JP2010028338A - Image capturing apparatus - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image capturing apparatus which easily generates video files that are to be uploaded to servers on the Internet. <P>SOLUTION: The image capturing apparatus includes: an image capturing means for capturing an image of an object to generate image data; a first storage means for storing video files which are generated by sequentially storing image data generated by the image capturing means; a second storage means for storing time information related to the longest record time for one video file; a first detection means for detecting elapsed time from beginning of image data generation by the image capturing means; a first calculation means for calculating the remaining time that the image capturing means can capture the image of the object based on the time information stored in the second storage means and the detection results of the first detection means; and a display means for displaying the calculation results of the first calculation means. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an imaging apparatus, and more particularly to an imaging apparatus capable of capturing a moving image.

Patent Document 1 discloses a digital camera that can be connected to a network such as the Internet. When the digital camera is connected to a network and transfers a captured image via the network, the digital camera deletes additional information such as Exif (Exchange image file format) information added to the captured image data. Thus, the digital camera can prevent information other than the captured image when transferring the captured image via the network.
JP 2004-343627 A

  However, Patent Document 1 does not disclose an imaging device that can easily generate a moving image file that can be uploaded to a server on the Internet.

  An object of the present invention is to provide an imaging apparatus capable of easily generating a moving image file that can be uploaded to a server on the Internet.

  In order to solve the above problems, an imaging apparatus according to the present invention is generated by sequentially storing an imaging unit capable of generating image data by capturing a subject image, and image data generated by the imaging unit. A first storage means capable of storing a moving image file, a second storage means for storing time information relating to the longest recording time for one moving image file, and generation of image data by the imaging means The remaining time that can be imaged by the imaging means is determined based on the first detection means for detecting the elapsed time, the time information stored in the second storage means, and the detection result by the first detection means. First calculation means for calculating, and display means for displaying a calculation result by the first calculation means are provided.

  The imaging apparatus according to the present invention also includes a third storage unit that stores capacity information related to the maximum storage capacity of one moving image file, and a capacity of the moving image file that is sequentially generated in the first storage unit. Based on the second detection means to detect, at least the capacity information stored in the third storage means, and the detection result by the second detection means, the remaining time that can be imaged by the imaging means A second calculating means for calculating; a comparing means for comparing the calculation result by the first calculating means and the calculation result by the second calculating means; and the display means according to the comparison result by the comparing means. The calculation result by the first calculation means or the calculation result by the second calculation means may be displayed.

  In addition, an imaging apparatus according to the present invention includes an imaging unit capable of generating image data by capturing a subject image, and a moving image file generated by sequentially storing image data generated by the imaging unit. Storable first storage means, second storage means for storing time information regarding the longest recording time for one moving image file, and detection of elapsed time since the start of image data generation by the imaging means And a stop means for stopping the generation of image data by the imaging means before the elapsed time indicated by the detection result by the detection means exceeds the longest recording time indicated by the time information stored in the second storage means .

  In addition, an imaging apparatus according to the present invention includes an imaging unit capable of generating image data by capturing a subject image, and a moving image file generated by sequentially storing image data generated by the imaging unit. Storable first storage means, second storage means for storing time information regarding the longest recording time for one moving image file, and detection of elapsed time since the start of image data generation by the imaging means Before the elapsed time indicated by the detection result by the detection means exceeds the longest recording time indicated by the time information stored in the second storage means, based on the image data generated by the imaging means Switching means for switching the moving image file from the currently generated moving image file to a new moving image file.

  In the imaging apparatus according to the present invention, the first storage unit may store a plurality of moving image files generated by switching the moving image file to be generated by the switching unit in association with each other.

  In addition, an imaging apparatus according to the present invention includes a storage unit that can store a plurality of moving image files generated by continuously capturing moving images, and a moving image file stored in the storage unit. Readout and playback means, and control means for controlling the playback means so as to continuously play back a plurality of associated video files stored in the storage means.

  In addition, an imaging apparatus according to the present invention includes a storage unit that can store a plurality of moving image files generated by continuously capturing moving images, and a moving image file stored in the storage unit. Communication means capable of uploading to a server on the Internet, and control means for controlling the communication means to collectively upload a plurality of associated moving image files stored in the storage means.

  ADVANTAGE OF THE INVENTION According to this invention, the imaging device which can produce | generate etc. easily the moving image file which can be uploaded to the server on the internet can be provided.

[1. Embodiment 1]
[1-1. Overview〕
The digital camera 100 according to the present embodiment can capture a moving image. A user can upload a moving image file captured by the digital camera 100 to a server on the Internet. The present invention is an invention made in an imaging apparatus such as the digital camera 100 so that a moving image file that can be uploaded to a server on the Internet can be easily generated.

[1-2. Constitution〕
Hereinafter, the configuration of the digital camera 100 according to the present embodiment will be described with reference to the drawings.

[1-2-1. Electrical configuration)
The electrical configuration of the digital camera 100 according to this embodiment will be described with reference to FIG. FIG. 1 is a block diagram showing a configuration of the digital camera 100. The digital camera 100 captures a subject image formed by an optical system including the zoom lens 110 and the like with a CCD image sensor 180. The image data generated by the CCD image sensor 180 is subjected to various processes by the image processing unit 190 and stored in the memory card 240. Further, the image data stored in the memory card 240 can be displayed on the liquid crystal monitor 260. Hereinafter, the configuration of the digital camera 100 will be described in detail.

  The optical system of the digital camera 100 includes a zoom lens 110, an OIS 140, and a focus lens 170. The zoom lens 110 can enlarge or reduce the subject image by moving along the optical axis of the optical system. The OIS 140 includes a correction lens that can move in a plane perpendicular to the optical axis. The OIS 140 reduces the shake of the subject image by driving the correction lens in a direction that cancels the shake of the digital camera 100. The focus lens 170 adjusts the focus of the subject image by moving along the optical axis of the optical system.

  The zoom motor 130 drives the zoom lens 110. The zoom motor 130 may be realized by a pulse motor, a DC motor, a linear motor, a servo motor, or the like. The zoom motor 130 may drive the zoom lens 110 via a mechanism such as a cam mechanism or a ball screw. The detector 120 detects where the zoom lens 110 exists on the optical axis. The detector 120 outputs a signal related to the position of the zoom lens by a switch such as a brush in accordance with the movement of the zoom lens 110 in the optical axis direction.

  The OIS actuator 150 drives the correction lens in the OIS 140 in a plane perpendicular to the optical axis. The OIS actuator 150 can be realized by a planar coil or an ultrasonic motor.

  The CCD image sensor 180 captures a subject image formed by an optical system including the zoom lens 110 and generates image data. The CCD image sensor 180 performs various operations such as exposure, transfer, and electronic shutter.

  The image processing unit 190 performs various processes on the image data generated by the CCD image sensor 180. The image processing unit 190 processes the image data generated by the CCD image sensor 180 to generate image data to be displayed on the liquid crystal monitor 260 or to store image data to be re-stored in the memory card 240. Or generate. For example, the detector 160 performs various processes such as gamma correction, white balance correction, and flaw correction on the image data generated by the CCD image sensor 180. Further, the image processing unit 190 compresses the image data with respect to the image data generated by the CCD image sensor 180 by a compression format or the like conforming to the JPEG standard. The image processing unit 190 can be realized by a DSP or a microcomputer.

  The controller 210 is a control means for controlling the whole. The controller 210 can be realized by a semiconductor element or the like. The controller 210 may be configured only by hardware, or may be realized by combining hardware and software. The controller 210 can be realized by a microcomputer or the like.

  The memory 200 functions as a work memory for the image processing unit 190 and the controller 210. The memory 200 can be realized by, for example, a DRAM or a ferroelectric memory.

  The liquid crystal monitor 260 can display an image indicated by image data generated by the CCD image sensor 180 and an image indicated by image data read from the memory card 240. Further, the liquid crystal monitor 260 can display an operation menu for operating the digital camera 100, information on the displayed image, and the like.

  The gyro sensor 220 is composed of a vibration material such as a piezoelectric element. The gyro sensor 220 vibrates a vibration material such as a piezoelectric element at a constant frequency, converts a force generated by the Coriolis force into a voltage, and obtains angular velocity information. By obtaining angular velocity information from the gyro sensor 220 and driving the correction lens in the OIS in a direction that cancels the shaking, the camera shake given to the digital camera 100 by the user is corrected.

  The card slot 230 is detachable from the memory card 240. The card slot 230 can be mechanically and electrically connected to the memory card 240. The memory card 240 includes a flash memory, a ferroelectric memory, and the like, and can store data.

  The internal memory 280 can store various information. For example, the digital camera 100 can capture a moving image. The digital camera 100 can capture a moving image in a limited shooting mode that limits the longest imaging time of one moving image file and the maximum storage capacity. In this case, for example, the internal memory 280 stores information on the longest imaging time and the maximum storage capacity of one moving image file. The internal memory 280 can also store captured image data.

  The operation member 250 is a generic name for members that receive operation instructions from the user. For example, the user can switch the mode of the digital camera 100 (for example, switching between the shooting mode and the playback mode), record a captured image, and the like by operating the operation member 250.

  The communication unit 270 is a member for connecting the digital camera 100 to the Internet via an external device. For example, it can be realized by a wireless LAN, USB, IEEE 1394, or the like.

[1-2-1. Correspondence with the present invention)
The CCD image sensor 180 is an example of an imaging unit of the present invention. The memory card 240 is an example of the first storage unit of the present invention. The internal memory 280 is an example of the second storage unit of the present invention. The controller 210 is an example of a first detection unit of the present invention. The controller 210 is an example of a first calculation unit of the present invention. The liquid crystal monitor 260 is an example of the display means of the present invention. The internal memory 280 is an example of the third storage unit of the present invention. The controller 210 is an example of the second detection means of the present invention. The controller 210 is an example of a second calculation unit of the present invention. The controller 210 is an example of a comparison unit of the present invention. The controller 210 is an example of the stopping means of the present invention. The controller 210 is an example of the switching means of the present invention.

  The memory card 240 is an example of the storage means of the present invention. The controller 210 is an example of the reproducing means of the present invention. The controller 210 is an example of the control means of the present invention. The communication unit 270 is an example of a communication unit of the present invention.

[1-3. Operation)
Hereinafter, the operation of the digital camera 100 according to the present embodiment will be described with reference to the drawings.

[1-3-1. (Record)
[1-3-1-1. (Recording operation)
A recording operation of the digital camera 100 according to the present embodiment will be described with reference to FIG. FIG. 2 is a flowchart for explaining the recording operation of the digital camera 100. The user can set the digital camera 100 to the restricted shooting mode by operating the operation member 250 (S101). Here, the limited shooting mode is a mode in which the longest recording time and the maximum storage capacity for each moving image file to be generated are limited. Here, for the longest recording time and the maximum storage capacity, the longest recording time and the maximum storage capacity defined in a predetermined video upload site on the Internet are used. In the present embodiment, the longest recording time is 10 minutes and the maximum storage capacity is 100 MB.

  When the restricted shooting mode is set, the controller 210 waits until the recording start button of the operation member 250 is pressed (S102). When the recording start button is pressed, the controller 210 starts recording the image data generated by the CCD image sensor 180 on the memory card 240 as a moving image file (S103).

  When recording of the image data to the memory card 240 is started, the controller 210 acquires information regarding the image data being recorded and information regarding the restricted shooting mode (S104). That is, the controller 210 detects the bit rate information (B) of the image data being recorded, the current shooting time information (T) of the image data being recorded, and the longest shooting time per moving image file in the limited shooting mode. Information (Trec) and maximum storage capacity information (Brec) per moving image file in the restricted shooting mode are acquired.

  When these pieces of information are acquired, the controller 210 determines the remaining recordable time from the acquired bit rate information of the image data being recorded, the current shooting time information, and the maximum storage capacity information for each moving image file. Calculate (S105). Specifically, the controller 210 calculates the remaining imageable time (Tsize) by calculating (Brec−B × T) / B.

  When the remaining shootable time is calculated from the maximum storage capacity information, the controller 210 calculates the remaining shootable time from the current shooting time information and the longest shooting time information per moving image file (S106). ). Specifically, the controller 210 calculates the remaining photographing time (Ttime) by calculating Trec-T.

  When the remaining shootable time is calculated from the longest recording time information, the controller 210 calculates the remaining shootable time (Tsize) calculated from the maximum storage capacity information and the remaining shootable time (Ttime) calculated from the longest shooting time information. Are compared (S107).

  If Tsize is shorter than Ttime, the liquid crystal monitor 260 displays Tsize as the remaining shootable time (S108). Specific examples of display contents will be described later.

  On the other hand, when Ttime is shorter than Tsize, the liquid crystal monitor 260 displays Ttime as the remaining shootable time (S109). Specific examples of display contents will be described later.

  When either Ttime or Tsize is displayed on the liquid crystal monitor 260, the controller 210 determines whether or not the current shooting time exceeds the longest shooting time (S110). At the same time, the controller 210 determines whether or not the current shooting capacity exceeds the maximum storage capacity (S110).

  If it is determined that neither the longest shooting time nor the maximum storage capacity has been exceeded, the controller 210 determines whether the user has selected the end of shooting (S111). If it is determined that the end of shooting is selected, the controller 210 ends shooting. On the other hand, when determining that the end of shooting has not been selected, the controller 210 continues moving image shooting (S103).

  On the other hand, if it is determined that either the longest shooting time or the maximum storage capacity is exceeded, the controller 210 generates a moving image file that is generated based on the image data captured by the CCD image sensor 180. The file is switched to a new moving image file (S112).

  When generation of a new moving image file is started based on image data captured by the CCD image sensor 180, the controller 210 changes the file name of the moving image file generated before the currently generated moving image file. Change (S113). For example, assume that the file name of the moving image file generated before the currently generated moving image file is Movie.mpg. In this case, it is assumed that generation of a new moving image file is started based on image data captured by the CCD image sensor 180 by continuously capturing moving images. In this case, the controller 210 changes the file name of the moving image file (Movie.mpg) generated before the currently generated moving image file to Movie1 / 2.mpg, The file name of the moving image file is Movie2 / 2.mpg. In short, the controller 210 sets file names of a plurality of moving image files generated by continuously capturing moving images as file names that indicate the generation order of each moving image file.

  When the file name of the moving image file generated before the currently generated moving image file is changed, the liquid crystal monitor 260 displays the moving image file continuously captured by the currently reproduced moving image file. Information indicating the number of the generated moving image file is displayed (S114). Specific examples of display contents will be described later.

  As described above, the digital camera 100 according to the present embodiment displays the remaining recordable recording time calculated from the predetermined longest recording time or the maximum storage capacity on the liquid crystal monitor 260 when recording a moving image. In addition, the digital camera 100 according to the present embodiment uses the longest recording time and the maximum storage capacity defined in a predetermined video upload site on the Internet as the longest recording time and the maximum storage capacity. In this way, the digital camera 100 notifies the user who is shooting the remaining shooting time so that the currently generated moving image file can be uploaded to a predetermined video upload site on the Internet. Can do.

  In addition, the digital camera 100 according to the present embodiment, when the shooting time or capacity of the generated moving image file exceeds the longest recording time or the maximum storage capacity, image data generated by continuously capturing images. Based on the above, generation of a new moving image file is started. As a result, even if the generated moving image file exceeds the maximum recording time or the maximum storage capacity, a moving image file that can be uploaded to a predetermined video uploading site while continuing to shoot continuously. Can be generated.

  In addition, the digital camera 100 according to the present embodiment continuously captures a moving image and changes the file name of the previously generated moving image file when starting to generate a new moving image file. To do. Thereby, the digital camera 100 can notify the user of the relationship between each of the plurality of moving image files generated by continuously capturing moving images by the file name.

  In addition, when the digital camera 100 according to the present embodiment generates a plurality of moving image files by continuously capturing moving images, the currently generated moving image file can be obtained through a series of imaging operations. Information regarding whether the moving image file is generated second is displayed on the liquid crystal monitor 260. As a result, the digital camera 100 can notify the user of the moving image file that is currently generated through a series of imaging operations.

[1-3-1-2. Example of LCD monitor display during recording)
An example of display on the liquid crystal monitor 260 during the recording operation by the digital camera 100 will be described with reference to FIG. When a moving image is captured and the first moving image file is generated, the liquid crystal monitor 260 displays a screen such as the display screen 300. That is, the liquid crystal monitor 260 displays a screen such as the display screen 300 in step S108 or step S109 in FIG. In this case, the liquid crystal monitor 260 displays a display indicating that the currently set mode is the restriction mode, a display regarding the remaining recordable time calculated from the longest recording time and the maximum storage capacity, in addition to the captured subject image. Is displayed.

  In this way, by displaying on the liquid crystal monitor 260 a display that the currently set mode is the limit mode and a display relating to the remaining recordable time calculated from the longest recording time and the maximum storage capacity, If the original remaining shooting time of the digital camera 100 is short, the user can be prevented from misunderstanding.

  When a plurality of moving image files are generated by continuously capturing moving images, the liquid crystal monitor 260 displays a screen such as the display screen 310. That is, the liquid crystal monitor 260 displays a screen such as the display screen 310 in step S114 in FIG. In this case, in addition to the items displayed on the display screen 300, the liquid crystal monitor 260 indicates what number the moving image file currently generated is a moving image file generated through a series of imaging operations. A display and a display indicating how much time-moving images are captured through a series of imaging operations are displayed.

  Hereinafter, a plurality of moving image files generated through such a series of continuous imaging operations will be referred to as a divided moving image group.

[1-3-2. (Playback operation)
A reproduction operation of the digital camera 100 according to the present embodiment will be described with reference to FIG. FIG. 4 is a flowchart for explaining the playback operation of the digital camera 100. The user can set the digital camera 100 to the reproduction mode by operating the operation member 250 (S201). When the playback mode is set, the liquid crystal monitor 260 displays a list of thumbnail images associated with the moving image file stored in the memory card 240 (S202). For example, a screen like the display screen 320 shown in FIG. 5 is displayed. Here, the moving image file 321, the moving image file 322, and the moving image file 323 are divided moving image groups, and the moving image file 324, the moving image file 325, and the moving image file 326 are independent moving image files. When the list of thumbnail images is displayed, the controller 210 waits until a moving image file to be reproduced is selected by the user (S203). When the moving image file to be reproduced is selected, the detector 160 determines whether or not the selected moving image file is a partial moving image file in the divided moving image group (S204).

  If it is determined that it is not part of the moving image file in the divided moving image group, the detector 160 reproduces the selected moving image file and displays the moving image on the liquid crystal monitor 260 (S205). When the moving image file is reproduced, the detector 160 determines whether or not the reproduction of the moving image file is finished (S206). If it is determined that the playback of the moving image file has been completed, the liquid crystal monitor 260 again displays a list of thumbnail images associated with the moving image file stored in the memory card 240 (S202).

  On the other hand, if it is determined that it is a part of the moving image file in the divided moving image group, the liquid crystal monitor 260 displays a screen that prompts the user to select a moving image file reproduction method (S207). In the present embodiment, a screen such as a display screen 330 shown in FIG. 5 is displayed. For example, on this screen, the user can select one of the two items of “continuous playback from the top” and “continuous playback from this moving image”.

  When the reproduction method selection screen is displayed on the liquid crystal monitor 260, the detector 160 waits until the user selects the reproduction method (S208). When the reproduction method is selected, the detector 160 determines whether or not “continuous reproduction from the top” is selected (S209).

  If it is determined that “continuous playback from the top” has been selected, the detector 160 plays back the top moving image file in the divided moving image group of which the selected moving image file constitutes a part (S210).

  On the other hand, when determining that “continuous playback from the top” has not been selected, the detector 160 plays back the selected moving image file (S211).

  When these moving image files are reproduced, the detector 160 determines whether or not the reproduction of the moving image file is completed (S212). If it is determined that the playback of the moving image file has ended, the detector 160 determines whether or not the played back moving image file is the last moving image file among the moving image files that constitute the divided moving image group (S214). ). If it is determined that the file is the last moving image file, the detector 160 ends the reproduction of the moving image file and displays a list of thumbnail images on the liquid crystal monitor 260 (S202). On the other hand, when determining that it is not the last moving image file, the detector 160 reproduces the subsequent moving image file (S215).

  As described above, when the digital camera 100 according to the present embodiment reproduces a part of a plurality of moving image files that constitute a divided moving image group, the other moving images that constitute the same divided moving image group continuously. Play the file. Accordingly, the user can automatically and continuously reproduce a plurality of moving image files generated by continuously capturing images. As a result, the digital camera 100 can make the user less aware of the fact that a plurality of moving image files generated by continuously capturing images are divided into a plurality of parts.

[1-3-3. (Uploading video file)
A video file upload operation by the digital camera 100 according to the present embodiment will be described with reference to FIG. FIG. 6 is a flowchart for explaining a moving image file upload operation by the digital camera 100. The user can set the digital camera 100 to the upload mode by operating the operation member 250 (S301). Here, the upload mode is a mode for uploading a moving image file to an upload site on the Internet. When the upload mode is set, the communication unit 270 connects the digital camera 100 directly or indirectly to the Internet (S302). When the connection to the Internet is made, the controller 210 waits until a video image file upload site is selected (S303). When the upload site is selected, the liquid crystal monitor 260 displays a list of thumbnail images related to the moving image file that can be uploaded (S304). Specifically, the liquid crystal monitor 260 displays a screen such as the display screen 340 shown in FIG. When a list of thumbnail images related to the moving image file is displayed, the controller 210 waits until a moving image file to be uploaded is selected (S305). When the moving image file to be uploaded is selected, the controller 210 determines whether or not the selected moving image file is a partial moving image file among the moving image files constituting the divided moving image group (S306). ).

  If the controller 210 determines that it is not part of the moving image files constituting the divided moving image group, the controller 210 controls the communication unit 270 to upload the selected moving image file to an upload site on the Internet ( S307).

  On the other hand, if it is determined that the video files are part of the moving image files constituting the divided moving image group, the LCD monitor 260 uploads all moving image files constituting the divided moving image group or selects the selected moving image files. Options for uploading only the image file are displayed (S308). Specifically, the liquid crystal monitor 260 displays a screen such as a display screen 350 shown in FIG. When the options are displayed on the liquid crystal monitor 260, the controller 210 waits until a selection is made by the user (S309). When the selection is made by the user, the controller 210 determines which one has been selected by the user (S310).

  When the option to upload all the moving image files constituting the divided moving image group is selected, the controller 210 controls the communication unit 270 to upload all the moving image files constituting the divided moving image group (S311). ).

  On the other hand, when the option to upload only the selected moving image file is selected, the controller 210 controls the communication unit 270 to upload only the selected moving image file (S312).

  As described above, in the digital camera 100 according to the present embodiment, when some moving image files constituting the divided moving image group are selected as upload targets, other than the selected moving image files constituting the divided moving image group. The video image file can be uploaded to the upload site at the same time. The reason for this will be described below.

  The divided moving image group is a moving image that the user wanted to shoot even when the time limit is exceeded in the limited shooting mode. Although a plurality of moving image files constituting such a divided moving image group are basically divided as moving image files, it is convenient to handle them as one moving image from the viewpoint of the user. Therefore, when the user selects one moving image file among a plurality of moving image files constituting the divided moving image group, it is highly likely that the user selects another moving image file constituting the divided moving image group. It is done. Therefore, by enabling batch uploading of a plurality of moving image files constituting a divided moving image group, it is possible to shorten the time for selecting a moving image to be uploaded. In addition, by enabling batch upload of multiple video files that make up a divided video group, it is possible to prevent forgetting to upload part of other video files among the video files that make up the split video group Can do. Also, it is possible to provide an effect such as automatically selecting and uploading the upload order of moving images from the oldest one at the time of shooting.

[1-3-3-2. Check the contents of the uploaded video file)
Next, content confirmation of the uploaded moving image file will be described with reference to FIGS. By operating the operation member 250, the user can set the digital camera 100 to a mode for confirming the contents of the uploaded moving image file (S301). When the mode for checking the content of the uploaded moving image file is set, the controller 210 connects the digital camera 100 to the Internet via the communication unit 270 (S302). When connected to the Internet, the controller 210 waits until receiving an upload site selection from the user (S302).

  When the upload site is selected, the controller 210 acquires the uploaded moving image file information acquired via the Internet, and displays the thumbnail image of the uploaded moving image file on the liquid crystal monitor 260 (S304). For example, the liquid crystal monitor 260 displays a screen as shown in FIG. The liquid crystal monitor 260 displays a thumbnail image of the first frame of the uploaded moving image file (A1), a thumbnail image near the middle, and a thumbnail image near the end. The reason for this configuration will be described below.

  A high communication rate is required to reproduce a moving image file via the Internet. However, many digital cameras such as the digital camera 100 do not have such a high communication capability. In such a case, a configuration in which only the thumbnail of one frame among the frames constituting the moving image file is displayed is also conceivable. However, according to such a configuration, since the user can view only one thumbnail image, there is a case where the content of the moving image file as a whole cannot be recalled. Therefore, in the digital camera 100 according to the present embodiment, thumbnail images of a plurality of frames constituting the moving image file are displayed on the liquid crystal monitor 260. Thereby, even in a digital camera in which a communication rate for moving image reproduction is not secured, the user can easily check whether or not the uploaded moving image file is a moving image file to be uploaded. When the “next” icon is selected on this screen, the liquid crystal monitor 260 displays a plurality of thumbnail images related to the moving image file uploaded next to A1. When the “return” icon is selected, the liquid crystal monitor 260 displays a plurality of thumbnail images related to the moving image file uploaded before A1.

When the thumbnail image related to the uploaded moving image file is displayed, the controller 210 waits until the moving image file to be deleted is selected by the user (S305). When the moving image file to be deleted is selected by the user, the controller 210 notifies the server on the Internet to delete the selected moving image file via the communication unit 270 (S306). Upon receiving the moving image file deletion notification from the controller 210, the server on the Internet deletes the selected moving image file (S306).
[2. Other Embodiments]
As described above, the first embodiment has been described as the embodiment of the present invention. However, the present invention is not limited to these. Therefore, other embodiments of the present invention will be described collectively in this section.

  In the first embodiment of the present invention, how long can a currently generated moving image file continue to be generated under the limitations on the capacity and time of a moving image file that can be uploaded to an upload site? Is configured to be displayed on the liquid crystal monitor 260. However, it is not necessarily limited to such a configuration. For example, when additional shooting is performed on a moving image file that has already been generated, additional shooting is performed based on the capacity and playback time of the moving image file that has already been generated and the capacity and time limit of the moving image file that can be uploaded to the upload site. It may be configured to display on the liquid crystal monitor 260 how long it is possible. Thus, even when additional shooting is performed on a moving image file that has already been generated, it is possible to notify the user of the remaining shooting time for generating a moving image file that can be uploaded to the upload site.

  In Embodiment 1 of the present invention, the moving image file is an MPEG file. However, such a configuration is not necessarily required. For example, it may be an AVI file or the like, and may be any of MPEG-2, MPEG-4, MPEG-4 / AVC, etc. among MPEG files. Thus, any moving image file may be used.

  In the first embodiment of the present invention, when a moving image file is automatically divided, a file name such as “what number / number of related files” is used. However, such a file name is not necessarily required. The file name of the first file is not particularly changed, and the file name of the second file may be a file name such as “first file name 2”. In short, any configuration that can identify the number of related files may be used.

  The optical system and drive system of the imaging apparatus to which the present invention is applied are not limited to those shown in FIG. For example, although FIG. 1 illustrates an optical system having a three-group configuration, a lens configuration having another group configuration may be used. Further, neither the OIS 140 nor the OIS actuator 150 is an essential component. In addition, each lens may be composed of one lens or a lens group composed of a plurality of lenses.

  In the first embodiment, the CCD image sensor 180 is exemplified as the imaging unit, but the present invention is not limited to this. For example, it may be composed of a CMOS image sensor or an NMOS image sensor.

  The image processing unit 190 and the controller 210 may be configured by one semiconductor chip or may be configured by separate semiconductor chips.

  The present invention can be applied to a digital still camera, a movie, and the like.

Block diagram of the digital camera 100 Flowchart for explaining recording operation in digital camera 100 Schematic diagram for explaining display during recording of liquid crystal monitor 260 Flowchart for explaining playback operation in digital camera 100 Schematic diagram for explaining display during reproduction of liquid crystal monitor 260 Flowchart for explaining upload operation in digital camera 100 Schematic diagram for explaining display during upload of liquid crystal monitor 260 Flowchart when checking uploaded video file in digital camera 100 Schematic diagram for explaining the display when confirming the uploaded moving image file on the liquid crystal monitor 260

Explanation of symbols

100 Digital Camera 110 Zoom Lens 120 Detector 130 Zoom Motor 140 OIS
150 OIS Actuator 160 Detector 170 Focus Lens 180 CCD Image Sensor 190 Image Processing Unit 200 Buffer 210 Controller 220 Gyro Sensor 230 Card Slot 240 Memory Card 250 Operation Member 260 LCD Monitor 270 Communication Unit 280 Internal Memory

Claims (7)

Imaging means capable of generating image data by capturing a subject image;
First storage means capable of storing a moving image file generated by sequentially storing image data generated by the imaging means;
A second storage means for storing time information relating to the longest recording time for one moving image file;
First detection means for detecting an elapsed time from the start of generation of image data by the imaging means;
First calculation means for calculating the remaining time that can be imaged by the imaging means based on the time information stored in the second storage means and the detection result by the first detection means;
Display means for displaying a calculation result by the first calculation means;
An imaging apparatus comprising: Third storage means for storing capacity information relating to a maximum storage capacity for one moving image file;
Second detection means for detecting a capacity of a moving image file sequentially generated in the first storage means;
A second calculation unit that calculates a remaining time that can be imaged by the imaging unit based on at least the capacity information stored in the third storage unit and the detection result by the second detection unit; ,
Comparing means for comparing the calculation result by the first calculation means and the calculation result by the second calculation means, further comprising:
The display means displays the calculation result by the first calculation means or the calculation result by the second calculation means according to the comparison result by the comparison means,
The imaging device according to claim 1. Imaging means capable of generating image data by capturing a subject image;
First storage means capable of storing a moving image file generated by sequentially storing image data generated by the imaging means;
A second storage means for storing time information relating to the longest recording time for one moving image file;
Detecting means for detecting an elapsed time from the start of generation of image data by the imaging means;
Stop means for stopping generation of image data by the imaging means before the elapsed time indicated by the detection result by the detection means exceeds the longest recording time indicated by the time information stored in the second storage means;
An imaging apparatus comprising: Imaging means capable of generating image data by capturing a subject image;
First storage means capable of storing a moving image file generated by sequentially storing image data generated by the imaging means;
A second storage means for storing time information relating to the longest recording time for one moving image file;
Detecting means for detecting an elapsed time from the start of generation of image data by the imaging means;
A moving image generated based on the image data generated by the imaging unit before the elapsed time indicated by the detection result by the detecting unit exceeds the longest recording time indicated by the time information stored in the second storage unit Switching means for switching the file from the currently generated moving image file to a new moving image file;
An imaging apparatus comprising: The first storage means is
A plurality of moving image files generated by switching the moving image file to be generated by the switching unit are stored in association with each other.
The imaging device according to claim 4. Storage means capable of storing a plurality of moving image files generated by continuously capturing moving images in association with each other;
Reproduction means for reading out and reproducing the moving image file stored in the storage means;
Control means for controlling the reproduction means so as to continuously reproduce a plurality of associated video files stored in the storage means;
An imaging apparatus comprising: Storage means capable of storing a plurality of moving image files generated by continuously capturing moving images in association with each other;
Communication means capable of uploading a moving image file stored in the storage means to a server on the Internet;
Control means for controlling the communication means to collectively upload a plurality of associated video files stored in the storage means;
An imaging apparatus comprising:

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