JP2010187112A - Image reproducing device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide an image reproducing device for properly switching and reproducing a plurality of moving images of different magnification rates. <P>SOLUTION: The image reproduction apparatus 1 includes: a selection means 20 for selecting one moving image data from a plurality of moving image data of different magnification rates; a signal generation means 20 for generating moving image reproducing signals based on the moving image data selected in the selection means 20; and a control means 20 for controlling the selection means 20 so as to select the moving image data corresponding to instructions. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to an image reproduction device.

  Select and record any one of the image information captured by the camera and the image information obtained by electronic zoom enlargement of a part of the image information, or select one of the image information. A video camera that displays images is known (see Patent Document 1).

JP 2000-270252 A

  In the prior art, when playing back an image based on recorded image information, if you want to view the entire image while playing back image information that has been electronically zoomed in, you must perform an electronic zoom reduction operation. When it is desired to view a part of the image during reproduction of the image information that has not been reproduced, the electronic zoom enlargement operation must be performed, and there is a problem that the operation of changing the electronic zoom is troublesome.

  An image reproduction apparatus according to the present invention includes a selection unit that selects one moving image data from a plurality of moving image data having different magnification rates, and a signal generation that generates a moving image reproduction signal based on the moving image data selected by the selection unit. Means and control means for controlling the selection means so as to select moving image data according to the instruction.

  In the image reproduction apparatus according to the present invention, a plurality of moving images having different magnification rates can be appropriately switched and reproduced.

It is a block diagram explaining the structural example of the electronic camera by one embodiment of this invention. It is a rear view of an electronic camera. It is a figure which illustrates the display screen of a live view image. It is a figure which illustrates the image which an image sensor acquires. It is a figure explaining the timing which acquires a 1st image and a 2nd image alternately. It is a figure which illustrates the display screen during 2 image recording. It is a figure which illustrates the image which an image sensor acquires. It is a figure explaining the timing which acquires a 1st image-a 4th image in order. It is a figure which illustrates the display screen during 4 image recording. It is a figure which shows the example of a display of a 2nd image. It is a figure which shows the example of a display of a 1st image-a 4th image. It is a figure explaining the file structure recorded on a storage medium. It is a figure which illustrates the time table based on time table information. It is a figure which illustrates the time table based on slow reproduction information. It is a figure explaining the reproduction | regeneration image signal. It is a figure which illustrates the list display of a thumbnail image. It is a figure which illustrates the display screen in recording in the case of the modification 10.

  Hereinafter, embodiments for carrying out the present invention will be described with reference to the drawings. FIG. 1 is a block diagram illustrating a configuration example of an electronic camera 1 according to an embodiment of the present invention. In FIG. 1, an electronic camera 1 includes a photographing optical system 11, an image sensor 12, an AFE (Analog front end) circuit 13, an image processing circuit 14, a timing generator (TG) 15, an LCD monitor 17, and a buffer. A memory 18, a flash memory 19, a CPU 20, a memory card interface (I / F) 21, and an operation member 22 are provided.

  The CPU 20, the buffer memory 18, the flash memory 19, the memory card interface 21, the image processing circuit 14, and the LCD monitor 17 are connected via the bus 16.

  The photographing optical system 11 includes a plurality of lens groups including a zoom lens and a focusing lens, and forms a subject image on the light receiving surface of the image sensor 12. In order to simplify FIG. 1, the photographing optical system 11 is shown as a single lens.

  The TG 15 generates a predetermined timing signal in response to an instruction sent from the CPU 20 and supplies the timing signal to the image sensor 12, the AFE circuit 13, and the image processing circuit 14. The image pickup device 12 and the like are driven and controlled by the timing signal, thereby controlling the image pickup timing by the image pickup device 12 and the readout timing of the analog image signal from the image pickup device 12.

  The imaging element 12 is configured by a CCD image sensor, a CMOS image sensor, or the like in which light receiving elements are two-dimensionally arranged on the light receiving surface. The image sensor 12 photoelectrically converts a subject image by a light beam that has passed through the photographing optical system 11 to generate an analog image signal. The analog image signal is input to the AFE circuit 13.

  The AFE circuit 13 performs analog processing such as correlated double sampling and gain adjustment on the analog image signal, and converts the image signal after the analog processing into digital image data. The digital image data is input to the image processing circuit 14. The image processing circuit 14 performs various types of image processing (pixel interpolation processing, gradation conversion processing, contour enhancement processing, white balance adjustment processing, image compression processing, image expansion processing, etc.) on the digital image data.

  The LCD monitor 17 is composed of a liquid crystal panel, and displays an image, an operation menu screen, and the like according to an instruction from the CPU 20. A touch operation member (not shown) is stacked on the display surface of the LCD monitor 17. The touch operation member generates a signal indicating the touch position on the operation member (that is, on the display screen of the liquid crystal monitor 17) when the user performs a touch operation, and sends the signal to the CPU 20.

  The buffer memory 18 temporarily stores digital image data before image processing by the image processing circuit 14, during image processing, and after image processing. Also, when performing two-image recording or four-image recording, which will be described later, sufficient storage capacity is secured to temporarily store each image data (first image data, second image data...). The flash memory 19 stores a program to be executed by the CPU 20.

  The CPU 20 controls an operation performed by the electronic camera 1 by executing a program stored in the flash memory 19. The CPU 20 also performs AF (autofocus) operation control and automatic exposure (AE) calculation. The AF operation uses, for example, a contrast detection method for obtaining a focus position of a focusing lens (not shown) based on contrast information of a through image. The live view image refers to a monitor image that is repeatedly acquired by the image sensor 12 at a predetermined time interval (for example, 30 frames / second = 30 fps) before a shooting instruction. The live view image is also called a through image.

  The memory card interface 21 has a connector (not shown), and a storage medium 51 such as a memory card is connected to the connector. The memory card interface 21 writes data to the connected storage medium 51 and reads data from the storage medium 51. The storage medium 51 is configured by a memory card incorporating a semiconductor memory, a hard disk drive, or the like.

  The operation member 22 includes a release button 22a, a recording switch 22i, a zoom switch 22b 22c, a cross switch 22g, a menu switch 22e, and the like which will be described later. The operation member 22 sends an operation signal corresponding to each operation, such as a function operation or a menu selection operation, to the CPU 20.

  FIG. 2 is a rear view of the electronic camera 1. On the back of the electronic camera 1, there are an LCD monitor 17, a zoom switch 22b (T), a zoom switch 22c (W), a function (F) switch 22d, a recording switch 22i, a menu switch 22e, and a deletion switch 22f. And a cross switch 22g and an OK switch 22h.

  The CPU 20 of the electronic camera 1 displays the above-described live view image on the LCD monitor 17 in the shooting mode. FIG. 3 is a diagram illustrating a display screen of the LCD monitor 17 that displays a live view image. The live view image is displayed based on the data of the pixels read out by thinning out of all the pixels of the image sensor 12. Therefore, when the number of pixels displayed on the LCD monitor 17 is smaller than the number of pixels of the image sensor 12, the thinning rate at the time of data reading is set so as to reduce the definition of the live view image. The thinning may be a simple thinning method or a pixel addition method. When the image sensor 12 performs imaging at 30 fps, a live view image can be displayed at 30 fps.

  When an operation signal is input from the release button 22a while a live view image is displayed, the CPU 20 starts a still image shooting process and acquires a still image. In still image shooting, a recorded image is usually generated based on pixel data read from all pixels of the image sensor 12. Note that, depending on the setting, a recorded image is generated based on pixel data read out at a predetermined thinning rate among all the pixels included in the image sensor 12, or read out from a predetermined area among the image areas included in the image sensor 12. It is also possible to generate a recorded image based on the pixel data.

  Further, when an operation signal is input from the recording switch 22i while the live view image is displayed, the CPU 20 starts moving image shooting processing and acquires a moving image. In moving image shooting, a recorded image is generated based on pixel data read out at a predetermined decimation rate among all the pixels of the image sensor 12, and pixels read out from a predetermined area of the image pickup area of the image sensor 12. A recorded image is generated based on the data. That is, a plurality of moving images are acquired during moving image shooting. An area for reading pixel data from the image sensor 12 is configured to be changeable by a setting operation described later.

  Since this embodiment has a feature in the operation when acquiring a moving image, the following description will focus on moving image acquisition (recording). In this description, two-image recording for acquiring two images and four-image recording for acquiring four images will be described as examples.

-Video recording-
<In case of 2 image recording>
When an operation signal is input from a touch operation member (not shown) on the LCD monitor 17 while displaying a live view image, the CPU 20 blinks a display frame 31 indicating the touch position on the live view image. (Superimposed display) (FIG. 3). In this example, the aspect ratio of the display frame 31 matches the aspect ratio of the display area of the LCD monitor 17. The display frame 31 represents the shooting range of the second image at the time of moving image acquisition (recording). Details of the second image will be described later.

  When an operation signal is input from a touch operation member (not shown) on the LCD monitor 17 while the display frame 31 is blinking, the CPU 20 moves the center position of the display frame 31 to the touch position. When an operation signal is input from the zoom switch 22c (W), the CPU 20 increases the size of the blinking display frame 31 according to the number of operations, and the operation signal is input from the zoom switch 22b (T). In such a case, the size of the blinking display frame 31 is reduced according to the number of operations. When an operation signal is input from the OK switch 22h, the CPU 20 changes the display frame 31 at that time from blinking display to lighting display.

  Note that the CPU 20 when the display position of the display frame 31 being lit is touched, changes the display frame 31 from the lit display to the blinking display. The CPU 20 deletes the blinking display frame 31 when an operation signal is input from the deletion switch 22f.

  When an operation signal is input from the recording switch 22i, the CPU 20 starts a moving image acquisition (recording) process. The CPU 20 acquires the full screen image and the enlarged image in a time division manner. The full screen image (referred to as the first image) is an image corresponding to the entire imaging area of the image sensor 12, and the enlarged image (referred to as the second image) is displayed on the display frame 31 in the imaging area of the image sensor 12. It is an image corresponding to a corresponding area.

  The CPU 20 changes the extraction range (thinning rate) of the pixel data read from the image sensor 12 according to the size of the display frame 31 when acquiring the second image. The acquired pixel data of the second image is subjected to enlargement processing so as to be equal to the resolution of the first image.

  FIG. 4 is a diagram illustrating an image acquired by the image sensor 12. From the left, frame images are acquired in the order of the Nth frame, the (N + 1) th frame, the (N + 2) th frame, the (N + 3) th frame, the (N + 4) th frame, the (N + 5) th frame, and so on. In the two-image recording, full-screen images (first images) and enlarged images (second images) are obtained alternately.

  FIG. 5 is a time chart for explaining the timing for alternately acquiring the first image and the second image. The CPU 20 captures the first image in the Nth frame (setting the imaging signal readout area, charge accumulation, readout of the imaging signal) and displays it on the LCD monitor 17 in 1/60 seconds, and the (N + 1) th frame is the next frame. ) In the frame, the display in the previous frame is continued, and in the next frame (N + 2), the first image is captured and displayed in 1/60 seconds. Thus, the acquired first image is displayed on the display screen of the LCD monitor 17 while recording the first image every 1/30 seconds, that is, at a frame rate of 30 fps.

  In FIG. 5, the CPU 20 captures the second image (sets the imaging signal readout area, charges accumulation, and readouts the imaging signal) within 1/60 seconds in the (N + 1) th frame, and makes 1 frame (N + 2) per frame. The second image is captured within 1/60 seconds in the next frame (N + 3). Accordingly, the second image is recorded at a frame rate of 30 fps while the first image is recorded at a frame rate of 30 fps.

  FIG. 6 is a diagram illustrating a display screen of the LCD monitor 17 during two-image recording. The CPU 20 displays a frame 62 indicating the imaging range of the first image (in this example, a thick solid line), indicating that the first image is being recorded. In addition, the CPU 20 displays the frame 61 indicating the imaging range of the second image in a mode different from the frame 62 (in this example, a thick broken line) to indicate that the second image is recorded.

  The two-image recording described above is performed when the display frame 31 is set (turned on) and when the display frame 31 is not set. When the display frame 31 is not set, the second image is not recorded, and the second image is handled as having recorded null data.

<For four-image recording>
When an operation signal is further input from the touch operation member (not shown) on the LCD monitor 17 while the display frame 31 is lit on the live view image, the CPU 20 displays a display frame (not shown) indicating the touch position. However, the display frame 32 will be displayed on the live view image in a blinking manner (superimposed display). In this example, the aspect ratio of the display frame 32 is matched with the aspect ratio of the display area of the LCD monitor 17 as in the case of the display frame 31. The display frame 32 represents the shooting range of the third image at the time of moving image acquisition (recording). Details of the third image will be described later.

  When an operation signal is input from a touch operation member (not shown) on the LCD monitor 17 while the display frame 32 is blinking, the CPU 20 moves the center position of the display frame 32 to the touch position. When an operation signal is input from the zoom switch 22c (W), the CPU 20 increases the size of the blinking display frame 32 according to the number of operations, and the operation signal is input from the zoom switch 22b (T). In such a case, the size of the blinking display frame 32 is reduced according to the number of operations. When an operation signal is input from the OK switch 22h, the CPU 20 changes the display frame 32 at that time from blinking display to lighting display.

  The CPU 20 displays the touch position when an operation signal is input from a touch operation member (not shown) on the LCD monitor 17 while the display frame 31 and the display frame 32 are lit on the live view image. A frame (not shown, but described as a display frame 33) is superimposed on the live view image and blinked (superimposed). The aspect ratio of the display frame 33 is matched with the aspect ratio of the display area of the LCD monitor 17 as in the case of the display frames 31 and 32. The display frame 33 represents the shooting range of the fourth image at the time of moving image acquisition (recording). Details of the fourth image will be described later.

  When an operation signal is input from a touch operation member (not shown) on the LCD monitor 17 while the display frame 33 is blinking, the CPU 20 moves the center position of the display frame 33 to the touch position. Further, when an operation signal is input from the zoom switch 22c (W), the CPU 20 increases the size of the blinking display frame 33 according to the number of operations, and the operation signal is input from the zoom switch 22b (T). In such a case, the size of the blinking display frame 33 is reduced according to the number of operations. When an operation signal is input from the OK switch 22h, the CPU 20 changes the display frame 33 at that time from blinking display to lighting display.

  Note that the CPU 20 when the display position of any of the display frames 31, 32, and 33 that are lit is touched, changes the corresponding display frame from the lit display to the blinking display. When an operation signal is input from the deletion switch 22f, the CPU 20 deletes the blinking display frame.

  When an operation signal is input from the recording switch 22i, the CPU 20 starts a moving image acquisition (recording) process. The CPU 20 acquires a full screen image and three enlarged images in a time division manner. The full screen image (referred to as the first image) is an image corresponding to the entire imaging region of the imaging element 12. The three enlarged images are an image corresponding to the area corresponding to the display frame 31 (referred to as a second image) in the image pickup area of the image sensor 12 and an image corresponding to the area corresponding to the display frame 32 (the third image and the third image). And an image corresponding to an area corresponding to the display frame 33 (referred to as a fourth image).

  As in the case of two-image recording, the CPU 20 increases the thinning rate when reading out pixel data from the image sensor 12 as the size of the display frames 31, 32, 33 increases, and the size of the display frames 31, 32, 33 increases. The smaller the value is, the lower the thinning rate when reading out the pixel data from the image sensor 12.

  FIG. 7 is a diagram illustrating an image acquired by the image sensor 12. From left to right, frame images are acquired in the order of Mth frame, (M + 1) th frame, (M + 2) th frame, (M + 3) th frame, (M + 4) th frame, (M + 5) th frame,. In the four-image recording, a first image that is a full-screen image, a second image that is an enlarged image, a third image, and a fourth image are acquired in this order.

  FIG. 8 is a time chart for explaining the timing of acquiring the first image to the fourth image in order. The CPU 20 captures the first image in the Mth frame (setting of the imaging signal readout area, charge accumulation, readout of the imaging signal) and display on the LCD monitor 17 in 1/120 seconds, and the next three frames (M + 1) In (M + 3), the display is continued, and in the next frame (not shown, (M + 4)), the first image is captured and displayed in 1/120 seconds. Thus, the acquired first image is displayed on the display screen of the LCD monitor 17 while recording the first image every 1/30 seconds, that is, at a frame rate of 30 fps.

  In FIG. 8, the CPU 20 performs imaging of the second image (setting of the imaging signal readout area, charge accumulation, readout of the imaging signal) within 1/120 seconds in the (M + 1) th frame, and the next three frames (M + 2). In (M + 4), the second image is captured within 1/120 second in the next frame (not shown, (M + 5)). Accordingly, the second image is recorded at a frame rate of 30 fps while the first image is recorded at a frame rate of 30 fps.

  Further, the CPU 20 causes the third image to be captured (setting of the imaging signal readout area, charge accumulation, imaging signal readout) within 1/120 seconds in the (M + 2) th frame, and the next three frames (M + 3) to ( After M + 5), the third image is captured within 1/120 second in the next frame (not shown, (M + 6)). Accordingly, the third image is recorded at the frame rate of 30 fps while the first image is recorded at the frame rate of 30 fps.

  Furthermore, the CPU 20 performs the imaging of the fourth image (setting of the imaging signal readout area, charge accumulation, readout of the imaging signal) within 1/120 second in the (M + 3) frame, and the next 3 frames (M + 4) to After (M + 6), the fourth image is captured within 1/120 second in the next frame (not shown, (M + 7)). As a result, the fourth image is recorded at a frame rate of 30 fps while the first image is recorded at a frame rate of 30 fps.

  FIG. 9 is a diagram illustrating a display screen of the LCD monitor 17 during recording of four images. The CPU 20 displays a frame 94 indicating the imaging range of the first image (in this example, a thick solid line), indicating that the first image is being recorded. The CPU 20 displays the frame 91 indicating the imaging range of the second image in a mode different from the frame 94 (in this example, a thick broken line) to indicate that the second image is recorded. Further, the CPU 20 displays the frame 92 indicating the imaging range of the third image and the frame 93 indicating the imaging range of the fourth image in different modes (for example, different colors with thick broken lines), and the third image and the fourth image are displayed. Indicates that an image is being recorded.

  The four-image recording described above is performed when the display frames 91 to 93 are set (lighted and displayed) and when the display frames 91 to 92 are set. When the display frame 93 is not set, the fourth image is not recorded, and the fourth image is handled as having recorded null data.

<Display switching during recording>
If the display position of any of the display frames 61 and 91 to 93 is touch-operated while the screen illustrated in FIG. 6 or FIG. 9 is being displayed on the LCD monitor 17, the CPU 20 during recording is displayed in the touch-operated display frame. The corresponding image (any one of the second image to the fourth image) is displayed largely on the screen of the LCD monitor 17. FIG. 10 is a diagram illustrating a display example of the second image corresponding to the display frame 61 in FIG. 6 and the display frame 91 in FIG. 9. A frame 101 (thick solid line in this example) indicating the imaging range of the second image indicates that the second image is recorded.

  In order to display the screen illustrated in FIG. 10 on the LCD monitor 17, the CPU 20 captures the first image in the (N) th frame (set of imaging signal readout area, charge accumulation, imaging) instead of the time chart of FIG. 5. Signal reading) is performed within 1/60 seconds, and the first image is captured within 1/60 seconds in the next frame (N + 2) after one frame.

  Further, the CPU 20 causes the second image to be captured (set of the imaging signal readout area, charge accumulation, imaging signal readout) and display on the LCD monitor 17 in 1/60 seconds in the (N + 1) th frame, and is the next frame. The display is continued in the (N + 2) th frame, and the second image is captured and displayed in 1/60 second in the next frame (N + 3). Thus, the acquired second image is displayed on the display screen of the LCD monitor 17 while recording the second image every 1/30 seconds, that is, at a frame rate of 30 fps.

  The CPU 20 displaying the screen illustrated in FIG. 10 on the LCD monitor 17 displays the screen illustrated in FIG. 10 when a double touch operation is performed anywhere in the screen (for example, twice or more within 0.5 seconds). Instead, the original screen (FIG. 6 or 9) is displayed on the LCD monitor 17. When returning from the display screen shown in FIG. 10 to the display screen shown in FIG. 6, the control may be returned to the control shown in the time chart of FIG.

  In addition, when the CPU 20 displaying the screen illustrated in FIG. 9 on the LCD monitor 17 is double-touched (for example, twice or more within 0.5 seconds) in any of the screens, the CPU 20 illustrates in FIG. Instead of the screen, the screen illustrated in FIG. 11 is displayed on the LCD monitor 17. FIG. 11 is a diagram illustrating a case where the first image (upper left), the second image (upper right), the third image (lower left), and the fourth image (lower right) are displayed side by side.

  The CPU 20 that is displaying the screen illustrated in FIG. 11 on the LCD monitor 17 displays a corresponding image on the screen of the LCD monitor 17 when the display position of any of the first image to the fourth image is touched. . That is, the screen illustrated in FIG. 9 is displayed on the LCD monitor 17 when the display position of the first image is touched, and the screen illustrated in FIG. 10 is displayed on the LCD monitor 17 when the display position of the second image is touched. Let Similarly, when the display position of the third image and the display position of the fourth image are touch-operated, the respective images are displayed on the screen of the LCD monitor 17 in a similar manner.

  The image file generated by the CPU 20 and recorded on the storage medium 51 includes a plurality of moving image data in one file. As illustrated in FIG. 12, this file structure includes a tag area 121 for recording image attached information and a data area 122 for recording data.

  The CPU 20 stores shooting conditions, shooting date and time, number of scenes (2 for two-image recording, 4 for four-image recording), and thumbnail image information in the header portion of the entire file. The thumbnail image information is a thumbnail image representing each moving image of the first image to the fourth image (for example, generated from the first one-second data).

  The CPU 20 records scene select information, time table information, and slow playback information as tags. The scene select information is information indicating an image displayed on the screen of the LCD monitor 17 at the time of recording. For example, the first image is displayed from the first 1 second to the 5th 1 second, the third image is displayed from the 6th 1 second to the 10th 1 second, and the 11th 1 second to the nth 1 second. It shows that the second image has been displayed.

  The time table information is information indicating an image to be reproduced and displayed on the screen of the LCD monitor 17 during reproduction. For example, the first image is reproduced and displayed from the first 1 second to the 10th 1 second, the second image is reproduced and displayed from the 11th 1 second to the 15th 1 second, and the nth image from the 16th 1 second. This indicates that the fourth image is reproduced and displayed for up to 1 second. The default value of the time table information is set so that the first image is reproduced and displayed from the first 1 second to the nth 1 second, but can be changed by an editing operation for moving image reproduction to be described later. .

  The slow playback information is information indicating a section to be slow played during playback. For example, it indicates that the playback from the 12th 1 second to the 14th 1 second is performed at a speed 1/3 times the normal speed. The default value of the slow playback information is set so as to be played back and displayed at a normal speed from the first 1 second to the nth 1 second, but can be changed by an editing operation for moving image playback to be described later.

  The CPU 20 amplifies a sound signal collected by a microphone (not shown), converts the amplified signal into digital sound data, and stores a sound file subjected to predetermined file formation.

  The moving image file is recorded as one set data for each predetermined time by being divided every predetermined time (for example, 1 second). According to FIG. 12, the first image, the second image, the third image, and the fourth image for the first one second are treated as one set, and thereafter, the first image, the second image for the next one second, Similarly, the third image and the fourth image are treated as one set, and each is recorded as one set image data.

  The AE (automatic exposure calculation), WB (white balance processing), and AF processing for the above-described two-image recording and four-image recording are usually performed based on the first image data. It should be noted that the AF process may be performed based on image data in which a zoom area exists when a zoom area exists. Further, it may be performed based on enlarged image data instructed by a shooting menu setting operation.

-Video playback-
The moving image reproduction based on the image file (FIG. 12) recorded as described above will be described below. FIG. 13 is a diagram illustrating a time table based on time table information. According to FIG. 13, the first image is reproduced and displayed from the first 1 second to the 10th 1 second, the second image is reproduced and displayed from the 11th 1 second to the 15th 1 second, and the 16th 1 second. Indicates that the fourth image is reproduced and displayed from the first to the nth second. The default value of the time table information is set so that the first image is reproduced and displayed from the first 1 second to the nth 1 second.

  FIG. 14 is a diagram illustrating a time table based on the slow playback information. FIG. 14 shows that the 12th 1 second to the 14th 1 second are reproduced at a speed 1/3 times the normal speed, and the other sections are reproduced and displayed at the normal speed. The default value of the slow reproduction information is set so as to reproduce and display at normal speed from the first 1 second to the nth 1 second.

  The CPU 20 generates a playback image signal using the time table information and the slow playback information. FIG. 15 is a diagram for explaining a reproduction image signal for displaying a moving image on the LCD monitor 17. According to FIG. 15, the first image is reproduced and displayed at the normal speed from the first 1 second to the 10th 1 second on the reproduction time axis, and the second image is reproduced at the normal speed during the 11th first second. The second image is played back at a slow playback speed from 1 second to the 20th 1 second, the second image is played back at the normal speed during the 21st 1 second, and the (n + 6) th 1 second from the 22nd 1 second. The fourth image is reproduced and displayed at a normal speed. Since a moving image corresponding to a recording time of 3 seconds is slowly reproduced (9 seconds) at a speed of 1/3, the reproduction time is 6 seconds longer than the recording time.

  Editing for moving image playback will be described. When the display of a plurality of thumbnails is instructed by a menu operation, the CPU 20 displays thumbnail images side by side on the LCD monitor 17 as illustrated in FIG. Each thumbnail image is generated based on information stored in the header portion of the entire moving image file illustrated in FIG.

  In FIG. 16, the upper left of the screen is a representative image for the first to fourth images generated based on the first 1-second data of the moving image file in which the first to fourth images are recorded. In FIG. 16, the upper right of the screen is a representative image for the first to fourth images generated based on the first one-second data of the moving image file in which the first to fourth images are recorded. .

  In FIG. 16, the lower left of the screen is a representative image for the first image to the second image generated based on the first one-second data of the moving image file in which the first image to the second image are recorded. In the two-image recording, when the second image is handled as null data because the display frame 31 is not set, only the representative image for the first image is displayed as in the lower left screen in FIG.

  In FIG. 16, the lower right corner of the screen is a representative image for the first to fourth images generated based on the first one-second data of the moving image file in which the first to fourth images are recorded. When an operation signal indicating the left / right operation of the cross switch 22g is input, the CPU 20 displays a thumbnail image representing another moving image file that is not displayed on the LCD monitor 17. When the thumbnail image (the display position) being displayed is touched, the CPU 20 starts the reproduction and display operation of the corresponding moving image file. The image displayed on the LCD monitor 17 and the playback speed follow the playback image signal illustrated in FIG.

<Editing for video playback>
The CPU 20 that is reproducing and displaying any one of the first image to the fourth image (for example, the same image as that shown in FIG. 10) performs a double touch operation (for example, 2 within 0.5 seconds). 11 times or more), a screen similar to FIG. 11 is displayed on the LCD monitor 17 instead of the screen being displayed. FIG. 11 is a diagram in which a first image (upper left), a second image (upper right), a third image (lower left), and a fourth image (lower right) are displayed side by side. During reproduction display, bold line display as illustrated in FIGS. 10 and 11 is omitted.

  The CPU 20 that is displaying the same screen as in FIG. 11 on the LCD monitor 17 causes the corresponding image to be displayed largely on the screen of the LCD monitor 17 when the display position of any of the first to fourth images is touched. . That is, the screen similar to FIG. 9 is displayed on the LCD monitor 17 when the display position of the first image is touched, and the screen similar to FIG. 10 is displayed when the display position of the second image is touched. . Similarly, when the display position of the third image and the display position of the fourth image are touch-operated, the respective images are displayed on the screen of the LCD monitor 17 in a similar manner. Note that the bold line display as illustrated in FIGS. 9 and 10 is omitted during the reproduction display.

  Further, when an operation signal is input from the function (F) switch 22d during moving image reproduction, the CPU 20 switches the reproduction speed to 1/3 slow reproduction. When an operation signal is input from the function (F) switch 22d during slow playback, the CPU 20 switches the playback speed from slow playback to normal playback speed.

  When ending the reproduction display of the moving image file, the CPU 20 continues to display the image based on the last one second (that is, the nth one second) and displays the following message in a superimposed manner. For example, when an operation signal is received from the OK switch 22h in a state where the message “Do you want to update the playback information?” Is displayed, the time table information and the slow playback information are respectively the contents at the start of playback display. From the above, the contents set and operated during the reproduction display are updated, and the tag of the reproduced moving image file (FIG. 12) is rewritten.

  By rewriting the tag, the image along the tag content can be reproduced at the reproduction speed along the tag content at the next moving image reproduction. If no operation signal is received from the OK switch 22h while the message “Do you want to update the playback information?” Is displayed, the playback display starts without updating the time table information and the slow playback information. Maintain tag information at the time.

According to the embodiment described above, the following operational effects can be obtained.
(1) The CPU 20 of the electronic camera 1 selects one piece of moving image data from a plurality of pieces of moving image data having different resolutions, generates a moving image reproduction signal based on the selected moving image data, Therefore, a plurality of moving images having different definition levels can be appropriately switched and reproduced without performing a complicated zoom operation.

(2) The CPU 20 reproduces from a plurality of moving image data based on information (time table information) that is information provided in advance and indicates the relationship between the elapsed time from the start of reproduction and the moving image data to be reproduced. Since the moving image data to be selected is controlled, the definition of the moving image to be reproduced can be automatically switched.

(3) The CPU 20 further provides the normal playback speed and the normal playback based on information (slow playback information) that is provided in advance and indicates the elapsed time from the start of playback and the time to be played back at low speed (slow playback information). Since the moving image reproduction signal is generated by switching the reproduction speed lower than the reproduction speed, the reproduction speed can be automatically switched.

(4) Information indicating the relationship between the elapsed time from the start of playback and moving image data to be played back, information indicating the elapsed time from the start of playback and time to be played back at low speed, and the plurality of moving image data are 1 Since it is included in one file, a moving image can be appropriately reproduced and displayed without referring to information outside the file.

(5) Further, the CPU 20 changes the information indicating the relationship between the elapsed time from the start of playback and the moving image data to be played back according to the operation signal, so the time table information can be changed.

(6) Further, the CPU 20 can change the slow reproduction information because the information indicating the elapsed time from the start of the reproduction and the information indicating the time for the low speed reproduction is changed according to the operation signal.

(7) The CPU 20 further generates a still image reproduction signal for displaying the still images side by side based on a plurality of still image data representing each of the plurality of moving image data before starting the reproduction. The moving image data corresponding to the still image indicated by the operation signal generated from the operation member during the generation of the reproduction signal is selected from the plurality of moving image data. Thereby, the user can reproduce and display a moving image corresponding to an arbitrary representative image.

(8) Since a plurality of still image data representing each of the plurality of moving image data and a plurality of moving image data are included in one file, the plurality of moving image data can be referred to without referring to information outside the file. Still image reproduction signals for displaying the still images side by side can be generated based on a plurality of still image data representing each of the above.

(Modification 1)
You may provide a restriction | limiting in the magnitude | size of the display frame which shows the imaging | photography range of a 2nd image-a 4th image. For example, the variable range of the size of the display frame is limited so that the number of pixels of the image sensor 12 in the range corresponding to the display frame is larger than the number of pixels constituting the moving image to be recorded. Thereby, the size when the size of the display frame is reduced is limited when the number of pixels read out from the image sensor 12 without thinning out becomes equal to the number of pixels recorded as a moving image.

(Modification 2)
When the number of pixels of the image sensor 12 in the range corresponding to the display frame is smaller than the number of pixels constituting the moving image to be recorded without the size limitation of the display frame as in the first modification, the image sensor The data to be recorded as a moving image may be generated by interpolating the pixel data read from 12 without being thinned out.

(Modification 3)
The aspect ratio of the display frame (that is, the aspect ratio of the second image to the fourth image) may be different from the aspect ratio of the LCD monitor 17. In this case, data to be recorded as a moving image is generated by adding monotone areas to the top and bottom or the left and right of the second image to the fourth image so as to match the aspect ratio of the LCD monitor 17.

(Modification 4)
Switching between the two-image recording and the four-image recording may be automatically switched according to the setting state of the display frame as described above, or may be switched according to the setting menu operation content.

(Modification 5)
Display frame setting operation (display frame 31 is turned on) indicating the shooting range of the second image in the case of two-image recording, and display indicating the shooting range of the second image to the fourth image in the case of four-image recording Acceptance of the frame setting operation (turning on the display frames 91 to 93) may be performed not only before the start of recording but also during recording after the start of recording.

(Modification 6)
The example in which the position and size of the display frame indicating the shooting range of the second image to the fourth image are set to the position and size corresponding to the set display frame has been described. Instead, the main subject may be detected from the live view image and automatically set. For example, the face area of a person in the live view image is detected, and the position and size of the display frame are automatically determined so as to include this face. Needless to say, the area for reading data from the image sensor 12 is changed according to the position and size of the display frame.

(Modification 7)
The example in which the position of the display frame indicating the imaging range of the second image to the fourth image is fixed at the set operation position has been described, but the main subject may be detected and tracked. For example, the face area of a person in the first image is detected even after the start of recording, the position of the display frame is sequentially determined so as to include this face, and the display frame is automatically moved to the determined position. It goes without saying that the data reading area from the image sensor 12 is changed according to the position of the display frame.

(Modification 8)
In addition to detecting the face area of a person as the main subject, it may be identified whether or not it is a face of a person registered in advance. For example, after the start of recording, the face area of the person in the first image is detected, and when it is determined that this face is the face of a registered person, the position of the display frame is sequentially determined so as to include the face, The display frame is automatically moved to the position. The face information of the registered person is captured in advance and stored in the flash memory 19 as reference data.

(Modification 9)
The method of determining the image to be displayed on the LCD monitor 17 and the playback speed at the time of moving image reproduction based on the reproduced image signal (FIG. 15) based on the time table information and slow reproduction information recorded in the tag of the moving image file has been described. In addition to this, a method of determining based on the scene selection information recorded in the tag of the moving image file may be selectable. By reproducing and displaying based on the scene select information, the same image displayed on the screen of the LCD monitor 17 at the time of recording can be displayed at the time of moving image reproduction.

(Modification 10)
It may be possible to make a setting in which the first image is not recorded (omitted) during two-image recording. In this case, since the CPU 20 does not record the first image (however, imaging is performed and image data necessary for display is read out), the first image is handled as having recorded null data.

  FIG. 17 is a diagram illustrating a display screen of the LCD monitor 17 during recording in the case of the tenth modification. The CPU 20 displays a frame 61 indicating the imaging range of the second image with a thick solid line, indicating that the second image is recorded. Unlike the case of FIG. 6, there is no display of a frame indicating the imaging range of the first image.

(Modification 11)
In the above description, the first image having a low enlargement ratio and the second image enlarged compared to the first image (in the case of four-image recording, the third image and the fourth image) are acquired in a time-sharing manner. I made it. Instead, all pixel data is read out from the entire imaging range of the image sensor 12 without thinning out, and one moving image data based on all the pixel data and information indicating the imaging ranges of the first image and the second image (four images) In the case of recording, information indicating the imaging range of the third image and the fourth image) may be further included in the image file.

  The moving image file of the modified example 11 is recorded as data for each predetermined time divided every predetermined time (for example, 1 second). More specifically, the first image for the first second and the first image for the next one second are recorded as image data every second.

  The tag records scene range information, time table information, and slow playback information. The scene range information is information indicating the scene range (position and size of the scene range in the shooting range) displayed on the screen of the LCD monitor 17 at the time of recording. For example, the first range (corresponding to the first image in the above-described embodiment) is displayed from the first 1 second to the fifth 1 second, and the third range (from the first 1 second to the 10th 1 second is described above). (Corresponding to the third image of the embodiment) and the second range (corresponding to the second image of the embodiment described above) from the 11th 1 second to the nth 1 second.

  The time table information is information indicating a scene range to be reproduced and displayed on the screen of the LCD monitor 17 during reproduction. For example, the first range is reproduced and displayed from the first 1 second to the 10th 1 second, the second range is reproduced and displayed from the 11th 1 second to the 15th 1 second, the 16th 1 second to the nth This indicates that the fourth range is reproduced and displayed for up to 1 second. The default value of the time table information is set so that the first range is reproduced and displayed from the first 1 second to the nth 1 second, but can be changed by an editing operation for moving image reproduction as in the above embodiment. It is configured.

  The slow playback information is information indicating a section to be slow played during playback. For example, it indicates that the playback from the 12th 1 second to the 14th 1 second is performed at a speed 1/3 times the normal speed. The default value of the slow playback information is set so as to be played back and displayed at normal speed from the first 1 second to the nth 1 second, but can be changed by an editing operation for moving image playback as in the above embodiment. It is configured.

  A reproduced image signal for display corresponding to each scene range of the second image to the fourth image is generated by thinning out and reading out data of pixels corresponding to each scene range among all the pixels included in the image sensor 12. As the scene range is narrower, the thinning rate is set lower, and the enlargement rate of the image displayed on the LCD monitor 17 becomes higher. Conversely, the wider the scene range, the higher the thinning rate is set and the lower the magnification rate of the image displayed on the LCD monitor 17.

  The above description is merely an example, and is not limited to the configuration of the above embodiment.

DESCRIPTION OF SYMBOLS 1 ... Electronic camera 12 ... Image pick-up element 14 ... Image processing circuit 15 ... TG
17 ... LCD monitor 18 ... Buffer memory 19 ... Flash memory 20 ... CPU
22 ... Operation member

Claims (8)

Selection means for selecting one moving image data from a plurality of moving image data having different magnification rates;
Signal generating means for generating a moving image reproduction signal based on the moving image data selected by the selecting means;
An image reproducing apparatus comprising: control means for controlling the selection means so as to select moving image data according to an instruction. The image reproduction apparatus according to claim 1,
The control means is provided with moving image data to be reproduced from the plurality of moving image data based on information provided in advance and indicating a relationship between an elapsed time from the start of reproduction and moving image data to be reproduced. An image reproducing apparatus, wherein the selection means is controlled to select. The image reproduction apparatus according to claim 2,
The control means further includes a normal playback speed and a playback speed lower than the normal playback speed based on information provided in advance and indicating information indicating an elapsed time from the start of playback and a time to be played back at a low speed. And the signal generation unit is controlled to generate the moving image reproduction signal. The image reproduction apparatus according to claim 3,
Information indicating the relationship between the elapsed time from the start of playback and moving image data to be played back, information indicating the elapsed time from the start of playback and time to be played back at low speed, and the plurality of moving image data are 1 An image reproduction device characterized in that it is included in one file. The image reproduction apparatus according to claim 4, wherein
An operation member that emits an operation signal;
An image reproducing apparatus, further comprising information changing means for changing information indicating a relationship between an elapsed time from the start of reproduction and moving image data to be reproduced according to the operation signal. The image reproduction apparatus according to claim 4, wherein
An operation member that emits an operation signal;
An image reproducing apparatus, further comprising: an information changing unit that changes information indicating an elapsed time from the start of reproduction and a time for low-speed reproduction according to the operation signal. The image reproduction apparatus according to claim 1,
An operation member that emits an operation signal;
The signal generating means further generates a still image reproduction signal for displaying the still images side by side based on a plurality of still image data representing each of the plurality of moving image data before starting reproduction.
The control unit selects, from the plurality of moving image data, moving image data corresponding to a still image indicated by the operation signal generated from the operation member while the signal generating unit generates the still image reproduction signal. As described above, an image reproducing apparatus that controls the selection means. The image reproduction device according to claim 7,
An image reproducing apparatus, wherein a plurality of still image data representing each of the plurality of moving image data and the plurality of moving image data are included in one file.

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