JP2005300858A - Zoom lens - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a zoom lens which is used for a small-sized digital camera or a camera incorporated in a mobile telephone, the lens being small in number of components, short in overall length length, and superior in performance. <P>SOLUTION: A zoom lens which has two lens groups, i.e. a 1st lens group with a negative refractive index and a 2nd lens group with a positive refractive index in order from an object side or has the 1st lens group with the negative refractive index, the 2nd lens group with the positive refractive index, and a 3rd lens group with a positive refractive index in order from the object side and varies the power by moving the 2nd lens group and 3rd lens group, or a zoom lens which varies the power by moving the 1st lens group and 2nd lens group is made to meet proper conditions of the Petzval sum. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a zoom lens, and more particularly to an ultra-small zoom lens used in a digital camera, a camera built in a mobile phone, and the like.

Conventionally, as a configuration of a zoom lens for a still camera of about 2 to 3 times that covers an angle of view of about 60 ° at a wide angle end, an uneven 2 group type zoom lens or an uneven 2 group type zoom lens is used. Are known. There are two groups of zoom lenses that have a small number of lenses, but this is a zoom lens for lens shutter cameras of silver halide cameras and is built into digital cameras and mobile phones. In the case where the CCD is an imaging plane as in a camera, a configuration in which the exit pupil of the optical system is far and close to telecentric is required in order to avoid the occurrence of color unevenness.
In this case, a concave / convex two-group type zoom lens having two lens groups each composed of a first lens group having a negative refractive index as a whole and a second lens group having a positive refractive index as a whole. However, this is advantageous as a wide angle lens. Therefore, the two-group type of concave / convex has been developed, and a three-group type in which a convex group is added later to distant the exit pupil has appeared and has been developed as a standard zoom lens type of a digital camera.

For example, Japanese Patent Laid-Open No. 2001-4920 discloses a zoom lens including two lens groups having negative and positive refractive indexes in order from the object side.
On the other hand, Japanese Patent Application Laid-Open No. 9-21950, Japanese Patent Application Laid-Open No. 11-52246, and Japanese Patent Application Laid-Open No. 2001-296475 are composed of three lens groups having negative, positive, and positive refractive indexes in order from the object side. A zoom lens is disclosed.

Japanese Patent Laid-Open No. 9-21950 JP 11-52246 A JP 2001-4920 A JP 2001-296475 A

However, all of the zoom lenses disclosed in Patent Documents 1 to 4 described above have a large number of lenses, and even if an aspherical lens is used, at least six lenses are required. In order to further improve the performance, a larger number of lenses are required, and there is a problem that the total length of the lens becomes longer.
In addition, since the zoom lens disclosed in Japanese Patent Laid-Open No. 2001-296475 moves all three groups, there is a problem that the control of the angular lens group is troublesome. On the other hand, in JP-A-11-52246 and JP-A-9-21950, the first lens group and the second lens group are moved and the third lens group is fixed, but the total number of lenses used is 8. There are many with 9 to 9 sheets.

Therefore, the present invention solves such a conventional problem, and is a compact and compact imaging system, and is used for a small digital camera whose imaging surface is a CCD and an ultra-small camera built in a mobile phone. An object of the present invention is to provide a zoom lens having an excellent performance with a pupil close to telecentric, a small number of lenses, and a short overall lens length.
Further, the present invention has a zoom ratio of about 2 to 3 times, an angle of view of 60 ° to 97 ° at the wide angle end, and can realize excellent image performance even when the number of pixels of the CCD increases. An object is to provide a zoom lens.
It is another object of the present invention to provide a zoom lens that can be easily controlled during zooming.

なる条件を満足することを特徴とするズームレンズを提供する。 In order to solve the above-mentioned problems, the invention according to claim 1 is, in order from the object side, two groups of lenses, a first lens group having a negative refractive index and a second lens group having a positive refractive index. A zoom lens that changes magnification by moving the first lens group and the second lens group, or a first lens group that has a negative refractive index in order from the object side, and a positive refractive index A zoom lens that includes a second lens group and a third lens group having a positive refractive index and performs zooming by moving the second lens group and the third lens group, or negative in order from the object side A first lens group having a refractive index of 2, a second lens group having a positive refractive index, and a third lens group having a positive refractive index, and moving the first lens group and the second lens group Zoom lens that performs zooming by When the focal length of the lens unit and fi (i is 1 to 3),

A zoom lens characterized by satisfying the following conditions is provided.

  The present invention makes it possible to secure performance while reducing the number of lenses by reducing the number of lenses in the two-group type, and further simplifying the structure by fixing the first group during zooming in the three-group type. In order to make the zoom ratio efficient by reducing the number of lenses as much as possible, it is necessary to limit the Petzval sum by the power arrangement, and to make the exit pupil far away, it is also necessary to determine the aperture position. is there. Considering the conditions with a small number of lenses by fully capturing the power arrangement, it is necessary to satisfy such conditions.

  In order to solve the above-mentioned problems, a second aspect of the present invention is the zoom lens having the two lens groups according to the first aspect, wherein the first lens group is formed with two concave and convex lenses. In addition, when zooming from the wide-angle end to the telephoto end, it moves with a convex U-turn toward the image side, and the second lens group is composed of two convex / concave lenses or convex / concave And a monotonic movement toward the object side when zooming from the wide-angle end to the telephoto end.

となり、第１レンズ群は凹、凸の２枚構成、第２レンズ群は凸、凹の２枚構成又は凸、凹、凸の３枚構成となる。 If the focal length of the first lens unit of the concave / convex two-group type is f1, the focal length of the second lens unit is f2, the zoom ratio is Z, and the telephoto side focal length is ft.

Thus, the first lens group has a concave and convex two-lens configuration, and the second lens group has a convex and concave two-lens configuration or a convex, concave and convex three-lens configuration.

  In order to solve the above-mentioned problems, a third aspect of the present invention is a zoom lens including the three lens groups according to the first aspect, and is changed by moving the first lens group and the second lens group. In a zoom lens that performs magnification, the first lens group is formed with two concave and convex lenses, and moves with a convex U-turn toward the image side when zooming from the wide-angle end to the telephoto end. The second lens group is formed with two convex and concave lenses, and is moved monotonically to the object side when zooming from the wide-angle end to the telephoto end, and The third lens group is formed with a single convex lens and is fixed.

  If the zoom unit of the second group type in claim 2 is proportionally enlarged and reduced to three groups, the total length becomes slightly longer.

  In order to solve the above-mentioned problems, a fourth aspect of the invention is a zoom lens including the three lens groups according to the first aspect, and is changed by moving the second lens group and the third lens group. In a zoom lens that performs magnification, the first lens group is formed with two concave and convex lenses and is fixed, and the second lens group is formed with two convex and concave lenses. When zooming from the wide-angle end to the telephoto end, the zoom lens is moved monotonically toward the object side, and the third lens group is formed with a single convex lens, and from the wide-angle end. When zooming to the telephoto end, it moves monotonically to the object side.

となり、１群は凹、凸レンズの２枚構成、２群は凸、凹レンズの２枚構成、３群は凸レンズの１枚構成となり、１群はズーミングで移動しない構成となる。 The first lens group is composed of a concave (negative lens system), the second lens group is composed of a convex (positive lens system), the third lens group is composed of a convex (positive lens system), and the focal length of the first lens group is f1. If the focal length of the second lens group is f2, the focal length of the third lens group is f3, the zoom ratio is Z, and the focal length on the telephoto side is ft.

Thus, the first group has a two-lens configuration of concave and convex lenses, the second group has a two-lens configuration of convex and concave lenses, and the third group has a single-lens configuration of convex lenses, and the first group does not move by zooming.

  In order to solve the above problem, the invention according to claim 5 is the zoom lens according to any one of claims 2, 3, and 4, of the two concave and convex lenses constituting the first lens group, At least one surface of the concave lens is an aspherical surface.

  Considering the use of aspheric surfaces, selection of glass materials, and plastic materials based on the power arrangement described above. According to the fifth aspect of the invention, in order to reduce distortion on the wide side (wide angle end side), at least the radius of curvature of the R2 surface of the concave lens of the first group needs to be reduced. Is required. Of course, it is also effective to make the R1 surface aspherical.

In order to solve the above-mentioned problems, the invention according to claim 6 is the zoom lens according to claim 2, wherein the second lens group includes two convex and concave lenses. The two concave and convex lenses constituting the two lens group are formed of a cemented lens, and at least one surface of the convex lens and the concave lens is an aspherical surface.
By making at least one surface of the convex lens and the concave lens an aspherical surface, it is possible to provide a lens with good performance even in a lens group with a small number of components, and it is easy to improve the eccentricity accuracy by bonding. .

  In order to solve the above-mentioned problem, according to a seventh aspect of the present invention, in the zoom lens according to the third or fourth aspect, at least one surface of the convex lens among the two convex and concave lenses constituting the second lens group is an aspherical surface. It is characterized by being.

  In order to solve the above-mentioned problem, the invention according to claim 8 is the zoom lens according to claim 2, wherein the second lens group includes three convex and concave lenses. Of the three convex and concave lenses constituting the second lens group, at least one surface of the convex lens is an aspherical surface.

  Conventionally, the number of lenses of the second lens group is increased to four or more to satisfy the aberration correction with respect to the brightness. However, in claims 6, 7, and 8, at least one surface of the convex lens constituting the second lens group is satisfied. Is made aspherical, making it possible to reduce the number of lenses compared to the prior art. Of course, the aspherical effect is effective not only on the R1 surface of the convex lens but also on the R2 surface and both surfaces of the next concave lens convex lens.

In order to solve the above-mentioned problems, the invention according to claim 9 is the zoom lens according to claim 3 or 4, wherein at least one surface of the convex lens constituting the third lens group is an aspherical surface.
The aberration correction as a whole is performed by setting at least one surface of one convex lens constituting the third group as an aspherical surface.

  In order to solve the above-mentioned problem, the invention according to claim 10 is the zoom lens according to any one of claims 2, 3, and 4, wherein the refractive index of the concave component of the first lens group and the Abbe number are set. Assuming that ndn1 and νdn1, respectively, the following conditions are satisfied: 1.50 <ndn1 <1.81, 40.0 <νdn1 <75.0.

  In order to solve the above-described problem, the invention described in claim 11 is the zoom lens described in any one of claims 2, 3, and 4, wherein the refractive index of the convex component of the first lens group and the Abbe number are set. Assuming that ndp1 and νdp1 respectively, the following conditions are satisfied: 1.55 <ndp1 <1.81, 25.4 <νdp1 <45.0.

In claims 10 and 11, since the first lens group has a negative refractive index, the achromatic condition is νdp <νdn.
Further, in order to achieve compactness, it is necessary to shorten the focal length and increase the radius of curvature, so that it is desired to select a material having a high refractive index ndn, ndp. In particular, the focal length of the first lens group is a negative value whose absolute value is smaller than the focal length of the second lens group. Therefore, in order to reduce the Petzval sum for reducing the curvature of field, the refraction of the concave lens is required. The rate needs to be larger. However, it is necessary to satisfy at least these conditions because of restrictions on the characteristics of the optical glass and plastic material forming the lens.

  In order to solve the above problem, the invention according to claim 12 is the zoom lens according to any one of claims 2, 3, and 4, wherein the refractive index of the convex component of the second lens group and the Abbe number are set. Assuming that ndp2 and νdp2 respectively, the conditions of ndp2 <1.74 and 48.0 <νdp2 are satisfied.

  In order to solve the above-mentioned problem, the invention described in claim 13 is the zoom lens according to any one of claims 2, 3, and 4, wherein the refractive index of the concave component of the second lens group and the Abbe number are set. Assuming that ndn2 and νdn2 respectively, the condition of 1.58 <ndn2 and νdn2 <30.0 is satisfied.

  In the twelfth and thirteenth aspects, since the second lens group is a positive lens group, the total Petzval sum considering the achromatic condition and the first lens group and the third lens group of the zoom lens optical system are taken into consideration. It is necessary to satisfy the conditions.

  In order to solve the above-described problem, the invention described in claim 14 is the zoom lens according to claim 3 or 4, wherein the refractive index of the convex component of the third lens group and the Abbe number are ndp3 and νdp3, respectively. The condition of 1.44 <ndp3 <1.65, 55.0 <νdp3 is satisfied.

  According to the fourteenth aspect, since the third lens group is a single convex lens, the larger the νd, the better the achromatic effect, and since it is a single lens, the higher the refractive index, the better the aberration balance. is good. However, by using an aspherical surface, the total number of sheets can be reduced and the Petzval sum can be reduced, so that even a material having a low refractive index can be used.

の
−０．０６５＜ｐ＜０．０６５を満足する材料を選択することになる。 Since the glass plastic material is selected under the conditions of claims 10 to 14, and the total Petzval sum is a four or five lens system,

The material satisfying −0.065 <p <0.065 is selected.

According to the zoom lens of the present invention, there is an effect that it is possible to provide a zoom lens having a small number of lenses and an excellent performance with a short total lens length.
That is, the zoom lens according to the present invention has a high angle of view up to an angle of view 2ω = 96 to 50 ° and an aperture ratio of about F3.5 to 5.1, and is approximately twice as large. There is an effect that it is possible to provide an ultra-compact high-performance zoom lens having four lenses having a zoom ratio of 4.
In addition, the number of lenses having an angle of view 2ω = 71.2 to 26.2 °, an F-number of about 2.8 to 4.8, and a zoom ratio of about 3 times is five. It is possible to provide an ultra-compact high-performance zoom lens.
Further, when the F number is 3.5 to 6.1, there is an effect that it is possible to design a 3 × zoom lens having four lenses with an angle of view 2ω = 80 ° to 30 °.

  In addition, according to the zoom lens according to the present invention, since the two lens groups are configured to be movable during zooming, there is an effect that control related to zooming can be easily performed.

  Hereinafter, the zoom lens according to the present invention will be described in more detail based on the illustrated preferred embodiment. FIG. 1 is a diagram showing the configuration and movement trajectory of the lens of Example 1, and FIG. 2 is an aberration diagram from the wide-angle end (a) to the telephoto end (c) at the infinity shooting distance of Example 1.

  The zoom lens 1 according to the first exemplary embodiment includes, in order from the object side, two lens groups including a first lens unit L1 having a negative refractive index and a second lens unit L2 having a positive refractive index. ing. The first lens group is formed with two lenses, a concave lens L11 and a convex lens L12, and moves with a convex U-turn toward the image side. The R1 and R2 surfaces of the concave lens L11 and the R3 surface of the convex lens L12 are aspherical surfaces. Here, “moving with a convex U-turn toward the image side” means that the moving lens group moves on the optical axis in order to make the position of the image at the time of zooming constant when zooming from the wide-angle end to the telephoto end. After moving to the image side, the movement direction is changed to the object side.

On the other hand, the second lens group is formed with two lenses, a convex lens L21 and a concave lens L22, and moves monotonously to the object side. The convex lens L21 and the concave lens L22 are bonded together, and the R6 surface of the convex lens L21 and the R8 surface of the concave lens L22 are aspherical surfaces. A stop S is disposed in the vicinity of the front surface of the convex lens L21 of the second lens unit L2. Here, “moving monotonously to the object side” means that the moving lens group simply moves linearly on the optical axis when moving from the wide-angle end to the telephoto end.
The zoom lens 1 shown in the figure is zoomed by moving the first lens group and the second lens group. G is a cover glass.

ペツバル和：ｐ＝0.003、後ろの２面はカバー硝子、D10はバックフォーカスの値、光学全長は焦点距離変化のレンズの最先端から像面までの距離。
R(I) D(I) Nd Vd
[1] 30.3606 0.97 1.73310 48.9
[2] 3.0864 1.55
[3] 6.1092 1.55 1.80518 25.4
[4] 7.3379 D4
[5] （絞り） 0.2647
[6] 2.9712 2.18 1.73310 48.9
[7] -4.6382 0.76 1.80518 25.4
[8] 17.6619 D8
[9] ∞ 0.3 1.51633 64.1
[10] ∞ D10
(非球面データ)
第１面e=1 第２面e=1 第３面e=1
C2 = 0.00000000D+00 C2 = 0.00000000D+00 C2 = 0.00000000D+00
C4 = 0.16081517D-01 C4 = 0.28363051D-01 C4= 0.50457893D-02
C6 =-0.15732674D-02 C6 = 0.35250975D-02 C6 = 0.88177722D-03
C8 = 0.72176126D-04 C8 =-0.26907433D-03 C8 =-0.19960150D-03
C10=-0.15013811D-05 C10=-0.48535912D-04 C10= 0.17890932D-04

第６面e=1 第８面e=1
C2 = 0.00000000D+00 C2 = 0.00000000D+00
C4 = 0.36195121D-03 C4 = 0.14185147D-01
C6 = 0.88328818D-03 C6 = 0.30227866D-02
C8 =-0.45798301D-03 C8 =-0.54010182D-03
C10= 0.77935024D-04 C10= 0.32797065D-03
焦点距離 ３．６４ ５．３８ ７．９５
可変間隔D4 4.818 2.5115 0.9562
D8 3.3289 4.8685 7.138
バックフォーカスD10 2.5 2.5 2.5
光学全長 １８．２３〜 １７．４６〜 １８．１８ｍｍ The zoom lens 1 is a zoom lens that is made of all four glass balls, has a wide angle of view of 80.8 °, an F number of 3.5, an image circle of 6 mmφ on the CCD, and a zoom ratio of about twice. Various data and conditions of the zoom lens of Example 1 are shown below.
Example 1
2 groups type: Zoom ratio of about 2
Focal length: 3.64 to 7.95 mm, F number = 3.5 to 5.3, exit pupil position: −5.3 to −9.11 (from image plane)
Since the focal length of the first group; f1 = −5.4134, the focal length of the second group; f2 = 4.7804,

Petzval sum: p = 0.003, the back two surfaces are the cover glass, D10 is the back focus value, and the total optical length is the distance from the forefront of the lens with focal length change to the image plane.
R (I) D (I) Nd Vd
[1] 30.3606 0.97 1.73310 48.9
[2] 3.0864 1.55
[3] 6.1092 1.55 1.80518 25.4
[4] 7.3379 D4
[5] (Aperture) 0.2647
[6] 2.9712 2.18 1.73310 48.9
[7] -4.6382 0.76 1.80518 25.4
[8] 17.6619 D8
[9] ∞ 0.3 1.51633 64.1
[10] ∞ D10
(Aspherical data)
First surface e = 1 Second surface e = 1 Third surface e = 1
C2 = 0.00000000D + 00 C2 = 0.00000000D + 00 C2 = 0.00000000D + 00
C4 = 0.16081517D-01 C4 = 0.28363051D-01 C4 = 0.50457893D-02
C6 = -0.15732674D-02 C6 = 0.35250975D-02 C6 = 0.88177722D-03
C8 = 0.72176126D-04 C8 = -0.26907433D-03 C8 = -0.19960150D-03
C10 = -0.15013811D-05 C10 = -0.48535912D-04 C10 = 0.17890932D-04

6th surface e = 1 8th surface e = 1
C2 = 0.00000000D + 00 C2 = 0.00000000D + 00
C4 = 0.36195121D-03 C4 = 0.14185147D-01
C6 = 0.88328818D-03 C6 = 0.30227866D-02
C8 = -0.45798301D-03 C8 = -0.54010182D-03
C10 = 0.77935024D-04 C10 = 0.32797065D-03
Focal length 3.64 5.38 7.95
Variable spacing D4 4.818 2.5115 0.9562
D8 3.3289 4.8685 7.138
Back focus D10 2.5 2.5 2.5
Optical total length 18.23 ~ 17.46 ~ 18.18mm

となる。 Here, how to represent the aspheric expression of the present invention will be described. Since the aspherical surface is a rotationally symmetric aspherical surface, if the rotation axis is x and the sag amount is expressed as a function of the height y from the optical axis,

It becomes.

  Next, Example 2 will be described. FIG. 3 is a diagram showing the configuration and movement trajectory of the lens of Example 2, and FIG. 4 is an aberration diagram from the wide-angle end (a) to the telephoto end (c) at the infinity shooting distance in Example 2.

  Similarly to the zoom lens 1 of the first embodiment, the zoom lens 2 of the second embodiment includes, in order from the object side, a first lens group L1 having a negative refractive index and a second lens group L2 having a positive refractive index. These two lens groups are provided. The first lens group is formed with two lenses, a concave lens L11 and a convex lens L12, and moves with a convex U-turn toward the image side. The R1 and R2 surfaces of the concave lens L11 and the R3 surface of the convex lens L12 are aspherical surfaces.

On the other hand, the second lens group is formed with two lenses, a convex lens L21 and a concave lens L22, and moves monotonously to the object side. The convex lens L21 and the concave lens L22 are bonded together, and the R6 surface of the convex lens L21 and the R8 surface of the concave lens L22 are aspherical surfaces. A stop S is disposed in the vicinity of the front surface of the convex lens L21 of the second lens unit L2.
The illustrated zoom lens 2 is zoomed by moving the first lens group and the second lens group. G is a cover glass.

ペツバル和：ｐ＝0.068、後ろの２面はカバー硝子、D10はバックフォーカスの値。
R(I) D(I) Nd Vd
[1] -34.1146 1.52 1.73310 48.9
[2] 2.017 0.73
[3] 2.1659 1.0 1.75520 27.5
[4] 3.0477 D4
[5] 絞り 0.2
[6] 1.8995 1.7 1.5247 56.2
[7] -1.6341 0.6 1.58349 29.9
[8] -10.5606 D8
[9] ∞ 0.3 1.51633 64.1
[10] ∞ D10
非球面データ
第１面e=1 第２面e=1 第３面e=1
C2 = 0.00000000D+00 C2 = 0.00000000D+00 C2 = 0.00000000D+00
C4 = 0.11768966D-01 C4 = 0.73182447D-02 C4 =-0.94285429D-02
C6 =-0.79615204D-03 C6 = 0.17146321D-01 C6 = 0.67476666D-02
C8 = 0.22926000D-04 C8 =-0.22742958D-02 C8 =-0.22159615D-02
C10=-0.19065732D-06 C10=-0.32678334D-03 C10= 0.14866271D-03

第６面e=1 第８面e=1
C2 = 0.00000000D+00 C2 = 0.00000000D+00
C4 =-0.59085205D-02 C4 = 0.29443076D-01
C6 = 0.10913823D-01 C6 = 0.16060468D-01
C8 =-0.12372022D-01 C8 =-0.73321231D-02
C10= 0.42907597D-02 C10= 0.47361672D-02
焦点距離 ２．６８ ３．９６ ５．８９
可変間隔D4 3.3443 1.6472 0.4880
D8 2.4769 3.6096 5.3119
バックフォーカス 1.787 1.787 1.787
光学全長 １３．６６ １３．０９ １３．６４ The zoom lens 2 is a four-lens lens made of two glass and two plastic lenses, with a wide angle of view of 96.6 °, F number of 3.5, an image circle on the CCD of 6mmφ, and a zoom ratio of about 2x. It is a lens. Various data and conditions of the zoom lens of Example 2 are shown below.
Example 2
2 groups type: Zoom ratio of about 2
Focal length: 2.68 to 5.89 mm, F-number = 3.5 to 5.1, exit pupil position: −4.48 to −7.32 (from image plane)
Since the focal length of the first group; f1 = −3.99832, the focal length of the second group; f2 = 3.5174,

Petzval sum: p = 0.068, the back two are cover glass, and D10 is the back focus value.
R (I) D (I) Nd Vd
[1] -34.1146 1.52 1.73310 48.9
[2] 2.017 0.73
[3] 2.1659 1.0 1.75520 27.5
[4] 3.0477 D4
[5] Aperture 0.2
[6] 1.8995 1.7 1.5247 56.2
[7] -1.6341 0.6 1.58349 29.9
[8] -10.5606 D8
[9] ∞ 0.3 1.51633 64.1
[10] ∞ D10
Aspheric data 1st surface e = 1 2nd surface e = 1 3rd surface e = 1
C2 = 0.00000000D + 00 C2 = 0.00000000D + 00 C2 = 0.00000000D + 00
C4 = 0.11768966D-01 C4 = 0.73182447D-02 C4 = -0.94285429D-02
C6 = -0.79615204D-03 C6 = 0.17146321D-01 C6 = 0.67476666D-02
C8 = 0.22926000D-04 C8 = -0.22742958D-02 C8 = -0.22159615D-02
C10 = -0.19065732D-06 C10 = -0.32678334D-03 C10 = 0.14866271D-03

6th surface e = 1 8th surface e = 1
C2 = 0.00000000D + 00 C2 = 0.00000000D + 00
C4 = -0.59085205D-02 C4 = 0.29443076D-01
C6 = 0.10913823D-01 C6 = 0.16060468D-01
C8 = -0.12372022D-01 C8 = -0.73321231D-02
C10 = 0.42907597D-02 C10 = 0.47361672D-02
Focal length 2.68 3.96 5.89
Variable spacing D4 3.3443 1.6472 0.4880
D8 2.4769 3.6096 5.3119
Back focus 1.787 1.787 1.787
Optical total length 13.66 13.09 13.64

  Next, Example 3 will be described. FIG. 5 is a diagram showing the configuration and movement trajectory of the lens of Example 3, and FIG. 6 is an aberration diagram from the wide-angle end (a) to the telephoto end (c) at the infinity shooting distance of Example 3.

  Similarly to the zoom lens 2 of the second embodiment, the zoom lens 3 of the third embodiment includes, in order from the object side, a first lens group L1 having a negative refractive index and a second lens group L2 having a positive refractive index. These two lens groups are provided. The first lens group is formed with two lenses, a concave lens L11 and a convex lens L12, and moves with a convex U-turn toward the image side. The R1 and R2 surfaces of the concave lens L11 and the R3 surface of the convex lens L12 are aspherical surfaces.

On the other hand, the second lens group is formed with two lenses, a convex lens L21 and a concave lens L22, and moves monotonously to the object side. The convex lens L21 and the concave lens L22 are bonded together, and the R6 surface of the convex lens L21 and the R8 surface of the concave lens L22 are aspherical surfaces. A stop S is disposed in the vicinity of the front surface of the convex lens L21 of the second lens unit L2.
The illustrated zoom lens 3 is zoomed by moving the first lens group and the second lens group. G is a cover glass.

ペツバル和：ｐ＝0.06、後ろの２面はカバー硝子、D10はバックフォーカス。
R(I) D(I) Nd Vd
[1] 348.5221 1.65 1.6935 53.2
[2] 2.6246 1.16
[3] 2.9459 1.0 1.58349 29.9
[4] 4.2095 D4
[5] 絞り 0.25
[6] 2.4518 2.2 1.5247 56.2
[7] -2.3326 0.75 1.58349 29.9
[8] -27.6927 D8
[9] ∞ 0.3 1.51633 64.1
[10] ∞ D10
(非球面データ)
第１面 e=1 第２面e=1 第３面e=1
C2 = 0.00000000D+00 C2 = 0.00000000D+00 C2 = 0.00000000D+00
C4 = 0.63036969D-02 C4 = 0.97730151D-02 C4 =-0.42092606D-03
C6 =-0.43316288D-03 C6 = 0.29381514D-02 C6 = 0.12828585D-02
C8 = 0.16239308D-04 C8 =-0.49812111D-03 C8 =-0.29169547D-03
C10=-0.25124673D-06 C10= 0.16772304D-04 C10= 0.15615633D-04

第６面 e=1 第８面 e=1
C2 = 0.00000000D+00 C2 = 0.00000000D+00
C4 =-0.84015076D-03 C4 = 0.17374798D-01
C6 = 0.26897610D-03 C6 = 0.50206859D-03
C8 =-0.70987843D-04 C8 = 0.20238579D-02
C10=-0.70216948D-04 C10=-0.33160654D-03
焦点距離 ３．６４ ５．３８ ８．００
可変間隔 D4 4.5699 2.2634 0.6879
D8 3.3725 4.9120 7.2255
バックフォーカスD10 2.4997 2.4997 2.4997
光学全長 17.7495 16.9826 17.7206 The zoom lens 3 is a four-lens lens made of glass and plastic, with a wide angle of view of 80.8 °, an F number of 3.5, an image circle of 6mmφ on the CCD, and a zoom ratio of about 2x. It is a lens. Various data and conditions of the zoom lens of Example 3 are shown below.
Example 3
2 groups type: Zoom ratio of about 2
Focal length: 3.64 to 8.00 mm, F number = 3.6 to 5.2, exit pupil position: −5.78 to −9.63 (from image plane)
Since the focal length of the first group; f1 = −5.4134, the focal length of the second group; f2 = 4.7804,

Petzval sum: p = 0.06, the back two are cover glass, D10 is back focus.
R (I) D (I) Nd Vd
[1] 348.5221 1.65 1.6935 53.2
[2] 2.6246 1.16
[3] 2.9459 1.0 1.58349 29.9
[4] 4.2095 D4
[5] Aperture 0.25
[6] 2.4518 2.2 1.5247 56.2
[7] -2.3326 0.75 1.58349 29.9
[8] -27.6927 D8
[9] ∞ 0.3 1.51633 64.1
[10] ∞ D10
(Aspherical data)
First surface e = 1 Second surface e = 1 Third surface e = 1
C2 = 0.00000000D + 00 C2 = 0.00000000D + 00 C2 = 0.00000000D + 00
C4 = 0.63036969D-02 C4 = 0.97730151D-02 C4 = -0.42092606D-03
C6 = -0.43316288D-03 C6 = 0.29381514D-02 C6 = 0.12828585D-02
C8 = 0.16239308D-04 C8 = -0.49812111D-03 C8 = -0.29169547D-03
C10 = -0.25124673D-06 C10 = 0.16772304D-04 C10 = 0.15615633D-04

6th surface e = 1 8th surface e = 1
C2 = 0.00000000D + 00 C2 = 0.00000000D + 00
C4 = -0.84015076D-03 C4 = 0.17374798D-01
C6 = 0.26897610D-03 C6 = 0.50206859D-03
C8 = -0.70987843D-04 C8 = 0.20238579D-02
C10 = -0.70216948D-04 C10 = -0.33160654D-03
Focal length 3.64 5.38 8.00
Variable spacing D4 4.5699 2.2634 0.6879
D8 3.3725 4.9120 7.2255
Back focus D10 2.4997 2.4997 2.4997
Optical total length 17.7495 16.9826 17.7206

  Next, Example 4 will be described. FIG. 7 is a diagram showing the configuration and movement trajectory of the lens of Example 4, and FIG. 8 is an aberration diagram from the wide-angle end (a) to the telephoto end (c) at the infinity shooting distance in Example 4.

  Similarly to the zoom lens 2 of Example 2 and the zoom lens 3 of Example 3, the zoom lens 4 of Example 4 includes, in order from the object side, a first lens unit L1 having a negative refractive index, and a positive refractive index. And a second lens unit L2 having two lens units. The first lens group is formed with two lenses, a concave lens L11 and a convex lens L12, and moves with a convex U-turn toward the image side. The R1 and R2 surfaces of the concave lens L11 and the R3 surface of the convex lens L12 are aspherical surfaces.

On the other hand, the second lens group is formed with two lenses, a convex lens L21 and a concave lens L22, and moves monotonously to the object side. The convex lens L21 and the concave lens L22 are bonded together, and the R6 surface of the convex lens L21 and the R8 surface of the concave lens L22 are aspherical surfaces. A stop S is disposed in the vicinity of the front surface of the convex lens L21 of the second lens unit L2.
The illustrated zoom lens 4 is zoomed by moving the first lens group and the second lens group. G is a cover glass.

ペツバル和：ｐ＝0.0541、後の２面はカバー硝子、D10はバックフォーカス。
R(I) D(I) Nd Vd
[1] 63.6993 1.46 1.80610 40.4
[2] 2.7330 1.15
[3] 3.0153 1.0 1.80627 25.4
[4] 4.0039 D4
[5] 絞り 0.0
[6] 2.5673 2.87 1.5247 56.2
[7] -1.9638 0.58 1.58349 29.9
[8] -13.7321 D8
[9] ∞ 0.3 1.51633 64.1
[10] ∞ D10
(非球面データ)
第１面e=1 第２面 e=1 第３面 e=1
C2 = 0.00000000D+00 C2 = 0.00000000D+00 C2 = 0.00000000D+00
C4 = 0.50687863D-02 C4 = 0.56277523D-02 C4 =-0.13943220D-02
C6 =-0.25534791D-03 C6 = 0.85603896D-03 C6 =-0.24664062D-03
C8 = 0.63854090D-05 C8 = 0.11805695D-04 C8 = 0.98480493D-04
C10=-0.45149534D-07 C10=-0.15514489D-04 C10=-0.12946006D-04

第６面 e=1 第８面 e=1
C2 = 0.00000000D+00 C2 = 0.00000000D+00
C4 =-0.47229475D-02 C4 = 0.38116475D-02
C6 = 0.43721339D-02 C6 = 0.40495949D-02
C8 =-0.31319070D-02 C8 =-0.50031984D-03
C10= 0.75948476D-03 C10= 0.88330612D-04
焦点距離 ３．４０ ５．３８ １０．００
可変間隔 D4 5.3141 2.5134 0.2907
D8 2.9166 4.6646 8.7448
バックフォーカスD10 2.5 2.5 2.5
光学全長 １８．１ １７．０５ １８．９１ The zoom lens 4 is composed of two glass balls, two glass balls, a wide angle of view of 84.0 °, an F number of 3.5, an image circle on the CCD of 6 mmφ, and a zoom ratio of about 3 times. It is a lens. Various data and conditions of the zoom lens of Example 4 are shown below.
Example 4
2 group type: Zoom ratio approx. 3
Focal length: 3.40 to 10.00 mm, F number = 3.5 to 6.1, exit pupil position: −5.48 to −11.31 (from image plane)
Since the focal length of the first group; f1 = −5.4134, the focal length of the second group; f2 = 4.7804,

Petzval sum: p = 0.0541, the last two surfaces are cover glass, and D10 is back focus.
R (I) D (I) Nd Vd
[1] 63.6993 1.46 1.80610 40.4
[2] 2.7330 1.15
[3] 3.0153 1.0 1.80627 25.4
[4] 4.0039 D4
[5] Aperture 0.0
[6] 2.5673 2.87 1.5247 56.2
[7] -1.9638 0.58 1.58349 29.9
[8] -13.7321 D8
[9] ∞ 0.3 1.51633 64.1
[10] ∞ D10
(Aspherical data)
First surface e = 1 Second surface e = 1 Third surface e = 1
C2 = 0.00000000D + 00 C2 = 0.00000000D + 00 C2 = 0.00000000D + 00
C4 = 0.50687863D-02 C4 = 0.56277523D-02 C4 = -0.13943220D-02
C6 = -0.25534791D-03 C6 = 0.85603896D-03 C6 = -0.24664062D-03
C8 = 0.63854090D-05 C8 = 0.11805695D-04 C8 = 0.98480493D-04
C10 = -0.45149534D-07 C10 = -0.15514489D-04 C10 = -0.12946006D-04

6th surface e = 1 8th surface e = 1
C2 = 0.00000000D + 00 C2 = 0.00000000D + 00
C4 = -0.47229475D-02 C4 = 0.38116475D-02
C6 = 0.43721339D-02 C6 = 0.40495949D-02
C8 = -0.31319070D-02 C8 = -0.50031984D-03
C10 = 0.75948476D-03 C10 = 0.88330612D-04
Focal length 3.40 5.38 10.00
Variable interval D4 5.3 141 2.5 134 0.2907
D8 2.9166 4.6646 8.7448
Back focus D10 2.5 2.5 2.5
Optical total length 18.1 17.05 18.91

  Next, Example 5 will be described. FIG. 9 is a diagram showing the configuration and movement trajectory of the lens of Example 5, and FIG. 10 is an aberration diagram from the wide-angle end (a) to the telephoto end (c) at the infinity shooting distance in Example 5.

  The zoom lens 5 according to the fifth exemplary embodiment includes, in order from the object side, two lens groups including a first lens unit L1 having a negative refractive index and a second lens unit L2 having a positive refractive index. ing. The first lens group is formed with two lenses, a concave lens L11 and a convex lens L12, and moves with a convex U-turn toward the image side. Further, the R1 surface and the R2 surface of the concave lens L11 are each aspherical.

On the other hand, the second lens group is formed by including three lenses of a convex lens L21, a concave lens L22, and a convex lens L23, and is moved monotonously to the object side. The R6 surface of the convex lens L21 and the R10 surface of the convex lens L23 are aspherical surfaces. A stop S is disposed in the vicinity of the front surface of the convex lens L21 of the second lens unit L2.
The illustrated zoom lens 5 is zoomed by moving the first lens group and the second lens group. G is a cover glass.

ペツバル和：ｐ=-0.063、後の２面はカバー硝子、D13はバックフォーカスの値。
R(I) D(I) Nd Vd
[1] -23.1272 0.5 1.69350 53.2
[2] 1.2599 0.8
[3] 2.4433 0.8 1.62588 35.7
[4] 6.4203 D4
[5] 絞り 0.3
[6] 1.5834 1.2 1.52470 56.2
[7] -3.9678 0.2
[8] 10.4329 0.4 1.80518 25.4
[9] 1.4697 0.2
[10] 1.4120 0.8 1.49194 56.0
[11] 3.4587 D11
[12] ∞ 0.3 1.51633 64.1
[13] ∞ D13=1.04
（非球面データ）
第１面 e=1 第２面 e=1
C2 = 0.0000000D+00 C2 = 0.00000000D+00
C4 = 0.35378769D-01 C4 =-0.79050657D-02
C6 =-0.91840761D-02 C6 = 0.17375669D-01
C8 =-0.81747594D-03 C8 =-0.41826037D-01
C10= 0.55453255D-03 C10=-0.23142887D-02

第6面 e=1 第10面 e=1
C2 = 0.0000000D+00 C2 = 0.00000000D+00
C4 =-0.22193067D-01 C4 =-0.74291596D-01
C6 =-0.12698702D-01 C6 =-0.10355944D-01
C8 = 0.16557039D-02 C8 =-0.42710754D-01
C10=-0.20940086D-02 C10= 0.25321829D-01
焦点距離 １．６０ ２．７７ ４．８０
可変間隔 D4 4.7911 2.4486 1.0961
D11 1.6326 2.9850 5.3276
光学全長 12.96〜 11.97〜 12.96mm The zoom lens 5 is made of five glass balls made of two pieces of glass, plastic, wide angle of view 72.2 °, F number 2.8, image circle 2.25mmφ on CCD, and zoom ratio is about 3 times. This is a zoom lens. Various data and conditions of the zoom lens of Example 5 are shown below.
Example 5
2 groups type: Zoom ratio 3
Focal length: 1.60 to 4.80 mm, F number = 2.8 to 5.1, exit pupil position; -4.67 to -8.37 (from image plane)
Since the focal length of the first group is f1 = −2.7713 and the focal length of the second group is f2 = 3.2,

Petzval sum: p = -0.063, the last two surfaces are cover glass, and D13 is the back focus value.
R (I) D (I) Nd Vd
[1] -23.1272 0.5 1.69350 53.2
[2] 1.2599 0.8
[3] 2.4433 0.8 1.62588 35.7
[4] 6.4203 D4
[5] Aperture 0.3
[6] 1.5834 1.2 1.52470 56.2
[7] -3.9678 0.2
[8] 10.4329 0.4 1.80518 25.4
[9] 1.4697 0.2
[10] 1.4120 0.8 1.49194 56.0
[11] 3.4587 D11
[12] ∞ 0.3 1.51633 64.1
[13] ∞ D13 = 1.04
(Aspheric data)
First side e = 1 Second side e = 1
C2 = 0.0000000D + 00 C2 = 0.00000000D + 00
C4 = 0.35378769D-01 C4 = -0.79050657D-02
C6 = -0.91840761D-02 C6 = 0.17375669D-01
C8 = -0.81747594D-03 C8 = -0.41826037D-01
C10 = 0.55453255D-03 C10 = -0.23142887D-02

6th surface e = 1 10th surface e = 1
C2 = 0.0000000D + 00 C2 = 0.00000000D + 00
C4 = -0.22193067D-01 C4 = -0.74291596D-01
C6 = -0.12698702D-01 C6 = -0.10355944D-01
C8 = 0.16557039D-02 C8 = -0.42710754D-01
C10 = -0.20940086D-02 C10 = 0.25321829D-01
Focal length 1.60 2.77 4.80
Variable spacing D4 4.7911 2.4486 1.0961
D11 1.6326 2.9850 5.3276
Optical total length 12.96〜 11.97〜 12.96mm

  Next, Example 6 will be described. FIG. 11 is a diagram showing the configuration and movement locus of the lens of Example 6, and FIG. 12 is an aberration diagram from the wide-angle end (a) to the telephoto end (c) at the infinity shooting distance in Example 6.

  The zoom lens 6 of Example 6 includes, in order from the object side, a first lens unit L1 having a negative refractive index, a second lens unit L2 having a positive refractive index, and a third lens having a positive refractive index. The lens unit L3 includes three lens units. The first lens group is formed with two lenses, a concave lens L11 and a convex lens L12, and moves with a convex U-turn toward the image side. Further, the R1 surface and the R2 surface of the concave lens L11 are each aspherical.

On the other hand, the second lens group is formed with two lenses, a convex lens L21 and a concave lens L22, and moves monotonously to the object side. The R6 surface of the convex lens L21 is an aspherical surface. A stop S is disposed in the vicinity of the front surface of the convex lens L21 of the second lens unit L2.
Furthermore, the third lens unit L3 includes a convex lens L31, and its R10 surface is an aspherical surface.
The illustrated zoom lens 6 is zoomed by moving the first lens unit L1 and the second lens unit L2. G is a cover glass.

ペツバル和：p=0.0088、最後の２面はカバー硝子、D13はバックフォーカスの値。
R(I) D(I) Nd Vd
[1] -9.2532 0.4 1.6935 53.2
[2] 1.8436 0.75
[3] 2.9483 1.0 1.6727 32.1
[4] 9.4627 D4
[5] 絞り 0.2
[6] 1.8486 1.1 1.48749 70.1
[7] -4.1481 0.1
[8] 2.9532 0.4 1.80518 25.4
[9] 1.4979 D9
[10] 3.7783 0.8 1.48749 70.1
[11] 21.7761 D11
[12] ∞ 0.3 1.51633 64.1
[13] ∞ D13=1.0
（非球面データ）
第１面 e=1 第２面 e=1
C2 = 0.0000000D+00 C2 = 0.00000000D+00
C4 = 0.38993440D-01 C4 = 0.23864549D-01
C6 =-0.11025637D-01 C6 = 0.91114503D-03
C8 = 0.15081266D-02 C8 =-0.64886885D-02
C10=-0.73592548D-04 C10= 0.87457802D-03

第6面 e=1 第10面 e=1
C2 = 0.0000000D+00 C2 = 0.00000000D+00
C4 =-0.28693632D-01 C4 =-0.82818998D-03
C6 = 0.31825853D-03 C6 = 0.50972730D-02
C8 =-0.58735539D-02 C8 =-0.50891657D-02
C10= 0.20935641D-02 C10= 0.16919110D-02
焦点距離 １．６０ ２．７７ ４．８０
可変間隔 D4 7.2604 3.9662 2.0643
D9 1.5061 3.408 6.7022
D11 1.0 1.0 1.0
光学全長： １５．８２〜 １４．４３〜 １５．８２ｍｍ The zoom lens 6 is a five-lens glass lens material with a wide angle of view of 72.0 °, F number of 2.8, image circle on CCD of 2.25mmφ, and zoom ratio of about 3 times. is there. The various data and conditions of the zoom lens of Example 6 are shown below.
Example 6
3 group type: zoom ratio 3 (moving lens group; first lens group, second lens group)
Focal length: 1.60 to 4.80 mm, F-number = 2.7 to 4.9, exit pupil position; -6.0 to -43.8 (from image plane)
Since the focal length of the first group is f1 = −4.0, the focal length of the second group is f2 = 4.5, and the focal length of the third group is f3 = 9.24,

Petzval sum: p = 0.0088, the last two surfaces are the cover glass, and D13 is the back focus value.
R (I) D (I) Nd Vd
[1] -9.2532 0.4 1.6935 53.2
[2] 1.8436 0.75
[3] 2.9483 1.0 1.6727 32.1
[4] 9.4627 D4
[5] Aperture 0.2
[6] 1.8486 1.1 1.48749 70.1
[7] -4.1481 0.1
[8] 2.9532 0.4 1.80518 25.4
[9] 1.4979 D9
[10] 3.7783 0.8 1.48749 70.1
[11] 21.7761 D11
[12] ∞ 0.3 1.51633 64.1
[13] ∞ D13 = 1.0
(Aspheric data)
First side e = 1 Second side e = 1
C2 = 0.0000000D + 00 C2 = 0.00000000D + 00
C4 = 0.38993440D-01 C4 = 0.23864549D-01
C6 = -0.11025637D-01 C6 = 0.91114503D-03
C8 = 0.15081266D-02 C8 = -0.64886885D-02
C10 = -0.73592548D-04 C10 = 0.87457802D-03

6th surface e = 1 10th surface e = 1
C2 = 0.0000000D + 00 C2 = 0.00000000D + 00
C4 = -0.28693632D-01 C4 = -0.82818998D-03
C6 = 0.31825853D-03 C6 = 0.50972730D-02
C8 = -0.58735539D-02 C8 = -0.50891657D-02
C10 = 0.20935641D-02 C10 = 0.16919110D-02
Focal length 1.60 2.77 4.80
Variable interval D4 7.2604 3.9662 2.0643
D9 1.5061 3.408 6.7022
D11 1.0 1.0 1.0
Optical total length: 15.82 to 14.43 to 15.82 mm

  Next, Example 7 will be described. FIG. 13 is a diagram showing the configuration and movement trajectory of the lens of Example 7, and FIG. 14 is an aberration diagram from the wide-angle end (a) to the telephoto end (c) at the infinity shooting distance in Example 7.

The zoom lens 7 according to the seventh exemplary embodiment includes, in order from the object side, a first lens unit L1 having a negative refractive index, a second lens unit L2 having a positive refractive index, and a third lens unit having a positive refractive index. The lens unit L3 includes three lens units. The first lens group is formed with two lenses, a concave lens L11 and a convex lens L12, and moves with a convex U-turn toward the image side. Further, the R1 surface and the R2 surface of the concave lens L11 are each aspherical.
On the other hand, the second lens group is formed with two lenses, a convex lens L21 and a concave lens L22, and moves monotonously to the object side. The R6 surface of the convex lens L21 is an aspherical surface. A diaphragm S is disposed in the vicinity of the front surface of the convex lens L21 of the second lens unit L2.
Furthermore, the third lens unit L3 includes a convex lens L31, and its R10 surface is an aspherical surface.
The illustrated zoom lens 7 is zoomed by moving the first lens unit L1 and the second lens unit L2. G is a cover glass.

ペツバル和：ｐ＝0.0195、最後の２面はカバー硝子、D13はバックフォーカスの値。
R(I) D(I) Nd Vd
[1] -9.1315 0.4 1.69350 53.2
[2] 1.755 0.76
[3] 4.7432 0.8 1.6727 32.1
[4] -31.6003 D4
[5] 絞り 0.2
[6] 1.9146 1.1 1.49194 56.0
[7] -3.1416 0.1
[8] 5.2333 0.4 1.80518 25.4
[9] 1.8972 D9
[10] 5.004 0.8 1.49194 56.0
[11] -47.1553 D11
[12] ∞ 0.3 1.51633 64.1
[13] ∞ D13=1.0
（非球面データ）
第１面 e=1 第２面 e=1
C2 = 0.0000000D+00 C2 = 0.00000000D+00
C4 =-0.10694995D-01 C4 =-0.49126107D-01
C6 = 0.12365887D-01 C6 = 0.14881827D-01
C8 =-0.27682256D-02 C8 = 0.20790177D-02
C10= 0.14376206D-03 C10=-0.29347420D-02

第6面 e=1 第10面 e=1
C2 = 0.0000000D+00 C2 = 0.00000000D+00
C4 =-0.37988929D-01 C4 =-0.44527640D-02
C6 = 0.88561753D-02 C6 =-0.24234441D-02
C8 =-0.15309566D-01 C8 = 0.79068651D-03
C10= 0.56705164D-02 C10= 0.13627796D-03
焦点距離 １．６０ ２．７７ ４．８０
可変間隔 D4 6.8351 3.5409 1.6389
D9 1.4219 3.3238 6.618
D11 1.1541 1.1541 1.1541
光学全長： １５．２６〜 １３．８７〜 １５．２６ｍｍ The zoom lens 7 is made up of 5 glass balls made of 3 glass and 2 plastic, wide angle of view 70.0 °, F number 2.7, image circle 2.25mmφ on CCD, zoom ratio approximately 3 times This is a zoom lens. The various data and conditions of the zoom lens of Example 7 are shown below.
Example 7
3 group type: zoom ratio 3 (moving lens group; first lens group, second lens group)
Focal length: 1.60 to 4.80 mm, F-number = 2.7 to 4.8, exit pupil position; -6.2 to -47.6 (from the image plane)
Since the focal length of the first group is f1 = −4.0, the focal length of the second group is f2 = 4.5, and the focal length of the third group is f3 = 9.24,

Petzval sum: p = 0.0195, the last two surfaces are the cover glass, and D13 is the back focus value.
R (I) D (I) Nd Vd
[1] -9.1315 0.4 1.69350 53.2
[2] 1.755 0.76
[3] 4.7432 0.8 1.6727 32.1
[4] -31.6003 D4
[5] Aperture 0.2
[6] 1.9146 1.1 1.49194 56.0
[7] -3.1416 0.1
[8] 5.2333 0.4 1.80518 25.4
[9] 1.8972 D9
[10] 5.004 0.8 1.49194 56.0
[11] -47.1553 D11
[12] ∞ 0.3 1.51633 64.1
[13] ∞ D13 = 1.0
(Aspheric data)
First side e = 1 Second side e = 1
C2 = 0.0000000D + 00 C2 = 0.00000000D + 00
C4 = -0.10694995D-01 C4 = -0.49126107D-01
C6 = 0.12365887D-01 C6 = 0.14881827D-01
C8 = -0.27682256D-02 C8 = 0.20790177D-02
C10 = 0.14376206D-03 C10 = -0.29347420D-02

6th surface e = 1 10th surface e = 1
C2 = 0.0000000D + 00 C2 = 0.00000000D + 00
C4 = -0.37988929D-01 C4 = -0.44527640D-02
C6 = 0.88561753D-02 C6 = -0.24234441D-02
C8 = -0.15309566D-01 C8 = 0.79068651D-03
C10 = 0.56705164D-02 C10 = 0.13627796D-03
Focal length 1.60 2.77 4.80
Variable interval D4 6.8351 3.5409 1.6389
D9 1.4219 3.3238 6.618
D11 1.1541 1.1541 1.1541
Optical total length: 15.26 to 13.87 to 15.26 mm

  Next, Example 8 will be described. FIG. 15 is a diagram showing the configuration and movement trajectory of the lens of Example 8, and FIG. 16 is an aberration diagram from the wide-angle end (a) to the telephoto end (c) at the infinity shooting distance in Example 8.

  The zoom lens 8 according to the eighth embodiment includes, in order from the object side, a first lens unit L1 having a negative refractive index, a second lens unit L2 having a positive refractive index, and a third lens unit having a positive refractive index. The lens unit L3 includes three lens units. The first lens group includes two lenses, a concave lens L11 and a convex lens L12, and is fixed without moving. The R1 surface and the R2 surface of the concave lens L11 are aspherical surfaces.

On the other hand, the second lens group is formed with two lenses, a convex lens L21 and a concave lens L22, and moves monotonously to the object side. The R6 surface of the convex lens L21 is an aspherical surface. A diaphragm S is disposed in the vicinity of the front surface of the convex lens L21 of the second lens unit L2.
Further, the third lens unit L3 includes a convex lens L31, and moves monotonously to the object side. The R10 surface of the convex lens L31 is an aspherical surface.
The zoom lens 8 shown in the figure is zoomed by moving the second lens unit L2 and the third lens unit L3. G is a cover glass.

ペツバル和：ｐ＝-0.003、後の２面はカバー硝子、D13はバックフォーカスの値。
光学全長：１２．４３ｍｍ（一定）
R(I) D(I) Nd Vd
[1] 45.1186 0.4 1.6935 53.2
[2] 1.2204 0.6257
[3] 1.9546 0.8 1.6727 32.1
[4] 3.428 D4
[5] 絞り 0.2
[6] 1.701 1.1 1.48749 70.1
[7] -5.0173 0.1
[8] 3.2469 0.4 1.80518 25.4
[9] 1.4810 D9
[10] 2.4773 0.8 1.48749 70.1
[11] -38.8863 D11
[12] ∞ 0.3 1.51633 64.1
[13] ∞ D13=1.0
（非球面データ）
第１面 e=1 第２面 e=1
C2 = 0.0000000D+00 C2 = 0.00000000D+00
C4 = 0.41734520D-01 C4 = 0.53832066D-02
C6 =-0.91694814D-02 C6 = 0.30548231D-01
C8 =-0.3624085D-02 C8 =-0.53388248D-01
C10= 0.14026456D-02 C10=-0.62586764D-02

第6面 e=1 第10面 e=1
C2 = 0.0000000D+00 C2 = 0.00000000D+00
C4 =-0.28318119D-01 C4 =-0.75276836D-02
C6 =-0.11320841D-02 C6 =-0.56885936D-02
C8 =-0.49693591D-02 C8 = 0.19251069D-02
C10= 0.28220677D-03 C10= 0.12818272D-02
焦点距離 １．６０ ２．７７ ４．８０
可変間隔 D4 4.3839 2.0413 0.6889
D9 0.5625 1.5526 0.5625
D11 1.7627 3.1151 5.4575 The zoom lens 8 is a five-lens glass lens, with a wide angle of view 66.6 °, F number 2.8, image circle 2.25mmφ on the CCD, and a zoom lens with a zoom ratio of about 3 times. is there. Various data and conditions of the zoom lens of Example 8 are shown below.
Example 8
3 group type: zoom ratio 3 (moving lens group; second lens group, third lens group)
Focal length: 1.60 to 4.80 mm, F-number = 2.8 to 4.8, exit pupil position; -5.67 to -9.37 (from image plane)
Since the focal length of the first group is f1 = −2.7713, the focal length of the second group is f2 = 4.8287, and the focal length of the third group is f3 = 4.8079,

Petzval sum: p = -0.003, the last two surfaces are cover glass, and D13 is the back focus value.
Optical total length: 12.43 mm (constant)
R (I) D (I) Nd Vd
[1] 45.1186 0.4 1.6935 53.2
[2] 1.2204 0.6257
[3] 1.9546 0.8 1.6727 32.1
[4] 3.428 D4
[5] Aperture 0.2
[6] 1.701 1.1 1.48749 70.1
[7] -5.0173 0.1
[8] 3.2469 0.4 1.80518 25.4
[9] 1.4810 D9
[10] 2.4773 0.8 1.48749 70.1
[11] -38.8863 D11
[12] ∞ 0.3 1.51633 64.1
[13] ∞ D13 = 1.0
(Aspheric data)
First side e = 1 Second side e = 1
C2 = 0.0000000D + 00 C2 = 0.00000000D + 00
C4 = 0.41734520D-01 C4 = 0.53832066D-02
C6 = -0.91694814D-02 C6 = 0.30548231D-01
C8 = -0.3624085D-02 C8 = -0.53388248D-01
C10 = 0.14026456D-02 C10 = -0.62586764D-02

6th surface e = 1 10th surface e = 1
C2 = 0.0000000D + 00 C2 = 0.00000000D + 00
C4 = -0.28318119D-01 C4 = -0.75276836D-02
C6 = -0.11320841D-02 C6 = -0.56885936D-02
C8 = -0.49693591D-02 C8 = 0.19251069D-02
C10 = 0.28220677D-03 C10 = 0.12818272D-02
Focal length 1.60 2.77 4.80
Variable interval D4 4.3839 2.0413 0.6889
D9 0.5625 1.5526 0.5625
D11 1.7627 3.1151 5.4575

  Next, Example 9 will be described. FIG. 17 is a diagram illustrating the configuration and movement locus of the lens of Example 9, and FIG. 18 is an aberration diagram from the wide-angle end (a) to the telephoto end (c) at the infinity shooting distance in Example 9.

  Similarly to the zoom lens 8 according to the eighth embodiment, the zoom lens 9 according to the ninth embodiment includes, in order from the object side, a first lens group L1 having a negative refractive index and a second lens group L2 having a positive refractive index. The third lens unit L3 includes a third lens unit L3 having a positive refractive index. The first lens group includes two lenses, a concave lens L11 and a convex lens L12, and is fixed without moving. The R1 surface and the R2 surface of the concave lens L11 are aspherical surfaces.

On the other hand, the second lens group is formed with two lenses, a convex lens L21 and a concave lens L22, and moves monotonously to the object side. The R6 surface of the convex lens L21 is an aspherical surface. A diaphragm S is disposed in the vicinity of the front surface of the convex lens L21 of the second lens unit L2.
Further, the third lens unit L3 includes a convex lens L31, and moves monotonously to the object side. The R10 surface of the convex lens L31 is an aspherical surface.
The zoom lens 9 shown in the figure is zoomed by moving the second lens unit L2 and the third lens unit L3. G is a cover glass.

ペツバル和：ｐ＝0.011、後の２面はカバー硝子、D13はバックフォーカスの値。
光学全長：１３．２３ｍｍ(一定)
R(I) D(I) Nd Vd
[1] 24.9243 0.4 1.69350 53.2
[2] 1.2538 0.6031
[3] 1.8476 1.0 1.6727 32.1
[4] 2.8475 D4
[5] 絞り 0.2
[6] 1.764 1.1 1.49194 56.0
[7] -2.9415 0.1
[8] 9.6499 0.4 1.80518 25.4
[9] 1.8921 D9
[10] 2.7143 0.8 1.49194 56.0
[11] -24.0947 D11
[12] ∞ 0.3 1.51633 64.1
[13] ∞ D13=1.0
（非球面データ）
第１面 e=1 第２面 e=1
C2 = 0.0000000D+00 C2 = 0.00000000D+00
C4 = 0.15999194D-01 C4 =-0.14826010D-01
C6 = 0.26442371D-01 C6 = 0.39461204D-01
C8 =-0.16508946D-01 C8 = 0.31281831D-01
C10= 0.26344900D-02 C10=-0.52531631D-01

第6面 e=1 第10面 e=1
C2 = 0.0000000D+00 C2 = 0.00000000D+00
C4 =-0.37069338D-01 C4 =-0.11599041D-01
C6 =-0.37211170D-02 C6 =-0.31407615D-02
C8 =-0.58019641D-02 C8 = 0.50688392D-02
C10= 0.21098899D-02 C10=-0.16986768D-02
焦点距離 １．６０ ２．７６ ４．７８
可変間隔 D4 4.7448 2.3048 0.8961
D9 0.6557 1.687 0.6557
D11 1.9293 3.3381 5.7781 The zoom lens 9 is made up of 5 glass balls made of 3 glass and 2 plastic lenses, a wide field angle of 71.2 °, an F number of 2.9, an image circle of 2.25 mmφ on the CCD, and a zoom ratio of about 3 times. This is a zoom lens. The various data and conditions of the zoom lens of Example 9 are shown below.
Example 9
3 group type: zoom ratio 3 (moving lens group; second lens group, third lens group)
Focal length: 1.60 to 4.78 mm, F-number = 2.9 to 4.8, exit pupil position: −6.09 to −9.94 (from image plane)
Since the focal length of the first group is f1 = −2.7713, the focal length of the second group is f2 = 5.0299, and the focal length of the third group is f3 = 5.0082,

Petzval sum: p = 0.011, the last two surfaces are cover glass, and D13 is the back focus value.
Optical total length: 13.23 mm (constant)
R (I) D (I) Nd Vd
[1] 24.9243 0.4 1.69350 53.2
[2] 1.2538 0.6031
[3] 1.8476 1.0 1.6727 32.1
[4] 2.8475 D4
[5] Aperture 0.2
[6] 1.764 1.1 1.49194 56.0
[7] -2.9415 0.1
[8] 9.6499 0.4 1.80518 25.4
[9] 1.8921 D9
[10] 2.7143 0.8 1.49194 56.0
[11] -24.0947 D11
[12] ∞ 0.3 1.51633 64.1
[13] ∞ D13 = 1.0
(Aspheric data)
First side e = 1 Second side e = 1
C2 = 0.0000000D + 00 C2 = 0.00000000D + 00
C4 = 0.15999194D-01 C4 = -0.14826010D-01
C6 = 0.26442371D-01 C6 = 0.39461204D-01
C8 = -0.16508946D-01 C8 = 0.31281831D-01
C10 = 0.26344900D-02 C10 = -0.52531631D-01

6th surface e = 1 10th surface e = 1
C2 = 0.0000000D + 00 C2 = 0.00000000D + 00
C4 = -0.37069338D-01 C4 = -0.11599041D-01
C6 = -0.37211170D-02 C6 = -0.31407615D-02
C8 = -0.58019641D-02 C8 = 0.50688392D-02
C10 = 0.21098899D-02 C10 = -0.16986768D-02
Focal length 1.60 2.76 4.78
Variable interval D4 4.7448 2.3048 0.8961
D9 0.6557 1.687 0.6557
D11 1.9293 3.3381 5.7781

  Incidentally, since there are various kinds of sizes of the CCD due to its development, FIG. 2, FIG. 4, FIG. 6, FIG. 8, FIG. In the vertical scale of the astigmatism diagram and the distortion diagram in FIG. 18, the half angle of view corresponding to the case where the sizes of various CCD sizes are determined without entering half of the diagonal length of the image height of that size. This is represented by the display angle ω.

(A), (b), and (c) are diagrams showing the configuration and movement trajectory of the lens of Example 1. FIG. FIG. 6 is an aberration diagram from Example 1 to the telephoto end (c) at an infinite distance shooting distance. (A) (b) (c) is a figure which shows the structure and movement locus | trajectory of the lens of Example 2. FIG. FIG. 6 is an aberration diagram from Example 2 to the telephoto end (c) at an infinity shooting distance. (A), (b), and (c) are diagrams showing a configuration and a movement locus of the lens of Example 3. FIG. FIG. 6 is an aberration diagram from Example 3 to the telephoto end (c) at an infinity shooting distance. (A), (b), and (c) are diagrams showing the lens configuration and movement trajectory of Example 4. FIG. FIG. 7 is an aberration diagram from Example 4 to the telephoto end (c) at an infinity shooting distance in Example 4. (A), (b), and (c) are diagrams showing the configuration and movement trajectory of the lens of Example 5. FIG. FIG. 9 is an aberration diagram from Example 5 to the telephoto end (c) at an infinity shooting distance. (A), (b), and (c) are diagrams showing a lens configuration and a movement locus of Example 6. FIG. FIG. 10 is an aberration diagram from the wide-angle end (a) to the telephoto end (c) at infinity shooting distance in Example 6. (A), (b), and (c) are diagrams showing a lens configuration and a movement locus of Example 7. FIG. FIG. 10 is an aberration diagram from Example 7 to the telephoto end (c) at an infinity shooting distance. (A), (b), and (c) are diagrams showing the configuration and movement trajectory of the lens of Example 8. FIG. FIG. 10 shows aberration diagrams from the wide-angle end (a) to the telephoto end (c) at infinity shooting distances in Example 8. (A), (b), and (c) are diagrams showing the configuration and movement trajectory of the lens of Example 9. FIG. FIG. 10 is an aberration diagram from Example 10 to the telephoto end (c) at an infinity shooting distance.

Explanation of symbols

L1 1st lens group L2 2nd lens group L3 3rd lens group G Cover glass d d line S Aperture

Claims (14)

In order from the object side, there are provided two lens groups, a first lens group having a negative refractive index and a second lens group having a positive refractive index, and the first lens group and the second lens group. A zoom lens that performs zooming by moving the lens, or a first lens group having a negative refractive index, a second lens group having a positive refractive index, and a positive refractive index in order from the object side. A zoom lens that performs zooming by moving the second lens group and the third lens group, or a first lens group having a negative refractive index in order from the object side, A zoom lens comprising a second lens group having a positive refractive index and a third lens group having a positive refractive index, and performing zooming by moving the first lens group and the second lens group There,
If the focal length of each lens group is fi (i is 1 to 3),

A zoom lens characterized by satisfying the following conditions: A zoom lens comprising the two lens groups according to claim 1.
The first lens group is formed with two concave and convex lenses, and is moved with a convex U-turn to the image side when zooming from the wide angle end to the telephoto end, and ,
The second lens group is formed with two convex / concave lenses or three convex / concave lenses, and moves monotonically toward the object side when zooming from the wide-angle end to the telephoto end. A zoom lens characterized by that. A zoom lens comprising the three lens groups according to claim 1, wherein the zoom lens performs zooming by moving the first lens group and the second lens group.
The first lens group is formed with two concave and convex lenses, and when moving from the wide angle end to the telephoto end, it moves with a convex U-turn on the image side.
The second lens group is formed with two concave and convex lenses, and is moved monotonically to the object side when zooming from the wide-angle end to the telephoto end, and
The zoom lens according to claim 3, wherein the third lens group is formed with a single convex lens and is fixed. A zoom lens comprising the three lens groups according to claim 1, wherein the zoom lens performs zooming by moving the second lens group and the third lens group.
The first lens group is formed with two concave and convex lenses and fixed.
The second lens group is formed with two concave and convex lenses, and is moved monotonically to the object side when zooming from the wide-angle end to the telephoto end, and
The third lens group is formed with a single convex lens, and is moved monotonically toward the object side when zooming from the wide-angle end to the telephoto end. Zoom lens. The zoom lens according to any one of claims 2, 3, and 4,
The zoom lens according to claim 1, wherein, of the two concave and convex lenses constituting the first lens group, at least one surface of the concave lens is an aspherical surface. 3. The zoom lens according to claim 2, wherein the second lens group includes two convex and concave lenses.
2. The zoom lens according to claim 2, wherein the two concave and convex lenses constituting the second lens group are made of a cemented lens, and at least one surface of the convex lens and the concave lens is an aspherical surface. The zoom lens according to claim 3 or 4,
A zoom lens according to claim 2, wherein at least one surface of the convex lens is an aspherical surface among the two convex and concave lenses constituting the second lens group. The zoom lens according to claim 2, wherein the second lens group includes three convex and concave lenses.
Of the three convex and concave lenses constituting the second lens group, at least one surface of the convex lens is an aspherical surface. The zoom lens according to claim 3 or 4,
A zoom lens, wherein at least one surface of the convex lens constituting the third lens group is an aspherical surface. The zoom lens according to any one of claims 2, 3, and 4,
When the refractive index of the concave component of the first lens group and the Abbe number are ndn1 and νdn1, respectively.
1.50 <ndn1 <1.81, 40.0 <νdn1 <75.0
A zoom lens that satisfies the following conditions. The zoom lens according to any one of claims 2, 3, and 4,
When the refractive index of the convex component of the first lens group and the Abbe number are ndp1 and νdp1, respectively.
1.55 <ndp1 <1.81, 25.4 <νdp1 <45.0
A zoom lens that satisfies the following conditions. The zoom lens according to any one of claims 2, 3, and 4,
When the refractive index of the convex component of the second lens group and the Abbe number are ndp2 and νdp2, respectively.
ndp2 <1.74, 48.0 <νdp2
A zoom lens that satisfies the following conditions. The zoom lens according to any one of claims 2, 3, and 4,
When the refractive index of the concave component of the second lens group and the Abbe number are ndn2 and νdn2, respectively.
1.58 <ndn2, νdn2 <30.0
A zoom lens that satisfies the following conditions. The zoom lens according to claim 3 or 4,
When the refractive index of the convex component of the third lens group and the Abbe number are ndp3 and νdp3, respectively.
1.44 <ndp3 <1.65, 55.0 <νdp3
A zoom lens that satisfies the following conditions.

Images