JPS6323116A - Conversion lens - Google Patents

Abstract

PURPOSE:To correctly transmit the focal distance information of an interchangeable lens to a camera body side, by properly correcting the focal distance information of the interchangeable lens in accordance with the magnification of a conversion lens. CONSTITUTION:The protruding quantity of the signal member 12 of an interchangeable lens 10 is transmitted to the input branch 17a of a camera-side lever 17 after it is magnified M times by an intermediate lever 31 provided in the body tube section of a rear conversion lens. The intermediate lever 31 is supported by a pin 32 under a slidable condition and forced to move leftward by a spring 33. In such way, the focal distance information of the interchangeable lens 10 is transmitted after it is magnified M times between the input branch 17a and intermediate lever 31 through the rear conversion lens whose magnification is M. Therefore, the difference between the protruding quantity of the signal member 12 when the interchangeable lens 10 is provided with no rear conversion lens and the protruding quantity of the intermediate lever 31 when the lens 10 is provided with the rear conversion lens becomes equal for any interchangeable lenses.

Description

DETAILED DESCRIPTION OF THE INVENTION The present invention relates to a conversion lens that can be freely attached and detached between an interchangeable lens and a camera body.

When a conversion lens is attached between the interchangeable lens and the camera body, the focal length information of the interchangeable lens changes depending on the magnification of the conversion lens. An object of the present invention is to provide a conversion lens having a correction means for correcting the focal length information according to the magnification.

Before describing two embodiments of the conversion lens of the present invention, the basic relationship between the interchangeable lens and the camera will be explained.

In FIG. 1, 9. A bayonet type lens mount 11 is fixedly mounted on the rear end surface of the lens 10 body.

Further, near the lens mount 11, a signal member 12 fixed to a fixed cylinder (not shown) protrudes. This signal member 12 protrudes from the reference plane by a predetermined amount depending on the focal length of the interchangeable lens. The interchangeable lens 10 has a focusing ring 13 and a preset aperture ring 14.

- On the camera body side, a mechanism for extracting focal length information from the signal member 12 is arranged on one side of the mirror box 15. That is, the input branch 17α of the detection lever 170, which is rotatably supported by the shaft 16 installed in the mirror box 15, can be engaged with the signal member 12. The lever 11 is biased counterclockwise by the spring 18, and the position where the stopper 19 and the branch lever 17b abut (as shown in the first figure) is the initial position f of the lever 17.
l (state before attaching the tab and interchangeable lens).

Further, a brush 20 made of three conductors is arranged on the branch lever 17C of the lever 17. These three conductors correspond to the three rows of digital code patterns 21 printed on the board 21.
G.

It is designed to slide on 21A and 21C. This brush 20 and digital code patterns 21α, 21jS,
21cm is a conversion unit that converts focal length information into a digital signal. Note that specific electrical connections are omitted.

Now, when the interchangeable lens 10 is attached to the camera body, the signal member 12 and the input branch 17CL come into contact with each other, so that the detection lever 17Vi can be rotated clockwise against the bias of the spring 18.

Here, this amount of rotation corresponds to the amount of protrusion of the signal member 12, that is, the focal length information. As a result, brush 20 also lever 1
The signal member 12 slides on the digital code pattern according to the amount of rotation of the signal member 12, and stops at a predetermined position corresponding to the amount of protrusion of the signal member 12 (this state is shown by a solid line in FIG. 2). The positional relationship between the brush 20 and the code pattern is extracted as a digital electric signal corresponding to the focal length of the interchangeable lens attached to the camera by an electric circuit (not shown), and the circuit that requires focal length information (input) .This circuit is
For example, the program exposure control circuit (Japanese Patent Laid-Open No. 50-2903
An example of this is the one disclosed in Japanese Patent No. 4) in which the program characteristics are changed depending on the focal length of the interchangeable lens. This program characteristic places emphasis on increasing the shutter speed in order to eliminate the effects of camera shake for intertwisted lenses with long focal lengths, and also places emphasis on narrowing down the aperture of some types of interchangeable lenses. can be rearranged into

As described above, focal length information can be transmitted from the interchangeable lens to the camera.The signal components of each interchangeable lens, which are scattered over a focal length range from several M to several thousand 1, are installed as follows. It's visible. That is, the amount of protrusion of the signal member relative to a predetermined reference plane is set in relation to the logarithm of the focal length of the interchangeable lens. Specifically, it is proportional to the logarithm of the focal length or the logarithm of the reciprocal of the focal length.

In Figure 3, where the vertical axis shows the protrusion amount of the signal member of the interchangeable lens, and the horizontal axis of the logarithmic scale shows the focal length of the interchangeable lens, point A is the maximum protrusion amount of the signal member to be punched due to design. Point B indicates the intersection with the maximum focal length of the interchangeable lens that needs to transmit focal length information to the camera, and point B indicates the intersection between the minimum protrusion and the focal length. Therefore, straight line AE
The slope of can be arbitrarily selected based on the design. The straight line between these two points represents the focal length of each interchangeable lens and the amount of protrusion of the signal member. This amount of protrusion corresponds to the amount of movement of the input branch 17g. Then, these two points are A (Z1%yl
), B m, yz), the equation of the line AB is '/z 9ty y-yt -,, -2-oq,, (1ayx-1o
yx1). Here, arbitrary two points P (Px, Py) corresponding to the focal lengths of two different types of interchangeable lenses,
QCQ:c%Qy) is written on the straight line AB. However, Q
x = MPx (M-focal length magnification), Q'1-P
Let y=1.

Next, pick an arbitrary point P' directly on tsAE, and set the x coordinate to (P's = Pxr +x) and the corresponding y coordinate to tp'y>. And the ym mark (
y coordinate (Q'y= P'y+
Let Q' be a point on the direct mAE having the corresponding two coordinates <q'x>. In this way, Q' y −P' y =m (la g Q'x −
lo yxl)-rn (logp'x-lags,
) Q/J = employment '7 =! (However, the door is represented by the slope of the straight line AE as −l ogx2−1 o 1xl.) Here, since Qx: = MPx, Qy −Py
= 1 Qx """7'i = mlogM. Next, ' = loyM and substitute this into equation (1) (2/z, , = M - (21). Therefore, for a certain focal length The difference in the amount of protrusion of the signal member when multiplied by the focal length I with respect to any point on the straight line AH can be easily determined between any interchangeable lenses.

Therefore, even if the amount of protrusion of the signal member 12 is related to the logarithm of the focal length, there will be no problem in transmitting information between the interchangeable lens and the camera body. Not only that, but the amount of protrusion of the signal member 12 varies depending on the focal length of 10, 100, 1000, etc. As the distance increases, the distance changes to 1 vm, 2 M, and 3 rm in Figure 3, so the protrusion amount on the short focal length side is relatively expanded, and as a result, when the focal length is in the range of 10 to 1100t, The error in reading the focal length information of a large number of scattered interchangeable lenses is reduced.

In other words, if the relationship between the focal length and the amount of protrusion of the signal member 12 is processed in a simple proportional manner, the amount of protrusion of the signal member for a focal length of several U to several thousand W is a short focus within the range allowed by design. This means that less light can be distributed on the distance side and more on the long focal length side. This means that focal length 8.10.15.
16.20.24.28.35.45.50,55.8
Considering the fact that 5.105m interchangeable lenses are already on the market, this is extremely unreasonable.On the other hand, the long focal length side VC is 200.300.400.500.10
There are only interchangeable lenses such as 00° and 2000 lenses. Therefore, on the short focal length side where the distribution of the protrusion of the signal member 12 is small, a large amount of information is condensed into this small amount of protrusion], the input branch 17α,
The brush 201 is broken because the reading error due to the digital needle pattern etc. becomes large.

The above is also true when the rear conversion lens is attached to an interchangeable lens and the focal length is multiplied by M ((In this case, the interchangeable lens and rear conversion lens are considered as one interchangeable lens. be able to.

Next, a conversion lens according to an embodiment of the present invention will be described.

The following description will be made on the assumption that the interchangeable lens 10 has a focal length of point P in FIG. 3, and when equipped with a rear composite lens, the focal length becomes the same point Q.

In FIG. 4, the amount of protrusion of the signal member 12 of the interchangeable lens 10 is multiplied by M by the intermediate lever 31 located at the lens barrel of the rear conversion lens.
The signal is transmitted to the input branch 17α. Now intermediate lever 3
1 is slidably supported by a bottle 32 and biased to the left in the figure by a spring 33.

In Figure 4 VC, σ) is the reference position of the input branch 17α without a lens attached, and ■ is the input branch 17α when the lens 10 is attached to the camera body.
The position of ■ is the input branch 17α when the M-times rear converter is attached.
The position of each is shown.

The difference between position ■ and position ■ is the change in magnification (change in focal length) due to the addition of the rear conversion lens.

In this way, the focal length information of the father conversion lens 10 is transmitted between the input branch 17α and the intermediate lever 31 via the rear conversion lens multiplied by y. Therefore, since Qx = MP = τ is established in Figure 4, 51: protrusion amount of the signal member 12 when the interchangeable lens 10 is a single unit, and the rear conversion lens is installed in the interchangeable lens 10. The difference between the amount of protrusion of the intermediate lever 31 and the amount of protrusion when doing so is the same for any interchangeable lens.

FIG. 5 shows another embodiment of the invention, in which interchangeable lenses with close focal lengths are divided into several small groups (for example, focal lengths 6~10 rz; 15 pills 241r).
6) Install a signal member having a common protrusion amount for the replacement lenses of this small group. Of course, the amount of protrusion of this signal member is the straight line AB (3rd line) in Figure 5.
Existing on the same location as shown. By doing this, for example, the focal length is 200
For lenses that are at risk of camera shake, such as interchangeable lenses with a range of between 500m and 500m, it is not very effective to change the program characteristics mentioned above individually. Even if one program characteristic is set, favorable results can be obtained in terms of circuit configuration or photographing.

Note that the signal member 12 is not limited to the amount of protrusion from the reference position, but has various aspects such as the rotation angle from the reference position.

In addition, since the focal length of a zoom lens changes with zooming, the signal member may be protruded and retracted Vi in accordance with zooming to correspond to the logarithm of each focal length.

As described above, according to the present invention, even if a conversion lens is attached between an interchangeable lens and a camera body, the focal length information of the interchangeable lens can be appropriately corrected according to the magnification of the conversion lens. The effect of transmitting focal length information to the camera body side to the positive Tln can be obtained.

[Brief explanation of drawings]

FIG. 1 is a perspective view of an example of the present invention, FIG. 2 is an explanatory diagram of the effect of the longevity example in FIG. FIG. 5 is a graph similar to FIG. 3 of another embodiment of the present invention. [Explanation of symbols of main parts] Signal member...12, Protector 8'-...31 Applicant
: Nippon Kogaku Kogyo Co., Ltd. LAA?

Claims (1)

[Claims] For conversion lenses that can be attached or removed between the interchangeable lens and the camera body, the focal length information of the interchangeable lens is
A conversion lens characterized by having a correction means for applying correction according to the magnification of the conversion lens.