JP4567937B2 - Moving picture reproducing apparatus and moving picture reproducing method - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to a moving image reproducing apparatus and a moving image reproducing method, and more particularly to a moving image reproducing apparatus and a moving image reproducing method which are applied to, for example, a hard disk video recorder and reproduce a moving image signal recorded on a recording medium such as a hard disk. About.
[0002]
[Prior art]
In the conventional moving image reproducing apparatus and moving image reproducing method of this type, when a reproduction operation is performed on a desired reduced still image among a plurality of reduced still images displayed in multi, a moving image signal related to the reduced still image is displayed. Is reproduced from the recording medium, and a moving image based on the reproduced moving image signal is displayed on the monitor in full screen. In addition, when an erasing operation is performed on a desired reduced still image, a related moving image signal is erased from the recording medium.
[0003]
[Problems to be solved by the invention]
However, it is not easy to understand the contents of a moving image signal only from a reduced still image. When an erasing operation is performed on one of the reduced still images, a moving image signal different from a desired moving image signal is erroneously deleted. There is a fear.
[0004]
Therefore, a main object of the present invention is to provide a moving image reproducing apparatus and a moving image reproducing method capable of preventing erroneous erasure of a moving image signal recorded on a recording medium.
[0005]
[Means for Solving the Problems]
According to a first aspect of the present invention, there is provided first output means for outputting a multi-screen signal including a plurality of reduced still image signals individually corresponding to a plurality of moving image signals recorded on a recording medium, and a desired multi-screen based on the multi-screen signal. Selection operation accepting means for accepting a selection operation of a reduced still image, reproduction means for reproducing a moving image signal corresponding to a desired reduced still image from a recording medium in response to the selection operation, and a reproduction moving image reproduced by the reproduction means Second output means for outputting an operation screen signal including a reduced moving picture signal based on the signal, an erasing operation accepting means for accepting an erasing operation on the operation screen based on the operation screen signal, and recording a reproduced moving picture signal in response to the erasing operation It is a moving image reproducing device provided with an erasing means for erasing from a medium.
[0006]
The second invention includes (a) a step of outputting a multi-screen signal including a plurality of reduced still image signals individually corresponding to a plurality of moving image signals recorded on a recording medium, and (b) a multi-screen signal based on the multi-screen signal. A step of accepting a selection operation of a desired reduced still image on the screen, (c) a step of reproducing a moving image signal corresponding to the desired reduced still image from the recording medium in response to the selection operation, (d) in step (c) A step of outputting an operation screen signal including a reduced moving image signal based on the reproduced moving image signal reproduced, (e) a step of accepting an erasing operation on the operation screen based on the operation screen signal, and (f) in response to the erasing operation. A moving image reproducing method comprising a step of erasing a reproduced moving image signal from a recording medium.
[0007]
[Action]
In the present invention, a multi-screen including a plurality of reduced still images is formed by the multi-screen signal. When a selection operation for selecting a desired reduced still image is performed on the multi-screen, a moving image signal corresponding to the desired reduced still image is reproduced from the recording medium. Then, an operation screen including a reduced moving image based on the reproduced moving image signal is formed by the operation screen signal. When an erasing operation for erasing a reproduced moving image signal represented by an arbitrary reduced moving image is performed on the operation screen, the reproduced moving image signal is erased from the recording medium. That is, after confirming the content of the moving image signal to be erased with the reduced moving image, the moving image signal can be erased.
[0008]
An embodiment of the present invention further includes a protect operation accepting unit that accepts a protect operation for the operation screen, and a protect unit that protects the reproduced moving image signal in response to the protect operation.
[0009]
In another embodiment of the present invention, the second output means is configured as follows. That is, reduction zoom means for generating a reduced moving image signal by reducing the reproduction moving image signal, generating means for generating a character signal having a window signal corresponding to the reduced moving image signal, and reduced moving image signal and character signal And a mixing means for generating an operation screen signal.
[0010]
In this case, it is desirable that the reduction zoom means execute the reduction zoom at a zoom magnification at which a reduced moving image having the same size as the reduced still image is displayed. That is, the size of the reduced still image displayed on the multi-screen and the size of the reduced moving image displayed on the operation screen are the same size.
[0011]
Furthermore, a playback operation receiving means for receiving a playback operation on the operation screen, an increasing means for increasing the zoom magnification of the reduction zoom means in response to the playback operation, and a window formed by a window signal in response to the playback operation You may further provide the expansion means to expand the area of this in steps. That is, the size of the reduced moving image is gradually increased, and the area of the window corresponding to the reduced moving image is also gradually increased.
[0012]
As the recording medium, a disk medium can be used.
[0013]
【The invention's effect】
According to the present invention, since the content of the moving image signal to be erased can be confirmed with the reduced moving image, unlike the above-described conventional technique in which the content of the moving image signal is understood only from the reduced still image, There is an effect that the erroneous erasure of the moving image signal can be surely prevented.
[0014]
The above object, other objects, features and advantages of the present invention will become more apparent from the following detailed description of embodiments with reference to the drawings.
[0015]
【Example】
Referring to FIG. 1, a hard disk video recorder 10 of this embodiment is a device for recording (recording) / reproducing a television broadcast program, and a receiving antenna 12 for receiving radio waves of the television broadcast program. Has an antenna input terminal T1 to which is connected. The receiving antenna 12 converts the received radio wave into a high-frequency electric signal, and the converted high-frequency signal is input to the tuner circuit 14 via the antenna input terminal T1. The tuner circuit 14 extracts a frequency component of an arbitrary channel from the input high frequency signal. Which frequency component is to be extracted is determined based on a channel selection command supplied from a CPU (Central Processing Unit) 16. The tuner circuit 14 converts the extracted signal into an analog television signal, and inputs the converted television signal to the recording processing circuit 18.
[0016]
The recording processing circuit 18 converts the input television signal into digital video data (strictly including audio data) according to the YUV format in units of one field. Further, the video recording processing circuit 18 compresses the converted video data according to the MPEG (Motion Picture Expert Group) 2 system by the moving picture compression circuit 20 incorporated therein (the audio data is compressed according to the MPEG1 audio system or the MPEG2 audio system). Thus, compressed moving image data is generated. The compressed moving image data is transferred to the hard disk 22 and recorded under the control of the CPU 16.
[0017]
Note that the CPU 16 generates the above-described channel selection command in response to an operation of a channel selection key (not shown) constituting the operation key 24 (or a remote control key (not shown)). Then, when a recording key (not shown) constituting the operation key 24 is pressed, the CPU 16 transfers the compressed moving image data after processing by the recording processing circuit 18 (after compression by the moving image compression circuit 20) to the hard disk 22 for recording. A recording operation is performed. At this time, the compression rate of the video data by the moving image compression circuit 20 can be set by operating a recording mode selection key (not shown) constituting the operation key 24. Specifically, the “high image quality mode” with a low compression rate, There are three modes: a “long-time mode” with a high compression ratio and a “standard mode” with an intermediate compression ratio between these modes. This series of recording operations is stopped by pressing a stop key (not shown) constituting the operation key 24.
[0018]
On the other hand, when a predetermined reproduction operation described later is performed by the operation key 24, the CPU 16 enters a reproduction operation. That is, the CPU 16 instructs the hard disk 22 to sequentially read the compressed moving image data of the program to be played back to the playback processing circuit 26. The compressed moving image data read to the reproduction processing circuit 26 in accordance with this instruction is decompressed by the decompression circuit 28 incorporated in the reproduction processing circuit 26, thereby reproducing the video data in accordance with the YUV format of one field unit described above. The The video data is temporarily stored in the video memory 30 under the control of the CPU 16 and then input to the encoder 38 via the variable scaler 32 and the mixing circuit 34.
[0019]
The encoder 36 converts the video data input from the mixing circuit 34 into an analog television signal. The converted television signal is output to the outside via the output terminal T2. Therefore, when a monitor device 50 such as a television receiver is connected to the output terminal T2, a playback video (moving image) is displayed on the display screen of the monitor device 50. In order to stop the series of reproduction operations, the stop key described above may be pressed.
[0020]
In a state other than the playback operation, a video of the program currently being received, that is, a so-called live video is displayed on the display screen of the monitor device 50. In this case, although not shown in the figure, the CPU 16 directly sends the video data processed by the recording processing circuit 18 (video data before compression by the moving image compression circuit 20) directly to the reproduction processing circuit 26 without going through the hard disk 22. Input (however, not via the decompression circuit 28).
[0021]
Furthermore, the hard disk video recorder 10 of this embodiment has an OSD (On Screen Display) function, and has an OSD memory 38 that is separate from the video memory 30 described above in order to realize this OSD function. . That is, when performing various settings such as channel selection initial setting and recording reservation setting, the CPU 16 displays OSD data corresponding to the setting screen in order to display a setting screen corresponding to each setting content on the display screen of the monitor device 50. Is written into the OSD memory 38. This OSD data is stored in advance in a memory area (not shown) in the CPU 16. However, since the OSD data conforms to the RGB format, the OSD data written in the OSD memory 38 is converted into YUV format data by the YUV conversion circuit 40 and then input to the mixing circuit 34.
[0022]
The mixing circuit 34 mixes the OSD data input from the YUV conversion circuit 40 and the video data input via the variable scaler 32 with each other. Then, the data after mixing them is input to the encoder 36. As a result, a screen composed of the video memory 30, a so-called video surface, and a screen composed of the OSD memory 38, a so-called OSD surface, are displayed on the monitor device 50. More specifically, the OSD screen setting screen is overlaid on the video screen image (reproduced video or live video). The operator can perform various settings such as channel selection initial setting and recording reservation setting by operating the operation key 24 while viewing the setting screen. Note that the video screen and the OSD screen have the same size (area).
[0023]
Incidentally, as shown in FIG. 2, in the hard disk 22, in addition to the compressed moving image data, a plurality of thumbnail data individually corresponding to each compressed moving image data is recorded. In the figure, the numbers written in parentheses ([]) in each compressed moving image data indicate the order in which each compressed moving image data is recorded on the hard disk 22. This order is also attached to each thumbnail data.
[0024]
The thumbnail data is data for displaying thumbnails of the compressed moving image data corresponding to each, and is generated by the thumbnail generation circuit 42. The thumbnail generation circuit 42 includes a fixed scaler 44 and a still image compression circuit 46, and video data is input from the video memory 30 to the fixed scaler 44. The fixed scaler 44 performs so-called reduction zoom processing on the video data so that the size of the image based on the input video data is reduced to 1 / Md of the size of the video surface, and the processed video data is processed. Input to the still image compression circuit 46. As a reduction ratio of 1 / Md, 1 / Md = 1/8 is appropriate. When a compression command is supplied from the CPU 16, the still image compression circuit 46 compresses video data input from the fixed scaler 44 at that time according to a JPEG (Joint Photographic Expert Group) method, and generates compressed still image data. To do. The compressed still image data is recorded on the hard disk 22 as thumbnail data.
[0025]
Note that the CPU 16 basically performs the above-described compression command so as to generate thumbnail data based on video data of a predetermined field counted from the first field when each compressed moving image data is reproduced for the first time. Is generated. However, when a pause key (not shown) constituting the operation key 24 is pressed during reproduction, a compression command is generated when the pause key is pressed. That is, by operating the pause key, an arbitrary field of the reproduced video can be recorded as a thumbnail.
[0026]
Furthermore, an EEPROM (Electrically Erasable Programmable Read-Only Memory) 48 is connected to the CPU 16, and a recording table as shown in FIG. 3 is stored in the EEPROM 48. As shown in the figure, in the recording table 48, various information relating to each compressed moving image data recorded on the hard disk 22 is recorded. Specifically, the recording order (No.) to the hard disk 22 is set. As a reference, information on the channel (CH), recording date, recording start time, recording time, recording mode, genre, and presence / absence of protection is recorded.
[0027]
Among these, the recording date, the recording start time, and the recording time are obtained based on time information given from a timer circuit (RTC: Real Time Clock) (not shown) connected to the CPU 16. The genre can be arbitrarily input by operating the operation key 24, but since it is not directly related to the gist of the present invention, detailed description thereof is omitted here. The protect is a so-called protection marker for making the compressed moving image data unerasable, and “1” is input to the compressed moving image data for which the protection is valid (that is, protected). Then, “0” is input to the compressed moving image data in which the protection is invalid (that is, the protection is not applied). The procedure for enabling or disabling this protection will be described later.
[0028]
The predetermined reproduction operation described above starts when the menu key 24a constituting the operation key 24 is pressed. That is, when the menu key 24a is pressed, the CPU 16 controls the video memory 30, the variable scaler 32, and the OSD memory 38 so as to display a menu screen as shown in FIG. 4C on the display screen of the monitor device 50.
[0029]
Specifically, the OSD data is written into the OSD memory 38 so as to form an OSD surface as shown in FIG. According to the OSD surface, a plurality of rectangular windows 52, 52,... Each having a transparent color are displayed in a matrix (in the figure, six windows 52, 52,. (Displayed in two columns). .. Are displayed below the windows 52, 52,... (In the figure, numbers "1" to "6"). The heading number 54 corresponds to the recording order of each compressed video data (the numerical value in the “No.” column in the recording list 48 of FIG. 3). Furthermore, a rectangular cursor 56 that is slightly larger than the window 52 is displayed so as to surround the outer periphery of any one window (here, the upper left window) 52. The size of each window 52 is 1 / Md of the entire OSD plane (in other words, the video plane). In addition, the portions other than the windows 52, 52,... Are opaque colors, and in detail, the heading numbers 54, 54,. The other background portions are represented in blue (so-called blue back).
[0030]
On the other hand, for the video memory 30, the above-described thumbnail data is read from the hard disk 22 through the reproduction processing circuit 26 by the number of windows 52 on the OSD surface. Based on the read thumbnail data (strictly, the thumbnail data after decompression by the decompression circuit 28), as shown in FIG. 4B, the arrangement of the windows 52, 52,. .. Are displayed in three horizontal rows and two vertical rows. At this time, the thumbnail numbers 54 assigned to the windows 52 and the thumbnails so that the recording order of the compressed moving image data corresponding to the thumbnails 58 arranged in accordance with the windows 52 match each other. 58, 58,... Are assigned.
[0031]
The variable scaler 32 arbitrarily changes the size and position when the image developed on the video screen is displayed on the display screen of the monitor device 50. As shown in FIG. 5, the size is arbitrarily reduced. Reduction zooming can be performed at a rate of 1 / Ms (0 <Ms ≦ 1). The position can be changed by arbitrarily setting the coordinates (Xs, Ys) of the base point on the display screen of the monitor device 50 with the upper left corner of the image as the base point. Since the technique for arbitrarily changing the image size and the display position in this manner is a known technique, a detailed description of this technique is omitted here. For the variable scaler 32, when displaying the menu screen, the CPU 16 sets the reduction ratio 1 / Ms to “1/1” and the base point coordinates (Xs, Ys) to “(0, 0)”. Control. In this case, the variable scaler 32 is in a through state, and outputs data input from the video memory 30 to the mixing circuit 34 as it is.
[0032]
By controlling the video memory 30, the variable scaler 32, and the OSD memory 38 in this way, the menu screen of FIG. 4C is displayed. In other words, six thumbnails 58, 58,... Are individually displayed in a frame of six windows 52, 52,. A heading number 54 is displayed below. Then, a cursor 56 is displayed so as to surround the outer periphery of any one thumbnail 58.
[0033]
The cursor 56 is for selecting a video to be reproduced, and can be moved by operating an arrow key 24b constituting the operation key 24. That is, when the arrow key 24b is pressed while the menu screen is displayed, the CPU 16 moves the cursor 56 in the direction specified by the arrow key 24b (either up, down, left, or right). The OSD memory 38 is controlled. However, the cursor 56 cannot be moved in a direction away from the menu screen.
[0034]
In this menu screen, it is assumed that the determination key 24dc constituting the operation key 24 is pressed in a state where any one of the thumbnails 52 is selected by the cursor 56 (here, the state shown in FIG. 4C). Then, the CPU 16 shifts the screen display of the monitor device 50 from the menu screen display to the operation screen display shown in FIG.
[0035]
Specifically, OSD data for configuring the OSD plane as shown in FIG. 6A is written into the OSD memory 38. That is, the window 60 having the same size as the window 52 in the upper left corner in FIG. 4A is displayed at the same position as the window 52, and predetermined characters 62 to 74 are displayed on the right side of the window 60. To do.
[0036]
Among the characters 62 to 74, the character 62 with the rectangular frame displayed at the top represents the recording order of the compressed moving image data corresponding to the thumbnail 58. The characters 64, 66 and 68 representing the channel, recording mode and genre are displayed below the character 62 representing the recording order, and the character 70 representing the recording date is displayed below these characters 64, 66 and 68. indicate. Further, characters 72 and 74 representing the recording start time and the recording time are displayed below the character 70. Then, characters 78, 80, 82 and 84 "reproduce", "erase", "protect" and "return" are displayed below the OSD surface across the partition line 76 along the horizontal direction. A rectangular cursor 86 is displayed so as to surround any of 78 to 84. In this operation screen, the window 60, the characters 62 to 84, and the cursor 86 are displayed in white, and the background portion is displayed in Boolean-back.
[0037]
For one video memory 30, the compressed moving image data corresponding to the selected thumbnail 52 is read from the hard disk 22 to the reproduction processing circuit 26, and the decompressed circuit 28 expands the read compressed moving image data to expand the video data. Reproduce. Then, by writing the reproduced video data into the video memory 30, as shown in FIG. 6B, a reproduced video (moving image) 88 is developed on the entire video screen. The reproduction operation is started from this point.
[0038]
With respect to the variable scaler 32, the size of the playback video 88 is reduced so that the playback video 88 developed on the video screen fits within the frame of the window 60 on the OSD screen, and the playback video 88 of the reduced playback video 88 is reduced. Set the display position. Specifically, the reduction ratio 1 / Ms is set to “1 / Md”, and the base point (Xs, Ys) is set to “(Xd, Yd)”. Here, “(Xd, Yd)” is an initial value of the base point (Xw, Yw) of the window 60.
[0039]
By controlling the video memory 30, the variable scaler 32, and the OSD memory 38 in this way, the operation screen shown in FIG. 6C is displayed on the monitor device 50. That is, the reproduced video 88 is reduced and displayed on the upper left of the screen, and characters 62 to 74 representing detailed information on the reproduced video 88 are displayed on the right side of the reduced reproduced video 88. At the bottom of the screen, characters 78 to 84 representing the contents of the processes “play”, “erase”, “protect” and “return” are displayed, and surround any of these characters 78 to 84. A cursor 86 is displayed.
[0040]
The cursor 86 is used to arbitrarily select one of the processes “play”, “erase”, “protect”, and “return”, and this selection is performed by operating the arrow key 24b and the decision key 24c described above. For example, when the determination key 24c is pressed in a state where the cursor 86 is moved so as to surround the character 78 “play” by the operation of the arrow key 24b, the process “play” is selected. In this case, the CPU 16 controls the OSD memory 38 and the variable scaler 32 as follows.
[0041]
That is, as shown in FIG. 7A, the OSD memory 38 is moved stepwise from the base point (Xw, Yw) of the window 60 toward the base point “(0, 0)” of the OSD plane.
At the same time, the size of the window 60 is increased stepwise, that is, the reduction ratio 1 / Mw of the size of the window 60 with respect to the size of the OSD plane is “1/1” from the initial reduction ratio of “1 / Md” described above. Change in steps until " When the base point (Xw, Yw) of the window 60 reaches the base point “(0, 0)” of the OSD plane, the reduction ratio 1 / Mw becomes “1/1” at the same time. Thus, the base point (Xw, Yw) and the reduction ratio 1 / Mw are changed.
[0042]
On the other hand, with respect to the variable scaler 32, the reproduced video 88 developed on the entire video screen as shown in FIG. 7B fits within the frame of the window 60 on the OSD surface of FIG. Change the size and position of the. That is, the reduction ratio 1 / Ms described above is set to “1 / Mw”, and the base point (Xs, Ys) is set to “(Xw, Yw)”.
[0043]
By controlling the OSD memory 38 and the variable scaler 32 in this way, as shown in FIG. 7C, the size of the reproduced video 88 displayed on the monitor device 50 gradually increases with time. Finally, the playback video 88 is displayed on the entire screen of the monitor device 50. In this embodiment, about 3 to 5 [s] is required until the size of the playback image 88 is maximized after selecting the process “play” on the operation screen (that is, after pressing the enter key 24c). I try to hang it. Of course, this time can be set arbitrarily.
[0044]
On the other hand, when “Erase” is selected on the operation screen of FIG. 6C (specifically, the enter key 24c is pressed with the cursor 86 moved so as to surround the character 80 “Erase” by the operation of the arrow key 24b). When pressed, the CPU 16 erases the compressed moving image data of the reproduced video 88 displayed on the operation screen and the corresponding thumbnail data from the hard disk 22. At the same time, the CPU 16 deletes various information related to the compressed moving image data from the recording table 48 and organizes (updates) the recording contents of the recording table 48 after the deletion. Then, the CPU 16 controls the video memory 30 and the OSD memory 38 so that the menu screen of FIG. 4C is displayed again based on the recorded contents of the updated recording table 48.
[0045]
However, when the above-described protector is applied to the compressed moving image data to be deleted, the CPU 16 displays a message indicating that effect (that is, the compressed moving image data cannot be deleted because the protector is valid). Displayed on the monitor device 50. Then, after the message is displayed, the video memory 30 and the OSD memory 38 are controlled so that the menu screen is displayed again.
[0046]
Further, when “Protect” (character 82) is selected on the operation screen of FIG. 6C, the CPU 16 applies a protector to the compressed moving image data of the reproduced video 88 displayed on the operation screen. Specifically, “1” is recorded in the “protect” column for the compressed image data in the recording list 48. After this protection processing, the CPU 16 controls the video memory 30 and the OSD memory 38 so that the menu screen is displayed again.
[0047]
If the compressed moving image data corresponding to the thumbnail 52 selected on the menu screen has already been protected, the upper right portion of the operation screen as shown by a rectangular dotted line 90 in FIG. A mark indicating that the protection is valid (for example, a character “PROTECT”) is displayed. Of course, the character 90 is written on the OSD memory 38. For compressed moving image data for which such protection is valid, when “protect” is selected on the operation screen, the protection is canceled, that is, invalidated.
[0048]
When “return” (character 84) is selected on the operation screen of FIG. 6C, the CPU 16 returns the screen display of the monitor device 50 to the state before the operation screen is displayed, that is, the menu screen. The video memory 30 and the OSD memory 38 are controlled.
[0049]
When the menu key 24a is pressed on the menu screen or the operation screen, the CPU 16 changes the entire OSD screen to a transparent color as shown in FIG. 8A and the video screen as shown in FIG. 8B. The OSD memory 38 and the video memory 30 are controlled so that the live video is displayed as a whole. At the same time, the CPU 16 sets the variable scaler 32 to the through state. As a result, as shown in FIG. 8C, a live image is displayed on the display screen of the monitor device 50 over the entire screen.
[0050]
In this way, the menu screen of FIG. 4C and the operation screen of FIG. 6C are displayed, and in order to implement each process using these screens, the CPU 16 stores the above-described memory area. Each process shown in the flowcharts of FIGS. 9 to 12 is executed in accordance with the stored control program. Before entering these processes, it is assumed that a live video is displayed on the display screen of the monitor device 50 as shown in FIG.
[0051]
Referring to FIG. 9, when menu key 24a is pressed, CPU 16 proceeds to step S1 and displays the screen shown in FIG. 4A on the OSD surface, the so-called menu screen (strictly speaking, OSD data for displaying the menu screen is written into the OSD memory 38). Then, the CPU 16 refers to the recording list in the EEPROM 48 in step S3, and reads the thumbnail data from the hard disk 22 in step S5 based on the reference result. Based on the read thumbnail data, a plurality of thumbnails 58, 58,... Are displayed on the video screen in a step S7 as shown in FIG. Are written in the video memory 30). As a result, the menu screen of FIG. 4C is displayed on the display screen of the monitor device 50.
[0052]
After the menu screen is displayed, the CPU 16 proceeds to step S9 and waits for an operation to be performed by the operation key 24. When any operation is performed, the CPU 16 proceeds to step S11 to determine the content of the operation.
[0053]
If it is determined in step S11 that the arrow key 24b has been pressed, the CPU 16 proceeds to step S13, moves the cursor 56 in the direction specified by the arrow key 24c on the OSD surface, and then returns to step S9. .
[0054]
On the other hand, when determining that the menu key 24a has been pressed, the CPU 16 proceeds to step S15. In step S15, the entire OSD plane is set to a transparent color, and in step S17, live video is displayed on the video plane, and a series of processes shown in the flowchart is completed.
[0055]
If it is determined in step S11 that the enter key 24c has been pressed, the CPU 16 proceeds to step S19 in FIG. In step S19, various information relating to the compressed video data corresponding to the thumbnail 58 selected on the menu screen of FIG. 4C is read from the recording list 48, and on the basis of the read information, the OSD is read in step S21. A screen shown in FIG. 6A, a so-called operation screen, is displayed on the screen.
[0056]
Further, in step S23, the CPU 16 sets the base point (Xs, Ys) of the variable scaler 32 to “(Xd, Yd)” and the reduction ratio 1 / Ms to “1 / Md”. In step S25, reading of the compressed moving image data corresponding to the thumbnail 58 selected on the menu screen of FIG. 4C is started, and in step S27, the video screen is displayed as shown in FIG. 6B. Thus, a moving image (reproduced video) based on the read compressed moving image data is developed. As a result, the operation screen shown in FIG. 6C is displayed on the display screen of the monitor device 50.
[0057]
After displaying this operation screen, the CPU 16 proceeds to step S29 and waits for some operation to be performed by the operation key 24. When any operation is performed, the CPU 16 proceeds to step S31 and determines the content of the operation.
[0058]
When the arrow key 24b is pressed here, the CPU 16 proceeds to step S33. Then, after moving the cursor 86 according to the operation of the arrow key 24c on the OSD surface, the process returns to step S29.
[0059]
On the other hand, when the menu key 24a is pressed, the CPU 16 proceeds to step S35. In step S35, the base point (Xs, Ys) of the variable scaler 32 is set to “(0, 0)”, and the reduction ratio 1 / Ms is set to “1/1”. Then, the process proceeds to step S15 in FIG.
[0060]
Further, assuming that “reproduction” is selected in step S31, the CPU 16 proceeds to step S37 in FIG. In step S37, the CPU 16 leaves only the window 60 on the OSD plane shown in FIG. 6A and erases other portions such as the characters 62 to 74. In step S39, as shown in FIG. 7A, the base point (Xw, Yw) of the window 60 on the OSD plane is moved one step toward “(0, 0)”. In step S41, the reduction ratio 1 / Mw of the window 60 is increased by one level (that is, Mw is reduced).
[0061]
In step S43, the base point (Xs, Ys) of the variable scaler 32 is adjusted to the base point (Xw, Yw) of the window 60 on the OSD plane, and in step S45, the reduction ratio 1 / Ms of the variable scaler 32 is set to the window 60. The reduction ratio is adjusted to 1 / Mw.
[0062]
After controlling the base point (Xs, Ys) and the reduction ratio 1 / Ms of the variable scaler 32 according to the window 60 on the OSD plane in this way, the CPU 16 proceeds to step S47. In step S47, it is determined whether or not the enlargement work of the variable scaler 32 is completed. Specifically, the base point (Xs, Ys) reaches “(0, 0)” and the reduction ratio 1 / Ms is reduced. It is determined whether or not 1/1. Here, the enlargement work is not completed (that is, the base point (Xs, Ys) has not reached “(0, 0)” and the reduction ratio 1 / Ms is not 1/1). When the determination is made, the CPU 16 proceeds to step S49, waits for a predetermined time (about several tens [ms]), and then returns to step S39. On the other hand, if the CPU 16 determines that the enlargement work has been completed (that is, the base point (Xs, Ys) has reached “(0, 0)” and the reduction ratio 1 / Ms has been reduced to 1/1), the CPU 16 Proceed to S51.
[0063]
In step S51, the CPU 16 determines whether or not the video currently being reproduced has been completely reproduced, or whether or not the above-described stop key has been pressed. Here, when the video currently being reproduced is completely reproduced or the stop key is pressed, the CPU 16 proceeds to step S53. In step S53, after the reproduction operation is stopped, the process returns to step S1 in FIG. 9 to display the menu screen again.
[0064]
Further, if it is determined that “Erase” is selected in step S31 of FIG. 10 (the operation screen of FIG. 6C), the CPU 16 proceeds to step S55 of FIG.
In step S55, the CPU 16 determines whether or not the protection of the compressed moving image data to be deleted is valid. If the protection is valid, the CPU 16 proceeds to step S57 and displays a message indicating that the compressed moving image data cannot be erased (strictly, OSD data for displaying this message is displayed). Write to OSD memory 38). After displaying this message, the CPU 16 proceeds to step S59 to set the variable scaler 32 to the through state, and then returns to step S1 in FIG. 9 to display the menu screen again.
[0065]
On the other hand, when determining in step S55 that the protection is invalid, the CPU 16 proceeds to step S61. In step S61, the compressed moving image data to be deleted and the corresponding thumbnail data are deleted from the hard disk 22, and various information relating to the compressed moving image data is deleted from the recording list 48. In step S63, the contents of the recording list 48 are updated, and then the process proceeds to step S59.
[0066]
If it is determined in step S31 in FIG. 10 that “Protect” has been selected, the CPU 16 proceeds to step S65 in FIG. In step S65, the CPU 16 determines whether the protection of the compressed moving image data is valid. If the protection is valid, the CPU 16 proceeds to step S67 to cancel the protection, that is, invalidates, and then proceeds to step S63. On the other hand, if the protection is invalid, the CPU 16 proceeds to step S69, sets the protection, that is, validates, and then proceeds to step S63.
[0067]
When “return” is selected in step S31 in FIG. 10, the CPU 16 sets the variable scaler 32 to the through state in step S59 in FIG. 12 to display the menu screen again, and then in step S1 in FIG. Return to.
[0068]
As described above, according to this embodiment, in order to delete arbitrary compressed moving image data, a menu screen is displayed by pressing the menu key 24a, and the compressed moving image to be deleted on the menu screen is displayed. It is necessary to display the operation screen by selecting the thumbnail 58 corresponding to the data. In this operation screen, the playback video 88 reduced based on the compressed video data to be deleted is displayed, so that the content of the compressed video data to be deleted can be confirmed from the playback video 88. . Therefore, it is possible to prevent an erroneous operation of accidentally deleting another compressed moving image data.
[0069]
Similarly, at the time of reproduction, the contents of the compressed moving image data to be reproduced can be confirmed from the reduced reproduction image 88 displayed on the operation screen, so that the desired compressed moving image data can be reliably reproduced.
[0070]
Further, since each compressed moving image data can be individually protected, erroneous erasure of the compressed moving image data can be more reliably prevented.
[0071]
Further, by changing the size of the reproduced video by the variable scaler 32 during reproduction, the display form of the reproduced video is interesting. If several control patterns of the variable scaler 32 are prepared, more various display modes can be realized.
[0072]
In this embodiment, the application of the present invention to the recordable / reproducible hard disk video recorder 10 has been described. However, the present invention is not limited to this. For example, the present invention may be applied to a reproduction-only device. Further, the present invention may be applied to an apparatus that employs another recording medium such as a DVD (Digital Versatile Disc) instead of the hard disk 22.
[0073]
Then, after selecting “play” on the operation screen shown in FIG. 6C, the size and position of both the window 60 and the playback video 88 are changed, but this is not restrictive. For example, the OSD surface may be a completely transparent color, and the size and position of the playback video 88 may be changed by the variable scaler 32. However, in this case, on the display screen of the monitor device 50, the portion other than the reproduced video 88 is displayed in black.
[0074]
Furthermore, although the MPEG2 system is employed as the video data compression system by the moving picture compression circuit 20, other compression systems such as a motion JPEG (Motion JPEG) system may be employed. Further, although the JPEG method is adopted as the compression method of the video data by the still image compression circuit 46 of the thumbnail generation circuit 42, other compression methods such as a GIF (Graphics Interchange Format) method may be adopted.
[0075]
The OSD memory 38 is compatible with the RGB format, but may be configured with a memory compatible with the YUV format. In this case, the YUV conversion circuit 38 is unnecessary, but it is necessary to create the OSD data in the YUV format.
[0076]
In the menu screen, six thumbnails 58, 58,... (Windows 52, 52,...) Are displayed as a list, but a number of thumbnails 58 other than six may be displayed. . If all the thumbnails 58 cannot be displayed on one screen, all the thumbnails 58 may be sequentially displayed by scrolling the screen according to the movement of the cursor 56, for example.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a schematic configuration of a hard disk video recorder according to an embodiment of the present invention.
2 is an illustrative view conceptually showing a configuration in a hard disk in the embodiment of FIG. 1; FIG.
FIG. 3 is an illustrative view conceptually showing recorded contents of a recording list in the embodiment of FIG. 1;
4 is an illustrative view conceptually showing a configuration of a menu screen in the embodiment of FIG. 1; FIG.
FIG. 5 is an illustrative view showing a concept of operation of a variable scaler in the embodiment of FIG. 1;
6 is an illustrative view conceptually showing a configuration of an operation screen displayed after a certain thumbnail is selected on the menu screen of FIG. 4;
7 is an illustrative view showing a transition state of the display screen after selecting “play” on the operation screen of FIG. 6; FIG.
FIG. 8 is an illustrative view conceptually showing the structure of a screen when a live video is displayed in the embodiment of FIG. 1;
FIG. 9 is a flowchart showing the operation of the CPU in the embodiment of FIG. 1;
FIG. 10 is a flowchart following FIG. 9;
FIG. 11 is a flowchart following FIG. 10;
12 is a flowchart different from FIG. 11 following FIG.
[Explanation of symbols]
16 ... CPU
22 ... Hard disk
24 ... operation keys
30 ... Video memory
32 ... Variable scaler
38 ... OSD memory
42 ... Thumbnail generation circuit

Claims (2)

A selection means for displaying a window area individually corresponding to a plurality of moving image signals recorded on the recording medium, and selecting one of the displayed window areas;
Display means for displaying a reduced moving image of the moving image signal corresponding to the window region selected by the selecting means, information indicating the size of the moving image signal, and an icon for deleting the moving image signal ;
A moving image reproducing apparatus comprising: an erasing operation accepting unit that accepts an erasing operation; and an erasing unit that erases the moving image signal and the information related to the moving image signal from the recording medium in response to the erasing operation. 2. The moving image reproducing apparatus according to claim 1, wherein the information suggesting the size of the moving image signal is a recording time and a recording mode.

Images