JP5370034B2 - Display device and camera using the same - Google Patents

Description

  The present invention relates to a display device and a camera using the display device.

  Conventionally, for example, there is a camera disclosed in Patent Document 1. This camera is provided with two display screens. One of the two display screens is composed of several inches of direct-view display elements mounted on the side or back of the camera body, and the other display screen is displayed on a small liquid crystal panel or the like. It consists of an electronic viewfinder that allows the photographer to look into the image. On each of these display screens, the same image is displayed by one scanning type display mechanism.

JP-A-2005-107361

  However, if the viewing environment of the image displayed on one display screen is different from the viewing environment of the image displayed on the other display screen, the user may not be able to recognize the image correctly.

The present invention has been made to solve such problems,
The display device according to claim 1 comprises:
A first display for displaying an image;
A second display that is provided separately from the first display and displays an image;
A visual environment detection unit for detecting the visual environment of the first display unit;
A display control unit configured to display, on the second display unit, the first image displayed on the first display unit and the second image displayed on the second display unit in the visual environment detected by the visual environment detection unit. It is characterized by.

  According to the present invention, an image can be correctly recognized.

1 is a front perspective view of a digital camera according to an embodiment of the present invention. It is a rear view of the digital camera shown in FIG. It is a block diagram which shows the outline of the electric circuit structure of the digital camera shown in FIG. It is a figure which shows the EVF screen which compared and displayed the 1st image displayed on the back monitor of the digital camera shown in FIG. 1, and the 2nd image displayed on EVF. It is a figure which shows the EVF screen by the modification of the comparison display shown in FIG.

  An embodiment for carrying out the present invention when the display device according to the present invention is applied to a digital camera will be described.

  FIG. 1 is a front perspective view showing the appearance of a digital camera 1 according to this embodiment.

  The digital camera 1 is provided with an optical lens unit 3 that guides light from a subject to an image sensor at the center of the front of a camera body 2 that constitutes a housing. The optical lens unit 3 is provided integrally with the camera body 2 or exchangeable with other optical lens units. A shutter button 4 is provided at the upper left of the optical lens unit 3, and a self-timer lamp 5 comprising a light emitting diode (LED) is provided at the upper right. When the shutter button 4 is half-pressed, the auto focus function is activated, and when the shutter button 4 is fully pressed, the shutter is opened at a preset shutter speed, and the subject image is exposed to the image sensor for a predetermined period of time. Take an image. Further, a shooting information display panel 6 for displaying various information at the time of shooting is provided on the upper surface of the shoulder portion of the camera body 2 behind the shutter button 4, and various shooting modes are provided on the upper surface of the opposite shoulder portion. A shooting mode dial 7 is provided for setting. In addition, an accessory shoe 8 for attaching accessories such as a lighting device that illuminates the subject is provided at the upper center of the camera body 2.

  FIG. 2 is a rear view showing the appearance of the digital camera 1 shown in FIG. In the figure, the same parts as those in FIG.

  The digital camera 1 includes a rear monitor 11 that constitutes a first display unit that displays an image, and an electronic viewfinder (hereinafter, EVF) that is provided separately from the rear monitor 11 and that constitutes a second display unit that displays an image. (Referred to as “Electronic View Finder”) 12. The back monitor 11 is made of a TFT (Thin Film Transistor) liquid crystal or the like, and is disposed on the surface of the housing at the center of the back of the camera body 2. On the rear monitor 11, a so-called through image that is an image captured by the image sensor via the optical lens unit 3, a reproduced image, various information related to photographing, and the like are displayed. The EVF 12 is provided above the rear monitor 11 with a small liquid crystal monitor made of TFT liquid crystal or the like disposed inside the viewfinder. On this small liquid crystal monitor, a through image, various kinds of information related to photographing, and the like are displayed and enlarged by an eyepiece. The photographer can view the image displayed on the small liquid crystal monitor by looking into the EVF 12.

  Further, on the left side of the rear monitor 11, a menu button 13 that is operated when displaying a menu screen for performing various settings of the digital camera 1 on the rear monitor 11, and an operation when displaying shooting information on the rear monitor 11. Information display button 14 to be displayed, reduction / thumbnail button 15 to be operated when the captured image displayed on the rear monitor 11 is reduced or displayed, and thumbnail button to be operated when the captured image is enlarged. 16 is provided.

  A command dial 17 for setting an exposure value, a shutter speed, ISO (International Organization for Standardization) sensitivity, and the like is provided on the upper right side of the camera body 2. A multi-selector 18 that performs an item selection operation or the like is provided. The multi-selector 18 includes an annular direction key 18a and a determination button 18b provided at the center thereof. The direction key 18a is pressed down in the up / down / left / right directions when the photographer selects an item to be set on the menu screen or the like displayed on the rear monitor 11. The determination button 18b is pressed when the direction key 18a is operated to determine the selected item. Note that the locations where these buttons are installed and the functions and roles provided for the buttons are merely examples, and can be changed as appropriate.

  An illuminance sensor 19 and a colorimetric sensor 20 are provided on the upper right side of the rear monitor 11. The illuminance sensor 19 detects the luminance around the display surface of the back monitor 11, and the colorimetric sensor 20 detects the color around the display surface of the back monitor 11. These sensors 19 and 20 constitute a visual environment detection unit that detects the visual environment of the first display unit, in this embodiment, the rear monitor 11.

  FIG. 3 is a block diagram showing an outline of the electric circuit configuration of the digital camera 1 according to the present embodiment. In the figure, the same parts as those in FIGS. 1 and 2 are denoted by the same reference numerals.

  The digital camera 1 includes a CPU (Central Processing Unit) 21, a nonvolatile memory 22 composed of an EEPROM (Electrically Erasable Programmable Read Only Memory), and a buffer memory 23 composed of a RAM (Random Access Memory). Yes. The nonvolatile memory 22 stores a control program that is referred to when the CPU 21 performs various controls. The CPU 21 controls each part of the circuit using the buffer memory 23 as a temporary storage work area in accordance with a control program stored in the nonvolatile memory 22.

  The light guided through the zoom lens 24 and the focus lens 25 constituting the optical lens unit 3 is a subject on the imaging surface 26a of the imaging device 26 such as a CCD (Charge Coupled Device) or a CMOS (Complementary Metal Oxide Semiconductor). Project an image. The optical lens unit 3 constitutes an optical system that projects a subject image onto the imaging surface 26a of the image sensor 26. The image sensor 26 photoelectrically converts subject light to capture the subject image, and electrically capture the image data. The image pickup unit that outputs the signal is configured. The zoom lens 24 and the focus lens 25 move back and forth on the optical axis as indicated by arrows when the motors 27 and 28 are respectively driven by the control of the CPU 21. As the zoom lens 24 moves on the optical axis, the subject image projected on the imaging surface 26a by the optical lens unit 3 is enlarged or reduced, and the magnification of the optical zoom is adjusted. Further, when the focus lens 25 moves on the optical axis, the focus of the subject image projected onto the imaging surface 26a by the optical lens unit 3 is adjusted. The positions on the optical axis of the lenses 24 and 25 moved by the motors 27 and 28 are detected by the position detectors 29 and 30 and output to the CPU 21. The motor 28, the position detection unit 30, and the CPU 21 constitute a focus adjustment unit that adjusts the focus of the optical lens unit 3 that projects the subject image on the image sensor 26.

  The subject image formed on the imaging surface 26 a of the imaging element 26 is converted into an analog imaging signal and converted into a digital signal by the A / D conversion unit 31. The image processing unit 32 acquires the imaging signal converted into a digital signal by the A / D conversion unit 31 via the bus 33, and performs image processing such as white balance processing and gamma correction on the acquired imaging signal. Then, image data of the captured image is generated by performing compression processing. The image data generated by the image processing unit 32 is stored in the buffer memory 23 by the CPU 21 and also stored in a recording medium 35 such as a card memory that is attached to and detached from a slot (not shown) via the I / F unit 34. The

  The image data stored in the buffer memory 23 is read by the monitor driver 37 under the control of the CPU 21, and a through image for confirming the composition of the subject image captured by the image sensor 26 is displayed on the rear monitor 11. . Further, the image is read by the EVF driver 38 under the control of the CPU 21 and a through image is displayed on the EVF 12.

  An operation unit 36 is connected to the CPU 21. The operation unit 36 includes the shutter button 4, the shooting mode dial 7, the menu button 13, the information display button 14, the reduction / thumbnail button 15, the enlargement button 16, the command dial 17 and the multi selector 18 described above.

  The CPU 21 is connected to the illuminance sensor 19 and the colorimetric sensor 20 described above. The luminance value around the display surface of the rear monitor 11 detected by the illuminance sensor 19 and the colorimetric sensor 20 detect the luminance value. Colorimetric values around the display surface of the rear monitor 11 are input from the illuminance sensor 19 and the colorimetric sensor 20. From these values, the CPU 21 and the image processing unit 32 simulate a through image that will be displayed on the rear monitor 11 under the influence of the visual environment around the rear monitor 11, and store the simulated image in the buffer memory. 23. The simulated image of the rear monitor 11 stored in the buffer memory 23 is displayed on the EVF 12 and the EVF 12 by selecting an item for simulation comparison display on the menu screen displayed on the rear monitor 11 by operating the menu button 13. The reduced through images displayed are displayed side by side for comparison.

  FIG. 4 shows a display screen displayed on the EVF 12 by the EVF driver 38 under the control of the CPU 21 when the simulation comparison display is selected and operated. FIG. 4A shows the EVF 12 when the viewing environment of the rear monitor 11 detected by the illuminance sensor 19 is bright, and FIG. 4B shows the EVF 12 when the viewing environment of the rear monitor 11 detected by the illuminance sensor 19 is dark. It is a display screen.

  On these display screens, the simulated image of the rear monitor 11 stored in the buffer memory 23 is the first image 41, the through image displayed on the EVF 12 is the second image 42, and the first image 41 and the second image are displayed. 42 are displayed side by side. The CPU 21 and the EVF driver 38 display the first image 41 displayed on the rear monitor 11 and the second image 42 displayed on the EVF 12 side by side on the EVF 12 in the visual environment detected by the illuminance sensor 19 and the colorimetric sensor 20. A display control unit is configured. Further, the rear monitor 11 and EVF 12 constituting the first display part and the second display part, the illuminance sensor 19 and the colorimetric sensor 20 constituting the visual environment detection part, and the display control part constitute a display device, The digital camera 1 includes an image sensor 26 that constitutes an imaging unit and this display device.

  The first image 41 is displayed in the inner area of the dotted frame in the same size as the second image 42, and in the outer area of the dotted frame, a pseudo visual environment display area for conveying the brightness of the visual environment to the photographer 43 is displayed. The visual environment display area 43 is bright when the visual environment of the rear monitor 11 is bright as shown in FIG. 5A, and is dark when the visual environment of the rear monitor 11 is dark as shown in FIG. Is dark and displayed.

  Also, below the first image 41 and the second image 42 displayed side by side, settings for adjusting the display parameters of the first image 41 and the second image 42, such as the brightness, color, and contrast of the image, for example. The item is displayed. The display section selection item written alongside “EVF” and “Back” is a setting item for selecting either the rear monitor 11 or the EVF 12 to be adjusted for display parameters by the left / right operation of the direction key 18a. . As shown in FIG. 6A, the display section selection item marked “back” is selected by moving the cursor 44 by the right operation of the direction key 18a, and the determination button 18b is pressed. The rear monitor 11 is selected as the parameter adjustment target, and the display section selection item labeled “back” is highlighted as indicated by the diagonal lines. In addition, as shown in FIG. 5B, when the display section selection item “EVF” is selected by moving the cursor 44 by the left operation of the direction key 18a, and the determination button 18b is pressed. The EVF 12 is selected as the display parameter adjustment target, and the display section selection item labeled “EVF” is highlighted as indicated by the hatched lines. Below the display section selection item, five adjustment parameter items of luminance, R (red), G (green), B (blue), and contrast are displayed. These adjustment parameter items are initially set to a predetermined percentage [%] as default values.

  The display parameter is adjusted by moving the cursor to the desired adjustment parameter item by the up / down operation of the direction key 18a after the display section selection item is set. For example, when performing an adjustment to increase or decrease the “brightness”, the cursor 44 is moved from the display unit selection item to the “brightness” adjustment parameter item by pressing down the direction key 18a once, and then the direction key. 18a is operated left and right to increase and decrease the brightness setting value. At this time, the CPU 21 increases or decreases the length of the blackened portion of the bar 45 by the amount by which the luminance is increased or decreased, and also increases or decreases the percentage [%] of the luminance displayed on the right side of the bar 45. The CPU 21 changes the luminance of the first image 41 or the second image 42 displayed side by side on the EVF 12 by the EVF driver 38 in real time according to the increase / decrease of the set value. The remaining four adjustment parameter items are also adjusted by the same operation of the multi-selector 18, and the adjusted display parameters are reflected in real time on the display of the first image 41 or the second image 42.

  Since the display of the EVF 12 is covered by the eyepiece and viewed by the photographer, it is hardly affected by the visual environment. Therefore, generally, the through image displayed on the EVF 12 looks closer to the actual subject image than the through image displayed on the rear monitor 11. For this reason, the photographer adjusts the display parameters necessary for the first image 41 while comparing the first image 41 and the second image 42, and is affected by the visual environment around the rear monitor 11. The image 41 is adjusted to an optimal value that can be viewed in the same manner as the second image 42 that is hardly affected by the visual environment. When this adjustment is completed, the determination button 18b is pressed. When the determination button 18 b is pressed, the CPU 21 stores the adjusted display parameter values in the nonvolatile memory 22, reads them, and writes them in the driver memory provided in the monitor driver 37. Accordingly, the through image is displayed on the rear monitor 11 based on the display parameter value newly stored in the driver memory of the monitor driver 37.

  In general, as described above, adjustment is performed so that the display on the rear monitor 11 is close to the display on the EVF 12. However, as shown in FIG. 4B, when the viewing environment of the rear monitor 11 is dark and the viewing environment of the EVF 12 is also dark, the through image displayed on the EVF 12 is displayed brightly and displayed on the rear monitor 11. There are cases where the through image is closer to the actual appearance of the subject image than the through image displayed on the EVF 12. In such a case, it is necessary to adjust the display of the EVF 12 to be close to the display of the rear monitor 11. In this case, the photographer operates the direction key 18a to the left, moves the cursor 44 to the display section selection item “EVF” as shown in FIG. 5B, and sets the display parameter adjustment target to the EVF 12. Subsequently, the same operation as that of the rear monitor 11 described above is performed using the direction key 18a, and the adjustment parameter item is selected and adjusted. Then, by pressing the enter button 18b, the adjusted display parameter value is stored in the nonvolatile memory 22 and written into the driver memory of the EVF driver 38. Accordingly, a through image is displayed on the EVF 12 based on the display parameter value newly stored in the driver memory of the EVF driver 38.

  The multi-selector 18 constitutes an adjustment unit that adjusts the display parameter of the first image 41 or the second image 42 displayed side by side on the EVF 12 by the display control unit, and the CPU 21 sets the display parameter adjusted by the adjustment unit. A display setting unit for setting display parameters of the rear monitor 11 or EVF 12 is configured.

  According to the digital camera 1 of this embodiment, a through image captured by the image sensor 26 is displayed on the two display units of the rear monitor 11 and the EVF 12 of the digital camera 1. Therefore, the difference between the through image displayed on the rear monitor 11 and the through image displayed on the EVF 12 under the influence of the visual environment, or the through image displayed on the EVF 12 and the rear monitor under the influence of the visual environment. 11 is compared with the EVF 12 that displays these images side by side as the first image 41 and the second image 42 as shown in FIG. By visually recognizing the through image displayed on the affected rear monitor 11 or EVF 12, it is possible to estimate and recognize the actual appearance of the subject image.

  In addition, according to the digital camera 1 of the present embodiment, the display parameters of the first image 41 are the same as those of the second image 42 while comparing the first image 41 and the second image 42 displayed side by side on the EVF 12. By adjusting to an optimal value that can be visually recognized and setting the display parameter of the rear monitor 11, the photographer can visually recognize the through image of the rear monitor 11 that is affected by the viewing environment without guessing the actual subject. It becomes possible to recognize how the image looks. In addition, by adjusting the display parameter of the second image 42 to an optimal value that can be viewed in the same manner as the first image 41 and setting it to the display parameter of the EVF 12, the photographer can pass through the EVF 12 that is affected by the visual environment. Even by visually recognizing the image, it becomes possible to recognize the actual appearance of the subject image without guessing. For this reason, even if a through image of the rear monitor 11 or the EVF 12 affected by the visual environment is visually recognized and an imaging operation is performed, an image according to the intention of the photographer is captured. As a result, for example, a bright through image displayed on the rear monitor 11 having a bright visual environment is visually recognized and an imaging operation is performed. The captured image is actually dark, and an image contrary to the intention of the photographer can be taken. There is no failure.

  In the above embodiment, the case where the first image 41 and the second image 42 are compared and displayed side by side in FIG. 4 has been described, but the present invention is not limited to this. For example, as shown in FIG. 5, the display unit selection item and the adjustment parameter item are displayed on the left side of the display screen of the EVF 12, and the first image 41 and the second image 42 are displayed side by side on the right side for comparison display. May be laid out. 5 that are the same as those in FIG. 4 are given the same reference numerals, and descriptions thereof are omitted. Even with such a configuration, the same operations and effects as the above-described embodiment can be obtained.

  Moreover, although the said embodiment demonstrated the case where the 1st image 41 and the 2nd image 42 were compared and displayed on EVF12, this invention is not limited to this. For example, the first image 41 and the second image 42 may be compared and displayed on the display screen of the rear monitor 11 instead of the EVF 12, as shown in FIG. According to this configuration, for example, even when the visual environment is dark and the EVF 12 is too bright, the first monitor 41 can be easily viewed in the dark visual environment, and the first monitor 41 is close to the actual subject image. By comparing and displaying the second image 42, the same operations and effects as the above-described embodiment are achieved.

  In the above embodiment, the case where a through image for confirming the composition of the subject image captured by the image sensor 26 is displayed on the rear monitor 11 and the EVF 12 has been described. However, the present invention is not limited to this. Absent. For example, an image captured by the photographer in advance or a sample image stored in the nonvolatile memory 22 may be displayed on the rear monitor 11 and the EVF 12. According to this configuration, the display parameters of the rear monitor 11 or the EVF 12 are adjusted according to the viewing environment using the pre-captured image or the sample image before shooting, and the adjusted display parameters are displayed at the time of shooting. By taking a composition while looking at the through image, an image in accordance with the intention of the photographer is taken.

  Moreover, although the said embodiment demonstrated the structure which used TFT liquid crystal for the display element of the back monitor 11 and EVF12, this invention is not limited to this, For example, display elements, such as organic EL (Electro Luminescence) You may comprise using. As for the rear monitor 11, a micro panel using a micro device having a shutter of MEMS (Micro Electro Mechanical Systems) may be used as a display panel. Further, a configuration in which different display elements are used for the back monitor 11 and the EVF 12, for example, the display element of the back monitor 11 may be an organic EL, and the display element of the EVF 12 may be a TFT liquid crystal. At this time, it is necessary to set the drivers 37 and 38 of the rear monitor 11 and the EVF 12 so that the same image is visually recognized in the same manner by the organic EL and the TFT liquid crystal.

  Moreover, although the said embodiment demonstrated the structure which adjusts those display parameters with the multi selector 18 for every visual environment of the back monitor 11 or EVF12, this invention is not limited to this. For example, when the viewing environment that has been adjusted once is changed to another viewing environment, the digital camera 1 automatically corrects the display parameter settings that have already been adjusted and corrects the display parameters according to the other viewing environment. You may make it the structure adjusted and set. In this case, a table in which display parameters are set according to each visual environment is stored in the nonvolatile memory 22. Then, for example, after the display parameter such as the brightness when the viewing environment of the rear monitor 11 is bright is adjusted and set, when the illumination sensor 19 detects that the viewing environment of the rear monitor 11 is dark, the CPU 21 The table stored in the nonvolatile memory 22 is referred to, the already adjusted display parameter is corrected, the display parameter corresponding to the new visual environment is obtained, and the obtained display parameter is automatically set in the digital camera 1. You may comprise. According to this configuration, it is possible to save the trouble of adjusting the display parameter every time the viewing environment of the digital camera 1 changes.

  Moreover, although the said embodiment demonstrated the case where a visual environment detection part was comprised using the illumination intensity sensor 19 and the colorimetric sensor 20, this invention is not limited to this. Since the colorimetric sensor 20 measures brightness, hue, and saturation, the illuminance sensor 19 that measures brightness can also be used. Therefore, the visual environment detection unit may be configured by only the colorimetric sensor 20, and in this case, the number of parts can be reduced and the manufacturing cost can be reduced.

  Moreover, although the said embodiment demonstrated the case where the display apparatus by this invention was applied to the digital camera 1, this invention is not limited to this. For example, the present invention is applied to a microscope having a first display unit for viewing an observation object through a binocular tube and a second display unit for outputting image data similar to the first display unit to an external monitor for visual recognition. May be. Further, the present invention may be applied to a reproduction image display that reproduces and displays an image captured by a digital camera, and a viewer that outputs reproduction image data from the reproduction image display to display on a television monitor or the like. Also with such devices, the same operations and effects as the above-described embodiment can be obtained.

That is, the present invention
A first display for displaying an image;
A second display that is provided separately from the first display and displays an image;
A visual environment detection unit for detecting the visual environment of the first display unit;
A display control unit configured to display a first image displayed on the first display unit and a second image displayed on the second display unit side by side in the visual environment detected by the visual environment detection unit and displayed on the second display unit; It can be applied to a display device.

  According to the display device having this configuration, the first image displayed on the first display unit under the influence of the visual environment detected by the visual environment detection unit, and the second image displayed on the second display unit, Displayed side by side on the second display unit by the display control unit. Therefore, the observer can compare the difference in the visual recognition of the image by the visual environment by comparing the detected image affected by the visual environment and the original image not affected by the visual environment on one display unit. Can be recognized. Therefore, by recognizing this difference, an original image that is not affected by the visual environment can be estimated and recognized by visually recognizing the image affected by the visual environment.

Further, an adjustment unit that adjusts display parameters of the first image displayed on the second display unit by the display control unit on the display device,
You may comprise so that the display parameter adjusted by the adjustment part may be provided with the display setting part which sets to the display parameter of a 1st display part.

  According to this configuration, the display parameter of the first image displayed side by side on the second display unit is adjusted by the adjustment unit, and is set to the display parameter of the first display unit by the display setting unit. Therefore, the observer compares the first image and the second image displayed side by side on the second display unit, while changing the display parameters of the first image, for example, the brightness, color, and contrast of the image. It can adjust to the optimal value which can be visually recognized similarly to, and can set it as the display parameter of a 1st display part. For this reason, the image displayed on the first display unit looks the same as the image displayed on the second display unit that is not affected by the visual environment, and is estimated by visually recognizing the first display unit. The original image can be recognized without doing so.

Further, an adjustment unit that adjusts display parameters of the second image displayed side by side on the second display unit by the display control unit on the display device,
You may comprise so that the display parameter adjusted by the adjustment part may be provided with the display setting part which sets to the display parameter of a 2nd display part.

  According to this configuration, the display parameter of the second image displayed side by side on the second display unit is adjusted by the adjustment unit, and set to the display parameter of the second display unit by the display setting unit. Therefore, when the image displayed on the first display unit is closer to the original image than the image displayed on the second display unit due to the viewing environment of the second display unit, While comparing the first image and the second image displayed side by side, the display parameter of the second image is adjusted to an optimum value that can be viewed in the same manner as the first image, and set as the display parameter of the second display unit can do. For this reason, in such a case, the image displayed on the second display unit looks the same as the image displayed on the first display unit close to the original image, and the second display unit is visually recognized. Thus, the original image can be recognized without guessing.

1 ... Digital camera 11 ... Rear monitor 12 ... EVF
18a ... Direction key 18b ... Decision button 19 ... Illuminance sensor 20 ... Colorimetric sensor 21 ... CPU
22 ... Nonvolatile memory 37 ... Monitor driver 38 ... EVF driver

Claims (5)

A first display for displaying an image;
A second display unit that is provided separately from the first display unit and displays an image;
A visual environment detection unit for detecting a visual environment of the first display unit;
A display control unit that displays a first image displayed on the first display unit and a second image displayed on the second display unit in the visual environment detected by the visual environment detection unit side by side on the second display unit A display device comprising: The display device according to claim 1,
An adjustment unit for adjusting display parameters of the first image displayed side by side on the second display unit by the display control unit;
A display setting unit configured to set a display parameter adjusted by the adjustment unit as a display parameter of the first display unit. The display device according to claim 1,
An adjustment unit for adjusting display parameters of the second image displayed side by side on the second display unit by the display control unit;
A display setting unit configured to set a display parameter adjusted by the adjustment unit as a display parameter of the second display unit. An imaging unit that captures a subject image;
The display apparatus of any one of Claim 1 to 3 which displays the image imaged by the said imaging part on each of a said 1st display part and a said 2nd display part, The camera characterized by the above-mentioned. . The camera according to claim 4, wherein
The first display unit is a monitor disposed on the surface of the housing,
2. The camera according to claim 1, wherein the second display unit is an electronic viewfinder that is viewed by a photographer.

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