JP2010081560A - Electronic apparatus and electronic camera - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a means for efficiently managing a representative image from a number of captured images in a storage medium having an electronic paper. <P>SOLUTION: An electronic apparatus with a removable storage medium includes a medium-side terminal, a memory including a nonvolatile memory, and the electronic paper enabling image display. Also, the electronic apparatus includes an apparatus-side terminal connectable to the medium-side terminal, a control unit, and an image processing unit. The control unit transmits and receives data to and from the storage medium connected via the apparatus-side terminal, and acquires the data of the designated representative image from a plurality of captured images stored in the memory. The image processing unit generates an identification image corresponding to the representative image as an identification image to be displayed on the electronic paper. Then, the control unit records representative image identification data for identifying the representative image from the plurality of captured images in the memory, and updates history data indicating past representative images for storing in the memory. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an electronic device and an electronic camera that use a storage medium with electronic paper.

Conventionally, in order to facilitate identification of individual recording media, a technique has been proposed in which electronic paper is provided on a storage medium and information for identification is displayed on the electronic paper. As an example, Patent Document 1 discloses a configuration example of a digital camera system that uses a storage medium with electronic paper.
JP 2000-276119 A

  By the way, it is also conceivable to use a representative image selected from captured images stored in a storage medium as an image for identifying the storage medium in a conventional storage medium with electronic paper. In this case, there is a demand for a configuration that efficiently manages a representative image among a large number of captured images for an electronic device that is operated in combination with a storage medium with electronic paper.

  Accordingly, an object of the present invention is to provide means for efficiently managing a representative image among a large number of captured images in a storage medium with electronic paper.

  In an electronic device of one embodiment, a storage medium including a medium side terminal, a storage unit including a nonvolatile memory, and electronic paper capable of displaying an image can be attached and detached. The electronic device includes a device-side terminal that can be connected to the medium-side terminal, a control unit, and an image processing unit. The control unit transmits / receives data to / from a storage medium connected via the device side terminal, and acquires representative image data designated from a plurality of captured images stored in the storage unit. The image processing unit generates the identification image corresponding to the representative image as an identification image to be displayed on the electronic paper. When the representative image is set, the control unit records representative image identification data for identifying the representative image from the plurality of captured images in the storage unit, and stores history data indicating the past representative image. Update to record.

  The electronic device according to one aspect described above may further include an operation unit that receives an operation related to image erasure. The control unit may output a warning based on the representative image identification data when a representative image is selected as an image to be deleted from the storage unit. Furthermore, the control unit may newly set the representative image from the captured images and update the representative image identification data when the representative image data is deleted from the storage unit.

  The electronic device according to one aspect described above may further include a display unit that reproduces and displays the captured image. The control unit may superimpose and display a mark indicating the representative image on the display unit based on the representative image identification data when the representative image is reproduced and displayed.

  Furthermore, an electronic camera according to one aspect includes an imaging unit that captures an image of a subject and generates captured image data, and the electronic apparatus according to the one aspect described above.

  According to the present invention, using the representative image identification data stored in the storage unit, it is possible to efficiently manage a representative image from among a large number of captured images, and manage a representative image that has been set in the past. can do.

<Description of Configuration of One Embodiment>
FIG. 1 is a block diagram illustrating a configuration example of an electronic camera system according to an embodiment. This electronic camera system has an electronic camera 1 and a storage medium 2 with electronic paper. The storage medium 2 with electronic paper is configured to be detachable from the electronic camera 1.

  The electronic camera 1 includes a lens unit 11, a first lens driver 12, an aperture driver 13, a shutter driver 14, a second lens driver 15, an image sensor 16, a signal processing unit 17, and an imaging control unit 18. The CPU 19 includes a first memory 20 and a second memory 21, a display control unit 22 and a monitor 23, a recording I / F (interface) 24, an operation unit 25, and a flash light emitting unit 26.

  Here, the first lens driver 12, the aperture driver 13, the shutter driver 14, the second lens driver 15, the signal processing unit 17, the imaging control unit 18, the display control unit 22, the recording I / F 24, the operation unit 25, and the flash light emitting unit. 26 are connected to the CPU 19, respectively. Further, the CPU 19, the first memory 20, and the second memory 21 are connected to each other via a bus 19a.

  The lens unit 11 includes a zoom lens 11a, a focusing lens 11b, a diaphragm 11c, and a shutter 11d. The zoom lens 11a is a lens for optically changing the photographing magnification. The lens position of the zoom lens 11a is adjusted by the first lens driver 12 in the optical axis direction. The focusing lens 11b is a lens for performing focus adjustment. The lens position of the focusing lens 11b is adjusted by the second lens driver 15 in the optical axis direction.

  The diaphragm 11 c of the lens unit 11 adjusts the amount of light per unit time incident on the image sensor 16. The opening amount of the diaphragm 11 c is controlled by the diaphragm driver 13. The shutter 11d blocks light to the image sensor 16 and adjusts the shutter speed at the time of imaging. The operation of the shutter 11d is controlled by the shutter driver 14. Each of the drivers (12 to 15) is driven in accordance with an instruction from the CPU 19.

  The image sensor 16 captures a subject image formed by the light flux that has passed through the lens unit 11 and generates an analog image signal. The output of the image sensor 16 is connected to the signal processing unit 17. Note that the imaging element 16 in one embodiment can perform both single-shot shooting of a still image and shooting of a moving image.

  Here, in the photographing mode of the electronic camera 1, the image sensor 16 captures a still image for recording or a moving image for recording in response to a full pressing operation of a release button described later. Further, the imaging element 16 in the shooting mode continuously takes images for observation (through images) at predetermined intervals even during standby for shooting. Here, the data of the through image acquired in time series is used for the moving image display on the monitor 23 and various arithmetic processes by the CPU 19.

  The signal processing unit 17 is an analog front-end circuit that performs analog signal processing on the output of the image sensor 16. The signal processing unit 17 performs correlated double sampling, image signal gain adjustment, and image signal A / D conversion. The digital image signal output from the signal processing unit 17 is input to the CPU 19.

  The imaging control unit 18 supplies control pulses to the imaging element 16 and the signal processing unit 17 based on instructions from the CPU 19. Note that the charge accumulation time of the image pickup device 16 and the signal reading timing are adjusted by the control pulse of the image pickup control unit 18.

  The CPU 19 is a processor that comprehensively controls the photographing operation and the reproduction operation of the electronic camera 1 according to the sequence program. As an example, the CPU 19 executes autofocus (AF) calculation, automatic exposure (AE) calculation, and auto white balance (AWB) calculation at the time of shooting using the above-described through image data, respectively, using known algorithms.

  Further, the CPU 19 has an image processing unit 27 that performs various image processing. The image processing unit 27 performs image processing such as color interpolation processing, gradation conversion processing, contour enhancement processing, and white balance adjustment on the image data captured by the image sensor 16. The image processing unit 27 performs image resolution conversion (pixel number conversion) and image trimming processing.

  The first memory 20 is configured by a volatile storage medium (for example, SDRAM). The first memory 20 temporarily stores image data and the like in the pre-process and post-process of image processing by the CPU 19.

  The second memory 21 is composed of a nonvolatile storage medium such as a flash memory. The second memory 21 stores a sequence program corresponding to each operation mode. Examples of operations in the shooting mode and the playback mode will be described later.

  The display control unit 22 displays various display images on the monitor 23 in accordance with instructions from the CPU 19 and controls lighting and extinguishing of the monitor 23. Thereby, the moving image display by the above-mentioned through image and the reproduction display of the image stored in the storage medium 2 with the electronic paper are performed on the monitor 23. In addition, the monitor 23 in one embodiment is comprised with a liquid crystal display panel, for example.

  The recording I / F 24 has a device-side terminal 28 to which the electronic paper-equipped storage medium 2 is detachably connected. The recording I / F 24 writes / reads data and supplies power to / from the electronic paper-equipped storage medium 2 connected via the device-side terminal 28.

  The operation unit 25 has a plurality of switches that accept operations from the user. Specifically, the operation unit 25 of one embodiment includes a release button, a zoom button, a cross key, a determination button, a playback button, and a delete button.

  The release button receives from the user an instruction input for starting an AF operation before photographing by a half-press operation and an instruction input for starting an imaging operation by a full-press operation. The zoom button accepts an optical zoom operation by moving the zoom lens 11a and an electronic zoom operation by changing the resolution of the image from the user. In addition, the cross key and the determination button accept, for example, an operation for changing the setting of the electronic camera 1 and an operation for designating a position to cut out an image at the time of trimming. The playback button receives from the user an operation of shifting to a playback mode in which a captured image is played back and displayed. The delete button accepts an operation for erasing data of the image corresponding to the displayed reproduction image from the user in the reproduction mode.

  The flash light emitting unit 26 irradiates the subject with flash light according to an instruction from the CPU 19. For example, the flash light emitting unit 26 includes a xenon arc tube, a main capacitor, a light emission control circuit, and the like.

  Next, a configuration example of the storage medium 2 with electronic paper in one embodiment will be described with reference to FIG. The storage medium with electronic paper 2 includes a medium side terminal 41, a memory controller 42, a main memory 43, a display controller 44, an auxiliary memory 45, and electronic paper 46.

  The medium side terminal 41 is detachably connected to the device side terminal 28 of the electronic camera 1. The medium side terminal 41 is used for transmission / reception of data to / from the electronic camera 1 and power supply from the electronic camera 1 to the storage medium 2 with electronic paper.

  The memory controller 42 is connected to the medium side terminal 41, the main memory 43, and the display controller 44, respectively. The memory controller 42 directly controls writing / reading of data to / from the main memory 43. The memory controller 42 indirectly controls the operations of the auxiliary memory 45 and the electronic paper 46 via the display controller 44.

  The main memory 43 is composed of a nonvolatile memory such as a flash memory. The main memory 43 stores data of captured images (still images or moving images) captured by the electronic camera 1 in a predetermined file format.

  When the user designates a representative image for identifying the storage medium, representative image identification data indicating the representative image is given by the electronic camera 1 to the image data that has become the representative image. For example, when the captured image data is an image file that conforms to the Exif (Exchangeable image file format for digital still cameras) standard, the representative image identification data is recorded using a maker note tag in the header area. The

  The display controller 44 is connected to the auxiliary memory 45 and the electronic paper 46, respectively. The display controller 44 executes writing / reading of data to / from the auxiliary memory 45 and display control of the electronic paper 46.

  The auxiliary memory 45 is composed of a nonvolatile memory such as a flash memory. Various data used for display on the electronic paper 46 are stored in the auxiliary memory 45.

  FIG. 3 shows an example of the storage area of the auxiliary memory 45. For example, the auxiliary memory 45 stores identification image data. Here, the identification image in one embodiment is an image displayed on the electronic paper 46 for identifying the storage medium. As an example, the identification image is configured by a QQVGA size (or QVGA size) reduced image that has a one-to-one correspondence with the captured image stored in the main memory 43. In one embodiment, when the above-described representative image is designated, the identification image is composed of a reduced image corresponding to the above-described representative image. When the representative image is not designated, the identification image is composed of a reduced image corresponding to the last image captured among the captured images.

  The auxiliary memory 45 also stores history data related to the representative image. The history data in one embodiment is composed of text data in which the file name of a captured image designated as a representative image is recorded. When the representative image is changed, the file name of the representative image before the change is sequentially recorded in the history data with the file name of the current representative image as the head. Of course, when the representative image is changed a plurality of times, the file names of past representative images are all left in the history data.

  As an example, when captured image data with file names “A”, “B”, and “C” are sequentially designated as representative images, the CPU 19 records the file names of the image data in the newest order as representative images. To generate history data (in order of “C”, “B”, “A”). Thereby, the electronic camera 1 can confirm the presence / absence of the setting of the representative image and the file name of the past representative image by referring to the history data.

  In addition, when the representative image is changed in one embodiment, all of the reduced image data corresponding to the past representative image is stored in the auxiliary memory 45. These reduced images corresponding to past representative images can be used as identification images when the current representative image is deleted in a deletion check process described later.

  As an example, when the captured images having the file names “A”, “B”, and “C” are sequentially designated as representative images as described above, the auxiliary memory 45 stores “A”, “B”, and “C”. All the reduced images corresponding to are stored.

  Each reduced image in the auxiliary memory 45 is given a file name indicating the correspondence with the original captured image by the CPU 19. Therefore, the CPU 19 can determine which of the past representative images the reduced image in the auxiliary memory 45 refers to by referring to the file name of the reduced image.

  The electronic paper 46 is a thin-plate display device that can electrically rewrite the display and can display a non-volatile display even when the power is turned off. Note that, as the electronic paper 46 of one embodiment, for example, a liquid crystal type electronic paper using cholesteric liquid crystal or an electronic paper using microcapsules can be used.

  The display surface of the electronic paper 46 is disposed so as to be visible from the outside of the storage medium 2. Then, the identification image is displayed on the display surface of the electronic paper 46 (see FIG. 4). Thereby, since the identification image is displayed in a non-volatile manner on the outer surface of the storage medium 2 with electronic paper by the electronic paper 46, the user can easily identify the storage medium.

<Explanation of shooting mode operation>
Hereinafter, an operation example in the shooting mode of the electronic camera 1 according to the embodiment will be described with reference to the flowchart of FIG. The shooting mode in one embodiment includes two sub-modes: a “still image shooting mode” for shooting a still image and a “moving image shooting mode” for shooting a moving image. Note that the CPU 19 performs switching between the “still image shooting mode” and the “moving image shooting mode” in accordance with an operation from the operation unit 25.

  In addition, a series of processing in the shooting mode is started with a power-on operation of the electronic camera 1 as a trigger. Note that the operation of the electronic camera 1 in the shooting mode is controlled by a program executed by the CPU 19.

(Step S101)
The CPU 19 initializes the system of the electronic camera 1 in response to power-on. At this time, the CPU 19 extends the lens unit 11 to a position where photographing can be performed, and moves the lens positions of the zoom lens 11a and the focusing lens 11b to the initial positions to initialize the lenses.

(Step S102)
The CPU 19 drives the image sensor 16 to start capturing a through image. Thereafter, the through images are sequentially generated at predetermined intervals.

(Step S103)
The CPU 19 turns on the monitor 23 and starts displaying a moving image on the shooting screen based on the through image. Accordingly, the user can perform framing for determining the shooting composition and zooming by operating the zoom button while referring to the image on the monitor 23 in the shooting mode.

(Step S104)
The CPU 19 reads the state of the operation unit 25 and determines whether or not the operation mode of the electronic camera 1 is set to the shooting mode. As an example, the CPU 19 makes a NO determination in S <b> 104 in order to start the playback mode when receiving a pressing operation of the playback button. If the above requirement is satisfied (YES side), the process proceeds to S106. On the other hand, if the above requirement is not satisfied (NO side), the process proceeds to S105.

(Step S105)
The CPU 19 stops driving the image sensor 16 and finishes capturing the through image. Thereby, the moving image display of the shooting screen on the monitor 23 is also interrupted. Thereafter, the CPU 19 starts a process of S301 in a reproduction mode described later.

(Step S106)
The CPU 19 executes AF calculation, AE calculation, and AWB calculation using the through image data. Note that AF calculation, AE calculation, and AWB calculation in S106 are periodically performed until the release button is half-pressed in the shooting mode.

(Step S107)
The CPU 19 determines whether or not the release button is half-pressed. If the release button is pressed halfway (YES side), the process proceeds to S110. On the other hand, if the release button is not half-pressed (NO side), the process proceeds to S108.

(Step S108)
The CPU 19 determines whether a power-off operation has been accepted. If the above requirement is satisfied (YES side), the process proceeds to S109. On the other hand, if the above requirement is not satisfied (NO side), the CPU 19 returns to S104 and repeats the above operation.

(Step S109)
The CPU 19 returns the lens unit 11 to the housed state, cuts off the power supply to each part of the electronic camera 1 and ends the series of processes.

(Step S110)
The CPU 19 executes AF calculation, AE calculation, and AWB calculation in response to the release button being pressed halfway. Thereafter, the CPU 19 stops the AF calculation, the AE calculation, and the AWB calculation and fixes the shooting condition parameters until the recording image is taken or the release button is half-pressed.

(Step S111)
The CPU 19 determines whether or not the release button has been fully pressed. When the release button is fully pressed (YES side), the process proceeds to S113. On the other hand, when the release button is not fully pressed (NO side), the CPU 19 proceeds to S112.

(Step S112)
The CPU 19 determines whether the half-press of the release button has been released. When the half-press of the release button is released (YES side), the CPU 19 returns to S104 and repeats the above operation. On the other hand, when the half-press of the release button is continued (NO side), the CPU 19 returns to S111 and waits for a full-press operation of the release button.

(Step S113)
The CPU 19 determines whether or not the current mode is the “still image shooting mode”. In the “still image shooting mode” (YES side), the process proceeds to S114. On the other hand, in the “moving image shooting mode” (NO side), the process proceeds to S115.

(Step S114)
The CPU 19 drives the image sensor 16 to capture a still image for recording. The recording of the still image for recording is performed based on the shooting condition parameters set in S110. The recording still image data is recorded in the main memory 43 of the electronic paper-equipped storage medium 2 through the recording I / F 24 after predetermined processing is performed by the signal processing unit 17 and the image processing unit 27. Is done. Then, the CPU 19 restarts the through image acquisition operation after the recording still image capturing process is completed. When the process of S114 is completed, the CPU 19 shifts the process to S118.

(Step S115)
The CPU 19 drives the image sensor 16 to start capturing a moving image for recording. The recording of the moving image for recording is performed based on the shooting condition parameter set in S110. In the example of the embodiment, the image size of the moving image is set to the VGA size.

  The data of each frame of the moving image for recording is subjected to predetermined processing by the signal processing unit 17 and the image processing unit 27, and then, for example, the first memory 20 or the main memory 43 of the storage medium 2 with electronic paper. And so on.

(Step S116)
The CPU 19 determines whether or not there is a moving image shooting end instruction. For example, the CPU 19 determines that a moving image shooting end instruction has been issued when the release button is fully pressed. If the above requirement is satisfied (YES side), the process proceeds to S117. On the other hand, when the above requirement is not satisfied (NO side), the CPU 19 continues to capture a moving image.

(Step S117)
The image processing unit 27 generates moving image data for recording in a predetermined file format in accordance with an instruction from the CPU 19. Then, the CPU 19 records the moving image data for recording in the main memory 43 of the storage medium 2 with electronic paper via the recording I / F 24. The CPU 19 resumes the through image acquisition operation after the recording of the moving image data is completed.

(Step S118)
CPU19 performs the information update process of the storage medium 2 with an electronic paper. The information update processing subroutine will be described below with reference to FIG.

  Step S201: The CPU 19 determines whether or not a representative image designated by the user is set in the currently connected storage medium 2 with electronic paper. Specifically, the CPU 19 in S201 searches the auxiliary memory 45 for history data. When the history data does not exist in the auxiliary memory 45, the CPU 19 determines that no representative image exists in the storage medium 2 with electronic paper.

  When the representative image is set (YES side), the CPU 19 returns to the processing of the flowchart of FIG. In this case (YES side of S201), the CPU 19 does not update the identification image displayed on the electronic paper unit 46. On the other hand, when the representative image is not set (NO side), the process proceeds to S202.

  Step S202: In response to an instruction from the CPU 19, the image processing unit 27 performs resolution conversion processing for reducing the recording image captured this time to a predetermined image size (eg, QQVGA size or QVGA size).

  Here, in the still image shooting mode, the image processing unit 27 in S202 generates a reduced image from the recording still image. In the moving image shooting mode, the image processing unit 27 in S202 generates a reduced image from the first frame among the moving images for recording.

  Step S203: The CPU 19 overwrites and records the reduced image data generated in S202 in the identification image storage area set in the auxiliary memory 45. Thereby, when the representative image is not set in the storage medium 2 with the electronic paper, a reduced image corresponding to the image captured last among the captured images stored in the main memory 43 is stored in the auxiliary memory 45. Only one frame is stored as an identification image. Note that the CPU 19 may overwrite-record a thumbnail image (160 × 120 pixels) compliant with the Exif standard as an identification image.

  Step S204: The CPU 19 switches the identification image displayed on the electronic paper 46 to the reduced image corresponding to the image captured last (the reduced image generated in S202) via the display controller 44. Thereafter, the CPU 19 returns to the process of the flowchart of FIG. 5 from the information update process subroutine.

  And CPU19 returns to S104 after the process of S118, and repeats the said operation | movement. Above, description of the flowchart of FIG. 5 is complete | finished.

  When the representative image is not set, the electronic camera 1 according to the embodiment displays only the reduced image corresponding to the last photographed image on the electronic paper 46 as the identification image. On the other hand, when the representative image is set, the electronic camera 1 according to the embodiment displays the identification image corresponding to the representative image on the electronic paper 46 as it is without updating the identification image every time shooting is performed. .

  Therefore, in one embodiment, an identification image that is considered to be more discriminating is displayed on the electronic paper 46 of the storage medium 2. Since the display of the identification image by the electronic paper 46 is maintained as it is even after the storage medium 2 is detached from the electronic camera 1, according to one embodiment, the identification of the storage medium 2 is increased without increasing the user's trouble. It becomes possible to raise.

<Description of playback mode operation>
Hereinafter, an operation example in the playback mode of the electronic camera 1 according to the embodiment will be described with reference to flowcharts of FIGS. 7 and 8. A series of processes in the reproduction mode is started after the process of S105 in the flowchart of FIG. Note that the operation of the electronic camera 1 in the playback mode is controlled by a program executed by the CPU 19.

(Step S301)
The CPU 19 reads the image data to be reproduced from the recording I / F 24. Specifically, the CPU 19 in S301 reads the data of the last image taken from the main memory 43 of the electronic paper-equipped storage medium 2 as a reproduction target.

(Step S302)
The CPU 19 determines whether or not the current reproduction target is still image data. When the reproduction target is still image data (YES side), the process proceeds to S303. On the other hand, when the reproduction target is moving image data (NO side), the process proceeds to S308.

(Step S303)
The CPU 19 reproduces and displays the current reproduction target still image on the monitor 23.

(Step S304)
The CPU 19 determines whether or not there is an instruction to delete still image data (deletion button is pressed). If the above requirement is satisfied (YES side), the process proceeds to S305. On the other hand, if the above requirement is not satisfied (NO side), the process proceeds to S318.

(Step S305)
The CPU 19 performs a deletion check process for confirming whether or not the still image to be deleted is a representative image. Hereinafter, the deletion check processing subroutine will be described with reference to FIG.

  Step S401: The CPU 19 determines whether or not the image to be deleted is a representative image. As an example, the CPU 19 in S401 refers to the header area of the data of the captured image to be deleted, and determines that it is a representative image when there is representative image identification data.

  If the above requirement is satisfied (YES side), the process proceeds to S402. On the other hand, if the above requirement is not satisfied (NO side), the process proceeds to S409.

  Step S402: The CPU 19 warns the user that the image to be deleted is a representative image. As an example, the CPU 19 in S402 displays characters such as “Representative image. Are you sure you want to delete it? YES / NO” on the monitor 23 and requests the user to confirm the deletion of the representative image. . At this time, the CPU 19 may output a warning sound from a speaker (not shown).

  Step S403: The CPU 19 determines whether or not a representative image deletion confirmation input (S402) has been received. If there is a representative image deletion confirmation input (YES side), the process proceeds to S404. On the other hand, when the deletion of the representative image is canceled (NO side), the CPU 19 ends the subroutine of the deletion check process and returns to the process of S318 in the flowcharts of FIGS.

  Step S404: The CPU 19 refers to the history data stored in the auxiliary memory 45 of the electronic paper-equipped storage medium 2. Then, the CPU 19 detects the newest image as the representative image among the past representative images remaining in the main memory 43.

  Specifically, the CPU 19 searches the main memory 43 for an image that was the representative image one before the representative image to be deleted this time, based on the history data. If the image can be detected, the CPU 19 shifts the process to S405. On the other hand, when the image is deleted from the main memory 43, the CPU 19 searches for an image that was the representative image two times before the representative image to be deleted this time. Thereafter, the CPU 19 sequentially searches past representative images according to the order of the file names in the history data by the same procedure.

  Step S405: The CPU 19 determines whether or not a past representative image has been detected in S404. If the above requirement is satisfied (YES side), the process proceeds to S406. On the other hand, if the above requirement is not satisfied (NO side), the process proceeds to S409.

  Step S406: The CPU 19 sets the newest image (the image detected in S404) as the representative image among the past representative images again as the representative image. Thereby, when a past representative image exists in the main memory 43, if the representative image is deleted, the past representative image is selected as an identification image.

  Step S407: The CPU 19 switches the identification image displayed on the electronic paper 46 to a reduced image corresponding to the new representative image (S406) via the display controller 44. Since the reduced image corresponding to the new representative image is stored in the auxiliary memory 45, the CPU 19 can quickly change the image display of the electronic paper 46.

  Step S408: The CPU 19 edits the history data and deletes the reduced image data corresponding to the deleted representative image from the auxiliary memory 45. Thereafter, the CPU 19 returns to the processing of the flowcharts of FIGS. 7 and 8 from the deletion check processing subroutine.

  Step S409: In response to an instruction from the CPU 19, the image processing unit 27 generates a reduced image corresponding to the image captured last among the captured images. Then, the CPU 19 records the reduced image data in the auxiliary memory 45 and causes the electronic paper 46 to display a reduced image corresponding to the image captured last as an identification image. In this case, since there is no representative image, the CPU 19 deletes history data and reduced image data other than the identification image from the auxiliary memory 45.

  Thereby, when the past representative image does not exist in the main memory 43, when the representative image is deleted, the last captured image is selected as the identification image. Thereafter, the CPU 19 returns to the processing of the flowcharts of FIGS. 7 and 8 from the deletion check processing subroutine.

(Step S306)
The CPU 19 deletes the currently reproduced image data from the main memory 43 of the electronic paper-equipped storage medium 2.

(Step S307)
The CPU 19 sets an image whose shooting order is one before the image deleted in S306 among the captured images stored in the main memory 43 as a reproduction target. Then, the CPU 19 reads data of a new reproduction target image from the recording I / F 24. Thereafter, the CPU 19 shifts the processing to S320.

(Step S308)
The CPU 19 displays the first frame of the moving image that is the current reproduction target on the monitor 23.

(Step S309)
The CPU 19 determines whether or not there is an instruction to start playback of the moving image that is the current playback target. If the above requirement is satisfied (YES side), the process proceeds to S310. On the other hand, if the above requirement is not satisfied (NO side), the process proceeds to S314.

(Step S310)
The CPU 19 reproduces and displays the moving image on the monitor 23 in response to the moving image reproduction start instruction (S309).

(Step S311)
The CPU 19 determines whether or not a playback stop operation has been performed during playback of a moving image. If the above requirement is satisfied (YES side), the process proceeds to S312. On the other hand, if the above requirement is not satisfied (NO side), the process proceeds to S313.

(Step S312)
The CPU 19 stops the reproduction of the moving image and moves the process to S314.

(Step S313)
The CPU 19 determines whether or not the reproduction of all frames of the moving image to be reproduced has been completed. If all of the moving image reproduction has been completed (YES side), the flow proceeds to S314. On the other hand, if the reproduction of the moving image has not ended (NO side), the CPU 19 returns to S311 and repeats the above operation.

(Step S314)
The CPU 19 determines whether or not there is an instruction to delete moving image data (deletion button pressing). If the above requirement is satisfied (YES side), the process proceeds to S315. On the other hand, if the above requirement is not satisfied (NO side), the process proceeds to S318.

(Step S315)
The CPU 19 performs a deletion check process for confirming whether or not the first frame of the moving image to be deleted is a representative image. Note that the deletion check process in S315 is the same as that in S305, and a duplicate description is omitted.

(Step S316)
The CPU 19 deletes the moving image data currently being reproduced from the main memory 43 of the storage medium 2 with electronic paper.

(Step S317)
The CPU 19 sets an image whose shooting order is one before the moving image deleted in S306 among the captured images stored in the main memory 43 as a reproduction target. Then, the CPU 19 reads data of a new reproduction target image from the recording I / F 24. Thereafter, the CPU 19 shifts the processing to S320.

(Step S318)
The CPU 19 determines whether or not an operation to change the image to be reproduced has been performed when the still image or the moving image is not deleted. If there is an operation for changing the image to be reproduced (YES side), the process proceeds to S319. On the other hand, when there is no operation for changing the image to be reproduced (NO side), the process proceeds to S320.

(Step S319)
The CPU 19 sets an image designated by the change operation in S318 among the captured images stored in the main memory 43 as a new reproduction target. Then, the CPU 19 reads data of a new reproduction target image from the recording I / F 24.

(Step S320)
The CPU 19 performs a representative image designation process for a new image to be reproduced. Hereinafter, a subroutine for designating a representative image will be described with reference to FIG. In the example of FIG. 10, for the sake of simplicity, the description will be made on the assumption that still image data becomes a new reproduction target, but it goes without saying that substantially the same processing is performed for moving image data. Nor.

  Step S501: The CPU 19 determines whether or not the current reproduction target image is a representative image. As an example, the CPU 19 in S501 refers to the header area of the captured image data, and determines that it is a representative image when there is representative image identification data.

  If the above requirement is satisfied (YES side), the process proceeds to S502. On the other hand, when the above requirement is not satisfied (NO side), the process proceeds to S503.

  Step S502: The CPU 19 reproduces and displays the representative image on the monitor 23. At this time, the CPU 19 superimposes a mark indicating that the image being reproduced is a representative image (for example, a character display of “representative image”) on the reproduced image on the monitor 23 (see FIG. 11). Thereby, the user can easily recognize that the image reproduced on the monitor 23 is the representative image. Thereafter, the CPU 19 returns from the subroutine for representative image designation processing to the processing of the flowcharts of FIGS.

  Step S503: The CPU 19 determines whether or not an operation for designating the current reproduction target image as a representative image has been accepted. If the above requirement is satisfied (YES side), the process proceeds to S504. On the other hand, if the above requirement is not satisfied (NO side), the CPU 19 returns to the processing of the flowcharts of FIGS. 7 and 8 from the representative image designation processing subroutine.

  Step S504: In response to an instruction from the CPU 19, the image processing unit 27 generates a reduced image from the representative image newly specified in S503. At this time, the CPU 19 determines whether an image trimming instruction has been received from the user. If the above requirement is satisfied (YES side), the process proceeds to S505. On the other hand, when the above requirement is not satisfied (NO side), the process proceeds to S506.

  Step S505: The image processing unit 27 generates a reduced image from the partial region of the representative image by trimming. Thereafter, the CPU 19 shifts the processing to S507. Note that the trimming in S505 is for determining the generation range of the reduced image, and the image data stored in the main memory 43 is held as it is.

  As an example, the image processing unit 27 superimposes a frame indicating the trimming range and position together with the representative image on the monitor 23 to allow the user to specify the trimming range and position of the image. At this time, the image processing unit 27 changes the frame display range according to the user's operation of the zoom button (see FIG. 12A). Further, the image processing unit 27 changes the position of the frame display according to the operation of the user's cross key (see FIG. 12B). Then, the image processing unit 27 determines the trimming range and position by pressing the determination button. Thereafter, the image processing unit 27 generates a reduced image from the trimmed representative image. As a result, the user can customize the identification image, and the identification performance in the identification image in the electronic paper-equipped storage medium 2 can be further improved.

  As another example, the image processing unit 27 may perform a known face detection process on the representative image and automatically determine the trimming range and position based on the position of the person's face. For example, the image processing unit 27 performs trimming so that the face of a person included in the representative image has a constant size at the center. In this case, an identification image that allows the user to more easily recognize a person can be generated.

  Step S506: In this case, the image processing unit 27 generates a reduced image by reducing the representative image newly specified in S503 as it is in accordance with an instruction from the CPU 19.

  Step S507: The CPU 19 records the reduced image data generated in S505 or S506 in the auxiliary memory 45 as an identification image.

  Step S508: The CPU 19 switches the identification image displayed on the electronic paper 46 to the reduced image corresponding to the new representative image (the reduced image generated in S505 or S506) via the display controller 44.

  Step S509: The CPU 19 associates the representative image identification data with the new representative image data. In addition, the CPU 19 deletes the representative image identification data associated with the past representative image data, and updates the history data. Thereafter, the CPU 19 returns from the subroutine for representative image designation processing to the processing of the flowcharts of FIGS.

(Step S321)
The CPU 19 determines whether or not a reproduction mode end operation has been received. If there is an operation for ending the reproduction mode (YES side), the process proceeds to S322. On the other hand, when there is no operation for ending the reproduction mode (NO side), the process proceeds to S323.

(Step S322)
The CPU 19 ends the reproduction and display of the image stored in the recording medium 2 with electronic paper, and drives the imaging element 16 again to start capturing a through image. Thereafter, the CPU 19 changes the operation mode to the shooting mode, and proceeds to the processing of S104 in the flowchart of FIG.

(Step S323)
The CPU 19 determines whether a power-off operation has been accepted. If the above requirement is satisfied (YES side), the process proceeds to S324. On the other hand, if the above requirement is not satisfied (NO side), the CPU 19 returns to S302 and repeats the above operation.

(Step S324)
The CPU 19 returns the lens unit 11 to the housed state, cuts off the power supply to each part of the electronic camera 1 and ends the series of processes. Above, description of the flowchart of FIG. 7, FIG. 8 is complete | finished.

  In one embodiment, the representative image identification data is recorded in association with the representative image data, thereby improving convenience when deleting the representative image or reproducing and displaying the representative image. Images can be managed efficiently.

<Supplementary items of the embodiment>
(1) In the above embodiment, the main memory 43 and the auxiliary memory 45 of the storage medium 2 with electronic paper may be configured as one memory. In the above embodiment, history data may be recorded in the main memory 43.

  (2) In the above embodiment, the electronic paper 46 of the storage medium 2 with electronic paper may display information related to the main memory 43 (remaining storage capacity of the main memory 43, last update date and time) superimposed on the identification image. . When displaying information related to the main memory 43 on the electronic paper, the CPU 19 may update the information display on the electronic paper 46 sequentially each time data is written to or deleted from the main memory 43.

  (3) In the above embodiment, the example in which the representative image identification data is recorded in association with the header of the representative image data has been described. However, the representative image identification data is configured by a file separate from the representative image data. Also good.

  (4) In the above embodiment, an example in which the identification image is generated from only one captured image has been described. However, a plurality of images may be included in one frame of the identification image.

  (5) The configuration of the above embodiment and the modification is merely an example. Therefore, when implementing the present invention, all combinations of the configurations shown in the above-described embodiments and modifications and the processing order thereof can be taken.

  From the above detailed description, features and advantages of the embodiments will become apparent. It is intended that the scope of the claims extend to the features and advantages of the embodiments as described above without departing from the spirit and scope of the right. Further, any person having ordinary knowledge in the technical field should be able to easily come up with any improvements and modifications, and there is no intention to limit the scope of the embodiments having the invention to those described above. It is also possible to use appropriate improvements and equivalents within the scope disclosed in.

1 is a block diagram illustrating a configuration example of an electronic camera system according to an embodiment. The block diagram which shows the structural example of the storage medium with electronic paper of one Embodiment Schematic diagram showing an example of the storage area of the auxiliary memory The figure which shows the example of a display of the identification image in a storage medium with electronic paper 6 is a flowchart showing an operation example in a shooting mode of the electronic camera in one embodiment. Flow chart showing an example of the operation of a subroutine for information update processing 6 is a flowchart showing an operation example in a playback mode of the electronic camera in one embodiment. Flow chart continued from FIG. Flow chart showing an example of the operation of a subroutine for deletion check processing Flow chart showing an example of operation of a subroutine for representative image designation processing The figure which shows an example of the reproduction | regeneration display state of a representative image (A) The figure which shows designation | designated of the range of trimming, (b) The figure which shows designation | designated of the position of trimming

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 ... Electronic camera, 2 ... Storage medium with electronic paper, 16 ... Imaging device, 17 ... Signal processing part, 18 ... Imaging control part, 19 ... CPU, 22 ... Display control part, 23 ... Monitor, 24 ... Recording I / F , 25 ... operation unit, 27 ... image processing unit, 28 ... device side terminal, 41 ... medium side terminal, 42 ... memory controller, 43 ... main memory, 44 ... display controller, 45 ... auxiliary memory, 46 ... electronic paper

Claims (5)

A medium side terminal;
A storage unit including a nonvolatile memory;
An electronic paper capable of displaying an image, and an electronic device in which a storage medium is detachable,
The electronic device is
A device side terminal connectable to the medium side terminal;
A control unit that transmits and receives data to and from the storage medium connected via the device-side terminal, and acquires data of a representative image specified from a plurality of captured images stored in the storage unit;
An image processing unit that generates the identification image corresponding to the representative image as an identification image to be displayed on the electronic paper;
The control unit records representative image identification data for identifying the representative image from the plurality of captured images in the storage unit when the representative image is set, and history data indicating past representative images Is recorded in the storage unit after being updated. The electronic device according to claim 1,
It further includes an operation unit that accepts operations related to image erasure,
The electronic device is characterized in that the control unit outputs a warning based on the representative image identification data when the representative image is selected as an image to be erased from the storage unit. The electronic device according to claim 2,
The control unit sets a new representative image from the captured images and updates the representative image identification data when the data of the representative image is erased from the storage unit. machine. The electronic device according to claim 1,
A display unit for reproducing and displaying the captured image;
The control device causes the display unit to superimpose and display a mark indicating a representative image based on the representative image identification data when the representative image is reproduced and displayed. An imaging unit that captures an image of a subject and generates captured image data;
An electronic camera comprising: the electronic device according to claim 1.

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