JPH02296207A - Autofocusing camera - Google Patents

Abstract

PURPOSE:To obtain a quick action in the case of mounting a long focal distance lens and to miniaturize a camera main body and an interchangeable lens unit by incorporating a motor for driving a short focal distance lens in a main body and incorporating the motor for driving the long focal distance lens in a unit. CONSTITUTION:The unit 6 provided with the short focal distance lens and the unit 21 provided with the long focal distance lens can be alternatively mounted and a driving motor 2 for driving according to the focusing information is incorporated in the main body. And the driving motor 23 for driving according to the output of the driving motor 2 after detecting the driving state by the driving motor 2 is incorporated in the unit 21, and in the case of loading the unit 6, the short focal distance lens is advanced or retreated by the driving motor 2, and in the case of loading the unit 21, the long focal distance lens is advanced or retreated by the driving motor 23. Thus, it is not necessary that the motor is incorporated in the short focal distance interchangeable lens unit, so that the camera can be made small in size and light in weight, and the quick action is obtained by using the motor incorporated in the unit as to the long focal distance lens.

Description

DETAILED DESCRIPTION OF THE INVENTION (a) Field of Industrial Application The present invention relates to an autofocus camera with interchangeable lenses.

(B) Conventional technology Conventionally, in a lens-interchangeable auto 7 orcus (hereinafter referred to as AF) camera that allows multiple lenses with different focal lengths to be exchanged depending on the application, the focus lens for performing the focusing operation is driven. For example, the lens drive method that uses
As shown in the June 1988 issue of the magazine "Photo Industry",
There are two types: ``One type with motor inside the body'' and ``One type with motor inside the lens.''

The in-body motor type has the following structure. That is, as shown in Fig. 2, an AF mode (2) is built into the camera body (1), and this AF mode is driven based on AF information obtained from an AP sensor (3), which is a distance measurement sensor. This driving force is then transmitted to the body AF coupler (4) fixed to the motor shaft (2a) of the AP momo (2).

The lens AF coupler (7) on the interchangeable lens unit (6) side that is attached to the lens mount part (5) of the camera body.
By connecting to the body AF coupler (4), the AF
The driving force of the momo (2) is transmitted to the interchangeable lens unit (6). Inside the interchangeable lens unit (6), the lens AF coupler (7) is connected to the shaft (8) and the relay gear group (9).
The driving force of the AF momo (2) is ultimately transmitted to this lens drive mechanism (10). Lens drive mechanism (1
0) is P11 of the June 1987 issue of the magazine "Photo Industry"
As disclosed in 2 to pH 3, the focus lead screw screw or this screw screw is fitted into the 7
It is composed of a moving frame that supports the orcus lens (11), and by rotating the seven orcus lead screws by the driving force of the AF momo and converting this rotation into a linear motion of the moving frame, Focus lens (1
0) in the optical axis direction. In addition, the body AP coupler (
4) and the lens AF coupler (7) are cylindrical rotating bodies with a concavo-convex shape on their tip surfaces, and are mechanically connected by engaging their concave-convex portions.

Therefore, in this method, the AP module inside the camera body (1)
- The driving force in (2) is directly and mechanically applied to the lens drive mechanism (1).
It can be said that this is a method in which the AF operation is performed by transmitting the signal to the focus lens (11) and moving the focus lens (11) forward and backward.

On the other hand, as shown in Figure 3, the in-lens motor type has an AF mode (13) built into the interchangeable lens unit (12), and the AF information obtained from the A and F sensors (3) on the camera body side. is electrically transmitted from the camera body to the interchangeable lens unit at the lens mount section (5), and the AF mode (13) is driven and controlled based on this AF information.
In this method, the driving force of the F momo is transmitted to the lens drive mechanism (10) to move the 7 orcus lens (110) forward and backward in the lens optical axis direction.

(c) Problems to be Solved by the Invention In the one-type in-body motor system, the single AF mode inside the camera body must be able to handle a wide variety of loads that vary from one interchangeable lens to another. It is necessary to adopt an AF mode that is as versatile as possible depending on the usage status of the camera body and interchangeable lenses. Normally, this in-body motor one-type AF mode uses wide-angle and
A motor suitable for standard AF lenses is used.

For this reason, when an interchangeable lens of the telephoto system A or F lens, which has a heavier load, is attached, there arises a disadvantage that the speed of the AF operation becomes significantly slow. Conversely, if a motor suitable for telephoto A and F lenses is used, the size of the motor itself will increase, making the camera body larger, which is also disadvantageous in terms of strengthening the motor power supply.

On the other hand, the disadvantages mentioned above are solved with the one-type in-lens motor, but the one-in-the-body motor can be used with a small motor, and wide-angle/standard AF is used frequently and has a light load. Regarding lenses, the AF mode is built into the interchangeable lens unit, which increases the size and weight of the unit itself.

(d) Means for Solving the Problems In the present invention, the first unit having a short focal length lens and the second unit having a long focal length lens can be attached selectively, and depending on focus information □, This is an auto 7 orcus camera that has a first drive motor built into the main body, and includes a drive state detection means that detects the drive state of the first drive moke, and a second drive motor that drives the second drive motor according to the output of the drive state detection means. It is built into 2 units, and when the 1st unit is installed,
The short focal length lens is moved forward and backward in the lens optical axis direction by the driving force of the first drive motor, and when the second unit is attached, the short focal length lens is
The long focal length lens is moved forward and backward in the lens optical axis direction by the driving force of the drive motor.

(E) Function Since the present invention is configured as described above, wide-angle/standard AF
For interchangeable lens units with short focal length lenses such as lenses, there is no need to incorporate an AF module, so they can be made smaller and lighter in weight, and for interchangeable lens units with long focal length lenses such as telephoto AF lenses. This enables rapid AF operation with the built-in AF mode that can handle heavy loads.

(f) Example An embodiment of the present invention will be described below with reference to the drawings.

Incidentally, the same parts as those in the conventional example are given the same reference numerals and the description thereof will be omitted.

In the apparatus of this embodiment, the camera body (1) has the same structure as the in-body motor type shown in FIG. still,
The AF momo (first drive motor) (2) is a small motor with low output for light loads, and requires a small power supply. On the other hand, there are two types of interchangeable lens units. This is an interchangeable lens unit (second unit) (21) having a telephoto AF lens with a long focal length and heavy motor load.

The former interchangeable lens unit has exactly the same structure as the interchangeable lens unit (6) in FIG. 2. Therefore, when performing AF operation with a wide-angle/standard AP lens, by attaching the interchangeable lens unit to the lens mount section (5) of the camera body (1), the AF operation can be performed as shown in Figure 2. --The driving force of (2) is mechanically transmitted to the lens driver elf (10) via the body AF coupler (4), lens AF coupler (7), and relay gear group (9), and the wide-angle/standard type The 7 orcus lens (11), which is an AF lens, moves back and forth in the optical axis direction to perform an AF operation. Furthermore, AP Momo
- When (2) is rotating forward, the focus lens (11
) is displaced in the periapsis direction, and when it is reversed, it is displaced in the ω-e direction. Furthermore, when the in-focus state is reached, the camera enters a stopped state.

On the other hand, the latter interchangeable lens unit (21) includes a lens AF coupler (7), a rotation state detector (
22), AF Momo (2nd drive motor) (23)
, a lens drive mechanism (10).

As shown in FIGS. 4 and 5, the rotational state detector (22) rotates integrally with the lens AF coupler 7) via a shaft (25), and a reflective piece (27) is fixed to a part of the rotation state detector (22). A rotating disk (26) and two photosensors (28) fixed to a substrate (28) facing the rotating disk (26).
29) (30) and these 7 otosensors (29) (
30) Consists of a signal processing circuit (31) that generates a control signal for controlling the drive of the AF momo (32) based on the output.

Here, the photosensors (29) and (30) both have a pair of light emitting element and light receiving element inside, and only while each photosensor faces the reflective piece (27), the light emitting element is removed from the light emitting element. The light is reflected by the reflecting piece (27), and this reflected light is received by the light receiving element. In addition, as shown in Figure 5, the photo sensors (29) (30) and the rotating disk (26)
The straight lines connecting the center of rotation (P) are arranged so as to be perpendicular to each other, and therefore a 90° phase difference occurs between the outputs of both photosensors, which become rectangular waves according to the rotation of the rotating disk (26). . For example, in FIG. 5, the rotation circle fi(26)
If it rotates clockwise, the output of the photosensor (30) will lead the output of the photosensor (29) by 90' in phase, and conversely, if it rotates counterclockwise, the output of the photosensor (29) will lead in phase by 90°. It turns out. Therefore, by comparing the phases of the outputs of both photosensors, it is possible to
That is, the rotational direction of the AF momo (2) can be determined.

The signal processing circuit (31) detects the above-mentioned rotation direction and calculates the rotation speed of the AF momo (2) by detecting the frequency of the photosensor (29). The AP motor (32) is then driven based on this information regarding the rotational direction and rotational speed, and the rotational direction and speed of both AF motors (2) and (32) are controlled to match.

The AF Momo (32) is a large motor suitable for driving heavy loads such as telephoto AF lenses, and it drives the lens while maintaining the same rotational state as the AF Momo (2) as described above. A focus lens (24), which is a telephoto AP lens, is moved forward and backward through a mechanism (10).

Therefore, when performing AF operation with a telephoto AF lens, attach the interchangeable lens unit (21) to the camera body (1).
When attached to the lens mount part (5) of the camera, the AF information from the AF sensor (3) drives the AF momo (2), and this driving force connects the body AF coupler (4) and lens AF coupler (7). The rotational state of the AF momo (2) is mechanically transmitted to the rotational state detector (22), which converts the rotational state of the AF momo (2) into an electrical signal, and based on this, the AF momo...
By driving (23), the mechanical gain of the driving force of the AF momo (2) increases, and the mechanical gain of the driving force of the AF momo (2) increases.
) can now be easily driven with the AF motor (23) even for lenses with heavy morph loads, which was difficult to handle with the AF motor. AF Momo (2) is AF
The AF operation can be performed without compromising compatibility with the mechanical coupling at the lens mount.

In this embodiment, optical means using a photosensor is used as the rotational state detector (22), but
It is also possible to use a magnet in place of the reflective piece (27), and to use magnetic means using two-phase magnetoresistive elements in place of the photosensors (29) and (30).

Also, when the AF momo (2) is stopped, the AF momo
- (32) can also be controlled to be in a stopped state, thereby making it possible to maintain a focused state.

Furthermore, as the AF sensor (3), an infrared sensor and a so-called mountain-climbing AF that extracts AF information such that the value obtained by integrating the high-frequency components of the imaged video signal at each predetermined period is maximized are used, and a solid-state image sensor (CCD) is used. ) itself may be used.

(G) Effects of the Invention As described above, according to the present invention, there is no need to incorporate an AF mode into an interchangeable lens unit having a short focal length lens, and an interchangeable lens unit having a long focal length lens is not required. Even in cases where the camera body and the interchangeable lens unit are mechanically connected to each other, it is possible to overcome heavy loads and perform quick AF operations while maintaining compatibility in the mechanical connection between the camera body and the interchangeable lens unit, thereby reducing the space and weight burden on the camera body and the interchangeable lens unit. will be optimized.

[Brief explanation of the drawing]

1, 4 and 5 relate to an embodiment of the present invention,
FIG. 1 is an explanatory diagram showing the camera structure, and FIGS. 4 and 5 are explanatory diagrams of main parts. Further, FIGS. 2 and 3 are explanatory diagrams showing a conventional camera structure. (6)... Interchangeable lens Uni Soto (Fl Uni Soto)
), (21)...interchangeable lens unit) (2nd -'-
=・throat), (2)...AF momo--(first drive motor), (22)・rotation state detector, (23)...
AF momo--(second drive motor).

Claims (1)

[Claims] (1) A first unit with a short focal length lens and a second unit with a long focal length lens can be attached selectively, and the first drive motor that drives according to focus information is built into the main body. In the focus camera, a drive state detection means for detecting the drive state of the first drive motor, and a second drive state detection means for driving according to the output of the drive state detection means.
A drive motor is built in the second unit, and when the first unit is attached, the short focal length lens is moved forward and backward in the lens optical axis direction by the driving force of the first drive motor, and when the second unit is attached, the short focal length lens is moved forward and backward in the lens optical axis direction. An autofocus camera characterized in that the long focal length lens is moved forward and backward in the lens optical axis direction by the driving force of two drive motors.