JP4993032B2 - Image recording / reproducing apparatus, image recording / reproducing method, and image editing method - Google Patents

Description

  The present invention relates to an image data management method for an electronic moving image camera that digitally encodes and records a moving image.

  In the past, moving images have been widely used, from 8mm movies using optical films to video cameras using magnetic recording video tapes. In particular, video cameras using VHS-C cassettes and 8 mm video cassettes are very popular for home use.

  The recording medium used by these moving image photographing cameras is a tape-like medium, and the photographed images are always continuously arranged on the tape in the photographing order. Therefore, the captured images are always stored in units of tape, and when viewing, it was necessary to view them in order of time from the top of the tape. In order to solve this problem, a method has been developed in which an index signal is input in the middle of the tape, and a necessary place is searched by fast-forwarding to the index position. Among them, <Pocket Digital Movie> DV1 manufactured by Victor records recorded images on a video tape as digital signals, and the playback operation is performed from a personal computer, so that playback images from a certain time on the tape to a certain time are performed. As a unit, a plurality of units are defined, and a method for reproducing images in an arbitrary order other than the order recorded on the tape has been developed and released. However, since this method also uses a medium called tape, it takes time to display the specified image, and in addition, management of the image on the tape is expressed only in relative time counted from the beginning of the tape. Management of recorded images was troublesome. It is possible to save multiple specified units of images as a single program-like continuous image with a title, but these operations must be performed while viewing the captured images after shooting. Was never convenient.

  The present invention uses an electronic camera that records images on a randomly accessible medium such as a hard disk, which generates an image file for each cut, rather than a sequential medium such as a tape. A large number of image files of several seconds to several tens of seconds generated at the time of shooting are automatically grouped according to specific conditions such as shooting time range and location, and the user is aware of the existence of each image file. Instead, the problem can be solved by allowing the image files in the group to be reproduced continuously in units of groups.

  According to the present invention, in a digital video camera, the existence of a large amount of image files created in units of several seconds to several tens of seconds can be easily organized without the user being conscious. Therefore, it is possible to provide an easy-to-use image data management method for an electronic video camera that takes advantage of both the random accessibility of digital images and the continuous image viewing performed by the video tape method.

1 is a block diagram of an electronic video camera according to the present invention. Explanatory drawing which shows the example of the format of the image data image | photographed and encoded with the electronic video camera by this invention. Explanatory drawing which shows the example of the image of the moving image image | photographed with the video camera using the conventional videotape. FIG. 3 is an explanatory diagram showing a recording image on an HDD of image data taken by an electronic video camera according to the present invention. Explanatory drawing which showed the management method of image data using the electronic video camera by this invention. FIG. 3 is an explanatory diagram illustrating a method of the first embodiment in which image data is automatically grouped when image data is grouped. Explanatory drawing which showed the method of the 2nd Example which performs grouping automatically at the time of imaging | photography when grouping image data. Explanatory drawing which showed the method of the 3rd Example which groups automatically at the time of imaging | photography in grouping image data. Explanatory drawing which showed the means for grouping the cut already image | photographed easily. Explanatory drawing which showed the method of selecting the designated cut at random from several imaging | photography cuts, and producing | generating a group. Explanatory drawing which showed the method of selecting a group at the time of reproduction | regeneration of an image. Explanatory drawing which showed the specific method of grouping of the image file by this invention. Explanatory drawing which showed the method of the division | segmentation using the division | segmentation of an image file and a division | segmentation file. Explanatory drawing which showed the method of integrating a several image file and cutting out the partial part in it and grouping it.

Hereinafter, a specific example of an embodiment of an image data management method for an electronic video camera according to the present invention will be described with reference to the drawings.
FIG. 1 is a block diagram of an electronic video camera according to the present invention. In the camera unit 10000, light 10011 from the subject to be photographed is focused on the sensor 10010 through the lens 10012. The virtual image of the subject input to the sensor 10010 is converted into an electrical signal and recorded in the image memory 10030 through the signal processing circuit 10020. In the case of a moving image, these operations are performed at a rate of 60 frames per second, for example, and the image data stored in the image memory is converted into compression-encoded moving image data by a sequential compression / decompression circuit 10040. . The compressed moving image data (hereinafter referred to as image data) is stored in a PCMCIA card type hard disk drive (HDD) 10200 mounted on the camera 10000. At this time, the date and time at the time of shooting and the shooting time of the shot file are read from the timer 10051, and are both stored in the HDD 10200 as attached information of the image data. These operation controls are performed by the camera controller 10050. The image data stored in the HDD 10200 is decoded again by the compression / decompression circuit 10040, returned again to the image memory, and then output to the outside of the camera as a video output signal 10031. The moving image is viewed on a TV or the like. I can do it.
The compressed and encoded image data can be transferred to the PC 10100 by removing the HDD 10200 from the camera and inserting it into the personal computer PC 10100. Further, the image data recorded on the HDD 10200 can be transferred to the PC 10100 via the I / F 10060 without replacing the HDD card. Further, without using the HDD 10200, captured images can be directly transferred to a PC using the I / F 10060 while being sequentially compressed. The PC 10100 includes a bus 10111 having a CPU 10110 as a core, an I / F 10120 that connects the camera 10000, a memory 10130, and a storage medium 10140 that stores image data.
FIG. 2 is an explanatory diagram showing an example of the format of image data shot and encoded by the electronic video camera according to the present invention. In the case of MPEG (Moving Picture Experts Group), for example, the famous moving image compression method described in FIG. 2A, first, an entire screen called I-PICTURE (Intra-PICTURE) 20010 is displayed at the top of the image file 20000. There are still images. Then, difference information 20020 in which the image changes in the time axis direction follows. The length 20030 of the image with these as one unit is a variable length. Basically, by inserting I-PICTURE in an appropriate time unit designated in advance, the error expansion due to the difference is reset. If the difference information makes the efficiency of encoding a moving image worse due to an extreme image change (camera pan or the like), a new I-PICTURE is inserted. FIG. 2B is an explanatory diagram showing the relationship between I-PICTURE = I and difference data P-PICTURE (Pre-PICTURE) = P in more detail. A vertical bar on the left side of each I represents a cut of a minimum unit of moving image data, and full-screen information corresponding to P frames is generated by interpolation using I20040 and P20050. Further, using it and P20051, full-screen information corresponding to the next P frame is generated. Therefore, a moving image file described in this format can be divided using the head position of I-PICTURE as a boundary.
FIG. 3 is an explanatory view showing an example of an image of a moving image taken by a video camera using a conventional video tape. In video cameras using magnetic tape, recorded images are always arranged in chronological order. The photographed images 30000 are arranged along the time axis 30050, and in this figure, each square box represents a one-shot photographed image (photograph button START-STOP unit cut). This videotape shows an image of a climbing trip to Shinshu, and the first five cuts show a set 30010 of images taken on the first day of climbing in climbing to Happo-one. The next 7 cuts show a set 30020 of images taken on the second day of mountain climbing, the next 6 cuts show a set 30030 of images taken when walking around Azumino after descent, and the last 4 cuts are the return trips. A set 30040 of images taken during the driving is shown. These cuts are arranged sequentially on the magnetic tape as shown in the figure. For example, when you want to see the scene of Azumino walk when the tape is completely rewound, fast-forward the tape and walk around Azumino. It is necessary to bring the playback pointer to the top of the set of images. Depending on the video camera, it is possible to put an index at the top of this set. For example, by designating the second index from the top, it is possible to view an image of walking around Azumino. However, in order to view a specific scene that has been taken, it is necessary to perform operations such as fast-forwarding and rewinding the tape, which is cumbersome and time-consuming, so in viewing video images taken using magnetic tape. It is a problem. For this reason, in many cases, it is often used that the captured video images are always viewed continuously from the beginning to the end.
FIG. 4 is an explanatory view showing a recorded image on the HDD of image data taken by the electronic video camera according to the present invention. 40000 is an internal image of the HDD, and each square frame indicates a cluster which is a unit of HDD data read / write access. Here, the image data corresponding to the set 30010 in FIG. 3 is described in five locations in the HDD. Specifically, there are five locations from 40020 to 40024, and new data on the function of the HDD is described in an empty area in the HDD. Therefore, when a set of image data is written continuously, Is not limited. However, due to the random accessibility of the HDD, these data can be accessed for almost any data in almost the same time, and since the time is short, the recorded image data is viewed from the user. Regardless of the order, the specified image data is called up instantly and can be viewed.
FIG. 5 is an explanatory view showing a method of managing image data using the electronic video camera according to the present invention. The image data 50000 shows one cut of the image data captured by each square frame, and the order in which they are arranged in the figure is the same as in FIG. 3, but the substance of each image data is described in the HDD shown in FIG. Therefore, the image data arranged side by side in the figure can be accessed and reproduced at substantially the same time for any of the data. Here, the first four, the next five, the next five, and the last three are grouped into sets of image data. This classification is the same as the description in FIG. 3, but here, since the image data is stored on the HDD, for example, when you want to view the third group Azumino walk image, you need to wait for fast-forwarding of the tape There is no, and you can recall and view the images of the Azumino exploration group in a very short time.
Furthermore, in the present invention, a group called Azumino travel digest video 50050 can be defined in addition to a group of continuous image data. This is feasible when the image data is stored in the HDD shown in FIG. 4, but a specified program is selected from a large number of image data in a random order and grouped to define a single program. Is possible.
FIG. 6 is an explanatory diagram showing the method of the first embodiment in which image data is automatically grouped when image data is grouped. A square frame 60000 is each cut of a photographed image and is photographed in order of time 60040. In this embodiment, paying attention to the difference in the shooting time of each shot that has been shot, there is an algorithm in which cuts shot at intervals within a certain time belong to the same group. For example, if the shooting interval has passed 30 minutes or more, and if it is assumed to belong to another group, the cut 60011 and the cut 60013 belong to the same group, group 1 (60010), because the time 60012 between them is within 30 minutes. However, since the time 60050 between the cut 60013 and the cut 60021 exceeds 30 minutes, when the cut 60021 is photographed, a new group 2 (60020) is created and the cut 60021 belongs to that group. Let Similarly, for a cut having an interval (60060) of 30 minutes or more, a group 3 (60030) is newly established and belongs to that group. By this method, it is possible to automatically perform grouping without the need for the user to classify images to be captured at the time of shooting.
FIG. 7 is an explanatory diagram showing a method of the second embodiment in which image data is automatically grouped when image data is grouped. A square frame 70010 is each cut of the captured image. In the present embodiment, attention is paid to the location where each cut is photographed, and an algorithm is employed in which cuts photographed at substantially the same location belong to the same group using a PHS (Personal Handyphone System) base station number. Here, the PHS is a system that uses a base station installed at an interval of about 300 m and can use a wireless telephone with less power than a normal mobile phone. The PHS can obtain a number unique to the base station at this time. Although the system configuration is not shown, for example, in FIG. 1, the PHS is connected to a portable PC such as a subnote, and the captured image data is transferred as it is to a remote place by PHS, and the PC receives from the PHS. The base station number may be used, or a PHS may be connected to an electronic camera having a PC function. Here, from the base station number of PHS, it is not necessary to express the current position of the electronic camera by an address or coordinates, and it is only necessary to be able to determine that it belongs to a specific base station. In this figure, it is assumed that photographing is performed at three locations where the base station numbers of PHS are A, B, and C. Image data taken in the vicinity of base station number A belongs to group 1 (70020), image data taken in the vicinity of base station number B belongs to group 2 (70030), and base station number C Image data photographed in the vicinity belongs to group 3 (70040). As in FIG. 6, when a new PHS number is recognized, a new group is created, and the image data captured there can be assigned to the group, and the image data linked to the location can be automatically grouped. . The location may be detected by using a position information detection method such as GPS (Global Positioning System), but the method using the PHS base station according to the present invention should also be used in an underground city where GPS cannot be received. Is possible. Here, the present embodiment has been described as an example using PHS. However, if the communication system can know the ID of a base station in the vicinity of the communication device using a wireless communication device, the same use can be made. Is possible.
FIG. 8 is an explanatory diagram showing a method of the third embodiment in which image data is automatically grouped when image data is grouped. In FIG. 8A, a square frame 80000 is each cut of a photographed image and is photographed in order of time 80010. In this embodiment, when shooting, the user defines a new group, and the shot that has been shot has an algorithm that belongs to the group specified in time order. The camera has a switch for designating open-close (OPEN-ClOSE), and a plurality of cuts taken from when the switch is opened to when the switch is closed belong to one group. Specifically, all the cuts shot during the first open-close (80020) belong to group 1 (80021), and all the cuts shot during the next open-close (80030) All cuts belonging to the group 2 (80031) and photographed during the next open-close (80040) belong to the group 3 (80041). The user can turn on the switch, start shooting, and when shooting that belongs to the group is finished, switch off the shot by a simple means, reflecting the user's intention and pre-grouping It is possible to easily manage captured image data without going through the complicated procedure of selecting a name. FIG. 8B is an example of a specific shape of the open-close switch. A switch 80051 is provided on the side of the electronic video camera 80050, and the switch is operated by switching to one of Open 80060 and Close 80061. If this switch is configured using the safety cover 80071 of the camera's shooting switch 80070, a new group is created when the cover is opened, and several cuts are shot there. When closing the camera to move, you can close the group by closing the safety cover. Also, if the camera's main switch is disconnected without closing, the procedure for automatically closing the group is performed, or the group that was used the last time when the main switch was turned on next time Either the closing process is performed or one of the methods is taken. Further, the date and time at the time of opening and closing are recorded as group attached information, and used as information necessary for selecting the group when accessing the group such as viewing an image later.
FIG. 9 is an explanatory diagram showing means for easily grouping cuts that have already been taken. A square frame 90000 is each cut of a photographed image and is photographed in order of time 90010. In this embodiment, an algorithm is provided in which each cut belongs to a designated group by designating a time range taken by the user. Time stamps are attached to the shots so that the time when the cuts are generated can be referred to at any time. Group 1 is a collection of cuts taken between 9:00 and 11:30, Group 2 is a collection of cuts taken after 11:30 to 13:50, and Group 3 is taken after 13:50. Is. This operation is performed after the photographing is finished, and may be performed on the camera or may be performed on the PC after being transferred to the PC shown in FIG. In addition, if the schedule is known in advance even before shooting, a group in which a time range is specified in advance is defined, and a shot that has been shot automatically belongs to that group. In addition, the time zone can be specified not only at the start time and the end time but also before a certain time or after a certain time.
FIG. 10 is an explanatory diagram showing a method for generating a group by randomly selecting a designated cut from a plurality of shooting cuts. 100000 is a multi-screen that displays all shots simultaneously. The first I-PICTURE of each cut may be displayed as a still image, or the I-PICTURE in each cut may be displayed one after another when the PLAY button is pressed. If the fast-forward button and the rewind button are used for this function, an operation of advancing or returning the I-PICTURE to be displayed is also possible. From each of the cuts displayed in this way, a cut to be a digest can be selected to create one group. The selection of the cut at this time may be performed by moving the selection frame 100010 displayed on the multi-screen 100000 by using a cross cursor or a left / right arrow cursor (not shown) installed on the camera.
FIG. 11 is an explanatory diagram showing a method of selecting a group during image reproduction. The photographed image data is classified into groups, and the user can reproduce the image data in the group only by selecting the group, and does not need to be aware of the existence of each image data file. FIG. 11A shows a method of displaying images in each group on a multi-screen and selecting a designated group from them. On the screen 110000, the first I-PICTURE of the image located at the head of each group in the multi-screen of 16 screens in this figure is displayed as a still image. By moving the selection frame 110010 with a cross cursor key or an arrow key (not shown) and selecting with the selection key, the image data registered in the group can be continuously reproduced. In addition to the first I-PICTURE still image display, for example, the cross-cursor up / down cursor displays all the I-PICTUREs of the image files in each group, and the image to be displayed on the multi-screen is selected with the left / right cursor. The frame 110010 may be moved and selected. FIG. 11B shows a method of selecting a group based on the date and time when the image was taken, without depending on visual recognition of the image. A list of groups is displayed on the screen 110020. The format is a sequential number of the group, a date 110021 and a time 110022 when the group was created or closed, and a total playback time 110023 of the image data included. : Displayed in seconds. By moving the selection frame 110024 with a cursor key (not shown) and selecting a group with a selection button, the image data in the designated group can be automatically and continuously reproduced.
FIG. 12 is an explanatory diagram showing a specific method of grouping image files according to the present invention. In FIG. 12A, the image file is FILE0001. MPG (120,000), FILE0002. MPG (120010), FILE0121. MPG (120020) and 121 files are prepared, and an attribute data image of each file is shown in the figure. The file name has the shooting date, the shooting start time, the length of the file in hours, and other information attached. These pieces of information are added to the image data entity and stored in the HDD. FIG. 12B shows data defining a group, which itself may be a file, or may be data that the camera program itself has. Group 1 (120030) includes FILE0002. MPG, FILE0014. MPG, FILE0007. MPG, and FILE0002. The MPG belongs, and each address 120040 is described in this data. The image file indicated by this address may be changed in order or duplicated. Further, the address may directly indicate a physical address in the HDD, but may be in a format indicated by a file name in accordance with information for managing the file system of the HDD. In this case, the data in the group need only be the relative address and file name from the group location of the area where the data exists.
FIG. 13 is an explanatory diagram showing image file division and grouping methods using the divided files. For example, an MPEG format image file can be divided in units of I-PICTURE as shown in FIG. Here, by dividing one photographed image file into finer scenes in units of I-PICTURE and handling them as independent files, it becomes possible to perform finer grouping. Original image file FILE0100. MPG (130000) is a unit separated by its I-PICTURE, FILE0101. MPG (130010), FILE0102. MPG (130020), FILE0107. The file is divided into MPG (130030) files. Each file describes the shooting date, time, length, and original file name as attribute data. By dividing an image file in units of I-PICTURE, an actual image can be divided by I-PICTURE included after performing extreme panning in addition to the regular periodic I-PICTURE. The scenes in which the camera is extremely swung can be removed from the captured image and used to generate a group, and in fact, the same effect as the editing work can be obtained. A group generated using these files is represented as group 1 (130040) in FIG. The contents are the same as in FIG. 12B, and a detailed description is omitted. Here, when copying a group of photographed images to show others, when the group 1 is copied, the image main body (130050) belonging to the group 1 is automatically copied together. Among them, only the image file main body defined in the group 1 is included, not the original image data before division. In order to pass only the minimum necessary image data at the time of copying, capacity saving and confidentiality can be performed.
FIG. 14 is an explanatory diagram showing a method of consolidating a plurality of image files and cutting out a partial portion and grouping them, contrary to FIG. The image data normally projected in FIG. 14A is divided into FILE0001. MPG (140000), FILE0002. MPG (140010), FILE0121. MPG (140020) and 121 cuts are prepared here. Integrating this, FILE-ALL. MPG (140030) is generated. In this operation, 121 original image files are arranged vertically to form one file. At this time, as additional information, address information indicating the head position of the original image file is provided for each original image file. The completed image file 140030 is one large image data, which can be divided into a plurality of image files. FIG. 14B shows an example in which a group is configured using the image file 140030. Group 1 (140040) includes a group using a part of images in image file 140030. Similarly to the example of FIG. 13, when copying this group to show it to other people, when the group 1 is copied, the image file 140030 is automatically copied together. It contains image data other than the image file defined in group 1. Even after copying, when editing group 1 or creating a new group, it does not belong to group 1 but first. All captured image data can be used.

10000 ... Camera, 10040 ... Compression / decompression circuit, 10200 ... PCMCIA-HDD
Card, 201010 ... I-PICTURE, 60000 ... Image file, 60010 ... Group, 100,000 ... Multi-screen.

Claims (1)

Photographing means for photographing a moving image or a still image as image data;
Detection means for detecting information about the shooting position;
Reproduction group creating means for creating a reproduction group by linking a plurality of image data according to the shooting position;
Display means for displaying a screen on which any one of the plurality of reproduction groups created by the reproduction group creation means can be selected;
Reproduction means for continuously reproducing a plurality of image data included in the selected reproduction group when one reproduction group is selected from the plurality of reproduction groups;
An image recording / reproducing apparatus method comprising:

Images