JPH08101342A - Zoom optical system capable of selecting variable power area - Google Patents

Abstract

PURPOSE: To inexpensively provide a compact zoom optical system which is constituted so that respective aberration is excellently corrected and whose constitution is simple. CONSTITUTION: The zoom optical system constituted of three lens groups I-II moved at a zooming time is constituted of two parts of a common lens group part consisting of the intermediate lens group II and the rear lens group III and a dedicated lens group part consisting of the front lens group (one of I-I") designed corresponding to the common lens group part and coupled with the common lens group. By selecting the front lens group (one of I-I") according to a desired variable power area, the zoom optical system provided with the desired variable power area out of the plural variable power areas whose zoom ratio are different is selectively realized. In such a case, the number of lens groups included in the dedicated lens group part whose variable power area should be selected is set to the minimum. That means, the number of lens groups included in the common lens group part is set as large as possible. As the result, a developing term is shortened and a cost is reduced.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a zoom optical system suitable for being mounted on a lens shutter camera generally used as a compact camera, and more particularly, a variable magnification range capable of selectively setting a plurality of variable magnification ranges. The present invention relates to a zoom optical system.

[0002]

2. Description of the Related Art In recent years, there has been an increasing demand for improved performance of lens shutter cameras that are generally used as compact cameras, and as one of them, there has been a demand for a photographic lens mounted as a zoom lens. Therefore, it has become possible to provide a so-called two-group zoom optical system which can be mounted on a lens shutter camera and can be reduced in cost and has a relatively simple structure. However, with the demand for improved performance of the lens shutter camera, a wider zoom range (increased zoom ratio) is required.

In order to meet such a demand, a three-group zoom optical system has appeared in which a zoom ratio of 2.5 or more can be obtained while performing the necessary aberration correction and the configuration is relatively simple. Has come to do. For example, the high-power zoom lens disclosed in Japanese Patent Laid-Open No. 6-67093 is one example.

This high-power zoom lens, as shown in FIG. 92, has a first positive lens group G _r1 arranged in order from the object side.
By using a three-group zoom optical system composed of a second positive lens group G _r2 and a third negative lens group G _r3 and using aspherical surfaces for a plurality of optical surfaces, zooming at the embodiment level However, the three-group zoom optical system disclosed in Japanese Patent Laid-Open No. 6-67093 has only one fixed zooming range. Therefore, for example, there is a demand for a product with a relatively small zoom ratio that allows a zoom lens, a product with a slightly larger zoom ratio, and a product with a larger zoom ratio. In such a case, it is necessary to manufacture a 3-group zoom optical system of each level and mount it on the target camera.
There are disadvantages in manufacturing and supply (sales).

For example, the variable magnification range is 38 to 110 mm, 38 to 115 mm,
Three types of cameras, each equipped with a zoom optical system different from 38 to 120 mm, are currently on the market as a series, but in such a case, the zoom optical system mounted on each model is different. Since it has to be designed separately or based on a zoom optical system originally designed for high magnification, it becomes a cost disadvantage,
In addition, there is a big problem that it lacks compactness. Such manufacturing or supply disadvantages are directly
This problem is of great concern to manufacturers and retailers because it adversely affects manufacturing costs and product / inventory management. Therefore, the emergence of an effective solution to this problem is strongly desired.

[0006]

In the field of 8 mm cine interchangeable lenses and some interchangeable lenses for single-lens reflex cameras,
The focal length can be made variable by attaching and detaching an afocal zoom system to a master lens that originally has only a predetermined focal length (for example, a predetermined interchangeable lens), and several interchangeable types with different zoom ranges Prepare an afocal zoom system, and at the time of shooting, the user attaches these interchangeable afocal zoom systems to the master lens according to the purpose at that time and changes the zoom range to the desired range. The technology is conventionally known.

The inventors of the present invention have paid attention to whether the above disadvantages in manufacturing or supply can be solved if this idea can be applied to a normal zoom optical system. As a result of studying the possibility of selecting the variable magnification range based on such an eye, the following conclusions were obtained.

That is, in the conventional way of thinking that the afocal zoom system is exchangeably added to the master lens, the function of the "master lens + afocal zoom system" is decomposed into a variable power system and an imaging system, and this function is maintained. Since this was the selection or setting of the variable magnification range within the possible range, this idea is
If this is followed, for example, in the case of an optical system composed of 5 lens groups, 4 of the 5 lens groups will have to be changed, and It turns out that the lens groups used have few common parts.

In this case, for example, in the case of maintaining / expanding the camera price and sales by a method of serializing the camera or upgrading the basic camera such as Mark II, the manufacturing cost is also increased. -It will be a significant disadvantage in terms of product management.

Therefore, the present inventors have proposed a zoom optical system having a relatively simple lens structure having a plurality of zoom-time moving lens groups, for example, a three-group zoom optical system having three zoom-time lens groups. Based on the system, the lens group that constitutes this zoom optical system is divided into two parts: a common lens group part and a dedicated lens group part designed corresponding to the common lens group part and coupled with the common lens group part. Whether or not it is possible to realize a zoom optical system having one zooming area of a plurality of zooming areas having different zoom ratios by selecting the dedicated lens group portion according to the desired zooming area. I made an earnest research effort toward that proposition.

As a result, spherical aberration, astigmatism, distortion, coma, etc. are well corrected and have a high zoom ratio of about 2.7 to about 3.7. We succeeded in obtaining a selectable zoom optical system.
The zoom optical system capable of selecting the variable magnification range is not limited to the zoom optical system of the zoom lens for the lens shutter camera, but the zoom lens for the single-lens reflex camera, the zoom lens for the camcorder, the zoom lens for the SVC, etc. It can be widely used as a zoom optical system.

The present invention has been made in view of such circumstances, and a lens capable of realizing a desired zooming range, for example, of a minimum number of lens groups among a plurality of lens groups constituting a zoom optical system. Simply by selectively changing to a group, multiple types of zoom optical system can be configured as a compact zoom optical system in which spherical aberration, astigmatism, distortion, coma, etc. are well corrected. An object of the present invention is to provide a zoom optical system in which a variable magnification range can be obtained.

[0013]

In order to achieve the above object, the present invention provides a zoom optical system having a plurality of zoom-time moving lens groups, wherein the lens groups constituting the zoom optical system are provided with a common lens. It is composed of two parts, a group part and a dedicated lens group part designed corresponding to the common lens group part and coupled with the common lens group part, and the dedicated lens group part is selected according to a desired zoom range. By doing so, it is possible to configure a zoom optical system having one zooming area among a plurality of zooming areas having different zoom ratios.

According to a second aspect of the invention, in order from the object side, the first lens group having a positive focal length, the second lens group having a positive focal length, and the second lens group having a negative focal length. The zoom lens is composed of three lens groups, and at the time of zooming from the wide-angle end to the telephoto end, the moving speed of the second lens group from the image side to the object side, and the moving speed of the first lens group from the image side to the object side. And the moving speed of the third lens group from the image side to the object side, respectively.

According to a third aspect of the invention, the lens group located closest to the object side is set as the lens group of the dedicated lens group portion, and when the lens group located closest to the object side is selected, It is characterized in that the composite focal length of the entire system at the telephoto end can be selectively set without changing the composite focal length of the entire system at the wide-angle end.

According to a fourth aspect of the invention, in order from the object side, the first lens group having a positive focal length, the second lens group having a positive focal length, and the negative lens having a negative focal length. The zoom lens is composed of three lens groups, and at the time of zooming from the wide-angle end to the telephoto end, the moving speed of the second lens group from the image side to the object side, and the moving speed of the first lens group from the image side to the object side. And the moving speed of the third lens group from the image side to the object side, respectively.

According to a fifth aspect of the invention, there is provided the first aspect.
The lens group is composed of at least one positive unit lens and one negative unit lens, and 1.0 <f _{1 (i)} / f _{T (i)} <1.8, where f _{1 (i)} : variable magnification The focal length f _{T (i)} of the first lens group in the range i is the focal length at the telephoto end in the variable power range i.

According to a sixth aspect of the present invention, the second aspect
A lens group and the third lens group are both made up of a respective one positive of the unit lens and a negative unit lenses, _{and, 0.55 <f 2 / f W} <0.9 0.6 <| f 3 | / f _W <1.0 where f _{2 is} the focal length of the second lens group (common in each zoom range) f ₃ : is the focal length of the third lens group (common in each zoom range) f _W : Focal length at the wide-angle end ( It is characterized by satisfying the conditional expression (common to each variable range).

The invention according to claim 7 is the second invention.
It is characterized in that at least one optical surface of the lens group is formed by using an aspherical surface having a shape such that the positive refracting power becomes weaker with distance from the optical axis. The invention described in claim 8 is characterized in that an aspherical surface of a predetermined shape is used for at least one optical surface of the third lens group.

[0020]

In the zoom optical system configured as described above, the conventional concept of changing the focal length by adding the afocal zoom system to the master lens in a replaceable manner is complicated in function. By introducing this into an optical system, we have realized multiple types of zoom optical systems with different zoom ranges with a relatively simple structure.

Specifically, in a zoom optical system having a plurality of zoom lens groups for zooming, the lens groups constituting this zoom optical system are previously associated with a common lens group part and this common lens group part. It is composed of two parts, which are designed and a dedicated lens group part to be combined with a common lens group part, and by selecting the dedicated lens group part according to a desired zoom range, a plurality of zoom ranges with different zoom ratios can be obtained. Each of the zoom optical systems having one variable magnification range can be selectively configured.

In this case, in the preferred embodiment, when selecting the zooming range, the number of lens groups constituting the dedicated lens group portion is minimized, that is, the number of lens groups constituting the common lens group portion is increased. It is configured to do. With this configuration, at the embodiment level, a desired zoom range is provided within the zoom range of the zoom ratio of about 1.7 to 3.7, and spherical aberration, astigmatism, distortion, coma, etc. However, it is possible to obtain a zoom optical system which is well corrected and which has a relatively simple structure and which has a compact variable power range.

As a result, when the zoom optical system of the present invention is mounted on a lens shutter camera, the development period at the time of product development can be shortened when developing a series of cameras, suppressing the price and maintaining / expanding the sales system. At that time, the cost reduction and the cost related to manufacturing cost, inventory control, sales control, etc. are significantly reduced.

[0024]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The construction and operation of the zoom optical system according to the present invention capable of selecting a variable power region will be described below by taking the illustrated three-group zoom optical system as a typical example. The symbols used in the following description are: : Composite focal length of the entire system f _T : Focal length at telephoto end f _W : Focal length at wide angle end f ₁ : Focal length of front lens group f ₂ : Focal length of intermediate lens group f ₃ : Rear lens group Focal length Bf: Back focus of the entire system F _{NO .} : F number ω: Maximum half angle of view R _i : Radius of curvature of the i-th lens surface counted from the object side D _i : i-th surface counted from the object side Interval Nd _i : Refractive index of optical material of i-th lens counted from object side νd _i : Abbe number of optical material of i-th lens counted from object side

FIG. 1 is an optical system layout diagram showing an example of an optical system configuration relating to a zoom optical system capable of selecting a zooming range according to the present invention. The optical system layout when the first zooming range is realized. Is shown. This zoom optical system is the zoom optical systems ZO _{11 to} ZO ₁₃ and ZO _{21 to} ZO of the first and second embodiments.
₂₃ , the front lens group I having a positive refractive power, which is sequentially arranged on the optical axis O from the object side (left side in FIG. 1), and the rear lens group I that sandwiches the diaphragm S and is located behind the image (image). On the side), the variable axial distance D _{4 from the} front lens group I-stop S and the stop S
An intermediate group lens group II having a positive refractive power, which is located at a distance D ₅ from the intermediate group lens group II, and a II-III variable axial interval D ₉ at the rear of the intermediate group lens group II. And a rear lens group III having a negative refractive power.

In the zoom optical system of the present invention constructed as described above, the intermediate lens group II and the rear lens group III are described in the claims in both the first and second embodiments. And the front lens group I is set as the dedicated lens group part described in the claims.

That is, each of the intermediate lens group II and the rear lens group III is commonly used for the front lens group I regardless of which zoom range is selected, and The front lens group I is designed to correspond to the intermediate lens group II and the rear lens group III, respectively. Then, the front lens group I is selected according to a desired zoom range, and the selected front lens group I is selected.
Is coupled to the intermediate lens group II and the rear lens group III so as to form a zoom optical system having one zooming area among a plurality of zooming areas having different zoom ratios. There is.

That is, when there are three types of variable power regions to be selected, the front lens group I for realizing the first variable power region,
A desired zooming range is selected from the three front group lens groups I ′ for realizing the second zooming range and the front lens group I ″ for realizing the third zooming range. A front lens group capable of realizing the above, and the selected front lens group (one of I to I ″) is used as an intermediate lens group II and a rear lens group III which are commonly used. By selectively coupling, it is possible to realize a zoom optical system having a desired zoom range.

In this case, in each of the illustrated embodiments, for example, the positions of the lens groups I to III shown in FIG. 1 are regarded as the positions of the wide-angle end (short focal length end), and during zooming, the wide-angle end to the telephoto end are used. By moving toward the (long focal length end), the long focal length can be realized from the short focal length to the intermediate focal length. The symbol F in FIG. 1 indicates the image plane of the zoom optical system.

In a preferred embodiment, the moving speed of the intermediate lens group II from the image side to the object side is equal to the moving speed of the front lens group I from the image side to the object side and the rear lens group II.
To be slower than the moving speed of I from the image side to the object side, that is, the I-II variable axis interval (D ₄ +
It is configured to move from the wide-angle end to the telephoto end while widening D ₅ ) and narrowing the II-III variable axial distance D ₉ .

In the present invention, the front lens group I to I "
Focusing on the dominant effect on the imaging performance on the telephoto side, and actively using this, when any one of the front lens groups I to I ″ is selected, The basic idea is to selectively configure a zoom optical system having different zoom ranges by changing the focal length at the telephoto end while keeping the focal length at a predetermined value.

In order to obtain a compact and high-performance zoom optical system under such a premise, in the present invention, 1.0 <f _{1 (i)} / f _{T (i)} <1.8 ( 1) where f _{1 (i)} : front lens group I to I ″ in the variable power range i
Focal length f _{T (i)} : focal length at telephoto end in zoom range i is defined in relation to focal length f _T at telephoto end.

This conditional expression (1) is for maintaining the proper power of the front lens group I to I ″, which is the only lens that can be exchanged in each embodiment when selecting the zooming range. If the lower limit of conditional expression (1) is exceeded, the front lens group I to
The power of I ″ becomes too strong, and aberrations must be corrected on the telephoto side under an excessive tele ratio, and the number of lenses must be increased to achieve desired performance. Achieving low cost becomes difficult.

If the upper limit of conditional expression (1) is exceeded, the amount of movement during zooming will increase, and the accompanying fluctuations in field curvature and distortion will increase, and the total length of the optical system on the telephoto side will increase. It becomes big. In order to correct chromatic aberration and the like in the front lens groups I to I ″, it is preferable to use at least one positive lens and one negative lens in each lens group.

The following two conditional expressions (2) and (3)
Also, when selecting the "front lens group I to I" described above,
In order to configure the intermediate lens group II and the rear lens group III so that they can be commonly used for each of the front lens groups I to I ″ ", the relationship with the focal length f _W at the wide angle end is defined. It was done. 0.55 <f ₂ / f _W <0.9 (2) 0.6 <| f ₃ | / f _W <1.0 (3) where f _{2 is} the focal length of the intermediate lens group II (common for each zoom) f ₃ : Focal length of rear lens group III (common to each zoom range) f _W : Focal length of wide-angle end (common to each zoom range)

In this case, if f ₂ exceeds the lower limit of the conditional expression (2), it is advantageous in terms of downsizing, but spherical aberration at the wide angle end is insufficiently corrected, or this insufficient correction is dealt with. Therefore, problems such as an increase in the number of lenses occur. Further, when f ₂ exceeds the upper limit, the focusing power of the axial light becomes insufficient and the back focus Bf is increased, so that downsizing in the entire zoom range cannot be achieved.

On the other hand, when | f ₃ | is below the lower limit of the conditional expression (3), a pincushion type having large distortion at the wide-angle end is obtained.
Spherical aberration at the telephoto end becomes positive and high performance cannot be realized. Also, when | f ₃ | exceeds the upper limit, the negative refraction action becomes too weak, and in the optical system adopting the telephoto type, the effect of adopting the telephoto type power arrangement is reduced, and the total length of the optical system is reduced. The result is that it cannot be shortened.

By the way, in order to suppress various aberrations in the lens group in the intermediate lens group II, it is preferable that at least one positive lens and at least one negative lens are used. Both are configured that way. However, when configured in this way, a strong power is required for the positive lens, and in a positive lens using a spherical surface, there is a risk that spherical aberration that acts under the intermediate group lens group II will occur due to this strong positive refraction action. Come out.

This is an obstacle to miniaturization (thinness reduction) and high performance of this positive lens.
In the examples and the second example, the occurrence of the above-mentioned spherical aberration is reduced by using an aspherical surface having a shape in which the positive refracting power is weakened toward the lens periphery, and a desired value of optical performance is secured in the entire zoom range. I am trying to do it. It should be noted that the most image-side optical surface of the intermediate lens group II (R _{8 in} FIG. 1) has a large refraction angle of the peripheral light on the axis, and therefore it is particularly effective to use an aspherical surface for this surface. First embodiment and second
In the embodiment, an aspherical surface is used for this optical surface.

On the other hand, on the wide-angle side, since the off-axis light flux leaving the intermediate lens group II passes through the rear lens group III in a separated state, it is not possible to use an aspherical surface for the rear lens group III. Is very effective for. That is, when the aspherical surface is used, the curvature of field can be suppressed corresponding to each angle of view, and it is also very effective in correcting distortion which tends to become positive. Therefore, in the first and second examples, an aspherical surface is used also in the rear lens group III, but in this case, one of the optical surfaces of the rear lens group III is placed on the object side. Since the surface located in the vicinity (for example, R _{10 in} FIG. 1) has a small effective diameter, it is advantageous in cost to use an aspherical surface for this surface.

Specific configuration examples of the first and second embodiments will be described below. Each of the front lens groups I according to these examples includes, in order from the object side, a first unit lens 1 including a negative meniscus lens having a convex surface directed toward the object side, and an object side arranged behind the first unit lens 1. 2 with the second unit lens 2 consisting of a positive meniscus lens with its convex surface facing
It is configured as a lens group including one unit lens.

Each of the intermediate lens groups II includes a third unit lens 3 composed of a negative meniscus lens having a convex surface facing the image side, and a fourth unit lens 4 arranged behind the third unit lens 3. The lens unit is composed of two unit lenses. Furthermore, the rear lens group III is
Both are configured as a lens group including two unit lenses, a fifth unit lens 5 including a negative meniscus lens having a convex surface directed toward the image side and a sixth unit lens 6 disposed behind the fifth unit lens 5 including a biconcave lens. Has been done.

The diaphragm S is constructed so that it can be moved to a predetermined position within the I-II variable axis interval (D ₄ + D ₅ ), for example, simultaneously with the intermediate lens group II. Now,
In the first embodiment having such a detailed configuration, the zoom ratio
The first variable magnification range of 2.7 (f = 39.151 to 106.788mm), or
Second zoom range (f = 39.151 to 116.446m with a zoom ratio of about 3.0)
m) or the third zoom range (f = 39.151) with a zoom ratio of about 3.2
～125.981Mm) was selectively comprises a, it is possible to provide three types of zoom optical system ZO ₁₁ ~ZO _13.

In this case, the first variable range (f = 39.151 to 106.78)
The zoom optical system ZO ₁₁ having 8 mm) has detailed data (parameters) as shown in Table 1 below, which are combined with the commonly used intermediate lens group II and rear lens group III. As a result, it will be configured as a zoom optical system that can cover the focal length range from the wide-angle end (f = 39.151) to the intermediate focal length (f = 64.65mm) to the telephoto end (f = 106.788mm). . The brightness at each focal length is as bright as F _NO. 4.8, F _NO. 6.5, and F _NO. 8.8.

[0045]

[Table 1]

In this zoom optical system ZO ₁₁ , as shown in Table 1, four optical surfaces R ₃ , R ₅ , R ₈ and
An aspherical surface is used for each R _10, and the shape of each aspherical surface matches the optical axis O to take the y coordinate, and is orthogonal to the optical axis O to set the z coordinate. When the conic constants A4 to A10 are aspherical coefficients of 4th to 10th, respectively,

[0047]

[Equation 1] It is set as a shape that satisfies the aspherical expression of.

Next, the second variable range (f = 39.151 to 116.446m
m) is a zoom optical system ZO ₁₂ , which is a zoom optical system ZO ₁₂ having a first zoom range.
The front lens group I'of 11 is selectively used in place of the front lens group I of ₁₁ to selectively use a front lens group I'which realizes a second variable power range. Variable axis spacing (D ₄ +
D ₅ ) and the intermediate group lens group II and the rear group lens group III, which are commonly used, are coupled to each other.

In this case, detailed data of the front lens group I'for the second variable power range are as shown in Table 2 below.
Further, detailed data of the intermediate lens group II and the rear lens group III coupled to this are as shown in Table 1 above. Although it will be formed as a third optical surface R ₃ also aspheric the front lens group I ', the aspheric shape is configured to be determined based on the aforementioned equation (4) ing.

[0050]

[Table 2]

The zoom optical system ZO ₁₂ having the second variable power range constructed in this way passes from the wide-angle end (f = 39.151) to the intermediate focal length (f = 67.513 mm) to the telephoto end (f = 116.446). m
The zoom optical system can cover the focal length range up to m). The brightness at each focal length is as bright as F _NO. 4.8, F _NO. 6.8, and F _NO. 9.6.

Furthermore, the third variable power range (f = 39.151 to 125.981m
The zoom optical system ZO _{13 including} m) selectively uses a front lens group I ″ that realizes a third zoom range, instead of the front lens group I for the first zoom range. With a distance S ₄ between the front lens group I and the diaphragm S on the variable axis and a distance D ₅ between this diaphragm S and the intermediate lens group II (D ₄ + D ₅ ). , The common lens group II and the rear lens group III are connected to each other.

In this case, the detailed data of the front lens group I ″ which realizes the third variable power range is as shown in Table 3 below, and the intermediate group lens group for common use which is combined with the front lens group I ″ is shown in Table 3 below.
The detailed data of II and the rear lens group III are as shown in Table 1 above, as in the case of the zoom optical system ZO ₁₂ having the second variable power region. The third optical surface R ₃ of the front lens group I ″ is also formed as an aspherical surface, and its aspherical shape is determined based on the above-mentioned formula (4).

[0054]

[Table 3]

The zoom optical system ZO ₁₃ having the third variable power range configured as described above has a wide-angle end (f = 39.151), an intermediate focal length (f = 70.217 mm), and a telephoto end (f = 125.981). m
The zoom optical system can cover the focal length range up to m), and the brightness at each focal length is as bright as F _NO. 4.8, F _NO. 7.1, and F _NO. 10.4.

Incidentally, each zoom optical system Z of the first embodiment
In all of O _{11 to} ZO ₁₃ , the variable focal length range is set so that the combined focal length f _T of the entire system at the telephoto end can be selectively set without changing the combined focal length f _W of the entire system at the wide-angle end. At the ratio between the focal length f ₂ of the intermediate lens group II and the focal length f _W at the wide-angle end, and the rear lens group II
The ratio of the focal length f _{3 of} I to the focal length f _W at the wide-angle end is set to be f ₂ / f _W = 0.696 | f ₃ | / f _W = 0.837, respectively. This is common to each zoom range.

Each of the zoom optical systems ZO _{11 to} ZO ₁₃ of the first embodiment having the above-described structure is similar to the aberration diagrams of FIGS. 2 to 16 in the zoom optical system ZO ₁₁ having the first variable power range. As shown, wide-angle end (f = 39.151mm: F _NO. 4.8), intermediate focal length (f = 64.65 mm: F _NO. 6.5), telephoto end (f = 106.788)
mm: F _NO. 8.8), the zoom optical system is well corrected for spherical aberration, astigmatism, distortion, and coma. In the drawings, (W) is an aberration diagram at the wide-angle end, (M) is an intermediate focal length, and (T) is an aberration diagram at the telephoto end.

It can be said that this is more than enough to show the superiority of the basic construction of the first embodiment including the zoom optical system ZO ₁₁ . Further, in the zoom optical system ZO ₁₂ having the second variable power range, as shown in each aberration diagram of FIGS.
Wide-angle end (f = 39.151 mm: F _NO. 4.8), intermediate focal length (f = 70.217 mm: F _NO. 6.8), telephoto end (f = 125.981)
mm: F _NO. 9.6), spherical aberration, astigmatism, distortion, and coma are well corrected, and the front lens group I for the first zoom range is replaced. It is sufficiently demonstrated that the desired high performance is maintained even when the front lens group I'for the second variable power range is used.

Further, in the zoom optical system ZO ₁₃ having the third variable power range, as shown in the aberration diagrams of FIGS. 32 to 46,
Good spherical aberration, astigmatism, distortion, and coma over the wide-angle end (F _NO. 4.8), intermediate focal length (F _NO. 7.1), and telephoto end (F _NO. 10.4) _. It is sufficiently corrected to show that the desired high performance is maintained even when the front lens group I ″ for the third zoom range is used.

On the other hand, in the second embodiment of the present invention, the first zoom range (f = 39.143 to 106.698 mm) with a zoom ratio of about 2.7 or the second zoom range (f = 39.143 to about zoom ratio of 3.2). 126.103m
m) or the third zoom range (f = 39.143) with a zoom ratio of about 3.7
Zoom optical system ZO ₂₁ equipped with
~ ZO ₂₃ can be provided.

In this case, the zoom optical system ZO ₂₁ having the first variable power range has detailed data as shown in Table 4 below, and each of the zoom optical systems ZO _{11 to} ZO of the first embodiment described above.
Similar to the case of ₁₃ , by selectively coupling this to the intermediate lens group II and the rear lens group III, the intermediate focal length (f = 64.62mm) from the wide-angle end (f = 39.143) of the lens. It will be configured as a zoom optical system that can cover the focal length range up to the telephoto end (106.698 mm). In addition,
The brightness at each focal length is F _NO. 4.8,
The bright values are F _NO. 6.5 and F _NO. 9.0.

[0062]

[Table 4]

Also in this zoom optical system ZO ₂₁ , as in the case of each zoom optical system ZO ₁₁ having the first variable magnification range of the first embodiment, the four optical surfaces R ₃ , R ₅ , R ₈ and R _{10 are used.} Each uses an aspherical surface, and the aspherical shape is determined based on the above-mentioned equation (4).

Next, the second variable range (f = 39.143 to 126.103m
m) and the zoom optical system ZO ₂₂ of the second embodiment,
Regarding the zoom optical system ZO ₂₃ of the second embodiment having a variable power range (f = 39.143 to 145.516 mm), these zoom optical systems ZO ₂₂ and ZO ₂₃ are also the second variable power of the first embodiment. Zoom optical system ZO _{21 having} the first variable range (f = 39.143 to 106.698 mm) as in the zoom optical systems ZO ₁₂ and ZO ₁₃ having the second variable range and the third variable range. Front lens group I
Instead of, the front lens group I ′ that realizes the second variable power range or the front lens group I ″ that realizes the third variable power area is selectively used, and the intermediate lens group commonly used in the second embodiment is used. Lens group II
And the rear lens group III.

In this case, detailed data of the front lens group I'for the second variable power region in the second embodiment is shown in Table 5 below.
Further, detailed data of the front lens group I ″ for the third variable power region are as shown in Table 6 below. Incidentally, in the second variable power region of the second example. The third optical surface R ₃ of each of the front lens group I ′ for the third lens group and the front lens group I ″ for the third variable power region is also formed as an aspherical surface, and in this case also The shape will be determined based on the above-mentioned equation (4).

[0066]

[Table 5]

[0067]

[Table 6]

The zoom optical system ZO ₂₂ having the second variable power range in the second embodiment having the above-mentioned structure passes from the wide-angle end (f = 39.143 mm) to the intermediate focal length (f = 70.251 mm). The zoom optical system can cover the focal length range up to the telephoto end (f = 126.103mm), and the brightness at each focal length is as bright as F _NO. 4.8, F _NO. 7.1, F _NO. 10.4 _. become. In addition, the zoom optical system ZO ₂₃ equipped with the third zoom range has a focal length from the wide-angle end (f = 39.143 mm) to the intermediate focal length (f = 75.463 mm) to the telephoto end (f = 145.516 mm). It becomes a zoom optical system that can cover the range,
The brightness at each focal length is F
The bright values are _NO. 4.8, F _NO. 7.6 and F _NO. 12.0.

Each zoom optical system Z of the second embodiment is
In each of O _{21 to} ZO ₂₃ , the combined focal length f _T of the entire system at the telephoto end can be selectively set without changing the combined focal length f _W of the entire system at the wide-angle end, in each zoom range. , The focal length f ₂ of the intermediate lens group II and the focal length f _W at the wide-angle end, and the ratio of the focal length f ₃ of the rear lens group III and the focal length f _W at the wide-angle end to f _{2 / f W = 0.7 | f} 3 | is configured to set a / f _W = 0.817. This is common to each variable power range in the second embodiment.

Each of the zoom optical systems ZO _{21 to} ZO ₂₃ of the second embodiment constructed as described above has the aberration diagrams of FIGS. 47 to 61 in the zoom optical system ZO ₂₁ having the first variable power range. As shown, wide-angle end (f = 39.143mm: F _NO. 4.8), intermediate focal length (f = 64.62mm: F _NO. 6.5), telephoto end (f = 106.698mm: F)
_No. 9.0), spherical aberration, astigmatism, distortion, and coma are well corrected.

It can be said that this is enough to show the excellentness of the basic construction of the second embodiment including the zoom optical system ZO ₂₁ . Further, in the zoom optical system ZO ₂₂ having the second variable power range, as shown in each aberration diagram of FIGS. 62 to 76,
Wide-angle end (f = 39.143mm: F _NO. 4.8), intermediate focal length (f = 7
0.251mm: F _NO. 7.1, telephoto end (f = 126.103mm: F _NO. 1)
0.4), spherical aberration, astigmatism, distortion, and coma are well corrected.
It is sufficiently shown that the desired high performance is maintained even when the front lens group I'for the variable power range is used.

Further, in the zoom optical system ZO ₂₃ having the third variable power range, as shown in each aberration diagram of FIGS. 77 to 91,
Wide-angle end (f = 39.143mm: F _NO. 4.8), intermediate focal length (f =
75.463mm: F _NO. 7.6), telephoto end (f = 145.516mm: F _NO. 1)
2.0), spherical aberration, astigmatism, distortion, and coma are well corrected,
It is sufficiently shown that the desired high performance is maintained even when the front lens group I ″ for the variable power region is used.

The above description is based on the illustrated embodiment, but the present invention is not limited to this, and various modifications can be made without departing from the spirit of the invention. For example, in the first embodiment and the second embodiment, the zoom optical system having a configuration in which all the three groups are moving lens groups during zooming is used, but the number of all lens groups forming the zoom optical system and all lens groups are used. Any of the number of movable lens groups during zooming can be arbitrarily determined at the time of design.

Further, in the first and second embodiments,
Although the telephoto type of the positive lens group, the positive lens group, and the negative lens group is adopted, it is also possible to adopt a type other than the telephoto type. In the first and second examples, only the front lens group is selected, and three types of zoom optical systems are realized with the intermediate lens group and the rear lens group as a common part. It is also possible to use a method of selecting only the intermediate group lens group or only the rear group lens group, and the types of variable power regions to be realized or to be realized are not limited to three types. .

Further, in the first and second embodiments,
Although only one group is selected from the entire system, in the present invention, it is possible to set the number of lens groups to be selected to plural groups in order to change the zooming range. Also,
In the first and second examples, the number of unit lenses forming each lens group is two, but the number of unit lenses in each lens group can be arbitrarily determined at the design stage. . Further, although the aspherical surface is used, this is not limited to the usage of the first and second embodiments, and it can be used for any optical surface according to the aberration correction method. .

[0076]

As described above, according to the present invention, the function is complicatedly incorporated into the conventional idea that an afocal zoom system is exchangeably added to the master lens to change the focal length. When introducing it into the zoom optical system,
A lens unit constituting a zoom optical system is configured to include two parts, a common lens group part and a dedicated lens group part designed corresponding to the common lens group part and coupled with the common lens group part. By selecting the dedicated lens group portion according to the desired zoom range, it has become possible to construct a zoom optical system having one zoom range out of a plurality of zoom ranges with different zoom ratios. So the zoom ratio is about 1.7 ~
A zoom optical system that has a variable magnification range of 3.7 and is well corrected for spherical aberration, astigmatism, distortion, coma, etc. Can be provided.

In this case, in the preferred embodiment, when selecting the zooming range, the number of lens groups to be selected is minimized, that is, the common lens group portion is made as large as possible. In the case of the above configuration, it is possible to inexpensively provide a zoom optical system with a simpler configuration and a selectable zoom range. As a result, when the zoom optical system of the present invention is mounted on a lens shutter camera, shortening the development period at the time of product development when developing a series of cameras and maintaining / expanding the price and sales system by Mark II, In this case, it is possible to obtain a great effect that the cost can be reduced and the manufacturing cost, inventory management, sales management cost, and the like can be significantly reduced. Also, in the case of interchangeable lens cameras such as single-lens reflex cameras,
It is possible to expect the same great effect.

[Brief description of drawings]

FIG. 1 is an optical system layout diagram showing an example of an optical system configuration relating to a zoom optical system capable of selecting a variable power range according to the present invention, showing an optical system layout when a first variable power range is realized. Is.

FIG. 2 is a zoom optical system according to a first embodiment having a first variable power range.
Wide-angle end (f = 39.151mm: F _NO.4.8) Spherical yield
It is an aberration diagram showing a difference and a sine condition. In the figure
The solid line SA indicates the spherical aberration, and the broken line SC indicates the sine condition.
And "d" is the aberration for the d-line, and "g" is
Indicate aberrations with respect to the g-line. In each equivalent diagram below
The same is true.

FIG. 3 is an aberration diagram showing astigmatism at the wide-angle end according to the zoom optical system of the first example having the first variable power range. In addition, in the figure, the solid line DS represents the abrupt direction and the broken line DM represents the meridional direction, respectively, and similarly to the case of FIG.
“D” indicates aberration for the d-line, and “g” indicates aberration for the g-line. The same applies to the corresponding figures below.

FIG. 4 is an aberration diagram showing distortion aberration at the wide-angle end according to the zoom optical system of the first example including the first variable power region.

FIG. 5 is an aberration diagram showing coma aberration in the meridional direction at the wide-angle end according to the zoom optical system of the first example including the first variable power region.

FIG. 6 is an aberration diagram showing coma in the sagittal direction at the wide-angle end according to the zoom optical system of the first example including the first variable power region.

FIG. 7 is an aberration diagram showing a spherical aberration and a sine condition at an intermediate focal length (f = 64.65 mm: F _NO. 6.5) according to the zoom optical system of the first example having the first variable power range.

FIG. 8 is an aberration diagram showing astigmatism at an intermediate focal length in the zoom optical system of Example 1 having the first zoom range.

FIG. 9 is an aberration diagram showing distortion at the intermediate focal length in the zoom optical system of Example 1 having the first zoom range.

FIG. 10 is an aberration diagram showing coma in the meridional direction at an intermediate focal length in the zoom optical system of the first example including the first variable power range.

FIG. 11 is an aberration diagram showing coma aberration in the sagittal direction at the intermediate focal length in the zoom optical system of the first example having the first zoom range.

FIG. 12 is an aberration diagram showing spherical aberration and sine conditions at the telephoto end (f = 106.788 mm: F _NO. 8.8) according to the zoom optical system of the first example including the first variable power region.

FIG. 13 is an aberration diagram showing astigmatism at the telephoto end according to the zoom optical system of the first example including the first variable power region.

FIG. 14 is an aberration diagram showing distortion aberration at the telephoto end according to the zoom optical system of the first example having the first variable power region.

FIG. 15 is an aberration diagram showing coma aberration in the meridional direction at the telephoto end according to the zoom optical system of the first example having the first variable power region.

FIG. 16 is an aberration diagram showing coma aberration in the sagittal direction at the telephoto end according to the zoom optical system of the first example having the first variable power region.

FIG. 17 is an aberration diagram showing spherical aberration and sine conditions at the wide-angle end (f = 39.151 mm: F _NO. 4.8) according to the zoom optical system of the first example having the second variable power range.

FIG. 18 is an aberration diagram showing astigmatism at the wide-angle end according to the zoom optical system of the first example having the second variable power region.

FIG. 19 is an aberration diagram showing distortion at the wide-angle end according to the zoom optical system of the first example including the second variable magnification region.

FIG. 20 is an aberration diagram showing coma in the meridional direction at the wide-angle end according to the zoom optical system of the first example including the second variable power region.

FIG. 21 is an aberration diagram showing coma aberration in the sagittal direction at the wide-angle end according to the zoom optical system of the first example having the second variable power region.

FIG. 22 is an aberration diagram showing a spherical aberration and a sine condition at an intermediate focal length (f = 67.513 mm: F _NO. 6.8) according to the zoom optical system of the first example having the second variable power range.

FIG. 23 is an aberration diagram showing astigmatism at an intermediate focal length in the zoom optical system according to Example 1 having the second zoom region.

FIG. 24 is an aberration diagram showing distortion at the intermediate focal length in the zoom optical system of Example 1 having the second zoom region.

FIG. 25 is an aberration diagram showing coma in the meridional direction at the intermediate focal length in the zoom optical system of the first example equipped with the second zoom region.

FIG. 26 is an aberration diagram showing coma aberration in the sagittal direction at the intermediate focal length in the zoom optical system of Example 1 having the second zoom region.

FIG. 27 is an aberration diagram showing a spherical aberration and a sine condition at the telephoto end (f = 116.446 mm: F _NO. 9.6) according to the zoom optical system of the first example having the second zoom region.

FIG. 28 is an aberration diagram showing astigmatism at the telephoto end according to the zoom optical system of the first example having the second zoom region.

FIG. 29 is an aberration diagram showing distortion aberration at the telephoto end according to the zoom optical system of the first example having the second zoom region.

FIG. 30 is an aberration diagram showing coma aberration in the meridional direction at the telephoto end according to the zoom optical system of the first example having the second zoom region.

FIG. 31 is an aberration diagram showing coma aberration in the sagittal direction at the telephoto end according to the zoom optical system of the first example having the second zoom region.

FIG. 32 is an aberration diagram showing spherical aberration and a sine condition at the wide-angle end (f = 39.151 mm: F _NO. 4.8) according to the zoom optical system of the first example having the third zoom region.

FIG. 33 is an aberration diagram showing astigmatism at the wide-angle end according to the zoom optical system of the first example having the third zoom region.

FIG. 34 is an aberration diagram showing distortion at the wide-angle end according to the zoom optical system of the first example having the third zoom region.

FIG. 35 is an aberration diagram showing coma in the meridional direction at the wide-angle end according to the zoom optical system of the first example including the third zoom region.

FIG. 36 is an aberration diagram showing coma in the sagittal direction at the wide-angle end according to the zoom optical system of the first example having the third zoom region.

FIG. 37 is an aberration diagram showing a spherical aberration and a sine condition at an intermediate focal length (f = 70.217 mm: F _NO. 7.1) according to the zoom optical system of the first example including the third zoom region.

FIG. 38 is an aberration diagram showing astigmatism at an intermediate focal length in the zoom optical system of Example 1 having the third zoom range.

FIG. 39 is an aberration diagram showing distortion at the intermediate focal length in the zoom optical system of Example 1 having the third zoom region.

FIG. 40 is an aberration diagram showing coma in the meridional direction at the intermediate focal length in the zoom optical system of the first example equipped with the third zoom region.

FIG. 41 is an aberration diagram showing coma aberration in the sagittal direction at the intermediate focal length in the zoom optical system of Example 1 having the third zoom region.

FIG. 42 is an aberration diagram showing spherical aberration and sine condition at the telephoto end (f = 125.981 mm: F _NO. 10.4) according to the zoom optical system of the first example including the third variable power region.

FIG. 43 is an aberration diagram showing astigmatism at the telephoto end according to the zoom optical system of the first example having the third zoom region.

FIG. 44 is an aberration diagram showing distortion at the telephoto end according to the zoom optical system of the first example having the third zoom region.

FIG. 45 is an aberration diagram showing coma aberration in the meridional direction at the telephoto end according to the zoom optical system of the first example having the third zoom region.

FIG. 46 is an aberration diagram showing coma aberration in the sagittal direction at the telephoto end according to the zoom optical system of the first example having the third zoom region.

FIG. 47 is an aberration diagram showing a spherical aberration and a sine condition at the wide-angle end (f = 39.143 mm: F _NO. 4.8) according to the zoom optical system of the second example including the first variable power region.

FIG. 48 is an aberration diagram showing astigmatism at the wide-angle end according to the zoom optical system of the second example including the first variable power region.

FIG. 49 is an aberration diagram showing distortion aberration at the wide-angle end in the zoom optical system of the second example which includes the first zoom region.

50 is an aberration diagram showing coma in the meridional direction at the wide-angle end according to the zoom optical system of the second example including the first variable magnification range. FIG.

FIG. 51 is an aberration diagram showing coma aberration in the sagittal direction at the wide-angle end according to the zoom optical system of the second example including the first variable magnification region.

52 is an aberration diagram showing spherical aberration and a sine condition at an intermediate focal length (f = 64.62 mm: F _NO. 6.5) according to the zoom optical system of the second example including the first variable power range. FIG.

FIG. 53 is an aberration diagram showing astigmatism at an intermediate focal length in the zoom optical system of the second example including the first variable power range.

FIG. 54 is an aberration diagram showing distortion aberration at an intermediate focal length in the zoom optical system of the second example having the first variable magnification range.

FIG. 55 is an aberration diagram showing coma in the meridional direction at the intermediate focal length in the zoom optical system according to the second example including the first variable magnification region.

FIG. 56 is an aberration diagram showing coma aberration in the sagittal direction at the intermediate focal length according to the zoom optical system of the second example including the first variable magnification region.

FIG. 57 is an aberration diagram showing spherical aberration and sine conditions at the telephoto end (f = 106.698 mm: F _NO. 9.0) according to the zoom optical system of the second example including the first variable power region.

FIG. 58 is an aberration diagram showing astigmatism at the telephoto end according to the zoom optical system of the second example including the first variable magnification region.

FIG. 59 is an aberration diagram showing distortion aberration at the telephoto end according to the zoom optical system of the second example including the first variable magnification region.

FIG. 60 is an aberration diagram showing coma aberration in the meridional direction at the telephoto end according to the zoom optical system of the second example including the first variable magnification region.

FIG. 61 is an aberration diagram showing coma aberration in the sagittal direction at the telephoto end according to the zoom optical system of the second example including the first variable magnification region.

FIG. 62 is an aberration diagram showing spherical aberration and a sine condition at the wide-angle end (f = 39.143 mm: F _NO. 4.8) according to the zoom optical system of the second example including the second zoom region.

FIG. 63 is an aberration diagram showing astigmatism at the wide-angle end according to the zoom optical system of the second example including the second zoom region.

FIG. 64 is an aberration diagram showing distortion at the wide-angle end in the zoom optical system of the second example including the second zoom region.

FIG. 65 is an aberration diagram showing coma in the meridional direction at the wide-angle end according to the zoom optical system of the second example including the second zoom region.

FIG. 66 is an aberration diagram showing coma aberration in the sagittal direction at the wide-angle end according to the zoom optical system of the second example including the second zoom region.

FIG. 67 is an aberration diagram showing spherical aberration and a sine condition at an intermediate focal length (f = 70.251 mm: F _NO. 7.1) according to the zoom optical system of the second example including the second zoom region.

FIG. 68 is an aberration diagram showing astigmatism at an intermediate focal length in the zoom optical system of the second example including the second zoom region.

FIG. 69 is an aberration diagram showing distortion in the intermediate focal length in the zoom optical system of the second example including the second zoom region.

FIG. 70 is an aberration diagram showing coma in the meridional direction at the intermediate focal length in the zoom optical system of the second example including the second zoom region.

FIG. 71 is an aberration diagram showing coma in the sagittal direction at the intermediate focal length in the zoom optical system of the second example including the second zoom region.

FIG. 72 is an aberration diagram showing spherical aberration and sine conditions at the telephoto end (f = 126.103 mm: F _NO. 10.4) according to the zoom optical system of the second example including the second zoom region.

FIG. 73 is an aberration diagram showing astigmatism at the telephoto end according to the zoom optical system of the second example including the second zoom region.

FIG. 74 is an aberration diagram showing distortion at the telephoto end according to the zoom optical system of the second example including the second zoom region.

FIG. 75 is an aberration diagram showing coma in the meridional direction at the telephoto end according to the zoom optical system of the second example including the second zoom region.

FIG. 76 is an aberration diagram showing coma in the sagittal direction at the telephoto end according to the zoom optical system of the second example including the second zoom region.

FIG. 77 is an aberration diagram showing spherical aberration and sine conditions at the wide-angle end (f = 39.143 mm: F _NO. 4.8) according to the zoom optical system of the second example including the third variable power region.

FIG. 78 is an aberration diagram showing astigmatism at the wide-angle end according to the zoom optical system of the second example including the third zoom region.

FIG. 79 is an aberration diagram showing distortion at the wide-angle end according to the zoom optical system of the second example including the third zoom region.

FIG. 80 is an aberration diagram showing coma in the meridional direction at the wide-angle end according to the zoom optical system of the second example including the third zoom region.

FIG. 81 is an aberration diagram showing coma aberration in the sagittal direction at the wide-angle end according to the zoom optical system of the second example including the third zoom region.

82 is an aberration diagram showing a spherical aberration and a sine condition at an intermediate focal length (f = 75.463 mm: F _NO. 7.6) according to the zoom optical system of the second example including the third zoom region. FIG.

FIG. 83 is an aberration diagram showing astigmatism at an intermediate focal length in the zoom optical system of the second example including the third zoom region.

FIG. 84 is an aberration diagram showing distortion at the intermediate focal length in the zoom optical system of the second example including the third zoom region.

FIG. 85 is an aberration diagram showing coma in the meridional direction at the intermediate focal length in the zoom optical system of the second example including the third zoom region.

FIG. 86 is an aberration diagram showing coma aberration in the sagittal direction at the intermediate focal length in the zoom optical system of the second example including the third zoom region.

87 is an aberration diagram showing spherical aberration and sine condition at the telephoto end (f = 145.516 mm: F _NO. 12.0) according to the zoom optical system of the second example including the third zoom region. FIG.

FIG. 88 is an aberration diagram showing astigmatism at the telephoto end according to the zoom optical system of the second example including the third zoom region.

FIG. 89 is an aberration diagram showing distortion at the telephoto end according to the zoom optical system of the second example including the third zoom region.

FIG. 90 is an aberration diagram showing coma in the meridional direction at the telephoto end according to the zoom optical system of the second example including the third zoom region.

FIG. 91 is an aberration diagram showing coma aberration in the sagittal direction at the telephoto end according to the zoom optical system of the second example having the third zoom region.

FIG. 92 is an optical system layout diagram showing an optical system configuration of a conventional zoom optical system having a three-group configuration.

[Explanation of symbols]

I, I ′, I ″ Front lens group II Intermediate lens group III Rear lens group 1 First unit lens 2 Second unit lens S Aperture 3 Third unit lens 4 4th unit lens 5 5th unit lens 6th 6 unit lens O optical axis F image plane D ₄ I-II variable axis interval D ₉ II-III variable axis interval R _{1 to} R ₁₂ 1st optical surface to 12th optical surface D _{1 to} D ₁₁ axial interval

[Procedure amendment]

[Submission date] October 26, 1994

[Procedure Amendment 1]

[Document name to be amended] Statement

[Correction target item name] 0062

[Correction method] Change

[Correction content]

[0062]

[Table 4]

Claims (8)

[Claims] 1. In a zoom optical system having a plurality of zooming movement lens groups, a lens group constituting this zoom optical system is designed to correspond to a common lens group portion and the common lens group portion, and the common lens group portion is designed. It is composed of two parts, a lens group part and a dedicated lens group part to be combined, and by selecting the dedicated lens group part according to a desired zoom range,
A zoom optical system capable of selecting a zooming range, wherein a zoom optical system having one zooming range among a plurality of zooming ranges having different zoom ratios can be configured. 2. A wide-angle lens comprising, in order from the object side, a first lens group having a positive focal length, a second lens group having a positive focal length, and a third lens group having a negative focal length. When zooming from the end to the telephoto end, the moving speed of the second lens unit from the image side to the object side is set to the first
The moving speed of the lens unit from the image side to the object side and the third speed
The zoom optical system according to claim 1, wherein the zoom optical system is configured to be slower than the moving speed of the lens unit from the image side to the object side. 3. The composite focal length of the entire system at the wide-angle end when the lens group located closest to the object side is set as the lens group of the dedicated lens group portion and the lens group located closest to the object side is selected. The zoom optical system with selectable zooming range according to claim 1, wherein the combined focal length of the entire system at the telephoto end can be selected and set without changing. 4. A wide-angle lens comprising, in order from the object side, a first lens group having a positive focal length, a second lens group having a positive focal length, and a third lens group having a negative focal length. When zooming from the end to the telephoto end, the moving speed of the second lens unit from the image side to the object side is set to the first
The moving speed of the lens unit from the image side to the object side and the third speed
The zoom optical system according to claim 3, wherein the zoom optical system is configured to be slower than the moving speed of the lens unit from the image side to the object side. 5. The first lens group comprises at least one positive unit lens and one negative unit lens, and 1.0 <f _{1 (i)} / f _{T (i)} <1.8, The f _{1 (i)} : focal length of the first lens unit in the variable power range i f _{T (i)} : focal length at the telephoto end in the variable power range i Zoom optical system with selectable zoom range. And wherein said second lens group and the third lens group are both made up of a respective one positive of the unit lens and a negative unit lenses, _{and, 0.55 <f 2 / f W} <0.9 0.6 <| f ₃ | / f _W <1.0 where f _{2 is} the focal length of the second lens group (common in each zoom range) f ₃ : is the focal length of the third lens group (common in each zoom range) f _W : The focal length at the wide-angle end (common to each zoom range), which satisfies the conditional expression: The zoom optical system with selectable zoom range according to claim 4 or 5. 7. The at least one optical surface of the second lens group is an aspherical surface having a shape such that its positive refracting power becomes weaker with distance from the optical axis.
7. A zoom optical system having a variable power range described in any one of 1 to 6 above. 8. The variable magnification range according to claim 4, wherein an aspherical surface of a predetermined shape is used for at least one optical surface of the third lens group. Zoom optics.