JP2023179230A - Leans adapter device - Google Patents

Abstract

To provide a lens adapter device capable of constantly correcting out-of-focus according to change in a state of a lens device, without impairing a degree of freedom in selecting device materials for imaging.SOLUTION: A lens adapter device can be mounted between a lens barrel having a flange back adjustment mechanism and a camera body comprising an imaging element, and can communicate with the lens barrel. The lens adapter device has driving means of driving a lens or a lens group in the lens adapter device in an optical axis direction, and a driving amount of the driving means is determined based on state information of the lens barrel.SELECTED DRAWING: Figure 5

Description

The present invention relates to a lens adapter device that connects a photographic lens and a camera body, and more particularly to a lens adapter device that can also serve as focus shift correction.

Conventionally, broadcasting lens devices have included a flange back adjustment mechanism for correcting out-of-focus, and maintain appropriate focus by finely adjusting the flange back adjustment mechanism depending on the camera used. Here, it is known that expansion or contraction of the lens due to environmental changes such as temperature and humidity is a cause of defocusing. However, since appropriate equipment is required when adjusting the flange back, it is not easy to manually correct out-of-focus outdoors. In addition, slight out-of-focus may occur due to the magnification change operation of the lens device during shooting, and for 4K lens devices with a shallow depth of field, the difficulty of designing and assembling is required to suppress this out-of-focus. It is rising. Therefore, a lens device is known that calculates the amount of out-of-focus based on changes in the environment such as temperature of the lens device or changes in state such as operation, and constantly corrects out-of-focus by driving an electric flange back adjustment mechanism.

International Publication No. 2018/042759 pamphlet

However, in order to regularly correct out-of-focus like the lens device described in Patent Document 1, the lens device needs to be equipped with an electric flange back adjustment mechanism in advance. Therefore, a dedicated lens device is required, which may limit the user's freedom in selecting equipment.

SUMMARY OF THE INVENTION An object of the present invention is to provide a lens adapter device that can constantly correct out-of-focus in response to changes in the state of a lens device without impairing the degree of freedom in selecting photographic equipment.

In order to achieve the above object, the lens adapter device of the present invention is attachable between a lens barrel having a flange back adjustment mechanism and a camera body equipped with an image sensor, and is capable of communicating with the lens barrel. In the lens adapter device, the lens adapter device has a driving means for driving the lens or lens group in the lens adapter device in the optical axis direction, and the driving amount of the driving device is determined based on state information of the lens barrel. It is characterized by being determined based on.

According to the present invention, it is possible to provide a lens adapter device that can constantly correct out-of-focus according to changes in the state of the lens device without impairing the degree of freedom in selecting equipment for photographing.

FIG. 3 is a perspective view of the lens adapter device in an embodiment of the present invention when it is attached to a lens device and a camera. FIG. 2 is a perspective view of the lens adapter device according to the embodiment of the present invention from the side where the lens device is attached. FIG. 2 is a perspective view of the lens adapter device according to the embodiment of the present invention from the camera mounting side. FIG. 3 is a longitudinal cross-sectional view of a lens adapter device in an embodiment of the present invention. FIG. 1 is a partially cross-sectional perspective view of a lens adapter device in an embodiment of the present invention. FIG. 3 is a cross-sectional view taken along line AA of the lens adapter device according to the embodiment of the present invention. It is a flowchart of focus shift correction by electric flange back adjustment of a lens adapter device in an example of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail based on the examples illustrated in FIGS. 1 to 6.

FIG. 1 is a diagram illustrating a lens adapter device 100 according to this embodiment when attached to a lens device 200 and a camera (imaging device) 300. FIGS. 2 and 3 are perspective views of the lens adapter device according to the present embodiment from the side where the lens device 200 is attached and the side where the camera 300 is attached, respectively. The lens adapter device 100 of this embodiment is provided with a lens device side mount 1 and a camera side mount 2 at the front and rear in the optical axis o direction, and is mounted between the lens device 200 and the camera 300. Here, the lens device 200 of this embodiment has a manual flange back adjustment mechanism (not shown) in order to adjust the flange back with respect to the camera 300.

The rotating ring 3 of the lens device side mount 1 is connected to the mount base 10 by a threaded portion, and by rotating the rotating ring 3 relative to the mount base 10, the position in the optical axis direction with respect to the mount base 10 can be changed. I can do it. The lens device 200 is positioned by fitting the lens mount fitting portion and the pin receiving portion to the lens fitting portion 2a and rotation stop pin 2b provided on the camera side mount 2 of the lens adapter device 100, respectively. . Then, by rotating the rotating ring 3, the lens mount collar is sandwiched between the lens abutting surface 2c of the camera-side mount 2 and the rotating ring 3, and the lens device 200 is fixed to the lens adapter device 100.

In the lens adapter device 100, the camera mount fitting portion of the camera 300 and the camera rotation stop pin fit into the camera fitting portion 2d and the camera pin receiving portion 2e provided on the camera side mount 2 of the lens adapter device 100, respectively. The position is determined by matching. By rotating the camera rotation ring of the camera 300, the collar 2f of the camera side mount section 2 is sandwiched and fixed between the lens abutting surface of the camera 300 and the camera rotation ring.

A lens contact 21, which is an electrical contact with the lens device 200, is fixed to the lens device side mount 1. The lens adapter device 100 communicates with the lens device 200 via a contact on the lens device 200 side that is in contact with the lens contact 21, and can obtain model identification and lens status information from sensors within the lens device 200. At this time, examples of lens state information from sensors in the lens device 200 include operation information such as focusing, variable magnification, and amount of light adjustment, and environmental information such as temperature and humidity. A drive motor 7 for driving the optical system inside the lens adapter device is built inside a motor case 70 that is fixed to the outer diameter portion of the exterior lens barrel 4 of the lens adapter device 100 with a plurality of screws. .

Further, a correction switch 42 is provided on the outer diameter portion of the exterior lens barrel 4 of the lens adapter device 100. A control circuit (not shown) is housed inside the lens adapter device 100, and the lens contact 21, the control circuit, the drive motor 7, and the correction switch 42 are connected to the lens contact 21, the control circuit, the drive motor 7, and the correction switch 42 by wiring (not shown) passing through the lens adapter device 100 and the motor case 70. There is no electrical connection. By switching the position of the correction switch 42 in the directions 400a and 400b, a signal is sent to the control circuit, and it is possible to switch whether or not to perform defocus correction by electric flange back adjustment of the lens adapter device 100.

4 is a longitudinal cross-sectional view of the lens adapter device 100, FIG. 5 is a partial cross-sectional perspective view of FIG. 4, and FIG. 6 is a cross-sectional view taken along line AA in FIG.

The cam structure of the lens adapter device 100 will be described with reference to FIG. 4. The lens adapter device 100 includes a lens barrel, a plurality of optical systems, and a drive system that drives some of the optical systems. The drive system of this embodiment uses a so-called cam mechanism to move an optical system (optical element) such as a lens in the optical axis direction to adjust the optical performance of the lens adapter device 100. The moving group 8 is configured by fixing the front optical systems 80a and 80b to a moving ring 81 using a lens holding structure such as a presser ring or caulking. The rear optical systems 90a and 90b have a similar lens holding structure and are fixed to the exterior lens barrel 4.

Cam follower 82 is fixed to moving ring 8 . The cam follower 82 is in sliding contact with the cam groove 51 in the rotating cam ring 50 and the linear groove 61 extending in the optical axis direction on the fixed barrel 60. Here, the cam follower 82, the cam groove 51, and the linear groove portion 61 are arranged at three approximately equally divided locations around the optical axis to maintain the posture of the movable ring 81. The cam ring 50 is held by a cam holder 53 on the inner diameter portion of the fixed cylinder 60 in a rotatable state around the optical axis. When the cam ring 50 rotates relative to the fixed cylinder 60, the cam follower 82 moves in the optical axis direction 500a, 500b along the cam groove 51, reducing the distance between the front optical systems 80a, 80b and the rear optical systems 90a, 90b. The focus shift is corrected by the change in .

The fixed barrel 60 is held between the mount base 10 and the exterior lens barrel 4 together with the gear ring 72. The mount base 10 is fixed to the exterior lens barrel 4 with a plurality of screws. The fixed barrel 60 is fixed to the exterior barrel 4 so as not to rotate around the optical axis o by screwing in a fixed barrel positioning pin 62 that fits into a locating pin hole 41 provided in the exterior barrel 4. . The gear ring 72 is held rotatably about the optical axis o with respect to the fixed barrel 60. The rotation interlocking pin 74 that fits into the interlocking pin hole 73 provided in the gear ring 72 is screwed into the cam ring 50, so that the gear ring 72 can rotate relative to the fixed cylinder 60 in synchronization with the cam ring 50. It becomes. A gear portion provided on the outer diameter of the gear ring 72 meshes with a gear portion of a motor gear 71 attached to the shaft of the drive motor 7. The lens adapter device 100 transmits the rotation of the drive motor 7 via the gear ring 72 and the motor gear 71, rotates the cam ring 50, drives the optical system, and performs out-of-focus correction by electric flange back adjustment.

FIG. 7 shows a flowchart of out-of-focus correction by electric flange back adjustment of the lens adapter device 100. First, based on the aircraft information acquired from the lens device 200 in step S01, in step S02, the position of the moving group 8 that can be properly focused is calculated in the lens device 200. In step S03, the amount of rotation of the drive motor 7 for moving the moving group 8 to the ideal position calculated in step S02 is calculated and output to the drive motor 7. In step S04, the drive motor 7 is driven based on the output in step S03, and the moving group 8 is driven to perform defocus correction (initial adjustment of flange back).

Next, in step S05, the state of the correction switch 42 is checked. If the correction switch 42 is OFF, the out-of-focus correction process ends. If the correction switch 42 is ON, lens status information is acquired from the lens device 200 in step S06. Information acquisition in these steps S01 and S06 is carried out by communicating with the lens device 200 via a contact on the lens device 200 side that is in contact with the lens contact 21. Here again, in step S02, calculation is performed using the lens state information obtained in step S06, and the position of the moving group 8 that can correct the focus shift in the environment where the acquired lens device 200 is placed or in the operating state is determined. calculate. Thereafter, in step S03, the amount of rotation of the drive motor 7 for moving the moving group 8 to the ideal position recalculated in step S02 is calculated and re-outputted to the drive motor 7. In step S04, the drive motor 7 is driven based on the output in step S03, and the moving group 8 is driven to perform defocus correction that reflects the lens state information.

Through the above processing, in this embodiment, by constantly grasping the state change of the lens device 200 and calculating the amount of defocus in that state, it becomes possible to regularly perform appropriate defocus correction. As in this example, by providing an electric flange back adjustment mechanism inside the lens adapter device and using it together with a lens device, even a lens device that is not equipped with an electric flange back adjustment mechanism can perform defocus correction on a regular basis. It becomes possible to take pictures.

In this embodiment, communication with the lens device is carried out via contacts, but this is not the case. For example, communication may be performed by connecting a communication cable provided on either one of the lens device or the lens adapter device to a cable connector provided on the other.

In addition, although the environmental information of the lens device is assumed to be acquired from the sensor within the lens device, this is not the case. Good too. With such a configuration, even if the lens device does not have an environmental information acquisition means, it is possible to perform constant defocus correction according to the environment based on information from the sensor in the lens adapter device.

Further, in this embodiment, the initial adjustment of the flange focal length is performed based on the aircraft information from the lens device, but this is not the only option. For example, only the initial adjustment of the flange focal length may be performed manually. With this configuration, even for lens devices that do not have a means to provide model information, the effects of the present invention can be achieved by correcting focus deviation by electric flange back adjustment as a difference from the initial state. You can enjoy it.

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 can be made within the scope of the gist thereof.

7 Drive motor 8 Moving group 21 Lens contact 50 Cam ring 51 Cam groove 60 Fixed cylinder 61 Straight groove 72 Gear ring 71 Motor gears 80a, 80b Front optical system 90a, 90b Rear optical system 82 Cam follower 100 Lens adapter device 200 Lens device 300 Camera

Claims (6)

A lens adapter device that can be installed between a lens barrel having a flange back adjustment mechanism and a camera body equipped with an image sensor, and that can communicate with the lens barrel,
The lens adapter device includes:
comprising a driving means for driving the lens or lens group in the lens adapter device in the optical axis direction,
A lens adapter device, wherein the driving amount of the driving means is determined based on state information of the lens barrel. 2. The lens adapter device according to claim 1, wherein the status information of the lens barrel is operation information of the lens barrel provided through communication from the lens barrel. 2. The lens adapter device according to claim 1, wherein the state information of the lens barrel is environmental information such as temperature, humidity, atmospheric pressure, posture difference, and carbon dioxide concentration. 4. The lens adapter device according to claim 3, further comprising a sensor for acquiring state information of the lens barrel. The lens adapter device according to any one of claims 1 to 4, further comprising a drive switch for switching the drive state of the drive means. The lens adapter device according to any one of claims 1 to 5, further comprising an operating means that can manually drive the lens or lens group in the lens adapter device in the optical axis direction.