JP2013178566A - Lens barrel and camera system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a lens barrel and a camera system satisfactory in startup performance.SOLUTION: A lens barrel 20 attachable to or detachable from imaging means 10 comprises: altering means 25 capable of altering the state of the lens barrel among a first state allowing focus by the focus adjustment of optical systems L1, L2, and L3, a second state not allowing focus, and an intermediate state between the first and second states and altering the state of the lens barrel 20 on the startup of the imaging means 10 from the second state through the intermediate state to the first state; and determining means 62 for determining the state of the lens barrel by first detection means 62F for detecting the intermediate state and second detection means 62R for detecting the second state. If the determining means 62 determines that the lens barrel 20 on the startup of the imaging means 10 is in the second state, the altering means 25 alters the lens barrel 20 to the first state. If the determining means 62 determines that it is in the first state, control is exerted to prevent the intermediate state from being detected by the first detection means 62F.

Description

  The present invention relates to a lens barrel and a camera system.

  For example, in an imaging apparatus such as an interchangeable lens camera, there is a camera that minimizes the length of a lens barrel that is mounted when the camera is turned off to improve portability (for example, patents). Reference 1). When the switch is turned on in such a camera, the lens is extended from the shortest state and is ready for photographing.

JP-A-8-43710

  However, since the camera is interchangeable, a lens barrel that is not in the shortest state may be attached to the camera. In this case, when the switch of the camera is turned on, the lens is once contracted and then extended to enter the photographing state, and it takes time to start up.

  An object of the present invention is to provide a lens barrel and a camera system with good startability.

The present invention solves the above problems by the following means.
The invention according to claim 1 is a lens barrel that is detachable from the imaging means, and is in a first state in which focusing is possible by adjusting the focus of the optical system, a second state in which focusing is not possible, and the first state. And the intermediate state between the first state and the second state, and the lens barrel is changed from the second state to the first state through the intermediate state when the imaging means is activated. Determining means for determining the state of the lens barrel by a first detecting means for detecting the intermediate state and a second detecting means for detecting the second state; and the imaging means by the determining means When it is determined that the state of the lens barrel at the time of starting is the second state, the lens barrel is changed to the first state by the changing means, and is determined to be the first state. When the intermediate state is detected by the first detection means A lens barrel, characterized in that it is controlled so as not to be detected.

  In addition, the said structure may be improved suitably, and at least one part may substitute for another structure.

  According to the present invention, it is possible to provide a lens barrel and a camera system with good startability.

1 is a perspective view conceptually showing a camera as an embodiment of a camera system according to the present invention. It is a functional block diagram of a camera. It is sectional drawing of a lens-barrel, Comprising: (a) shows a shortening accommodation state, (b) shows a photography standby state, respectively. It is a chart figure of the detection signal of a lens state discrimination mechanism. It is a control flowchart when a power switch is turned off after the end of photographing. It is a control flowchart when a power switch is operated from OFF to ON. 7 is a control flowchart when the lens barrel is attached after the power of the camera body is turned on in a state where the lens barrel is not attached.

  Embodiments of the present invention will be described below with reference to the drawings. Each drawing shown below is provided with an XYZ orthogonal coordinate system as appropriate for easy explanation and understanding. In this coordinate system, the position of the camera when the photographer shoots a horizontally long image with the optical axis OA being horizontal is called a normal position. In this normal position, the direction toward the left when viewed from the photographer is the X plus direction, the direction toward the upper side is the Y plus direction, the direction toward the subject is the Z plus direction, and the direction toward the image side is the Z axis minus direction.

  1A and 1B are perspective views conceptually showing an embodiment of a camera system 1 according to the present invention, in which FIG. 1A shows a state in which a lens barrel 20 is mounted on the camera 10, and FIG. 1B shows a camera 10 and a lens. A state where the lens barrel 20 is separated is shown. FIG. 2 is a functional block diagram of the camera system 1 according to the present invention. 3A and 3B are cross-sectional views showing a schematic configuration of the lens barrel 20, wherein FIG. 3A is a shortened storage state, and FIG. 3B is an extended photographing state. FIG. 4 is a chart diagram of detection signals of the lens state determination mechanism 60 provided in the lens barrel 20.

The camera system 1 includes an interchangeable lens digital camera 10 and a lens barrel 20 that can be attached to and detached from the camera 10.
From the separated state shown in FIG. 1B, the camera 10 and the lens barrel 20 are detachably coupled by a mount mechanism 30 as shown in FIG. It is like that. Accordingly, the camera system 1 can shoot with various lens barrels 20 having different focal lengths, functions, and the like attached to the camera 10 in accordance with the shooting target.

  The lens barrel 20 attached to the camera 10 is in a compact and convenient state in which the first lens unit L1 is retracted into the fixed barrel 21 as shown by a solid line in FIG. The state is referred to as a shortened storage state), and a state in which the first lens unit L1 is extended and protruded as shown by a two-dot difference line in FIG. 1A (hereinafter referred to as an extended photographing state). One state can be taken. In the following description, the operation from the abbreviated storage state to the extended shooting state is referred to as an expansion operation, the operation from the extended shooting state to the shortened storage state is referred to as a contraction operation, and both are referred to as an expansion / contraction operation.

The mount mechanism 30 is a known bayonet mount, and includes a body mount 10M provided in the camera 10 and a lens mount 20M provided in the lens barrel 20.
The body mount 10M includes a body side contact 10T, and the lens mount 20M includes a lens side contact 20T. The body-side contact 10T and the lens-side contact 20T are in contact with each other in a state where the body mount 10M and the lens mount 20M are coupled to each other, exchange information between the camera 10 and the lens barrel 20, and the lens from the camera 10 to the lens. Power is supplied to the lens barrel 20. Further, due to the conduction between the body side contact 10T and the lens side contact 20T, a camera control device 40 (not shown in FIG. 1; see FIG. 2) described later recognizes the mounting of the lens barrel 20. Yes.

Hereinafter, each part of the camera 10 will be described in order.
The camera 10 includes a body mount 10M and a detachable button 11 on the front surface. In addition, the camera 10 includes an image pickup device 12 and a camera control device 40 (not shown in FIG. 1; see FIG. 2) for overall control of the camera 1. Further, the camera 10 includes various operation members constituting the operation unit 13 (see FIG. 2) on the outer surface thereof and a display device 14 on the rear surface.

  As described above, the body mount 10M is a component on the camera 10 side of the mount mechanism 30 and is detachably coupled to the lens mount 20M included in the lens barrel 20.

  The detachable button 11 is disposed so as to be able to be pressed from the front side of the camera 10, and has a function of releasing the engagement between the body mount 10M and the lens mount 20M by the engagement mechanism when pressed. . Further, the attach / detach button 11 is interlocked with an electrical lens barrel length shortening switch 15 (shown in FIG. 2), and pressing information of the attach / detach button 11 (that is, operation information of the lens barrel length shortening switch 15) is controlled by the camera. It is input to the device 40. The pressing (ON) information of the lens barrel shortening switch 15 is used for instructing the shortening operation of the lens barrel 20.

  The image sensor 12 is composed of a CCD or the like that converts subject light into an electrical signal. The image sensor 12 is installed inside the camera 10 such that its light receiving surface is orthogonal to the optical axis OA. The image sensor 12 is driven and controlled by the camera control device 40 and outputs electronic image information obtained by converting subject light to the camera control device 40.

The operation unit 13 includes a power switch 13A, a shutter button 13B, and a mode selection dial 13C.
The power switch 13 </ b> A is a main switch that starts energization of the camera 10. In the present embodiment illustrated in FIG. 1, the camera 10 is disposed on the upper surface.
The shutter button 13 </ b> B is a switch that instructs the camera control device 40 to perform a shooting operation, and is disposed on the upper surface of the camera 10.

The mode selection dial 13C is a switch for switching display on the display device 14 to be described later. For example, a display (live view mode) of an image (through image) captured by the image sensor 12 at that time and a reproduction display (reproduction mode) of an image (captured image) that has been captured and recorded in a storage device (not shown) ) And. The mode selection dial 13 </ b> C is disposed on the upper surface of the camera 10.
The operation unit 13 includes buttons or a dial for performing various settings (not shown) other than the above. Further, the operation mode and arrangement position of each operation member in the operation unit 13 are not limited to this embodiment, and can be set as appropriate.

  The display device 14 is configured by a liquid crystal panel or the like, and displays a through image captured by the image sensor 12, a captured image, its histogram, shooting information, and the like. Further, setting information, setting menus, setting items and the like in the camera 1 are displayed.

Although not shown, the camera control device 40 includes a CPU, a buffer memory, a storage device that stores various control programs, and the like. The camera control device 40 also includes a setting registration unit 41 that stores settings relating to control of the camera 1 arbitrarily set by the user. For example, when the power switch 13A is turned OFF, the setting registration unit 41 sets “ON / OFF” the lens barrel 20 attached to the camera 10 to the shortened storage state (hereinafter, this is referred to as a barrel length reduction setting). Is stored as control information.
The camera control device 40 comprehensively controls the entire camera 1 including the lens barrel 20 based on an operation command input via the operation unit 13 and a control program stored in the storage device. The expansion / contraction control of the lens barrel 20 by the camera control device 40 will be described in detail later.

In the camera 10 configured as described above, when the power switch 13A is turned on with the lens barrel 20 mounted as shown in FIG. It becomes possible.
When the camera 10 is controlled by the camera control device 40 and the shutter button 13B is pressed, the imaging element 12 converts the subject image formed by the lens barrel 20 into an electrical signal to obtain imaging data. Data is signal-processed as image data and recorded in a recording device (not shown).

In accordance with the operation of the operation unit 13, the display device 14 displays the photographed image, its histogram, photographing information, setting information, setting menu, setting items, and the like for the camera 1 as described above. As described above, the captured image is displayed on the display device 14 by switching the mode selection dial 13C in the operation unit 13 to the reproduction mode.
Also, if the power switch 13A of the camera 10 is in the ON state and no operation of the operation unit 13 is performed for a predetermined time, the camera control device 40 stops the power supply in the state at that time and enters the sleep state. Also performs sleep control.

Next, the lens barrel 20 will be described.
The lens barrel 20 is a zoom lens that includes three lens groups (a first lens group L1, a second lens group L2, and a third lens group L3) and can change (zoom) the focal length. Further, as described above, the lens barrel 20 is in a state (shortened storage state) in which the telescopic tube 23 (first lens group L1) shown in FIG. It is possible to take two states, that is, a state in which the telescopic cylinder 23 holding the first lens unit L1 shown in (b) protrudes from the external cylinder 21 to the front side (extended photographing state). In the shortened storage state, the front surface of the telescopic cylinder 23 substantially coincides with the front surface of the external cylinder 21. In this shortened storage state, shooting is not possible, and zooming is performed in the extended shooting state.

Hereinafter, each part of the lens barrel 20 will be described in order.
The lens barrel 20 includes a rotating cylinder 22, a telescopic cylinder 23 that holds the first lens unit L <b> 1, and a fixed inner cylinder 24 concentrically inside an external cylinder 21. Further, the lens barrel 20 includes a telescopic drive motor 25, a control board 26 constituting a lens control device 50 (not shown in FIG. 3, but shown in FIG. 2), a lens state determination mechanism 60, and the like.

The outer cylinder 21 is cylindrical and forms the outer shape of the lens barrel 20. The base end portion (image side end portion) of the external cylinder 21 is fixed to the back plate 27 constituting the lens mount 20M.
The rotary cylinder 22 is fitted to the inner periphery of the external cylinder 21 so as to be rotatable and immovable in the direction of the optical axis OA. A spiral cam groove 22 </ b> A is formed on the inner peripheral surface of the rotary cylinder 22. In this cam groove 22A, a cam follower 23B of a telescopic cylinder 23 described later is slidably fitted.
Further, an inner peripheral gear 22G is formed on the inner peripheral portion of the image side end portion of the rotating cylinder 22. The inner peripheral gear 22G meshes with a drive gear 25G of a telescopic drive motor 25 described later.

The telescopic cylinder 23 is formed in a cylindrical shape with an outer diameter that is slidably fitted to the inner peripheral surface of the rotary cylinder 22, and the telescopic cylinder 23 has an annular holding portion 23A on the inner periphery on the front surface side. The first lens unit L1 is held via the.
A cam follower 23B projects from the outer peripheral surface of the telescopic cylinder 23, and this cam follower 23B is fitted in a cam groove 22A of the rotary cylinder 22 so as to be slidable.
Further, a rectilinear groove 23C is formed in parallel with the optical axis OA on the inner periphery of the telescopic cylinder 23. A rectilinear guide protrusion 24A of a fixed inner cylinder 24 described later is fitted in the rectilinear groove 23C so as to be slidable.

  Further, a protrusion 61 constituting the lens state determination mechanism 60 is formed on the inner periphery of the telescopic cylinder 23. The protruding portion 61 is a plate having a predetermined thickness, and extends from the holding portion 23A toward the image side in parallel with the optical axis OA direction. An edge on the image side of the protruding portion 61 is a detected portion 61A described later. The arrangement position of the projecting portion 61 corresponds to a sensor 62 (first sensor 62F, second sensor 62R) provided on the fixed inner cylinder 24 described later.

The fixed inner cylinder 24 is fixed to the back plate 27 at its base end. The end portion on the front side of the fixed inner cylinder 24 is retracted to the image side from the front end face of the outer appearance cylinder 21.
Further, a rectilinear guide protrusion 24 </ b> A protrudes from the outer peripheral side of the front end portion of the fixed inner cylinder 24. The rectilinear guide protrusion 24A is fitted in the rectilinear groove 23C of the telescopic cylinder 23 so as to be slidable.

  Further, the fixed inner cylinder 24 includes a pair of (two) sensors 62 (a first sensor 62F and a second sensor 62R) that constitute a lens state determination mechanism 60 together with the protrusion 61 formed on the telescopic cylinder 23. . The first sensor 62F is provided at the front end of the fixed inner cylinder 24, and the second sensor 62R is provided at a predetermined interval from the first sensor 62F to the image side in the optical axis OA direction.

  The sensor 62 is a photo interrupter in which a light emitting portion and a light receiving portion are arranged to face each other, and is arranged so as to detect a protruding portion 61 in the telescopic cylinder 23 described later. That is, the output of the sensor 62 is turned off when there is no shielding object in the detection area, and the output is turned on when the protruding portion 61 crosses the detection area.

As described above, the lens state discriminating mechanism 60 is constituted by the sensor 62 (first sensor 62F, second sensor 62R) provided on the fixed inner cylinder 24 and the protrusion 61 formed on the telescopic cylinder 23. Yes.
Here, the protrusion 61 and the sensor 62 (the first sensor 62F and the second sensor 62R) are configured in the following positional relationship.

  In the shortened storage state shown in FIG. 3A, the protruding portion 61 is located in the detection area of the first sensor 62F, and the detected portion 61A is exactly located in the detection area of the second sensor 62R. This is because when the output signal of the first sensor 62F is ON and the telescopic cylinder 23 (first lens unit L1) is moved toward the image side by the storing operation from the extended photographing state, the second sensor 62R. This is the position where the output signal switches from OFF to ON. Hereinafter, the signal state in the shortened storage state is [1, 1].

  On the other hand, when the telescopic cylinder 23 (first lens unit L1) extends from the shortened storage state, the protruding portion 61 continues to be positioned in the detection area of the first sensor 62F, but the detected portion 61A is detected by the second sensor 62R. Get out of range. As a result, the output signal of the first sensor 62F is turned on and the output signal of the second sensor 62R is turned off. The signal state in this intermediate state is [1, 0].

  In the extended photographing state shown in FIG. 3B, the protruding portion 61 is out of the detection area of the second sensor 62R, and the detected part 61A is positioned just in the detection area of the first sensor 62F. This is because when the output signal of the second sensor 62R is OFF and the telescopic cylinder 23 (first lens unit L1) moves toward the front side by the extension operation, the output signal of the first sensor 62F is This is the position where the switch is made from ON to OFF. The signal state in this extended photographing state is [0, 0].

With the configuration of the lens state discriminating mechanism 60 as described above, the expansion / contraction state of the lens barrel 20 can be grasped from the output signal. That is, as shown in FIG. 4, if both the output signals of the first sensor 62F and the second sensor 62R are ON (signal [1, 1]), the storage state is shortened, and the first sensor 62F and the second sensor 62R If the output signals of both are OFF (signal [0, 0]), the camera is in an expanded shooting state. Further, when the output signal of the first sensor 62F is ON and the output signal of the second sensor 62R is OFF (signal [1, 0]), it is understood that the intermediate state is between the shortened storage state and the extended photographing state.
The output signal of the lens state determination mechanism 60 is input to the lens control device 50 as lens state detection information.

Inside the fixed inner cylinder 24, a second lens group L2 and a third lens group L3 are provided so as to be movable in the direction of the optical axis OA. The focal length of the lens barrel 20 changes (zooming) by the movement of the second lens unit L2 and the third lens unit L3 in the direction of the optical axis OA. This zooming operation is performed by a zoom drive mechanism (not shown) in accordance with an operation of a zoom switch 28 provided on the outer peripheral surface of the external cylinder 21.
The third lens unit L3 is a focusing lens and can be independently driven to move in the direction of the optical axis OA. The focal position changes due to the movement of the third lens unit L3 in the direction of the optical axis OA. To adjust the focus.

  The telescopic drive motor 25 is disposed on the image side (back plate 27 side) between the outer cylinder 21 and the fixed inner cylinder 24 with the rotation axis parallel to the optical axis OA. A drive gear 25G is fixed to the rotation shaft of the telescopic drive motor 25, and the drive gear 25G meshes with the inner peripheral gear 22G of the rotary cylinder 22. Thereby, the telescopic drive motor 25 is configured to rotationally drive the rotary cylinder 22 by its rotation. The telescopic drive motor 25 is driven and controlled by a lens control device 50 described later, and rotates in both forward and reverse directions. That is, the telescopic drive motor 25 drives the rotary cylinder 22 to rotate in both forward and reverse directions.

  The control board 26 is disposed at a position adjacent to the back plate 27 between the outer cylinder 21 and the fixed inner cylinder 24. The control board 26 is mounted with a CPU or the like and constitutes a lens control device 50.

  In the lens barrel 20 configured as described above, the telescopic cylinder 23 cannot rotate because the rectilinear guide protrusion 24A of the fixed inner cylinder 24 is fitted in the rectilinear groove 23C, but the rectilinear groove 23C It is movable in the extending direction (that is, the direction parallel to the optical axis OA). The cam follower 23B of the telescopic cylinder 23 is fitted in the cam groove 22A of the rotary cylinder 22 so as to be slidable. As a result, when the rotary cylinder 22 rotates, the cam follower 23B of the telescopic cylinder 23 is moved in the optical axis OA direction according to the displacement of the cam groove 22A in the optical axis OA direction. That is, when the rotary cylinder 22 is rotationally driven by the expansion / contraction driving motor 25, the expansion / contraction cylinder 23 moves in the direction of the optical axis OA. The expansion / contraction drive motor 25 is controlled and driven by the lens control device 50 as described above. That is, the lens control device 50 controls the expansion / contraction operation of the expansion / contraction cylinder 23.

  When the lens barrel 20 is coupled to the camera 10 by the mount mechanism 30, the lens control device 50 is connected to the camera control device 40 of the camera 10 through the lens mount 20M (mount mechanism 30) so that information can be exchanged. Then, the lens control device 50 grasps the expansion / contraction state of the lens barrel 20 based on the input information from the lens state determination mechanism 60 and sends the state information to the camera control device 40 of the camera 10. The expansion / contraction drive motor 25 is driven and controlled on the basis of a command sent from 40.

  As described above, the camera system 1 configured by the camera 10 and the lens barrel 20 has a lens barrel that the camera control device 40 of the camera 10 sends via the operation of the operation unit 13 and the lens control device 50. The expansion / contraction control of the lens barrel 20 is performed via the lens control device 50 based on the status information 20 and a predetermined program.

  Next, expansion / contraction control of the lens barrel 20 by the camera control device 40 will be described with reference to flowcharts shown in FIGS. In the following description and drawings, “step” is also abbreviated as “S”.

First, the control when the power switch 13A is turned off after the end of photographing shown in the flowchart of FIG. 5 will be described.
At the time when the photographing is finished, the lens barrel 20 is in an extended photographing state. When the power switch 13A is turned off from this state, the camera control device 40 refers to the “lens barrel length shortening setting” in the setting registration unit 41, and the lens barrel 20 ( The telescopic drive motor 25) is controlled and driven.

That is, when the power switch 13A is turned OFF (S01), it is determined whether or not “lens barrel length shortening setting” is set to “shorten the lens barrel length when the power is turned off” (S02).
In step 02, when it is determined that the “lens barrel length shortening setting” is set to “shorten the lens barrel length when the power is turned off” (Yes), the telescopic drive motor 25 is driven to the contraction operation side. (S03), it is determined when the lens barrel 20 is in the shortened storage state (S04).
The determination that the lens barrel 20 is in the shortened retracted state in step 04 is made when the lens control device 50 detects the signal [1, 1] in the lens state determining mechanism 60.

In step 04, when it is determined that the lens barrel 20 is in the shortened storage state (Yes), the storage operation (drive of the telescopic drive motor 25) is stopped (S05). Thereby, the lens barrel 20 is in a shortened storage state, and the power is turned off (S06).
On the other hand, if the “lens barrel length shortening setting” is set to “do not shorten the barrel length when the power is turned off” in step 02 (No), the telescopic drive motor 25 is not driven (lens barrel). 20 remains in the extended shooting state), only the function of the lens barrel length shortening switch 15 is enabled, the power is turned off (S07), and the ON operation of the lens barrel length shortening switch 15 (that is, the pressing operation of the detachable button 11) is determined. (S08).
If it is determined in step 08 that the lens barrel length shortening switch 15 is turned on (Yes), each step of the storing operation after step 03 is executed, and the power is turned off as the shortened storing state ( S06).

  According to the control when the power switch 13A is turned off as described above, “no barrel length reduction is set when the power is turned off” is set in the “lens barrel length shortening setting” of the setting registration unit 41 in the camera control device 40. Accordingly, the power can be turned off while the lens barrel 20 is in the extended photographing state. As a result, when the power is turned on next time, an extension operation for changing the lens barrel 20 from the shortened retracted state to the extended photographing state becomes unnecessary.

  That is, if the lens control device 50 is in the extended photographing state in which the signal [0, 0] of the lens state determination mechanism 60 is detected, the initial operation of once moving the lens barrel 20 to a predetermined state and grasping the position. Without performing the above, it is possible to immediately recognize the extended shooting state and perform the subsequent control. For this reason, if the power switch 13A is turned on, it is possible to take a picture in an extremely short time, and it is possible to avoid a problem that a photo opportunity is missed due to the initialization operation.

  Further, when the lens barrel shortening switch 15 is pressed while the lens barrel 20 is in the extended photographing state and the power is OFF, the contraction drive is performed. For this reason, even if the “lens barrel length shortening setting” is set to “do not shorten the lens barrel length when the power is turned off”, the lens barrel 20 can be arbitrarily shortened and stored after the power is turned off.

Next, control when the power switch 13A is operated from OFF to ON as shown in the flowchart of FIG. 6 will be described.
When the power switch 13A is turned on (S11), whether the lens barrel 20 is in the shortened retracted state (whether the lens control device 50 detects the signal [1, 1] in the lens state determining mechanism 60). Is determined (S12).

If it is determined in step 12 that the lens barrel 20 is in the shortened retracted state (Yes), the expansion / contraction drive motor 25 is driven to extend (S13), and the lens barrel 20 is in the extended photographing state. Is determined (S14).
The determination that the lens barrel 20 is in the extended photographing state is performed when the lens control device 50 detects the signal [0, 0] in the lens state determination mechanism 60.
If it is determined in step 14 that the lens barrel 20 is in the extended shooting state (Yes), the extension operation (drive of the extension drive motor 25) is stopped (S15). As a result, the lens barrel 20 is in an extended photographing state.

On the other hand, when it is determined in step S12 that the lens barrel 20 is not in the shortened storage state (No), it is next determined whether or not the lens barrel 20 is in the intermediate state (S16).
The determination that the lens barrel 20 is in the intermediate state is performed when the lens control device 50 detects the signal [1, 0] in the lens state determination mechanism 60.

If it is determined in step 16 that the lens barrel 20 is in the intermediate state (Yes), the above-described steps 13 to 15 are executed to place the lens barrel 20 in the extended photographing state.
If it is determined in step 16 that the lens barrel 20 is not in the intermediate state (No), the lens barrel 20 is in the extended shooting state (that is, the lens control device 50 outputs the signal [0, 0] in the lens state determination mechanism 60). Or the lens barrel 20 is not mounted, and the control is terminated.

In the control as described above, when the power switch 13A is turned ON, the lens barrel 20 is set in the extended photographing state regardless of the state at that time.
That is, according to the control when the power switch 13A shown in the flowchart of FIG. 5 is turned off, the lens barrel 20 is in the shortened retracted state and the extended photographing state when the camera 1 (camera 10) is turned off. There is also a possibility that the lens barrel 20 is attached / detached in one state and further in the power-off state, and the intermediate lens barrel 20 is attached.
According to the control when the power switch 13A is turned on, in any of these states, the lens barrel 20 can be set to the extended photographing state in accordance with the power switch 13A being turned on.

Next, the control in the case where the lens barrel 20 is attached after the camera 10 is turned on with the lens barrel 20 not attached as shown in the flowchart of FIG. 7 will be described.
When the lens barrel 20 is attached with the camera 10 powered on (S21), it is first determined whether or not the camera 10 is in the shooting mode (S22).
If it is determined in step 22 that the state of the camera 10 is not the shooting mode (No), the control is terminated as it is the playback mode.

On the other hand, if it is determined in step 22 that the camera 10 is in the shooting mode (Yes), it is next determined whether or not the attached lens barrel 20 is in the extended shooting state (S23).
If it is determined in step 23 that the lens barrel 20 is in the extended shooting state (Yes), the control is terminated as it is.

If it is determined in step 23 that the lens barrel 20 is not in the extended shooting state (No), it is next determined whether or not the lens barrel 20 is in an intermediate state (S24).
If it is determined in step 24 that the lens barrel 20 is not in the intermediate state (No), the camera 10 is set in the sleep state (S25), and the control is terminated.
If it is determined in step 24 that the lens barrel 20 is in the intermediate state (Yes), a warning message “The lens barrel 20 in the intermediate state is mounted” is displayed on the display device 14 ( S26), the control is terminated.

  In the control as described above, when the lens barrel 20 in the shortened storage state is attached to the camera 10 in the shooting mode with the power turned on, the camera 10 enters the sleep state. When the intermediate lens barrel 20 is attached, a warning is displayed. As a result, it is possible to prevent problems caused by the lens barrel 20 being extended as soon as the lens barrel 20 is attached to the camera 10.

The camera 10 in the sleep state is released from the sleep state by operating any one of the operation members of the operation unit 13. When the sleep state is canceled, the same control as when the power is turned on as shown in the flowchart of FIG. 6 is performed, and the lens barrel 20 enters the extended photographing state.
When the intermediate lens barrel 20 is mounted on the camera 10 and a warning is displayed, the power switch 13A is turned off once and turned on again to turn on the power shown in the flowchart of FIG. The time control is performed, and the lens barrel 20 enters the extended photographing state.

  Further, when the camera 10 is in the reproduction mode, the lens barrel 20 does not operate in any state in the above control. In this case, by switching the mode selection dial 13C to the photographing mode, the same control as that when the power is turned on is performed, and the lens barrel 20 enters the extended photographing state.

As described above, this embodiment has the following effects.
(1) In the camera 1, the lens barrel 20 can take different states between the shortened storage state and the extended photographing state. The lens barrel 20 includes two sensors 62 (a first sensor 62F and a second sensor 62R) and a protruding portion 61 detected by the sensor 62, and the lens barrel 20 is in a shortened retracted state and extended photographing. The lens state discriminating mechanism 60 is provided so that the combination of output signals from the sensor 62 differs from the state. Thereby, the state of the lens barrel 20 can be recognized by the output signal of the lens state determination mechanism 60, and the subsequent control can be performed based on the state.

(2) According to the control when the power switch 13A is turned off by the camera control device 40, the “lens length shortening setting” of the setting registration unit 41 in the camera control device 40 is set to “no shortening of the lens barrel length when the power is turned off” ”Is set, the power can be turned off while the lens barrel 20 is in the extended photographing state. As a result, when the power is turned on next time, it is possible to immediately take a picture without performing the extending operation of the lens barrel 20, and it is possible to avoid the problem of missing a photo opportunity for the initialization operation.

(3) According to the control by the camera control device 40 when the power switch 13A is turned off, when the lens barrel 20 is in the extended photographing state and the power is turned off and the detachable button 11 is pressed, the contraction drive is performed. Do. For this reason, even if the “lens barrel length shortening setting” is set to “do not shorten the lens barrel length when the power is turned off”, the lens barrel 20 can be arbitrarily shortened and stored after the power is turned off. Further, when the detachable button 11 is pressed to replace the lens, the lens barrel 20 is retracted to enter a shortened retracted state. Thereby, the lens barrel 20 in a single state removed from the camera 10 is fixed in a compact shortened storage state.

(4) According to the control when the power switch 13A is turned on by the camera control device 40, when the power switch 13A is turned on, the lens barrel 20 is in any state such as a shortened storage state or an intermediate state at that time. Even if it exists, it can be set as an expansion photography state.

(5) According to the control performed by the camera control device 40 when the lens barrel 20 is attached after the power of the camera 10 is turned on with the lens barrel 20 not attached, the image is taken with the power turned on. When the lens barrel 20 in the shortened storage state is attached to the camera 10 in the mode, the camera 10 enters the sleep state. When the intermediate lens barrel 20 is attached, a warning is displayed. As a result, it is possible to prevent problems caused by the lens barrel 20 being extended as soon as the lens barrel 20 is attached to the camera 10.

(Deformation)
The present invention is not limited to the above-described embodiment, and various modifications and changes as described below are possible, and these are also within the scope of the present invention.
(1) In the present embodiment, the expansion / contraction control of the lens barrel 20 has been described as being performed by the camera control device 40 included in the camera 10 based on the lens state information input from the lens control device 50. However, the camera control device 40 may be configured to grasp the lens state information, and the lens control device 50 may be configured to perform expansion / contraction control of the lens barrel 20. Furthermore, the camera control device 40 and the lens control device 50 may be configured to appropriately share and control.

(2) In the present embodiment, the sensor 62 (first sensor 62F, second sensor 62R) in the lens state determination unit 60 is configured by a photo interrupter. However, the detection means is not limited to this, and any other means may be used as long as detection is possible.

(3) In this embodiment, the detachable button 11 and the lens barrel length shortening switch 15 are configured to be interlocked. However, the lens barrel length shortening switch 15 may be provided independently.

  In addition, although embodiment and a deformation | transformation form can also be used in combination as appropriate, detailed description is abbreviate | omitted. Further, the present invention is not limited to the embodiment described above.

  1: Camera, 10: Camera body, 11: Detachable button, 12: Image sensor, 13: Operation unit, 13A: Power switch, 13B: Shutter button, 13C: Mode selection dial, 14: Display device, 15: Lens barrel length Shortening switch, 20: lens barrel, 21 external cylinder, 23: telescopic cylinder, 25: telescopic drive motor, 30: mount mechanism, 10M: body mount, 10T: body side contact, 20M: lens mount, 20T: lens side contact , 40: camera control device, 41: setting registration unit, 50: lens control device, 60: lens state determination means, 61: protruding portion, 61A: detected portion, 62: sensor, 62F: first sensor, 62R: first 2 sensors, OA: optical axis, L1: first lens group

Claims (5)

A lens barrel detachable from the imaging means,
The state of the lens barrel can be changed to a first state where focusing is possible by adjusting the focus of the optical system, a second state where focusing is not possible, and an intermediate state between the first state and the second state. ,
Changing means for changing the lens barrel from the second state to the first state via the intermediate state when the imaging means is activated;
Discriminating means for discriminating the state of the lens barrel by first detecting means for detecting the intermediate state and second detecting means for detecting the second state;
When the determining means determines that the state of the lens barrel when starting the imaging means is the second state, the changing means changes the lens barrel to the first state, When it is determined that the state is the first state, the lens barrel is controlled so that the intermediate state is not detected by the first detection unit. The lens barrel according to claim 1,
The second state is a state in which the length of the lens barrel along the optical axis direction of the optical system is shorter than the first state. The lens barrel according to claim 2,
The lens barrel according to claim 2, wherein the second state is a state in which at least a part of the optical system is moved to the imaging means side as compared with the first state. The lens barrel according to claim 3,
When the state of the lens barrel at the time of starting up the imaging unit is determined to be the second state, the first detection unit is controlled to detect the intermediate state. Lens barrel.   A camera system comprising the lens barrel according to any one of claims 1 to 4.

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