JP2009282378A - Imaging apparatus and imaging apparatus body - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a technique for allowing a user to visually recognize a photographing range corresponding to an interchangeable lens, while suppressing the cost of an imaging apparatus. <P>SOLUTION: The imaging apparatus 1A includes: the interchangeable photographic lens 3; a main imaging element 5 which obtains a photographed image on a subject image formed by the photographic lens 3; a lens information obtaining means which obtains the lens information of the photographic lens 3; a finder means for confirming the photographing range by the main imaging element 5; a determination section 122 which determines whether or not the photographic lens 3 is suitable for the main imaging element 5, based on the lens information; and a changing means which shields part of subject light forming the subject image, to change the photographing range shown on the finder means, according to the determination result of the determination section 122. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an imaging device in which a photographic lens can be replaced, and an imaging device main body in the imaging device.

  In an imaging device with interchangeable lenses, a circular range (also referred to as an “image circle”) in which an image is formed differs for each interchangeable lens (photographing lens) to be mounted. Some elements are not compatible.

  Specifically, when the size of the image circle of the interchangeable lens is smaller than the size of the image sensor and the image sensor protrudes from the image circle of the interchangeable lens, vignetting occurs in the acquired captured image.

  On the other hand, for example, in Patent Document 1, the photographing use area used for generating image data in the image sensor is changed for each attached interchangeable lens.

  Further, in Patent Document 1, a liquid crystal display (LCD) member is provided in the finder optical system, and a frame display corresponding to the shooting use area is changed according to the mounted interchangeable lens, so that the shootable object field can be changed. A technique for indicating a range (photographing range) within the field of view of an optical viewfinder has been proposed.

JP 2005-277963 A

  However, in the technique described in Patent Document 1, an expensive member called an LCD is used to allow the user to visually recognize the photographing range corresponding to the attached interchangeable lens, so that the cost of the imaging device is increased.

  Therefore, an object of the present invention is to provide a technique that allows a user to visually recognize an imaging range corresponding to an interchangeable lens while suppressing the cost of an imaging apparatus.

  A first aspect of the present invention is an imaging apparatus, which is an interchangeable imaging lens, an imaging device that acquires a captured image related to a subject image formed by the imaging lens, and lens information of the imaging lens Lens information acquisition means, a finder means for confirming a photographing range by the image sensor, a determination means for determining whether or not the photographing lens is compatible with the image sensor based on the lens information, According to a determination result of the determination unit, a change unit that blocks part of the subject light forming the subject image and changes the photographing range indicated by the finder unit is provided.

  According to a second aspect of the present invention, there is provided an imaging apparatus, an interchangeable imaging lens, an imaging element that acquires a captured image related to a subject image acquired by the imaging lens, and the subject image as a viewfinder image. A finder optical system that leads to a finder window along a predetermined optical path, a translucent member that represents a line drawing showing a photographing range by the imaging device corresponding to the photographing lens, and the translucent member, Provided on the predetermined optical path, the line drawing is superimposed on the viewfinder image.

  According to a third aspect of the present invention, there is provided an imaging device main body, an imaging element that acquires a photographic image related to a subject image formed by an interchangeable photographic lens, and a lens that acquires lens information of the photographic lens. Information acquisition means, finder means for confirming the photographing range by the image sensor, determination means for determining whether the photographing lens is compatible with the image sensor based on the lens information, and the determination means According to the determination result, a part of the subject light that forms the subject image is shielded, and a changing unit that changes the photographing range indicated by the finder unit is provided.

  According to a fourth aspect of the present invention, there is provided an imaging device main body, an imaging device for acquiring a photographic image related to a subject image acquired by an interchangeable photographic lens, and a predetermined optical path using the subject image as a finder image. A finder optical system that leads to a finder window along the line, a translucent member on which a line drawing indicating a photographing range by the imaging element corresponding to the photographing lens is represented, and the translucent member includes the predetermined light Provided on the road, the line drawing is superimposed on the viewfinder image.

  According to the present invention, it is possible to change the photographing range indicated by the finder unit in accordance with the photographing lens while suppressing the cost of the imaging device.

  Embodiments of the present invention will be described below with reference to the drawings.

<1. First Embodiment>
<Configuration>
1 and 2 are diagrams showing an external configuration of an imaging apparatus 1A according to the first embodiment of the present invention. Here, FIG. 1 is a front external view of the image pickup apparatus 1A, and FIG. 2 is a rear external view of the image pickup apparatus 1A. This imaging device 1A is configured as a lens interchangeable single-lens reflex digital camera.

  As shown in FIG. 1, the imaging device 1 </ b> A includes an imaging device main body (camera main body) 2. An interchangeable photographic lens unit (also simply referred to as “photographing lens” or “interchangeable lens”) 3 can be attached to and detached from the camera body 2.

  The photographic lens 3 is mainly composed of a lens barrel 101, a lens group 37 (see FIG. 3) and an aperture (not shown) provided inside the lens barrel 101, and the like. The lens group 37 includes a focus lens that changes the focal position by moving in the optical axis direction.

  The camera body 2 is provided with an annular mount Mt to which the photographing lens 3 is attached at the front center, and an attachment / detachment button 89 for attaching / detaching the photographing lens 3 is provided near the annular mount Mt.

  Further, the camera body 2 is provided with a mode setting dial 82 in the upper left part of the front surface and a control value setting dial 86 in the upper right part of the front surface. By operating the mode setting dial 82, various camera modes (such as various shooting modes (such as portrait shooting mode, landscape shooting mode, and continuous shooting mode), a playback mode for playing back captured images, and external devices can be used. It is possible to perform a setting operation (switching operation) including a communication mode for performing data communication. Further, by operating the control value setting dial 86, it is possible to set control values in various shooting modes.

  Further, the camera body 2 includes a grip portion 14 for the user to hold at the left front end portion. A release button (shutter button) 11 for instructing the start of exposure is provided on the upper surface of the grip portion 14. A battery storage chamber and a card storage chamber are provided inside the grip portion 14. For example, four AA batteries are housed in the battery compartment as a power source for the camera, and the card compartment contains a recording medium (here, a memory card 90 (FIG. 5)) is detachably stored.

  The release button 11 is a two-stage detection button that can detect two states, a half-pressed state (S1 state) and a fully-pressed state (S2 state). When the release button 11 is half-pressed to enter the S1 state, a preparation operation (for example, an AF control operation and an AE control operation) for acquiring a recording still image (main captured image) related to the subject is performed. When the release button 11 is further pushed into the S2 state, an exposure operation relating to the subject image is performed using the photographing operation (imaging element (or “main imaging element”)) 5 (described later) of the actual photographed image. A series of operations for performing predetermined image processing on the image signal obtained by the exposure operation) is performed.

  In FIG. 2, a monitor 12 is provided as a display unit approximately at the center of the back surface of the camera body 2. The monitor 12 is configured as a color liquid crystal display (LCD), for example. The monitor 12 can display a menu screen for setting shooting conditions and the like, and can reproduce and display a captured image recorded in the memory card 90 in the reproduction mode.

  A finder window 10 is provided at the upper center of the back surface of the camera body 2. The subject image from the photographic lens 3 is guided to the finder window 10, and the user can visually recognize an image equivalent to the subject image acquired by the main image sensor 5 by looking into the finder window 10. Specifically, the subject image incident on the photographing optical system is reflected upward by the mirror mechanism 6 (see FIG. 3) and viewed through the eyepiece lens 67. Thus, the user can determine the composition by looking through the finder window 10. When the photographing operation of the main photographed image is started by detecting the S2 state of the release button 11, the mirror mechanism 6 is retracted from the light path of the light (subject light) forming the subject image, and the light from the photographing lens 3 ( (Light forming the subject image) reaches the main image sensor 5 and a photographed image (image data) relating to the subject is obtained.

  An eyepiece detection sensor 13 is provided below the finder window 10. The eyepiece detection sensor 13 is a sensor that detects the presence or absence of a proximity object, and detects whether or not the user is using an optical viewfinder.

  A main switch 81 is provided at the upper left of the monitor 12. The main switch 81 is composed of two slide switches. When the contact is set to the left “OFF” position, the imaging apparatus 1A is turned off, and when the contact is set to the right “ON” position, the imaging is performed. The apparatus 1A is turned on.

  A direction selection key 84 and a display changeover switch 9 are provided on the right side of the monitor 12. The direction selection key 84 has a circular operation button, and it is possible to detect a pressing operation in four directions of upper, lower, left and right, and a pressing operation in four directions of upper right, upper left, lower right and lower left on the operation button. It has become. In addition, the direction selection key 84 is configured to detect a pressing operation of a push button at the center, in addition to the pressing operations in the eight directions.

  The display changeover switch 9 is composed of three slide switches. When the contact of the display changeover switch 9 is set to the upper “optical” position, the optical viewfinder mode (also referred to as “OVF mode”) is selected, and the subject image is displayed in the optical viewfinder field of view. Accordingly, the user can visually recognize the subject image in the optical finder field through the finder window 10 and perform a composition determination operation (also referred to as “framing”).

  Further, when the contact point of the display changeover switch 9 is set to the lower “liquid crystal” position, an electronic viewfinder mode (also referred to as “EVF mode”) is selected, and the live view image related to the subject image on the monitor 12 is a moving image mode. Is displayed (live view display). Accordingly, the user can perform framing by visually recognizing the live view image displayed on the monitor 12.

  Further, when the contact of the display changeover switch 9 is set to the middle “automatic” position, the display in the optical finder field of view (also referred to as “OVF display”) and the live view depending on the presence or absence of the eyepiece on the finder window 10. The display is automatically switched. Thus, the user can perform framing by visually recognizing either the display in the optical finder field of view or the live view display according to the usage mode of the imaging apparatus 1A.

  On the left side of the monitor 12, a setting button group 83 including a plurality of buttons for setting a menu screen, deleting an image, and the like is provided.

  Next, the internal configuration of the imaging apparatus 1A will be described. 3 and 4 are longitudinal sectional views of the imaging apparatus 1A according to the first embodiment.

  As shown in FIG. 3, in the imaging apparatus 1 </ b> A, a finder unit (also referred to as “finder optical system”) 102, a mirror mechanism 6, a phase difference AF module (hereinafter also simply referred to as AF module) 20, a shutter 4, A main image sensor 5 and a sub image sensor 7 are provided.

  The main image pickup element (here, a CCD sensor (also simply referred to as a CCD)) 5 is disposed on a plane perpendicular to the optical axis L on the optical axis L of the lens group 37 provided in the photographing lens 3. The main imaging element 5 converts the subject image received on the imaging surface into an electrical signal by photoelectric conversion action, and generates an image signal related to the actual captured image.

  The main image sensor 5 of the present embodiment employs an image sensor having a size equivalent to a 35 mm film.

  A shutter 4 is disposed immediately before the main image sensor 5. The shutter 4 is a mechanical focal plane shutter that includes a curtain body that moves in the vertical direction and performs an optical path opening operation and an optical path blocking operation of subject light guided to the main image sensor 5 along the optical axis L.

  As shown in FIG. 3, a mirror mechanism 6 is provided on an optical path (also referred to as “imaging optical path”) from the imaging lens 3 to the main image sensor 5.

  The mirror mechanism 6 has a main mirror 61 (main reflection surface) that reflects light from the photographing optical system upward. For example, a part or all of the main mirror 61 is configured as a half mirror, and transmits a part of light from the photographing optical system. The mirror mechanism 6 also includes a sub mirror 62 (sub reflective surface) that reflects light transmitted through the main mirror 61 downward.

  Further, the mirror mechanism 6 is configured as a so-called quick return mirror, and the posture can be switched between a mirror-down state and a mirror-up state.

  Specifically, the mirror mechanism 6 is arranged so as to be in the mirror-down state until the release button 11 is fully pressed in the shooting mode, in other words, when determining the composition (see FIG. 3). . In the mirror-down state, the subject light from the photographic lens 3 is reflected upward by the main mirror 61 and enters the finder unit (also referred to as “finder optical system”) 102 as an observation light beam. Details of the finder unit 102 will be described later.

  A part of the subject light is transmitted through the main mirror 61, reflected downward by the sub mirror 62, and guided to the AF module 20.

  The AF module 20 includes a line sensor (focus detection sensor) that detects focus information (also referred to as “ranging information”) of a subject, and functions as a so-called AF sensor. Specifically, the AF module 20 receives light from a subject in a distance measurement area (also referred to as “focus area” or “AF area”) set in the shooting area, and according to the degree of focus of the subject image. A phase difference detection function for generating a phase difference detection signal. That is, in the mirror-down state during shooting standby, the AF module 20 outputs a phase difference detection signal based on subject light guided to the AF module 20.

  As described above, the AF module 20 functions as a shooting information acquisition unit that acquires distance measurement information as shooting information from an AF area fixedly set at a predetermined position in the shooting area.

  On the other hand, when the release button 11 is fully pressed S2, the mirror mechanism 6 is driven so as to be in the mirror up state (see FIG. 4), and the exposure operation is started.

  Specifically, as shown in FIG. 4, at the time of exposure, the mirror mechanism 6 jumps upward with the rotating shaft 63 as a fulcrum and retracts from the photographing optical path. Specifically, the main mirror 61 and the sub mirror 62 are retracted upward so as not to block the light from the photographing optical system, and the light from the photographing lens 3 reaches the main image sensor 5 in accordance with the opening timing of the shutter 4. . The main imaging device 5 generates an image signal related to the subject image based on the received light flux by photoelectric conversion. As described above, the light from the subject is guided to the main image sensor 5 through the photographing lens 3, so that a photographed image (photographed image data) relating to the subject is obtained.

<Functional block>
Next, an outline of functions of the imaging apparatus 1A will be described. FIG. 5 is a block diagram illustrating a functional configuration of the imaging apparatus 1A according to the first embodiment.

  As illustrated in FIG. 5, the imaging apparatus 1A includes a phase difference AF module 20, an operation unit 80, an overall control unit 100, a mirror mechanism 6, a shutter 4, a main imaging device 5, an A / D conversion circuit 52, and digital signal processing. A circuit 50 and an image memory 56 are provided.

  The operation unit 80 includes various buttons and switches including the release button 11 (see FIG. 1). In response to a user input operation on the operation unit 80, the overall control unit 100 implements various operations.

  The main image sensor 5 responds to drive control signals (accumulation start signal and accumulation end signal) input from a timing control circuit (not shown), and exposes the subject image formed on the light receiving surface (imaging surface) ( Charge accumulation by photoelectric conversion) is performed, and an image signal related to the subject image is generated.

  The image signal (analog signal) acquired by the main image sensor 5 is converted into a digital signal by the A / D conversion circuit 52. The image signal converted into the digital signal is input to the digital signal processing circuit 50.

  The digital signal processing circuit 50 performs digital signal processing on the image signal input from the A / D conversion circuit 52. Specifically, signal processing such as black level correction processing, white balance (WB) processing, and γ correction processing is performed. The image signal (image data) after the signal processing is stored in the image memory 56.

  The image memory 56 is a high-speed accessible image memory for temporarily storing the generated image data, and has a capacity capable of storing image data for a plurality of frames.

  At the time of actual photographing, the image data temporarily stored in the image memory 56 is subjected to image processing (compression processing or the like) as appropriate in the overall control unit 100 and then stored in the memory card 90.

  The sub image sensor 7 basically has the same function as the main image sensor 5 and plays a role as a so-called live view image acquisition (electronic finder) image sensor (auxiliary image sensor). Specifically, the sub image sensor 7 exposes the subject image guided to the finder optical system, and acquires an image signal related to an image for live view display. Note that the sub image sensor 7 only needs to have a resolution for generating an image signal for live view, and is usually configured with a smaller number of pixels than the main image sensor 5.

  The image data acquired by the sub imaging device 7 is subjected to predetermined processing in the A / D conversion circuit 52 and the digital signal processing circuit 50, temporarily stored in the image memory 56, and then displayed on the monitor 12.

  The overall control unit 100 is configured as a microcomputer and mainly includes a CPU, a RAM 120A, a ROM 120B, and the like. The overall control unit 100 implements various functions by reading a program stored in the ROM 120B and executing the program by the CPU.

  The overall control unit 100 executes a phase difference AF control unit 121, a determination unit 122, a drive control unit 123, an image frame shutter control unit 124, a display control unit 125, a display element control unit 126, and a mirror control by executing the above-described program. The unit 127 and the like are functionally realized.

  The phase difference AF control unit 121 performs an automatic focusing (AF) operation (also referred to as “phase difference AF”) by a phase difference method. Specifically, the phase difference AF control unit 121 specifies the position of the focus lens at the time of focusing (lens focusing position) based on the phase difference detection signal output from the AF module 20. Perform the action.

  In addition, the phase difference AF control unit 121 cooperates with the drive control unit 123 to execute a lens driving operation for moving the focus lens to the lens focusing position.

  Specifically, the phase difference AF control unit 121 transmits a control signal to the lens side control unit 31 of the photographing lens 3 via the drive control unit 123 to drive the lens driving unit 38, and the lens group of the photographing lens 3. The focus lens included in 37 is moved in the optical axis direction. Further, the position of the focus lens is detected by the lens position detection unit 39 of the photographing lens 3, and data indicating the position of the focus lens is sent from the lens side control unit 31 to the overall control unit 100 of the camera body 2.

  Information transmission between the lens-side control unit 31 and the overall control unit 100 is performed via the connector Ec.

  The determination unit 122 acquires lens information of the photographing lens 3 from the lens-side ROM 31B provided in the lens-side control unit 31 via the connector Ec, and the photographing lens 3 conforms to the main imaging element 5 based on the lens information. It is determined whether or not to do. Details will be described later.

  The image frame shutter control unit 124 drives the image frame shutter drive unit 92 according to the determination result in the determination unit 122 and operates the image frame adjustment shutter (also simply referred to as “image frame shutter”) 91.

  The display control unit 125 controls display contents on a display unit such as the monitor 12. For example, the display control unit 125 causes the monitor 12 to display a continuous image based on the captured images continuously acquired by the sub imaging element 7.

  The display element control unit 126 controls the output of a superimpose display element (also simply referred to as “display element”) 66 provided in the finder unit 102.

  The mirror control unit 127 controls state switching between a state in which the mirror mechanism 6 is retracted from the optical path (mirror up state) and a state in which the mirror mechanism 6 blocks the optical path (mirror down state).

<Composition determination operation (framing operation)>
Next, the composition determination operation in the imaging apparatus 1A will be described. As described above, in the imaging apparatus 1A, the user performs composition determination using the optical viewfinder in the OVF mode or the composition determination using the electronic viewfinder in the EVF mode by the slide operation of the display changeover switch 9. Can be selected. FIG. 6 is a longitudinal sectional view of the imaging apparatus 1A in the EVF mode.

  When the composition is determined, the mirror mechanism 6 is arranged so as to be in a mirror-down state (see FIGS. 3 and 6). As described above, in the mirror-down state, the subject image from the photographing lens 3 is reflected upward by the main mirror 61 and guided to the finder unit 102 as an observation light beam.

  The finder unit 102 includes a pentamirror 65, an eyepiece lens 67, an eyepiece shutter 68, a finder window 10, a superimpose display element 66, an imaging lens 69, a sub imaging element 7, and the like.

  The pentamirror 65 has a plurality of mirrors (reflection surfaces), and has a function of changing the light path of the subject light and a function of changing the light path of the subject light by changing the top and bottom of the subject image by reflection.

  Specifically, the pentamirror 65 includes two mirrors (dach mirrors) 65a and 65b formed in a triangular roof shape, a surface 65c fixed to the roof mirrors (dach surfaces) 65a and 65b, and an optical path change. And a mirror (reflection surface) 65e.

  The roof mirrors 65a and 65b are formed as an integral part 65d by plastic molding, and have a function of reversing the posture of the subject image by reflecting the subject light twice. The optical path changing mirror 65e has a function of changing the optical path of the subject light according to which of the optical finder and the electronic finder is used to determine the composition.

  The eyepiece 67 has a function of guiding the subject image that has been erected by the pentamirror 65 to the outside of the finder window 10.

  The eyepiece shutter 68 is provided between the eyepiece 67 and the finder window 10, and blocks the outside light entering the imaging apparatus 1 </ b> A from the finder window 10 and does not block the outside light from the finder window 10. It functions as a light shielding (shutter) means capable of switching the state between the light shielding states. For example, in the EVF mode, the eyepiece shutter 68 is in a light shielding state, and in the OVF mode, it is in a non-light shielding state.

  The superimpose display element 66 is composed of, for example, a light emitting diode (LED) and has a function of superimposing additional information on a subject image passing through the finder unit 102. Specifically, the superimpose display element 66 superimposes additional information on the subject image by irradiating light to an SI (superimpose) screen HS disposed immediately above the focusing screen 64.

  Hereinafter, each of the framing operation using the optical finder and the framing operation using the electronic finder will be described in detail. FIG. 7 is a diagram illustrating display in the optical finder field of view in the imaging apparatus 1A.

  First, the framing operation using the optical finder will be described.

  As shown in FIG. 3, in the OVF mode, the mirror mechanism 6 is arranged on the optical path of the subject image from the photographing lens 3, and the subject image passes through the main mirror 61, the pentamirror 65, and the eyepiece 67 in order. Guided to window 10. Thus, the finder optical system 102 including the main mirror 61, the pentamirror 65, and the eyepiece 67 guides the subject image acquired by the photographing optical system to the finder window 10.

  More specifically, the subject light that has passed through the photographing lens 3 is reflected upward by the main mirror 61 and forms an image on the focusing screen 64. The subject light imaged on the focusing screen 64 passes through the focusing screen 64 and the like (specifically, the focusing screen 64 and the SI screen HS), and after the course is changed by the pentamirror 65, passes through the eyepiece 67 and the viewfinder. It goes to the window 10 (see the optical path PA in FIG. 3). Thus, the subject image guided to the finder window 10 along the optical path PA reaches the eyes of the user (observer) and is visually recognized.

  That is, in the OVF mode, the user can visually check the subject image displayed in the viewfinder field by looking through the viewfinder window 10 and determine the composition.

  In the optical viewfinder, for example, a line drawing (also referred to as “line drawing” or “target mark”) Gv indicating the focus position and / or photometry position with respect to the subject is superimposed on the subject image as shown in FIG. It is reflected in the finder window 10. This line drawing Gv is composed of a plurality of line drawings corresponding to a plurality of photographing conditions relating to focus and / or exposure.

  Such a line drawing Gv is drawn by ruled one side of the SI screen HS configured as a translucent member. That is, the line drawing Gv superimposed on the subject image and guided to the finder window 10 is shown on the SI screen HS provided on the optical path PA that guides the subject light that has passed through the photographing lens 3 to the finder window 10.

  Next, a framing operation using the electronic viewfinder will be described.

  As shown in FIG. 6, in the EVF mode, the mirror mechanism 6 is disposed on the optical path of the subject image from the photographing lens 3. Then, the subject light that has passed through the photographing lens 3 is reflected upward by the main mirror 61 and forms an image on the focusing screen 64. The subject light imaged on the focusing screen 64 passes through the focusing screen 64 and the like, and after the path is changed by the pentamirror 65, the imaging surface of the sub imaging device 7 is passed through the imaging lens 69 (imaging optical system). Re-imaging is performed above (see optical path PB in FIG. 6).

  As described above, in the EVF mode, the subject image is guided to the sub imaging element 7 along the optical path PB different from the optical path PA in the OVF mode.

  Such an optical path change in the finder unit 102 is realized by changing the angle of the optical path change mirror 65e (installation angle with respect to the camera body 2) in accordance with the finder mode.

  Specifically, the optical path changing mirror 65e is configured to be rotatable around the axis AX1 in conjunction with the slide operation of the display changeover switch 9, and in the EVF mode (see FIG. 6), the OVF mode (see FIG. 3). As compared with the axis AX1, it is rotated by a predetermined angle AN around the axis AX1 in the direction of the arrow AR1.

  Then, the overall control unit 100 determines whether to perform the composition determination operation using the optical finder according to the detection result by the angle detector (not shown) that detects the angle of the optical path changing mirror 65e with respect to the axis AX1. Decide what action to take.

  At the angle of the optical path changing mirror 65e shown in FIG. 3, it is determined that the composition determination operation by the optical finder is to be performed, and processing such as stopping the power supply to the sub image sensor 7 and hiding the monitor 12 is performed. On the other hand, at the angle of the optical path changing mirror 65e shown in FIG. 6, it is determined that the composition determination operation by the electronic finder is to be performed, EVF mode processing, that is, feeding power to the sub-imaging device 7 and displaying the live view image on the monitor 12 Is displayed.

  Thus, in the EVF mode, the optical path of the subject light in the finder unit 102 is changed by changing the posture of the optical path changing mirror 65e. Thereby, the subject light passes through the imaging lens 69 and reaches the sub imaging element 7.

  As described above, the sub-image sensor 7 receives the subject light that has reached along the optical path PB, and sequentially acquires the captured images related to the subject image at a minute time interval (for example, 1/60 seconds). The acquired time-series captured images are sequentially displayed on the monitor 12 in a moving image manner (live view display).

  Thus, the user can determine the composition by visually recognizing the moving image (live view image) displayed on the monitor 12.

  The imaging lens 69 and the sub-imaging device 7 are disposed at a position where the light beam traveling from the optical path changing mirror 65e to the eyepiece lens 67 is not blocked in the OVF mode (here, above the eyepiece lens 67).

  Thus, in the imaging apparatus 1A, the optical path of the subject light is changed by changing the attitude of the optical path changing mirror 65e of the finder unit 102, and the OVF mode and the EVF mode are switched.

<Operations associated with replacement of the photographic lens 3>
Next, the operation of the image pickup apparatus 1A executed when the photographing lens 3 is replaced will be described. FIG. 8 is a diagram illustrating the relationship between the main image sensor 5 and the image circle GC of the photographic lens 3. FIG. 9 is a diagram showing a display in the field of view of the optical viewfinder. FIG. 10 is a diagram showing the image frame shutter 91.

  In the imaging apparatus 1A, the photographic lens 3 can be replaced. When a new photographic lens 3 is attached, the imaging apparatus 1A performs a lens checking operation.

  In the lens checking operation, lens information is acquired from the mounted photographic lens 3, and based on the lens information, it is determined whether or not the photographic lens 3 is a lens corresponding to the main imaging element 5 of the imaging device 1A. . Here, the determination of whether or not the lens is a corresponding lens is made based on whether or not the imaging range of the main imaging element 5 fits in the image circle of the imaging lens 3.

  Specifically, the size of the image circle formed by the mounted photographic lens 3 is calculated based on the lens information. Then, on the basis of whether or not the diagonal length of the region (also referred to as “photographing use region”) used to acquire the actual captured image in the main imaging element 5 is equal to or less than the diameter of the image circle of the photographing lens 3, It is determined whether or not vignetting is caused by the combination of the mounted photographing lens 3 and the main image sensor 5. When vignetting does not occur, it is determined that the photographic lens 3 is a lens (adaptive lens) corresponding to the main image sensor 5. When vignetting occurs, the photographic lens 3 is a lens that does not correspond to the main image sensor 5. It is determined that it is a (non-adaptive lens).

  Then, in the imaging apparatus 1A, the subject image range (also referred to as “field-of-view range”) that can be confirmed by the shooting use area and the viewfinder (specifically, the optical viewfinder and the electronic viewfinder) according to the determination result of the lens determination. ) ER is changed respectively.

  The change of the shooting use area is performed in order to acquire a rectangular main shooting image without vignetting, and is realized by performing image processing on the shooting image acquired by the main imaging element 5.

  Specifically, when the photographing lens 3 that does not correspond to the main image sensor 5 is attached and the main photographing is performed, a captured image having a vignetting part is acquired by the main image sensor 5, but the vignetting part is subjected to image processing. Removed by.

  More specifically, as shown in FIG. 8, when the diameter of the image circle GC of the photographing lens 3 is shorter than the diagonal length of the main image sensor 5, the four corners NP of the main image sensor 5 are vignetted. . When the main photographing is performed in this state, the main image pickup device 5 obtains photographed images with vignetting at the four corners. Therefore, the imaging apparatus 1A performs image processing for removing the vignetting portion on the captured image, and acquires the actual captured image HG that does not have the vignetting portion.

  The actual captured image HG acquired in this way corresponds to an image acquired by using the rectangular area surrounded by the one-dot chain line KA on the main imaging element 5 as the imaging use area, and the imaging apparatus 1A obtains the determination result of the lens determination. Accordingly, it can be expressed that the photographing use area is changed and the main photographing image HG is acquired.

  In the imaging apparatus 1A, the field-of-view range ER that can be confirmed by the finder is changed between the range ER1 (see FIG. 7) and the range ER2 (see FIG. 9) according to the determination result of the lens determination.

  As the changing means for changing the visual field range, an image frame shutter 91 provided between the focusing screen 64, which is the imaging position of the subject image, and the SI screen HS (see FIG. 3) is used.

  As shown in FIG. 10, the image frame shutter 91 is composed of two light shielding plates AS1 and AS2 that are slidable within a plane perpendicular to the optical path of the subject light that has passed through the focusing screen 64. The light shielding plates AS1 and AS2 shield part of the subject light that has passed through the focusing screen 64 when the image frame shutter 91 is in the closed state QA. The image frame shutter 91 having such a light-shielding function defines a visual field range (also referred to as “basic visual field range”) ER1 corresponding to a normal photographing range by the main imaging element 5 in the open state QB, and is in a closed state QA. , A visual field range (also referred to as “narrow visual field range”) ER2 narrower than the basic visual field range ER1 is defined. In the imaging apparatus 1A, the image frame shutter 91 is normally set to the open state QB so as to define the basic visual field range ER1.

  Thus, the visual field range ER is changed according to the determination result of the lens determination, and the changed visual field range ER corresponds to the photographing range by the main imaging element 5.

  Further, the image frame shutter 91 is disposed at the imaging position of the subject image in the vicinity of the focusing screen 64 on the optical path of the subject light in the finder optical system. According to this, the narrow field range ER2 is defined in the finder. The frame to be displayed can be clearly displayed.

  Hereinafter, the above-described lens checking operation will be described with reference to the flowchart of the lens checking operation shown in FIG.

  In the imaging apparatus 1A, when the photographing lens 3 is exchanged and a new photographing lens 3 is attached, the lens checking operation shown in FIG. 11 is started.

  Specifically, first, in step SP11, the determination unit 122 acquires lens information (lens data) of the photographic lens 3 attached.

  The lens information is stored in advance in the lens-side ROM 31B of the photographing lens 3, and the lens information includes information such as the focal length and the angle of view of the photographing lens 3, for example.

  In step SP12, the determination unit 122 determines whether or not the mounted photographing lens 3 corresponds to the main imaging element 5 of the imaging device 1A.

  Since the main image pickup device 5 of the present embodiment employs an image pickup device having a size equivalent to a 35 mm film, for example, when the shooting lens 3 for APS-C size is attached, the determination unit 122 It is determined that the inappropriate photographing lens 3 is attached.

  As described above, when it is determined in step SP12 that the imaging lens 3 inappropriate for the main image sensor 5 is attached, the process proceeds to step SP13.

  In step SP13, an operation of closing the image frame shutter 91 is executed, and the image frame shutter 91 is in the closed state QA.

  Thereby, the visual field range displayed on the finder is narrowed, and the user can visually recognize the subject image in the visual field range corresponding to the photographing range by the main image sensor 5.

  On the other hand, if it is determined in step SP12 that the photographing lens 3 suitable for the main image sensor 5 is attached, the image frame shutter 91 remains in the open state QB, and the process proceeds to step SP14.

  In step SP14, it is confirmed whether or not the taking lens 3 is removed. When the photographic lens 3 is not removed, the camera enters a standby state. When the photographic lens 3 is removed, the process proceeds to step SP15.

  In step SP15, it is determined whether or not the image frame shutter 91 is in the open state QB. If the image frame shutter 91 is in the open state QB, the lens checking operation is ended as it is.

  If the image frame shutter 91 is not in the open state QB (is in the closed state QA), the process proceeds to step SP16, and after the operation for setting the image frame shutter 91 to the open state QB is executed, the lens checking operation is completed. Is done.

  As described above, the imaging apparatus 1A determines whether or not the mounted photographing lens 3 is compatible with the main imaging element 5, operates the image frame shutter 91 that blocks the subject light according to the determination result, and operates the finder. Change the shooting range shown in. According to this, without providing an expensive member such as a liquid crystal display member in the finder optical system, that is, while suppressing the cost of the imaging device, it is possible to make the user recognize the change of the photographing range through the finder. Become.

<2. Second Embodiment>
Next, a second embodiment of the present invention will be described.

  The imaging apparatus 1A according to the first embodiment can recognize the imaging range by the main imaging element 5 by changing the visual field range displayed on the finder, but the imaging apparatus 1B according to the second embodiment In addition, by superimposing and displaying additional information by the superimpose display element 66, the photographing range by the main image sensor 5 can be visually recognized by the user.

  FIG. 12 is a block diagram illustrating a functional configuration of the imaging apparatus 1B. FIG. 13 is a diagram illustrating display in the optical finder field of view in the imaging apparatus 1B.

  Note that the imaging apparatus 1B according to the second embodiment is the first except that the superimpose display element 66 is used to indicate the shooting range, and the image frame shutter 91 and the configuration related thereto are not provided. The configuration and function (see FIGS. 1 to 4 and 6) that are substantially the same as those of the image pickup apparatus 1A according to the embodiment are provided, and common portions are denoted by the same reference numerals and description thereof is omitted.

  The determination unit 122 of the imaging apparatus 1B illustrated in FIG. 12 acquires lens information of the photographing lens 3 from the lens side ROM 31B provided in the lens side control unit 31, and the photographing lens 3 is based on the lens information. Whether or not the lens is compatible with 5 is determined.

  The display element control unit 126 controls the output of the superimpose display element 66 according to the determination result of the determination unit 122, and displays a frame (“shooting range frame” or “image frame” indicating the shooting range by the main image pickup device 5. Is also highlighted.

  More specifically, a line drawing Gvw indicating a shooting range frame when the shooting lens 3 for APS-C size is attached is drawn in advance on the SI screen HS of the imaging apparatus 1B. As a result, as shown in FIG. 13, the line drawing Gvw is displayed superimposed on the subject image in the viewfinder field of the optical viewfinder. Therefore, when the user recognizes in advance that the mounted shooting lens 3 is a lens that does not correspond to the main imaging element 5 equivalent to a 35 mm film, the user can set the shooting range corresponding to the shooting lens 3 in the viewfinder field of view. Can be confirmed.

  Furthermore, the imaging device 1B has a light projection LED (also referred to as “image frame LED”) 66D as a superimpose display element 66 for each line drawing Gvw, and the display element control unit 126 includes a determination unit. In response to the determination result at 122, the image frame LED 66D is caused to emit light.

  In this manner, in the imaging apparatus 1B, the imaging range frame is highlighted by causing the image frame LED 66D to emit light, so that the user can check the imaging range according to the imaging lens 3 attached.

  Hereinafter, the lens checking operation executed in the imaging apparatus 1B will be described with reference to the flowchart of the lens checking operation shown in FIG.

  In the imaging apparatus 1B, when the photographic lens 3 is replaced and a new photographic lens 3 is attached, the lens checking operation shown in FIG. 14 is started.

  Specifically, first, in step SP21, as in step SP11 of the imaging apparatus 1A, the determination unit 122 acquires lens information (lens data) of the mounted photographing lens 3.

  In step SP22, as in step SP12, the determination unit 122 determines whether or not the mounted photographic lens 3 corresponds to the main imaging element 5 of the imaging device 1B.

  If it is determined in step SP22 that the inappropriate imaging lens 3 is attached to the main image sensor 5, the process proceeds to step SP23, and if it is determined that the imaging lens 3 adapted to the main image sensor 5 is attached. The process proceeds to step SP26.

  In step SP23, it is determined whether or not the user is using the optical viewfinder in accordance with the presence or absence of the eyepiece to the viewfinder window 10.

  If it is determined in step SP23 that the optical viewfinder is used, the process proceeds to step SP24, and the image frame LED 66D is turned on.

  On the other hand, when it is determined in step SP23 that the optical viewfinder is not used, the process proceeds to step SP25, and the image frame LED 66D is turned off.

  As described above, when the imaging lens 3 that is incompatible with the main imaging element 5 is attached and an eyepiece is detected, the imaging device 1B turns on the image frame LED 66D. By including the condition with eyepiece detection in the condition for turning on the image frame LED 66D and turning off the image frame LED 66D when the eyepiece is not detected, wasted power due to the lighting of the image frame LED 66D during the non-use period of the optical finder. It becomes possible to reduce consumption.

  In the next step SP26, whether or not the taking lens 3 has been removed is confirmed in the same manner as in step SP14. When the taking lens 3 is not removed, the process proceeds to step SP22, and the operations of steps SP22 to SP26 are repeatedly executed.

  On the other hand, when the taking lens 3 is removed, the process proceeds to step SP27.

  In step SP27, it is determined whether or not the image frame LED 66D is turned off. If the image frame LED 66D is turned off, the lens checking operation is terminated as it is.

  If the image frame LED 66D is not in the off state (it is in the on state), the process proceeds to step SP28, and after the image frame LED 66D is turned off, the lens checking operation is terminated.

  As described above, in the imaging device 1B, the line image Gvw indicating the imaging range is highlighted by the light projection by the image frame LED 66D, and thus the user can recognize the imaging range by the main imaging element 5. According to this, without providing an expensive member such as a liquid crystal display member in the finder optical system, that is, it is possible to make the user recognize the change of the photographing range through the finder while suppressing the cost of the imaging device. Become.

<3. Modification>
Although the embodiments of the present invention have been described above, the present invention is not limited to the contents described above.

  For example, in the first embodiment, the image frame shutter 91 including the two light shielding plates AS1 and AS2 is used. However, the present invention is not limited to this. FIG. 15 is a diagram illustrating an image frame shutter 91 according to a modification.

  Specifically, as shown in FIG. 15, an image frame shutter 91 including four light shielding plates AS3 to AS6 may be used.

1 is a diagram illustrating an external configuration of an imaging apparatus according to a first embodiment of the present invention. 1 is a diagram illustrating an external configuration of an imaging apparatus according to a first embodiment of the present invention. It is a longitudinal cross-sectional view of the imaging device which concerns on 1st Embodiment. It is a longitudinal cross-sectional view of the imaging device which concerns on 1st Embodiment. It is a block diagram which shows the function structure of the imaging device which concerns on 1st Embodiment. It is a longitudinal cross-sectional view of the imaging device in EVF mode. It is a figure which shows the display in the optical finder visual field in 1st Embodiment. It is a figure which shows the relationship between the main image pick-up element and the image circle of a taking lens. It is a figure which shows the display in an optical finder visual field. It is a figure which shows an image frame shutter. It is a flowchart of the lens confirmation operation | movement in 1st Embodiment. It is a block diagram which shows the function structure of the imaging device which concerns on 2nd Embodiment. It is a figure which shows the display in the optical finder visual field in 2nd Embodiment. It is a flowchart of the lens confirmation operation | movement in 2nd Embodiment. It is a figure which shows the image frame shutter which concerns on a modification.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1A, 1B Image pick-up device 2 Camera main body part 3 Shooting lens 5 Main image pick-up element 10 Finder window 13 Eyepiece detection sensor 64 Focus plate 66 Superimpose display element 91 Image frame shutter 102 Finder optical system (finder part)
122 determination unit 124 image frame shutter control unit 126 display element control unit GC image circle Gv, Gvw line drawing

Claims (11)

Interchangeable shooting lens,
An image sensor for obtaining a photographed image related to a subject image formed by the photographing lens;
Lens information acquisition means for acquiring lens information of the photographing lens;
Finder means for confirming the photographing range by the image sensor;
Determination means for determining whether or not the photographing lens is compatible with the image sensor based on the lens information;
A changing unit that blocks a part of the subject light that forms the subject image according to a determination result of the determining unit, and changes the shooting range indicated by the finder unit;
An imaging apparatus comprising: The changing means is
A light shielding plate for shielding a part of the subject light;
Control means for moving the light shielding plate according to the determination result of the determination means;
The imaging device according to claim 1, comprising: The finder means has a finder optical system for guiding the subject image to a finder window along a predetermined optical path,
The imaging device according to claim 2, wherein the light shielding plate is provided at an imaging position of the subject image on the predetermined optical path. The finder means has a focusing screen,
The imaging device according to claim 3, wherein the light shielding plate is provided at the imaging position in the vicinity of the focusing screen.   5. The imaging according to claim 4, wherein the control unit moves the light shielding plate between a first state in which part of the subject light is shielded and a second state in which part of the subject light is not shielded. apparatus.   The imaging apparatus according to claim 5, wherein the determination unit derives the determination result based on whether or not the shooting range is within an image circle of the shooting lens. Interchangeable shooting lens,
An image sensor for obtaining a photographed image related to the subject image obtained by the photographing lens;
A finder optical system that guides the subject image to a finder window along a predetermined optical path as a finder image;
A translucent member on which a line drawing showing a photographing range by the imaging element corresponding to the photographing lens is represented;
The translucent member is provided on the predetermined optical path,
An imaging apparatus in which the line drawing is superimposed on the viewfinder image. Lens information acquisition means for acquiring lens information of the photographing lens;
A display element provided in the finder optical system for highlighting the line drawing superimposed on the finder image;
Determination means for determining whether or not the photographing lens is compatible with the image sensor based on the lens information;
Element control means for controlling the output of the display element according to the determination result of the determination means;
The imaging device according to claim 7, further comprising: Eyepiece detecting means for detecting an eyepiece to the viewfinder window;
Further comprising
The imaging device according to claim 8, wherein the element control unit does not perform the highlight display when the eyepiece is not detected by the eyepiece detection unit. An image sensor for acquiring a photographed image related to a subject image formed by an interchangeable photographing lens;
Lens information acquisition means for acquiring lens information of the photographing lens;
Finder means for confirming the photographing range by the image sensor;
Determination means for determining whether or not the photographing lens is compatible with the image sensor based on the lens information;
A changing unit that blocks a part of the subject light that forms the subject image according to a determination result of the determining unit, and changes the shooting range indicated by the finder unit;
An imaging apparatus main body comprising: An image sensor for obtaining a photographed image related to a subject image obtained by an interchangeable photographing lens;
A finder optical system that guides the subject image to a finder window along a predetermined optical path as a finder image;
A translucent member on which a line drawing showing a photographing range by the imaging element corresponding to the photographing lens is represented;
The translucent member is provided on the predetermined optical path,
The main body of the imaging apparatus in which the line drawing is superimposed on the viewfinder image.

Images