JP5359456B2 - Image reproducing apparatus and digital camera - Google Patents

Description

  The present invention relates to an image reproducing apparatus and a digital camera that reproduce and display an image such as a still image.

  In a digital photographing apparatus / device such as a digital camera, for example, as disclosed in Patent Document 1, an image recorded on a memory card or the like by photographing is used in order to make the user confirm the performance of the photographed image. What has the function (image reproduction function) to reproduce | regenerate and display on screens, such as a liquid crystal monitor, is common.

JP 2002-223413 A

  By the way, in the prior art, in order to display the next image (frame) on the screen after confirming the image being displayed at the time of image reproduction, the user is provided for frame advance, for example, the right and left of the cross key. It is necessary to operate the buttons and the left and right buttons of the multi selector.

  For this reason, for example, when playing and displaying images taken with a camera at a ski resort in winter, the user needs to remove his / her gloves to perform frame-by-frame operations. It was hanging. Also, it is difficult for some users to operate the buttons themselves, such as a child who handles the camera.

  The present invention is to solve the above-mentioned problems of the prior art. An object of the present invention is to provide an image reproducing apparatus and a digital camera that can easily perform frame advance at the time of image reproduction without trouble.

  An image reproduction apparatus according to a first aspect of the present invention includes detection means and control means. The detecting means detects the posture of the own device. The control unit displays an image on the display unit during image reproduction, and changes the speed and / or order of frame advance of the image displayed on the display unit according to the posture of the own apparatus detected by the detection unit.

  In a second aspect based on the first aspect, the control means automatically executes frame advance when the posture of the own device is a posture for instructing automatic execution of frame advance, and the posture of the own device is automatic frame advance. If it changes from the posture that instructs execution, automatic execution of frame advance is stopped.

  According to a third aspect, in the second aspect, the control means is a posture in which the posture of the own device instructs automatic execution of frame advance, and when a predetermined time has passed with the same posture, The feeding speed is made faster than the speed before the predetermined time has elapsed.

  In a fourth aspect based on the second aspect, the detecting means further detects a change amount of the detected attitude of the own apparatus from a predetermined reference attitude, and the control means determines that the attitude of the own apparatus is frame-advanced. If the posture is to instruct the automatic execution, the frame feed speed is changed in accordance with the amount of change detected by the detecting means.

  According to a fifth aspect of the present invention, in any one of the second to fourth aspects of the present invention, the control means includes a case in which the posture of the own device is a first posture instructing automatic execution of frame advance and a posture of the own device. Is the second posture instructing the automatic execution of the frame advance, and the frame advance is performed with the frame advance order reversed.

  In a sixth aspect based on any one of the second to fifth aspects, the control means performs the frame advance in the order based on the oldest and newest shooting date and time of the image.

  In a seventh aspect based on any one of the second to fifth aspects, the control means performs frame advance in the order based on the size of the file number of the image.

  According to an eighth invention, in any one of the second to seventh inventions, when the control means performs frame advance, an image to be frame-adjusted is detected in a lower direction in the detected posture of the own apparatus. Scroll to display on the display.

  According to a ninth invention, in any one of the second to eighth inventions, when the control means performs frame advance, the display direction of the frame-advanced image indicates that the image at the time of photographing the image. The image is displayed on the display unit so that the direction coincides with the orientation of the photographed device.

  The digital camera according to a tenth aspect of the invention is an image pickup unit that picks up an image of the object scene and acquires an image, and handles the image acquired by the image pickup unit as an image to be displayed on the display unit. An image reproducing device according to claim 1.

  In the present invention, at the time of image reproduction, the posture of the own device is detected, and the frame feed speed and / or order of the image displayed on the display unit (LCD monitor or the like) is changed according to the detected posture.

  Therefore, if the present invention is used, frame advance at the time of image reproduction can be easily performed without trouble.

It is a block diagram of the digital camera of this embodiment. It is a flowchart (1/2) which shows the operation | movement of image reproduction of a digital camera. It is a flowchart (2/2) which shows the operation | movement of image reproduction of a digital camera. It is a figure explaining the attitude | position and attitude | position information of a digital camera. It is a figure which shows the display image of the image on the LCD monitor for every attitude | position. It is a figure which shows the scroll direction in case an attitude | position is "vertical +90 degree | times." It is a figure which shows the display image of the image to the LCD monitor for every attitude | position (in the case with a normal position display function). It is a figure which shows a scroll direction in case an attitude | position is "vertical +90 degree | times" (when a normal position display function is provided). It is a figure which shows a scroll direction (left-right) in case an attitude | position is "vertical +90 degree | times" (when a normal position display function is provided). It is a figure explaining the 2nd method of stopping automatic frame advance.

  Embodiments of the present invention will be described below. The present embodiment is an embodiment of a digital camera.

  FIG. 1 is a block diagram of the digital camera of this embodiment.

  The digital camera includes an imaging lens 11 and a lens driving unit 12, an imaging element 13, an analog signal processing unit 14, a timing generator (TG) 15, a buffer memory 16, an image processing unit 17, and a display control unit 18. A display unit 19, a control unit 20, a sensor unit 21, a compression / decoding unit 22, a recording interface (recording I / F) 23, a recording medium 24, an operation unit 25, and a bus 26. ing. Here, the buffer memory 16, the image processing unit 17, the display control unit 18, the control unit 20, the sensor unit 21, the compression / decoding unit 22, and the recording I / F 23 are connected via a bus 26. Further, the lens driving unit 12, the analog signal processing unit 14, the TG 15, and the operation unit 25 are connected to the control unit 20, respectively.

  The imaging lens 11 includes a plurality of lens groups including a focus lens and a zoom lens. For simplicity, the imaging lens 11 is illustrated as a single lens in FIG.

  The lens driving unit 12 generates a lens driving signal in accordance with an instruction from the control unit 20, performs focus adjustment and zoom adjustment by moving the imaging lens 11 in the optical axis direction, and subjects the light flux that has passed through the imaging lens 11 to the subject. An image is formed on the light receiving surface of the image sensor 13.

  The imaging element 13 is a CCD type or CMOS type imaging element, and is arranged on the image space side of the imaging lens 11. The image sensor 13 photoelectrically converts a subject image formed on the light receiving surface to generate an analog image signal. The output of the image sensor 13 is connected to an analog signal processing unit 14.

  The analog signal processing unit 14 performs analog signal processing such as CDS (correlated double sampling), gain adjustment, and A / D conversion on the analog image signal output from the image sensor 13 in accordance with an instruction from the control unit 20. And the processed image signal is output. The output of the analog signal processing unit 14 is connected to the buffer memory 16.

  Further, the analog signal processing unit 14 sets an adjustment amount for gain adjustment based on an instruction from the control unit 20, and thereby adjusts photographing sensitivity corresponding to ISO sensitivity.

  The TG 15 supplies timing pulses to the image sensor 13 and the analog signal processing unit 14 based on instructions from the control unit 20. The drive timing of the image sensor 13 and the analog signal processing unit 14 is controlled by the timing pulse.

  The buffer memory 16 temporarily stores the image signal output from the analog signal processing unit 14 as image data. The buffer memory 16 temporarily stores image data read from the recording medium 24 by the control unit 20 and image data created in the course of processing by the control unit 20.

  The image processing unit 17 performs image processing such as white balance adjustment, interpolation, contour enhancement, gamma correction, resolution conversion (pixel number conversion) on the image data in the buffer memory 16 in accordance with an instruction from the control unit 20. Note that resolution conversion (pixel number conversion) is a process necessary for displaying image data on the display unit 19. The image processing unit 17 is configured as an ASIC or the like.

  In response to an instruction from the control unit 20, the display control unit 18 performs predetermined signal processing (for example, signal processing for converting into an NTSC composite video signal) on the image data after the image processing, and displays the image data on the display unit 19. Output. With this output, the image data is displayed on the display unit 19. The display unit 19 is an LCD monitor provided on the back surface of the digital camera housing, an electronic viewfinder having an eyepiece unit, or the like.

  The sensor unit 21 includes a sensor for detecting the attitude of the digital camera, such as a gyro sensor. The control unit 20 drives the sensor unit 21 to acquire information (posture information) indicating the posture of the digital camera. This posture information will be described later.

  The compression / decoding unit 22 performs compression processing or decoding processing on the image data in the buffer memory 16 in accordance with an instruction from the control unit 20. The compression process and the decoding process are performed in a JPEG (Joint Photographic Experts Group) format or the like. The compression / decoding unit 22 is configured to be able to perform lossless compression (so-called lossless encoding).

  The recording I / F 23 is formed with a connector for connecting the recording medium 24. The recording I / F 23 accesses the recording medium 24 connected to the connector, and writes and reads various data. At the time of shooting, the control unit 20 records the image data after the compression processing of the buffer memory 16 on the recording medium 24 via the recording I / F 23. However, when the digital camera is set to the uncompressed recording mode, the control unit 20 records the image data after the image processing in the buffer memory 16 on the recording medium 24 without being compressed, without being compressed. . Further, the controller 20 reads the recorded image data from the recording medium 24 via the recording I / F 23 and records it in the buffer memory 16 during image reproduction. The recording medium 24 is a memory card with a built-in semiconductor memory, a small hard disk, or the like.

  The operation unit 25 includes various operation members such as a release button (shutter button), a mode setting button, a menu button, an image reproduction button, and the like, and an operation signal corresponding to the content of the member operation by a user such as a photographer. Send to.

  The control unit 20 comprehensively controls each unit of the digital camera according to the operation content of the operation member by the user. For example, when the digital camera is set to the shooting mode by operating the mode setting button or the like, the control unit 20 drives the lens driving unit 12, the analog signal processing unit 14, and the TG 15 to start acquiring a through image. At this time, the image sensor 13 is driven in the draft mode (decimation readout mode), and the image data of the through image is sequentially recorded in the buffer memory 16 via the analog signal processing unit 14. The control unit 20 performs focus adjustment control (AF) of the imaging lens 11 in cooperation with the lens driving unit 12 based on the image data of the through image. Further, when the control unit 20 drives a photometry unit (not shown) to calculate the evaluation value of the shooting scene based on the image data of the through image in the buffer memory 16, the analog signal processing unit 14 and the like are based on the evaluation value. Adjust the settings of. The control unit 20 drives the image processing unit 17 to perform image processing on the image data of the through image in the buffer memory 16, and then drives the display control unit 18 to display the image data of the through image after image processing. The information is sequentially displayed on the display unit 19 (live view display).

  Next, when the release button is pressed halfway during operation in the shooting mode, the control unit 20 performs focus adjustment control (AF) of the imaging lens 11 in cooperation with the lens driving unit 12 prior to the main shooting.

  When the release button is fully pressed during operation in the shooting mode, the control unit 20 sets shooting conditions (aperture value, shutter speed, presence / absence of flash emission, etc.) based on an evaluation value calculated by a photometry unit (not shown). decide. Then, the control unit 20 drives the lens driving unit 12, the analog signal processing unit 14, and the TG 15 under the determined shooting conditions to perform the main shooting. At this time, the image sensor 13 is driven in a frame mode (all pixel readout mode), and image data of a captured image (captured image) is recorded in the buffer memory 16 via the analog signal processing unit 14. Thereafter, the control unit 20 drives the image processing unit 17 to perform image processing on the image data of the captured image recorded in the buffer memory 16. In addition, the control unit 20 drives the display control unit 18 to cause the display unit 19 to display a captured image after image processing. Then, the control unit 20 drives the compression / decoding unit 22 to perform compression processing on the image data of the captured image after the image processing, and the image data of the captured image after the compression processing via the recording I / F 23. To the recording medium 24. Note that when the digital camera is set to the non-compression recording mode, the control unit 20 does not drive the compression / decoding unit 22 and records the image data of the captured image after image processing without being compressed. Recording is performed on the recording medium 24 via F23.

  When the image playback button is pressed, the control unit 20 reads image data such as a captured image recorded on the recording medium 24 to the buffer memory 16 via the recording I / F 23. Thereafter, the control unit 20 drives the compression / decoding unit 22 as necessary to perform decoding processing on the image data in the buffer memory 16. Further, the control unit 20 drives the image processing unit 17 as necessary to perform processing such as resolution conversion (pixel number conversion) on the image data in the buffer memory 16. Then, the control unit 20 drives the display control unit 18 to display the image data in the buffer memory 16 on the display unit 19.

  Hereinafter, the image reproduction operation of the digital camera will be described with reference to the flowcharts of FIGS. 2 and 3 are flowcharts executed when the user presses the image playback button.

  Step 101 (S101): The control unit 20 drives the sensor unit 21 to acquire information (posture information) indicating the posture of the digital camera.

  Here, the posture information will be described with reference to FIG. In the following description, the surface on which the LCD monitor screen is provided is described as the front of the digital camera. In the present embodiment, when the bottom surface of the digital camera is in the direction of gravity as shown in FIG. 4A, for example, posture information “lateral” is acquired. Also, as shown in FIG. 4B, when the left side surface of the digital camera is in the direction of gravity, for example, posture information of “vertical-90 degrees” is acquired. Also, as shown in FIG. 4C, when the right side surface of the digital camera is in the gravity direction, for example, posture information of “vertical +90 degrees” is acquired. As described above, in the digital camera according to the present embodiment, three types of posture information of “horizontal”, “vertical −90 degrees”, and “vertical +90 degrees” are acquired.

  The control unit 20 determines the attitude of the digital camera based on the acquired attitude information.

  For convenience of explanation, “horizontal”, “vertical −90 degrees”, and “vertical +90 degrees” of the posture information are used as they are as names for representing the posture of the digital camera.

  Step 102: The control unit 20 determines whether the attitude of the digital camera is “vertical” based on the attitude information. If the posture is “vertical”, that is, if the posture of the digital camera is “vertical −90 degrees” or “vertical +90 degrees”, the control unit 20 proceeds to step 103 and performs the image reproduction processing of the present invention. Execute (Yes side). On the other hand, if the posture is not “vertical”, that is, if the posture of the digital camera is “horizontal”, the control unit 20 proceeds to step 118 (FIG. 3) and executes the conventional image reproduction processing (No side). Steps 118 to 121 in FIG. 3 show an example of conventional image reproduction processing.

  Step 103: Based on the posture information, the control unit 20 determines whether or not a predetermined time has passed with the same posture, that is, the predetermined time with the posture of “vertical −90 degrees” or “vertical +90 degrees”. It is determined whether or not it has elapsed. The control unit 20 proceeds to Step 105 when the predetermined time has passed with the posture of “vertical −90 degrees” or “vertical +90 degrees” (Yes side). On the other hand, if there is a change in the attitude of the digital camera within a predetermined time, the control unit 20 proceeds to step 104 (No side).

  Step 104: The control unit 20 uses a value (for example, 3 seconds) set in advance for normal frame advance as frame advance interval information. Then, the control unit 20 proceeds to Step 106.

  Step 105: The control unit 20 uses a preset value (for example, 1 second) for high-speed frame advance as information of the frame advance interval.

  Step 106: The control unit 20 determines whether or not the image display to be performed this time is the first time after the start of this flowchart. If this is the first time, the control unit 20 proceeds to step 107 (Yes side), while if not the first time, the control unit 20 proceeds to step 111 (No side).

  Step 107: The control unit 20 determines whether or not the posture of the digital camera is “vertical +90 degrees” based on the posture information. If the posture is “vertical +90 degrees”, the control unit 20 proceeds to step 108 (Yes side), and otherwise, proceeds to step 109 (No side).

  Step 108: The control unit 20 acquires the image with the oldest shooting date and time from the images recorded on the recording medium 24 via the recording I / F 23. The acquired image data is recorded in the buffer memory 16. The control unit 20 drives the compression / decoding unit 22 as necessary to perform decoding processing on the image data in the buffer memory 16. Further, the control unit 20 drives the image processing unit 17 as necessary to perform processing such as resolution conversion (pixel number conversion) on the image data in the buffer memory 16. Then, the control unit 20 drives the display control unit 18 to display the image data in the buffer memory 16 on the display unit 19. FIG. 5C shows a display image of an image on the display unit 19, for example, an LCD monitor, when the orientation of the digital camera is “vertical +90 degrees”. After displaying the image in this way, the control unit 20 proceeds to step 110.

  Step 109: The control unit 20 acquires the image with the latest shooting date and time from the images recorded on the recording medium 24 via the recording I / F 23. The acquired image data is recorded in the buffer memory 16. The control unit 20 drives the compression / decoding unit 22 as necessary to perform decoding processing on the image data in the buffer memory 16. Further, the control unit 20 drives the image processing unit 17 as necessary to perform processing such as resolution conversion (pixel number conversion) on the image data in the buffer memory 16. Then, the control unit 20 drives the display control unit 18 to display the image data in the buffer memory 16 on the display unit 19. FIG. 5B shows a display image of an image on the display unit 19, for example, an LCD monitor, when the orientation of the digital camera is “vertical-90 degrees”.

  Step 110: The control unit 20 sets the frame advance interval information as the next frame display waiting time.

  Step 111: Based on the posture information, the control unit 20 determines whether or not the posture of the digital camera has changed from the previous execution of the processing of step 111 to the current execution. If the posture has not changed during that time, the control unit 20 proceeds to Step 112 in order to determine the progress of the next frame display waiting time (described above) (No side). On the other hand, if the posture has changed during that time, the control unit 20 forcibly skips the determination process of step 112 and proceeds to step 113 (Yes side).

  Step 112: The control unit 20 determines whether or not the next frame display waiting time set above has elapsed. When the next frame display waiting time has elapsed, the control unit 20 proceeds to Step 113 in order to display the next image (frame) (Yes side). On the other hand, when the next frame display waiting time has not elapsed, the control unit 20 proceeds to Step 117 while continuing to display the current image (No side).

  Step 113: The control unit 20 determines whether the attitude of the digital camera is “vertical +90 degrees” based on the attitude information. If the posture is “vertical +90 degrees”, the control unit 20 proceeds to step 114 (Yes side), but if not (that is, “vertical −90 degrees”), the control unit 20 proceeds to step 115 (No). side).

  Step 114: The control unit 20 acquires an image whose shooting date and time is next to the image currently displayed from the images recorded on the recording medium 24 through the recording I / F 23. The acquired image data is recorded in the buffer memory 16. The control unit 20 drives the compression / decoding unit 22 as necessary to perform decoding processing on the image data in the buffer memory 16. Further, the control unit 20 drives the image processing unit 17 as necessary to perform processing such as resolution conversion (pixel number conversion) on the image data in the buffer memory 16. Then, the control unit 20 drives the display control unit 18 to display the image data in the buffer memory 16 on the display unit 19. After performing the image display in this way, the control unit 20 proceeds to Step 116.

  Step 115: The control unit 20 acquires, through the recording I / F 23, an image that is the next newest image after the image that is currently displayed from the images recorded on the recording medium 24. The acquired image data is recorded in the buffer memory 16. The control unit 20 drives the compression / decoding unit 22 as necessary to perform decoding processing on the image data in the buffer memory 16. Further, the control unit 20 drives the image processing unit 17 as necessary to perform processing such as resolution conversion (pixel number conversion) on the image data in the buffer memory 16. Then, the control unit 20 drives the display control unit 18 to display the image data in the buffer memory 16 on the display unit 19.

  Step 116: The control unit 20 sets the frame advance interval information as the next frame display waiting time.

  Step 117: The control unit 20 determines whether or not an instruction to end image reproduction has been issued. Note that the instruction to end image reproduction is given by the user pressing the image reproduction button of the digital camera again, for example. If the end instruction has not been given, the control unit 20 proceeds to step 101 and repeats the above processing. On the other hand, when an end instruction is given, the control unit 20 stops driving the display control unit 18 to stop image display on the display unit 19 and then ends the processing of this flowchart.

  Step 118: The control unit 20 determines whether or not the image display to be performed this time is the first time after the start of this flowchart. If this time is the first time, the control unit 20 proceeds to step 119 (Yes side), but if not the first time, the control unit 20 proceeds to step 120 (No side).

  Step 119: The control unit 20 acquires the image with the latest shooting date and time from the images recorded on the recording medium 24 via the recording I / F 23. The acquired image data is recorded in the buffer memory 16. The control unit 20 drives the compression / decoding unit 22 as necessary to perform decoding processing on the image data in the buffer memory 16. Further, the control unit 20 drives the image processing unit 17 as necessary to perform processing such as resolution conversion (pixel number conversion) on the image data in the buffer memory 16. Then, the control unit 20 drives the display control unit 18 to display the image data in the buffer memory 16 on the display unit 19. FIG. 5A shows a display image of an image on the display unit 19, for example, an LCD monitor, when the posture of the digital camera is “horizontal”.

  Step 120: The control unit 20 determines whether or not a frame advance instruction has been issued. The frame advance instruction is performed by the user operating, for example, a left / right button or an up / down button (not shown) of a multi-selector of an operation member provided in the digital camera. When an instruction for frame advance is given, the control unit 20 proceeds to step 121 (Yes side). On the other hand, if the frame advance instruction has not been given, the control unit 20 proceeds to step 117 while continuing to display the current image (No side).

  Step 121: If the frame advance instruction is forward frame advance (for example, when the user presses the right side of the left and right buttons of the multi-selector), the control unit 20 sends the recording medium 24 via the recording I / F 23. The image having the shooting date and time that is next to the image that is currently displayed is acquired from the recorded images. However, when the currently displayed image is the image with the latest shooting date and time, the image with the oldest shooting date and time is acquired from the recording medium 24.

  On the other hand, if the frame advance instruction is the reverse frame advance (when the user presses the left side of the left / right button of the multi selector, for example), the control unit 20 sends the recording medium 24 to the recording medium 24 via the recording I / F 23. From the recorded images, a new image is acquired next to the image whose shooting date is currently displayed. However, when the currently displayed image is the image with the oldest shooting date and time, the image with the newest shooting date and time is acquired from the recording medium 24.

  The acquired image data is recorded in the buffer memory 16.

  The control unit 20 drives the compression / decoding unit 22 as necessary to perform decoding processing on the image data in the buffer memory 16.

  Further, the control unit 20 drives the image processing unit 17 as necessary to perform processing such as resolution conversion (pixel number conversion) on the image data in the buffer memory 16.

  Then, the control unit 20 drives the display control unit 18 to display the image data in the buffer memory 16 on the display unit 19.

  After the image display is performed in this way, the control unit 20 proceeds to step 117.

(Supplementary items of this embodiment)
Note that when displaying an image in each of the above steps 108, 109, 114, and 115, the image may be displayed on the display unit 19 while being scrolled. In this case, for example, if the attitude of the digital camera is “vertical +90 degrees”, the image is displayed on the display unit 19 while being smoothly moved (smooth scrolling) in the “down” direction as shown in FIG. Note that the scroll display direction is not limited to “down”, but may be “up”, “right”, “left”, and the like.

  In addition, as disclosed in, for example, Japanese Patent Application Laid-Open No. 2007-201539, a digital camera is a device that captures the image when the image is displayed (for example, a digital camera). When the image display function (normal position display function) is provided so that the direction matches the orientation, the image display may be performed as follows. Specifically, as a normal position display function, for example, when an image taken in a “horizontal” posture is displayed in a “vertical-90 degree” or “vertical +90 degree” posture, the image is displayed on the right side. When the image is displayed in the above steps 108, 109, 114, and 115, the image is displayed as “horizontal”. May be displayed. In this case, for example, as shown in FIG. 7A, an image taken in the “horizontal” posture is shown in FIG. 7B when the posture is “vertical-90 degrees”, and the posture is “ “Vertical +90 degrees” is displayed on the display unit 19 as shown in FIG.

  In addition, when it is possible to change whether the normal position display function is enabled or disabled by mode setting or the like, if the function is enabled, image display is performed as shown in FIGS. 7B and 7C. On the other hand, if it is disabled, an image may be displayed as shown in FIGS.

  Further, when the image is displayed in the “horizontal” orientation with the orientation of “vertical −90 degrees” or “vertical +90 degrees” by the normal position display function, the image may be displayed on the display unit 19 while scrolling. Good. In this case, for example, if the attitude of the digital camera is “vertical +90 degrees”, the image is displayed on the display unit 19 while being smoothly moved (smooth scrolling) in the “down” direction as shown in FIG. The direction of the scroll display is not limited to “down”, but may be “up”, and may be “left” or “right” as shown in FIG.

  Also, in the above, when the attitude of the digital camera is “vertical-90 degrees”, the image shooting date / time of the image is changed from the newest to the oldest, and when the attitude is “vertical +90 degrees”, the shooting date / time of the image is changed. Although it has been described that images are displayed by frame advance from the oldest to the newest, the correspondence between the posture and the frame advancement order may be reversed.

  Further, in the above description, the image is displayed by frame-by-frame order from the oldest to newest shooting date, but the image file name or the file number assigned as the file name (for example, DSC0001, DSC0002, etc.) The images may be displayed by frame-by-frame in order.

  Further, in the processing of the above flowchart, when the digital camera is set to the “vertical” posture, that is, the “vertical −90 degrees” or “vertical +90 degrees” posture, and a predetermined time elapses in the posture, the display is performed. The frame advance speed is changed so that the frame advance of the image is faster than before the predetermined time has elapsed. However, when the sensor included in the sensor unit 21 is capable of linearly detecting a change in the posture of the digital camera in units of several degrees, for example, a “lateral” posture is set as the reference posture, and the digital camera For example, the frame advance rate of the display image may be changed according to the amount of change (such as the amount of tilt) detected when the posture changes from the reference posture in the direction of the “vertical” posture, for example. Good. In this case, for example, the change is made so that the frame advance speed of the display image is increased as the detected change amount is larger. Specifically, the value used as the frame advance interval information described in the processing of steps 104 and 105 is changed so as to be smaller as the change amount is larger.

  Further, in the processing of the above flowchart, when the digital camera is placed in the “vertical −90 degrees” or “vertical +90 degrees” posture, frame advancement of the display image is started, and then the digital camera is placed in the “horizontal” posture. The frame advance is stopped. However, after the frame advance is started, for example, as shown in FIG. 10, the digital camera is “turned down” with the surface opposite to the side on which the LCD monitor (display unit 19) is provided facing down. Even in the case of the state posture, the posture may be detected and frame advance of the display image may be stopped.

  Further, in the processing of the above flowchart, when the posture of the digital camera is “vertical”, that is, “vertical −90 degrees” or “vertical +90 degrees”, the frame advance of the display image is automatically executed, and the digital camera When the posture changes from “vertical” to “horizontal”, the automatic execution is stopped. That is, in the processing of the above flowchart, the posture for instructing the automatic execution of frame advance is “vertical”, that is, “vertical −90 degrees” (first posture instructing the automatic execution of frame advance) or “vertical +90 degrees”. (Second posture instructing automatic execution of frame advance). However, on the other hand, if the digital camera's posture is “horizontal”, frame advance of the displayed image is automatically executed, and if the posture changes from “horizontal” to “vertical”, the automatic execution is performed. You may make it stop. That is, the posture for instructing the automatic execution of frame advance may be “horizontal”.

(Operational effect of this embodiment)
Hereinafter, the effect of this embodiment is demonstrated.

  In the digital camera of this embodiment, when the posture of the digital camera is detected at the time of image reproduction and the posture is a posture for instructing automatic execution of frame advance (for example, “vertical”), frame advance of the display image is performed. Automatically executed. When the posture of the digital camera changes from a posture (for example, “vertical”) for instructing automatic execution of frame advance to another posture (for example, “horizontal”), automatic execution of the frame advance is stopped.

  In the digital camera of this embodiment, the posture of the digital camera is detected at the time of image reproduction, and the posture is not a posture (for example, “vertical”) instructing automatic execution of frame advance (for example, a “horizontal” posture). In the case of), the frame advance of the display image is not automatically executed. In this case, the frame advance of the display image is manually performed by the user operating the left and right buttons of the multi-selector as usual.

In the digital camera of the present embodiment, the posture of the digital camera is detected during image playback, and the posture is a posture (for example, “vertical”) that instructs automatic execution of frame advance. When time elapses, the frame advance speed is changed so that the frame advance of the display image is performed at a speed faster than the speed before the elapse of time .

  In the digital camera according to the present embodiment, when the posture of the digital camera is detected at the time of image reproduction and the posture is a posture (for example, “vertical”) instructing automatic execution of frame advance, the posture (for example, The frame-advance speed of the display image is changed according to the amount of change from the reference orientation (for example, “horizontal”) of “vertical”. For example, as the amount of change increases, the frame advance speed is changed so that the frame advance of the display image is performed faster.

  In the digital camera according to the present embodiment, when an image is reproduced, the posture of the digital camera is detected, and the posture is a first posture (for example, “vertical −90 degrees”) that instructs automatic execution of frame advance. In this case, the frame-by-frame display of images is performed in order from the newest shooting date to the oldest.

  Further, in the digital camera of the present embodiment, when an image is reproduced, the posture of the digital camera is detected, and the posture is a second posture (for example, “vertical +90 degrees”) instructing automatic execution of frame advance. The frame-by-frame display of images is performed in order from the oldest to newest.

  In the digital camera according to the present embodiment, when an image is reproduced, the posture of the digital camera is detected, and the posture is a first posture (for example, “vertical −90 degrees”) that instructs automatic execution of frame advance. In this case, frame advancement of the display image is performed in order from the largest file number assigned as the file name to the smallest file number.

  Further, in the digital camera of the present embodiment, when an image is reproduced, the posture of the digital camera is detected, and the posture is a second posture (for example, “vertical +90 degrees”) instructing automatic execution of frame advance. The frame advance of the display image is performed in order from the smallest file number given as the file name.

  In other words, according to the digital camera of the present embodiment, when the posture of the digital camera is changed during image reproduction, the frame advance speed and / or order of the reproduced image is changed.

  Therefore, according to the digital camera of the present embodiment, frame advance during image reproduction can be easily performed without trouble.

  In the digital camera of the present embodiment, when the posture of the digital camera is detected during image reproduction and the posture is a posture (for example, “vertical”) that instructs automatic execution of frame advance, the frame of the display image is displayed. Feeding is automatically executed. Then, the frame-advanced image is displayed while being scrolled in the downward direction in the posture.

  Therefore, according to the digital camera of the present embodiment, it is possible to give an interesting visual effect such that an image falls downward in an image displayed by automatic frame advance during image reproduction.

  In the digital camera of the present embodiment, when the posture of the digital camera is detected during image reproduction and the posture is a posture (for example, “vertical”) that instructs automatic execution of frame advance, the frame of the display image is displayed. Feeding is automatically executed. Then, the display direction of the image displayed by the automatic frame advance is aligned with the orientation of the device (for example, a digital camera) that captured the image at the time of capturing the image, Display is performed.

  Therefore, according to the digital camera of the present embodiment, it is possible to display an image displayed by automatic frame advance so that there is no sense of incongruity during image reproduction.

(Other)
Note that a part or all of the above-described program related to the operation of the digital camera may be executed by an external processing device such as a computer. In that case, a necessary program is installed in the external processing apparatus via a computer-readable storage medium such as a CD-ROM or a communication network such as the Internet.

  In the above description, the embodiment of the digital camera has been described. However, the image playback apparatus of the present invention is also applicable to other devices capable of playing back and displaying an image, such as a mobile phone and a digital video camera. It is possible.

DESCRIPTION OF SYMBOLS 11 ... Imaging lens, 12 ... Lens drive part, 13 ... Imaging device, 14 ... Analog signal processing part, 15 ... Timing generator (TG), 16 ... Buffer memory, 17 ... Image processing part, 18 ... Display control part, 19 ... Display unit, 20 ... control unit, 21 ... sensor unit, 22 ... compression / decoding unit, 23 ... recording interface (recording I / F), 24 ... recording medium, 25 ... operation unit, 26 ... bus

Claims (8)

Detecting means for detecting the posture of the device;
During playback, the causes to display an image on the display unit, in response to the posture detected by the detection means, and control means for varying the speed and / or order of frame advance of an image to be displayed on the display unit ,
The control means automatically executes the frame advance when the attitude is an attitude instructing the automatic execution of the frame advance, and the frame is changed when the attitude changes from an attitude instructing the automatic execution of the frame advance. When the automatic execution of the feed is stopped, the posture is an orientation for instructing the automatic execution of the frame advance, and when a predetermined time has passed with the same posture, the frame feed speed is set to the predetermined time. An image reproducing apparatus characterized in that it is faster than the speed before the elapse of time . The image reproduction apparatus according to claim 1 ,
The detection means further detects a change amount of the detected posture from a predetermined reference posture,
The control means, when the attitude is an attitude for instructing automatic execution of the frame advance, changes the frame advance speed according to the change amount detected by the detection means. Image playback device. The image reproduction apparatus according to claim 1 or 2 ,
The control means includes the frame advance when the posture is a first posture instructing automatic execution of the frame advance and when the posture is a second posture instructing automatic execution of the frame advance. The image playback apparatus is characterized in that the frame advance is performed in the reverse order. The image reproducing apparatus according to any one of claims 1 to 3,
The image reproduction apparatus characterized in that the control means performs the frame advance in an order based on the newest and oldest date and time of image capturing. The image reproducing apparatus according to any one of claims 1 to 3,
The image reproduction apparatus characterized in that the control means performs the frame advance in an order based on the size of an image file number. In the image reproduction device according to any one of claims 1 to 5 ,
The image reproduction apparatus characterized in that, when performing the frame advance, the control means displays the frame-advanced image on the display unit while scrolling downward in the posture. The image reproducing apparatus according to any one of claims 1 to 6,
The control means, when performing the frame advance, displays the image in the display unit so that a display direction of the frame-advanced image coincides with a posture of an apparatus that captured the image at the time of capturing the image. An image reproducing apparatus characterized by being displayed on the screen. Imaging means for capturing an image of the object scene and acquiring an image;
A digital camera comprising: the image reproduction device according to claim 1 , wherein an image acquired by the imaging unit is handled as an image to be displayed on the display unit.

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