JP2023011031A - Rear attachment lens and image capturing optical system using the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a rear attachment lens which offers good optical performance even when used with a master lens with a short back focus and a relatively long distance to an exit pupil position.

SOLUTION: A rear attachment lens provided herein is designed to be attached to a master lens on the image side to make a focal length of the entire system longer than a focal length of the master lens, and includes a positive lens Lr located on the most image side, the positive lens Lr having a convex surface on the image side. A focal length fe of the rear attachment lens, an imaging magnification βe of the rear attachment lens when attached to the master lens, a distance np2 from a lens surface of the rear attachment lens on the most image side to a rear principal point when attached to the master lens, and others are appropriately set.

SELECTED DRAWING: Figure 1

COPYRIGHT: (C)2023,JPO&INPIT

Description

The present invention relates to a rear attachment lens that is detachably mounted between a master lens for imaging and an image sensor and that changes the focal length of the entire system to a longer one than the original focal length of the master lens. .

A rear attachment lens is known that is mounted between a master lens for imaging and an image sensor and changes the focal length of the entire system to be longer than the focal length of the master lens alone (Patent Documents 1 to 3). .

A rear attachment lens that makes the focal length of the entire system longer than the focal length of the master lens alone generally has a negative refractive power. The image formed by this is magnified, and the focal length of the entire system is changed to be longer than the focal length of the master lens alone according to the imaging magnification. At this time, the F-number (F-number) is characterized by becoming darker according to the imaging magnification.

Since the master lens is independently corrected for aberrations, the rear attachment lens mounted on the image side of the master lens must also be sufficiently corrected for aberrations independently. In particular, among various aberrations, the rear attachment lens must sufficiently correct field curvature and lateral chromatic aberration. Japanese Patent Application Laid-Open No. 2002-200002 discloses conditions for obtaining good image plane characteristics, and Japanese Patent Application Laid-Open No. 2002-200010 discloses a method of correcting lateral chromatic aberration.

Since Patent Documents 1 and 2 are mainly single-lens reflex systems (imaging devices), the back focus of the master lens is ensured to be very long, and the rear attachment lens can be configured with a relatively weak refractive power. . Therefore, there is a feature that it is easy to obtain good aberration. In addition, the master lens must have a long back focus when the quick return mirror is placed on the image side of the rear attachment lens.

On the other hand, in a mirrorless camera without a quick return mirror, the back focus of the master lens may be short. For this reason, mirrorless cameras require a rear attachment lens that can obtain good aberration even if the back focus is short.

Patent Document 3 discloses a rear attachment lens for a mirrorless camera that corresponds to a master lens with a short back focus.

JP-A-63-106715 Japanese Unexamined Patent Application Publication No. 2011-123336 International Publication 2017/134928

In general, when the back focus of the master lens to which the rear attachment lens is attached becomes short, the rear attachment lens with negative refractive power needs to be positioned on the image side. Therefore, the focal length of the rear attachment lens is shorter to obtain the same magnification. In general, when the negative refractive power of the rear attachment lens increases, the Petzval sum increases in the negative direction and the image plane characteristics deteriorate. For this reason, it is necessary to satisfactorily correct this.

Also, when the back focus of the master lens is shortened, the distance from the image plane to the exit pupil is shortened. Therefore, in the master lens having a short distance from the image plane to the exit pupil, it becomes easy to increase the imaging magnification of the rear attachment lens. However, in a telephoto lens where it is useful to use a rear attachment lens, a longer distance from the image plane to the exit pupil is advantageous from the viewpoint of obtaining high optical performance.

Therefore, an object of the present invention is to obtain a rear attachment lens that has a short back focus and that can provide good optical performance even when used with a master lens that has a relatively long distance to the exit pupil position. .

In the rear attachment lens of the present invention, the focal length of the entire system when the rear attachment lens is mounted on the image side of the master lens is longer than the focal length of the master lens,
The rear attachment lens has six or more lenses including a first positive lens, a first negative lens, and a second positive lens arranged in order from the most object side,
A positive lens Lr is arranged closest to the image side of the attachment lens, and a positive lens is arranged next to the positive lens Lr,
The positive lens Lr has a convex shape on the image side, the second positive lens has a convex shape on the image side,
fe is the focal length of the rear attachment lens, βe is the imaging magnification of the rear attachment lens when the rear attachment lens is attached to the master lens, and the rear attachment is the rear attachment when the rear attachment lens is attached to the master lens. When the distance from the lens surface closest to the image side to the rear principal point position is np2, and the lens thickness of the rear attachment lens is De,
|fe|/(fe×(1−βe)+np2)>9
2<|fe/De|≦27.5
It is characterized by satisfying the following conditional expression:

According to the present invention, it is possible to obtain a rear attachment lens that has a short back focus and provides good optical performance even when used with a master lens that has a relatively long distance to the exit pupil position.

Lens sectional view of the rear attachment lens of Example 1 Aberration diagram when the rear attachment lens of Example 1 is attached to the master lens Lens sectional view of the rear attachment lens of Example 2 Aberration diagram when the rear attachment lens of Example 2 is attached to the master lens Lens sectional view of the rear attachment lens of Reference Example 1 Aberration diagram when the rear attachment lens of Reference Example 1 is attached to the master lens Lens cross-sectional view of the rear attachment lens of Example 3 Aberration diagram when the rear attachment lens of Example 3 is attached to the master lens Lens sectional view of the rear attachment lens of Example 4 Aberration diagram when the rear attachment lens of Example 4 is attached to the master lens Lens sectional view of the rear attachment lens of Example 5 Aberration diagram when the rear attachment lens of Example 5 is attached to the master lens Lens sectional view of the rear attachment lens of Example 6 Aberration diagram when the rear attachment lens of Example 6 is attached to the master lens Lens sectional view of the rear attachment lens of Example 7 Aberration diagram when the rear attachment lens of Example 7 is attached to the master lens Illustration of paraxial refractive power arrangement when a rear attachment lens is attached to the master lens Cross section of master lens Aberration diagram of the master lens Cross-sectional view of the lens when the rear attachment lens of Example 1 is attached to the master lens Optical path diagram showing the relationship between the exit pupil of the master lens and the rear attachment lens Schematic diagram showing the configuration of an imaging device (digital camera)

Preferred embodiments of the present invention will be described below with reference to the accompanying drawings.

The rear attachment lens of the present invention is detachably attached to the image side of the master lens (main lens system). When the rear attachment lens is mounted on the image side of the master lens, the focal length of the entire system changes to be longer than the focal length of the master lens.

FIG. 1 is a lens sectional view of the rear attachment lens of Example 1. FIG. FIG. 2 is an aberration diagram when the rear attachment lens of Example 1 is attached to the master lens. By attaching the rear attachment lens to the master lens, the focal length of the entire system is expanded to 1.4 times the focal length of the master lens.

FIG. 3 is a lens sectional view of the rear attachment lens of Example 2. FIG. FIG. 4 is an aberration diagram when the rear attachment lens of Example 2 is attached to the master lens. By attaching the rear attachment lens to the master lens, the focal length of the entire system is expanded to 1.4 times the focal length of the master lens.

5 is a lens sectional view of the rear attachment lens of Reference Example 1. FIG. FIG. 6 is an aberration diagram when the rear attachment lens of Reference Example 1 is attached to the master lens. By attaching the rear attachment lens to the master lens, the focal length of the entire system is enlarged to 2.0 times the focal length of the master lens.

FIG. 7 is a lens sectional view of the rear attachment lens of Example 3. FIG. FIG. 8 is an aberration diagram when the rear attachment lens of Example 3 is attached to the master lens. By attaching the rear attachment lens to the master lens, the focal length of the entire system is enlarged to 2.0 times the focal length of the master lens.

FIG. 9 is a lens sectional view of the rear attachment lens of Example 4. FIG. FIG. 10 is an aberration diagram when the rear attachment lens of Example 4 is attached to the master lens. By attaching the rear attachment lens to the master lens, the focal length of the entire system is enlarged to 2.0 times the focal length of the master lens.

FIG. 11 is a lens sectional view of the rear attachment lens of Example 5. FIG. FIG. 12 is an aberration diagram when the rear attachment lens of Example 5 is attached to the master lens. By attaching the rear attachment lens to the master lens, the focal length of the entire system is enlarged to 2.0 times the focal length of the master lens.

FIG. 13 is a lens sectional view of the rear attachment lens of Example 6. FIG. FIG. 14 is an aberration diagram when the rear attachment lens of Example 6 is attached to the master lens. By attaching the rear attachment lens to the master lens, the focal length of the entire system is expanded to 1.4 times the focal length of the master lens.

FIG. 15 is a lens sectional view of the rear attachment lens of Example 7. FIG. FIG. 16 is an aberration diagram when the rear attachment lens of Example 7 is attached to the master lens. By attaching the rear attachment lens to the master lens, the focal length of the entire system is enlarged to 2.0 times the focal length of the master lens.

FIGS. 17A and 17B are schematic optical path diagrams when a rear attachment lens is attached to the master lens.

FIG. 18 is a lens sectional view of a master lens to which the rear attachment lens of each embodiment is attached.

19 is an aberration diagram of the master lens of FIG. 18. FIG.

FIG. 20 is a lens sectional view when the rear attachment lens of Example 1 is attached to the master lens.

21A and 21B are explanatory diagrams of optical paths when the distance from the image plane to the position of the exit pupil of the master lens is long and when it is short.

FIG. 22 is a schematic diagram of the essential parts of the imaging apparatus of the present invention.

In the lens sectional views, ML is the master lens and EL is the rear attachment lens. In the master lens ML, Bi is the i-th lens group. Arrows indicate the direction of movement of the lens group during focusing from infinity to close. img is the image plane. STO is the aperture stop. Lr is the positive lens closest to the image side of the rear attachment lens EL, and L1 is the positive lens closest to the object side of the rear attachment lens.

In the aberration diagrams showing the aberration diagram of the master lens ML and the aberration diagram when the rear attachment lens EL is attached to the master lens ML, spherical aberration, astigmatism, distortion, and lateral chromatic aberration are shown from the left side of the paper.

In terms of spherical aberration, the solid line d is the d-line (wavelength 587.56 nm), the dashed line f is the f-line (wavelength 486.13 nm), the dashed line C is the C line (wavelength 656.27 nm), and the dashed double-dot line g is Aberration of the g-line (wavelength 435.83 nm) is shown. The scale of the horizontal axis is the defocus amount, which ranges from -0.4 to +0.4 [mm].

In the astigmatism diagrams, the solid line S indicates the sagittal image surface, and the dotted line M indicates the field curvature of the meridional image surface. The horizontal axis is the same as spherical aberration.

The distortion aberration is represented by a scale of -5 to +5 [%] on the horizontal axis. The chromatic aberration of magnification indicates deviation from the d-line, and the scale of the horizontal axis is -0.03 to +0.03 [mm].

FIG. 17A shows a schematic diagram of the rear attachment lens EL when the back focus of the master lens (main lens system) ML is sufficiently long. It represents a lens of negative refractive power.

If the back focus of the master lens ML is sufficiently long, the distance s from the imaging point MS of the master lens ML to the rear attachment lens EL can be made sufficiently long. Therefore, the focal length of the rear attachment lens EL required to obtain the same imaging magnification β of the rear attachment lens EL can be lengthened (because β=1/(1+s/fe)). If the refracting power can be weakened, the Petzval sum can be easily corrected, and good curvature of field can be obtained.

On the other hand, in the case of FIG. 17B where the back focus of the master lens ML is shortened and the distance s from the imaging point of the master lens ML to the rear attachment lens EL is shortened, conversely, the refraction of the rear attachment lens EL force increases in the negative direction. As a result, the Petzval sum remains large and negative, making it difficult to obtain good curvature of field.

The Petzval sum can be simply expressed as Σ(φk/Nk) using the refractive power φk of each lens and the refractive index Nk of the material. We have improved the Petzval sum using modulus material. At this time, if the back focus of the master lens ML is short and the optical path length in which the lens can be arranged is short, it becomes difficult to arrange the lens necessary for correction, and the improvement effect becomes insufficient, or correction of chromatic aberration becomes difficult. Cheap.

Therefore, in the rear attachment lens of each embodiment, as shown in FIG. 17B, the rear attachment lens EL has a refractive power arrangement of negative + positive in order from the object side to the image side. By increasing the distance between the principal points and moving the distance to the rear principal point toward the object side, the refractive power of the rear attachment lens EX is weakened (the focal length is increased). This makes it easy to correct the Petzval sum for a rear attachment lens with a long back focus.

In order to configure the rear attachment lens EL with the refractive power arrangement shown in FIG. 17B, the positive lens Lr is provided closest to the image side, and Lr is brought as close to the image position img as possible.

The rear attachment lens EL has a positive lens Lr closest to the image side, and the positive lens Lr has a convex shape toward the image side. Let fe be the focal length of the rear attachment lens EL, and βe be the imaging magnification of the rear attachment lens EL when the rear attachment lens LE is attached to the master lens ML. Let np2 be the distance from the final lens surface to the rear principal point position when the rear attachment lens EL is attached to the master lens ML. At this time,
|fe|/(fe×(1−βe)+np2)>9 (1)
satisfies the following conditional expression.

The denominator component of conditional expression (1) corresponds to the sum of the paraxial back focus and the rear principal point position, and roughly represents the back focus. If the lower limit of conditional expression (1) is exceeded, it becomes difficult to reduce the Petzval sum.

Further, by adopting such a refractive power arrangement, it is easy to make the refractive power of the rear attachment lens EL, which was conventionally negative, slightly positive, so the focal length fe is an absolute value.

More preferably, the numerical range of conditional expression (1) is set as follows.
|fe|/(fe(1−βe)+np2)>18 (1a)

In each embodiment, it is preferable to satisfy one or more of the following conditional expressions.

Let R1 be the radius of curvature of the object side lens surface of the positive lens Lr on the image side, and R2 be the radius of curvature of the image side lens surface of the positive lens Lr. Let φr be the effective diameter of the positive lens Lr. Let fe (mm) be the focal length fe, and np2 (mm) be the distance np2. Let De be the lens thickness of the rear attachment lens EL (the length from the first lens surface to the image plane). Let BF be the back focus in the imaging optical system having the master lens ML and the rear attachment lens EL detachably attached to the image side of the master lens ML.

In the case of an image pickup apparatus having an image pickup optical system and an image pickup device for receiving an image formed by the image pickup optical system, the effective diameter of the positive lens Lr is φr, and the maximum when the rear attachment lens EL is attached to the master lens ML Let Yi be the image height. Let φ1 be the effective diameter of the positive lens closest to the object side of the rear attachment lens EL. At this time, one or more of the following should be satisfied.
-5.00<(R2+R1)/(R2-R1)<-0.85 (2)
1.8<φr/(fe×(1−βe)+np2)<20.0 (3)
−5<1000 (mm)/(fe+np2)<5 (4)
-4<1000 (mm)/(fe×βe)<4 (5)
|fe/De|>2 (6)
|fe/BF|>9 (7)
1.8<φr/Yi<2.2 (8)
1.85<φ1×βe/Yi<3.00 (9)

Next, the technical meaning of each of the above conditional expressions will be explained.

If the lens shape of the positive lens Lr closest to the image side is set within the range of conditional expression (2), it becomes easier to move the position of the principal point of the positive lens Lr alone toward the image side, so an appropriate refractive power arrangement It becomes easier to take If the upper limit of conditional expression (2) is exceeded, the principal point tends to be located on the object side and the thickness of the positive lens Lr tends to increase, which is not preferable. If the lower limit of conditional expression (2) is exceeded, the curvature of the image-side lens surface becomes too strong, and a large amount of coma tends to occur in the upper line of peripheral light, which is not preferable.

In each embodiment, since the positive lens Lr is arranged on the image side, the effective diameter φr of the positive lens Lr becomes large in order to capture peripheral light. If the lower limit of conditional expression (3) is exceeded, it becomes difficult to secure the necessary amount of peripheral light in combination with the master lens ML, which has a long distance from the image plane to the exit pupil. Exceeding the upper limit of conditional expression (3) is not preferable because the thickness of the positive lens Lr becomes too long. In addition, the effective diameter φr must be accommodated in the mount member that connects the lens unit and the camera, and the present configuration with the relatively large effective diameter φr is suitable for implementation with a large-diameter mount.

The denominator of conditional expression (4) represents the rear focal position, and when set to a numerical range that satisfies conditional expression (4), the refractive power of the rear attachment lens EL can be weakened, making it easy to reduce the Petzval sum. . When the lower limit of conditional expression (4) is exceeded, the Petzval sum tends to remain negative, and when the upper limit of conditional expression (4) is exceeded, overcorrection occurs, and the Petzval sum tends to remain positive.

If the imaging magnification of the rear attachment lens EL increases, it is necessary to increase the negative refracting power in order to increase the imaging magnification, but if the numerical range of conditional expression (5) is set, the Petzval sum can be satisfactorily corrected. If the upper limit of the conditional expression (5) is exceeded, the Petzval sum tends to be overcorrected, and if the lower limit of the conditional expression (5) is exceeded, the correction tends to be insufficient.

In order to attach the rear attachment lens EL to the master lens ML having a short back focus, it is necessary to shorten the optical path length in proportion to this. Therefore, the lens thickness De tends to be short. Therefore, by setting the focal length of the rear attachment lens EL within the numerical range of conditional expression (5), it becomes easy to correct the Petzval sum. If the lower limit of conditional expression (6) is exceeded, it will be difficult to secure a necessary length of back focus, or the back focus of the master lens ML must be lengthened, which is not preferable.

By shortening the back focus BF and moving the positive lens Lr closest to the image side closer to the image side, it becomes easier to lengthen the focal length fe. Therefore, if the numerical range of conditional expression (7) is set, good curvature of field can be easily obtained. If the lower limit of conditional expression (7) is exceeded, the Petzval sum will either be undercorrected or overcorrected, which is not desirable.

If the lower limit of conditional expression (8) is exceeded, it is not preferable because when the rear attachment lens EL is attached to the master lens ML, which has a long distance from the image plane to the exit pupil, peripheral light tends to be kicked out. If the upper limit of conditional expression (8) is exceeded, the lens thickness becomes unnecessarily thick, which is not preferable.

If the distance from the image plane of the master lens ML to the exit pupil is long, peripheral light cannot be taken in unless the effective diameter of the positive lens L1 closest to the object side is increased as shown in FIG. 21(A). Conversely, when the distance from the image plane of the master lens ML to the exit pupil is short, the effective diameter of the positive lens L1 closest to the object side can be reduced as shown in FIG. 21(B). Therefore, if the lower limit of conditional expression (9) is exceeded, the amount of peripheral light will decrease when the master lens ML having a long distance from the image plane to the exit pupil is attached, which is not preferable. If the upper limit is exceeded, the positive lens L1 becomes unnecessarily thick, making it difficult to obtain the required imaging magnification.

More preferably, the numerical ranges of conditional expressions (2) to (9) are set as follows.
−5.00<(R2+R1)/(R2−R1)<−0.87 (2a)
2.1<φr/(fe×(1−βe)+np2)<20.0 (3a)
−3<1000 (mm)/(fe+np2)<3 (4a)
-2<1000 (mm)/(fé×βe)<2 (5a)
|fe/De|>4.8 (6a)
|fe/BF|>18 (7a)
1.85<φr/Yi<2.10 (8a)
1.82<φ1×βe/Yi<2.50 (9a)

FIG. 22 is a schematic diagram showing the configuration of the imaging device (digital camera) 10. As shown in FIG. (a) of FIG. 22 is a perspective view, and (b) of FIG. 22 is a side view. The imaging apparatus 10 includes a camera body 13, a master lens ML, and a rear attachment lens EL similar to any of the first to eighth embodiments described above. Further, a light-receiving element (imaging element) 12 that photoelectrically converts an image formed by the master lens ML and the rear attachment lens EL is provided.

As the light receiving element 12, an imaging element such as a CCD sensor or a CMOS sensor can be used. The master lens ML and the rear attachment lens EL may be configured integrally with the camera body 13, or may be configured to be detachable from the camera body 13, respectively. When the master lens ML and the rear attachment lens EL are configured integrally with the camera body 13, the rear attachment lens EL is configured to be removable on the optical axis.

Although preferred embodiments of the present invention have been described above, the present invention is not limited to these embodiments, and various modifications and changes are possible within the scope of the gist.

Numerical examples of the rear attachment lenses EL of Examples 1 to 8 and numerical examples of the master lens ML equipped with the rear attachment lenses EL of the examples of the present invention are shown in Table 1 below.

The order in which i is counted from the object side is shown. In each numerical example, Bi indicates the i-th lens group and Si indicates the i-th surface. EAi is the effective diameter of the ith surface, Ri is the radius of curvature of the ith lens surface, and di is the distance between the ith and (i+1)th surfaces. ndi and νdi are the refractive index for the d-line (wavelength 587.56 nm) of the medium between the i-th and the (i+1)-th and the Abbe number based on the d-line. A lens surface with an S attached to the left side of the surface number indicates the position of the aperture stop.

A lens surface with an asterisk (*) attached to the right side of the surface number indicates that it has an aspherical shape according to the following function, and its coefficients are shown in numerical examples. y indicates the coordinate in the radial direction with reference to the surface vertex of the lens surface, and x indicates the coordinate in the optical axis direction with reference to the surface vertex of the lens surface. A, B, C, and D are aspheric coefficients.
x=(y ² /R)/[1+{1−(1+K)(y ² /R ² )} ^1/2 ]+
^Ay4 + ^By6 + ^Cy8 + ^Dy10

For the rear attachment lens EL, the focal length f and F-number F are values when the object distance is infinite. The total lens length here indicates the distance from the first lens surface to the imaging position. BF indicates the back focus, which is the distance from the lens surface having the refractive power closest to the image side to the imaging plane, and is calculated by excluding an element having no refractive power, such as a flat plate, if present in the distance. is the equivalent air length.

Numerical examples of the rear attachment lens EL have a negative surface distance on the starting lens surface, which indicates the distance from the imaging position of the master lens ML to the first lens surface of the rear attachment lens EL. there is When the rear attachment lens EL is attached to the master lens ML, the input is continued as in Numerical Example 1.

The master lens ML of the numerical example is designed to have a distance of -106 mm from the image plane to the exit pupil, which is a relatively long value in a mirrorless imaging optical system with a short back focus BF. The back focus BF of the master lens ML was set to 35 mm from the viewpoint of the performance and versatility of the rear attachment lens EL.

Examples 1 to 5 of the rear attachment lens EL correspond to a full-size sensor and are optimized for an ideal optical system in which the distance between the image plane and the exit pupil is 100 mm. The optical performance can be confirmed by attaching it to the master lens ML described above, or attaching it to an ideal optical system of 100 mm. The F value of the master lens ML is initially set to F2, but depending on the corresponding F value of the rear attachment lens EL, the aperture of the master lens ML can be narrowed down to the aperture diameter described in the numerical examples. preferable.

Examples 1 to 5 of the rear attachment lens EL were created by changing the imaging magnification, the corresponding F value, and the minimum back focus of the master lens, respectively. is shown. In Examples 6 and 7, an ideal optical system of 50 mm is optimized according to the sensor size, but a sufficient amount of light is ensured even when attached to the master lens ML.

In Numerical Example 1, the surface numbers s1 to s26 are the master lens ML, and the surface numbers s27 to s38 are the rear attachment lens EL. Surface number s11 is an aperture stop. Surface number s27 is a dummy surface used for design.

In Numerical Example 1, the magnification is 1.4, and the corresponding F number of the master lens ML is 2.8 (the F number when combined with the master lens ML is F4.0), so the effective diameter of the surface number s is φ23.0. It is assumed that it will be used only for

It is assumed that the first lens surface of the rear attachment lens EL is arranged at a position −33 mm from the image forming position of the master lens ML, and the clearance (interval) with the master lens ML is 2 mm.

Numerical Examples 2 to 7 show only the rear attachment lens EL, and assume that the master lens ML with the surface numbers s1 to s26 of Numerical Example 1 is attached. Numerical Example 2 has a magnification of 2.0, a corresponding F number of the master lens ML of 2.0 (F number when combined with the master lens ML is F2.8), and corresponds to a large aperture master lens ML. .

When a large-aperture lens is used, even if the Petzval sum is reduced, the peripheral field curvature is often disturbed. In Numerical Example 2, it is used for surface number 3.

Further, in Numerical Example 2, the refractive power is reversed to have a weak positive refractive power. In this case, the sign of the distance np2 from the final lens surface to the rear principal point is inverted and has a positive value. Numerical Reference Example 1 and Numerical Examples 3 to 7 are also shown in the same manner as Numerical Example 2.

(Numerical example of master lens)
BS EA R d glass nd vd
OBJ 1E+30
1 1 52.60 89.7804 7.0000 SLAH96 1.76385 48.49
2 51.69 -430.9980 0.5000
3 46.32 48.3018 9.6000 SFPM3 1.53775 74.70
4 44.77 -136.5166 1.8000 SNBH56 1.85478 24.80
5 41.83 141.7310 4.0272
2 6 39.28 342.7978 5.0000 SNPH4 1.89286 20.36
7 38.15 -104.6205 1.5000 SBSL7 1.51633 64.14
8 32.92 30.4224 6.0000
9 32.90 -125.4496 1.5000 STIM8 1.59551 39.24
10 32.47 91.3223 14.1566
3 s11 32.84 (aperture) 2.0000
12 33.11 -4e+010 4.0000 TAFD35 1.91082 35.25
13 33.17 -92.1494 2.3500
14 33.09 -39.9735 2.5000 STIH10 1.72825 28.46
15 34.03 -85.4438 13.2476
4 16 35.22 184.1552 4.6000 SLAH96 1.76385 48.49
17 35.17 -68.0760 0.5000
18 33.00 44.4430 7.4000 SFPM3 1.53775 74.70
19 32.37 -57.1397 1.5000 STIH6 1.80518 25.42
20 32.09 -159.1922 1.0000
5 21 30.91 301.3443 1.5000 SNBH52 1.67300 38.15
22 29.87 31.5275 18.2616
23 34.00 -30.8186 1.5000 SNSL36 1.51742 52.43
24 37.76 -130.0211 0.5000
25 39.73 1275.4399 6.5000 TAFD35 1.91082 35.25
26 40.64 -49.8300 35.0000
Ext
IMGMore

Infinity Intermediate Nearest focal length 100.15 100.04 95.86
F number 2.00 2.00 2.80
Angle of view 12.19 12.20 12.72
Image height 21.63 21.63 21.63
Overall lens length 118.44 118.44 118.44
BF 35.00 35.00 35.00
Object distance (OBJ) 1e+015 4845.07 231.23
d5 4.027 4.327 15.154
d10 14.157 13.856 3.030
d15 13.248 12.780 2.905
d20 1.000 1.467 11.343
d26 35.000 35.000 35.376

Aperture diameter (F2) 32.8 32.8 27.2
Aperture diameter (F2.8) 23.0 23.0 19.4

Group data group Starting surface Last surface Focal length
B1 1 5 70.9504
B2 6 10 -44.4358
B3 11 15 1954.0227
B4 16 20 36.5660
B5 21 26 -137.5262

(Numerical example 1) (master lens) + (rear attachment lens)
f = 140.08 F = 4.00 angle = 8.78 Y = 21.635
BS EA R d glass nd vd
OBJ 1E+30
1 1 52.60 89.7804 7.0000 SLAH96 1.76385 48.49
2 51.69 -430.9980 0.5000
3 46.32 48.3018 9.6000 SFPM3 1.53775 74.70
4 44.77 -136.5166 1.8000 SNBH56 1.85478 24.80
5 41.83 141.7310 4.0272
2 6 39.28 342.7978 5.0000 SNPH4 1.89286 20.36
7 38.15 -104.6205 1.5000 SBSL7 1.51633 64.14
8 32.92 30.4224 6.0000
9 32.90 -125.4496 1.5000 STIM8 1.59551 39.24
10 32.47 91.3223 14.1566
3 s11 23.00 1e+018 2.0000
12 33.11 -4e+010 4.0000 TAFD35 1.91082 35.25
13 33.17 -92.1494 2.3500
14 33.09 -39.9735 2.5000 STIH10 1.72825 28.46
15 34.03 -85.4438 13.2476
4 16 35.22 184.1552 4.6000 SLAH96 1.76385 48.49
17 35.17 -68.0760 0.5000
18 33.00 44.4430 7.4000 SFPM3 1.53775 74.70
19 32.37 -57.1397 1.5000 STIH6 1.80518 25.42
20 32.09 -159.1922 1.0000
5 21 30.91 301.3443 1.5000 SNBH52 1.67300 38.15
22 29.87 31.5275 18.2616
23 34.00 -30.8186 1.5000 SNSL36 1.51742 52.43
24 37.76 -130.0211 0.5000
25 39.73 1275.4399 6.5000 TAFD35 1.91082 35.25
26 40.64 -49.8300 35.0000
6 27 60.00 1e+018 -33.0000
28 29.62 232.6593 4.5000 STIM28 1.68893 31.07
29 29.57 -51.6795 4.1500
30 27.76 -37.9548 1.2000 SLAH65VS 1.80400 46.53
31 28.56 26.1818 6.6000 SNBH5 1.65412 39.68
32 29.15 579.4296 5.6000
33 29.89 -32.2186 1.2000 TAFD45 1.95375 32.32
34 33.22 -590.9164 0.3000
35 34.81 338.0844 9.4000 SNSL36 1.51742 52.43
36 37.48 -32.9619 0.3000
37 40.66 -211.2193 7.6500 SBSL7 1.51633 64.14
38 41.83 -38.7354 12.2814
Img

(Numerical Example 2) (Rear attachment lens)
f = 139.80 F = 2.80 angle = 8.80 Y = 21.635
BS EA R d glass nd vd
6 1 60.00 ∞ -34.0000
2 30.02 115.9877 3.6000 LTIM28 1.68948 31.02
3* 29.86 -160.8553 3.6500
4 28.67 -129.2898 1.0000 TAFD30 1.88300 40.80
5 28.24 22.9193 7.7000 STIM28 1.68893 31.07
6 28.52 -325.2307 8.0000
7 28.93 -23.4773 1.2000 TAFD55 2.00100 29.13
8 32.88 -112.2037 2.3000
9 35.94 -118.3406 8.4000 SFSL5 1.48749 70.24
10 38.42 -29.0088 0.2000
11 42.26 -124.1290 6.6000 TAFD30 1.88300 40.80
12 43.56 -43.0690 10.7705
Img

Aspherical surface 3
r = -1.60855e+002
K = 0.00000e+000
A = -2.16358e-006
B = 1.24978e-009
C = -9.69077e-012
D = 2.00404e-014

(Numerical reference example 1) (Rear attachment lens)
f = 200.25 F = 5.72 angle = 6.17 Y = 21.635
BS EA R d glass nd vd
6 1 60.00 1e+018 -33.0000
2 23.18 308.4763 1.0000 SLAH89 1.85150 40.78
3 22.89 18.0290 7.2000 SNBH8 1.72047 34.71
4 23.00 -54.3214 7.5000
5 21.57 -30.5683 1.2000 SLAH65VS 1.80400 46.53
6 22.89 24.3680 9.4000 SNBH5 1.65412 39.68
7 23.77 -19.5554 1.0000
8 23.26 -19.3709 1.2000 TAFD45 1.95375 32.32
9 26.55 58.7309 8.5000 STIM2 1.62004 36.26
10 28.40 -24.7449 0.3000
11 29.30 -46.1174 1.5000 SLAM2 1.74400 44.79
12 31.60 172.0800 8.0000
13 40.24 800.0000 12.5000 SBSL7 1.51633 64.14
14 42.26 -28.7639 10.7751
img
It is assumed that the master lens ML with the surface numbers s1 to s26 of Numerical Example 1 is attached.

(Numerical Example 3) (Rear attachment lens)
f = 200.17 F = 4.00 angle = 6.17 Y = 21.635
BS EA R d glass nd vd
6 1 60.00 1e+018 -31.0000
2 22.62 61.7715 3.1500 SNBH56 1.85478 24.80
3 22.24 -848.1440 2.5000
4 21.05 96.5357 1.0000 SLAH58 1.88300 40.76
5 19.90 16.3502 0.9500
6 20.86 18.0000 8.8000 STIM25 1.67270 32.10
7 20.55 -21.6503 1.0000 TAFD45 1.95375 32.32
8 20.83 65.0179 2.5000
9 21.22 -71.2082 1.0000 SLAH58 1.88300 40.76
10 22.81 28.3480 11.0000 STIM8 1.59551 39.24
11 25.47 -20.0000 1.5000 TAFD45 1.95375 32.32
12 30.67 423.6680 1.2000
13 33.32 1073.8356 9.8000 STIL6 1.53172 48.84
14 36.30 -26.6847 0.2000
15 40.75 -96.2909 11.0000 SBSL7 1.51633 64.14
16 42.95 -27.9384 10.6865
img
It is assumed that the master lens ML with the surface numbers s1 to s26 of Numerical Example 1 is attached.

(Numerical Example 4) (Rear Attachment Lens)
f = 200.20 F = 4.00 angle = 6.17 Y = 21.635
BS EA R d glass nd vd
6 1 21.70 1e+018 -32.0000
2 22.80 81.5499 3.2000 STIM5 1.60342 38.03
3 22.54 -159.2407 0.7500
4 22.03 105.8002 1.0000 SLAH58 1.88300 40.76
5 20.79 14.3718 9.2000 STIM25 1.67270 32.10
6 20.66 -31.2980 1.0000 SLAH58 1.88300 40.76
7 20.81 85.1104 8.8000
8 22.76 -38.2927 1.0000 SLAH58 1.88300 40.76
9 24.38 84.3201 10.5000 STIM8 1.59551 39.24
10 26.62 -18.0000 1.2000 TAFD45 1.95375 32.32
11 31.78 -132.5183 2.6000
12 32.61 -45.0059 6.0000 SLAL12 1.67790 55.34
13 35.72 -27.6032 0.2000
14 41.93 -514.9956 10.8000 SBAL42 1.58313 59.37
15 43.50 -31.5822 10.6679
img
It is assumed that the master lens ML with the surface numbers s1 to s26 of Numerical Example 1 is attached.

(Numerical Example 5) (Rear attachment lens)
f = 200.17 F = 4.00 angle = 6.17 Y = 21.635
BS EA R d glass nd vd
6 1 60.00 1e+018 -32.0000
2 23.09 65.1772 3.2000 STIM28 1.68893 31.07
3 22.87 -74.4145 3.2000
4 21.12 -70.2712 1.0000 TAFD32 1.87070 40.73
5 20.44 16.7212 6.0000 STIM28 1.68893 31.07
6 20.49 729.0121 2.4000
7 20.54 -38.2802 1.0000 TAFD37 1.90043 37.37
8 21.88 27.9778 9.0000 STIM2 1.62004 36.26
9 23.19 -18.0000 0.8000
10 23.13 -16.6181 1.5000 TAFD55 2.00100 29.13
11 28.18 3765.6048 0.8000
12 29.22 -324.5649 10.0000 STIM8 1.59551 39.24
13 33.26 -23.7687 7.6000
14 42.46 -107.3812 10.0000 SBSL7 1.51633 64.14
15 44.03 -30.0000 14.5496
img
It is assumed that the master lens ML with the surface numbers s1 to s26 of Numerical Example 1 is attached.

(Numerical Example 6) (Rear attachment lens)
f = 140.05 F = 4.00 angle = 5.57 Y = 13.650
BS EA R d glass nd vd
6 1 60.00 1e+018 -22.0000
2 18.22 117.3822 3.5000 STIM28 1.68893 31.07
3 18.17 -27.6401 2.1500
4 17.09 -20.7062 1.0000 SLAH65V 1.80400 46.58
5 17.71 15.5408 4.3000 SNBH5 1.65412 39.68
6 18.10 -1362.5945 3.0000
7 18.49 -21.3503 1.0000 TAFD55 2.00100 29.13
8 20.61 1e+004 0.2000
9 22.08 90.9319 6.0000 SNSL36 1.51742 52.43
10 23.32 -19.8251 0.2000
11 24.49 -44.2778 4.2000 SLAL54 1.65100 56.16
12 25.63 -23.4041 10.7795
img
It is assumed that the master lens ML with the surface numbers s1 to s26 of Numerical Example 1 is attached.

(Numerical Example 7) (Rear Attachment Lens)
f = 199.91 F = 5.60 angle = 3.91 Y = 13.650
BS EA R d glass nd vd
6 1 60.00 1e+018 -22.0000
2 15.13 56.8990 2.8000 STIM28 1.68893 31.07
3 14.88 -44.8911 2.7000
4 13.53 -35.1499 0.7000 TAFD37 1.90043 37.37
5 13.26 9.8306 5.0000 STIH18 1.72151 29.23
6 13.56 262.0958 1.8000
7 13.64 -17.1933 0.7000 TAFD45 1.95375 32.32
8 15.42 25.3307 6.2000 STIM35 1.69895 30.13
9 17.31 -16.2429 3.2000
10 19.02 -25.3265 1.0000 TAFD45 1.95375 32.32
11 21.14 97.0709 6.0000 SBSL7 1.51633 64.14
12 23.69 -27.9646 0.3000
13 26.56 369.1436 9.0000 SFSL5 1.48749 70.24
14 28.27 -20.0000 10.5000
img
It is assumed that the master lens ML with the surface numbers s1 to s26 of Numerical Example 1 is attached.

Value of conditional expression in each example

ML Master lens EL Rear attachment lens Lr Positive lens L1 First positive lens

Claims (13)

A rear attachment lens in which the focal length of the entire system when the rear attachment lens is mounted on the image side of the master lens is longer than the focal length of the master lens,
The rear attachment lens has six or more lenses including a first positive lens, a first negative lens, and a second positive lens arranged in order from the most object side,
A positive lens Lr is arranged closest to the image side of the attachment lens, and a positive lens is arranged next to the positive lens Lr,
The positive lens Lr has a convex shape on the image side, the second positive lens has a convex shape on the image side,
fe is the focal length of the rear attachment lens, βe is the imaging magnification of the rear attachment lens when the rear attachment lens is attached to the master lens, and the rear attachment is the rear attachment when the rear attachment lens is attached to the master lens. When the distance from the lens surface closest to the image side to the rear principal point position is np2, and the lens thickness of the rear attachment lens is De,
|fe|/(fe×(1−βe)+np2)>9
2<|fe/De|≦27.5
A rear attachment lens that satisfies the following conditional expression: When the radius of curvature of the object-side lens surface of the positive lens Lr is R1, and the radius of curvature of the image-side lens surface of the positive lens Lr is R2,
-5.00<(R2+R1)/(R2-R1)<-0.85
2. The rear attachment lens according to claim 1, wherein the following conditional expression is satisfied. When the effective diameter of the positive lens Lr is φr,
1.8<φr/(fe×(1−βe)+np2)<20.0
3. The rear attachment lens according to claim 1, wherein the following conditional expression is satisfied. When the focal length fe is fe (mm) and the distance np2 is np2 (mm),
-5<1000 (mm)/(fe+np2)<5
4. The rear attachment lens according to any one of claims 1 to 3, wherein the following conditional expression is satisfied. When the focal length fe is fe (mm) and the distance np2 is np2 (mm),
-4 < 1000 (mm) / (fe × βe) < 4
5. The rear attachment lens according to any one of claims 1 to 4, wherein the following conditional expression is satisfied. 9<|fe|/(fe×(1−βe)+np2)≦177.7
6. The rear attachment lens according to any one of claims 1 to 5, wherein the following conditional expression is satisfied. 7. The rear attachment lens according to any one of claims 1 to 6, wherein the second positive lens is a biconvex lens. An imaging optical system having a master lens and a rear attachment lens detachably attached to the image side of the master lens,
The focal length of the entire system when the rear attachment lens is mounted on the image side of the master lens is longer than the focal length of the master lens,
The rear attachment lens has six or more lenses including a first positive lens, a first negative lens, and a second positive lens arranged in order from the most object side,
A positive lens Lr is arranged closest to the image side of the attachment lens, and a positive lens is arranged next to the positive lens Lr,
The positive lens Lr has a convex shape on the image side, the second positive lens has a convex shape on the image side,
When the focal length of the rear attachment lens is fe, the back focus when the rear attachment lens is attached to the master lens is BF, and the lens thickness of the rear attachment lens is De,
|fe/BF|>9
2<|fe/De|≦27.5
An imaging optical system characterized by satisfying the following conditional expression: 9<|fe/BF|≦142.9
9. The imaging optical system according to claim 8, wherein the following conditional expression is satisfied. 10. The imaging optical system according to claim 8, wherein the second positive lens is a biconvex lens. master lens and
A rear attachment lens according to any one of claims 1 to 7;
An image pickup device comprising an image pickup device for receiving an image formed by the rear attachment lens. An imaging apparatus comprising the imaging optical system according to any one of claims 8 to 10 and an imaging device for receiving an image formed by the imaging optical system,
Let φr be the effective diameter of the positive lens Lr, and let Yi be the maximum image height when the rear attachment lens is attached to the master lens.
1.8<φr/Yi<2.2
An imaging device characterized by satisfying the following conditional expression: When the effective diameter of the positive lens L1 is φ1 and the imaging magnification of the rear attachment lens when the rear attachment lens is attached to the master lens is βe,
1.85<φ1×βe/Yi<3.00
13. The imaging apparatus according to claim 12, wherein the following conditional expression is satisfied.

Images