JP4497169B2 - Image information display device - Google Patents

Description

  The present invention relates to an image information display apparatus and method suitable for use in a television receiver that continuously records a received program on a recording medium.

  While enjoying a television broadcast, it is often the case that a telephone call suddenly rings or a visitor misses the broadcast program. If a television broadcast program is missed, it cannot be viewed again, except for a rebroadcast program. Programs that are rebroadcast in a short period of time are rare, and news programs and sports programs are not rebroadcast in most cases. Therefore, in many cases, if a television broadcast program is missed, the program cannot be viewed again.

  In addition, scenes that are desired to be saved while watching broadcast programs such as famous scenes of movies and dramas, interviews with important persons, highlight scenes of sports programs, etc. may suddenly start. In such a case, even if the VTR is set immediately, the scene is often not in time and the scene cannot be recorded.

  Therefore, the present inventor has proposed a television receiver that records a program on a recording medium continuously while watching a broadcast program. In such a television receiver, even if there is a sudden telephone call or visitor, the program can be played back retroactively, so that the program is not missed. In addition, the program can be easily saved, and it is possible to cope with a sudden start of a program to be recorded.

  Further, the inventor of the present application proposes to use a hard disk drive as a recording medium in a television receiver that continuously records a program on a recording medium. Conventionally, a magnetic tape has been widely used as a recording medium for recording a video signal. However, the magnetic tape has a low access speed and is difficult to use as a recording medium used in such a television receiver. Although semiconductor memory can be used, large-capacity semiconductor memory is very expensive, and the stored program disappears when the power is turned off. It is not suitable for cases where In contrast, a hard disk drive has a large capacity and a sufficiently high access speed.

  In such a television receiver in which a program is continuously recorded on a recording medium, when a hard disk drive is used as the recording medium, the hard disk drive has a large capacity, so that the program can be stored for a long time. Furthermore, if a video signal is compressed and recorded using a high-efficiency code, recording for a longer time becomes possible.

  However, if the recording time of the program becomes long, it becomes difficult for the user to search for a desired scene. For example, if a hard disk drive having a capacity of about 1 Gbyte is used and a video signal is recorded by compression with motion JPEG, a recording time of about 60 minutes can be secured. However, it is not easy to search for a desired scene from such a long recording screen and reproduce it.

  In view of this, an image that has been distinguished as an index image is recorded in advance, the index image is read out according to a predetermined procedure, and a search is performed. A scene change is detected, and the detected image at the time of the scene change is searched as an index image. A method, a method of simply dividing a recording time every predetermined time, and using a representative image for each time zone as an index, etc. can be considered.

  However, in the method of recording an image that has been distinguished as an index image in advance, and reading out the index image according to a predetermined procedure and performing a search, it is necessary to record a predetermined index image, and the contents recorded on the reception screen are recorded. Not applicable when searching. In addition, the method of detecting scene changes on the playback screen and using the place where the scene change occurred as an index requires a correlation detection circuit and a motion detection circuit to detect the scene change, increasing the circuit scale and cost. Invite. In addition, the method of simply dividing the recording time every predetermined time and using a representative image for each time period as an index does not necessarily become a meaningful image that can identify the position of the search image. An efficient search is not possible.

  In addition, as described above, when the reception screen is recorded on the hard disk drive, since the video data is compressed and recorded, it is difficult to form an index image by simply dividing the recording time every predetermined time. .

  That is, when the reception screen is recorded in the hard disk drive device in this way, the video data is compressed in order to improve the recording time. As a compression processing method of video data, an MPEG (Motion Picture Experts Group) method and a motion JPEG (Joint Photographics Coding Group) method are known. Although the MPEG method has high compression efficiency, since compression in the time axis direction is performed, it becomes difficult to perform search and variable speed reproduction in field units. Therefore, when recording the reception screen on the hard disk in this way, it is conceivable to compress the video data by the motion JPEG method.

  However, in the motion JPEG method, the screen compression rate varies depending on the picture or the like. For this reason, when video data is compressed by motion JPEG and recorded on the hard disk drive, the correspondence between the address of the hard disk drive and the recording time cannot be obtained. For this reason, it is not possible to simply obtain the recording time from the address of the hard disk drive, and it is difficult to display the recording time by dividing it into predetermined time intervals.

  Accordingly, an object of the present invention is to provide a display device for image information that can easily search for a desired scene or program from a recording screen and that does not increase the circuit scale or increase the cost.

In order to solve the above problems, the present invention provides a recording medium on which moving image information is recorded,
Division time setting means for setting a first division time at a predetermined division interval as an image division time;
Division means for dividing the moving image information recorded on the recording medium at the image division time;
The screen area of the display means is divided into a plurality of small screen areas, and the moving image information divided at the first division time is displayed as an index image corresponding to each of the divided small screen areas. Display control means for controlling to display the elapsed time in each screen;
An offset time setting means for newly setting an offset time when the index image is updated,
When the screen area is divided into multiple small screen areas and all index images are displayed, when one of the multiple small screen areas is selected, the video display small screen area included in the screen area is displayed. , The video corresponding to the index image of the selected small screen area is displayed ,
When updating the displayed index image, the dividing unit divides each moving image information recorded on the recording medium at a second division time obtained by adding an offset time to a predetermined interval, and the display control unit This is a display device for image information in which the newly divided moving image information is displayed as an index image .

In the present invention, the overview retrieval key is pressed, the display screen is divided into a plurality of small screens, each divided screen, course index image of the moving image information recorded on the hard disk drive for each predetermined time index images Each of them is divided and displayed with time . Then, by selecting an index image of moving image information to be reproduced from among the index images divided and displayed on the small screen, a moving image corresponding to the index image selected in the moving image projecting small screen region included in the screen region Is displayed.

In the present invention, when a new offset time is set, the index image of the moving image information divided at different image division times is displayed in the small screen area. A new index image is obtained by increasing the offset time by 1 minute.

Furthermore, in the present invention, when one of the plurality of small screen areas is selected and determined, a moving image corresponding to the determined index image of the small screen area is displayed in the entire area of the screen area.

Therefore, Ru can be easily retrieve a desired playback start position by the index image the elapsed time is displayed in the screen area is displayed. In addition , an index image displayed in one of these small screen areas is selected, and a moving image corresponding to the reproduction start position is displayed in the selected index image in the moving image projecting small screen area included in the screen area. Thus, it is possible to confirm in more detail whether or not the desired reproduction start position is reached .

  Embodiments of the present invention will be described below with reference to the drawings. The present invention is applied to a television receiver in which a hard disk drive is built in the television receiver. In a television receiver equipped with such a hard disk drive, it is possible to play back a missed scene or a scene to be viewed again, or to record and play back a desired program.

  FIG. 1 shows a configuration of a television receiver to which the present invention is applied. In FIG. 1, the reception signal received by the antenna 1 is supplied to the tuner circuit 2. A channel setting signal is supplied from the system controller 10 to the tuner circuit 2. The tuner circuit 10 selects a signal of a desired reception channel based on the channel setting signal, and converts this signal into an intermediate frequency signal.

  The output of the tuner circuit 2 is supplied to the video intermediate frequency circuit 3. In the video intermediate frequency circuit 3, the intermediate frequency signal from the tuner circuit 2 is amplified, and this signal is video-detected. Thereby, for example, an NTSC composite video signal is obtained. This video signal is supplied to one input terminal 5 A of the video source selector switch 5. Further, an audio signal is detected from a beat component of, for example, 4.5 MHz output from the intermediate frequency circuit 3. This output is supplied to the audio demodulation circuit 12.

  A video signal from the external video input terminal 6 is supplied to the other input terminal 5B of the video source changeover switch 5. A select signal is supplied from the system controller 10 to the video source selector switch 5. The video source changeover switch 5 switches between a video signal based on the received television broadcast and a video signal from the external video input terminal 6.

  The output of the video source selector switch 5 is supplied to the video signal processing circuit 7. The video signal processing circuit 7 separates the luminance signal Y and the chroma signal C from the NTSC composite video signal, further demodulates the color difference signals U and V from the chroma signal C, and converts the component video signals Y, U and V into It is formed. The component video signals Y, U, and V are supplied to the terminal 8A of the switch circuit 8 and also supplied to the A / D converter 21 in order to store the video signal in the hard disk drive 30. The output of the D / A converter 35 is supplied to the other input terminal 8B of the switch circuit 8 in order to output a reproduction screen from the hard disk drive 30.

  The switch circuit 8 is for switching between a screen based on a received television broadcast or a video signal from the external video input terminal 6 and a reproduction screen from the hard disk drive 30. The switch circuit 8 is controlled by the system controller 10. When the screen based on the received television broadcast or the video signal from the external video input terminal 6 is projected, the switch circuit 8 is switched to the terminal 8A side. When the reproduction screen from the hard disk drive 30 is displayed, the switch circuit 8 is switched to the terminal 8B side.

  The output of the switch circuit 8 is supplied to the video output circuit 9. The video output circuit 9 drives a matrix circuit for forming the three primary color signals R, G, B from the component video signals Y, U, V from the switch circuit 8 and the three primary color signals R, G, B. And a video amplification circuit for supplying to the color picture tube 11. In the video output circuit 9, the component video signals Y, U, and V from the switch circuit 8 are converted into three primary color signals R, G, and B and supplied to the color picture tube 11.

  An audio signal detected from, for example, a 4.5 MHz beat component of the output of the intermediate frequency circuit 3 is supplied to the audio demodulation circuit 12. The audio demodulation circuit 12 demodulates the audio signal. This audio signal is supplied to the input terminal 13A of the audio source selector switch 13.

  The audio signal from the external audio input terminal 14 is supplied to the other terminal 13B of the audio source changeover switch 13. The audio source changeover switch 13 selects an audio signal based on the received television broadcast and an audio signal from the external audio input terminal 14.

  The output of the audio source changeover switch 13 is supplied to the terminal 15A of the switch circuit 15 and also supplied to the A / D converter 25 in order to store the audio signal in the hard disk drive 30. The other input terminal 15B of the switch circuit 15 is supplied with the output of the D / A converter 38 in order to output the audio signal from the hard disk drive 30.

  The switch circuit 15 switches between a received television broadcast or an audio signal from the external audio input terminal 14 and an audio signal reproduced from the hard disk drive 30. The switch circuit 15 is controlled by the system controller 10. When the received television broadcast or the audio signal from the external audio input terminal 14 is output, the switch circuit 15 is switched to the terminal 15A side. When outputting an audio signal from the hard disk drive 30, the switch circuit 15 is switched to the terminal 15B side.

  The output of the switch circuit 15 is supplied to the audio amplifier 16. The audio signal from the switch circuit 15 is amplified by the audio amplifier 16. This audio signal is supplied to the speaker 17.

  The component video signals Y, U, and V from the video signal processing circuit 7 are supplied to the A / D converter 21 for storage by the hard disk drive 30. The component video signal from the video signal processing circuit 17 is digitized by the A / D converter 21. The output of the A / D converter 21 is supplied to the field memory 22. The output of the field memory 22 is supplied to the image compression circuit 23. The component video signal is compressed by the image compression circuit 23. As an image compression method, for example, motion JPEG is used, and compression is performed so that the code amount of one field becomes equal. The video data compressed by the image compression circuit 23 is sent to the bus 29 via the buffer memory 24.

  The audio signal from the audio source switching circuit 13 is supplied to the A / D converter 25 for storage by the hard disk drive 30. The A / D converter 25 digitizes the audio signal from the audio source switching circuit 13. The output of the A / D converter 25 is supplied to the audio compression circuit 26. The audio compression circuit 26 compresses the audio signal. As an audio compression method, for example, non-linear PCM is used. The audio data compressed by the audio compression circuit 26 is sent to the bus 29 via the buffer amplifier 28.

  Video data from the buffer memory 24 and audio data from the audio compression circuit 26 are combined into fixed-length blocks. Each block is provided with a predetermined header for identifying the block.

  Thus, the blocked video data and audio data are recorded on the hard disk drive 30 via the bus 29 under the control of a recording / reproducing controller 27 comprising a CPU (Central Processing Unit). As a result, video data and audio data are stored in the hard disk drive 30.

  Video data and audio data recorded in the hard disk drive 30 are reproduced under the control of the recording / reproducing controller 27. Reproduction data from the hard disk drive 30 is supplied to the buffer memories 31 and 36 via the bus 29.

  Video data from the buffer memory 31 is supplied to the image decompression circuit 32. Component video data Y, U, and V are formed from video data compressed by, for example, motion JPEG in the image decompression circuit 32. The output of the image expansion circuit 32 is supplied to the D / A converter 35 via the image processing circuit 33 and the field memory 34 for forming a multi-screen. The digital video signal is converted into an analog video signal by the D / A converter 35. The output of the D / A converter 35 is supplied to the terminal 8B of the switch circuit 8.

  The audio data from the buffer memory 36 is supplied to the audio decompression circuit 37. The output of the audio decompression circuit 37 is supplied to the D / A converter 38. The digital audio signal is converted into an analog audio signal by the D / A converter 38. The output of the D / A converter 38 is supplied to the terminal 15B of the switch circuit 15.

  The system controller 10 performs overall control of the television receiver. The system controller 10 and the recording / playback processing controller 27 are connected bidirectionally.

  An input from the remote commander 52 is given to the system controller 10 via the light receiving unit 42. Various operations are set based on the input from the remote commander 52. The output of the system controller 10 is supplied to the display generation circuit 44. The display generation circuit 44 generates display signals indicating various operation setting states. The output of the display generation circuit 44 is supplied to the video output circuit 9, and various operation states are displayed on the screen. A timer 45 is provided for the system controller 10. The timer 45 is used when setting a time for storing a program.

  A television receiver to which the present invention is applied can be operated using a remote commander 52 as shown in FIG.

  The remote commander 52 has various keys for performing basic settings of the television receiver, that is, a power switch 61 for turning on / off the power of the television receiver, and a channel key for performing channel setting. 62, 62, 62,..., Channel up / down keys 63A and 63B, volume up / down keys 64A and 64B, and an input source changeover switch 65 are arranged.

  Further, the remote commander 52 for operating the television receiver to which the present invention is applied includes a program pause key 66, a bookmark as various keys for controlling recording / playback of the hard disk drive 30 of the television receiver. Record key 67, section repeat key 68, cancel key 69, reverse skip playback key 70, reverse fast feed key 71, double speed key 72, forward fast feed key 73, forward skip key 74, overview search key 75, arrow Keys 76A and 76B and an enter key 77 are provided.

  When the program pause key 66 is pressed, the receiving screen is stopped on the spot and displayed as a still image. Meanwhile, the program is recorded on the hard disk drive 30 of the television receiver. When the program pause key 66 is pressed again, the program recorded in the hard disk drive 30 is reproduced from the scene where it is a still image.

  When the bookmark recording key 67 is pressed, the program broadcast at this time can be stored in the hard disk drive 30 of the television receiver.

  Repeat playback is set by the section repeat key 68. When the section repeat key 68 is pressed first, the repeat start position is set. When the section repeat key 68 is pressed next, the repeat end position is set.

  A cancel key 69 is pressed when canceling a set operation or function.

  The reverse skip reproduction key 70, reverse high speed feed key 71, double speed key 72, normal rotation high speed feed key 73, and normal rotation skip key 74 are keys for performing variable speed reproduction.

  An overview search key 75, arrow keys 76A and 76B, and an enter key 77 are used for program search. When the overview search key 75 is pressed, the screen of the television receiver is divided into a central screen and a plurality of surrounding small screens. On the surrounding small screen, a screen for every predetermined time is displayed from the screens recorded on the hard disk drive 30. When a desired screen is selected from a plurality of screens by operating the arrow keys 76A and 76B and the reproduction start position is searched, the enter key 77 is pressed. When the enter key 77 is pressed, playback is started from the selected screen.

  Thus, the remote commander 52 of the television receiver to which the present invention is applied is provided with the overview search key 75. By using the overview search key 75, a desired reproduction start position can be easily searched from information recorded in the hard disk drive 30.

  That is, assuming that the recording time of the hard disk drive 30 is 60 minutes, for example, when the overview search key 75 is pressed, the recording screen of 60 minutes is divided every 5 minutes, for example, and the screen every 5 minutes is displayed as an index image. Is done.

  That is, as shown in FIG. 3, the screen 80 is divided into a plurality of small screens 81A, 81B, 81C,. If the screen of the screen 81A is a screen of “0 minute”, the screens of “5 minutes”, “10 minutes”, “15 minutes”,... Are displayed on the screens 81B, 81C, 81D,. Is done. The time order of the screens 81A, 81B, 81C,... Is clockwise so that the user can easily recognize them. In each screen 81B, 81C, 81D,..., The elapsed time is displayed in text. A moving image of the selected screen is displayed on the small screen 83 in the center.

  A desired attention screen is selected from the screens 81A, 81B, 81C,... Every five minutes. The attention screen is selected by operating the arrow keys 76A and 76B of the remote commander. A screen frame 82 different from the other screen frames is displayed on the selected screen among the screens 81A to 81L. At the same time, a moving image corresponding to the selected screen of interest is displayed on the central screen 80. In this moving image, the elapsed time is displayed in text. Which index image time zone is associated with the currently played time zone can be visually recognized by making the color of the screen frame the same.

  Further, when the overview search key 75 is pressed, each screen is offset by 1 minute as shown in FIG. 3B, and the screens 81A, 81B, 81C, 81D,. A screen of “minute”, “11 minutes”, “16 minutes”,... Is displayed. Further, when the overview search key 75 is pressed, each screen is further offset by one minute, and the screens 81A, 81B, 81C, 81D,... Have “2 minutes”, “7 minutes”, A screen of “12 minutes” and “17 minutes” is displayed.

  The user searches for a time zone in which moving image playback is to be started while viewing these index screens 81A, 81B, 81C,. When a time zone for starting moving image reproduction is searched, the enter key 77 is pressed. When the enter key 77 is pressed, as shown in FIG. 3C, a full screen display is displayed, and reproduction of a moving image is started from the screen at the selected time.

As described above, according to the present invention, the time zone of the index image associated with the currently reproduced time zone can be visually recognized by, for example, making the color of the screen frame the same. In addition, the time sequence of the index screens displayed on the screens 81A, 81B, 81C, 81D,... Is clockwise in consideration of real life. Also, the screen 81A of each index, 81B, 81C, 81D, the ...., elapsed time is indicated character table, the moving image in the center of the screen 83, a detailed reproduction elapsed time is the character displayed . For this reason, the user can easily recognize the time and can easily perform the search.

  As described above, when the overview search key 75 is pressed, the 60-minute recording screen recorded on the hard disk drive 30 is divided, for example, every 5 minutes, and a plurality of screens 81A, 81B, 81C, 81D,.・ Projected in Further, when the overview search key 75 is pressed, each screen is offset by one minute. Therefore, an image serving as an index of the screen that the user wants to search is displayed somewhere on these index screens 81A, 81B, 81C, 81D,..., And a desired reproduction start position is searched from this screen. be able to.

  FIG. 4 is a flowchart showing processing for easily searching for a desired reproduction start position by dividing and displaying the image information stored in the hard disk drive 30 at predetermined time intervals. It is.

  In FIG. 4, it is determined whether or not to create an index screen as shown in FIG. 3 based on whether or not the overview search key 75 is pressed (step ST1). When creating an index screen, a division time T, a division interval t, and an offset time n (n = 0) are set (step ST2).

  The image information recorded in the hard disk drive 30 is divided at a division time T at every division interval t (step ST3). In the present invention, one field of video data is compressed and recorded in a fixed-length field on the hard disk drive 30. For this reason, the address of the hard disk drive 30 and the recording time have a correspondence relationship. Therefore, the image information recorded on the hard disk drive 30 can be divided at predetermined intervals by a simple address calculation.

  When the image information of the hard disk drive 30 is divided every predetermined time, the screen is accessed, index images are created from these divided screens, a search screen is created, and these are displayed (step ST4). As a result, as shown in FIG. 3A, an image for each time is displayed on the multi-screen as an index screen.

  On such a multi-screen, a desired time zone for reproducing a moving image is selected (step ST5), and it is determined whether or not to update the index screen (step ST6). When updating the index screen, the overview search key 75 is further pressed.

  When updating the index screen, an offset time n is set (step ST7), and the process returns to step ST3. As a result, as shown in FIG. 3B, the index screen advanced by the offset time n is displayed in multiple screens.

  If the index screen is not updated in step ST6, it is determined whether or not a screen for starting moving image playback on multiple screens has been determined (step ST8). When the time zone of the screen on which the moving image playback is to be started is set, the enter key 77 is pressed. When the enter key 77 is pressed and the time zone in which video playback is to be started is determined, the video data for that time is read from the hard disk drive 30 and the video is displayed in full screen as shown in FIG. 3C. (Step ST9).

  As described above, in a television receiver to which the present invention is applied, video data is compressed by motion JPEG so that one field of data has a fixed length. For this reason, it is possible to divide the image information recorded in the hard disk drive 30 every predetermined time or to give an offset time by a simple address calculation. These calculations are performed by the system controller 10, for example, and the hard disk drive 30 is accessed based on the calculation results.

  That is, in the television receiver to which the present invention is applied, when video data is compressed and recorded in the hard disk drive 30, the image compression circuit 23 performs compression processing so that the compressed data of one field becomes equal. For example, the input video data is dropped into ¼ field, the compression amount for the video data in the same field is tried multiple times, the code amount is estimated, and the quantization table is set so that the predetermined code amount is obtained. It is done by doing.

  One field of video data having a predetermined code amount is blocked into fixed-length blocks as shown in FIG. As shown in FIG. 5, each block includes video data in which one field is compressed at a fixed length, and audio data, and a predetermined header for identifying the block is provided at the head of each block. In this way, data is recorded in the hard disk drive 30 using the fixed-length block as a file.

As described above, since the image of each field is recorded in the hard disk drive 30 as a fixed-length file, the access address on the hard disk 30 of the index image at a certain division time T is the elapsed time from the recording start time. By converting to the number of fields, it can be obtained by a simple calculation. In other words, the logical address on the hard disk (HDD) is obtained as follows from the start address of the hard disk and the number of fields converted from the elapsed time and the number of block fixed-length sectors.
(Logical address on HDD) =
(HDD start address + (number of fields) x (block fixed sector length)

  Conversion of the number of fields can be easily calculated because it can be defined by how many seconds of one recorded field corresponds to real time. For example, in the case of reproduction by dropping a frame of 1/4 field, the image data for one field corresponds to about 0.25 seconds.

  As described above, in the television receiver to which the present invention is applied, when the overview search key 75 is pressed, the 60-minute recording screen is divided, for example, every 5 minutes, and a plurality of screens 81A every 5 minutes. 81B, 81C, 81D,... Further, when the overview search key 75 is pressed, each screen is offset by one minute. Therefore, an image serving as an index of a screen that the user wants to search is displayed somewhere on these index screens 81A, 81B, 81C, 81D,..., And a desired recording position is searched from this screen. Can do. Since the hard disk drive 30 records video data with one field compressed to a fixed length, a playback screen for each time can be displayed by a simple address calculation.

  In this embodiment, the video data based on the received screen is stored in the hard disk drive. However, the present invention may store other recording media, for example, the video data in the semiconductor memory based on the received screen. The same applies to the case.

1 is a block diagram of an example of a television receiver to which the present invention is applied. It is a top view used for description of the remote commander in the television receiver to which this invention is applied. It is a basic diagram used for description of an index screen. It is a flowchart used for description of an index screen. It is a basic diagram used for description of the data structure in the television receiver to which this invention is applied.

Explanation of symbols

22, 34 ... Field memory 23 ... Image compression circuit 30 ... Hard disk drive 75 ... Overview search key

Claims (4)

A recording medium on which video information is recorded;
Division time setting means for setting a first division time at a predetermined division interval as an image division time;
Dividing means for dividing the moving image information recorded on the recording medium at the image dividing time;
The screen area of the display means is divided into a plurality of small screen areas, and the moving image information divided at the image division time is displayed as an index image corresponding to each of the divided small screen areas, Display control means for controlling to display elapsed time in each screen;
An offset time setting means for newly setting an offset time when updating the index image,
When one of the plurality of small screen areas is selected in a state where the screen area is divided into a plurality of small screen areas and all the index images are displayed, the video image included in the screen area is displayed. A moving image corresponding to the index image of the selected small screen area is displayed in the small screen area .
When updating the displayed index image, the dividing unit divides the moving image information recorded on the recording medium at a second dividing time obtained by adding the offset time to the predetermined interval, and The display device for displaying image information, wherein the display control means displays the newly divided moving image information as an index image . When a new offset time is set by the offset time setting means,
The division time setting means sets a time obtained by adding the new offset time to the first division time as a new image division time,
The dividing means divides each moving image information recorded on the recording medium at a new image dividing time,
2. The image information display device according to claim 1, wherein the display control means displays the newly divided moving image information as an index image. The image information display device according to claim 2, wherein the offset time setting means sets the offset time by incrementing one minute when updating the index image. When one of the multiple small screen areas is selected and determined,
4. The image information display device according to claim 3, wherein the display control means controls to display a moving image corresponding to the index image of the determined small screen area in the entire area of the screen area.

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