JP2000227626A - Film unit with lens - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent a background from being photographed darkly in photographing with strobe light, especially, in a wide room or out of doors where illumination is little. SOLUTION: This film unit is equipped with a photographing lens 1, and a diaphragm plate 11 for changing the diaphragm value of a photographing lens. The plate 11 is constituted so that the diaphragm value of the lens 1 can be switched at least to the 1st diaphragm value and the 2nd diaphragm value at which a diaphragm aperture is larger than the 1st diaphragm value. Assuming that MTF of the photographing lens in the vicinity of an optical axis in spatial frequency 15.00 lines/mm at the 2nd diaphragm value when a subject distance is 4 m is M24, and the MTF of the photographing lens in the vicinity of the optical axis in the spatial frequency 15.00 lines/mm at the 2nd diaphragm value when the subject distance is 2 m is M22, the film unit satisfies conditional expressions 0.1<M24 and 0.1<M22.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a lens-equipped film unit having a built-in flash.

[0002]

2. Description of the Related Art Conventionally, since a film unit with a lens has been designed to be simple and inexpensive, it has no mechanism for adjusting the exposure, and the aperture is only the aperture of the taking lens. , Shutter speed is 1/12
It is about 5 speeds. The taking lens is composed of one or two plastic lenses, and the F value of the open aperture is 1
It is as dark as 0. Therefore, if an ISO 100 film is used, the shooting is limited to daylight sunny weather. Therefore, an ISO 400 film is mounted so that shooting can be performed with a little lower brightness.

For example, when the shutter speed is set to 1/125,
Assuming that the aperture is 11 in T number in consideration of the transmittance of the lens, the exposure amount in ISO 100 is EV14.
Therefore, when an ISO400 film is used, the EV value becomes 1
2 and relying on the latitude of film or photographic paper, it is possible to shoot from the daytime of fine weather to the dim morning and evening.

However, even in this case, it is impossible to take a picture indoors or at night. Therefore, there is a film unit with a lens which has a built-in strobe to enable low-brightness photography. But,
In a film unit with a lens, it is difficult to incorporate a large-capacity strobe because it hinders downsizing and increases the cost, so that the guide number in ISO 100 is usually about 10. For this reason, ISO400
Assuming that the shooting distance of the proper exposure is relatively short, 1.8 m, when the T number is set to 11 using the film described above, the shortage of the exposure amount up to EV1.5 can be compensated by the latitude of the film or the like. The limit is about 3.0 m.

[0005] In order to extend the photographing distance when using the strobe, a film unit with a lens loaded with an ISO800 film is commercially available. As a result, under the same conditions as above, the shooting distance for proper exposure is 2.5 m,
The shooting distance is 4.
Extend to 3m.

[0006]

In flash photography, since the photographing distance for proper exposure is one point, if a main subject such as a person is set at that distance, a subject at a shorter distance than that subject will be overexposed. However, the background subject at a long distance becomes underexposed. Since the film loaded in the film unit with the lens is a negative film, the latitude is wide in the direction of overexposure, and this does not cause much problem for a subject at a short distance. On the other hand, the background subject is not so far away when photographing in a small room such as at home, and the strobe light bounces on various objects to irradiate the background, so that the exposure is not less than the calculated exposure. In addition, since there is illumination other than the strobe light in a room such as a home, the underexposure of the background is also reduced by this.

[0007] However, flash photography is not limited to indoors such as at home, but is also performed in a large room such as a hotel lobby or outdoors with little illumination. In this case, if a main subject such as a person is placed at an appropriate shooting distance, the main subject will be properly exposed. However, if the background distance is several tens of meters, no strobe light reaches the background at all.

Conventional film units with lenses include I
Some have a built-in SO800 film.
The value is 10.3, the shutter speed is 1/110, and the guide number of the strobe is 11.6 in ISO100. Therefore, shooting with external light has proper exposure at EV10.5, and shooting with strobe light has proper exposure at a distance of 3.2 m.

2. The lens-equipped film unit is used in a large room such as a hotel lobby or outdoors with little illumination.
If the main subject is placed at a distance of 2 m and flash photography is performed, the main subject will be properly exposed. In addition, distant backgrounds where strobe light does not reach are exposed only by external light,
The latitude of the film is 1.5 EV at the underexposure side.
Therefore, if the distant background has the brightness of the EV9 rank, the background can be visually recognized even on the completed photograph. However, for example, if flash photography is performed when the brightness of a distant background is EV 8.5 or less, and printing is performed so that the main subject obtained by flash photography has an appropriate exposure, the background is darkly crushed on the photograph. In other words, a distant background that is reasonably visible to the human eye becomes completely invisible on the finished photograph.

The present invention has been made in view of such a problem, and in particular, in strobe photography in a large room or outdoors with little illumination, the aperture diameter is set so that the background is not darker than a conventional film unit with a lens. It is an object of the present invention to propose a lens-equipped film unit capable of photographing with a large aperture diameter.

[0011]

The above object is achieved by the following means.

A film unit with a built-in film and a strobe device is provided with a photographic lens and an aperture member for changing the aperture value of the photographic lens. The aperture value can be switched between at least a first aperture value and a second aperture value having a larger aperture than the first aperture value.
Spatial frequency 1 at the second aperture value at an object distance of
The MTF of the photographing lens near the optical axis at 5.00 lines / mm is M24, and the MTF of the photographing lens near the optical axis at the spatial frequency of 15.00 lines / mm at the second aperture value at an object distance of 2 m at the second aperture value. Is M22,
A film unit with a lens, characterized by satisfying the following conditional expression.

0.1 <M24 0.1 <M22

[0014]

DESCRIPTION OF THE PREFERRED EMBODIMENTS An embodiment of a film unit with a lens according to the present invention will be described in detail with reference to FIGS.

FIG. 1 is an external perspective view of a film unit with a lens. On the front, a taking lens 1, a finder window 2, a strobe light panel 3, a strobe switch lever 4
, A release button 5, an indexer window 6, and a charging display window 7 are arranged on the upper surface, and a hoisting knob 8 is arranged on the rear surface. Here, when performing flash photography, when the flash switch lever 4 is slid rightward in the figure, the internal main switch is turned on, and charging of the flash is started. When the internal main capacitor is charged to a predetermined voltage, the charging state can be visually recognized by lighting the charging display window 7. The photographer can press the release button 5 for shooting. In addition,
When the strobe switch lever 4 is slid rightward as shown in the figure, the tip 4a projects rightward, and it can be easily determined that the main switch has been turned on.

Next, a description will be given of a configuration in which the aperture and shutter speed are switched between a normal photographing state in which no flash is used during the daytime and a flash photographing state with reference to FIGS.

FIG. 2 is a perspective view of a configuration for switching the aperture. Reference numeral 11 denotes an aperture plate. A large aperture 11a and a small aperture 11b each having two through holes are provided substantially at the center. In FIG. 1, the large aperture 11a is located behind the photographing lens 1, and has a T-number, for example. 7.3 is formed.

The strobe switch lever 4 shown in FIG. 1 is fixed to the right arm 11c of the diaphragm plate 11, and two elongated holes 11d formed in the lateral direction of the diaphragm plate 11 are fixed to a fixed body such as a unit body. Guide pins 12 erected from above are fitted. Therefore, by the sliding operation of the strobe switch lever 4, the diaphragm plate 11 slides in the left-right direction. In addition, inverted V-shaped notches 11e and 11f are provided at the lower portion of the diaphragm plate 11, and the inverted V-shaped tip of the leaf spring 13 is pressed against these notches.
It is positioned at several locations.

Reference numeral 15 denotes a strobe unit. Reference numeral 151 denotes a printed circuit board on which a strobe circuit is mounted. Reference numeral 152 denotes a strobe light emitting unit that emits strobe light and emits strobe light from the strobe light panel 3 of FIG. On the back surface of the arm portion 11c of the aperture plate 11, a contact piece 16 whose tip branches into two branches and operates as a main switch of the strobe is provided, and the tip of the contact piece 16 is pressed against the surface of the printed circuit board 151. . Here, in FIG. 2, since the tip of the contact piece 16 is in contact with both the conductive patterns 151a and 151b forming the main switch on the printed circuit board 151, the conductive patterns 151a and 151b are conductive, and The switch is on. Accordingly, the flash is charged and flash photography is possible, and the aperture is the large aperture 11a, which is an open aperture, so that a sufficient flash photography distance can be obtained.

Next, the flash switch lever 4 is slid to slide the aperture plate 11 to the left. Then, the tip of the inverted V-shape of the leaf spring 13 stops in a state of being pressed against the notch 11f, and the small aperture 11 is located behind the photographing lens 1.
b (for example, 13.4 in T number) is located. Further, since the tip of the contact piece 16 is separated from the conductive patterns 151a and 151b on the printed circuit board 151, the conductive patterns 151a and 151b become non-conductive and the main switch is turned off. Accordingly, a photographing state suitable for high-brightness photographing during the daytime or the like is obtained.

With respect to the configuration of the above-mentioned aperture plate 11, a fixed aperture is provided in the optical path of the taking lens L, and the large aperture 1 is provided.
1a is formed to have a diameter larger than the fixed stop,
The portion a may be cut out.

Next, a configuration for switching the shutter speed by sliding the strobe switch lever 4 will be described with reference to FIGS. FIG. 3 is a front view showing a state where shutter charging has been completed, and FIG. 4 is a front view showing an opening of the sector.

In FIG. 3, the sector 21 rotates about a support shaft 22 and is urged clockwise by a tension spring 23. Therefore, when stationary, the terminal 21 of the sector 21
a is in contact with the stopper 24 and the sector 21
Closes an opening 26 through which subject light to the film passes. Note that the sector 21 corresponds to the diaphragm plate 11 shown in FIG.
It is located behind.

At the time of shutter charge, the charge lever 25 moves from left to right in FIG. At this time, the hole 2 of the sector 21 fitted with the support shaft 22
1c is formed in a long hole, so that the charge lever 25
, The tip 21b is pushed and the sector 21 moves slightly downward, but does not open the opening 26 at all.

When the user presses the release button 5 shown in FIG. 1 after the shutter is charged as shown in FIG. 3, the charge lever 25 is rapidly moved to the left by a charge spring (not shown), Since the right side of the tip 21b is hit, the sector 21 rotates counterclockwise to open the opening 26 as shown in FIG. The sector 21 rotates by a predetermined angle due to inertial force against the urging force of the tension spring 23, and then stops by contacting a stopper 27 erected on the diaphragm plate 11, and then the urging force of the tension spring 23. To rotate clockwise to close the opening 26.

Here, when the diaphragm plate 11 slides to the left and the main switch of the strobe is off, the stopper 27
4 is in contact with the sector 21 at a position 27a indicated by a solid line in FIG. 4, and the shutter speed is high (for example, 1/125), but the diaphragm plate 11 slides rightward as shown in FIG. ,
When the main switch of the strobe is on, the stopper 27 moves to the position 27b shown by the two-dot chain line in FIG. 4 and does not come into contact with the sector 21, so that the shutter speed becomes low (for example, 1/80).

As described above, in the normal photographing state in which the flash photography is not performed, the aperture is small (13.4), the shutter speed is high (1/125), and when the flash photography is performed, The aperture becomes large (7.3) and the shutter speed becomes low (1/80).

Here, in the film unit with a lens of the present embodiment, the film to be loaded in the manufacturing process in advance is a negative film of ISO800. The taking lens 1 realizes an open aperture of 7.3 in the T number which is a large aperture for a two-lens plastic lens, and the guide number of the strobe is 7 in ISO100.

The EV value when a film of ISO 100 is used can be expressed by the following equation.

EV = log (F ² / T) / log 2 where F: T number of a photographing lens at the time of photographing,
T: shutter speed.

Further, in consideration of the ISO sensitivity (S) of the film loaded in advance, the EV value converted to the EV value when using a film of ISO 100 is given by the following equation.

EV = [log ₁₀ F ² + log ₁₀ (1 /
T) −log ₁₀ (S / 100)] / log ₁₀ 2 Therefore, in this specification, the EV value converted to the EV value when a film of ISO 100 is used is defined as the EV value of the reference exposure amount.

In the present embodiment, the aperture is set to 13.
4. Since the shutter speed is 1/125, the ISO 10
Although the EV value when the film of No. 0 is used is EV 14.5, since the sensitivity of the film is ISO800, the EV value of the reference exposure amount is substantially EV 11.5.

In flash photography, the iris is 7.3 in T number, and the guide number of 7 in ISO 100 is 19.8 when converted to ISO 800. Therefore, the shooting distance at which an appropriate exposure is obtained is 19.8 /
7.3 = 2.7 m. That is, an 18% reflector having a reflectance of 18%, which is generally called a standard reflector and is set based on the reflectance of the skin of an average person, is referred to as “2.
When placed at 7 m, this reflector is exposed in a properly exposed state.

Incidentally, if it is allowed to underexposure up to EV1.5, the maximum photographing distance is 4.6 m. Therefore, a sufficient photographing distance can be obtained despite the use of a small strobe having a smaller guide number, that is, a strobe having a small light amount.

On the other hand, in flash photography, the exposure amount for the background to which the flash light does not reach is 7.
Since the shutter speed is determined only by the aperture of 3 and the shutter speed of 1/80, the EV value when using a film of ISO100 is EV12.1 from the above equation.
800, the EV value of the reference exposure amount is substantially EV
9.0.

Therefore, the background farther than the maximum photographing distance in the flash photographing is exposed at the reference exposure amount of EV 9.0, and the latitude of the film is shifted toward the under-exposed side by E.
Since the V value is about 1.5, the background will not be darkened on a completed photograph up to EV 7.5 which is darker than the conventional one.

In the case of a film unit with a lens, the closest shooting distance is usually set to 1 m.
The exposure amount of the subject by the strobe light when the subject is strobed with an 18% reflective plate of m is equivalent to EV12, the brightness difference from the background is within the latitude EV4.5 of ordinary photographic paper, and EV7.5. Can be reproduced on the print.

When only the dimly lit scenery of the morning and evening is photographed, it does not matter at all whether the flash is fired. However, if the aperture is opened in the flash photography state, the photograph is taken with EV 9.0, so that it is sufficiently appropriate. You can get a picture of the exposure.

As described above, when the film unit with the lens is configured to be able to switch between the flash photography state and the normal photography state, it is determined by the aperture value, the shutter speed, and the sensitivity of the loaded film in the flash photography state. Assuming that the EV value of the reference exposure amount converted to the film sensitivity of ISO 100 is A, A is configured to satisfy A ≦ 10.

As described above, the EV value of the reference exposure amount can be obtained by the following equation.

EV = [log ₁₀ F ² + log ₁₀ (1 /
T) -log ₁₀ (S / 100)] / log ₁₀ 2 where F is the T number of the taking lens, T is the shutter speed (second), and S is the ISO sensitivity of the film.

The T number F of the taking lens, the shutter speed T (second), and the ISO sensitivity S of the film are respectively
It is desirable to set within the range of F ≧ 5.6, T = 1/100 to 1/30, and S ≧ 640.

It is desirable that the T-number of the photographing lens at the time of flash photography is set to 9 or less so that the condenser capacity of the flash can be made as small as possible.

Further, a strobe having a light amount such that an object at a predetermined distance within a range of 2 to 3 m is properly exposed is selected in accordance with the ISO sensitivity of the film to be loaded and the aperture value in the strobe photographing state.

As described above, a predetermined distance of 18 m
By using a strobe with a light amount that allows the subject composed of the percent reflector to be properly exposed, the light amount of the subject at a distance of 1.1 m, which is the closest shooting distance, becomes A + 3 or less in EV value, and the subject at a distance of 1.1 m And a low-luminance subject with an EV value of A-1.5 are compared with EV, which is the latitude of photographic paper.
The value can be within the luminance range of 4.5, and it is possible to simultaneously reproduce a subject within the flash photographable distance range of 1.1 m or more and a low-luminance background subject on a print.

It should be noted that, specifically, it is desirable to select a strobe having a guide number of 2 to 9 as a guide number converted into an ISO 100 film so that the capacity of the condenser can be reduced as much as possible.

If the EV value A exceeds 10 under the condition that the EV value in the flash photography state is A, the main subject of 2 to 3 m and the EV of less than or equal to 8.5 in photography under night illumination in the flash photography state. It becomes difficult to obtain a print in which the background of a room with a wide brightness is in a good exposure state. Note that the upper limit of the EV value A is preferably set to 9.5.

It is desirable that the lower limit of the EV value A is 4. In order to set the reference exposure amount to low brightness, it is necessary to use a larger-diameter photographing lens, but it is difficult to use a film unit with a lens that is limited in cost, so using a high-sensitivity film It is conceivable to reduce the shutter speed. However, when the shutter speed is set to a low speed, camera shake occurs. Generally, the limit of the shutter speed at which camera shake is suppressed is that the focal length of the photographing lens is 30 mm.
Is assumed to be 1/30. Therefore, even if a film with a sensitivity of ISO 6400 is loaded, the EV becomes 3.9 if the shutter speed is 1/30 and the aperture is 5.6 in T number.
A value of 4 is the limit.

When these conditions are summarized, the EV value A is preferably 4 ≦ A ≦ 10, more preferably 4 ≦ A ≦ 9.5.

Also, an IS determined by an aperture value, a shutter speed, and a sensitivity of a loaded film in a normal photographing state.
Assuming that the EV value converted to the film sensitivity of O100 is B, B is desirably configured to satisfy A + 1 ≦ B and 9 ≦ B.

Further, the upper limit of the EV value B is the above EV value.
It is desirable to satisfy the relationship with the value A and set to 13 or less.

Next, desirable conditions for the photographing lens to be used will be described. In the following description, the aperture value of the photographing lens will be described with an F number, but the relationship between the F number and the T number will be described below in the case of an embodiment in which a photographing lens described later is configured with two plastic lenses. Become.

T number ≒ 1.085 × F number The aperture value of the taking lens to be used can be switched between at least a first aperture value and a second aperture value having a larger aperture than the first aperture value. At an object distance of 4 m, the MTF of the imaging lens near the optical axis at a spatial frequency of 15.00 lines / mm at the second aperture value is M24, and a spatial frequency of 15.00 at the second aperture value at an object distance of 2 m.
The MTF of the photographing lens near the optical axis at this line / mm is M2
When 2, the following conditional expression is satisfied.

0.1 <M24 (1) 0.1 <M22 (2) More preferably, the taking lens to be used is composed of two lens components, a first lens and a second lens, and an aperture from the object side, and When the open F number of the taking lens is F _O (corresponding to the second aperture value), it is desirable that the configuration satisfy the following conditional expression.

5.6 <F _O <8 (3) More preferably, when the condition (3) is satisfied, the half angle of view of the taking lens is ω, and the focal length is f, the following conditional expression is satisfied. Configuration.

5 <f / (F _O · tan ω) <7 (4) More preferably, the condition (3) is satisfied, and the F number of the photographing lens is such that the spherical aberration of the marginal ray of F is SA.
Assuming that (F) and half of the length of the photographing screen in the long side direction is y _L , the configuration satisfies the following conditional expression.

−0.072 y _L <SA (F _O /0.7)<−0.024 y _L (5) More preferably, the condition (1) is satisfied and the F number of the photographing lens at the time of flash photography is F _{When O} is set and the F number in the normal photographing state is set to F _Off (corresponding to the first aperture value), the following conditional expression is satisfied.

0.4 <F _O / F _Off <0.7 (6) More preferably, the conditions of (3) and (6) are satisfied, and the spherical aberration of the marginal ray with the F number of the photographing lens of F is set to SA. (F), half of the length of the shooting screen in the long side direction is y
_{When L} is set, the configuration satisfies the following conditional expression.

−0.008F _Off · y _L <SA (F _O ) <− 0.003F _Off · y _L (7) and −0.072y _L <SA (F _O /0.7)<−0.024y _L (8) In the above configuration, each conditional expression will be described.

First, in the case of a film with a lens, photographing is performed without performing focus adjustment. However, even if the aperture is switched by using a photographing lens, good image quality can be obtained at each aperture value according to the photographing conditions. It is necessary to be able to take pictures so that a photograph can be obtained. Conditional expressions (1) and (2) are conditions for this. If the lower limit of conditional expressions (1) and (2) is exceeded, a photograph of good image quality can be obtained in the flash photography assumed with the second aperture value. Disappears.

If the upper limit of conditional expression (3) is exceeded, sufficient exposure for a low-luminance object cannot be obtained. In other words, when flash photography is performed in the shade of a tree, at sunset, or indoors, the illumination of the flash light on the background, which is a long-distance subject, is reduced, so that the exposure is insufficient and a high-quality photograph cannot be obtained. On the other hand, if the lower limit of conditional expression (3) is not reached, the two lenses cannot sufficiently correct various aberrations including spherical aberration, and the depth of focus becomes too shallow, resulting in field curvature and manufacturing time. The effect of the back focus error and the mounting error at the time of assembling the lens is too large, so that the photograph often becomes poorly focused.

When a photographic lens is formed by using three lenses, unless each lens is provided with an anti-reflection coating, the transmitted light becomes about 79% of the light incident on the lens, and the transmitted light on the refracting surface is 2%. The ratio of flare light that reaches the screen after being reflected more than once reaches 2.2% of the transmitted light, which is undesirable. To prevent this, it is necessary to coat at least one lens with an anti-reflection coating, and cost increases can be avoided. Absent. on the other hand,
In the case of two lenses, even without applying an anti-reflection coat,
The transmitted light is about 85%, and the flare light is
It is as small as 0.86%, which is sufficient. Therefore, the lens
Constructing with one piece is cost and lens performance comprehensive,
It is most suitable as a taking lens of a film unit with a lens.

Conditional expression (4) is a condition for obtaining a sufficient depth of field as a fixed focus camera with a taking lens having an open F-number of conditional expression (3). Conditional expression (4)
If the upper limit is exceeded, the depth of field becomes too shallow, whereas if it falls below the lower limit, the lens becomes too wide-angle, and the peripheral light quantity becomes insufficient due to the cosine fourth law, and the effect of the perspective becomes poor. It is not preferable because it tends to be too large and uncomfortable.

It is preferable that the photographic lens satisfies the conditional expression (5) due to insufficient correction of spherical aberration. If the upper limit of conditional expression (5) is exceeded, spherical aberration is excessively corrected, the center focus position approaches the ideal image plane position, and the difference from the focus position of the off-axis light flux, that is, the influence of field curvature increases, which is preferable. Absent. When the value goes below the lower limit of conditional expression (5), the spherical aberration is undesirably too large.

When the F-number of the lens is changed so as to satisfy the conditional expression (6), overexposure does not occur even in a sunny day outdoors where the subject brightness is high, and the F-number becomes small in an indoor location where the subject brightness is insufficient. The strobe light reaches even if the guide number of the strobe is relatively small,
Exposure of a subject at a longer distance than the background can be sufficiently obtained. If the upper limit of conditional expression (6) is exceeded, the difference between F _O and F _Off is too small to obtain a sufficient effect. Conversely, if the value falls below the lower limit, there is too much difference in the T number, so that exposure of a subject whose luminance is intermediate is likely to be inappropriate regardless of which one is selected.

When the condition (6) is satisfied and the above-mentioned photographic lens satisfies the conditional expression (5), it is possible to satisfactorily correct various aberrations when the lens is opened as described above.

Further, satisfying the conditions (3) and (6),
If conditional expression (7) is satisfied, an appropriate depth of field can be obtained both when the strobe is used and when it is not used. If the upper limit of conditional expression (7) is exceeded, the open F-number F
Spherical aberration is small at the _O, less the amount of displacement of the best focus position when focused on F _Off, when the auxiliary light by the strobe light so that the depth of field to enter the well within reach when opened, narrowed down to F _Off This is not preferable because the resolution of a distant subject is not sufficiently improved. Displacement is too large the best focus position when focused on F _Off When falls below the lower limit of the inverse of conditional expression (7), the resolution of the near object can not be sufficiently obtained when focused on F _Off.

It is to be noted that the conditional expression (2) satisfies 0.2 <M2
It is desirable to satisfy Condition 2.
It is desirable to satisfy the condition of 0.2 <M24.

[0070]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the taking lens will be described below. The symbols in each embodiment are as follows.

F _O : The open F number of the photographing lens, the F number when using the flash F _Off : The F number in the normal photographing state f: The focal length of the photographing lens ω: Half angle of view r: The radius of curvature of the refraction surface d: distance between refraction surfaces N _d : refractive index at d-line ν _d : Abbe number y _L : half of the length in the long side direction of the photographing screen U: distance between object and image The aspherical surface used in the present invention The shape is represented by the equation (1), where the coordinate is the x-axis in the optical axis direction and the height in the direction perpendicular to the optical axis is h.

[0072]

(Equation 1)

In Equation 1, K is the conic constant of the aspheric surface, A
_2i indicates an aspheric coefficient (i = 2, 3, 4, 5, 6).

In the figure, ΔS represents sagittal, and ΔM represents meridional.

(Example 1) FIG. 5 is a sectional view of a lens optical axis.
FIG. 6 shows a lens aberration diagram. Table 1 shows the lens data.
Shown in

[0076]

[Table 1]

Where f / (F _O tan ω) = 6.0 SA (F _O /0.7)/y _L = −0.044 F _O / F _Off = 0.42 to 0.67 SA (F _O ) / (F _Off · y _L ) = − 0.0042 to −
0.0067 FIGS. 7 and 8 show that the aperture 2 (AP2) disposed on the film side of the second lens L2 is a variable aperture and F _Off is 13,
The distance between the final surface of the taking lens and the image screen is 25.8 mm
The MTF at each subject distance in the long side direction of the screen when the imaging surface is a cylindrical surface having a curvature radius of 110 mm and the aperture is F _O is shown. Similarly, FIGS. 9 and 10 show MTF diagrams at each subject distance in the long side direction of the screen when the aperture is reduced to F _Off .

As shown in the MTF diagrams of FIGS.
Spatial frequency 15.00 at _O (corresponding to the second aperture value)
MT near the optical axis at a subject distance of 4 m in lines / mm
M24, which is F, is about 0.25, and M22, which is the MTF near the optical axis at a spatial frequency of 15.00 lines / mm at an object distance of 2 m, is about 0.4. The focus is good for a subject from 1 m to 4 m, and as shown in the MTF diagrams of FIGS.
The focus is good from 1 m to infinity. In addition, the MTF value itself is sufficient, and a photograph of good image quality can be obtained.

The variable stop can be the stop 1 (AP1) between the first lens L1 and the second lens L2.

(Embodiment 2) FIG. 11 shows a sectional view of the lens optical axis, and FIG. 12 shows a lens aberration diagram. Table 2 shows lens data.

[0081]

[Table 2]

Where f / (F _o · tan ω) = 6.16 SA (F _o /0.7)/y _L = −0.044 F _o / F _Off = 0.42 to 0.67 SA (F _O ) / (F _Off · y _L ) = − 0.0040 to −
(Example 3) FIG. 13 is a sectional view of the lens optical axis, and FIG. 14 is a lens aberration diagram. Table 3 shows the lens data.

[0083]

[Table 3]

Where f / (F _O · tan ω) = 6.12 SA (F _O /0.7)/y _L = -0.044 F _O / F _Off = 0.42 to 0.67 SA (F _O ) / (F _Off · y _L ) = − 0.0040 to −
0.0064

[0085]

According to the film unit with a lens according to any one of claims 1 to 4, it is possible to produce a crushed photograph with a dark background in a strobe photographing in a particularly large room or outdoors with little illumination. And a good photograph can be obtained at each subject distance.

[Brief description of the drawings]

FIG. 1 is an external perspective view of a film unit with a lens.

FIG. 2 is a perspective view of a configuration for switching aperture plates.

FIG. 3 is a front view showing a state where shutter charging is completed.

FIG. 4 is a front view in which a sector has an opening.

FIG. 5 is a sectional view of a lens optical axis according to the first embodiment.

FIG. 6 is a lens aberration diagram of the first embodiment.

FIG. 7 is a diagram of MTF in F 2 _O of Example 1.

FIG. 8 is a diagram of MTF in F 2 _O of Example 1.

FIG. 9 is a diagram of an MTF at F _Off in the first embodiment.

FIG. 10 is a diagram of an MTF at F _Off in the first embodiment.

FIG. 11 is a sectional view of a lens optical axis according to a second embodiment.

FIG. 12 is a lens aberration diagram of the second embodiment.

FIG. 13 is a sectional view of a lens optical axis according to a third embodiment.

FIG. 14 is a lens aberration diagram of the third embodiment.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Shooting lens 3 Strobe light emission panel 4 Strobe switch lever 11 Aperture plate 11a Large aperture 11b Small aperture 15 Strobe unit 151 Printed circuit board 21 Sector 27 Stopper

──────────────────────────────────────────────────続 き Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat ゛ (Reference) G03C 3/00 575 G03C 3/00 575B 585 585Z (72) Inventor Yoshichika Noda 1 Sakuracho, Hino City, Tokyo Konica Corporation In-house F term (reference) 2H053 AD00 AD01 AD21 DA00 2H087 KA02 LA01 PA02 PA17 PB02 QA02 QA07 QA12 QA21 QA32 QA34 QA41 RA12 RA32 RA35 UA01 2H101 AA01

Claims (4)

[Claims] 1. A film unit with a built-in film and a strobe device, comprising: a photographing lens; and a diaphragm member for changing a diaphragm value of the photographing lens. The aperture value of the lens can be switched between at least a first aperture value and a second aperture value having a larger aperture than the first aperture value, and the spatial frequency at the second aperture value at an object distance of 4 m The MTF of the photographing lens near the optical axis at 15.00 lines / mm is M24, and the MTF of the photographing lens near the optical axis at the spatial frequency of 15.00 lines / mm at the second aperture value at an object distance of 2 m at the second aperture value. Wherein M22 is satisfied, and the following conditional expression is satisfied: 0.1 <M24 0.1 <M22 2. At an object distance of 2 m, M22, which is the MTF of the photographic lens near the optical axis at a spatial frequency of 15.00 lines / mm at the second aperture value, satisfies the following conditional expression. The film unit with a lens according to claim 1, wherein: 0.2 <M22 3. The photographing lens is composed of two lenses, a first lens and a second lens from the object side, and an aperture member for changing an aperture value of the photographing lens is the second lens. The lens-equipped film unit according to claim 1, wherein the film unit is disposed on the film side. 4. The photographing lens is composed of two lenses, a first lens and a second lens, from the object side, and an aperture member for changing an aperture value of the photographing lens is the first lens. 3. The lens-fitted film unit according to claim 1, wherein the film unit is disposed between the first lens and the second lens. 4.