JP4223311B2 - Imaging lens - Google Patents

Description

【００１８】
また、本実施形態に係る撮像レンズでは、第１レンズＬ_１と開口絞り１の間隔が、開口絞り１と第２レンズＬ_２の間隔よりも小さくなるように構成されている。
これにより、撮像レンズの製造性を良好に保ちつつ、非点収差およびコマ収差を良好に補正するとともに、画角毎の諸収差の最適化を図ることができる。
【００１９】
さらに、本実施形態に係る撮像レンズは、下記条件式（１）〜（５）を満足する。
｜ｆ_１／ｆ_２｜ ＜ ０．３ ・・・ （１）
ｄ_２１／ｄ_２２ ＜ ０．３ ・・・ （２）
Ｌ／ｆ ＜ １．２ ・・・ （３）
Ｆ ≦ ４．０ ・・・ （４）
ω ≧ ２５° ・・・ （５）
ただし、
ｆ_１ ・・・ 第１レンズの光軸近傍における焦点距離
ｆ_２ ・・・ 第２レンズの光軸近傍における焦点距離
ｄ_２１ ・・・ 第１レンズの像側面から開口絞りまでの光軸上の距離
ｄ_２２ ・・・ 開口絞りから第２レンズの物体側面までの光軸上の距離
ｆ ・・・ レンズ全系の光軸近傍における焦点距離
Ｌ ・・・ 第１レンズの物体側面から像面までの光軸上の距離（ただし、第２レンズと像面との間に、フィルタ等の光路上挿入物がないとき）
Ｆ ・・・ Ｆナンバ
ω ・・・ 半画角（度）
【００２０】
次に、上記条件式（１）〜（５）の技術的意義について説明する。
条件式（１）は、第１レンズＬ_１の光軸近傍における焦点距離ｆ_１と第２レンズＬ_２の光軸近傍における焦点距離ｆ_２の比ｆ_１／ｆ_２の絶対値を規定したもので、非点収差を良好に補正するとともに、撮像素子に対する適切な受光量を確保するための条件式である。
【００２１】
この条件式（１）では、第１レンズＬ_１の正のパワーが小さくなるか、あるいは第２レンズＬ_２のパワーが大きくなると、上限を超えることとなる。すなわち、第２レンズＬ_２の正のパワーが大きくなると、これに対して第１レンズＬ_１の正のパワーを小さくしなくてはならず、条件式（１）において、ｆ_１／ｆ_２の絶対値が上限を超えると、非点収差を良好に補正することが困難となる。また、第２レンズＬ_２の負のパワーが大きくなり、条件式（１）においてｆ_１／ｆ_２の絶対値が上限を超えると、撮像素子に対する軸外光の入射角が大きくなって受光量が低下し、好ましくない。
【００２２】
条件式（２）は、第１レンズＬ_１の像側面から開口絞り１までの光軸上の距離ｄ_２１と、開口絞り１から第２レンズＬ_２の物体側面までの光軸上の距離ｄ_２２の比ｄ_２１／ｄ_２２の値を規定したもので、撮像レンズの製造性を良好に保ちつつ、非点収差およびコマ収差を良好に補正するとともに、画角毎の諸収差の最適化を図るための条件式である。
【００２３】
この条件式（２）において、ｄ_２１／ｄ_２２の値が上限を超えると、第１レンズＬ_１を通過する光束の光軸からの高さが大きくなって第１レンズＬ_１の外径が大きくなり、第１レンズＬ_１の外周部における光軸方向の厚さが小さくなるため、撮像レンズの製造性が悪化する。
【００２４】
そして、このような不都合を避けるために第１レンズＬ_１の厚さを増してゆくと、非点収差およびコマ収差を良好に補正することができなくなり、光学性能が低下する。また、第２レンズＬ_２を通過する光束の光軸からの高さが小さくなって、第２レンズＬ_２の外径は小さくなるが、画角毎に第２レンズＬ_２を通過する光束の位置の差が小さくなって、画角毎に諸収差の最適化を図ることができなくなる。
【００２５】
条件式（３）は、第１レンズＬ_１の物体側面から像面までの光軸上の距離Ｌと、レンズ全系の光軸近傍における焦点距離ｆとの比Ｌ／ｆの値を規定したもので、非点収差を良好に補正するとともに、レンズ系の小型化を図るための条件式である。
この条件式（３）において、Ｌ／ｆの値が上限を超えると、第１レンズＬ_１の正のパワーが小さくなり、非点収差を良好に補正することが困難となる。また、レンズ系を小型化することが困難となる。
【００２６】
条件式（４）は、Ｆナンバを規定することにより、明るいレンズ系とするための条件式である。この条件式（４）において、Ｆナンバの値が上限を超えると、明るいレンズ系として機能しなくなる。
【００２７】
条件式（５）は、半画角を規定することにより、広画角なレンズ系とするための条件式である。この条件式（５）において、半画角の値が下限を超えると、広画角なレンズ系として機能しなくなる。
【００２８】
以下、具体的数値を用いて、本発明の実施例を説明する。
【００２９】
＜実施例１＞
実施例１における各レンズ面の曲率半径Ｒ（ｍｍ）、各レンズの中心厚および各レンズ間の空気間隔Ｄ（ｍｍ）、各レンズのｅ線における屈折率Ｎ_ｅおよび各レンズのｄ線におけるアッベ数ν_ｄを下記表１の上段に示す。
ただし、この表１において、各記号Ｒ、Ｄ、Ｎ_ｅ、ν_ｄに対応させた数字は物体側から順次増加するようになっている（表２において同じ）。
また、実施例１における各レンズ面は、上記非球面式により表される非球面とされている。表１の中段に、これら非球面に関する非球面係数を示す。
【００３０】
また、表１の下段に、この実施例１におけるレンズ全系の光軸近傍における焦点距離ｆ（ｍｍ）、第１レンズＬ_１の光軸近傍における焦点距離ｆ_１（ｍｍ）、第２レンズＬ_２の光軸近傍における焦点距離ｆ_２（ｍｍ）、第１レンズＬ_１の像側面から開口絞り１までの光軸上の距離ｄ_２１（ｍｍ）、開口絞り１から第２レンズＬ_２の物体側面までの光軸上の距離ｄ_２２（ｍｍ）、第１レンズＬ_１の物体側面から像面までの光軸上の距離（フィルタを除いた値）Ｌ（ｍｍ）、および条件式（１）〜（５）にそれぞれ対応するｆ_１／ｆ_２、ｄ_２１／ｄ_２２、Ｌ／ｆ、Ｆ、ωの値を示す。
【００３１】
【表１】

【００３２】
表１から明らかなように、実施例１では、条件式（１）〜（５）の全てを満足している。
【００３３】
＜実施例２＞
実施例２における各レンズ面の曲率半径Ｒ（ｍｍ）、各レンズの中心厚および各レンズ間の空気間隔Ｄ（ｍｍ）、各レンズのｅ線における屈折率Ｎ_ｅおよび各レンズのｄ線におけるアッベ数ν_ｄを下記表２の上段に示す。
また、実施例２における各レンズ面は、上記非球面式により表される非球面とされている。表２の中段に、これら非球面に関する非球面係数を示す。
【００３４】
また、表２の下段に、この実施例２におけるレンズ全系の光軸近傍における焦点距離ｆ（ｍｍ）、第１レンズＬ_１の光軸近傍における焦点距離ｆ_１（ｍｍ）、第２レンズＬ_２の光軸近傍における焦点距離ｆ_２（ｍｍ）、第１レンズＬ_１の像側面から開口絞り１までの光軸上の距離ｄ_２１（ｍｍ）、開口絞り１から第２レンズＬ_２の物体側面までの光軸上の距離ｄ_２２（ｍｍ）、第１レンズＬ_１の物体側面から像面までの光軸上の距離（フィルタを除いた値）Ｌ（ｍｍ）、および条件式（１）〜（５）にそれぞれ対応するｆ_１／ｆ_２、ｄ_２１／ｄ_２２、Ｌ／ｆ、Ｆ、ωの値を示す。
【００３５】
【表２】

【００３６】
表２から明らかなように、実施例２では、条件式（１）〜（５）の全てを満足している。
【００３７】
図２および図３に、実施例１および実施例２に対応させた各収差図（球面収差、非点収差、歪曲収差、横収差）をそれぞれ示す。なお、球面収差の各収差図にはｅ線、ｇ線、Ｃ線に対する収差が示されており、非点収差の各収差図には、サジタル像面およびタンジェンシャル像面に対する収差が示されている。
図２および図３から明らかなように、上記各実施例によれば、諸収差を全て良好なものとすることができる。
【００３８】
【発明の効果】
以上説明したように、本発明の撮像レンズでは、全てのレンズ面が非球面とされた２群２枚構成とし、各レンズ面の非球面形状を規定することにより、小型化および広角化を図るとともに、諸収差を良好に補正することができる。
また、所定の条件式を満足させることにより、さらに確実に、小型化および広角化を図るとともに、諸収差を良好に補正することができる。
【図面の簡単な説明】
【図１】本発明の実施形態に係る撮像レンズのレンズ構成図
【図２】実施例１に係るレンズの各収差図（球面収差、非点収差、歪曲収差、横収差）
【図３】実施例２に係るレンズの各収差図（球面収差、非点収差、歪曲収差、横収差）
【符号の説明】
Ｌ_１〜Ｌ_２ レンズ
Ｒ_１〜Ｒ_４ レンズ面の曲率半径
Ｄ_１〜Ｄ_３ レンズ面間隔（レンズ厚）
Ｘ 光軸
Ｐ 結像位置
１ 開口絞り
２ フィルタ
３ 結像面[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an image pickup lens having two groups and two elements for reading an image formed on an image pickup device such as a CCD or a CMOS, and more specifically, suitable for an image input unit or a digital camera in a mobile terminal such as a mobile phone. The present invention relates to an imaging lens having a relatively small image size, which has an F number of 4.0 or less, a half angle of view of 25 ° or more, and a lens outer diameter of 8 mm or less.
[0002]
[Prior art]
In an image input unit or a digital camera in a portable terminal such as a mobile phone, an image pickup device such as a CCD or a CMOS is provided on an image formation surface, and there are various image pickup lenses for reading an image formed on the image pickup device. Proposed.
[0003]
By the way, with recent technological advancement, the downsizing of the image sensor has progressed and the number of pixels has increased. As an image pickup lens used for a portable terminal or a digital camera having such an image sensor, various types have a small size and a wide angle of view. What can correct | amend an aberration favorably is desired.
2. Description of the Related Art Conventionally, an imaging lens having a two-group, two-element configuration that attempts to meet such demands for miniaturization and wide angle of view is known (see, for example, Patent Document 1, Patent Document 2, and Patent Document 3).
[0004]
[Patent Document 1]
JP-A-6-67089 [Patent Document 2]
JP-A-11-295592 [Patent Document 3]
Japanese Patent Laid-Open No. 13-183578
[Problems to be solved by the invention]
However, the imaging lens described in Patent Document 1 has a half angle of view of about 18.4 °, and it was difficult to say that it was a wide angle of view.
[0006]
In the imaging lenses described in Patent Document 2 and Patent Document 3, the distance from the object side surface of the first lens to the image plane is long, the distance from the object side surface of the first lens to the image plane, and the focal length of the entire lens system. The imaging lens described in Patent Document 2 has a ratio of approximately 3.8 to 4.5, and the imaging lens described in Patent Document 3 has a ratio of approximately 2.45.
[0007]
Thus, when the ratio of the distance from the object side surface of the first lens to the image plane and the focal length is large, the positive power of the first lens is small, and it is difficult to correct astigmatism well. At the same time, the total length of the lens system becomes long, which is against the demand for miniaturization.
[0008]
The present invention has been made in view of such circumstances, and it is an object of the present invention to provide an imaging lens capable of satisfactorily correcting various aberrations with a small size and a wide angle in an imaging lens having two groups and two elements. is there.
[0009]
[Means for Solving the Problems]
The imaging lens of the present invention is an imaging lens in which a first lens, an aperture stop, and a second lens are disposed in order from the object side, and both surfaces of the first lens and the second lens are aspherical surfaces. There,
The first lens has a positive refractive power, has a convex shape on the object side in the vicinity of the optical axis on the object side surface, has a concave shape on the image side in the vicinity of the optical axis on the image side surface,
The second lens has a convex shape on the object side in the vicinity of the optical axis on the object side surface, a concave shape on the object side in the periphery of the object side surface, and a concave shape on the image side in the vicinity of the optical axis on the image side surface. A convex portion is formed on the image side in the peripheral portion of the image side surface, the power in the vicinity of the optical axis is weaker than that of the first lens, and the following conditional expressions (1) to (5) are satisfied. Is.
| F ₁ / f ₂ | <0.3 (1)
d ₂₁ / d ₂₂ <0.3 (2)
L / f <1.2 (3)
F ≦ 4.0 (4)
ω ≧ 25 ° (5)
However,
f ₁ ... Focal length in the vicinity of the optical axis of the first lens
f ₂ ... Focal length in the vicinity of the optical axis of the second lens
d ₂₁ ... Distance on the optical axis from the image side surface of the first lens to the aperture stop
d ₂₂ ... Distance on the optical axis from the aperture stop to the object side surface of the second lens f ... Focal length near the optical axis of the entire lens system L ... Distance from the object side surface of the first lens to the image plane Distance on the optical axis (when there is no filter or other insert between the second lens and the image plane)
F ・ ・ ・ F number
ω ・ ・ ・ Half angle of view (degrees)
[0010]
In the imaging lens of the present invention, in addition to the above configuration, it is preferable that the distance between the first lens and the aperture stop is smaller than the distance between the aperture stop and the second lens.
[0012]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of an imaging lens of the present invention will be described based on the drawings.
FIG. 1 is a lens configuration diagram of an imaging lens according to an embodiment of the present invention.
[0013]
As shown in FIG. 1, the imaging lens according to the embodiment of the present invention includes a first lens L ₁ , an aperture stop 1, and a second lens L ₂ arranged in this order from the object side. _A filter 2 made of a glass plate or a plastic plate is disposed between ₂ and the imaging plane 3. In this imaging lens, the light beam incident along the optical axis X from the object side is imaged at the imaging position P of the imaging surface 3.
[0014]
The first lens L ₁ has a positive refractive power, has a convex shape on the object side in the vicinity of the optical axis on the object side surface, and has a concave shape on the image side in the vicinity of the optical axis on the image side surface.
[0015]
The second lens L ₂ is, without a concave on the object side in the periphery of the object side surface with forming a convex shape toward the object side near the optical axis of the object side surface, forming a concave shape on the image side near the optical axis of the image-side surface with a convex shape toward the image side in the peripheral portion of the image side surface, the power near the optical axis is configured to be weak in comparison with the first lens L _1.
[0016]
Further, the first lens L ₁ and second lens L ₂ surfaces are aspherical represented by the following aspheric expression.
[0017]
[Expression 1]

[0018]
Further, in the imaging lens according to the present embodiment, the first lens distance L ₁ and the aperture stop 1 is configured to be smaller than the spacing of the aperture stop 1 and the second lens L _2.
As a result, it is possible to satisfactorily correct astigmatism and coma while maintaining good manufacturability of the imaging lens and to optimize various aberrations for each angle of view.
[0019]
Furthermore, the imaging lens according to the present embodiment satisfies the following conditional expressions (1) to (5).
| F ₁ / f ₂ | <0.3 (1)
d ₂₁ / d ₂₂ <0.3 (2)
L / f <1.2 (3)
F ≦ 4.0 (4)
ω ≧ 25 ° (5)
However,
f ₁ ... Focal length f ₂ near the optical axis of the first lens f ₂ ... Focal length d ₂₁ near the optical axis of the second lens d ₂₁ ... On the optical axis from the image side surface of the first lens to the aperture stop Distance d ₂₂ ... Distance on the optical axis from the aperture stop to the object side surface of the second lens f ... Focal length L in the vicinity of the optical axis of the entire lens system ... From the object side surface of the first lens to the image plane On the optical axis (when there is no filter or other insert between the second lens and the image plane)
F ... F number ω ... Half angle of view (degrees)
[0020]
Next, the technical significance of the conditional expressions (1) to (5) will be described.
Conditional expression (1) defines the absolute value of the ratio f ₁ / f ₂ of the focal length f ₁ near the optical axis of the first lens L ₁ and the focal length f ₂ near the optical axis of the second lens L _2. Thus, this is a conditional expression for satisfactorily correcting astigmatism and ensuring an appropriate amount of received light for the image sensor.
[0021]
In the conditional expression (1), if either the first lens L ₁ of the positive power is decreased, or the second lens L ₂ of the power is increased, and thus exceed the upper limit. That is, when the positive power of the second lens L ₂ is increased, the positive power of the first lens L ₁ must be decreased with respect to this, and in the conditional expression (1), f ₁ / f ₂ If the absolute value exceeds the upper limit, it is difficult to correct astigmatism satisfactorily. Further, when the negative power of the second lens L ₂ increases and the absolute value of f ₁ / f ₂ exceeds the upper limit in the conditional expression (1), the incident angle of off-axis light with respect to the image sensor increases and the received light amount Is not preferable.
[0022]
Conditional expression (2) indicates that the distance d ₂₁ on the optical axis from the image side surface of the first lens L ₁ to the aperture stop 1 and the distance d on the optical axis from the aperture stop 1 to the object side surface of the second lens L _2. It defines the ratio value of d _{21 /} d ₂₂ of _22, while maintaining good productivity of the imaging lens, as well as satisfactorily correct astigmatism and coma, the optimization of the various aberrations in each angle of view This is a conditional expression for illustration.
[0023]
In this conditional expression (2), when the value of d ₂₁ / d ₂₂ exceeds the upper limit, the height of the light beam passing through the first lens L ₁ increases from the optical axis, and the outer diameter of the first lens L ₁ becomes smaller. become large, because the optical axial thickness at the outer peripheral portion of the first lens L ₁ becomes small, manufacturing of the imaging lens is deteriorated.
[0024]
When Yuku increased thickness of the first lens L ₁ in order to avoid such an inconvenience, the astigmatism and coma aberration can not be satisfactorily corrected, the optical performance deteriorates. Further, the height of the light beam passing through the second lens L ₂ from the optical axis is reduced, and the outer diameter of the second lens L ₂ is reduced, but the light beam passing through the second lens L ₂ at every angle of view. The difference in position becomes small, and it becomes impossible to optimize various aberrations for each angle of view.
[0025]
Condition (3) is defined and the distance L along the optical axis to the image plane from the first lens object side surface of the L _1, the value of the ratio L / f between the focal length f in the vicinity of the optical axis of the entire lens system Thus, this is a conditional expression for satisfactorily correcting astigmatism and reducing the size of the lens system.
In this condition (3), the value of L / f exceeds the upper limit, positive power of the first lens L ₁ becomes smaller, the astigmatism can be satisfactorily corrected becomes difficult. In addition, it is difficult to reduce the size of the lens system.
[0026]
Conditional expression (4) is a conditional expression for obtaining a bright lens system by defining the F number. In this conditional expression (4), if the F number exceeds the upper limit, it will not function as a bright lens system.
[0027]
Conditional expression (5) is a conditional expression for obtaining a lens system having a wide angle of view by defining a half angle of view. In this conditional expression (5), if the value of the half angle of view exceeds the lower limit, the lens system does not function as a wide angle of view.
[0028]
Hereinafter, examples of the present invention will be described using specific numerical values.
[0029]
<Example 1>
The radius of curvature R of each lens surface in Example 1 (mm), axis surface spacing D of each lens (mm), Abbe at the d-line refractive index N _e of each lens at e-line of each lens The number ν _d is shown in the upper part of Table 1 below.
However, in Table 1, the numbers corresponding to the symbols R, D, N _e , and ν _d are sequentially increased from the object side (the same applies in Table 2).
In addition, each lens surface in Example 1 is an aspheric surface represented by the above aspheric expression. The middle part of Table 1 shows the aspheric coefficients related to these aspheric surfaces.
[0030]
Further, the lower part of Table 1, the optical axis focal length in the vicinity f of the entire lens system in the embodiment 1 (mm), the focal length f ₁ in the vicinity of the optical axis of the first lens L _{1 (mm),} the second lens L ₂ , the focal distance f ₂ (mm) in the vicinity of the optical axis ₂ , the distance d ₂₁ (mm) on the optical axis from the image side surface of the first lens L ₁ to the aperture stop 1, and the object of the second lens L ₂ from the aperture stop 1 Distance d ₂₂ (mm) on the optical axis to the side surface, distance on the optical axis from the object side surface of the first lens L ₁ to the image plane (value excluding the filter) L (mm), and conditional expression (1) The values of f ₁ / f ₂ , d ₂₁ / d ₂₂ , L / f, F, and ω corresponding to .about. (5) are shown.
[0031]
[Table 1]

[0032]
As is clear from Table 1, in Example 1, all conditional expressions (1) to (5) are satisfied.
[0033]
<Example 2>
The radius of curvature R of each lens surface in Example 2 (mm), axis surface spacing D of each lens (mm), Abbe at the d-line refractive index N _e of each lens at e-line of each lens The number ν _d is shown in the upper part of Table 2 below.
In addition, each lens surface in Example 2 is an aspheric surface represented by the above aspheric expression. The middle part of Table 2 shows the aspheric coefficients related to these aspheric surfaces.
[0034]
Further, the lower part of Table 2, this embodiment of the lens system in 2 focal length at the vicinity of the optical axis f (mm), the focal length f ₁ in the vicinity of the optical axis of the first lens L _{1 (mm),} the second lens L ₂ , the focal distance f ₂ (mm) in the vicinity of the optical axis ₂ , the distance d ₂₁ (mm) on the optical axis from the image side surface of the first lens L ₁ to the aperture stop 1, and the object of the second lens L ₂ from the aperture stop 1 Distance d ₂₂ (mm) on the optical axis to the side surface, distance on the optical axis from the object side surface of the first lens L ₁ to the image plane (value excluding the filter) L (mm), and conditional expression (1) The values of f ₁ / f ₂ , d ₂₁ / d ₂₂ , L / f, F, and ω corresponding to .about. (5) are shown.
[0035]
[Table 2]

[0036]
As is clear from Table 2, in Example 2, all the conditional expressions (1) to (5) are satisfied.
[0037]
2 and 3 show aberration diagrams (spherical aberration, astigmatism, distortion, and lateral aberration) corresponding to Example 1 and Example 2, respectively. In addition, each aberration diagram for spherical aberration shows aberrations for the e-line, g-line, and C-line, and each aberration diagram for astigmatism shows aberrations for the sagittal image surface and the tangential image surface. Yes.
As is apparent from FIGS. 2 and 3, according to each of the above embodiments, all the aberrations can be made favorable.
[0038]
【The invention's effect】
As described above, the imaging lens of the present invention has a two-group two-lens configuration in which all lens surfaces are aspherical surfaces, and defines the aspherical shape of each lens surface, thereby achieving a reduction in size and a wide angle. At the same time, various aberrations can be corrected satisfactorily.
Further, by satisfying a predetermined conditional expression, it is possible to further reliably reduce the size and widen the angle and correct various aberrations satisfactorily.
[Brief description of the drawings]
FIG. 1 is a lens configuration diagram of an imaging lens according to an embodiment of the present invention. FIG. 2 is a diagram showing aberrations of the lens according to Example 1 (spherical aberration, astigmatism, distortion, lateral aberration).
FIG. 3 shows aberration diagrams of the lens according to Example 2 (spherical aberration, astigmatism, distortion, lateral aberration).
[Explanation of symbols]
L ₁ ~L ₂ lens _R 1 to R ₄ lens surface curvature radius _D 1 to D ₃ lens surface spacing (lens thickness)
X Optical axis P Imaging position 1 Aperture stop 2 Filter 3 Imaging plane

Claims (2)

An imaging lens in which a first lens, an aperture stop, and a second lens are arranged in order from the object side, and both surfaces of the first lens and the second lens are aspherical surfaces,
The first lens has a positive refractive power, has a convex shape on the object side in the vicinity of the optical axis on the object side surface, has a concave shape on the image side in the vicinity of the optical axis on the image side surface,
The second lens has a convex shape on the object side in the vicinity of the optical axis on the object side surface, a concave shape on the object side in the periphery of the object side surface, and a concave shape on the image side in the vicinity of the optical axis on the image side surface. A convex portion is formed on the image side in the peripheral portion of the image side surface, the power in the vicinity of the optical axis is weaker than that of the first lens, and the following conditional expressions (1) to (5) are satisfied. Imaging lens.
| F ₁ / f ₂ | <0.3 (1)
d ₂₁ / d ₂₂ <0.3 (2)
L / f <1.2 (3)
F ≦ 4.0 (4)
ω ≧ 25 ° (5)
However,
f ₁ ... Focal length in the vicinity of the optical axis of the first lens
f ₂ ... Focal length in the vicinity of the optical axis of the second lens
d ₂₁ ... Distance on the optical axis from the image side surface of the first lens to the aperture stop
d ₂₂ ... Distance on the optical axis from the aperture stop to the object side surface of the second lens f ... Focal length near the optical axis of the entire lens system L ... From the object side surface of the first lens to the image plane Distance on the optical axis (when there is no filter or other insertion material between the second lens and the image plane)
F ・ ・ ・ F number
ω ・ ・ ・ Half angle of view (degrees)   The imaging lens according to claim 1, wherein an interval between the first lens and the aperture stop is smaller than an interval between the aperture stop and the second lens.

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