JP3775611B2 - Editing system - Google Patents

Description

[0001]
【table of contents】
The present invention will be described in the following order.
TECHNICAL FIELD OF THE INVENTION
Conventional technology
Problems to be solved by the invention
Means for solving the problem
BEST MODE FOR CARRYING OUT THE INVENTION
(1) Overall configuration of editing system (Fig. 1)
(2) Internal configuration of the computer (Fig. 2)
(3) Graphic display for GUI
(3-1) Picture mode (Fig. 3)
(3-2) Timeline mode (Figs. 4 and 5)
(4) Clip image data management method (FIGS. 6 to 11)
(5) Configuration of hybrid recorder (FIG. 12)
(6) Playback speed setting
(6-1) Playback speed setting area (FIG. 13)
(6-2) Dedicated controller (FIGS. 14 and 15)
(6-3) Playback speed setting method
(7) Pre-roll mode (FIGS. 16 and 17)
(8) Work data folder (Fig. 18)
(9) Description of computer operation (FIGS. 19 to 26)
(10) Operation and effect of the embodiment
(11) Other embodiments
The invention's effect
[0002]
BACKGROUND OF THE INVENTION
The present invention relates to an editing system, and is suitable for application to an editing system that edits a material that requires rapid reporting, such as sports or news.
[0003]
[Prior art]
Conventionally, as this kind of editing system, a system using a video tape recorder (hereinafter abbreviated as VTR) as recording means for recording a material to be edited has been proposed. In such an editing system, live video such as sports and news is recorded in sequence by a VTR, and the recorded video is read as an editing material and used for program editing.
[0004]
[Problems to be solved by the invention]
By the way, in order to provide viewers with more powerful and realistic video when handling live video such as sports and news, it is desirable that the editing system be capable of editing operations with high speed. However, since the conventional editing system as described above uses a VTR as a recording medium, it takes time to cue, fast forward, or rewind the VTR, and the VTR must be controlled just before on-air. When you can't do a quick editing operation, there is a problem.
[0005]
In addition, the conventional editing system requires a variety of equipment in addition to the VTR for editing, such as confirmation of the recorded video and confirmation of the edited video. There is always a problem when it ends. In addition, various equipment must be operated, and there is a problem when the operation becomes complicated.
In this way, conventional editing systems are not considered to be able to efficiently perform editing work in a limited environment at the site, and materials that require real-time properties such as sports broadcasts and news reports are required. It is not considered to be handled, and there are still some inadequacies in usability.
[0006]
The present invention has been made in consideration of the above points, and intends to propose an editing system with improved usability capable of realizing high-speed real-time editing.
[0007]
[Means for Solving the Problems]
In order to solve this problem, the present invention is an editing system having a main recording / reproducing apparatus and a computer, and the main recording / reproducing apparatus records source video data supplied from the outside on a recording medium while In response to the playback command, the source video data recorded on the recording medium is played back, the source video data recorded on the recording medium is output to the computer as first video data, and the played back source video data Are output to the computer as second video data.
In the computer, the desired event specified via the user interface means is selected from the events formed from the first or second video data from the IN point to the OUT point specified via the user interface means. The playback speed of the second video data for the event is set to the playback speed specified through the user interface means.
[0008]
As a result, the present invention can perform real-time editing by simultaneously performing recording and playback, and can set different slow playback within the event to provide viewers with more powerful video, thus real-time editing. It is possible to realize an editing system with improved usability while speeding up.
[0009]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.
[0010]
(1) Overall configuration of editing system
In FIG. 1, reference numeral 1 denotes an editing system to which the present invention is applied as a whole, which is roughly composed of a computer 2 and a hybrid recorder 3. The computer 2 includes a main body 2a having a CPU, various processing circuits, a floppy disk drive, a hard disk drive, etc., and a monitor 2b, a keyboard 2c, a mouse 2d, and a dedicated controller 2e connected to the main body 2a. . In such a computer 2, an application program for editing video data is preinstalled in the hard disk drive, and is started as an editing system by operating the application program under the operating system. ing.
This application program includes a GUI (Graphical User Interface) for generating a control command used for editing work. When the application program is started, the GUI is displayed on the monitor 2b. A graphic display for the purpose is displayed.
[0011]
On the other hand, the hybrid recorder 3 includes a hard disk array in which a plurality of hard disks are connected in an array and a VTR provided for backup of the hard disk array, and a source video signal V1 supplied from the outside. The source audio signal A1 is sequentially recorded. The hybrid recorder 3 apparently performs recording and reproduction at the same time. While recording the video signal V1 and the audio signal A1 in real time, the recorded video signal V1 and audio signal A1 in real time. Has been made to play.
[0012]
Of the reproduced video signal V3 and audio signal A2, the video signal V3 is supplied to the main body 2a of the computer 2. The hybrid recorder 3 outputs the input video signal V1 almost as it is, and the output video signal V2 (the signal is substantially the same as the video signal V1) is also the main body 2a of the computer 2. To supply. Incidentally, the video signal V1 input here is a composite video signal photographed by a video camera or the like, or a composite video signal transmitted from a VTR.
[0013]
The computer 2 and the hybrid recorder 3 are connected by a communication cable 4 based on the communication format of the RS-422 interface so that a control command and a response command to the control command can be transmitted via the communication cable 4. Has been made. The RS-422 interface communication format is a communication format capable of simultaneously transmitting / receiving a control command and a response command to the control command.
[0014]
Here, the operation of the editing system 1 will be briefly described. First, a composite video signal V1 photographed by a video camera or the like is input to the hybrid recorder 3 and sequentially recorded. A video signal V2 that is output as it is through the hybrid recorder 3 is input to the computer 2. The computer 2 displays a reduced image corresponding to the video signal V2 on the monitor 2b.
On the other hand, the hybrid recorder 3 encodes the input video signal V1 in real time and records it on the hard disk array and the VTR.
[0015]
An operator who operates the computer 2 operates a pointing device such as a mouse 2d connected to the computer 2 while watching the video signal V2 displayed on the monitor 2b which is a display means. An edit point such as an out point (edit end point) or the like is designated, and a control command for editing is generated using the GUI displayed on the monitor 2b. This control command is transmitted to the hybrid recorder 3 as an RS-422 control command. Thus, the reproduction operation of the hybrid recorder 3 is controlled, and the reproduced video signal V3 is displayed on the monitor 2b of the computer 2 and sent to the outside.
In this manner, in the editing system 1, editing can be easily performed by operating a pointing device such as the mouse 2d while looking at the monitor 2b. In addition, the editing system 1 uses the hybrid recorder 3 that can perform recording and playback operations at almost the same time, so that editing can be performed in real time, and materials such as sports broadcasts and news reports can be created without impairing real-time performance. You can edit it.
[0016]
(2) Internal configuration of the computer
In this section, the internal configuration of the computer 2 will be specifically described. As shown in FIG. 2, the computer 2 includes a system bus 5 for transmitting command data and video data, a CPU 10 for controlling the entire computer, and first and second image processing and the like for input video signals. 2 video processors 11 and 12, a display controller 13 for managing graphic display for video data and GUI displayed on the monitor 2b, an HDD interface 15 for controlling a local hard disk drive (local HDD) 15a, a flow A pointing device that generates a control command based on commands from a pointing device such as an FDD interface 16, a mouse (cursor control device) 2d, a dedicated controller 2e, and a keyboard 2c for controlling the tupee disk drive (FDD) 16a. Chair interferons chair 17, has an external Interferon chair 18 having a software driver for performing data communication based on the communication the format of hybridizing bracts recorder 3 and RS-422.
[0017]
The system bus 5 is a bus for communicating video data, command data, address data, and the like inside the computer 2, and an image data bus 5a for transmitting video data, and for transmitting command data and the like. The command data bus 5b is used.
A CPU 10, first and second video processors 11, 12, a display controller 13, a HDD interface 15 and an FDD interface 16 are connected to the image data bus 5a, respectively. The first and second video processors are connected to the image data bus 5a. The sensors 11 and 12, the display controller 13, the HDD interface 15 and the FDD interface 16 transmit video data via the image data bus 5a.
[0018]
On the other hand, the command data bus 5b includes a CPU 10, first and second video processors 11, 12, a display controller 13, an HDD interface 15, an FDD interface 16, a pointing device interface 17, and an external interface 18. Each is connected (that is, all the blocks inside the computer 2 are connected), and command data and address data are transmitted via the command data bus 5b.
[0019]
The CPU 10 is a block for controlling the entire computer 2, and includes a ROM 10a in which the operating system of the computer 2 is stored, and a RAM 10b in which an uploaded application program is stored. When starting the computer 2, the CPU 10 executes a software program based on the operating system stored in the ROM 10a. When the application program is executed under this operating system, the CPU 10 first reads the application program recorded on the hard disk of the hard disk drive 15a, uploads it to the RAM 10b, and then the application program. Run the program.
[0020]
The first video processor 11 receives the first video signal V2 input to the computer 2, performs data conversion on the first video signal V2, and temporarily converts the converted video data. This is a block for buffering. Specifically, the first video processor 11 includes a processor controller 11a for controlling the entire video processor 11 and data conversion for converting the received analog composite video signal V2 into digital component video data. And a frame memory 11c that temporarily stores video data for several frames sent from the data converter 11b.
[0021]
The processor controller 11a controls the data conversion operation of the data converter 11b by sending a control signal to the data converter 11b, and sends the control signal to the data converter 11b. The unit 11b extracts the time code from the composite video signal V2. The processor controller 11a controls the read / write timing and read / write address of the frame memory 11c by sending a control signal to the frame memory 11c. Incidentally, regarding the read timing, the processor controller 11a controls the read timing of the frame memory 11c so that the time code sent to the display controller 13 and the video data (frame data) correspond to each other.
[0022]
The data converter 11b converts the analog composite video signal V2 into a component video signal based on a control signal from the processor controller 11a, and then converts the analog component video signal into digital video data. The time code is extracted when an analog component video signal is converted into digital video data. The digitally converted video data is sent to the frame memory 11c, and the extracted time code is sent to the processor controller 11a.
[0023]
Here, the time code is encoded and inserted into two lines 14H and 16H or 12H and 14H in the vertical blanking period of the composite video signal V2, and is called a so-called VITC (Vertical Interval Time Code). Therefore, when extracting the time code from the composite video signal V2, it is possible to easily extract it by decoding only the digitally converted time code in the vertical synchronization period when converting the analog signal to digital data. it can. Incidentally, this time code is added when the video signal V2 is output in the hybrid recorder 3.
[0024]
The frame memory 11c temporarily stores video data supplied from the data converter 11b. The read / write timing of the frame memory 11c is controlled by the processor controller 11a as described above. The frame memory 11c is composed of two frame memories and has a total storage capacity of 4 Mbytes. The video data stored in the frame memory 11c is video data composed of 1520 pixels × 960 pixels, and the frame memory 11c can store such video data for two frames.
[0025]
The video data of 1520 pixels × 960 pixels stored in the frame memory 11c is read based on the read control of the processor controller 11a. The video data read from the frame memory 11c is not video data of 1520 pixels × 960 pixels, that is, video data in which the data amount is thinned out to be 380 pixels × 240 pixels. Here, thinning out the data amount simply means that the sampling rate for reading video data from the frame memory 11c is set to ¼ to reduce the amount of video data to be read. The video data of 380 pixels × 240 pixels read out in this way is sent to the display controller 13 via the image data bus 5a.
[0026]
The second video processor 12 has the same configuration as the first video processor. That is, the video processor 12 includes a processor controller 12a that controls the entire video processor 12, a data converter 12b that converts the received analog composite video signal V3 into digital component video data, and a data converter. And a frame memory 12c for temporarily storing video data for several frames sent from 12b. The difference between the first video processor 11 and the second video processor 12 is that the composite video signal V2 is input to the first video processor 11 and the composite is supplied to the second video processor 12. The video signal V3 is input.
[0027]
Here, since the composite video signal V2 is a video signal in which the time code is superimposed in the vertical synchronization period of the input video signal V1 inside the hybrid recorder 3, it is temporally identical to the input video signal V1 inputted in real time. It is a video signal. That is, the video data stored in the frame memory 11c is the same video data as the digitalized input video signal V1.
On the other hand, the composite video signal V3 is a video signal reproduced from the hybrid recorder 3 in response to a command from the computer 2. Therefore, the composite video signal V3 is an asynchronous video signal that is not temporally related to the input video signal V1.
[0028]
This point will be described in detail below. When the operator designates reproduction of desired video data to the computer 2, the computer 2 sends a reproduction command of the video data to the hybrid recorder 3. The hybrid recorder 3 reproduces video data designated by the operator in response to a reproduction command from the computer 2. The hybrid recorder 3 stores a time code corresponding to the video data in units of frames, and reproduces the time code of the reproduced video data based on the correspondence.
The hybrid recorder 3 superimposes the reproduced time code in the vertical synchronization period of the reproduced video data, and converts the resulting video data into an analog composite video signal V3 so that it can be transmitted to the computer 2. This is sent to the computer 2. Since the composite video signal V3 is a video signal reproduced in accordance with an instruction from the operator in this manner, the composite video signal V3 is a signal that is asynchronous in time with the input video signal V1.
[0029]
Similar to the composite video signal V2 supplied to the first video processor 11, the composite video signal V3 supplied to the second video processor 12 is predetermined via the data converter 12b and the frame memory 12c. After being subjected to the signal processing, it is transmitted to the display controller 13 as digital video data of 380 pixels × 240 pixels.
[0030]
The display controller 13 is a control block for controlling data displayed on the monitor 2b. The display controller 13 includes a memory controller 13a and a VRAM (Video Random Access Memory) 13b. The memory controller 13a controls the read / write timing of the VRAM 13b in accordance with the internal synchronization inside the computer 2. In this VRAM 13b, video data from the frame memory 11c of the first video processor 11, video data from the frame memory 12c of the second video processor 12, and image data from the CPU 10 are respectively sent from the memory controller 13a. Is stored based on the timing control signal. The image data stored in the VRAM 13b is read from the VRAM 13b based on the timing control signal from the memory controller 13b based on the internal synchronization of the computer, and is displayed graphically on the monitor 2b. The graphic display displayed on the monitor 2b in this way becomes a graphic display for the GUI. Here, the image data sent from the CPU 10 to the VRAM 13b is, for example, image data such as a window, a cursor, or a scroll bar. By displaying these plural types of image data on the monitor 2b, a graphic display for the GUI can be obtained.
[0031]
The hard disk interface 15 is an interface block for communicating with a local hard disk drive (HDD) 15 a provided in the computer 2. The hard disk interface 15 and the hard disk drive 15a communicate with each other based on a SCSI (Small Computer System Interface) transmission format.
The hard disk drive 15a is installed with an application program to be started by the computer 2, and when the application program is executed, the hard disk drive 15a is read from the hard disk drive 15a and uploaded to the RAM 10b of the CPU 10. When the application program is terminated, the work data file created by the editing operation stored in the RAM 10b is downloaded to the hard disk via the hard disk drive 15a.
[0032]
The Floppy disk interface 16 is an interface block for communicating with a Floppy disk drive (FDD) 16 a provided in the computer 2. The Floppy Disk Interface 16 and the Floppy Disk Drive 16a communicate with each other based on the SCSI transmission format. An EDL (Edition Decision List) indicating the editing result of the editing operation is stored in the Floppy disk via the Floppy disk drive 16a.
[0033]
The pointing device interface 17 is an interface block that receives information from the mouse 2d, the dedicated controller 2e, and the keyboard 2c connected to the computer 2. The pointing device interface 17 receives, for example, detection information of a two-dimensional rotary encoder provided in the mouse 2d and click information of the left and right buttons provided in the mouse 2d from the mouse 2d, and receives the received information. Decode and send to CPU 10. Similarly, the pointing device interface 17 receives information from the dedicated controller 2e and the keyboard 2c, decodes the received information, and sends it to the CPU 10.
[0034]
The external interface 18 is a block for communicating with the hybrid recorder 3 connected to the outside of the computer 2. The external interface 18 has an RS-422 driver that converts command data generated by the CPU 10 into an RS-422 communication protocol, and controls the playback command and the like to the hybrid recorder 3 via the RS-422 driver. Send a command.
[0035]
(3) Graphic display for GUI
(3-1) Picture mode
In the editing system 1, two types of modes are prepared as graphic displays for the GUI. One is the picture mode where the program is edited by rearranging the events while looking at the screen of the in and out points of the registered event, and the other is the time length of the registered event. It is a timeline mode that allows you to adjust the program while looking at it. These two modes can be easily switched by clicking a mode button, which will be described later, and this allows the operator to select the GUI that is easier to use according to the editing purpose, which is convenient for editing work. Can be improved.
[0036]
In this section, the picture mode will be described first. In the case of the picture mode, a graphic display as shown in FIG. 3 is displayed on the monitor 2b. As shown in FIG. 3, the graphic display in the picture mode includes a recording video display area 21, a timing display area 22, a playback video display area 23, a recording video marking area 24, a playback speed setting area 25, and a recycle box. The area 26, the reproduction video marking area 27, the clip display area 28, the event display area 29, and the program display area 30 are divided into 10 areas.
[0037]
The recording video display area 21 includes a recording video screen 21a, a recording start point display unit 21b, a storage capacity remaining time display unit 21c, and a recording display unit 21d. The video signal displayed on the recording video screen 21a is a video signal obtained from the composite video signal V2 output from the hybrid recorder 3, and is thinned out when supplied from the frame memory 11c to the VRAM 13b. This is a video signal whose image size has been changed to 380 pixels × 240 pixels.
In the recording start point display portion 21b, a time code indicating from which point the video signal displayed on the recording video screen 21a is started to be recorded by the hybrid recorder is displayed.
[0038]
The remaining storage capacity time display unit 21c displays the remaining storage capacity of the hybrid recorder 3. The remaining time displayed here can be easily obtained by subtracting the value obtained by subtracting the recording start time from the current time from the recordable time of the hybrid recorder 3 because the total storage capacity of the hybrid recorder 3 is previously determined. Can be requested.
A character string “REC” indicating that the video signal displayed on the recording video screen 21a is currently recorded is displayed on the recording display portion 21d.
[0039]
The timing display area 22 includes a one-minute display unit 22a, a time display unit 22b, an input video signal time code display unit 22c, a playback video signal time code display unit 22d, an on-air display unit 22e, and a mode button 22f. , A pre-roll button 22g and a playback speed setting (DMC: dynamic motion controller) button 22h.
The one-minute meter display unit 22a is an area for counting one minute (or three minutes depending on the menu setting) in seconds and displaying it visually. As the counting progresses, the one-minute meter display unit 22a is configured such that the color of the display unit provided along the outer periphery changes sequentially in units of seconds, which makes it easy for the operator to visually pass the time. Can grasp. For example, when the minute display unit 22a is used to count one minute, for example, the input video side or the playback video side specifies the IN point, counts one minute, and outputs the OUT point. This is used to specify 1 or to count one minute from the start of preview when previewing a created program.
[0040]
The time display unit 22b displays the current time. In the recording video signal time code display portion 22c, the time code of the video signal displayed in the recording video display area 21 is displayed. This time code is a time code extracted from the vertical synchronization period of the composite video signal V2 by the processor controller 11a of the first video processor 11.
The playback video signal time code display unit 22d displays the time code of the video signal displayed in the playback video display area 23. This time code is a time code extracted from the vertical synchronization period of the composite video signal V3 by the processor controller 12a of the second video processor 12.
[0041]
The on-air display unit 22e is a display unit that indicates whether or not the vehicle is on-air. When a tally signal indicating that the vehicle is on-air is supplied from the outside, the display color is changed to red. The tally signal indicating the on-air is a signal supplied when the composite video signal V3 output from the hybrid recorder 3 is on-air. In this way, the display color of the on-air display unit 22e is changed according to the on-air state, so that the operator can easily grasp visually that the air is on-air.
[0042]
The mode button 22f is a button used when switching between the picture mode shown in FIG. 3 and a timeline mode described later. When the mode button 22f is clicked using the mouse 2d, mode switching can be designated, and the display mode can be switched between the picture mode and the timeline mode.
The pre-roll button 22g is a button used when setting the pre-roll mode. A playback speed setting button (DMC) 22h is a button used to set the playback speed of the selected event. The two buttons will be described in detail later.
[0043]
The playback video display area 23 includes a playback video screen 23a, a shuttle button 23b, a jog button 23c, and a playback state display section 23d.
The video signal displayed on the reproduction video screen 23a is a video signal obtained from the composite video signal V3 reproduced by the hybrid recorder 3, and is used for thinning-out processing when supplied from the frame memory 12c to the VRAM 13b. Therefore, the video signal has an image size changed to 380 pixels × 240 pixels.
The shuttle button 23b is a button used when the video data reproduced from the hybrid recorder 3 and displayed on the reproduction video screen 23a is to be fast-forwarded (so-called shuttle feed). When the shuttle button 23b is designated by the operation of the mouse 2d and the shuttle button 23b is dragged in the direction in which video data is desired to be sent, the playback operation of the hybrid recorder 3 can be controlled in accordance with the drag operation.
[0044]
The jog button 23c is a button that is used when the video data reproduced from the hybrid recorder 3 and displayed on the reproduction video screen 23a is frame-advanced. When the video data displayed on the playback video screen 23a is frame-by-frame, click on the jog button 23c in the direction you want to frame-by-frame using the mouse 2d, and the playback video data is frame-framed according to the click operation. be able to.
In the reproduction state display section 23d, a character “PLAY” or “STILL” is displayed according to the state of the video data displayed on the reproduction video screen 23a. Specifically, when the video data displayed on the playback video screen 23a is a moving image played back from the hybrid recorder 3, the characters “PLAY” are displayed, and the video data displayed on the playback video screen 23a is hybridized. When the image is a still image reproduced from the recorder 3, the characters “STILL” are displayed.
[0045]
The recording video marking area 24 is an area used when marking clip image data of the in point or the out point from the video data displayed on the recording video screen 21a. The meaning of “marking” here means that an In point or an Out point is designated, or that an In point or an Out point is set. Further, the “clip image” referred to here is a “still image”. The recorded video marking area 24 includes an increment display area 24a, an in-point time code display section 24b, a mark-in button 24c, an out-clip display area 24d, an out-point time code display section 24e, and a mark-out button. 24f.
[0046]
The clip display area 24a is an area for displaying clip image data marked as an IN point by the operator clicking the mark-in button 24c. The clip image data displayed in the clip display area 24a is image data obtained from the composite video signal V2 output from the hybrid recorder 3, and is an image thinned out to an image size of 95 pixels × 60 pixels. It is data.
The time code display unit 24b displays the time code of the clip image data displayed in the clip display area 24a. This time code is a time code extracted from the composite video signal V2 by the processor controller 11a of the first video processor 11 when the operator clicks the mark-in button 24c to mark the in point.
[0047]
The mark-in button 24c is a button for marking the IN point. The operator clicks the mark-in button 24c while watching the video data displayed on the recorded video screen 21a. When the mark-in button 24c is clicked, clip image data (95 pixels × 60 pixels) corresponding to the video data displayed on the recording video screen 21a at this time is generated, and the generated clip image data is the increment. It is displayed in the display area 24a.
The out clip display area 24d is an area for displaying clip image data of the out point marked by the operator clicking the mark out button 24f. The clip image data displayed in the out clip display area 24d is image data obtained from the composite video signal V2 output from the hybrid recorder 3, and is thinned to an image size of 95 pixels × 60 pixels. Image data.
[0048]
The time code display unit 24e displays the time code of the clip image data displayed in the out clip display area 24d. This time code is the time code extracted from the composite video signal V2 by the processor controller 11a of the first video processor 11 when the operator clicks the markout button 24f to mark the out point.
The markout button 24f is a button for marking an out point. The operator clicks the markout button 24f while watching the video data displayed on the recorded video screen 21a. When the markout button 24f is clicked, clip image data (95 pixels × 60 pixels) corresponding to the video data displayed on the recording video screen 21a at this time is generated, and the generated clip image data is output. It is displayed in the clip display area 24d.
[0049]
The playback speed setting area 25 is an area used when setting the playback speed for the selected event, and the operator sets the playback speed while viewing the information displayed here. The reproduction speed setting area 25 will be described later in detail.
The recycle box 26 is an area used when deleting the generated clip image data. When erasing is performed, the clip image data is designated by the mouse 2d and the clip image data is dragged to the area of the recycle box 26, and the erasure is executed. When restoring the deleted clip image data, if the recycle box 26 is clicked, all of the clip image data discarded in the recycle box 26 is displayed. When the clip image data to be restored is designated from among them, the designated clip image data is restored.
[0050]
The playback video marking area 27 is an area used when marking clipped image data of the In point or Out point from the video data displayed on the playback video screen 23a. The playback video marking area 27 includes an increment display area 27a, an in-point time code display portion 27b, a mark-in button 27c, an out-clip display area 27d, an out-point time code display portion 27e, and a mark-out button. 27f.
The clip display area 27a is an area for displaying clip image data marked as an IN point by the operator clicking the mark-in button 27c. The clip image data displayed in the clip display area 27a is image data obtained from the composite video signal V3 output from the hybrid recorder 3, and is an image thinned out to an image size of 95 pixels × 60 pixels. It is data.
[0051]
The time code display unit 27b displays the time code of the clip image data displayed in the clip display area 27a. This time code is a time code extracted from the composite video signal V3 by the processor controller 12a of the second video processor 12 when the operator clicks the mark-in button 27c to mark the in point.
The mark-in button 27c is a button for marking the IN point. The operator clicks the mark-in button 27c while watching the video data displayed on the playback video screen 23a. When the mark-in button 27c is clicked, clip image data (95 pixels × 60 pixels) corresponding to the video data displayed on the playback video screen 23a at this time is generated, and the generated clip image data is the increment. It is displayed in the display area 27a.
[0052]
The out clip display area 27d is an area for displaying clip image data of an out point marked by the operator clicking the mark out button 27f. The clip image data displayed in the out clip display area 27d is image data obtained from the composite video signal V3 output from the hybrid recorder 3, and is thinned to an image size of 95 pixels × 60 pixels. Image data.
The time code display unit 27e displays the time code of the clip image data displayed in the out clip display area 27d. This time code is the time code extracted from the composite video signal V3 by the processor controller 12a of the second video processor 12 when the operator clicks the markout button 27f to mark the out point.
[0053]
The markout button 27f is a button for marking an out point. The operator clicks the markout button 27f while watching the video data displayed on the playback video screen 23a. When the markout button 27f is clicked, clip image data (95 pixels × 60 pixels) corresponding to the video data displayed on the playback video screen 23a at this time is generated, and the generated clip image data is output. It is displayed in the clip display area 27d.
[0054]
The clip display area 28 includes clip image data marked by clicking the mark-in button 24c or the mark-out button 24f provided in the recording video marking area 24, and the mark-in provided in the reproduction video marking area 27. This is an area for displaying clip image data marked by clicking the button 27c or the markout button 27f. The clip image data displayed in the clip display area 28 is clip image data that is not used as an in point or out point of an event. Clip image data used as an In point or an Out point of an event is displayed in the event display area 29. The clip display area 28 includes a clip image data display area 28a, a time code display portion 28b, a clip type display portion 28c, a clip number display portion 28d, a feed button 28e, and a return button 28f.
[0055]
The clip image data display area 28a is clip image data moved from any one of the recording side display area 24a or the out clip display area 24d or the reproduction side clip display area 27a or the out clip display area 27d. Therefore, the image data has an image size of 95 pixels × 60 pixels.
The time code display unit 28b displays the time code of the clip image data displayed in the clip image data display area 28a. This time code is similarly moved when the clip image data is moved from the display area 24a, the clip display area 24d, the clip display area 27a, or the clip display area 27d to the clip image data display area 28a. Is done.
[0056]
In the clip type display section 28c, data indicating whether the clip image data displayed in the clip image data display area 28a is the clip image data of the in point or the out point is displayed. For example, if the clip image data displayed in the clip image data display area 28a is clip image data obtained from the clip display area 24a, a red “IN” character is displayed. If the clip image data displayed in the clip image data display area 28a is clip image data obtained from the out clip display area 24d, a red color “OUT” is displayed. If the clip image data displayed in the clip image data display area 28a is clip image data obtained from the clip display area 27a, a blue color “IN” is displayed. If the clip image data displayed in the clip image data display area 28a is clip image data obtained from the out clip display area 27d, a blue color “OUT” is displayed.
[0057]
In the clip number display portion 28d, the clip number assigned to the clip image data displayed in the clip image data display area 28a is displayed. The clip number is a number automatically assigned to the clip image data in the order in which the clip image data is marked.
The forward button 28e and the return button 28f are buttons used when the display of clip image data in the clip display area 28 is advanced or returned backward. When a large number of clip image data is generated, the size of the clip display area 28 is finite, so that all the clip image data cannot be displayed simultaneously. At that time, all the clip image data can be displayed on the monitor by operating the forward button 28e and the return button 28f to advance the clip image data forward or backward.
[0058]
The event display area 29 is provided in the clip image data of the event generated by sequentially clicking the mark-in button 24c and the mark-out button 24f provided in the recording video marking area 24, and the reproduction video marking area 27. This is an area for displaying clip image data of an event generated by clicking the mark-in button 27c and the mark-out button 27f in order. For one event, clip image data of either in-point clip image data or out-point clip image data is displayed. Similar to the clip display area 28, the event display area 29 is a clip image data display area 29a, a time code display portion 29b, a clip type display portion 29c, an event number display portion 29d, a feed button 29e, and a return button. 29f and an event title display section 29g.
[0059]
In the clip type display section 29c, data indicating whether the clip image data of the event displayed in the clip image data display area 29a is the clip image data of the In point or the Out point is displayed. When IN-point clip image data is displayed as the clip image data of an event, the characters “IN” are displayed on the clip type display portion. When it is desired to display the clip image data at the out point instead of the clip image data at the in point, clicking the clip type display portion 29c displays the clip image data at the out point. Thereafter, every time the clip type display section 29c is clicked, the display of the clip image data at the in-point and the clip image data at the out-point is alternately switched.
[0060]
In the event number display section 29d, an event number assigned to the generated event is displayed. This event number is a number that is automatically assigned to the event in the order in which the event was generated, and has nothing to do with the clip number.
In the event title display section 29g, the title attached to the event is displayed in a crisp character. This title can be registered by the title menu and can be registered for each event.
[0061]
The program display area 30 is an area used to create a program by copying the event displayed in the event display area 29. A copy of the clip image data of the event displayed in the event display area 29 is displayed. It is made to be done. When creating a program by rearranging events, the clip image data of the event displayed in the event display area 29 is first dragged and copied to the program display area 30. As a result, it is possible to create a program by freely rearranging the events displayed in the event display area 29. At this time, by dragging the clip image data of the event displayed in the program display area 30 and moving it again to another place in the program display area 30, the events can be rearranged freely in the program display area 30 as well. be able to. In this case, the event is moved and not copied.
Similar to the event display area 29, the program display area 30 includes a clip image data display area 30a, a time code display unit 30b, a clip type display unit 30c, an event number display unit 30d, and a feed button 30e. , A return button 30f and an event title display section 30g. Since these are the same as those in the event display area 29, description thereof is omitted here.
[0062]
The recording start button 31 a and the recording end button 31 b are buttons for sending control commands for recording start and recording end to the hybrid recorder 3. When the recording start button 31a is clicked, the CPU 10 detects that the recording start button 31a has been pressed, and instructs the external interface 18 to output a recording start command. The external interface 18 receives this command and sends a recording start command (REC START command) defined by RS-422 to the hybrid recorder 3. The hybrid recorder 3 starts recording the video signal V1 on the hard disk and the VTR in response to the received recording start command.
On the other hand, when the recording end button 31b is clicked, the CPU 10 detects that the recording end button 31b has been pressed, and instructs the external interface 18 to output a recording end command. In response to this command, the external interface 18 sends a recording end command (REC STOP command) defined by RS-422 to the hybrid recorder 3. The hybrid recorder 3 ends the recording of the video signal V1 on the hard disk and the VTR in response to the received recording end command.
[0063]
The preview button 32 is a button used when previewing a selected event or program (so-called content confirmation). When an event or program is specified, clip image data of the specified event or program is displayed on the playback video screen 23a in a still image (STILL) state. When the preview button 32 is clicked at this time, the CPU 10 detects that the preview button 32 has been pressed, and instructs the external interface 18 to output a playback start command. Upon receiving this command, the external interface 18 sends a playback start command (PLAY START command) defined by RS-422 to the hybrid recorder 3. The hybrid recorder 3 starts to reproduce the composite video signal V3 from the hard disk (or VTR) in response to the received reproduction start command.
[0064]
The new event button 33 is a button used when creating a new event. The new event button 33 is clicked when an event whose IN point and OUT point have been changed is registered as another new event with respect to the event designated by the operator.
The replace button 34 is a button used when it is desired to change the In point and Out point of the selected event. The replace button 34 is clicked when an event in which the In point and the Out point have been changed is replaced with the designated event instead of as another new event with respect to the event designated by the operator.
The delete button 35 is a button used when deleting a selected event or program. The deleted event or program is discarded in the recycle box 26.
[0065]
(3-2) Timeline mode
Next, in this section, the timeline mode will be described. In the timeline mode, a graphic display as shown in FIG. 4 is displayed on the monitor 2b. As shown in FIG. 4, the graphic display in the timeline mode includes a recording video display area 21, a timing display area 22, a playback video display area 23, a recording video marking area 24, a playback speed setting area 25, The recycle box area 26, the playback video marking area 27, the event display area 29, the timeline display area 40, the edit tool display section 41, and the program view area 42 are divided into 11 areas.
The recording video display area 21, timing display area 22, playback video display area 23, recording video marking area 24, playback speed setting area 25, recycle box area 26, playback video marking area 27, and event display area 29 are shown in FIG. It is the same as that in the picture mode shown in.
[0066]
The timeline display area 40 is a display area where the program can be edited while checking the time length of each event. As shown in FIG. 5, the timeline display area includes a time scale display section 40a, an action display area 40b, a GPI area 40c, a video editing area 40d, and first and second audio editing areas 40e and 40f. And scroll buttons 40g and 40h and an edit bar 40i.
[0067]
A time scale (hereinafter referred to as a time scale) is displayed on the time scale display section 40a, and the time length of each event is clearly shown on the basis of this time scale. This time scale is a frame unit scale, and the minimum unit of the scale is set to an arbitrary number of frames by user setting.
[0068]
The action display area 40b is an area for designating a position where the operation is stopped when a program or event is previewed or transmitted. The stop position can be set to an arbitrary position regardless of the IN point and OUT point. Further, a stop flag 40ba is displayed at the designated position as shown in the figure, so that the operator can easily confirm the designated position. By specifying the stop position in the action display area 40b in this way, it is possible to preview or send a program or event for an arbitrary section. In order to validate the stop position specified by the action display area 40b, the action button 40bc may be clicked.
[0069]
The GPI area 40c is an area for designating an output point of a control command of GPI (General Purpose Interface: a general-purpose interface for outputting a control command from an editing apparatus to control an external device). The GPI output point can be set at an arbitrary position regardless of the IN point or OUT point. A mark 40ca is displayed at the position of the GPI output point, so that the operator can easily confirm the position designated by the operator. By specifying the GPI output point in the GPI area 40c in this way, it is possible to control the external device by outputting a control command at the specified output point. In order to validate the GPI output point designated by the GPI area 40c, the GPI button 40cb may be clicked.
[0070]
The video editing area 40d is an area for editing the program by rearranging the events dragged from the event display area 29. Events displayed in the video editing area 40d are events dragged from the event display area 29 or events arranged in the picture display area 30 in the picture mode called by the program call button in the program view area 42 described later. It is. In the video editing area 40d, the clip image data of the event in and out points is not displayed as in the picture mode, but the event number and the title attached to the event are displayed. However, the size of the display area of each event is made different depending on the length of the event, so that the length of the event is visually compared with the time scale of the time scale display unit 40a. It has become possible to confirm. In addition, since the length of each event can be visually confirmed, the length of the entire edited program can also be visually confirmed. Therefore, it is possible to easily confirm whether or not the edited program is within a desired length.
[0071]
In the video editing area 40d, each event can be moved to an arbitrary position, and an arbitrary event can be interrupted into another event, thereby rearranging the events in an arbitrary order. Thus, a program in a desired order can be generated. By the way, when an event is moved or interrupted, it is connected so that there is no gap between events.
The event move destination and interrupt destination are designated by the edit bar 40i which is a reference position mark. The edit bar 40i is fixedly displayed at substantially the center position of the screen, and when the movement destination or interrupt destination is designated, the event display is scrolled so that the candidate position of the movement destination or interrupt destination is matched with the edit bar 40i. . Thereby, the position is designated as a movement destination or an interruption destination.
When an operation is performed on the video editing area 40d, the video editing area 40d can be made operable by clicking the video button 40db.
[0072]
The first and second audio editing areas 40e and 40f are areas for editing the audio data of each event. When the audio data is taken into the first and second audio editing areas 40e and 40f, the audio data of the event is taken by dragging the event from the event display area 29 after clicking the audio buttons 40ea and 40fa. Can do.
An event number and a title attached to the event are displayed for the captured audio data.
In the first and second audio editing areas 40e and 40f, as in the video editing area 40d, the audio data of each event is moved to an arbitrary position, or the audio data of an arbitrary event is transferred to other events. You can interrupt the audio data. Similarly, the position designation at this time may be achieved by scrolling the audio data so that the candidate position of the movement destination or interruption destination is matched with the edit bar 40i.
The difference between the first and second audio editing areas 40e and 40f is only the difference between the right side and the left side of the stereo output.
[0073]
The scroll buttons 40g and 40h are buttons operated when scrolling the entire section from the action display area 40b to the second audio editing area 40f in the right or left direction as a whole. When the button in the direction to be sent is clicked among the scroll buttons 40g and 40h, scrolling is executed in that direction.
The scroll buttons 40g and 40h include buttons 40ga and 40ha for executing scrolling in units of time scales displayed on the time scale display unit 40a, buttons 40gb and 40hb for executing scrolling in units of frames, and seconds. Buttons 40gc and 40hc for executing scrolling in units, buttons 40gd and 40hd for executing scrolling in units of time, and buttons 40ge and 40he for executing scrolling in units of in points.
[0074]
Here, returning to FIG. 4 again, the timeline mode will be described. The edit tool display section 41 displayed below the timeline display area 40 is a command button for instructing commands used for program editing in the timeline display area 40. The edit tool display unit 41 includes an action tool button 41a, a single event movement tool button 41b, a track tool button 41c, a ripple edit tool button 41d, an overlay tool button 41e, and a clear tool button 41f. It is composed.
[0075]
The action tool button 41a is a button operated when setting the stop flag 40ba in the action display area 40b of the timeline display area 40 described above. When the stop flag 40ba is set, the scroll button 40g or 40h is operated to scroll the event, and the position where the stop flag 40ba is to be set is adjusted to the edit bar 40i. Thereafter, when the action tool button 41a is clicked, the stop flag 40ba is set at the edit bar 40i, and the stop flag 40ba is displayed at that position.
[0076]
The single event moving tool button 41b is a button used when selecting one event in the video editing area 40d or audio data in the audio editing areas 40e and 40f and moving the selected one. For example, when an event in the video editing area 40d is moved, the video button 40db in the video editing area 40d is first clicked, and then the event is scrolled so that the destination is moved to the edit bar 40i. Next, after clicking the single event moving tool button 41b, the event to be moved is clicked. As a result, the clicked event moves to the position of the edit bar 40i.
[0077]
The track tool button 41c is a button used when selecting an event in the video editing area 40d or audio data in the audio editing areas 40e and 40f and moving all of the selected items together. The operation when moving the event using the track tool button 41c is basically performed by clicking the video button 40db or the audio buttons 40ea, fa, and then moving the destination to the edit bar 40i, and then the track tool button. 41c, the event to be moved may be clicked in order.
[0078]
The ripple editing tool button 41d is used to select an event in the video editing area 40d or audio data in the audio editing areas 40e and 40f, and move the selected one to a desired position in another event to be interrupted. It is a button to do.
The overlay tool button 41e is used to select an event in the video editing area 40d or audio data in the audio editing areas 40e and 40f, and move the selected one to another event to overwrite it. is there.
These operation procedures are basically the same as those of the single event moving tool button 41b and the like.
The clear tool button 41f is a button used when selecting an event in the video editing area 40d or audio data in the audio editing areas 40e and 40f and deleting it, or canceling the setting of the stop flag 40ba or the like. When the clear tool button 41f is used to delete or cancel the setting, after the clear tool button 41f is clicked, the deletion target or the setting cancel target may be clicked.
[0079]
Next, the program view area 42 displayed below the timeline display area 40 will be described. In the timeline display area 40, the length of the event display area is basically changed according to the length of each event, thereby making it easy to visually understand the length of each event. However, since the clip image data of each event is not displayed, it may be difficult to understand what kind of image each event is. Therefore, in the case of the editing system 1, by providing the program view area 42, it is possible to easily understand what kind of image each event is even in the timeline mode.
[0080]
The program view area 42 has a view area 42a, a program call button 42b, a send button 42c, and a return button 42d.
The view area 42a is an area for displaying clip image data at the IN point or OUT point of each event. The order of the clip image data displayed in the view area 42a matches the order of the events of the program created in the timeline display area 40. As a result, the sequence of events of the program created in the timeline display area 40 can be easily confirmed based on the clip image data, and the image sequence of the program can be easily confirmed. . Incidentally, each clip image data displayed in the view area 42 a is image data generated by thinning out the clip image data in the event display area 29, and the image size is displayed in the event display area 29. It is about half the size of the clip image data.
[0081]
The program call button 42b is a button used when inputting a program call instruction for calling an event displayed in the program display area 30 in the picture mode to the timeline display area 40 and the view area 42a. When the program call button 42b is clicked, a program call is instructed, and the events displayed in the program display area 30 in the picture mode can be called into the timeline display area 40 without changing the arrangement order. Similarly, the clip image data in the same order as the program display area 30 is called up and displayed in the view area 42a. As described above, the program call button 42b is provided so that the program can be called, so that the program generated in the other mode can be easily called to the timeline mode, and the program generated in the other mode can be called. However, it is possible to easily perform time adjustment.
[0082]
The feed button 42c and the return button 42d are buttons used to advance or return the display of clip image data in the view area 42a. When the created program consists of a plurality of events, all clip image data cannot be displayed in the view area 42a. In such a case, all the clip image data can be displayed by operating the forward button 42c or the return button 42d and moving the clip image data forward or backward.
[0083]
(4) Clip image data management method
Next, a method for storing clip data, event data, and program data will be described. However, the clip data referred to here includes data for displaying the clip image data in the clip display area 28 and data for storing the clip image data. The same applies to event data and program data.
[0084]
First, the first management record data for clip data, event data, and program data will be described with reference to FIG.
One first management record data is provided for each of clip data, event data, and program data. That is, the first management record data for clip data is data for managing all clip image data displayed in the clip display area 28. The first management record data for event data is data for managing all clip image data displayed in the event display area 29. The first management record data for program data is data for managing all clip image data displayed in the program display area 30. In this embodiment, the first management record data has only one first management record data for clip data, event data, and program data.
[0085]
The first management record data includes a pointer to previously linked data, a pointer to linked data, a display horizontal size for one page, a display vertical size for one page, a screen It has data on the upper display position, the display head position, and the total number of links.
The pointer to previously linked data is data for indicating a pointer of management record data linked before the first management record data. If there is no previously linked management record data, its own pointer is stored.
The pointer to data linked later is data indicating the pointer of management record data linked after the first management record data. If there is no management record data linked later, its own pointer is stored.
[0086]
The display horizontal size for one page is data indicating the maximum display number of clip image data displayed in the horizontal direction in each of the clip display area 28, the event display area 29, and the program display area 30. In this embodiment, since the clip display area 28, the event display area 29, and the program display area 30 can display 11 clip image data, "11" is displayed as the display horizontal size for one page. The indicated data is stored in each first management record data.
[0087]
The display vertical size for one page is data indicating the maximum display number of clip image data displayed in the vertical direction in each of the clip display area 28, the event display area 29, and the program display area 30. In this embodiment, the clip display area 28, the event display area 29, and the program display area 30 all display only one clip image data, so that data indicating “one” as the display vertical size for one page is displayed. Is stored in the first management record data.
[0088]
The display position on the screen is data for indicating in which display area the clip image data is displayed. In this embodiment, a clip display area 28 is provided in the lower part of the screen, an event display area 29 is provided in the middle part of the screen, and a program display area 30 is provided in the upper part of the screen. Therefore, if the first management record data for clip data, data indicating “lower” is stored as the display position on the screen, and if the first management record data for event data, the display position on the screen is “ Data indicating “middle stage” is stored, and if it is the first management record data for program data, data indicating “upper stage” is stored as a display position on the screen.
[0089]
The display head position is data for indicating from which position the display of clip image data is started in each display area of the clip display area 28, the event display area 29, and the program display area 30. In this embodiment, eleven clip image data are displayed in the clip display area 28, eleven clip image data are displayed in the event display area 29, and eleven clip image data are displayed in the program display area 30, respectively. The clip image data can be displayed. A total of 33 display positions are numbered in order from the upper stage on the screen to manage the display positions. For example, the display position of the program display area 30 is the display position of the numbers “1” to “11”, the display position of the event display area 29 is the display position of the numbers “12” to “22”, and the display position of the clip display area 28 is the number. The display positions of “23” to “33” are determined. Therefore, if it is the first management record data for clip data, data indicating “23” is stored as the head of the display position. If it is the first management record data for event data, “12” is displayed as the head of the display position. In the case of the first management record data for program data, data indicating “1” is stored as the display head position.
The total number of links is data indicating the total number of management record data linked after the first management record data.
[0090]
Next, the second management record data for clip data will be described with reference to FIG. The second management record data for clip data is data for managing the clip image data displayed in the clip display area 28 for each clip image data. Therefore, the same number of second management record data for clip data as the number of clip image data displayed in the clip display area 28 exists.
The second management record data for clip data includes a pointer to the previously linked data, a pointer to the later linked data, an attribute, a clip image data handle, a clip type, and a time code. Data and the index number of the clip image data.
[0091]
The pointer to previously linked data is data indicating a pointer of management record data linked before the second management record data. Since the first management record data or the second management record data always exists in the second management record data, the pointer of the data linked before is always stored.
The pointer to the data linked later is data indicating the pointer of the management record data linked after the second management record data. If there is no management record data linked later, its own pointer is stored.
[0092]
The attribute is data indicating whether the second management record data is for clip data, event data, or program data.
The clip image data handle is data indicating an address where the clip image data is stored. Therefore, by referring to the clip image data handle in the second management record data corresponding to the desired clip image data, the address where the clip image data is stored can be obtained.
The clip type is data indicating whether the clip image data managed by the second management record data is in-point clip image data or out-point clip image data.
[0093]
The time code data is data indicating the time code of the clip image data managed by the second management record data.
The index number of the clip image data is an index number assigned to the clip image data. This index number is a number assigned in order to all the clip image data marked regardless of the generation of the IN point, OUT point, and event. That is, it is the same number as the clip number displayed on the clip number display portion 28d. All clip image data is managed by this index number.
[0094]
Next, the second management record data for event data and program data will be described with reference to FIG. The second management record data for event data is data for managing clip image data displayed in the event display area 29 for each clip image data. Therefore, the same number of second management record data for event data as the number of clip image data displayed in the event display area 29 exists. Similarly, the second management record data for program data is data for managing clip image data displayed in the program display area 30 for each clip image data. Accordingly, the same number of second management record data for program data as the number of clip image data displayed in the program display area 30 exists.
[0095]
The second management record data for event data and program data includes a pointer to previously linked data, a pointer to linked data, an attribute, an event number, a title, and a subtitle. In-point clip image data handle, In-point clip type, In-point timecode data, In-point clip image data index number, Out-point clip image data handle, Out-point clip It has a type, out point time code data, out point clip image data index number, slow type, symbol type, and symbol time code data.
[0096]
Since the pointer to the data linked before, the pointer to the data linked later and the attribute are the same as the second management record data for clip data described above, the description is omitted here. .
The event number is a number assigned to the event in the order of generation. This event number is displayed in the event number display part 29d.
A title and a subtitle are a title and a subtitle given in advance to a registered event, and are stored as actual characters. Of these, the title is displayed in the title display section 29g.
[0097]
The in-point clip image data handle is data indicating an address at which the in-point clip image data is stored. Accordingly, by referring to the clip image data handle of the in point in the second management record data corresponding to the clip image data of the desired in point, the address where the clip image data of the in point is stored is obtained. Can do.
The in-point clip type is data indicating whether the in-point clip image data managed by the second management record data is the in-point clip image data or the out-point clip image data. It is. Here, since all are clip image data of the IN point, data indicating the IN point is stored.
The in-point time code data is data indicating the time code of the in-point clipped image data managed by the second management record data.
The index number of the IN-point clipped image data is an index number assigned to the IN-point clipped image data. Similar to the index number in the second management record data for the clip data described above, the index number of the clip image data at the in-point is marked regardless of the generation of the in-point, the out-point, and the event. This is a number assigned to all clip image data in order.
[0098]
The out-point clipped image data handle is data indicating an address at which the out-point clipped image data is stored. Accordingly, by referring to the clip image data handle of the out point in the second management record data corresponding to the clip image data of the desired out point, the address where the clip image data of the out point is stored is obtained. Can do.
The out-point clip type is data indicating whether the out-point clip image data managed by the second management record data is the in-point clip image data or the out-point clip image data. It is. Here, since all the clip image data is the out point, data indicating the out point is stored.
The out-point time code data is data indicating the time code of the out-point clipped image data managed by the second management record data.
The index number of the out-point clipped image data is an index number assigned to the out-point clipped image data. Similar to the index number in the second management record data for clip data described above, the index number of this out-point clip image data is marked regardless of the generation of the in-point, out-point and event. This is a number assigned to all clip image data in order.
[0099]
The slow type is data indicating whether an event or program managed by the second management record data is controlled at the playback speed using the playback speed setting area 25 or at a normal playback speed.
The symbol type is data indicating whether or not there is clip image data defined as a symbol in the period of the In point and Out point of the event managed by the second management record data. The symbol mentioned here means typical clip image data for representing the event.
The symbol time code data is a time code of clip image data set as a symbol.
[0100]
Next, how the clip image data is managed using the first management record data and the second management record data described above will be described with reference to specific examples shown in FIGS. .
First, the “marking” line shown in FIG. 9 indicates whether the marking is performed at the In point or the Out point. In this example, it means that marking is performed 15 times in order from the left, IN, IN, OUT, IN, OUT, IN, IN, IN, OUT, IN, OUT, IN, IN, IN, IN. The “index number (INDEX NO.)” Line indicates the index number assigned to the clipped image data of the marked in and out points. This index number is a number assigned to all the clipped image data marked in order regardless of the IN point and OUT point. Accordingly, as shown in FIG. 9, index numbers “1” to “15” are sequentially assigned to the marked clip image data.
In the row of “clip number (clip NO.)”, The clip number displayed in the clip number display area 28d of the clip display area 28 is shown. The clip number displayed in the clip number display area 28d is the same number as the index number.
In the row of “event number (event No.)”, the event number displayed in the event number display area 29d of the event display area 29 is shown. This event number is a number that is automatically assigned in the order of event generation, regardless of the index number and clip number.
[0101]
FIG. 10 is a diagram showing which clip image data is displayed in the clip display area 28, the event display area 29, and the program display area 30 when marking is performed as shown in FIG.
In the clip display area 28, the clip image data with the index number “1”, the clip image data with the index number “6”, the clip image data with the index number “7”, the clip image data with the index number “12”, and the index number “ The clip image data of “13” and the clip image data of index number “14” are displayed in order.
[0102]
In the event display area 29, the four created events are displayed. That is, clip image data with index number “2” is displayed as an event with event number “1”, clip image data with index number “4” is displayed as an event with event number “2”, and event with event number “3” is displayed. The clip image data with the index number “8” is displayed, and the clip image data with the index number “10” is sequentially displayed as the event with the event number “4”.
[0103]
In the program display area 30, clip image data is not displayed only by specifying the IN point and OUT point. In this example, it is assumed that a program as shown in FIG. 10 is created by exchanging four events displayed in the event display area 29. The program is an event number “2” event, an event number “4” event, and an event number “1” event in order. Therefore, in the program display area 30, clip image data with index number “4” registered as an event with event number “2”, clip image data with index number “10” registered with event number “4”, and event The clip image data with the index number “2” registered as the number “1” is displayed.
[0104]
FIG. 11 is a diagram showing how clip image data is managed by the first management record data and the second management record data.
FIG. 11C shows how clip image data displayed in the clip display area 28 is managed. Management record data 101 is first management record data for clip data. As shown in FIG. 6, the first management record data 101 for clip data is data for managing the entire area of the clip display area 28 and the position of the clip image data displayed in the clip display area 28. have.
[0105]
Management record data 201 linked after the first management record data 101 is second management record data for clip data. The second management record data 201 is data for managing clip image data with the index number “1”. As shown in FIG. 7, the second management record data 201 has a clip image data handle indicating the address where the clip image data with the index number “1” is stored.
[0106]
Management record data 206 linked after the second management record data 201 is second management record data for clip data. The second management record data 206 is data for managing clip image data with the index number “6”, and a clip image data handle indicating an address where the clip image data with the index number “6” is stored. Have.
[0107]
Similarly, second management record data 207 for managing clip image data with an index number “7” is linked after the second management record data 206, and after the second management record data 207, The second management record data 212 for managing the clip image data with the index number “12” is linked. After the second management record data 212, the clip image data with the index number “13” is managed. The second management record data 213 is linked, and the second management record data 214 for managing the clip image data having the index number “14” is linked after the second management record data 213.
[0108]
FIG. 11B shows how clip image data displayed in the event display area 29 is managed. The management record data 102 is first management record data for event data. As shown in FIG. 6, the first management record data 102 includes data for managing the entire area of the event display area 29 and the position of clip image data displayed in the event display area 29. Yes.
Management record data 202 linked after the first management record data 102 is second management record data for event data. As shown in FIG. 8, the second management record data 202 includes an in-point clip image data indicated by an index number “2” and an out-point clip image data indicated by an index number “3”. Has data to manage. Specifically, the second management record data 202 includes an in-point clip image data handle indicating an address where the in-point clip image data indicated by the index number “2” is stored, and an index number “3”. And an out-point clip image data handle indicating an address where the out-point clip image data is stored.
[0109]
Similarly, after the second management record data 202, the second management record data for managing the clip image data of the in-point with the index number “4” and the clip image data of the out-point with the index number “5”. 204 is linked, and the second management record data 204 is followed by a second management for managing the clip image data of the in-point with the index number “8” and the clip image data of the out-point with the index number “9”. Record data 208 is linked, and the second management record data 208 is followed by a second for managing clip image data at the in-point with the index number “10” and clip image data at the out-point with the index number “11”. Management record Data 210 is linked.
[0110]
FIG. 11A shows how clip image data displayed in the program display area 30 is managed. The management record data 103 is first management record data for program data. As shown in FIG. 6, the first management record data 103 includes data for managing the entire area of the program display area 30 and the position of clip image data displayed in the program display area 30. Yes.
[0111]
After the first management record data 103 for program data, a second management record for managing the clip image data at the in-point with the index number “4” and the clip image data at the out-point with the index number “5”. Data 204 is linked, and the second management record data 204 is followed by a second management image data for managing the clip image data of the in-point with the index number “10” and the clip image data of the out-point with the index number “11”. Management record data 210 is linked, and after the second management record data 210, the clip image data of the in-point with the index number “2” and the clip image data of the out-point with the index number “3” are managed. 2 management men Record data 202 is linked.
[0112]
Here, FIG. 11B showing the management of event data is compared with FIG. 11A showing the management of program data. The clip image data with the index number “2”, the clip image data with the index number “4”, and the clip image data with the index number “10” are stored in the order of FIG. 11B and FIG. There has been no change between. That is, this means that the storage position of the clip image data is not changed at all. The difference between FIG. 11B and FIG. 11A is that the link order of the second management record data is changed. In other words, in this editing system 1, when changing the display order of events, the storage order of clip image data representing events is not changed, but the link order of second management record data that directly manages clip image data. To change. As a result, the editing system 1 has a special effect when the display order of events can be changed at high speed.
[0113]
Further, the display order of clip image data displayed in the clip display area 28 is not limited to changing the display order of events, and the same is true for changing the display order of clip image data. For example, even if the clip image data is deleted or newly added to change the display order of the clip image data, the second management record data is not actually moved, but the clip image data storage position is not moved. The display order can be easily changed by simply changing the link order by correcting the link information (that is, the pointer portion to the data linked before and after).
[0114]
Next, the marking operation from the first marking to the 15th marking will be specifically described below including the movement of each circuit block.
First, before starting the marking, the first management record data 101 for clip data and the first management for event data are already present at the start address of the area for storing work data secured in the RAM 10b. Record data 102 and first management record data 103 for program data are generated. However, since there is no second management record data to which any of the first management record data is linked, its own address is stored in “pointer to data linked later”.
[0115]
[First marking (In point)]
When the first marking is performed, the clip image data of 95 pixels × 60 pixels is formed by controlling reading from the frame memory 11c. The formed clip image data is stored in the empty area of the RAM 10b as clip image data with the index number “1”. Simultaneously with this storage, the formed clip image data is displayed in the clip display area 24a. At this time, the second management record data 201 for managing the clip image data is temporarily stored in a register in the CPU 10 and is not stored in the RAM 10b. This is because at this time, it is unclear to which management record data the second management record data 201 is linked.
[0116]
[Second marking (In point)]
When the second marking is performed, the clip image data with the index number “2” is similarly formed and stored in the empty area of the RAM 10b. At this time, since the IN point is marked twice, the clip image data with the index number “1” displayed in the clip display area 24a is not used as an event. Accordingly, the clip image data having the index number “1” displayed in the clip display area 24 a is moved to the clip display area 28. Further, by this second marking, it is determined that the second management record data 201 for managing the clip image data with the index number “1” is linked to the first management record data 101 for clip data. Therefore, as shown in FIG. 11C, the second management record data 201 temporarily stored in the register of the CPU 10 is stored in the RAM 10b so as to be linked to the first management record data 101. Is done.
[0117]
On the other hand, the clip image data with the index number “2” generated by the second marking is newly displayed in the clip display area 24a in place of the clip image data with the index number “1”. Similar to the first marking, the second management record data 202 for managing the clip image data with the index number “2” is newly temporarily stored in a register in the CPU 10.
[0118]
[3rd marking (out point)]
When the third marking is performed, the clip image data having the index number “3” is similarly formed and stored in the empty area of the RAM 10b. Since the third marking is an out point, an event is formed in which the clip image data with the index number “2” is the in point and the clip image data with the index number “3” is the out point. Therefore, the clip image data with the index number “2” displayed in the increment display area 24a is copied to the event display area 29 while being displayed in the increment display area 24a. Further, by this third marking, it is determined that the second management record data 202 for managing the clip image data with the index number “2” stored in the register is linked to the first management record data 102 for event data. Is done. Therefore, as shown in FIG. 11B, the second management record data 202 temporarily stored in the register of the CPU 10 is stored in the RAM 10b so as to be linked to the first management record data 102. The
[0119]
On the other hand, the clip image data with the index number “3” generated by the third marking is newly displayed in the out clip display area 24d. Since the second management record data 202 for managing the clip image data with the index number “3” is determined to be linked to the first management record data 102, it is not stored in the register in the CPU 10. .
[0120]
[Fourth marking (in point)]
When the fourth marking is performed, the clip image data with the index number “4” is similarly formed and stored in the empty area of the RAM 10b. Simultaneously with this storage, the formed clip image data is displayed in the clip display area 24a. Similarly to the first marking, the second management record data 204 for managing the clip image data with the index number “4” is temporarily stored in a register in the CPU 10. Note that the clip image data of the index number “3” displayed in the out clip display area 24d has already been stored, and is thus cleared from the out clip display area 24d.
[0121]
[Fifth marking (out point)]
When the fifth marking is performed, the clip image data with the index number “5” is similarly formed and stored in the empty area of the RAM 10b. As with the third marking, since the fifth marking is an out point, there is an event in which the clip image data with the index number “4” is the in point and the clip image data with the index number “5” is the out point. It is formed. Accordingly, the clip image data with the index number “4” displayed in the increment display area 24a is copied to the event display area 29 while being displayed in the increment display area 24a. Further, by this fifth marking, it is determined that the second management record data 204 for managing the clip image data of the index number “4” stored in the register is linked to the previously stored second management record data 202. Is done. Therefore, as shown in FIG. 11B, the second management record data 204 temporarily stored in the register of the CPU 10 is stored in the RAM 10b so as to be linked to the second management record data 202. The
[0122]
On the other hand, the clip image data of the index number “5” generated by the fifth marking is newly displayed in the out clip display area 24d. Since the second management record data 204 for managing the clip image data with the index number “5” is determined to be linked to the second management record data 202, it is not stored in a register in the CPU 10. .
[0123]
[6th marking (in point)]
When the 6th marking is performed, the clip image data with the index number “6” is similarly formed and stored in the empty area of the RAM 10b. Simultaneously with this storage, the formed clip image data with the index number “6” is displayed in the clip display area 24a. Similarly to the fourth marking, the second management record data 206 for managing the clip image data with the index number “6” is temporarily stored in a register in the CPU 10. Note that the clip image data of the index number “5” displayed in the out clip display area 24d has already been stored, and is thus cleared from the out clip display area 24d.
[0124]
[Seventh marking (in point)]
When the seventh marking is performed, the clip image data with the index number “7” is similarly formed and stored in the empty area of the RAM 10b. In this case, since the IN point is marked twice in succession, the clip image data with the index number “6” displayed in the clip display area 24 a is moved to the clip display area 28. As a result of this seventh marking, the second management record data 206 stored in the register of the CPU 10 is linked to the second management record data 201 as shown in FIG. Is remembered.
On the other hand, the formed clip image data with the index number “7” is displayed in the clip display area 24a. Similarly to the sixth marking, the second management record data 207 for managing the clip image data with the index number “7” is temporarily stored in a register in the CPU 10. Hereinafter, since the 9th to 15th markings are performed in the same manner as the 1st to 7th markings, the description is omitted here.
[0125]
(5) Configuration of hybrid recorder
Next, the hybrid recorder 3 will be described with reference to FIG. As shown in FIG. 12, the hybrid recorder 3 has a hard disk drive (HDD) 300 that can perform recording and playback of the input video signal V1 at substantially the same time, and recording and playback to the hard disk drive 300. And a video tape recorder (VTR) 301 for backing up video, so that, for example, a video at a decisive moment can be reproduced while always recording video during sports broadcasting, and recorded on the hard disk drive 300. Alternatively, even if a playback error occurs, the video tape recorder 301 backup allows the recording and playback to be performed reliably without missing the video at the decisive moment.
[0126]
The configuration of the hybrid recorder 3 will be specifically described below.
First, the hybrid recorder 3 is provided with an interface unit 302 based on the communication protocol of RS-422. By this interface unit 302, a recording start sent from the external interface 18 of the computer 2; Control commands such as recording end, playback start, playback end and the like are received. The interface unit 302 passes the received control command to the CPU 303.
The CPU 303 is a control unit that controls the overall operation of the hybrid recorder 3 and controls the operation of each unit in accordance with a control command received from the interface unit 302. As a result, the hybrid recorder 3 records the input video signal V1, or reproduces the recorded video signal and outputs a reproduced video signal V3.
[0127]
First, the video signal V 1 continuously supplied from the source side of a video camera or the like is input to the first switch 304. In addition to this, a video signal output from the decoder 305 is also input to the first switch 304. The first switch 304 selects a video signal to be recorded on the hard disk drive 300 and the video tape recorder 301 based on a control signal from the CPU 303, and includes a video signal V 1 and a video signal output from the decoder 305. Either one is selected and output to the encoder 306. Since the video signal V1 is normally recorded, the video signal V1 is selected as the first switch 304. Incidentally, when the video signal output from the decoder 305 is selected, the video signal recorded on the hard disk drive 300 is transferred to the video tape recorder 301 for recording.
[0128]
The encoder 306 converts the analog video signal supplied from the first switch 304 into a digital video signal, and converts the digitized video signal in units of frames based on the MPEG standard (Moving Picture coding Experts Group). The compressed encoded video signal is output to the second switch 307 and the video tape recorder 301.
In addition to the encoded video signal output from the encoder 306, the video signal output from the video tape recorder 301 is input to the second switch 307. The second switch 306 selects a video signal to be supplied to the hard disk drive 300 based on a control signal from the CPU 303, and an encoded video signal output from the encoder 306 and a video output from the video tape recorder 301. Either one of the signals is selected and output. Normally, the hard disk drive 300 records the encoded video signal, so the encoded video signal is selected as the second switch 307. Incidentally, when the video signal output from the video tape recorder 301 is selected, the video signal recorded on the video tape recorder 301 is transferred to the hard disk drive 300 for recording.
[0129]
The video signal selected by the second switch 307 is input to the input buffer memory 308. The input buffer memory 308 has a storage capacity sufficient to store, for example, 15 frames of video signals, and temporarily stores input video signals.
The hard disk drive 300 includes a hard disk array in which a plurality of hard disks are connected in an array, and thereby has a sufficient storage capacity for the video signal V1. When a recording operation is instructed by a control signal from the CPU 303, the hard disk drive 300 sequentially reads out video signals stored in the input buffer memory 308 and stores them in the hard disk array in units of frames. In addition, when a playback operation is instructed by the control signal from the CPU 303, the hard disk drive 300 reads out and reproduces the video signal at the location instructed by the CPU 303 from the hard disk array. The reproduced video signal is output to an output buffer memory 309 having a storage capacity for 15 frames, for example, and temporarily stored. The output buffer memory 309 sequentially reads out the temporarily stored video signals and outputs them to the third switch 310.
[0130]
Here, the recording and reproducing operations of the hard disk drive 300 will be specifically described below. In this hybrid recorder 3, all recording and reproduction operations of the hard disk drive 300 are managed by the CPU 303.
The CPU 303 assigns a time code to each video frame of the video signal to be recorded based on the time code output from the time code generation unit 313 and assigns a recording address to each video frame of the video signal. The CPU 303 stores the allocated time code and recording address as a correspondence table.
During the recording operation, the CPU 303 instructs a recording address and a recording command to the hard disk drive 300. As a result, the hard disk drive 300 records the video signal at the designated recording address. On the other hand, when a video signal to be read by the time code is instructed from the computer 2 during the reproduction operation, the CPU 303 refers to the correspondence table described above to check where the video frame of the instructed time code is recorded (ie, Check the recording address). Then, the CPU 303 instructs the hard disk drive 300 on the recording address checked together with the reproduction command. As a result, the hard disk drive 300 reproduces the video signal from the instructed address, and reproduces the video signal requested by the computer 2. In this way, the CPU 303 stores the correspondence relationship between the time code and the recording address as a correspondence table, so that even when the reproduction position is designated by the time code from the computer 2, the designated reproduction position is reproduced promptly. be able to.
[0131]
When the external time code (EXT.TC) is supplied from the outside, the time code generation unit 313 described above supplies the external time code as the time code to the CPU 303, and when the external time code is not supplied. Is configured to generate its own time code and supply it to the CPU 303.
[0132]
Next, the roles of the input buffer memory 308 and the output buffer memory 309 provided on the input side and output side of the hard disk drive 300 will be described. The two buffer memories 308 and 309 are buffer materials that allow the hard disk drive 300 to perform the recording operation and the reproducing operation in parallel in appearance. The hard disk drive 300 can perform a recording operation at a speed at least twice as fast as the input buffer memory 308 takes in the video signal, and at least twice as fast as the output buffer memory 309 reads out the video signal. Playback operation can be performed at speed. Therefore, if the buffer memories 308 and 309 are provided on the input side and the output side, the hard disk drive 300 can perform the reproduction operation and store the video signals in the output buffer memory 309 while the input buffer memory 308 is capturing the video signals. In addition, while the output buffer memory 309 is reading the video signal, the hard disk drive 300 can read the video signal from the input buffer memory 308 and perform a recording operation. Therefore, if the buffer memories 308 and 309 are provided on the input side and the output side of the hard disk drive 300 as described above, the recording operation and the reproduction operation of the hard disk drive 300 can be apparently performed simultaneously.
[0133]
Here, returning to FIG. 12 again, description of each part is continued. As described above, the encoded video signal output from the encoder 306 is also supplied to the video tape recorder 301. The video tape recorder 301 is provided for backup of the hard disk drive 300, and performs a recording operation or a reproducing operation based on a control signal from the CPU 303. For example, when the hard disk drive 300 is performing a recording operation, the video tape recorder 301 operates for recording backup, so the video tape recorder 301 records a video signal input in parallel with the recording operation of the hard disk drive 300 on the video tape. Further, when the hard disk drive 300 is performing a reproduction operation in response to an instruction from the CPU 303, the hard disk drive 300 operates as a reproduction backup, so that the video signal of the same video frame as the video signal being reproduced by the hard disk drive 300 is converted to a video tape. Play from and output.
[0134]
The recording and playback operations of the video tape recorder 301 are managed by the CPU 303 as in the hard disk drive 300. However, in the case of a video tape recorder, the position cannot be specified by the address as in the hard disk drive. The CPU 303 instructs the time code itself instead of the address information. That is, the video tape recorder 301 adds and records the time code given from the CPU 303 at the time of recording, and determines the read position based on the time code instructed by the CPU 303 at the time of reproduction to perform the reproducing operation.
[0135]
The video signal reproduced from the video tape recorder 301 is input to the third switch 310 in the same manner as the video signal reproduced from the hard disk drive 300. The third switch 310 selects a video signal to be output as a reproduced video signal V3 based on a control signal from the CPU 303. That is, the third switch 310 selects one of the video signal reproduced by the hard disk drive 300 and the video signal reproduced by the video tape recorder 301 based on a control signal from the CPU 303. Normally, a video signal reproduced by the hard disk drive 300 is selected. The video signal on the video tape recorder 301 side is selected when an error has occurred in the video signal on the hard disk drive 300 side.
[0136]
The video signal selected by the third switch 310 is supplied to the decoder 305. The decoder 305 decodes a video signal that has been compression-encoded in units of frames, and decodes an input video signal based on the MPEG standard. The decoder 305 converts the decoded digital video signal into an analog video signal and outputs the analog video signal to the first time code adding unit 311.
[0137]
The first time code adding unit 311 adds a time code to the vertical synchronization period of the video signal output from the decoder 305 based on the time code supplied from the CPU 303. However, when the video signal output from the decoder 305 is a video signal reproduced by the video tape recorder 301, the time code is not added since the time code is already added, and the hard disk drive 300 is used. A time code is added only for a reproduced video signal. Note that the time code added to the video signal is the same as the time code assigned at the time of recording.
The video signal to which the time code is added by the first time code adding unit 311 is output to the outside as the reproduced video signal V3 and also sent to the computer 2.
[0138]
The hybrid recorder 3 outputs a video signal V2 that is substantially the same as the input video signal V1 in addition to the reproduced video signal V3. This video signal V2 is a video signal obtained by adding a time code to the input video signal V1 by the second time code adding unit 312.
In this case, the second time code adding unit 312 adds a time code to the vertical synchronization period of the input video signal V1 based on the time code output from the CPU 303, and outputs this as a video signal V2. At that time, the second time code adding unit 312 adds the time code to the video signal V1 so that the correspondence between the time code and the video frame to which the time code is added becomes the same as that of the video signal V3. For example, if the time code “00: 01: 23: 45” is added to a certain video frame in the first time code adding unit 311, for example, it is the same as the video frame matching the video frame in the video signal V 1. The time code “00: 01: 23: 45” is added.
[0139]
In this manner, the hybrid recorder 3 can reproduce the video signal V3 from the hard disk drive 300 while recording the video signal V1 on the hard disk drive 300, and can perform the recording operation and the reproducing operation almost simultaneously. It is made like that. In the case of this hybrid recorder 3, a video tape recorder 301 is provided for backup of the hard disk drive 300, so that even if a problem occurs on the hard disk drive 300 side, recording and playback operations can be performed reliably. Has been made.
[0140]
(6) Playback speed setting
(6-1) Playback speed setting area
Next, event playback speed setting will be described. In the editing system 1, the playback speed of the event can be set in units of frames using the playback speed setting area 25 in either the picture mode or the timeline mode. This makes it possible to set slow playback for the event at the moment of hitting a home run, for example, in a baseball broadcast, and video that represents the movement of the butter and the whereabouts of the ball more realistically by slow playing the event of the home run scene Can be provided to the viewer. Also, since the playback speed can be set in units of frames, for example, you can set a relatively early slow playback in a scene where the pitcher throws the ball, and a relatively slow slow playback in the scene where the butter hits the ball. By setting different slow playback within the event, it is possible to provide viewers with more powerful video.
[0141]
This point will be specifically described below with reference to FIG. First, the playback speed setting area 25 shown in FIG. 13 becomes operable by clicking the playback speed setting button 22h in the timing display area 22. The playback speed setting area 25 includes a learn button 25a, a speed foot button 25b, a normal playback speed setting button 25c, an event number display section 25d, an event duration display section 25e, and a timeline scale display section 25f. A time runner display unit 25g, a point display unit 25h, an in-point time code display unit 25i, an out-point time code display unit 25j, and a remaining memory indicator unit 25k.
[0142]
The learn button 25a is a button used when setting the playback speed using a dedicated controller 2e described later. After clicking the Learn button 25a, when the reproduction speed information is input using the dedicated controller 2e, the speed information is stored and the event reproduction speed is set.
The speed fit button 25b is a button used when the playback speed is automatically set by inputting a numerical value from the keyboard 2c to the length from the IN point to the OUT point (so-called delay). After clicking the speed foot button 25b, if a derating value is input from the keyboard 2c, the optimum playback speed is automatically set based on the derating value.
[0143]
The normal playback speed setting button 25c is a button used to cancel the playback speed setting. When the normal playback speed setting button 25c is clicked after designating an event for which the playback speed is set, the set playback speed is canceled and the normal playback speed, that is, the normal speed is set.
The event number display part 25d is an area for displaying the event number of the designated event. The displayed event number is the same as the event number displayed in the event number display part 29d of the event display area 29.
[0144]
The event duration display unit 25e is an area for displaying the length from the In point to the Out point of the designated event, that is, the deduration. The event duration display unit 25e displays the duration in units of frames. The timeline scale display unit 25f is an area representing a scale, that is, a scale for visually representing the delay of a specified event. The scale displayed on the timeline scale display unit 25f is in units of frames.
[0145]
When the playback speed is set by the dedicated controller 2e described later or when an event for which the playback speed is set is previewed, the time runner display unit 25g is currently set or played back in the event. It is a position display part which displays whether it is. The time runner display section 25g displays an icon 25ga in the shape of a human being running, and is currently set depending on the display position of the icon 25ga based on the scale of the timeline scale display section 25f. Alternatively, the position within the event being played can be specified. Therefore, the operator can easily understand which position is set or reproduced visually by the position of the icon 25ga. In this case, the icon 25ga moves sequentially from the IN point to the OUT point along the scale as the setting or reproduction progresses. At this time, the icon 25ga is changed according to the set reproduction speed. Therefore, the operator can easily visually confirm when and at what part the playback speed in the event is fast and which part is slow.
[0146]
The point display portion 25h is an area that indicates whether there is another in point or out point set during the editing operation between the in point and the out point of the specified event. In the point display portion 25h, when such other IN point or OUT point exists, the pointer 25ha is displayed at the position. Thus, the operator can easily grasp the existence of other editing points based on the presence or absence of the pointer 25ha.
The in-point time code display unit 25i and the out-point time code display unit 25j are areas for displaying the time code of the selected in point and out point, respectively.
[0147]
The memory remaining amount indicator section 25k is an area that indicates the remaining amount with respect to the maximum learn duration when the learn button 25a is clicked, the reproduction speed is set using the dedicated controller 2e, and the reproduction speed is stored in the RAM 10b of the CPU 10. It is. Since the storage area allocated for setting the playback speed for one event is determined in advance, the remaining amount can be easily calculated by examining the remaining capacity of the storage area. By providing such a memory remaining amount indicator unit 25k, the remaining amount of memory can be visually recognized, so that it is possible to avoid a reproduction speed setting that exceeds the maximum learn duration.
[0148]
(6-2) Dedicated controller
Next, the dedicated controller 2e used for setting the reproduction speed will be described with reference to FIG. As shown in FIG. 14, the dedicated controller 2e has a search dial 400 which is a rotary encoder and a motion control lever 401 which is a slide encoder in addition to a plurality of operation buttons, and uses these two operation means. Thus, the playback speed can be freely input by a manual operation.
[0149]
First, the arrangement of operation buttons provided on the operation panel surface of the dedicated controller 2e will be described. At the upper center of the operation panel surface, there are a learn button 402, a start button 403, a stop button 404, a recording side selection button 405, a reproduction side selection button 406, a play button 407, a stale button 408, a mark in button 409, and a mark out button 410. Is provided. In addition, the search dial 400 described above, a shuttle button 411, a jog button 412, a variable button 413, and a variable indicator 414 are provided below these operation buttons.
On the other hand, a preview button 415, a cursor button 416, and an enter button 417 are provided on the right side of the operation panel from the top. On the other hand, on the left side of the operation panel, the above-described motion control lever 401 is provided so as to be slidable with respect to the top and bottom of the operation panel.
[0150]
Of these operation buttons, the learn button 402 is a button used for setting the reproduction speed by the motion control lever 401 or the search dial 400 and storing it. After the learn button 402 is pressed, the playback speed is stored until the motion control lever 401 or the search dial 400 is operated or the markout button 410 is pressed. The Learn button 402 is functionally substantially the same as the Learn button 25a displayed in the playback speed setting area 25.
The start button 403 is a button operated when outputting a recording start command to the hybrid recorder 3 and recording a video signal displayed in the recording video display area 21. The stop button 404 is a button operated when outputting a recording stop command to the hybrid recorder 3 and stopping the recording operation of the video signal displayed in the recording video display area 21. These buttons 403 and 404 are functionally the same as the recording start button 31a and the recording end button 31b displayed on the monitor 2b.
[0151]
The recording side selection button 405 and the reproduction side selection button 406 are buttons used when selecting an object to be controlled by the dedicated controller 2e. When the recording side is controlled by the dedicated controller 2e, the recording side selection button 405 is pressed, and when the playback side is controlled, the playback side selection button 406 is pressed.
The play button 407 is a button used when a playback start command is output to the hybrid recorder 3 to display a video signal in the playback video display area 23. The stale button 408 is a button used when outputting a playback stop command to the hybrid recorder 3 and stopping the playback operation of the video signal displayed in the playback video display area 23. When the stale button 408 is pressed, a still image is displayed on the playback video screen 23a.
[0152]
A mark-in button 409 and a mark-out button 410 are buttons used when setting an in point and an out point, respectively. These buttons 409 and 410 operate in the same manner as the mark-in button 24c and the mark-out button 24f of the recording video marking area 24 when the recording-side selection button 405 is pressed, and the playback-side selection button 406 is selected. When pressed, it operates in the same manner as the mark-in button 27c and mark-out button 27f in the playback video marking area 27.
[0153]
The shuttle button 411 is a button that is pressed when the search dial 400 is desired to operate in the shuttle mode, and the jog button 412 is a button that is pressed when the search dial 400 is desired to operate in the jog mode. The variable button 413 is a button that is pressed when the search dial 400 is to be operated in the variable mode or when the motion control lever 401 is to be operated. When the variable button 413 is pressed once, the variable indicator 414 on the right side is turned on and the search dial 400 is set to the variable mode. When the button is pressed again, the variable indicator 414 on the left side is turned on and the motion control lever 401 is turned on. When the button becomes usable and is pressed once more, the left and right variable indicators 414 are turned off, and the search dial 400 and the motion control lever 401 become unusable.
[0154]
The preview button 415 is a button used to preview the selected event or program. When this preview button 415 is pressed with an event or program selected, the playback start command for that event or program is output to the hybrid recorder 3, and the video signal for that event or program is displayed on the playback video screen 23a. .
[0155]
The cursor button 416 includes four buttons, an up button, a down button, a left button, and a right button. When the clip image data is selected in the clip display area 28, the event display area 29, or the program display area 30, the cursor button 416 is displayed. This is a button for moving the cursor to.
Two types of functions are assigned to the enter button 417. One is a function of inputting a registration instruction when newly registering an event from an IN point to an OUT point set in the playback video marking area 27 (the same as the new event button 33 displayed on the monitor 2b). The other is a function for inputting a transmission instruction when a selected event or program is transmitted.
[0156]
The search dial 400 is a rotary encoder that inputs reproduction speed information according to the rotation operation of the operator. As described above, the search dial 400 operates in the three modes of the shuttle mode, the jog mode, and the variable mode by pressing the shuttle button 411, the jog button 412 and the variable button 413. First, in the shuttle mode, the reproduction speed information from -100 times speed to +100 times speed can be inputted according to the rotational position of the search dial 400. In this mode, the search dial 400 is in a clicking state at a position of a still image, + 10 × speed and −10 × speed.
In the jog mode, playback speed information from -1 × speed to + 1 × speed can be input according to the rotational position of the search dial 400.
In the variable mode, playback speed information from -1 times speed to +3 times speed can be input according to the rotational position of the search dial 400. In this mode, the search dial 400 is in a click state at the still image and + 1 × speed positions.
In this way, select the jog mode that can set the fine playback speed by narrowing the control range, the shuttle mode that can set a wide range by coarse playback speed setting, and the variable mode that widens the setting range on the plus side By doing so, the operator can switch the playback speed according to his / her desired playback speed and freely set the playback speed.
[0157]
The motion control lever 401 is a slide encoder that inputs reproduction speed information corresponding to the operator's slide operation. By sliding the motion control lever 401 up and down, it is possible to input reproduction speed information from a still image to + 1 × speed. Note that a range expansion button 401a is provided on both sides of the motion control lever 401, and the reproduction speed information that can be input by pressing the range expansion button 401a is in the range from -1 to +3 times speed. Can be extended.
As described above, by allowing the motion control lever 401 to input the playback speed information from the still image to the + 1 × speed, the operator can freely set the playback speed within the range.
Further, as a mechanism for inputting playback speed information, a rotation operation type search dial 400 and a slide operation type motion control lever 401 are provided, so that an operator can select a user-friendly one to display playback speed information. It is possible to input, and usability can be improved.
[0158]
Note that the instruction information input from the various operation buttons of the dedicated controller 2e described here and the playback speed information input from the search dial 400 and the motion control lever 401 are sent to the CPU 10 via the pointing device interface 17. Sent out. Thus, the CPU 10 performs operation control according to the instruction information and performs a reproduction operation according to the reproduction speed information for the designated event. When the learn button is pressed, the CPU 10 stores the reproduction speed information in the RAM 10b as the reproduction speed of the designated event.
[0159]
Incidentally, when storing the reproduction speed information, for example, it is stored in a data format as shown in FIG. That is, the speed data is stored for each video frame from the In point to the Out point of the designated event. The speed data is digital data output from the search dial 400 or the motion control lever 401 and decoded by the pointing device interface 17. At the time of reproduction, the CPU 10 reads the speed data stored in this format and controls the reproduction speed. At this time, the CPU 10 assumes that speed data is N and playback speed is v, where v = 10. ^{(N / 32-2)} The value obtained as a result is set as the reproduction speed. Therefore, for example, when the speed data N is “64”, the playback speed is “1.0”, and when the speed data N is “32”, the playback speed is “0.1”.
[0160]
(6-3) Playback speed setting method
Next, a setting procedure when setting the playback speed using the playback speed setting area 25 will be described. First, there are roughly three methods for setting the playback speed. The first method is a method of inputting playback speed information (speed data) from the keyboard 2c without using the dedicated controller 2e. The second method is to specify the event and use the dedicated controller 2e to play back the playback speed. This is a method for inputting information (speed data). The third method is a method for inputting reproduction speed information using the dedicated controller 2e without designating an event.
[0161]
In the case of the first method, first, a desired event whose playback speed is to be set is designated from the event display area 29 by performing a click operation. Next, the playback speed setting button 22h in the timing display area 22 is clicked. As a result, the number and delay of the designated event are displayed in the playback speed setting area 25. Next, the speed fit button 25b in the reproduction speed setting area 25 is clicked. As a result, the playback speed information can be input from the keyboard, so the operator inputs the playback speed information. In this case, actually, the playback speed information (speed data) itself is not input, but the delay value is input. By this operation, the optimum playback speed corresponding to the degeneration value is automatically set for the event.
After that, if the event is to be previewed, the preview button 32 may be clicked. If the set playback speed is to be saved, the new event button 33 or the replace button 34 may be clicked.
[0162]
In the case of the second method, first, a desired event whose playback speed is to be set is designated from the event display area 29 by performing a click operation. Next, the playback speed setting button 22h in the timing display area 22 is clicked. As a result, the number and delay of the designated event are displayed in the playback speed setting area 25. Next, the learn button 25a in the reproduction speed setting area 25 is clicked. As a result, the playback speed can be set, so the playback speed information is input by operating the motion control lever 401 or the search dial 400 of the dedicated controller 2e. The input reproduction speed is sequentially stored in the RAM 10b of the CPU 10. Thereafter, if the setting of the playback speed is to be ended, the setting of the playback speed is ended by pressing the markout button 27f of the playback video marking area 27 or the markout button 410 of the dedicated controller 2e at the position to be ended. If the set playback speed is to be stored, the new event button 33 or the replace button 34 may be clicked.
[0163]
In the case of the third method, first, the learn button 402 of the dedicated controller 2e is pushed at a desired position while viewing the playback video screen 23a in the playback video display area 23. Thus, the IN point is set and the playback speed can be set. Similarly, the playback speed information may be input by operating the motion control lever 401 or the search dial 400 of the dedicated controller 2e. The input reproduction speed is sequentially stored in the RAM 10b of the CPU 10. Thereafter, if the setting of the playback speed is to be ended, the setting of the playback speed is ended by pressing the markout button 27f of the playback video marking area 27 or the markout button 410 of the dedicated controller 2e at the position to be ended. If the set playback speed is to be stored, the new event button 33 or the replace button 34 may be clicked.
[0164]
(7) Pre-roll mode
Next, the pre-roll mode provided in the editing system 1 will be described. In general, when generating an event, the operator clicks the mark-in button 24c and the mark-out button 24f in the recording video marking area 24 while watching the video data displayed on the recording video screen 21a, and sets the in and out points. Point to the point. Thereby, in the editing system 1, video data from the designated in point to out point is registered as an event. When confirming the registered event, the operator clicks and designates the event displayed in the event display area 29 and then clicks the preview button 32. Thereby, the playback operation of the event is started, and the video data from the IN point to the OUT point of the event is displayed on the playback video screen 23a.
[0165]
By the way, when instructing the in point of the event, the operator operates the mark in button 24c while viewing the video data displayed on the recording video screen 21a, so that the in point is instructed. Due to the operational delay, etc., the IN point may be instructed after the scene to be registered as an event. For example, when registering a scene of hitting a home run in a baseball broadcast as an event, it is generally desirable to register as an event from when the pitcher throws the ball until the ball hit by the butter stands in, Whether or not it is a home run scene is not known until the ball hit by the butter stands in, so it is inevitably delayed to indicate the in point. In such an event where the IN point is delayed, since an important scene is not included, the event must be corrected.
[0166]
Therefore, in the case of this editing system 1, there is a pre-roll mode in which the reproduction operation is automatically started from a position before a predetermined time before the position of the in point designated by the operator, and the marking point can be easily corrected. Is provided. This pre-roll mode will be specifically described below.
First, the time used in the pre-roll mode, that is, the time for shifting the playback start point before the IN point specified by the operator (hereinafter referred to as the queue time) can be freely set in the menu environment setting. It is made like that. When setting the queue time, an environment setting prepared as a menu is called, and a queue item is selected from the environment settings. By selecting this queue item, a queue setting screen as shown in FIG. 16 is displayed on the screen. In this queue setting screen, after clicking the set time display area 500 and inputting the time to be set as the queue time from the keyboard in seconds, the time is displayed in the set time display area 500 and temporarily set.
[0167]
When the button in the desired direction is clicked among the jog buttons 501 adjacent to the set time display area 500, the time is shifted in seconds in that direction. You may enter the time.
When the set time 502 is clicked after inputting the queue time in this way, the time displayed in the set time display area 500 is formally registered as the queue time. Specifically, the inputted clean time is stored in a storage area for environment setting data in the RAM 10b. Note that when the cancel button 503 is clicked, the time displayed in the set time display area 500 is reset, and it becomes possible to input a new cute time. Incidentally, when the setting button 502 is clicked, this cute setting screen automatically disappears from the screen.
[0168]
When the pre-roll button 22g in the timing display area 22 is clicked in the state in which the cute time is set in this way, activation of the pre-roll mode is instructed, whereby the pre-roll button 22g is lit and the pre-roll mode is activated. . When canceling the pre-roll mode, when the pre-roll button 22g is clicked again, the end of the pre-roll mode is instructed, whereby the pre-roll button 22g is turned off and the pre-roll mode is canceled.
[0169]
When the operator clicks the mark-in button 24c in the recording video marking area 24 while the pre-roll mode is activated, the in-point is instructed, and the clip image data instructed as the in-point is displayed in the ink display area 24a. Is displayed. At the same time, the set cut time is read out, and as shown in FIG. 17, the time code at the position shifted forward by the cut time is calculated from the time code at the position designated as the IN point. . Then, by outputting a playback command to the hybrid recorder 3 using the calculated time code position as a playback start point, the editing system 1 automatically starts a playback operation from the playback start point. Since the reproduced video signal V3 is displayed on the reproduced video screen 23a, the operator can easily correct the In point by clicking the mark-in button 27c in the reproduced video marking area 27 while viewing the reproduced video screen 23a. can do. After that, if the mark-out button 27f is clicked to indicate the out point, and the new event button 33 is clicked, the video data of the section from the in point to the out point is registered as an event.
[0170]
If the pre-roll mode is previously activated in this way, for example, even when the ball hit by the butter stands at the time of baseball broadcast and the mark-in button 24c is clicked to indicate the in-point, the in-point Since the playback operation is automatically performed from a position before a predetermined time from the beginning, it is possible to easily correct the IN point by simply clicking the mark-in button 27c on the playback side and instructing the IN point while viewing the playback screen. it can. For example, if the In point is corrected when the pitcher throws the ball, an event including a desired scene such as the moment when the butter hits the ball can be easily created in real time.
[0171]
(8) Work data folder
Next, in this section, the work data folder will be described. In this editing system 1, work data related to events, programs, etc. generated by the editing operation is normally stored in the RAM 10b. However, when the application program is terminated and the editing operation is terminated, Those work data are downloaded to a hard disk drive 15a provided in the computer 2 and stored in the hard disk in the hard disk drive 15a. At this time, the work data is stored in a hierarchical structure called a folder.
[0172]
Here, this point will be specifically described below with reference to FIG. As shown in FIG. 18, work data related to events, programs, and the like are stored in a hierarchical structure called a folder. This folder is almost the same as a directory in MS-DOS or the like, and the work data folder 600 is set as the highest hierarchy, and lower folders 601 to 603 are formed below the hierarchy of the work data folder 600 so that each data file is stored. It is designed to store while managing in a hierarchical structure. The work data folder 600 is formed in the hard disk drive 15a by the computer 2 when the editing system 1 is activated.
[0173]
First, the clip image data displayed in the clip display area 28, the event display area 29, the program display area 30, or the like is clipped as a clip image file below the clip folder 601 formed below the work data folder 600. Stored in image data units. The contents of the clip image file are clip image data itself, and video data indicating the clip image is written therein. As the file name of the clip image file, as shown in parentheses, a name obtained by adding the extension “.pic” to the index number assigned to each clip image data is used.
[0174]
The symbol image data registered as a representative clip image in the event is stored in symbol image data units as symbol image files below the symbol folder 602 formed below the work data folder 600. Video data indicating a symbol image is written as the contents of the symbol image file. As the file name of the symbol image file, as shown in parentheses, a name obtained by adding the extension “.pic” to the event number including the symbol image is used.
[0175]
The work data related to the program is stored as a program file directly under the hierarchy of the work data folder 600 without forming a lower-order folder. In this program file, the event numbers of the events that make up the program are written in order, and by knowing which event the program is formed by referring to the program file Has become possible. As the file name of the program file, a name obtained by adding “.dat” as an extension to “PROG” indicating the program file is used.
[0176]
The work data related to the event is also stored as an event file directly under the hierarchy of the work data folder 600 without forming a lower folder. In this event file, the clip number of the IN point and OUT point is written in order for each event number. By referring to the event file, the IN point and OUT point that form each event are written. You can see the clip number. As the file name of the event file, a name obtained by adding “.dat” to the extension “EVNT” indicating the event file is used.
[0177]
The work data related to the clip image data is also stored as a clip file directly under the hierarchy of the work data folder 600 without forming a lower folder. In this clip file, the index number and time code of the clip image data are written in order for each clip number. By referring to the clip file, each clip image data has an image number of which index number. It has become possible to know whether it is formed with data. As the file name of the clip file, a name obtained by adding the extension “.dat” to “CLIP” indicating the clip file is used.
[0178]
Further, the speed data (see FIG. 15) indicating the playback speed of the event set using the playback speed setting area 25 is a slow data file below the slow data folder 603 formed below the work data folder 600. Each event is stored in units of events. In this slow data file, speed data as shown in FIG. 15 is written for each frame, and the playback speed set for the event by referring to the slow data file. So that you can know. As the file name of the slow data file, as shown in parentheses, a name obtained by adding the extension “.dat” to the event number assigned for each event is used.
[0179]
In this way, in the editing system 1, when the application program is terminated, work data relating to events, programs, etc. generated by the editing operation is stored in a hard disk of the hard disk drive 15a in a hierarchical structure. . As a result, when the application program is restarted, these work data stored in the hard disk can be read and the same clip image data as before the end can be displayed in the program display area 30, the event display area 29, etc. It is possible to return to the state before the end of the program. Further, by storing the work data in this manner, the work data can be read out later and an edit list such as an EDL (Edit Decision List) can be output.
[0180]
(9) Explanation of computer operation
In this section, the operation of the computer 2 in each process will be described using a flow chart. The flow chart used in the following description basically explains the operation of the CPU 10.
[0181]
(Initial operation)
First, the initial operation of the computer 2 will be described with reference to FIG. First, when execution of the application program is designated by the operator at step SP1, the CPU 10 of the computer 2 starts its operation. In the next step SP2, since the application program is stored in the hard disk of the hard disk drive 15a, the CPU 10 uploads the application program to the operation RAM 10b provided in the CPU 10.
[0182]
In the next step SP3, the CPU 10 executes the application program uploaded to the RAM 10b. In the next step SP4, the CPU 10 secures a memory area in the RAM 10b for storing a plurality of clip image data, edit data and the like generated by the editing work to be performed. At this time, the first management recorder for clip data, event data, and program data as shown in FIG. 11 is also generated in the RAM 10b.
In the next step SP5, the CPU 10 generates a work data folder for storing work data relating to programs and events generated by the editing work to be performed in the hard disk of the hard disk drive 15a.
[0183]
In the next step SP6, in order to display a graphic display for GUI on the monitor 2b, the CPU 10 transfers the graphic data to the VRAM 13b in real time in synchronization with the internal clock of the computer 2. As a result, in the next step SP7, the same graphic as the graphic data stored in the VRAM 13b is displayed on the monitor 2b.
In the next step SP8, the CPU 10 determines whether or not to display the video signal V2 on the recording video screen 21a. This determination is made based on the designation of video display by the operator. If there is no designation of video display, it is determined that the editing operation is not performed, the process proceeds to step SP16, and the process is terminated. In the normal case, since the video display is designated for performing the editing operation, the process proceeds to step SP9 to move to the display processing of the video signal V2.
[0184]
In step SP9, the CPU 10 outputs an RS-422 control command to the hybrid recorder 3 to instruct the hybrid recorder 3 to output the video signal V2. Upon receiving this, the hybrid recorder 3 generates a video signal V2 by adding a time code to the input video signal V1, and sends it to the computer 2.
In the next step SP10, the data converter 11b extracts a time code from the input composite video signal V2 and converts the composite video signal V2 into digital component video data. The converted video data is input to the frame memory 11c and temporarily stored in units of frames. The extracted time code data is supplied to the processor controller 11a and sent to the CPU 10 via the processor controller 11a.
[0185]
In the next step SP11, the video data stored in the frame memory 11c is transferred to the VRAM 13b. The video data to be transferred is video data reduced to 380 pixels × 240 pixels because the number of read samples from the frame memory 11c is decreasing. At this time, by arbitrating the image data bus 5a, image data for the GUI is transferred from the CPU 10 to the VRAM 13b in addition to the video data. At this time, by updating the video data stored in the VRAM 13b in real time, the video data can be displayed on the monitor 2b in real time.
[0186]
In the next step SP12, the image data and video data stored in the VRAM 13b are displayed on the monitor 2b in real time. In the next step SP13, the CPU 10 determines whether or not the video data displayed on the recording video screen 21a is to be recorded in the hybrid recorder 3. This determination is made based on a click operation of the recording start button 31a by the operator. That is, if the recording start button 31a is clicked, it is determined that video data is to be recorded, and the process proceeds to the next step SP14. If the recording start button 31a is not clicked, it is determined that no video data is recorded, and the process proceeds to step SP16. finish.
[0187]
In step SP14, the CPU 10 sends a recording start command to the external interface 18. Receiving this, the external interface 18 converts the recording start command into an RS-422 standard communication format and sends it to the hybrid recorder 3. As a result, the hybrid recorder 3 starts a recording operation of the input video signal V1.
At the next step SP15, since the recording operation is started by the hybrid recorder 3, the CPU 10 determines that all the initial settings have been completed, and ends the procedure of the initial operation as shown in this flow chart.
[0188]
[Marking on the recording side]
Next, marking using the recording video marking area 24 will be described using a flow chart shown in FIG. It should be noted that this marking can be understood more easily with reference to the description of FIGS.
First, when the procedure of the initial operation shown in FIG. 19 is completed, the marking operation can be performed, and the process starts from step SP20.
In step SP21, the CPU 10 determines whether or not a new marking has been performed. The determination as to whether or not marking has been performed is made based on whether or not the mouse 2d has been clicked with the cursor positioned in the area of the mark-in button 24c or mark-out button 24f of the recording video marking area 24. At that time, since an interrupt command is generated by a click operation of the mouse 2d, the CPU 10 determines marking according to the generation of the interrupt command. If the mark-in button 24c is clicked as a result of the determination, it is determined that the in-point has been designated, and the process proceeds to step SP22. If the mark-out button 24f has been clicked, it is determined that the out-point has been designated. Then, the process proceeds to step SP30.
[0189]
In step SP22, in-point clip image data is generated. This IN-point clipped image data is generated by reading video data stored in the frame memory 11c into the VRAM 13b. At this time, since the data amount is thinned out to 1/16 by reducing the number of read samples, a clip image data having an image size of 95 × 60 pixels is generated.
In step SP23, the IN-point clip image data stored in the storage area for the clip display area of the VRAM 13b is read and displayed in the clip display area 24a.
[0190]
In step SP24, the CPU 10 determines whether or not the marking in step SP21 is the first in-point marking. As a result, if it is the first marking, the process returns to step SP21, and if it is the second or more marking, the process proceeds to step SP25.
In step SP25, the CPU 10 determines whether or not the clip image data previously marked is in-point clip image data. As a result, if the previously marked clip image data is the clip image data at the in point, the process proceeds to step SP26, and if the clip image data previously marked is the clip image data at the out point, step SP27. Proceed to
[0191]
In step SP26, the clip image data of the IN point marked earlier is moved to the clip display area 28. That is, since the IN point is marked twice in succession, the clip image data marked earlier is not used as an event, but is moved to the clip display area 28. At this time, as shown in FIGS. 9 to 11, second management record data for the clip image data moved to the clip display area 28 is generated.
[0192]
On the other hand, in step SP27, the CPU 10 determines whether or not an event has been generated based on the clipped image data of the out point previously marked. As a result, if an event has been generated by the previous marking, the process proceeds to step SP29, and if an event has not been generated by the previous marking, the process proceeds to step SP28.
In step SP28, the clip image data of the out point displayed in the outclip display area 24d by the previous marking is moved to the clip display area 28. This is because the clip image data of the out point generated by the previous marking is not used as an event, but may be used in the future, so that it is left as a marking history.
On the other hand, in step SP29, the clip image data of the out point displayed in the out clip display area 24d is cleared. In this case, the clip image data displayed in the out clip display area 24d has already been used as the out point of the event, and therefore it is not necessary to display any more.
[0193]
On the other hand, if it is determined in step SP21 that the marking of the out point has been detected and the process proceeds to step SP30, the clip image data of the out point is generated here. This out-point clipped image data is also generated by reading the video data stored in the frame memory 11c into the VRAM 13b. Also in this case, the clip image data of 95 pixels × 60 pixels is generated by thinning out the data amount to 1/16 at the time of reading.
In step SP31, the clip image data at the out point stored in the storage area for the clip display area of the VRAM 13b is read and displayed in the clip display area 24d.
[0194]
In the next step SP32, the CPU 10 determines whether or not the marking in step SP21 is the marking of the first out point. As a result, if it is the first marking, the process returns to step SP21. If it is the second or more marking, the process proceeds to step SP33.
In step SP33, the CPU 10 determines whether or not the clip image data previously marked is in-point clip image data. As a result, if the previously marked clip image data is the clip image data at the in point, the process proceeds to step SP34, and if the clip image data previously marked is the clip image data at the out point, step SP36. Proceed to
[0195]
In step SP34, the CPU 10 registers, as an event, a section from the previously marked in point to the marked out point. As described above, in the editing system 1, when the out point is marked after the in point, it is automatically registered as an event. At this time, as shown in FIGS. 9 to 11, second management record data relating to the event is generated.
In the next step SP35, the clip image data of the generated in-point of the event is copied to the event display area 29, and the clip image data is displayed in the event display area 29.
[0196]
On the other hand, in step SP36, the CPU 10 determines whether or not an event has been generated based on the clipped image data of the out point previously marked. As a result, if an event has been generated by the previous marking, the process proceeds to step SP38, and if an event has not been generated by the previous marking, the process proceeds to step SP37.
In step SP37, the clip image data of the out point generated by the previous marking is moved to the clip display area 28. This is because the clip image data of the out point generated by the previous marking is not used as an event, but may be used in the future, so that it is left as a marking history.
On the other hand, at step SP38, the clip image data of the IN point displayed in the clip display area 24a is cleared. This is because the event is generated by the clip image data displayed in the clip display area 24a and the clip image data of the previously marked out point, and the clip image data displayed in the clip display area 24a is This is because it will not be used in the future and there is no need to display any more.
[0197]
When the processing of step SP26, step SP28, step SP29, step SP35, step SP37 or step SP38 is completed, the CPU 10 proceeds to step SP39 and determines whether or not the marking operation is ended. If the marking operation is to be continued, the process returns to step SP20 again to repeat the process. If the marking operation is to be terminated, the process proceeds to step SP40 and the process is terminated.
[0198]
[Marking on playback side]
Next, a case where marking is performed using the playback video marking area 27 while watching the video signal V3 reproduced from the hybrid recorder 3 will be described using the flow charts shown in FIGS.
First, this marking starts from a state where clip image data is already stored. In step SP51 entered from step SP50, the CPU 10 determines whether or not the clip image data in the clip display area 28 has been designated. At this time, the CPU 10 determines that the clip image data is designated when the mouse 2d is double-clicked (two consecutive click operations) while the cursor is at the display position (28a) of the clip image data.
As a result, when clip image data is designated, the designated clip image data is displayed in the reproduction video marking area 27 in the next step SP52. That is, if in-point clip image data is specified, it is displayed in the clip display area 27a, and if out-point clip image data is specified, it is displayed in the out clip display area 27d.
[0199]
In the next step SP53, the CPU 10 refers to the time code of the designated clip image data, and sends a control command for still reproduction of the video data of the time code to the external interface 18. Receiving this, the external interface 18 converts the still reproduction command into an RS-422 standard communication format and sends it to the hybrid recorder 3. Thus, the hybrid recorder 3 refers to the correspondence table between the time code and the recording address based on the received time code, checks the recording address, and reads the video data from the position of the recording address, thereby Play. This video data is sent to the second video processor 12 in the computer 2 as a video signal V3.
[0200]
In the next step SP54, the second video processor 12 extracts a time code from the video signal V3 and performs image processing for converting the video signal V3 into digital component video data. The converted video data is temporarily stored in the frame memory 12c in the second video processor 12.
In the next step SP55, the still playback video data stored in the frame memory 12c is reduced to 380 pixels × 240 pixels and then transferred to the VRAM 13b.
In the next step SP56, the reproduction video data stored in the VRAM 13b is displayed on the reproduction video screen 23a. In this case, since the hybrid recorder 3 sends only still video data corresponding to the instructed clip image data, not real-time video data, a still image is displayed on the playback video screen 23a.
[0201]
In the next step SP57, the CPU 10 determines whether or not reproduction is instructed for the still video data displayed on the reproduction video screen 23a. At this time, if the preview button 32 is clicked while still video data is displayed on the playback video screen 23a, the CPU 10 determines that playback has been instructed.
As a result, when a reproduction instruction is given, the CPU 10 sends a reproduction start command to the external interface 18 at the next step SP58. Receiving this, the external interface 18 converts the reproduction start command into an RS-422 standard communication format and sends it to the hybrid recorder 3. As a result, the hybrid recorder 3 reads out the video data in order from the recording address corresponding to the video data displayed on the playback video screen 23a, thereby normal playback following the video data displayed on the playback video screen 23a. Generate video data. This reproduced video data is sent to the second video processor 12 in the computer 2 as a video signal V3.
[0202]
In the next step SP59, the CPU 10 determines whether or not marking has been performed. The determination as to whether or not the marking has been made is made based on whether or not the mouse 2d has been clicked with the cursor positioned in the area of the mark-in button 27c or the mark-out button 27f in the playback video marking area 27. At that time, since an interrupt command is generated by a click operation of the mouse 2d, the CPU 10 determines marking according to the generation of the interrupt command. If the mark-in button 27c has been clicked as a result of the determination, it is determined that the in-point has been specified, and the process proceeds to step SP60. If the mark-out button 27f has been clicked, it is determined that the out-point has been specified. Then, the process proceeds to step SP63.
[0203]
In step SP60, in-point clip image data is generated. This IN-point clipped image data is generated by reading video data stored in the frame memory 12c into the VRAM 13b. At this time, since the data amount is thinned out to 1/16 by reducing the number of read samples, a clip image data having an image size of 95 × 60 pixels is generated.
In the next step SP61, the clip image data at the IN point stored in the storage area for the clip display area of the VRAM 13b is read and displayed in the clip display area 27a.
In the next step SP62, the clip image data of the IN point that was previously marked and displayed in the clip display area 27a is moved to the clip display area 28. It should be noted that this process is not performed when the marking is not performed first and the clip image data is not displayed in the clip display area 27a. When the processing of step SP62 is completed, the CPU 10 proceeds to step SP70.
[0204]
On the other hand, if the process proceeds to step SP63 for marking the out point, the clip image data of the out point is generated here. This out-point clipped image data is also generated by reading the video data stored in the frame memory 12c into the VRAM 13b. Also in this case, the clip image data of 95 pixels × 60 pixels is generated by thinning out the data amount to 1/16 at the time of reading.
In step SP64, the clip image data of the out point stored in the storage area for the clip display area of the VRAM 13b is read and displayed in the clip display area 27d.
[0205]
In the next step SP65, the CPU 10 determines whether or not the clip image data previously marked is the clip image data at the IN point. As a result, if the previously marked clip image data is the clip image data at the in point, the process proceeds to step SP66, and if the clip image data previously marked is the clip image data at the out point, step SP67. Proceed to
In step SP66, the CPU 10 determines whether or not to newly register as an event. This determination is made based on a click operation of the new event button 33 by the operator. If the new event button 33 is clicked and an event registration is instructed, the process proceeds to step SP68. If the new event button 33 is not clicked and no event registration is instructed, the process proceeds to step SP67.
[0206]
In step SP68, the CPU 10 registers the section from the in point to the out point as an event. As described above, in this editing system 1, when the out point is marked after the in point and the new event button 33 is clicked, the section from the in point to the out point is registered as a new event. At this time, as shown in FIGS. 9 to 11, second management record data relating to the event is generated.
In the next step SP69, the clip image data of the generated in-point of the event is copied to the event display area 29, and the clip image data is displayed in the event display area 29. When this process ends, the CPU 10 proceeds to the next step SP70.
[0207]
On the other hand, if the clip image data generated by the previous marking is the clip image data of the out point and the process proceeds to step SP67, the clip image data of the out point generated by the previous marking is performed here. To the clip display area 28. It should be noted that this process is not performed when the marking is not performed first and the clip image data is not displayed in the out clip display area 27d. When this process ends, the CPU 10 proceeds to step SP70. In step SP70, the CPU 10 determines whether or not an instruction to stop playback of the video data displayed on the playback video screen 23a has been issued. This determination is made based on whether or not the stale button 408 of the dedicated controller 2e has been pressed. If playback stop is not instructed, the process returns to step SP59 and the process is repeated. If playback stop is instructed, the process proceeds to the next step SP71.
In step SP71, the CPU 10 sends a reproduction stop command to the external interface 18. Receiving this, the external interface 18 converts the reproduction stop command into an RS-422 standard communication format and sends it to the hybrid recorder 3. As a result, the hybrid recorder 3 stops the video data reading operation and stops the reproduction operation. When the process at step SP71 is completed, the CPU 10 proceeds to step SP72 and ends the marking process.
[0208]
〔trimming〕
Next, a process for changing the IN point or OUT point by designating the generated event, so-called trimming, will be described with reference to the flowchart shown in FIG. This flow chart starts from a state where an event has already been generated.
First, in step SP81 entered from step SP80, the CPU 10 determines whether or not the clip image data in the event display area 29 has been designated. At this time, the CPU 10 determines that the clip image data is designated when the mouse 2d is double-clicked (two consecutive click operations) while the cursor is at the clip image data display position (29a).
As a result, when the clip image data is designated, in the next step SP82, the CPU 10 refers to the time code of the designated clip image data, and performs a reproduction command for still reproduction of the video data of that time code. Is sent to the hybrid recorder 3 via the external interface 18. Based on this playback command, the hybrid recorder 3 plays back the specified video data to generate playback video data, so that playback video data corresponding to the specified clip image data is displayed on the playback video screen 23a. The
[0209]
In the next step SP83, the CPU 10 determines whether or not the shuttle button 23b of the playback video display area 23 has been pressed. This determination is made based on whether or not the mouse 2d has been clicked while the cursor is at the position of the shuttle button 23b.
As a result, if the shuttle button 23b has been pressed, the process proceeds to the next step SP84, where the CPU 10 determines whether or not the shuttle button 23b has been dragged. This determination is made based on whether or not the shuttle button 23b has been moved by moving the cursor while the shuttle button 23b is clicked.
As a result, if the shuttle button 23b has been dragged, the process proceeds to the next step SP85, where the CPU 10 calculates the direction and distance the cursor has moved. Then, the CPU 10 calculates the time code of the designated video data based on the obtained direction and distance and the time code of the video data currently displayed on the playback video screen 23a. Specifically, if it is in the right direction, the time code of the specified video data is calculated by adding the time code for the moving distance to the time code of the currently displayed video data. The time code of the specified video data is calculated by subtracting the time code corresponding to the moving distance from the time code of the currently displayed video data.
[0210]
In the next step SP86, the CPU 10 sends a reproduction command for reproducing the video data of the obtained time code to the hybrid recorder 3 via the external interface 18.
In the next step SP87, the hybrid recorder 3 reproduces the video data of the designated time code based on this reproduction command, so that the reproduced video data of the designated time code is displayed on the reproduction video screen 23a. .
[0211]
In the next step SP88, the CPU 10 determines whether or not marking has been performed. The determination as to whether or not the marking has been made is made based on whether or not the mouse 2d has been clicked with the cursor positioned in the area of the mark-in button 27c or the mark-out button 27f in the playback video marking area 27. As a result of the determination, if either the mark-in button 27c or the mark-out button 27f is clicked, the process proceeds to step SP89, and if neither is clicked, the process returns to step SP83 to repeat the process.
In step SP89, marked clip image data is generated. The clip image data is generated by reading the video data stored in the frame memory 12c into the VRAM 13b. At this time, since the data amount is thinned out to 1/16 by reducing the number of read samples, a clip image data having an image size of 95 × 60 pixels is generated.
[0212]
In the next step SP90, the clip image data stored in the VRAM 13b is read out and displayed in the clip display area 27a or the clip display area 27d of the reproduction video marking area 27. Specifically, if it is marked as an IN point, the clip image data is displayed in the clip display area 27a, and if it is marked as an OUT point, the clip image data is displayed in the out clip display area 27d. .
In the next step SP91, the CPU 10 determines whether or not the new event button 33 has been pressed. This determination is made based on whether or not the mouse 2d is clicked with the cursor at the position of the new event button 33. As a result, if the new event button 33 has been pressed, the process proceeds to step SP92, and if the new event button 33 has not been pressed, the process proceeds to step SP94.
[0213]
In step SP92, the IN point or OUT point is replaced with clip image data marked in step SP88, and this is registered as a new event. For example, if the IN point is marked at step SP88, the new IN point and the section to the already registered OUT point are registered as new events, and the OUT point is marked at step SP88. For example, the previously registered In point and the interval from the new Out point are registered as new events. At this time, as shown in FIGS. 9 to 11, second management record data relating to the event is newly generated.
In the next step SP93, the clip image data of the IN point of the new event is displayed in the event display area 29. When this process ends, the CPU 10 proceeds to the next step SP97 and ends the trimming process.
[0214]
On the other hand, if the new event button 33 has not been pressed and the process proceeds to step SP94, the CPU 10 determines whether or not the replace button 34 has been pressed. This determination is made based on whether or not the mouse 2d is clicked with the cursor at the position of the replace button 34. As a result, if the replace button 34 has been pressed, the process proceeds to step SP95, and if the replace button 34 has not been pressed, the process returns to step SP83 to repeat the process.
In step SP95, the CPU 10 replaces the IN point or OUT point with the clip image data marked in step SP88. That is, in this case, the contents of the second management record data relating to the event are simply replaced with the marked in-point or clip-out clip image data, and the original event contents are not registered. Just update.
In the next step SP96, the clip image data of the updated event in point is displayed at the position of the original event in the event display area 29. When this process ends, the CPU 10 proceeds to the next step SP97 and ends the trimming process.
[0215]
[Program creation]
Next, processing when creating a program using the generated event will be described with reference to the flowchart shown in FIG. Note that this flow chart starts from a state where an event has already been generated.
First, in step SP101 entered from step SP100, the CPU 10 determines whether or not an event has been designated. At this time, the CPU 10 determines that the event is designated when the mouse 2d is double-clicked (two consecutive click operations) with the cursor positioned at the display position (29a) of the clip image data in the event display area 29. .
As a result, when an event is designated, in the next step SP102, the CPU 10 puts the designated event into an active state, that is, a movable state.
[0216]
In the next step SP103, the CPU 10 determines whether or not the cursor has been moved with the mouse 2d still clicked, that is, whether or not it has been dragged. As a result, if it is dragged, the direction and distance in which the cursor has moved are calculated in the next step SP104. In the next step SP105, the CPU 10 changes the display position of the clip image data of the designated event based on the calculated direction and distance. Since the processing from step SP103 to step SP105 is performed quickly, the clip image data of the event seems to move together with the cursor on the screen of the monitor 2b.
[0217]
In the next step SP106, the CPU 10 determines whether or not the click button of the mouse 2d has been released, that is, whether or not the click has been released. As a result of the determination, if the click is not released, the process returns to step SP103 and repeats the process. If the click is released, the process proceeds to the next step SP107, where the cursor position when the click is released is calculated. .
In the next step SP108, based on the calculated cursor position, the CPU 10 determines whether another event is displayed on the right side of the display position of the event designated by the cursor position. As a result, if another event is displayed on the right side, the process proceeds to step SP109, and if another event is not displayed on the right side, the process proceeds to step SP110.
In step SP109, the CPU 10 moves the display position of the other event displayed on the right side to the right side so that the specified event can be inserted. When this is finished, the CPU 10 proceeds to step SP110.
[0218]
In step SP110, the CPU 10 displays clip image data of the designated event at a position on the program display area 30 designated by the cursor.
In the next step SP111, the CPU 10 updates the data content of the second management record data related to the program in accordance with the event insertion by the step SP110. Specifically, the pointer portion to the data linked before or behind in the second management record data is corrected. Since there is no second management record data for the newly inserted event, it is newly generated.
When this process is completed, the CPU 10 proceeds to the next step SP112 to determine whether or not to continue the program creation process. If so, the process returns to step SP101 and the process is repeated to finish the program creation process. In step SP113, the process is terminated.
[0219]
[Pre-roll]
Next, a pre-roll operation for automatically starting a reproduction operation from a position before a designated marking point and correcting the marking point will be described with reference to flowcharts shown in FIGS. This flow chart starts from the state in which the hybrid recorder 3 starts the recording operation of the video signal V1 and the video signal V2 is displayed on the recording video screen 21a.
First, in step SP121 entered from step SP120, the CPU 10 determines whether or not activation of the pre-roll mode is set. This determination is made based on whether or not the pre-roll button 22g in the timing display area 22 has already been clicked and activation of the pre-roll mode is designated.
In the next step SP122, the CPU 10 determines whether or not the above-described queue time has already been set as the pre-roll time in the environment setting. This determination is made based on whether or not the queue time is stored in the storage area for environment setting data in the RAM 10b. If it is determined that the pre-roll mode is activated and the pre-roll time is set, the CPU 10 proceeds to the next step SP123.
[0220]
In step SP123, the CPU 10 determines whether or not the mark-in button 24c in the recording video marking area 24 has been clicked to mark the in-point. As a result, if the in-point marking has been performed, the process proceeds to the next step SP124, where the clip image data of the in-point is generated. The clip image data is generated by reading the video data stored in the frame memory 11c into the VRAM 13b. At that time, since the data amount is thinned out to 1/16 by reducing the number of read samples, the clip image data having an image size of 95 pixels × 60 pixels is generated.
[0221]
In the next step SP125, the clip image data stored in the VRAM 13b is read and displayed in the clip display area 24a of the recording video marking area 24.
In the next step SP126, the CPU 10 calculates a time code for the queue. Specifically, the time code of the clip image data at the designated in point is referred to, and the set cut time is referred to, and the position shifted from the designated in point by the cut time (ie, playback time). Start time) is calculated.
In the next step SP127, the CPU 10 sends to the external interface 18 a reproduction command for reproducing the video data in real time from the calculated time code position. Receiving this, the external interface 18 converts the playback command into an RS-422 standard communication format and sends it to the hybrid recorder 3. Thus, the hybrid recorder 3 sequentially reads video data from the recording address corresponding to the instructed time code, thereby generating reproduced video data starting from the instructed time code. This video data is sent to the second video processor 12 in the computer 2 as a video signal V3.
[0222]
In the next step SP128, the second video processor 12 extracts a time code from the video signal V3 and performs image processing for converting the video signal V3 into digital component video data. The converted video data is temporarily stored in the frame memory 12c in the second video processor 12.
In the next step SP129, the playback video data stored in the frame memory 12c is reduced to 380 pixels × 240 pixels and then transferred to the VRAM 13b.
In the next step SP130, the reproduction video data stored in the VRAM 13b is displayed on the reproduction video screen 23a. As a result, real-time video data starting from a position before the in-point designated by the operator by the cute time is displayed on the playback video screen 23a.
[0223]
In the next step SP131, the CPU 10 determines whether or not marking has been performed. The determination as to whether or not the mark has been made is made based on whether or not the mouse 2d has been clicked with the cursor positioned in the area of the mark-in button 27c or mark-out button 27f in the playback video marking area 27. As a result, if the mark-in button 27c has been clicked, it is determined that the in-point has been specified, and the process proceeds to step SP132. If the mark-out button 27f has been clicked, it is determined that the out-point has been specified. Proceed to step SP135.
[0224]
In step SP132, in-point clip image data is generated. This IN-point clipped image data is generated by reading video data stored in the frame memory 12c into the VRAM 13b. At that time, since the data amount is thinned out to 1/16 by reducing the number of read samples, the clip image data having an image size of 95 pixels × 60 pixels is generated.
In the next step SP133, the clip image data at the IN point stored in the VRAM 13b is read out and displayed in the increment display area 27a.
In the next step SP134, the clip image data of the IN point that was previously marked and displayed in the clip display area 27a is moved to the clip display area 28. It should be noted that this process is not performed when the marking is not performed first and the clip image data is not displayed in the clip display area 27a. When the processing of step SP134 is completed, the CPU 10 proceeds to step SP142.
[0225]
On the other hand, if the process proceeds to step SP135 for marking the out point, clip image data of the out point is generated here. This out-point clipped image data is also generated by reading the video data stored in the frame memory 12c into the VRAM 13b. Also in this case, the clip image data of 95 pixels × 60 pixels is generated by thinning out the data amount to 1/16 at the time of reading.
In step SP136, the clip image data of the out point stored in the VRAM 13b is read and displayed in the outclip display area 27d.
[0226]
In the next step SP137, the CPU 10 determines whether or not the clip image data previously marked is the clip image data at the IN point. As a result, if the clip image data marked earlier is the clip image data at the in-point, the process proceeds to step SP138, and if the clip image data marked earlier is the clip image data at the out-point, step SP139. Proceed to
In step SP138, the CPU 10 determines whether or not to newly register as an event. This determination is made based on a click operation of the new event button 33 by the operator. If the new event button 33 is clicked and an event registration is instructed, the process proceeds to step SP140. If the new event button 33 is not clicked and no event registration is instructed, the process proceeds to step SP139.
[0227]
In step SP140, the CPU 10 registers the section from the in point to the out point as an event. At this time, as shown in FIGS. 9 to 11, second management record data relating to the event is generated.
In the next step SP 141, the clip image data of the generated in-point of the event is copied to the event display area 29, and the clip image data is displayed in the event display area 29. When this process ends, the CPU 10 proceeds to the next step SP142.
[0228]
On the other hand, if the clip image data generated by the previous marking is the clip image data of the out point and the process proceeds to step SP139, the clip image data of the out point generated by the previous marking is performed here. To the clip display area 28. It should be noted that this process is not performed when the marking is not performed first and the clip image data is not displayed in the out clip display area 27d. When the processing of step SP139 is completed, the CPU 10 proceeds to step SP142.
In step SP142, the CPU 10 determines whether or not an instruction to stop playback of the video data displayed on the playback video screen 23a has been issued. As a result, if playback stop is not instructed, the process returns to step SP131 and the process is repeated. If playback stop is instructed, the process proceeds to the next step SP143.
In step SP143, the CPU 10 sends a reproduction stop command to the hybrid recorder 3 via the external interface 18. As a result, the hybrid recorder 3 stops the video data reading operation and stops the reproduction operation. When the process of step SP143 is completed, the CPU 10 proceeds to step SP144 and ends the preroll process.
[0229]
(10) Operation and effect of the embodiment
In the above configuration, in the case of the editing system 1, two types of modes are prepared as a graphic display for GUI. One is a picture mode where you can edit the program by rearranging the events while viewing the clip image data of the registered in and out points of the registered event, and the other is visualizing the length of time of the registered event. It is a timeline mode in which events are rearranged while editing and the program is edited. In the editing system 1, the two modes can be easily switched by clicking the mode button 22f, so that the operator can select the GUI that is easier to use according to the editing purpose. Therefore, in the case of this editing system 1, the usability in editing work is improved as compared with the conventional editing system.
[0230]
For example, when there is no time restriction in the program, if you select the picture mode, you can edit while viewing the clip image data of the In point or Out point of each event. Editing work can be performed while checking whether the event is composed of contents. If there are time constraints in the program, select the timeline mode and the display area of each event will change according to the length of the event. Or the like, and a program having a desired length can be easily generated.
[0231]
In the case of the editing system 1, a program view area 42 is provided in the timeline mode, and clip image data at the in-point of each event constituting the program is displayed by the program view area 42. As a result, even in the timeline mode, it is possible to easily confirm what kind of event the generated program is composed of.
[0232]
In the case of the editing system 1, a pre-roll mode is provided in which when the mark-in button 24c is operated to designate an in point, a reproduction operation is automatically performed from a position a predetermined time before the position of the in point. ing. Accordingly, if such a pre-roll mode is activated in advance, for example, even when the ball hit by the butter stands at the time of baseball broadcast and the mark-in button 24c is clicked to specify the in-point. Since the playback operation is automatically performed from a position a predetermined time before the in-point, the in-point can be easily corrected by clicking the mark-in button 27c on the playback side while viewing the playback screen. An event including a desired scene such as a moment when a ball is hit can be easily created in real time.
[0233]
In the case of the editing system 1, the playback speed setting area 25 can be used to set the playback speed of the event to an arbitrary speed. This makes it possible to set slow playback for an event at the moment of hitting a home run in a baseball broadcast, for example, an event that represents the movement of the butter and the direction of the ball more realistically by slow playing the event of the home run scene Can be generated and provided to the viewer.
[0234]
Further, in the case of the editing system 1, since the hybrid recorder 3 capable of recording and reproducing at the same time is used, real-time editing can be performed by simultaneously recording and reproducing.
Further, in the case of the editing system 1, the video signal V2 on the source side, the video signal V3 obtained by reproducing the edited event or program, or clip image data indicating the event or program is displayed on one monitor 2b. By doing so, it is not necessary to provide a plurality of monitors as in the prior art, so that the editing operation can be performed sufficiently even in a limited environment at the site, and the configuration of the entire editing system can be simplified. it can.
[0235]
According to the above configuration, when the mark-in button 24c is operated to specify the point-in, the playback operation is automatically started from a position a predetermined time before the position of the point-in and the reproduced video signal is reproduced. By displaying V3 on the monitor 2b, even if the IN point instruction is delayed, the IN point can be easily corrected by operating the mark-in button 27c on the playback side while viewing the playback screen. An event including a desired scene can be easily created in real time. Further, by using the hybrid recorder 3 capable of recording and reproducing at the same time, real-time editing can be performed by simultaneously recording and reproducing. In this way, it is possible to realize an editing system 1 with improved usability that can realize high-speed real-time editing.
[0236]
(11) Other embodiments
In the above-described embodiment, the case where the hybrid recorder 3 including the hard disk drive 300 and the video tape recorder 301 is used as the recording / reproducing device has been described. However, the present invention is not limited to this, and the hard disk drive is simply configured. A recording / reproducing apparatus may be used. In short, recording means for recording source video data on a recording medium, playback means for reproducing source video data recorded on the recording medium while recording source video data on the recording medium, and source video to be recorded Any recording / reproducing apparatus having output means for outputting data and source video data to be reproduced and capable of simultaneously recording and reproducing can obtain the same effects as those of the above-described embodiments.
[0237]
In the above-described embodiment, the case where various instructions and various information are input to the editing system 1 using the keyboard 2c, the mouse 2d, or the dedicated controller 2e has been described. However, the present invention is not limited thereto, and other inputs are possible. Various instructions and various information may be input using a device. In short, it is only necessary to provide user interface means for inputting various instructions and various information from the operator to the editing system 1.
[0238]
In the above-described embodiments, the case where the pre-roll mode is controlled by the CPU 10 has been described. However, the present invention is not limited to this, and when the recording-side video data in-point is designated, the in-point is controlled. If a control means is provided for outputting a playback command for starting a playback operation from a position before a predetermined time to the recording / playback apparatus and displaying the video data played back from the recording / playback apparatus on the display means, The same effects as those described above can be obtained.
[0239]
【The invention's effect】
According to the present invention, while recording the source video data supplied from the outside on the recording medium, the source video data recorded on the recording medium is reproduced according to the reproduction command, and via the user interface means. Among the events formed from the first or second video data from the designated In point to the Out point, the reproduction speed of the second video data for the desired event designated through the user interface means is set. The playback speed specified through the user interface means is set. This makes it possible to perform real-time editing by simultaneously performing recording and playback, and can set different slow playback within the event to provide viewers with more powerful video, thus speeding up real-time editing. An editing system with improved usability can be realized.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of an editing system according to an embodiment of the present invention.
FIG. 2 is a block diagram showing an internal configuration of a computer constituting the editing system.
FIG. 3 is a schematic diagram showing a GUI in a picture mode.
FIG. 4 is a schematic diagram showing a GUI in a timeline mode.
FIG. 5 is a schematic diagram showing a configuration of a timeline display area.
FIG. 6 is a chart for explaining first management record data;
FIG. 7 is a chart for explaining second management record data for clip data.
FIG. 8 is a chart for explaining second management record data for event data and program data;
FIG. 9 is a chart for explaining an index number, a clip number, and an event number.
FIG. 10 is a schematic diagram illustrating a display example of each display area.
FIG. 11 is a schematic diagram for explaining a management method using first and second management record data;
FIG. 12 is a block diagram showing a configuration of a hybrid recorder.
FIG. 13 is a schematic diagram illustrating a configuration of a reproduction speed setting area.
FIG. 14 is an external view showing a configuration of a dedicated controller.
FIG. 15 is a chart for explaining a storage format of speed data.
FIG. 16 is a schematic diagram showing a queue setting screen.
FIG. 17 is a schematic diagram for explaining a pre-roll mode.
FIG. 18 is a schematic diagram for explaining a hierarchical structure for storing work data;
FIG. 19 is a flowchart for explaining an initial operation.
FIG. 20 is a flowchart for explaining the marking operation on the recording side.
FIG. 21 is a flowchart for explaining the marking operation on the reproduction side.
FIG. 22 is a flowchart for explaining the marking operation on the reproduction side.
FIG. 23 is a flowchart for explaining a trimming operation;
FIG. 24 is a flowchart for explaining a program creation operation.
FIG. 25 is a flowchart for explaining a pre-roll operation.
FIG. 26 is a flowchart for explaining a pre-roll operation.
[Explanation of symbols]
1 ... Editing system, 2 ... Computer, 2a ... Main body, 2b ... Monitor, 2c ... Keyboard, 2d ... Mouse, 2e ... Dedicated controller, 3 ... Hybrid recorder, 10 ... CPU, 11 ... First video processor, 12... Second video processor, 13... Display controller, 21 ..Recording video display area, 22... Timing display area, 23. ... Recording video marking area, 25 ... Playback speed setting area, 26 ... Recycle box area, 27 ... Playback video marking area, 28 ... Clip display area, 29 ... Event display area, 30 ... Program display area, 40 …… Timeline display area, 41 …… Edit tool display area, 42 …… Program viewer A.

Claims (5)

In an editing system having a main recording / reproducing device and a computer,
The main recording / reproducing apparatus comprises:
Recording means for recording source video data supplied from the outside on a recording medium;
Reproducing means for reproducing the source video data recorded on the recording medium in response to a reproduction command from the computer while recording the source video data on the recording medium;
The source video data recorded on the recording medium is output to the computer as first video data, and the source video data reproduced by the reproducing means is output to the computer as second video data. Output means,
The above computer
User interface means,
And Table shows means,
Of the events formed from the first or second video data from the In point to the Out point specified via the user interface means, a desired event specified via the user interface means is selected. An editing system comprising: control means for setting the reproduction speed of the second video data to a reproduction speed designated via the user interface means. The control means includes
2. The editing system according to claim 1, wherein clip image data corresponding to an in point or an out point of the event is displayed and a playback speed of the second video data for the desired event is set. The control means includes
Rotary diene for inputting the reproduction speed - da or slide ene - editing system according to claim 1, characterized in that it comprises a da. The control means includes
The editing system according to claim 1, wherein a reproduction speed of the second video data for the desired event is set in units of frames. The control means includes
Display the playback speed setting area on the display means,
The playback speed setting area is
A scale display unit for displaying a scale indicating the length from the In point to the Out point of the event in the designated second video data ;
Based on the display position of the icon on the scale, a position display section showing a position where the playback speed is set in the event,
In-point time code display section showing the in-point time code of each event,
The editing system according to claim 1, further comprising: an out point time code display unit that indicates a time code of an out point of each event.

Images