10A

to

10

D are graphic representations of the aberrations of the numerical example 2 of the invention at the telephoto end.

FIGS. 11A

to

11

D are graphic representations of the aberrations of the numerical example 3 of the invention at the wide-angle end.

FIGS. 12A

to

12

D are graphic representations of the aberrations of the numerical example 3 of the invention in a middle focal length position.

FIGS. 13A

to

13

D are graphic representations of the aberrations of the numerical example 3 of the invention at the telephoto end.

FIGS. 14A

to

14

D are schematic diagrams for explaining the optical principle of the image stabilizing system according to the invention.

FIG. 15

is a lens block diagram of a numerical example 4 of the invention at the wide-angle end.

FIG. 16

is a lens block diagram of a numerical example 5 of the invention at the wide-angle end.

FIG. 17

is a lens block diagram of a numerical example 6 of the invention at the wide-angle end.

FIGS. 18A

to

18

D are graphic representations of the aberrations of the numerical example 4 of the invention at the wide-angle end.

FIGS. 19A

to

19

D are graphic representations of the aberrations of the numerical example 4 of the invention in a middle focal length position.

FIGS. 20A

to

20

D are graphic representations of the aberrations of the numerical example 4 of the invention at the telephoto end.

FIGS. 21A

to

21

D are graphic representations of the aberrations of the numerical example 5 of the invention at the wide-angle end.

FIGS. 22A

to

22

D are graphic representations of the aberrations of the numerical example 5 of the invention in a middle focal length position.

FIGS. 23A

to

23

D are graphic representations of the aberrations of the numerical example 5 of the invention at the telephoto end.

FIGS. 24A

to

24

D are graphic representations of the aberrations of the numerical example 6 of the invention at the wide-angle end.

FIGS. 25A

to

25

D are graphic representations of the aberrations of the numerical example 6 of the invention in a middle focal length position.

FIGS. 26A

to

26

D are graphic representations of the aberrations of the numerical example 6 of the invention at the telephoto end.

FIG. 27

is a schematic diagram of the paraxial refractive power arrangement of a variable magnification optical system according to another embodiment of the invention, which corresponds to numerical examples 7 to 9.

FIG. 28

is a lens block diagram of the numerical example 7 at the wide-angle end.

FIG. 29

is a lens block diagram of the numerical example 8 at the wide-angle end.

FIG. 30

is a lens block diagram of the numerical example 9 at the wide-angle end.

FIGS. 31A

to

31

D are graphic representations of the various aberrations of the numerical example 7 at the wide-angle end.

FIGS. 32A

to

32

D are graphic representations of the various aberrations of the numerical example 7 in a middle focal length position.

FIGS. 33A

to

33

D are graphic representations of the various aberrations of the numerical example 7 at the telephoto end.

FIGS. 34A

to

34

D are graphic representations of the various aberrations of the numerical example 8 at the wide-angle end.

FIGS. 35A

to

35

D are graphic representations of the various aberrations of the numerical example 8 in a middle focal length position.

FIGS. 36A

to

36

D are graphic representations of the various aberrations of the numerical example 8 at the telephoto end.

FIGS. 37A

to

37

D are graphic representations of the various aberrations of the numerical example 9 at the wide-angle end.

FIGS. 38A

to

38

D are graphic representations of the various aberrations of the numerical example 9 in a middle focal length position.

FIGS. 39A

to

39

D are graphic representations of the various aberrations of the numerical example 9 at the telephoto end.

DETAILED DESCRIPTION OF THE INVENTION

Hereinafter, preferred embodiments of the invention will be described in detail with reference to the drawings.

FIG. 1

shows a thin lens system whose paraxial refractive power arrangement is equivalent to those of the numerical examples 1 to 3 of an embodiment of the invention, which will be described more fully later.

FIGS. 2

,

3

A and

4

are longitudinal section views of the numerical examples 1 to 3 of variable magnification optical systems of the invention at the wide-angle end, respectively.

In these figures, reference character L

1

denotes a first lens unit of positive refractive power, reference character L

2

denotes a second lens unit of negative refractive power, and reference character L

3

denotes a third lens unit of positive refractive power.

In this embodiment, the third lens unit L

3

is made to move in a direction perpendicular to an optical axis to compensate for the shaking of an image on the focal plane when the variable magnification optical system vibrates (or tilts.)

Reference character L

4

denotes a fourth lens unit of positive refractive power. Reference character SP stands for an aperture stop positioned in front of the third lens unit L

3

, reference character G stands for a glass block such as face plate, and reference character IP stands for an image plane.

In the present embodiment, during zooming from the wide-angle end to the telephoto end, as shown by the arrows, the second lens unit moves toward the image side, while simultaneously moving the fourth lens unit to compensate for the shifting of the image with variation of the magnification.

The fourth lens unit is also made to axially move for focusing purposes. That is, the rear focusing method is employed. A curved solid line

4

a

and a curved dashed line

4

b

in

FIG. 1

show the loci of motion of the fourth lens unit to compensate for the shifting of the image with zooming from the wide-angle end to the telephoto end when focused on an infinitely distant object and a close object, respectively. Incidentally, the first and third lens units remain stationary during zooming and during focusing.

In the present embodiment, the function of compensating for the shifting of the image with zooming and the focusing function both are performed by moving one and the same lens unit, i.e., the fourth lens unit. In particular, as shown by the curved lines

4

a

and

4

b

in

FIG. 1

, the total zooming movement depicts a locus convex toward the object side. This assures efficient utilization of the space between the third lens unit and the fourth lens unit, thus achieving a much desired shortening of the total length of the entire optical system.

In the present embodiment, with the setting in, for example, the telephoto end, during focusing from an infinitely distant object to a close object, the fourth lens unit moves forward as shown by a straight line

4

c

in FIG.

1

.

The optical system in the present embodiment takes a zoom type in which the first and second lens units as a composite system form a virtual image that is focused to a real image on a photosensitive surface by the third and fourth lens units.

In the present embodiment, as compared with the conventional so-called 4-component zoom lens that moves the first component forward to effect focusing, the effective diameter of the first lens unit is prevented from becoming larger, by employing the rear focusing method described above with an advantage of defending the performance against deterioration due to an error of axial alignment of the first lens unit.

Then, by locating the aperture stop just in front of the third lens unit, the variation of aberrations of the movable lens units is lessened, and the axial separation between the lens units ahead of the aperture stop is shortened to facilitate reduction of the diameter of the front members of the first lens unit.

In the numerical examples 1 to 3 of the invention, the third lens unit L

3

is made to move in a direction perpendicular to the optical axis so as to compensate for the shaking of the image when the variable magnification optical system vibrates. This enables the image to be stabilized, without having to add a novel optical member, such as the lens unit, for sole use in stabilizing the image, or a variable angle prism as is necessary in the prior art.

Next, for the variable magnification optical system to function as the image stabilizing system, because, according to the invention, the shaking of the image on the focal plane is compensated for by moving the lens unit in the direction perpendicular to the optical axis, the optical principle to be used will be explained by using

FIGS. 14A

to

14

D.

As shown in

FIG. 14A

, an optical system in question is assumed to comprise three parts, i.e., a fixed lens unit Y

1

, a decentering lens unit Y

2

and a fixed lens unit Y

3

. An object point P on the optical axis located sufficiently away from the optical system is assumed to cast itself as an image point p at the center on the focal plane IP.

Now, suppose the optical system with inclusion of the focal plane IP instantaneously tilts by vibration as shown in

FIG. 14B

, then the object point P also instantaneously moves its image to a point p′, shaking the image.

Meanwhile, if the decentering lens unit Y

2

moves in a direction perpendicular to the optical axis, then the image point p shifts to a position p″. The resultant amount and direction of the movement of the image point p depend on the power arrangement, being expressed as the decentering sensitivity of that lens unit.

On this account, the decentering lens unit Y

2

is made to move in an appropriate direction perpendicular to the optical axis and by an appropriate distance so as to bring the displaced image point p′ in

FIG. 14B

to the initial position p. As shown in

FIG. 14D

, the shake compensation or image stabilization is thus performed.

Now assuming that the optical axis has inclined to θ° and letting the focal length of the entire optical system be denoted by f and the decentering sensitivity of the lens unit Y

2

for shifting by TS, the required amount of (shifting) movement, Δ, of the decentering lens unit Y

2

for correcting the inclination is given by the following equation:

Δ=

f

·tan(θ)/

TS.

If the decentering sensitivity TS of the lens unit for shifting is too large, the amount of movement Δ takes a small value. Therefore, the required amount of movement for stabilizing the image can be made small, but it becomes difficult to control the movement with an accuracy high enough to stabilize the image. So, an inadequate correction results.

Particularly for the video camera or digital still camera, because, as the image size of the sensor, such as CCD, is smaller than for the silver halide film, the equivalent focal length to the same image angle is shorter, the shifting lens unit has to move a shorter distance, Δ, to correct the same angle.

Hence, if the precision accuracy of the operating mechanism is on the same order, it results that the insufficiency of correction becomes relatively large.

If the decentering sensitivity TS is too small, on the other hand, the required amount for control of movement of the lens unit for shifting becomes large and the actuator or like driving means for moving the lens unit for shifting also becomes large.

In the present invention, the refractive power arrangement of the lens units is made appropriate to determine the decentering sensitivity TS of the third lens unit at a proper value, thus achieving an optical system which is less inadequate to correct for stabilizing the image due to the control tolerance of the mechanisms and which lays a smaller load on the driving means such as actuator.

In the present embodiment, the third lens unit is composed of a positive lens L

31

of which both lens surfaces are convex, a negative lens L

32

of meniscus form having a strong concave surface facing the image side and a positive lens L

33

of meniscus form convex toward the object side, as arranged in this order from the object side.

In the numerical examples 1 and 2 shown in FIG.

2

and

FIG. 3A

, respectively, the front surface (on the object side) of the positive lens L

31

and the rear surface (on the image side) of the positive lens L

33

are formed to aspheric shapes.

Using the negative lens of meniscus form concave toward the image side, the third lens unit as a whole takes the telephoto form. Accordingly, the interval between the principal points of the second and third lens units is shortened, thus achieving a shortening of the total length of the optical system.

In a case where such a negative meniscus lens is introduced, its surfaces produce positive distortion.

Now suppose that the third lens unit as a whole has positive distortion and that the third lens unit as a whole has moved upward as shown in

FIG. 3A

for the purpose of stabilizing an image. At this time, an off-axial ray which advances to a point S

1

passes through the third lens unit at a lower height. So, the positive distortion decreases. For another off-axial ray which advances to a point S

2

, the positive distortion increases. Therefore, an object of rectangular shape, when imaged, deforms to a trapezoid, such as that shown by solid lines in FIG.

3

B.

Conversely, when the third lens unit has moved downward, the deformation is like that shown by dashed lines in FIG.

3

B. As vibrations are given, the deformation of the image changes. Particularly in motion pictures, the viewer is made uncomfortable. To reduce this deformation, one need only decrease the distortion produced by the whole third lens unit.

In the numerical examples 1 and 2, the positive lens L

33

is positioned on the image side of the negative meniscus lens L

32

and has its rear surface provided with an asphere. Accordingly, while keeping the telephoto form, the distortion is corrected in the third lens unit. The decentering distortion produced when the image is stabilized by shifting the third lens unit is thus reduced.

Also, since, in the numerical examples 1 and 2, the lens L

31

is provided with an aspheric surface at the front surface, the spherical aberration is suppressed in the third lens unit, which in turn reduces the decentering coma in stabilizing the image.

In the numerical examples 3 shown in

FIG. 4

, the negative lens L

32

of meniscus form is provided with an aspheric surface at the rear surface. Accordingly, while keeping the telephoto form, the distortion is corrected in the third lens unit. The decentering distortion produced when the image is stabilized by shifting the third lens unit is thus reduced. The lens L

31

, too, is provided with an aspheric surface at the front surface to suppress the spherical aberration and coma within the third lens unit. The decentering coma is thus reduced in stabilizing the image.

The features described above, when satisfied, realize the variable magnification optical system having the image stabilizing function according to the invention. To further improve the optical performance, while still maintaining the shortening of the total length of the optical system to be achieved, it is preferable to satisfy at least one of the following conditions.

(i-1) The focal length f

3

N of the negative lens L

32

in terms of the focal length f

3

of the third lens unit lies in the following range:

1.0

<|f

3

N/f

3

|<1.6 (1).

The inequalities of condition (1) have an aim to make up the third lens unit in the telephoto type to thereby achieve a compact form of the entirety of the optical system. When the lower limit of the condition (1) is exceeded, as this means that the refractive power of the negative lens L

32

in the third lens unit is too strong, it is easier to shorten the total length of the optical system, but the Petzval sum increases in the negative sense so that the curvature of field is difficult to correct. Conversely, when the upper limit is exceeded, the total length of the optical system is left insufficiently shortened. (i-2) The focal length f

3

of the third lens unit in terms of the focal length fW at the wide-angle end of the entire optical system lies in the following range:

2.3

<f

3

/

fW

<4.0 (2).

The inequalities of condition (2) have an aim to make a good compromise between the shortening of the total length of the optical system and the proper decentering sensitivity of the shift lens unit, thus maintaining good performance in stabilizing the image. When the refractive power of the third lens unit is too strong as exceeding the lower limit of the condition (2), the decentering sensitivity of the shift lens unit becomes unduly high. So, the precision accuracy of the operating mechanism must be made severe. Otherwise, the inadequacy of correction would remain large in stabilizing the image. Conversely, when the refractive power of the third lens unit is weakened beyond the upper limit, in some cases, the shifting amount of the third lens unit for stabilizing the image increases greatly.

(i-3) The focal length f

2

of the second lens unit lies in the following range:

0.23

<|f

2

/{square root over (

fW·fT

)}|<0.35 (3)

where fW and fT are the focal lengths at the wide-angle end and the telephoto end of the entire optical system, respectively.

When the lower limit of the condition (3) is exceeded, as this means that the focal length of the second lens unit is too strong, the total length of the optical system is easy to shorten, but it becomes objectionably difficult to correct the field curvature and distortion for good stability throughout the entire zooming range. When the refractive power of the second lens unit is too weak over the upper limit of the condition (3), the required movement for the given zoom ratio of the second lens unit increases unduly greatly.

Also, for the image stabilizing optical system according to the invention to secure a compensating angle large enough to stabilize the image in most situations in such a manner that the optical performance is maintained stable throughout the entire range of compensating angles, it is preferable to satisfy the following condition:

\begin{matrix} 3.5 \times 10^{- 3} < \frac{Dm (1 - β 3 t) β 4 t}{fT} < 5.2 \times 10^{- 2} & (4) \end{matrix}

where Dm is the possible maximum movement of the third lens unit when stabilizing the image, and β

3

t and β

4

are the paraxial lateral magnifications at the telephoto end of the third lens unit and the fourth lens unit, respectively.

When the lower limit of the condition (4) is exceeded, the compensating angle for stabilizing the image becomes small, so that the image stabilizing effect becomes small. When the upper limit is exceeded, the stabilization of the image causes deterioration of the optical performance and conspicuous changes of the light amount

Next, the numerical examples 1 to 3 of the invention are shown with the numerical data in tables below, where Ri is the radius of curvature of the i-th lens surface when counted from the object side, Di is the i-th lens thickness or air separation when counted from the object side, and Ni and νi are respectively the refractive index and Abbe number of the glass of the i-th lens element when counted from the object side.

The values of the factors in the above-described conditions (1) to (4) for the numerical examples 1 to 3 are listed in Table-1.

The shape of the aspheric surface is expressed in the coordinates with an X axis in the axial direction and an H axis in the direction perpendicular to the optical axis, the direction in which light advances being taken as positive, by the following equation:

X = \frac{(1 / R) H^{2}}{1 + \sqrt{1 - {(H / R)}^{2}}} + {AH}^{2} + {BH}^{4} + {CH}^{6} + {DH}^{8} + {EH}^{10}

where R is the radius of the osculating sphere, and A, B, C, D and E are the aspheric coefficients. The values of the aspheric coefficients are also tabulated where the notation: “e−

0

X” means 10

−x

.

NUMERICAL EXAMPLE 1

f = 1-9.75

Fno = 1.85-2.46

2ω = 60.5°-6.8°

R1 = 12.404

D1 = 0.18

N1 = 1.84666

ν1 = 23.8

R2 = 4.052

D2 = 1.21

N2 = 1.71299

ν2 = 53.8

R3 = −17.341

D3 = 0.04

R4 = 3.150

D4 = 0.60

N3 = 1.77249

ν3 = 49.6

R5 = 6.789

D5 = Variable

R6 = 4.605

D6 = 0.14

N4 = 1.88299

ν4 = 40.8

R7 = 1.042

D7 = 0.54

R8 = −1.239

D8 = 0.12

N5 = 1.71299

ν5 = 53.8

R9 = 1.474

D9 = 0.44

N6 = 1.84666

ν6 = 23.8

R10 = −10.154

D10 = Variable

R11 = Stop

D11 = 0.33

*R12 = 1.589

D12 = 0.86

N7 = 1.66910

ν7 = 55.4

R13 = −20.729

D13 = 0.04

R14 = 2.119

D14 = 0.14

N8 = 1.84666

ν8 = 23.8

R15 = 1.189

D15 = 0.21

R16 = 2.082

D16 = 0.40

N9 = 1.58312

ν9 = 59.4

*R17 = 4.282

D17 = Variable

*R18 = 2.376

D18 = 0.64

N10 = 1.58312

ν10 = 59.4

R19 = −1.744

D19 = 0.12

N11 = 1.84666

ν11 = 23.8

R20 = −3.655

D20 = 0.71

R21 = ∞

D21 = 0.88

N12 = 1.51633

ν12 = 64.1

R22 = ∞

*Aspheric Surface

Aspheric Coefficients:

R12:

K = −3.068e + 00

B = 6.133e − 02

C = −1.048e − 02

D = −4.205e − 03

E = 2.843e − 03

R17:

K = −5.948e + 01

B = 7.172e − 02

C = −5.099e − 02

D = 5.965e − 03

E = 0

R18:

K = −4.437e + 00

B = 3.052e − 02

C = −6.496e − 03

D = 9.474e − 03

E = −1.915e − 03

Variable

Focal Length

Separation

1.00

4.61

9.75

D5

0.14

2.06

2.60

D10

2.65

0.73

0.19

D17

1.34

0.52

1.36

The Maximum Movement of the third Lens Unit: 0.320

NUMERICAL EXAMPLE 2

f = 1-9.77

Fno = 1.85-2.57

2ω = 59.4°-6.7°

R1 = 12.041

D1 = 0.17

N1 = 1.80518

ν1 = 25.4

R2 = 3.662

D2 = 1.19

N2 = 1.69679

ν2 = 55.5

R3 = −15.896

D3 = 0.04

R4 = 2.995

D4 = 0.59

N3 = 1.77249

ν3 = 49.6

R5 = 6.384

D5 = Variable

R6 = 4.213

D6 = 0.14

N4 = 1.88299

ν4 = 40.8

R7 = 0.999

D7 = 0.52

R8 = −1.184

D8 = 0.12

N5 = 1.69679

ν5 = 55.5

R9 = 1.425

D9 = 0.42

N6 = 1.84666

ν6 = 23.8

R10 = −14.838

D10 = Variable

R11 = Stop

D11 = 0.33

*R12 = 1.485

D12 = 0.70

N7 = 1.66910

ν7 = 55.4

R13 = −15.967

D13 = 0.03

R14 = 2.006

D14 = 0.14

N8 = 1.84666

ν8 = 23.8

R15 = 1.169

D15 = 0.24

R16 = 2.449

D16 = 0.35

N9 = 1.58312

ν9 = 59.4

*R17 = 4.140

D17 = Variable

*R18 = 2.346

D18 = 0.63

N10 = 1.58913

ν10 = 61.2

R19 = −1.584

D19 = 0.12

N11 = 1.84666

ν11 = 23.8

R20 = −3.394

D20 = 0.70

R21 = ∞

D21 = 0.86

N12 = 1.51633

ν12 = 64.1

R22 = ∞

Aspheric Coefficients:

R12:

K = −2.933e + 00

B = 7.010e − 02

C = −1.269e − 02

D = −4.760e − 03

E = 3.375e − 03

R17:

K = −4.936e + 01

B = 7.490e − 02

C = −3.698e − 02

D = 7.116e − 03

E = 0

R18:

K = −4.241e + 00

B = 3.389e − 02

C = −9.367e − 03

D = 1.652e − 02

E = −5.909e − 03

Variable

Focal Length

Separation

1.00

4.61

9.77

D5

0.13

1.94

2.45

D10

2.51

0.70

0.19

D17

1.42

0.60

1.48

The Maximum Movement of the third Lens Unit: 0.150

NUMERICAL EXAMPLE 3

f = 1-9.76

Fno = 1.85-2.44

2ω = 60.5°-6.8°

R1 = 13.534

D1 = 0.18

N1 = 1.84666

ν1 = 23.8

R2 = 4.112

D2 = 1.21

N2 = 1.71299

ν2 = 53.8

R3 = −16.831

D3 = 0.04

R4 = 3.173

D4 = 0.60

N3 = 1.77249

ν3 = 49.6

R5 = 6.780

D5 = Variable

R6 = 4.370

D6 = 0.14

N4 = 1.83480

ν4 = 42.7

R7 = 1.013

D7 = 0.57

R8 = −1.234

D8 = 0.12

N5 = 1.69679

ν5 = 55.5

R9 = 1.525

D9 = 0.44

N6 = 1.84666

ν6 = 23.8

R10 = −11.259

D10 = Variable

R11 = Stop

D11 = 0.33

*R12 = 1.649

D12 = 0.76

N7 = 1.67790

ν7 = 55.3

R13 = −13.084

D13 = 0.04

R14 = 2.280

D14 = 0.14

N8 = 1.84666

ν8 = 23.8

*R15 = 1.243

D15 = 0.18

R16 = 2.016

D16 = 0.40

N9 = 1.58312

ν9 = 59.4

R17 = 4.117

D17 = Variable

*R18 = 2.391

D18 = 0.64

N10 = 1.58913

ν10 = 61.2

R19 = −1.763

D19 = 0.12

N11 = 1.84666

ν11 = 23.8

R20 = −3.732

D20 = 0.60

R21 = ∞

D21 = 0.88

N12 = 1.51633

ν12 = 64.1

R22 = ∞

Aspheric Coefficients:

R12:

K = −3.240e + 00

B = 6.578e − 02

C = −1.729e − 02

D = −8.774e − 04

E = 1.601e − 03

R15:

K = 1.204e − 01

B = −2.688e − 03

C = 1.003e − 02

D = −2.891e − 02

E = 0

R18:

K = −3.069e + 00

B = 2.134e − 02

C = −4.778e − 03

D = 1.123e − 02

E = −4.209e − 03

Variable

Focal Length

Separation

1.00

4.47

9.76

D5

0.15

2.13

2.69

D10

2.74

0.75

0.19

D17

1.64

0.81

1.63

The Maximum Movement of the third Lens Unit: 0.250

TABLE 1

Numerical Example

Condition

1

2

3

(1)

|f3N/f3|

1.233

1.318

1.256

(2)

f3/fW

2.795

2.719

2.744

(3)

|f2/{square root over (fW · fT)}|

0.282

0.268

0.280

(4)

\frac{Dm (1 - β 3 t) β 4 t}{fT}

0.0353

0.0167

0.0285

X = \frac{(1 / R) H^{2}}{1 + \sqrt{1 - {(H / R)}^{2}}} + {AH}^{2} + {BH}^{4} + {CH}^{6} + {DH}^{8} + {EH}^{10}

f = 1-9.75

Fno = 1.85-2.43

2ω = 60.5°-6.8°

R1 = 13.432

D1 = 0.18

N1 = 1.84666

ν1 = 23.8

R2 = 4.279

D2 = 1.21

N2 = 1.71299

ν2 = 53.8

R3 = −16.292

D3 = 0.04

R4 = 3.174

D4 = 0.60

N3 = 1.77249

ν3 = 49.6

R5 = 6.374

D5 = Variable

R6 = 4.590

D6 = 0.14

N4 = 1.88299

ν4 = 40.8

R7 = 1.088

D7 = 0.56

R8 = −1.302

D8 = 0.12

N5 = 1.71700

ν5 = 47.9

R9 = 1.618

D9 = 0.44

N6 = 1.84666

ν6 = 23.8

R10 = −7.312

D10 = Variable

R11 = Stop

D11 = 0.31

*R12 = 1.614

D12 = 0.45

N7 = 1.58312

ν7 = 59.4

R13 = 23.575

D13 = 0.02

R14 = 2.006

D14 = 0.14

N8 = 1.84666

ν8 = 23.8

R15 = 1.372

D15 = 0.43

*R16 = 5.106

D16 = 0.26

N9 = 1.58312

ν9 = 59.4

R17 = −21.356

D17 = Variable

*R18 = 2.762

D18 = 0.64

N10 = 1.58312

ν10 = 59.4

R19 = −1.484

D19 = 0.12

N11 = 1.84666

ν11 = 23.8

R20 = −2.909

D20 = 0.71

R21 = ∞

D21 = 0.88

N12 = 1.51633

ν12 = 64.1

R22 = ∞

*Aspheric Surface

Aspheric Coefficients:

R12:

K = −1.847e − 02

B = −2.316e − 02

C = 1.045e − 03

D = −4.875e − 03

E = 0

R16:

K = 9.862e + 00

B = −1.198e − 02

C = −1.155e − 03

D = −2.915e − 03

E = 5.173e − 0

R18:

K = −1.754e + 00

B = 6.556e − 03

C = −5.764e − 03

D = 1.252e − 02

E = −3.690e − 03

Variable

Focal Length

Separation

1.00

4.42

9.75

D5

0.14

2.15

2.72

D10

2.77

0.76

0.19

D17

1.69

1.09

1.94

NUMERICAL EXAMPLE 5

f = 1-9.75

Fno = 1.85-2.43

2ω = 60.5°-6.8°

R1 = 13.123

D1 = 0.18

N1 = 1.84666

ν1 = 23.8

R2 = 4.332

D2 = 1.21

N2 = 1.71299

ν2 = 53.8

R3 = −15.563

D3 = 0.04

R4 = 3.205

D4 = 0.60

N3 = 1.77249

ν3 = 49.6

R5 = 6.250

D5 = Variable

R6 = 4.973

D6 = 0.14

N4 = 1.88299

ν4 = 40.8

R7 = 1.098

D7 = 0.53

R8 = −1.293

D8 = 0.12

N5 = 1.71700

ν5 = 47.9

R9 = 1.554

D9 = 0.44

N6 = 1.84666

ν6 = 23.8

R10 = −7.532

D10 = Variable

R11 = Stop

D11 = 0.31

*R12 = 2.768

D12 = 0.33

N7 = 1.66910

ν7 = 55.4

R13 = 4.909

D13 = 0.24

*R14 = 1.673

D14 = 0.45

N8 = 1.58312

ν8 = 59.4

R15 = −17.228

D15 = 0.02

R16 = 2.003

D16 = 0.14

N9 = 1.84666

ν9 = 23.8

R17 = 1.290

D17 = Variable

*R18 = 2.427

D18 = 0.64

N10 = 1.58312

ν10 = 59.4

R19 = −1.533

D19 = 0.12

N11 = 1.84666

ν11 = 23.8

R20 = −3.220

D20 = 0.71

R21 = ∞

D21 = 0.88

N12 = 1.51633

ν12 = 64.1

R22 = ∞

Aspheric Coefficients:

R12:

K = −6.606e + 00

B = 2.935e − 02

C = −9.942e − 03

D = 3.892e − 04

E = −2.100e − 03

R14:

K = −3.167e − 01

B = −1.124e − 02

C = −4.208e − 03

D = 2.283e − 03

E = 0

R18:

K = −2.585e + 00

B = 1.786e − 02

C = −1.134e − 02

D = 1.482e − 02

E = −2.606e − 03

Variable

Focal Length

Separation

1.00

4.53

9.75

D5

0.14

2.17

2.74

D10

2.79

0.76

0.19

D17

1.73

1.09

1.94

NUMERICAL EXAMPLE 6

f = 1-9.75

Fno = 1.85-2.25

2ω = 60.5°-6.8°

R1 = 13.453

D1 = 0.18

N1 = 1.84666

ν1 = 23.8

R2 = 4.446

D2 = 1.29

N2 = 1.69679

ν2 = 55.5

R3 = −13.988

D3 = 0.04

R4 = 3.223

D4 = 0.60

N3 = 1.77249

ν3 = 49.6

R5 = 6.152

D5 = Variable

R6 = 5.790

D6 = 0.14

N4 = 1.88299

ν4 = 40.8

R7 = 1.116

D7 = 0.53

R8 = −1.274

D8 = 0.12

N5 = 1.69350

ν5 = 53.2

R9 = 1.679

D9 = 0.44

N6 = 1.84666

ν6 = 23.8

R10 = −8.414

D10 = Variable

*R11 = 3.966

D11 = 0.29

N7 = 1.66910

ν7 = 55.4

R12 = 23.810

D12 = 0.24

R13 = Stop

D13 = 0.33

*R14 = 1.637

D14 = 0.45

N8 = 1.58312

ν8 = 59.4

R15 = −14.062

D15 = 0.02

R16 = 2.342

D16 = 0.14

N9 = 1.84666

ν9 = 23.8

R17 = 1.365

D17 = Variable

*R18 = 2.331

D18 = 0.60

N10 = 1.58312

ν10 = 59.4

R19 = −1.690

D19 = 0.12

N11 = 1.84666

ν11 = 23.8

R20 = −3.598

D20 = 0.71

R21 = ∞

D21 = 0.88

N12 = 1.51633

ν12 = 64.1

R22 = ∞

Aspheric Coefficients:

R11:

K = −1.316e + 01

B = 2.207e − 02

C = −9.331e − 03

D = −1.570e − 03

E = 2.801e − 03

R14:

K = −4.979e − 01

B = −1.037e − 02

C = 1.652e − 04

D = 5.116e − 04

E = 0

R18:

K = −1.937e + 00

B = 1.339e − 02

C = −1.140e − 02

D = 1.230e − 02

E = −2.217e − 04

Variable

Focal Length

Separation

1.00

4.52

9.75

D5

0.15

2.22

2.80

D10

2.85

0.78

0.19

D17

1.86

1.11

1.89

TABLE 2

Numerical Example

Condition

4

5

6

(5)

fSL/f3

1.523

1.517

1.684

(6)

|f2/{square root over (fW · fT)}|

0.312

0.309

0.306

(7)

f3/fW

3.284

3.150

3.002

It will be appreciated from the foregoing that, according to the invention, as applied to the variable magnification optical system in which a lens unit of relatively small size and light weight moves in the direction perpendicular to the optical axis to compensate for the shaking of the image as the variable magnification optical system vibrates (tilts), the proper rules of design are set forth for the construction and arrangement of the constituent lenses of that lens unit. This produces great advantages of improving the compact form of the entire optical system, simplifying the structure of the operating mechanism, and reducing the load on the driving means, while still permitting the decentering aberrations to be maintained stable at a minimum throughout the entire shifting range. A variable magnification optical system having the image stabilizing function which is corrected well for the decentering aberrations is thus achieved.

By the way, in recent years, even for the video camera for home use to improve the image quality, the 3-CCD model is employed in some cases. However, if, as the variable magnification optical system with four lens units of positive, negative, positive and positive refractive powers is adapted to the 3-CCD model, its third lens unit is made movable as a whole in a direction perpendicular to the optical axis to compensate for the shaking of the image , the sensitivity for correction of the optical axis of the third lens unit for image stabilization becomes too much small. In turn, the amount of movement of the third lens unit as the compensating lens unit becomes too much large. Accordingly, there is a problem that the entire optical system increases in diameter unduly greatly.

An embodiment to describe below is concerned with an image-stabilizing variable magnification optical system which has further promoted the compactness of the optical system.

FIG. 27

schematically shows the paraxial refractive power arrangement of the present embodiment.

FIGS. 28

to

30

are the lens block diagrams of numerical examples 7 to 9 at the wide-angle end, respectively.

In

FIGS. 27

to

30

, reference character L

1

denotes a first lens unit of positive refractive power, reference character L

2

denotes a second lens unit of negative refractive power, and reference character L

3

denotes a third lens unit of positive refractive power.

The third lens unit L

3

has at least two lens sub-units, i.e., a first lens sub-unit L

31

of negative refractive power and a second lens sub-unit L

32

of positive refractive power.

In the numerical examples 7 to 9, the second lens sub-unit L

32

is made to move in a direction perpendicular to an optical axis, as indicated by the arrow

3

, to compensate for the shaking of an image on the focal plane as the variable magnification optical system vibrates (tilts).

Reference character L

4

denotes a fourth lens unit of positive refractive power. Reference character SP denotes an aperture stop disposed either in front of the third lens unit L

3

, or in the interior of the third lens unit L

3

, or in a space between the third and fourth lens units L

3

and L

4

. Reference character G denotes a glass block such as phase plate. Reference character IP denotes an image plane.

As shown in

FIG. 27

, in the present embodiment, during zooming from the wide-angle end to the telephoto end, the second lens unit L

2

is moved toward the image side as indicated by the arrow, while the fourth lens unit L

4

is simultaneously moved to compensate for the image shift with zooming.

Also, focusing is performed by axially moving the fourth lens unit L

4

. That is, the rear focusing method is employed. A curved solid line

4

a

and a curved dashed line

4

b

in

FIG. 27

represent the loci of motion of the fourth lens unit L

4

to compensate for the image shift with zooming from the wide-angle end to the telephoto end when focusing on an infinitely distant object and an object at the minimum distance, respectively. Incidentally, the first and third lens units L

1

and L

3

remain stationary during zooming and during focusing.

In the present embodiment, the compensating provision for the image shift with zooming and the focusing provision both are made in the fourth lens unit L

4

. In particular, the total zooming movement of the fourth lens unit L

4

is made to depict a locus convex toward the object side, as shown by the curved lines

4

a

and

4

b

in FIG.

27

. This assures efficient utilization of the space between the third and fourth lens units L

3

and L

4

, thus achieving a shortening of the total length of the entire optical system.

In the present embodiment, with the setting in, for example, the telephoto end, focusing from an infinitely distant object to a close object is performed by moving the fourth lens unit L

4

forward as shown by a straight line

4

c

in FIG.

27

.

The zoom lens in the present embodiment takes a zoom type in which the composite system of the first and second lens units L

1

and L

2

forms a virtual image, which is focused to a real image on a photosensitive surface by the third and fourth lens units L

3

and L

4

.

In the present embodiment, as compared with the conventional so-called 4-component zoom lens in which the first component is moved forward to effect focusing, the diameter of the first lens unit is advantageously prevented from becoming larger by employing the rear focusing method described above, while keeping the performance against deterioration due to the error of axial alignment of the first lens unit.

In addition, the aperture stop SP is disposed either just in front of the third lens unit L

3

, or in the interior of the third lens unit L

3

, or in the space between the third and fourth lens units L

3

and L

4

. This leads to a reduction in the variation of aberrations due to the moving lens units. As the axial separations between any adjacent two of the lens members which lie before the aperture stop SP are shortened, the shortening of the diameter of the front members is made easier to achieve.

In the numerical examples 7 and 9 shown in

FIGS. 28 and 30

, the third lens unit L

3

is constructed with two lens sub-units, the first of which is a first lens sub-unit L

31

of negative refractive power and the second of which is a second lens sub-unit L

32

of positive refractive power. In the numerical example 8 shown in

FIG. 29

, the third lens unit L

3

is constructed with three lens sub-units, the first of which is a first lens sub-unit L

31

of negative refractive power, the second of which is a second lens sub-unit L

32

of positive refractive power and the third is a third lens sub-unit L

33

of positive refractive power.

Incidentally, in the present embodiment, the third lens unit L

3

may be constructed with four or more lens sub-units. Then, the second lens sub-unit in the third lens unit L

3

is used for stabilizing the image. When the variable magnification optical system vibrates, the second lens sub-unit is moved in the direction perpendicular to the optical axis so as to compensate for the image shaking. The image stabilization is thus achieved without having to use any additional optical element such as a unit of mating lenses, or a variable angle prism which is required in the conventional image stabilizing optical systems.

Here, in the photographic lens for the video camera assigned to the 3-CCD model, there is need to create a space the prism for color separation occupies. Therefore, the back focal distance must be made longer than that for the photographic lens for the single plate model. For this reason, the positive refractive power of the third lens unit becomes weak as compared with the positive refractive power of the fourth lens unit. Therefore, the third lens unit has a small sensitivity in the direction perpendicular to the optical axis.

Therefore, if the third lens unit is made to move as a whole in a direction perpendicular to the optical axis to stabilize the image, the amount of movement of the third lens unit becomes too much larger. Supposing that the 4-unit form of zoom lens, which is now common in practice, is used in the photographic lens for the video camera and the decentering sensitivity of the third lens unit is to increase, then a necessity arises in that the refractive power of the third lens unit is increased. This results in a difficulty of securing the back focal distance long enough. Hence, it is not suited to the 3-CCD model.

Therefore, in the present embodiment, the third lens unit L

3

is divided into at least two lens sub-units, i.e., the first lens sub-unit L

31

of negative refractive power and the second lens sub-unit L

32

of positive refractive power. By using the second lens sub-unit L

32

as the shift lens, increasing the refractive power of the second lens sub-unit L

32

and, therefore, increasing its decentering sensitivity, too, an image-stabilizing optical system, although being adapted to the 3-CCD model, is achieved in an improved compact form.

The present embodiment has, despite the use of the image stabilizing function, to achieve improvements of the compact form, so that it provides such an arrangement and construction of the constituent parts of the variable magnification optical system. In this connection, it is preferred to satisfy the following conditions:

8

<f

3

/

fW

<25 (8)

0.3

<|f

32

/

f

3

|<0.75 (9)

where f

3

is the focal length of the third lens unit L

3

, fW is the focal length at the wide-angle end of the entire optical system, and f

32

is the focal length of the second lens sub-unit L

32

.

The inequalities of conditions (8) and (9), in view of the 4-unit zoom lens of the configuration described above, give proper ranges for the focal lengths (refractive powers) of the third lens unit L

3

and the second lens sub-unit L

32

and have an aim chiefly to increase the sensitivity of the shift lens, while securing the sufficiently long back focal distance.

When the lower limit of the condition (8) is exceeded, as this means that the refractive power of the third lens unit L

3

is too strong, although it is advantageous at shortening the total length of the entire optical system, the desired back focal distance becomes difficult to secure. When the refractive power of the third lens unit L

3

is too weak over the upper limit of the condition (8), it becomes difficult to shorten the total length of the entire optical system.

The condition (9) is concerned with the refractive power distribution over the first and second lens sub-units of the third lens unit L

3

. When the proportion of the refractive power of the second lens sub-unit increases over the lower limit of the condition (9), the decentering sensitivity increases rapidly, causing the mechanical tolerance to affect the image stabilization with the result of a large compensation residual. Conversely, when the refractive power of the second lens sub-unit is weaker beyond the upper limit, the required movement for the equivalent compensation of the second lens sub-unit becomes too much large. To drive the second lens sub-unit, the actuator or like drive device, too, has to increase in size objectionably.

It is also preferred that, for the wide-angle end, the back focal distance bfw (the length of the optical path from the last lens surface to the image plane) falls in the following range:

3

<bfw/fW

<6 (10)

By satisfying the condition (10), the zoom lens is made well adapted to the 3-CCD model of video camera.

When the back focal distance is shorter beyond the lower limit of the condition (10), there is no space for the color separation prism to insert therein. Conversely, when the upper limit is exceeded in order to insure an increase of the back focal distance, the first lens sub-unit has to take too strong a refractive power. So, it becomes difficult to keep the optical performance when the optical system is switched to the image stabilization mode by shifting the second lens sub-unit.

It is also preferred that the focal length f

2

of the second lens unit L

2

lies within the following range:

0.3

<|f

2

/{square root over (

fW·fT

)}|<0.5 (11)

where fT is the focal length in the telephoto end of the entire optical system.

By satisfying the condition (11), a further shortening of the total length of the entire optical system can be assured.

When the lower limit of the condition (11) is exceeded, as this means that the refractive power of the second lens unit L

2

is too strong, although it is advantageous at shorting the total length of the entire optical system, the difficulty of correcting the variation of field curvature and distortion over the entire zooming range increases objectionably. When the refractive power of the second lens unit L

2

is too weak as exceeding the upper limit of the condition (11), the required movement for the entire zooming range of the second lens unit L

2

increases objectionably.

Also, in the present embodiment, to sufficiently correct chromatic aberrations throughout the entire zooming range, it is preferred to construct the second lens unit L

2

as comprising, in order from the object side, a negative lens of meniscus form concave toward the image side, a negative lens of bi-concave form, a positive lens and a negative lens. Also, as the back focal distance increases in adaptation to the 3-CCD model, the refractive power of the fourth lens unit L

4

increases and, at the same time, the height at which the axial beam passes through the fourth lens unit L

4

increases to increase the possibility of production of spherical aberrations. It is, therefore, desired to construct the fourth lens unit L

4

with at least one negative lens and two positive lenses and with inclusion of at least one aspheric surface.

Referring to

FIG. 28

, the numerical example 7 is explained, where the third lens unit L

3

comprises, in order from the object side, a fixed first lens sub-unit of negative refractive power and a second lens sub-unit of positive refractive power which shifts in a direction perpendicular to the optical axis in order to compensate for the image shaking. The first lens sub-unit is constructed with a negative lens of bi-concave form and a positive lens. The second lens sub-unit is constructed with a negative lens of meniscus form concave toward the image side and two positive lenses of bi-convex form.

Further, the first and second lens sub-units each are provided with at least one aspheric surface to thereby reduce the various aberrations of the respective individual sub-units to a minimum. The optical performance is thus kept stable against switching to the image stabilization mode.

In the numerical example 7, the aspheric surface is introduced to the frontmost surface in the first lens sub-unit and to the rearmost surface in the second lens sub-unit, so that each sub-unit produces smaller spherical aberration and coma. When stabilizing the image, the decentering aberrations, particularly coma, are corrected well.

Incidentally, any one of the other surfaces in each lens sub-unit may be made aspherical. Also, to correct decentering lateral chromatic aberration and curvature of field, it is desired that the shift lens itself is as well corrected for chromatic aberrations as possible and its Petzval sum is made as small as possible.

Therefore, the inclusion of at least one negative lens in the shift lens (second lens sub-unit) is advantageous at facilitating the correction of chromatic aberrations and the minimization of the Petzval sum. Also, if this measure is to take, the entire optical system has to keep good the chromatic aberrations. For this purpose, it is preferred that, besides the second lens sub-unit, the third lens unit is included with at least one positive lens.

Referring next to

FIG. 29

, the numerical example 8 is explained. The third lens unit L

3

comprises, in order from the object side, a fixed first lens sub-unit of negative refractive power, a second lens sub-unit of positive refractive power, which shifts in a direction perpendicular to the optical axis in order to stabilize the image, and a third lens sub-unit of weak refractive power (its focal length being not less than five times as large as the focal length f

3

of the third lens unit).

The first lens sub-unit is constructed with one negative lens, the second lens sub-unit is constructed with a negative lens and a positive lens of bi-convex form, and the third lens unit is constructed with a cemented lens composed of a negative lens and a positive lens. An aspheric surface is introduced to the second lens sub-unit at the rearmost surface to reduce the spherical aberration and coma in itself. With this aspheric surface, when stabilizing the image, decentering coma is produced at a minimum.

In the numerical example 8, the third lens sub-unit is made to have a weak refractive power relative to the overall one. Accordingly, the third lens unit is corrected as a whole for chromatic aberrations, and, at the same time, the influence of the position error of the third lens sub-unit is minimized.

Referring next to

FIG. 30

, the numerical example 9 is explained. The third lens unit L

3

comprises, in order from the object side, a fixed first lens sub-unit of negative refractive power and a second lens sub-unit of positive refractive power which shifts in the direction perpendicular to the optical axis in order to stabilize the image. The first lens sub-unit is constructed with a negative lens of bi-concave form and a positive lens of bi-convex form. The second lens sub-unit is constructed with a negative lens of meniscus form convex toward the object side and a positive lens of bi-convex form.

The front surface of the first lens sub-unit and the rear surface of the second lens sub-unit are made aspherical to prevent the optical performance from lowering when stabilizing the image.

Next, the numerical examples 7 to 9 are shown with the numerical data in tables below, where Ri is the radius of curvature of the i-th surface when counted from the object side, Di is the i-th lens thickness or air separation when counted from the object side, and Ni and νi are respectively the refractive index and Abbe number of the material of the i-th lens element when counted from the object side. Also, R

29

to R

33

in the numerical example 7, R

28

to R

32

in the numerical example 8 and R

26

to R

30

in the numerical example 9 each represent an optical filter, a phase plate and others, but these can be omitted according to the needs.

The shape of the aspheric surface is expressed in the coordinates with an X axis in the axial direction and an H axis in the direction perpendicular to the optical axis, the direction in which light advances being taken as positive, by the following equation:

X = \frac{(1 / R) H^{2}}{1 + \sqrt{1 - (1 + K) {(H / R)}^{2}}} + {AH}^{2} + {BH}^{4} + {CH}^{6} + {DH}^{8} + {EH}^{10}

where R is the radius of the osculating sphere, and K, A, B, C, D and E are the aspheric coefficients. The values of the aspheric coefficients are also tabulated where the notation: “e−

0

X” means 10

−x

.

The values of the factors in the above-described conditions (8) to (11) for the numerical examples 7 to 9 are listed in Table-3.

NUMERICAL EXAMPLE 7

f = 1˜11.82

Fno = 1.66˜2.85

2ω = 58.4°˜5.4°

R1 = 9.925

D1 = 0.29

N1 = 1.846660

ν1 = 23.8

R2 = 5.595

D2 = 1.12

N2 = 1.487490

ν2 = 70.2

R3 = −43.779

D3 = 0.04

R4 = 5.260

D4 = 0.75

N3 = 1.696797

ν3 = 55.5

R5 = 19.736

D5 = Variable

R6 = 8.248

D6 = 0.18

N4 = 1.882997

ν4 = 40.8

R7 = 1.490

D7 = 0.64

R8 = −3.502

D8 = 0.14

N5 = 1.834807

ν5 = 42.7

R9 = −108.997

D9 = 0.10

R10 = 2.620

D10 = 0.58

N6 = 1.846660

ν6 = 23.8

R11 = −4.432

D11 = 0.05

R12 = −3.132

D12 = 0.14

N7 = 1.804000

ν7 = 46.6

R13 = 4.496

D13 = Variable

R14 = Stop

D14 = 0.96

*R15 = −3.797

D15 = 0.27

N8 = 1.677900

ν8 = 55.3

R16 = 5.698

D16 = 0.48

N9 = 1.761821

ν9 = 26.5

R17 = −8.672

D17 = 0.16

R18 = 9.112

D18 = 0.17

N10 = 1.846660

ν10 = 23.8

R19 = 4.683

D19 = 0.02

R20 = 5.105

D20 = 0.43

N11 = 1.487490

ν11 = 70.2

R21 = −1309.349

D21 = 0.16

R22 = 8.305

D22 = 0.50

N12 = 1.589130

ν12 = 61.2

*R23 = −9.804

D23 = Variable

*R24 = 5.880

D24 = 0.59

N13 = 1.583126

ν13 = 59.4

R25 = −10.117

D25 = 0.05

R26 = 5.327

D26 = 0.18

N14 = 1.846660

ν14 = 23.8

R27 = 2.419

D27 = 0.89

N15 = 1.487490

ν15 = 70.2

R28 = −9.512

D28 = 0.46

R29 = ∞

D29 = 0.32

N16 = 1.516330

ν16 = 64.2

R30 = ∞

D30 = 0.32

N17 = 1.552320

ν17 = 63.4

R31 = ∞

D31 = 0.17

N18 = 1.556710

ν18 = 58.6

R32 = ∞

D32 = 3.19

N19 = 1.589130

ν19 = 61.2

R33 = ∞

*Aspheric Surface

Variable

Focal Length

Separation

1.00

5.26

11.82

D 5

0.18

3.71

4.71

D13

4.87

1.34

0.34

D23

1.57

0.83

1.57

Aspheric Coefficients:

R15:

K = −8.37349e − 01

B = −4.62595e − 03

C = −9.58087e − 04

D = 3.38343e − 05

E = 0.00000e + 00

R23:

K = 1.56127e + 01

B = 2.87554e − 03

C = 1.34138e − 04

D = 5.55133e − 05

E = 0.00000e + 00

R24:

K = 2.53420e − 01

B = −2.12625e − 03

C = 1.63471e − 04

D = −1.34379e − 05

E = 0.00000e + 00

NUMERICAL EXAMPLE 8

f = 1˜11.79

Fno = 1.65˜2.80

2ω = 59.9°˜5.6°

R1 = 10.374

D1 = 0.32

N1 = 1.846660

ν1 = 23.8

R2 = 5.695

D2 = 1.27

N2 = 1.603112

ν2 = 60.6

R3 = −180.598

D3 = 0.04

R4 = 5.778

D4 = 0.78

N3 = 1.696797

ν3 = 55.5

R5 = 19.516

D5 = Variable

R6 = 8.548

D6 = 0.19

N4 = 1.882997

ν4 = 40.8

R7 = 1.552

D7 = 0.70

R8 = −3.274

D8 = 0.14

N5 = 1.834807

ν5 = 42.7

R9 = −29.337

D9 = 0.11

R10 = 2.610

D10 = 0.58

N6 = 1.846660

ν6 = 23.8

R11 = −5.401

D11 = 0.05

R12 = −3.527

D12 = 0.14

N7 = 1.772499

ν7 = 49.6

R13 = 3.752

D13 = Variable

R14 = Stop

D14 = 0.71

*R15 = −3.173

D15 = 0.28

N8 = 1.677900

ν8 = 55.3

R16 = −6.447

D16 = 0.44

R17 = 9.216

D17 = 0.16

N9 = 1.846659

ν9 = 23.8

R18 = 5.554

D18 = 0.64

N10 = 1.677900

ν10 = 55.3

*R19 = −7.524

D19 = 0.35

R20 = −61.514

D20 = 0.16

N11 = 1.603112

ν11 = 60.7

R21 = 3.578

D21 = 0.47

N12 = 1.603420

ν12 = 38.0

R22 = −329.776

D22 = Variable

*R23 = 4.655

D23 = 0.64

N13 = 1.583126

ν13 = 59.4

R24 = −12.477

D24 = 0.04

R25 = 5.495

D25 = 0.19

N14 = 1.846660

ν14 = 23.8

R26 = 2.569

D26 = 1.04

N15 = 1.487490

ν15 = 70.2

R27 = −7.822

D27 = 0.47

R28 = ∞

D28 = 0.33

N16 = 1.516330

ν16 = 64.2

R29 = ∞

D29 = 0.33

N17 = 1.552320

ν17 = 63.4

R30 = ∞

D30 = 0.18

N18 = 1.556710

ν18 = 58.6

R31 = ∞

D31 = 3.29

N19 = 1.589130

ν19 = 61.2

R32 = ∞

*Aspheric Surface

Variable

Focal Length

Separation

1.00

5.36

11.79

D 5

0.17

3.71

4.70

D13

4.88

1.35

0.35

D22

1.98

1.14

1.89

Aspheric Coefficients:

R15:

K = 4.96648e − 01

B = 5.80929e − 04

C = 6.64646e − 05

D = 0.00000e + 00

E = 0.00000e + 00

R19:

K = 1.40724e + 01

B = 5.49610e − 03

C = 3.08330e − 04

D = 3.36288e − 04

E = 0.00000e + 00

R23:

K = −4.76698e − 01

B = −2.61764e − 03

C = 1.32790e − 04

D = −4.95738e − 06

E = 0.00000e + 00

NUMERICAL EXAMPLE 9

f = 1˜11.79

Fno = 1.65˜2.85

2ω = 59.9°˜5.6°

R1 = 9.974

D1 = 0.33

N1 = 1.846660

ν1 = 23.8

R2 = 5.521

D2 = 1.32

N2 = 1.603112

ν2 = 60.6

R3 = −369.252

D3 = 0.04

R4 = 5.752

D4 = 0.78

N3 = 1.696797

ν3 = 55.5

R5 = 20.226

D5 = Variable

R6 = 8.400

D6 = 0.19

N4 = 1.882997

ν4 = 40.8

R7 = 1.587

D7 = 0.74

R8 = −3.274

D8 = 0.14

N5 = 1.834807

ν5 = 42.7

R9 = −37.214

D9 = 0.11

R10 = 2.691

D10 = 0.58

N6 = 1.846660

ν6 = 23.8

R11 = −5.145

D11 = 0.05

R12 = −3.416

D12 = 0.14

N7 = 1.772499

ν7 = 49.6

R13 = 3.822

D13 = Variable

R14 = Stop

D14 = 0.71

*R15 = −2.929

D15 = 0.19

N8 = 1.677900

ν8 = 55.3

R16 = 17.608

D16 = 0.49

N9 = 1.698947

ν9 = 30.1

R17 = −6.475

D17 = Variable

R18 = 9.699

D18 = 0.16

N10 = 1.846660

ν10 = 23.8

R19 = 6.493

D19 = 0.71

N11 = 1.589130

ν11 = 61.2

*R20 = −5.919

D20 = Variable

*R21 = 4.974

D21 = 0.64

N12 = 1.583126

ν12 = 59.4

R22 = −13.664

D22 = 0.04

R23 = 5.735

D23 = 0.19

N13 = 1.846660

ν13 = 23.8

R24 = 2.719

D24 = 1.04

N14 = 1.487490

ν14 = 70.2

R25 = −7.127

D25 = 0.47

R26 = ∞

D26 = 0.33

N15 = 1.516330

ν15 = 64.2

R27 = ∞

D27 = 0.33

N16 = 1.552320

ν16 = 63.4

R28 = ∞

D28 = 0.18

N17 = 1.556710

ν17 = 58.6

R29 = ∞

D29 = 3.29

N18 = 1.589130

ν18 = 61.2

R30 = ∞

*Aspheric Surface

Variable

Focal Length

Separation

1.00

5.31

11.79

D 5

0.17

3.63

4.60

D13

4.78

1.33

0.35

D17

0.24

0.24

0.24

D20

2.35

1.60

2.36

Aspheric Coefficients:

R15:

K = 3.31301e − 01

B = −5.15009e − 04

C = 9.55288e − 05

D = 0.00000e + 00

E = 0.00000e + 00

R20:

K = 5.35769e + 00

B = 4.25451e − 03

C = 3.96870e − 04

D = 1.19474e − 04

E = 0.00000e + 00

R21:

K = −5.05051e − 01

B = −2.57290e − 03

C = 1.42977e − 04

D = −7.66155e − 06

E = 0.00000e + 00

TABLE 3

Numerical Example

Condition

7

8

9

(8)

f3/fW

11.59

19.07

17.95

(9)

|f32/f3|

0.63

0.35

0.39

(10)

bfw/fW

4.04

4.12

4.13

(11)

|f2/{square root over (fW · fT)}|

0.42

0.41

0.41

It will be appreciated from the foregoing that, according to the present embodiment, the variable magnification optical system is provided with a lens sub-unit of relatively small size and light weight as arranged to move in a direction perpendicular to the optical axis to compensate for image shaking as the variable magnification optical system vibrates (or tilts from the line of sight). This produces advantages of improving the compact form of the entire optical system, simplifying the structure of the operating mechanism, and reducing the load on the driving means. Nonetheless, the produced amount of decentering aberrations by moving that lens sub-unit is suppressed to a minimum. It is, therefore, made possible to achieve a variable magnification optical system having the image stabilizing function that is not only corrected well for the decentering aberrations but also has its image stabilizing lens sub-unit made to have a higher sensitivity, thereby further improving the compact form of the entire optical system.

Number	Date	Country
9-084428	Mar 1997	JP
9-084429	Mar 1997	JP
10-054435	Feb 1998	JP

Number	Name	Date	Kind
4832471	Hamano	May 1989	A
4859042	Tanaka	Aug 1989	A
4934796	Sugiura et al.	Jun 1990	A
4988174	Horiuchi et al.	Jan 1991	A
4998809	Tsuji et al.	Mar 1991	A
5050972	Mukaiya et al.	Sep 1991	A
5134524	Hamano et al.	Jul 1992	A
5138492	Hamano et al.	Aug 1992	A
5249079	Umeda	Sep 1993	A
5299064	Hamano et al.	Mar 1994	A
5396367	Ono et al.	Mar 1995	A
5418646	Shibata et al.	May 1995	A
5430576	Hamano	Jul 1995	A
5521758	Hamano	May 1996	A
5543970	Hata et al.	Aug 1996	A
5546230	Sato et al.	Aug 1996	A
5579171	Suzuki et al.	Nov 1996	A
5583697	Mukaiya	Dec 1996	A
5585966	Suzuki	Dec 1996	A
5600490	Sugawara et al.	Feb 1997	A
5610766	Aoki et al.	Mar 1997	A
5638216	Horiuchi et al.	Jun 1997	A
5654826	Suzuki	Aug 1997	A
5677792	Hamano	Oct 1997	A
5751496	Hamano	May 1998	A
5771123	Hamano	Jun 1998	A
5933283	Hamano	Aug 1999	A
5963378	Tochigi et al.	Oct 1999	A

Number	Date	Country
56-21133	May 1981	JP
56-34847	Aug 1981	JP
57-7414	Feb 1982	JP
61-223819	Oct 1986	JP
1-116619	May 1989	JP
2-124521	May 1990	JP
5-60974	Mar 1993	JP
6-331891	Dec 1994	JP
7-128619	May 1995	JP
7-199124	Aug 1995	JP
8-278445	Oct 1996	JP

	Number	Date	Country
Parent	09/037856	Mar 1998	US
Child	09/251415		US

Variable magnification optical system having image stabilizing function

Information

Patent Number

Date Filed

Date Issued

Inventors

Original Assignees

Examiners

Agents

CPC

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US

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Abstract

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Priority Claims (3)

Parent Case Info

US Referenced Citations (28)

Foreign Referenced Citations (11)

Continuation in Parts (1)