JP6991825B2 - Optical equipment - Google Patents

Description

The present invention relates to an optical instrument.

The digital camera described in Patent Document 1 is known as an optical device capable of changing the operation resistance (operation torque) of the operation ring. In the digital camera described in Patent Document 1, a function as a focus ring and a function as a zoom ring can be assigned to one operation ring, and mode switching for switching each function can also be performed by the operation ring. be. Further, it is possible to generate a click feeling when switching modes or when operating the operation ring after the function is assigned, and to change the operation resistance at the time of operation with a click feeling.

JP-A-2015-52800

Here, if the torque of the operation ring is too light when shooting a moving image, for example, the moving image may have a sudden change in the angle of view during playback. Alternatively, smooth zoom-in or zoom-out may be difficult. However, Patent Document 1 does not disclose a configuration for suppressing the influence of the torque of the operation ring during such moving image shooting on the moving image.

Therefore, an object of the present invention is to provide an optical device capable of suppressing the influence of the operation resistance of the operation unit during moving image shooting on the moving image.

In order to achieve the above object, the optical instrument of the present invention
Operation unit and
A resistance changing unit for changing the operating resistance of the operating unit,
An optical device including a control unit capable of controlling the resistance changing unit so that the operating resistance of the operating unit during movie shooting is larger than the operating resistance of the operating unit during still image shooting.
The resistance changing part is
The drive unit and
A moving unit that can be moved so that the relative position with respect to the operating unit is changed by the driving unit.
A contact portion provided on the moving portion and capable of contacting the operation portion,
A position detection unit for detecting the position of the moving unit is provided.
The operation resistance changes depending on the positional relationship between the contact portion and the operation portion .

INDUSTRIAL APPLICABILITY According to the present invention, it is possible to provide an optical device capable of suppressing an influence on a moving image due to an operation resistance of an operation unit at the time of moving image shooting.

System configuration diagram of the lens device 101 and the camera body 201 of the first embodiment Configuration diagram of the load adjustment unit 117 before applying operating torque Configuration diagram of the load adjustment unit 117 after applying operating torque The figure which shows the liquid crystal display part 207 in the operation torque adjustment mode. The figure which shows the liquid crystal display part 207 in the operation torque adjustment mode. An application drawing of the lens device 101 of the modified example of the first embodiment. The drawing of the external application of the lens apparatus 101 in the second embodiment. System configuration diagram of the lens device 101, the adapter device 400, and the camera body 201 of the third embodiment

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

[First Example]
The system configuration of the lens device 101 and the camera body 201, which are optical devices in this embodiment, will be described with reference to FIG. 1.

(Structure of lens device 101)
The lens device 101 includes a zoom lens unit 102, a focus lens unit 103, an aperture unit 104, an image shake correction lens unit 105, and a fixed lens unit 106. The lens device 101 further serves as a control unit for controlling an operation ring 116 as an operation unit, a storage unit 121, a gyro sensor 107 as a vibration detection unit, each drive source described later, a load adjustment unit (resistance change unit) 117, and the like. The main CPU 108 on the lens side of the above is provided.

The main CPU 108 on the lens side issues an instruction to the aperture drive source 110, the focus lens drive source 111, and the zoom lens drive source 122 to drive the focus lens unit 103, the aperture unit 104, and the zoom lens unit 102. Further, the load adjusting unit 117 can change the operating resistance (operating torque) of the operating ring 116 according to an instruction from the lens-side main CPU 108.

The lens device 101 is detachably fixed to the camera body 201 via the mount 112, and the light from the subject is imaged on the image pickup element 202 held by the camera body 201 through the optical member in the lens device 101. Take an image of the subject. That is, the lens device 101 is an accessory device that can be attached to the camera body 201, and is also a lens device including at least one lens.

(Structure of camera body 201)
The camera body 201 holds an image sensor 202, and includes a camera-side main CPU 203 as a control unit, a release button 204, a main power supply 205, an image recording medium 206, and a liquid crystal display unit 207 as a display unit. The camera body 201 further includes an operation dial 208, an operation switch 209, a finder 210, a storage unit 211, and a shooting mode switching unit 212. The shooting mode switching unit 212 is a mode switching unit capable of switching between a moving image shooting mode and a still image shooting mode.

The release button 204 has a two-step push configuration, and the first step is SW1 and the second step is SW2. When SW1 is pressed, preparations for starting shooting such as returning from shooting standby, starting image stabilization, starting autofocus, and starting metering are performed. When SW2 is pressed, an image is taken and an image recording instruction is given to the image recording medium 206.

A plurality of functions can be assigned to the above-mentioned operation ring 116. In other words, the operation ring 116 can function as a first operation unit for changing the first parameter, and a second operation for changing a second parameter different from the first parameter. It can also function as a department. In other words, the operation ring 116 can realize a plurality of functions.

The camera body 201 is provided with the above-mentioned operation dial 208 and operation switch 209 in order to select whether the operation ring 116 functions as a first operation unit or a second operation unit. By rotating the operation dial 208, the function assigned to the operation ring 116 can be selected, and by pressing the operation switch 209, the function assigned to the operation ring 116 can be determined to be the function selected by the operation dial 208. That is, the operation dial 208 and the operation switch 209 are selection units for selecting whether the operation ring 116 functions as the front 1 operation unit or the second operation unit. Then, the operation ring 116 can function as a first operation unit or a second operation unit based on the selection result by the selection unit. However, the camera body 201 may be configured so that only one of the operation dial 208 and the operation switch 209 functions as a selection unit.

The operation ring 116 can be assigned a function as a zoom ring for changing the position of the zoom lens unit 102 and a function as a focus ring for changing the position of the focus lens unit 103. Further, a function as a diaphragm ring for changing the aperture diameter of the diaphragm unit 104 can also be assigned to the operation ring 116.

In addition to the function as a ring for driving the optical member on the lens device 101 side, the operation ring 116 can also be assigned a function as a ring for changing the settings on the camera body 201 side such as the shutter speed. It is possible.

The operation ring 116 is provided with a rotation detection unit (not shown), and when the user rotates the operation ring 116, a signal corresponding to the output of the rotation detection unit is transmitted to the lens side main CPU 108. As a result, the lens-side main CPU 108 can grasp the operation amount of the operation ring 116, and can control each drive source based on the grasped operation amount to realize the adjustment desired by the user.

It should be noted that communication between the camera-side main CPU 203 and the lens-side main CPU 108 and power supply from the camera body 201 to the lens device 101 can be performed via a contact block (not shown) provided on the mount 112. ..

(Structure of resistance change part)
Next, the configuration of the load adjusting unit 117 will be described with reference to FIGS. 2 and 3. FIG. 2 is a diagram showing a load adjusting portion 117 when the elastic portion 117d described later is not in contact with the operation ring 116, and FIG. 3 is a diagram showing a load adjusting portion 117 when the elastic portion 117 is in contact with the operation ring 116. It is a figure which shows.

As shown in FIGS. 2 and 3, the load adjusting section 117 includes an elastic section 117d as a contact section, a base section 117a as a moving section, a connecting section 117c, a motor 118 as a driving section, and a changeover switch 119 as a region discrimination section. , A convex portion 119a is provided.

Since the base portion 117a is mechanically connected to the motor 118 fixed to the lens device 101 via the connecting portion 117c, the base portion 117a moves along the optical axis direction by the driving force from the motor 118. be able to. That is, the base portion 117a is a moving portion capable of moving so that the position relative to the operation ring 116 changes.

The connection structure between the motor 118 and the connecting portion 117c may be a structure capable of transmitting the driving force from the motor 118 such as a simple gear connection or a combination of a rack and a pinion to the base portion 117a. Further, the load adjusting unit 117 and the motor 118 may be connected by a screw or the like, and a gear that engages with a member included in the motor 118 may be provided on the lens device 101 side. In this configuration, the load adjusting unit 117 and the motor 118 are integrally movable with respect to the lens device 101 and the operation ring 116.

The cutout portion 117b sandwiches the convex portion 119a of the changeover switch 119, which is a region determination unit (position detection unit). Therefore, when the load adjusting unit 117 is moved by the motor 118, the convex portion 119a also moves and the changeover switch 119 is switched, so that the position of the load adjusting unit 117 can be detected. The configuration for detecting the position of the load adjusting unit 117 is such that a magnetic component is fixed to the base unit 117a, a magnetic sensor is arranged instead of the changeover switch 119, and the position of the base member 117a is non-contactly positioned. It may be configured to detect.

The elastic portion 117d is a component made of an elastically deformable material such as rubber. As shown in FIG. 3, the elastic portion 117d is charged on the end face of the operation ring 116, that is, when it is pressed against the operation ring 116, a frictional force is generated and the operation torque of the operation ring 116 is changed. In other words, the operating torque of the operating ring 116 changes depending on the positional relationship between the elastic portion 117d and the operating ring 116. As described above, in this embodiment, the operating torque of the elastic portion 117d is adjusted with respect to the operating ring 116 in two states, a non-contact state and a charged state. However, there may be a configuration in which a plurality of operating torques can be selected or a configuration in which the operating torque can be continuously changed by adjusting the charge amount of the elastic portion 117d.

As described above, in this embodiment, the operating torque is changed by adjusting the contact state between the elastic portion 117d and the operating ring 116. However, as the load adjusting unit, a configuration may be adopted in which the contact state between the operation ring 116 and the oscillator is adjusted, and more specifically, the pressing force exerted by the oscillator is adjusted to change the operating torque. Compared with the configuration using such an oscillator, the load adjusting unit 117 shown in FIGS. 2 and 3 continuously energizes the oscillator and does not need to control the amount of energization, so that the power consumption can be increased. Can be reduced. More specifically, the load adjusting unit 117 shown in FIGS. 2 and 3 consumes power because it is not necessary to energize the motor 118 after the elastic portion 117 is pressed against the operating ring 116 to adjust the operating torque. Can be reduced.

(About operation torque when shooting movies and still images)
In this embodiment, the lens-side main CPU 108 controls the load adjusting unit 117 so that the operating torque (operating resistance) of the operating ring 116 during moving image shooting is larger than the operating torque of the operating ring 116 during still image shooting. It is possible to do.

For example, if you try to zoom in or zoom out smoothly as a video effect during movie shooting, and the operation torque of the operation ring 116 is too light, the angle of view will change suddenly and the movie will be zoomed in or zoomed smoothly. It becomes difficult to give out. On the contrary, if the operation torque of the operation ring 116 is too heavy when shooting a still image, a photo opportunity may be missed. Therefore, in this embodiment, the lens-side main CPU 108 controls the load adjusting unit 117 so that the operation (operation resistance) of the operation ring 116 during movie shooting is larger than the operation torque of the operation ring 116 during still image shooting. It is configured so that it can be done. Such a configuration facilitates smooth zoom-in and zoom-out, and makes it difficult to miss a photo opportunity. That is, according to this embodiment, it is possible to suppress the influence on the moving image due to the operation resistance of the operation unit at the time of moving image shooting.

Here, the time of moving image shooting means the period from the start of recording to the end of recording when the camera body 201 is in the movie shooting mode, and the time of still image shooting means that the camera body 201 is in the still image shooting mode. It refers to the period of time. The period until the camera body 201 is in the moving image shooting mode and recording is started is set as the moving image shooting preparation time. At this time, in order to be able to start movie shooting quickly, the lens side main CPU 108 is set, and the load adjusting unit 117 is set so that the operation torque of the operation ring 116 is smaller than the operation torque at the time of movie shooting when preparing for movie shooting. It may be configured so that it can be controlled.

In this embodiment, the initial setting of the operating torque of the operating ring 116 is the setting shown in FIG. The initial setting referred to here is a setting at the time of factory shipment of the lens device 101 or the camera body 201, or a setting when the initialization operation is performed by the lens device 101 or the camera body 201. FIG. 4 shows information displayed on the liquid crystal display unit 207 when the operation torque adjustment mode is selected by using the operation dial 208 or the like of the camera body 201. In FIG. 4, 300 is a memory showing the magnitude of the operation torque of each operation such as the zoom operation and the focus operation, and 301 is an index showing the operation torque currently set in each operation.

As shown in FIG. 4, in the initial setting, the moving image torque, which is the operation torque at the time of moving image shooting, is the operation torque at the time of still image shooting in each operation of zoom operation, focus operation, aperture operation, and shutter speed operation. It is larger than the torque. The memory 300 means that the closer the index 301 is to the numerical value 0, the smaller the operating torque is, and the closer the index 301 is to the numerical value 100, the larger the operating torque is.

In the operation torque adjustment mode shown in FIG. 4, in addition to the operation torque adjustment described later, the function to be assigned to the operation ring 116 can be selected. When the operation dial 208 is rotated in the operation torque adjustment mode, the frame 302 indicating the function currently assigned to the operation ring 116 moves.

In FIG. 4, the zoom operation is selected by the frame 302 in the initial setting, and when the operation switch 209 is pressed in this state, the mode shifts to the mode for adjusting the moving image torque of the zoom operation. When the operation dial 208 is rotated in this state, the index 301 moves on the memory 300 to adjust the moving image torque of the zoom operation. When the operation switch 209 is pressed again after adjusting the moving image torque of the zoom operation, the mode shifts to the mode of adjusting the still image torque of the zoom operation. When the operation dial 208 is rotated in this state, the index 301 moves on the memory 300 to adjust the still image torque of the zoom operation. That is, the operation dial 208 and the operation switch 209 have a function as a designation unit for designating the magnitude of the operation torque of the operation ring 116 in addition to the function as the selection unit described above.

When the operation switch 209 is pressed again after adjusting the still image torque of the zoom operation and the operation dial 208 is rotated, the frame 302 moves again and the function assigned to the operation ring 116 can be selected.

When selecting the function to be assigned to the operation ring 116 by rotating the operation dial 208 to move the frame 302, the camera body 201 may perform the processing as described below. That is, if the operation switch 209 is pressed and held for a predetermined time or longer while the frame 302 has one of the functions selected, the function to be assigned to the operation ring 116 is determined without shifting to the above-mentioned mode for adjusting the operation torque. May be good. After deciding which function is to be assigned to the operation ring 116, the information is transmitted from the camera side main CPU 203 to the lens side main CPU 108, and various settings are made so that the operation ring 116 can realize the selected function on the lens device 101 side. I do.

(Regarding control to maintain the magnitude relationship between video torque and still image torque)
When adjusting the moving image torque or the still image torque described above, as shown in FIG. 5, the operating torque of the operation ring 116 during moving image shooting by the user becomes smaller than the operating torque of the operating ring 116 during still image shooting. It is assumed that the following settings are made. If such a setting is made, smooth zoom-in and zoom-out may become difficult as described above, or a photo opportunity may be missed.

Therefore, in this embodiment, when the above setting is made by the user, the operation torque of the operation ring 116 at the time of moving image shooting is smaller than the operation torque of the operation ring 116 at the time of still image shooting. The indicated information is displayed on the liquid crystal display unit 207. Specifically, when the above settings are made, the moving image torque set in the liquid crystal display unit 207 is smaller than the still image torque. Therefore, an arrow 303 for prompting an operation for increasing the moving image torque and an index 304 indicating a position (target position) where the moving image torque is larger than the currently set still image torque are displayed. By displaying such information on the liquid crystal display unit 207, it is possible to prevent the moving image shooting from being performed in a state where the operating torque of the operation ring 116 at the time of moving image shooting is too small.

If the operation torque is not adjusted by the user after the above arrow 303 and the index 304 are displayed, the operation torque of the operation ring 116 at the time of moving image shooting is the operation of the operation ring 116 at the time of still image shooting. It may be set so as to be smaller than the torque. Alternatively, after the above arrow 303 and the index 304 are displayed, unless the operation torque of the operation ring 116 at the time of moving image shooting is set to be larger than the operation torque of the operation ring 116 at the time of still image shooting. It may be set so that shooting cannot be performed.

Further, when the user sets the operation torque of the operation ring 116 when shooting a moving image to be smaller than the operation torque of the operation ring 116 when shooting a still image, the operation torque is automatically adjusted. The settings may be different. Specifically, when the above settings are made, the lens-side main CPU 108 may control the load adjusting unit 117 so that the moving image torque is larger than the set still image torque.

In FIG. 4, the operation torque of the zoom operation and the operation torque of the focus operation at the time of still image shooting are set to the same value, but different settings may be made. For example, the operation torque of the focus operation may be set to be larger than the operation torque of the zoom operation when shooting a still image or a moving image. In this case, the angle of view can be changed quickly, and focusing can be performed while finely adjusting with a heavy operating torque.

(About the memory of set functions and operating torque)
At least one of the storage unit 121 on the lens device 101 side and the storage unit 211 on the camera body 201 side can store the adjustment results of the moving image torque and the still image torque in various operations shown in FIG. 4 set by the user. Storing the adjustment result of the moving image torque and the still image torque is replaced with storing, for example, the position of the base member 117a when the moving image torque of the zoom operation is adjusted, or the output value of the changeover switch 119 at that position. You may think.

It is assumed that the function assigned to the operation ring 116 by the user is changed from the zoom operation to the focus operation. At this time, the information indicating that the function has been changed and the information regarding the set moving image torque and the still image torque in the changed function are sent from the camera side main CPU 203 to the lens side main CPU 108. Then, the lens-side main CPU 108 controls the load adjusting unit 117 based on the received information, and reproduces the set moving image torque or still image torque. That is, the lens-side main CPU 108 controls the load adjusting unit 117 based on the selection result by the selection unit. Further, it can be said that the lens-side main CPU 108 controls the load adjusting unit 117 based on the designated result by the designated unit or the information from the storage unit that stores the designated result. As a result, both the function change of the operation ring 116 and the operation torque adjustment can be completed in a short time.

(Modification example)
A modified example of this embodiment will be described with reference to FIG.

As shown in FIG. 1, the lens device 101 in this embodiment has only the operation ring 116 as a member on the lens device 101 side that can be operated by the user. On the other hand, in the modification shown in FIG. 6, in addition to the operation ring 116, the zoom operation ring 114 and the focus operation ring 115 are also provided on the lens device 101 as members on the lens device 101 side that can be operated by the user.

The zoom operation ring 114 is an operation member for manual zoom, and the focus operation ring 115 is an operation member for manual focus. As described above, the operation ring 116 is an operation member to which various functions can be assigned. In the modification shown in FIG. 6, the zoom operation ring 114 can manually perform the zoom operation by moving the zoom lens unit 102 in the optical axis direction via a connecting component (not shown). The focus operation ring 115 is not mechanically connected to the parts inside the lens barrel 101, and the focus lens unit 103 is driven by outputting the rotation detection value at the time of operation to the lens side main CPU 108. It is an operating member for.

Also in this modification, the lens-side main CPU 108 uses the load adjusting unit 117 so that the operating torque (operating resistance) of the operating ring 116 during movie shooting is larger than the operating torque of the operating ring 116 during still image shooting. It is possible to control. Therefore, this modification can also obtain the same effect as that of the first embodiment described above.

In this modification, the operation ring 116 may be set so that only functions other than the zoom operation ring and the focus operation ring can be assigned, or the operation ring 116 can be assigned the functions of the zoom operation ring and the focus operation ring. It may be set.

[Second Example]
A second embodiment of the present invention will be described with reference to FIG. 7.

The difference between the first embodiment and the present embodiment described above lies in the means for changing the function assigned to the operation ring 116. Specifically, in the above-mentioned first embodiment, the function assigned to the operation ring 116 could be changed by using the operation dial 208 and the operation switch 209 provided on the camera body 201. On the other hand, in the present embodiment, as shown in FIG. 7, the function assigned to the operation ring 116 can be changed by using the push switch 120 provided on the outer peripheral portion of the lens device 101.

The user pressing the push switch 120 is detected by a detection unit (not shown). When the detection unit detects that the push switch 120 has been pressed, the detection unit transmits to that effect to the lens-side main CPU 108, and simultaneously changes the operation function of the operation ring 116 and adjusts the operation torque.

It may not be possible to change the initial function assigned to the operation ring 116 at startup and the order in which the function changes each time the push switch 120 is pressed from the initial function, or even if it can be changed on the camera body 201 side. good. Further, if the moving image torque and the still image torque in each set operation are stored in the storage unit as in the first embodiment described above, the function assigned to the operation ring 116 can be changed in a short time after the push switch 120 is pressed. And the change of operating torque can be completed.

In this embodiment, since the function assigned to the operation ring 116 and the operation torque can be changed on the lens device 101 side, the function and the operation torque can be changed while looking through the finder 210. By displaying the function of the change destination and the operation torque in the finder 210, the user may be able to recognize that the function has been changed.

By using the above configuration, the function and operation torque of the operation ring 116 can be changed from the lens device 101 side as well, and further improvement in operability can be realized.

[Third Example]
A third embodiment of the present invention will be described with reference to FIG.

Unlike the first embodiment described above, in this embodiment, the lens device 101 is not provided with the operation ring 116 and the load adjusting unit 117. Instead, the adapter device 400 as an optical device provided between the lens device 101 and the camera body 201 has an operation ring 401 having the same function as the operation ring 116 and a load having the same function as the load adjustment unit 117. An adjusting unit 402 is provided. The adapter device 400 is also provided with a main CPU 403 on the adapter side.

By using the adapter device 400 shown in this embodiment, the function of the operation ring on the lens device 101 side can be assigned to the operation ring 401 even when the operation ring on the lens device 101 side cannot adjust the operation torque. Then, the operating torque of the operating ring 401 may be adjusted by the load adjusting unit 402 in the same manner as in the first embodiment described above. As a result, even when the operation ring on the lens device 101 side cannot adjust the operation torque, the operation torque at the time of moving image shooting and the operation torque at the time of still image shooting can be appropriately set by using the adapter device 400. can.

[Modification example]
Although the preferred embodiments of the present invention have been described above, the present invention is not limited to these embodiments, and various modifications and modifications can be made within the scope of the gist thereof.

For example, the operation ring 116 and the operation ring 400 described above are endless electronic rings that can rotate 360 degrees. However, when the operation ring 116 or 400 is rotated by a predetermined angle, the operation torque may be increased by the load adjusting unit to create a pseudo end.

Further, the lens device 101 may be newly provided with a mechanism for imparting a click feeling to the above-mentioned operation rings 116 and 400. It may be a mechanism that gives a click feeling when the aperture operation function and the shutter speed operation function are assigned to the operation rings 116 and 400.

Further, in addition to the functions of the zoom operation ring, the focus operation ring, the aperture ring, and the shutter speed ring, the above-mentioned operation rings 116 and 400 may be assigned a function of changing the ISO sensitivity and the like.

Further, instead of displaying the arrow 303 and the target position 304 shown in FIG. 5, it is shown that the liquid crystal display unit 207 is set so that the operation torque at the time of moving image shooting is smaller than the operation torque at the time of still image shooting. You may display a message.

101 Lens device (optical equipment)
108 Lens side main CPU (control unit)
116 Operation ring (operation unit)
117 Load adjustment part (resistance change part)

Claims (19)

Operation unit and
A resistance changing unit for changing the operating resistance of the operating unit,
An optical device including a control unit capable of controlling the resistance changing unit so that the operating resistance of the operating unit during movie shooting is larger than the operating resistance of the operating unit during still image shooting.
The resistance changing part is
The drive unit and
A moving unit that can be moved so that the relative position with respect to the operating unit is changed by the driving unit.
A contact portion provided on the moving portion and capable of contacting the operation portion,
A position detection unit for detecting the position of the moving unit is provided.
An optical device characterized in that the operating resistance changes depending on the positional relationship between the contact portion and the operating portion . The operation unit can function as a first operation unit for changing the first parameter, and also as a second operation unit for changing a second parameter different from the first parameter. The optical device according to claim 1, wherein the optical instrument is also capable of functioning. The operation unit is the first operation unit or the second operation unit based on the selection result by the selection unit for selecting whether to function as the first operation unit or the second operation unit. The optical device according to claim 2, wherein the optical instrument can function as a unit. The optical device according to claim 3, wherein the control unit controls the resistance changing unit based on the selection result of the selection unit. 4. The control unit is characterized in that the resistance changing unit is controlled based on the selection result by the selection unit at the same time as the selection by the selection unit is made or after the selection is made. Optical equipment described in. The control unit is the operation unit at the time of moving image shooting in at least one of the case where the operation unit functions as the first operation unit and the case where the operation unit functions as the second operation unit. 2 . The optical device according to paragraph 1. The first parameter is any one of the focus lens position, the zoom lens position, the aperture value, and the shutter speed.
2. The second parameter is characterized in that the position of the focus lens, the position of the zoom lens, the aperture value, and the shutter speed are any of the positions different from the first parameter. The optical device according to any one of 6 to 6. One of claims 1 to 7, wherein the control unit controls the resistance change unit based on a designation result by the designation unit for designating the magnitude of the operation resistance of the operation unit. Optical equipment as described in the section. The optical device according to claim 8, wherein the control unit controls the resistance changing unit during the moving image shooting and the still image shooting based on the designated result by the designated unit. When the designated result by the designated unit is such that the operating resistance of the operating unit during the moving image shooting is smaller than the operating resistance of the operating unit during the still image shooting, the control unit may use the control unit. The feature is that the resistance changing unit is controlled so that the operating resistance of the operating unit during movie shooting is larger than the operating resistance of the operating unit during still image shooting, regardless of the specified result. The optical device according to claim 9. When the designated result by the designated unit is such that the operating resistance of the operating unit during the moving image shooting is smaller than the operating resistance of the operating unit during the still image shooting, the control unit may use the control unit. The display unit is controlled so that information indicating that the operation resistance of the operation unit during movie shooting is smaller than the operation resistance of the operation unit during still image shooting is displayed on the display unit. The optical device according to claim 9. The control unit has an operation resistance when the operation unit functions as the first operation unit when shooting a moving image and an operation resistance when the operation unit functions as the first operation unit when shooting a still image. The optical device according to any one of claims 2 to 11, wherein the resistance changing unit is controlled based on the information from the storage unit that stores the and. The control unit has an operation resistance when the operation unit functions as the second operation unit when shooting a moving image and an operation resistance when the operation unit functions as the second operation unit when shooting a still image. The optical device according to claim 12, wherein the resistance changing unit is controlled based on the information from the storage unit that stores the and. The control unit is characterized in that the resistance change unit is controlled based on the information from the storage unit that stores the designation result by the designation unit for designating the magnitude of the operation resistance of the operation unit. The optical device according to claim 12 or 13. The optical device according to any one of claims 1 to 14 , wherein the optical device is an accessory device that can be attached to and detached from a camera body that holds an image pickup element. The optical device according to claim 15 , wherein the optical device is a lens device including at least one lens. A zoom ring for changing the position of the zoom lens unit,
Further equipped with a focus ring for changing the position of the focus lens unit,
16. The 16th aspect of the present invention , wherein the operation unit is an operation ring capable of realizing a function different from the function of changing the position of the zoom lens unit and the function of changing the position of the focus lens unit. Optical equipment. The optical device according to claim 15 , wherein the optical device is a lens device including at least one lens and an adapter device that can be attached to the camera body and the camera body. The optical instrument is
The camera body that holds the image sensor and
The optical device according to any one of claims 1 to 14 , further comprising a lens device for guiding light from a subject to the image pickup device.

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