JP3832444B2 - Editing method and system - Google Patents

Description

[0001]
[Industrial application fields]
The present invention relates to an editing method and an editing system suitable for application to, for example, an editing system using a VTR.
[0002]
[Prior art]
2. Description of the Related Art Conventionally, for example, in a broadcasting station, work for editing a material to be broadcast and recording it on a video tape cassette has been performed. For example, for editing a plurality of commercial (CM) materials into one video tape cassette and recording them, creating a so-called CM single tape, and editing and recording materials used in one program into a video tape cassette The editing work (for sending) corresponds to this.
[0003]
Usually, a video tape cassette in which the original material is recorded is called a material tape. The video tape cassette as the material tape is reproduced by the VTR, various signal processing is performed on the reproduction signal, and the material signal obtained by performing the signal processing is recorded on the video tape cassette used for broadcasting. Create a videotape cassette.
[0004]
FIG. 18 is a block diagram showing an example of a conventional editing system. The conventional editing system will be described below with reference to FIG.
[0005]
In FIG. 18, 1 is a video tape cassette as a material tape, and 13 is a broadcast video tape cassette. The video tape cassette 1 as the material tape is set in the playback side VTR 2 and played back, and the video tape cassette 13 for broadcasting is set in the recording side VTR, and the output from the DME (digital multi effector) 7 is recorded. . In this example, DME7 is used. However, as long as a tape for broadcasting is simply created, a system using an editing machine may be used, and a playback side VTR2 and a recording side VTR8 are connected. Things can be used.
[0006]
In other words, in the system shown in FIG. 18, the video tape cassette 1 as the material tape is played back on the playback side VTR 2 and the playback signal is subjected to special effect processing by the DME 7 and playback that has been subjected to this special effect processing. The signal is recorded in the broadcast video tape cassette 13 set in the recording side VTR 8.
[0007]
Further, in the reproducing side VTR 2 shown in FIG. 18, the reproducing head 3 is connected to one fixed contact 5a of the head switching switch 5, and the reproducing head 4 is connected to the other fixed contact 5b of the head switching switch 5. The movable contact 5c of the switch 5 is selectively connected to one or the other fixed contact 5a or 5b by a switching signal from a system controller (not shown) of the VTR body 6.
[0008]
Regardless of whether the playback side VTR2 is an analog VTR or a digital VTR, the video and audio signals output from the playback side VTR2 are based on 60 fields / second in the case of the NTSC system and 50 fields / second in the case of the PAL system. Supplied to DME 7 at a transfer rate. In the analog VTR, the video signal output from the reproduction side VTR 2 has a transfer rate of 60 fields / second in the NTSC format and 50 fields / second in the PAL format. In this example, analog video and audio input terminals and digital video and audio input terminals are provided as input terminals of the DME 7.
[0009]
In the DME 7, various processes such as special effects such as a mosaic effect, image movement, reduction, enlargement, and rotation are performed on the video signal from the reproduction-side VTR 2. This process is performed based on, for example, 60 fields / second in the NTSC system and 50 fields / second in the PAL system. The output of the DME 7 is supplied to the recording side VTR 8 and recorded in the video tape cassette 13 set after the analog or digital signal processing is performed in the VTR main body 12 of the recording side VTR 8. Is done.
[0010]
Similarly to the reproduction side VTR2, the recording side VTR8 is connected to the one fixed contact 11a of the head switching switch 11 and the recording head 10 is connected to the other fixed contact 11b of the head switching switch 11. ing. In the switch 11, the movable contact 11c is selectively connected to one or the other fixed contact 11a or 11b by a switching signal supplied to the VTR main body 12 from a system controller (not shown). This recording is also performed based on the same timing as described above, that is, 60 fields / second in the NTSC system and 50 fields / second in the PAL system.
[0011]
The applicant first displays the first and second points of the predetermined unit of image data on the display unit, and displays the first and second points of image data of the predetermined unit displayed on the display unit. The control means displays the time code data of the image data of the first or second point specified by the specifying means, the state of the related device, and the identification number, thereby improving the editing efficiency. An editing device that can improve usability, for example, editing files EDL1 to EDLn by deleting, copying, moving, and exchanging image data in edit units displayed on the screen using a pointing device or a keyboard. It is now possible to change the contents of multiple VTRs so that multiple VTRs can be played back and rechecked, or the memory address can be confirmed using a keyboard, etc. However, an editing apparatus has been proposed that can perform editing work without any troublesome work such as inputting it, thereby improving the efficiency of the editing work (Japanese Patent Application No. 5). -87413).
[0012]
[Problems to be solved by the invention]
By the way, as described above, conventionally, the transfer speed of the video signal in the editing system is 60 fields / second in the case of the NTSC system and 50 fields / second in the case of the PAL system, and the transfer speed of the video signal is the video signal. This is based on the field frequency or frame frequency.
[0013]
In the example of the editing system as shown in FIG. 18, the playback side VTR 2 plays back the material recorded in the video tape cassette 1 and outputs a video signal in 60 field seconds, and this 60 field / second video signal. Is processed on the basis of 60 field seconds by the DME 7, and the processed video signal of 60 field seconds is recorded on the video tape cassette 13 set in the recording side VTR 8.
[0014]
That is, as shown in FIG. 18, in the conventional editing system, the transfer speed is always determined uniquely by the field or frame frequency of the video signal, so that the video signal (of course, the audio signal) is edited and edited. In order to obtain the resulting videotape cassette 13, it was necessary to spend a very large amount of time. In particular, during the editing process, a process other than the process of operating the DME 7 (or switcher or the like) to perform desired processing on the playback video signal, that is, playback, transfer, recording, etc., which are not directly related to the operator performing the editing operation. (This is because the operator does not operate and process like the DME 7), and the extra time is consumed, which is a cause of deteriorating the editing work efficiency.
[0015]
In other words, the processing time in the DME 7 that is directly operated by the operator may be long, but playback on the playback side VTR 2, transfer of playback signals from the playback side VTR 2 to the DME 7, and from the DME 7 to the recording side VTR 8. The shorter the time spent for the transfer of the processing signal, the recording at the recording side VTR 8, etc., the shorter the time spent for the editing process. However, at present, as described above, since all processing is performed based on the field or frame frequency of the video signal, the time required for editing work is shortened, and a good editing environment that is easy for the operator to operate is provided. Can't offer.
[0016]
If the operator performs processing using the DME 7 and records the video signal as the processing result in the recording side VTR 8 and then determines that the processing by the DME 7 needs to be performed again, the operator sets the playback side VTR 2. The video tape cassette 1 being set to the original tape position, the video tape cassette 13 set in the recording side VTR 8 to the original tape position, and thereafter the playback side VTR 2 is set to the playback state and the recording side VTR 8 is set to the playback side. The recording state must be changed and the editing process must be performed again by operating the DME 7 again. This greatly deteriorates the work efficiency in editing. However, since the recording medium is a video tape cassette, it is inevitable that the editing process with low work efficiency is redone, and at present, such a problem cannot be solved. Also, if you try again and again, you may damage your valuable tape.
[0017]
Also, in the case of editing by mixing and switching two materials, another playback-side VTR 2 must be added to the editing system shown in FIG. As the number increases, the playback side VTR2 must be increased as much as possible.
[0018]
Further, the editing system as shown in FIG. 18 employs a method in which the reproduction signal reproduced by the reproduction side VTR 2 is processed by the DME 7 and the signal processed by the DME 7 is recorded in the recording side VTR 8. And recording the result on the video tape cassette a plurality of times on one video tape cassette. In this case, the video tape cassette 13 shown in FIG. 18 is formed by the previous recording process. Thus, a large number of edit points including the magnetic track and the magnetic track formed by the current recording process are formed. Since this editing point (or a joint portion consisting of the previous recording portion and the current recording portion) exists, when the video tape cassette 13 in which this many editing points exist is played back, for example, an image is displayed at the editing point. There is a high possibility that disturbance or the like will occur, or that the effect of the edit point will appear in the reproduced image.
[0019]
The present invention has been made in consideration of such points, and when the video tape cassette that has been created by editing is reproduced by simplifying the components of the editing system, making the editing work simple and efficient. The present invention is intended to propose an editing method and system capable of preventing the reproduction image from being affected by the editing point.
[0020]
[Means for Solving the Problems]
  The editing system of the present invention (first editing system) includes a semiconductor memory 155 and a writing / reading control unit 156. When storing input information in the semiconductor memory 155, the writing / reading control unit 156 includes: When a control signal for writing is supplied to the semiconductor memory 155 and the stored information is read from the semiconductor memory 155, the writing / reading control means 156 reads the information at a transfer rate n times the normal transfer rate. By supplying the semiconductor memory 155 with a read control signal at a speed n times faster than the write control signal used when storing the input information in the semiconductor memory 155, the information to be edited can be reproduced at a normal reproduction speed. a high-speed playback unit 21 that reproduces information at a speed n times and outputs information at a transfer speed n times the normal transfer speed; From the signal processing unit 25, a recording or storage unit 22 that records or stores the reproduction information from the unit 21, a signal processing unit 25 that performs predetermined signal processing on the information read from the recording or storage unit 22, and the signal processing unit 25 When the information outputted and recorded or stored in the storage unit 22 is read out at a transfer speed n times the normal transfer speed, the read information is read out by n times the normal recording or storage speed. A high-speed recording or storage unit 26 for recording or storing at a high speed, a high-speed playback unit 21, a recording or storage unit 22, a signal processing unit 25, and a control unit 28 for controlling the high-speed recording or storage unit 26. Alternatively, the storage unit 22 includes a first demultiplexer 61 that divides information at a transfer rate n times the normal transfer rate into a plurality of pieces of information, and a first demultiplexer 61 that divides input information at a normal transfer rate into a plurality of pieces of information. The demultiplexer 75, recording or storage means 78-1 to 78 -m for recording or storing a plurality of pieces of information from the first or second demultiplexer 61, 75, and recording or storage means 78-1. A matrix switcher 65 for selectively outputting a plurality of information read from 78-m, and a transfer speed n times the normal transfer speed read from the recording or storage means 78-1 to 78-m. It comprises a multiplexer 81 that converts a plurality of pieces of information into original information and outputs it.
  The editing system of the present invention (second editing system) reproduces information to be edited at a speed n times the normal playback speed and outputs the information at a transfer speed n times the normal transfer speed. 21, a recording or storage unit 22 that records or stores the reproduction information from the high-speed reproduction unit 21, a signal processing unit 25 that performs predetermined signal processing on the information read from the recording or storage unit 22, A semiconductor memory 155 and a write / read control means 156 are included, and information output from the signal processing unit 25 and recorded or stored in the recording or storage unit 22 is read at a transfer rate n times the normal transfer rate. When the read information is stored in the semiconductor memory 155, the write / read control means 156 supplies a control signal for writing to the semiconductor memory 155. Thus, the read / write control means stores the read information at a speed n times the normal storage speed and reads the stored information from the semiconductor memory 155 so that it can be read at the normal transfer speed. The high-speed storage unit 156 supplies the semiconductor memory 155 with a read control signal at a speed 1 / n times the write control signal used when storing information in at least the semiconductor memory 155, and the high-speed reproduction unit 21 A recording / storage unit 22, a signal processing unit 25, and a control unit 28 for controlling the high-speed recording / storage unit 26. The recording / storage unit 22 stores information on a transfer rate n times the normal transfer rate. A first demultiplexer 61 that divides the information into a plurality of pieces of information; a second demultiplexer 75 that divides input information of a normal transfer rate into a plurality of pieces of information; Recording or storage means 78-1 to 78-m for recording or storing a plurality of pieces of information from the demultiplexers 61 and 75, and a plurality of information read from the recording or storage means 78-1 to 78-m. A matrix switcher 65 for selectively outputting information, and a plurality of information having a transfer rate n times the normal transfer rate read from the recording or storage means 78-1 to 78-m is converted into the original information. And a multiplexer 81 that outputs the data.
[0028]
Further, in the editing system of the present invention, as described above, the recording or storage unit 22 is divided into information of a transfer rate n times the normal transfer rate into n pieces of information, and the input of the normal transfer rate. A second demultiplexer 75 that divides information into n pieces of information, and recording or storage means 78-1, 78- for recording or storing each piece of n pieces of information from the first or second demultiplexer 61, 75. 2,... 78-m, 80-1, 80-2,... 80-m, and a matrix switcher 65 for selectively outputting a plurality of information read from the recording or storage means , Recording or storing means 78-1, 78-2,... 78-m, 80-1, 80-2,. Convert n pieces of speed information to the original information Which is constituted by a multiplexer 81 to.
[0029]
Furthermore, the editing system of the present invention is the above-described first and second demultiplexers 61 and 75, recording or storing means 78-1, 78-2,... 78-m, 80-1, 80-2,. ... Between the 80-m and the matrix switcher 65 are the first or second demultiplexers 61 and 75 or recording or storage means 78-1, 78-2,... 78-m, 80-1. 80-2, ... 80-m are connected by the same number of buses 62-1, 62-2, ... 62-m, and buses 62-1, 62-2, ... Are provided with control units 64 and 76 for controlling temporal distribution of input / output information on 62-m.
[0031]
Further, the editing system according to the present invention is the above-described decompression means for temporally decompressing information at a transfer rate n times the normal speed from the high-speed reproducing unit between the output side of the recording or storage unit 22 and the input side of the signal processing unit 25. 23-1, 23-2,..., 23 -k, and the output of the signal processing unit or the input information from the outside between the recording or storage unit 22 and the output side of the signal processing unit or the outside And a compressing means 24 for temporal compression.
[0032]
Further, in the editing system of the present invention, the decompression means 23-1, 23-2,..., 23-k are information on the transfer speed n times the normal transfer speed read from the recording or storage unit 22. Buffer memory means 91-1, 91-2, ... 91-n, 92-1, 92-2, ... 92-n, 94, and buffer memory means 91-1, 91. ,... 91-n, 92-1, 92-2,..., 92-n, 94, and variable speed reproduction processing means 96, 97 for performing variable speed reproduction processing of the output information of the normal transfer rate; , Output means 102, 104, 98, 100 for outputting output information from the variable speed reproduction processing means 96, 97, and buffer memory means 91-1, 91-2,... Based on the control signal from the control unit 27. .. 91-n, 92-1, 92-2, ... 92- , 94, which is constituted by a reproduction control communication unit 107 for controlling the variable-speed reproduction processing unit 96, 97.
[0034]
Further, in the editing system of the present invention, as described above, the compression means is the input means 111, 113, 116, 118 for inputting the information of the normal transfer rate from the signal processing unit 25 or the outside, and the input means 111, 113, The buffer memory 121 temporarily stores output information from 116 and 118, the input means 111, 113, 116 and 118, and the recording control communication means 124 for controlling the buffer memory 121.
[0036]
[Action]
  According to the configuration of the editing system of the present invention described above, the high-speed playback unit 21 plays back information to be edited at a speed n times the normal playback speed and outputs the information at a transfer speed n times the normal transfer speed. Then, the reproduction information from the high-speed reproduction unit 21 is recorded or stored in the recording or storage unit 22, and the information read out from the recording or storage unit 22 is subjected to predetermined signal processing by the signal processing unit 25. When the information output from the processing unit 25 and recorded or stored in the recording or storage unit 22 is read at a transfer rate n times the normal transfer rate, the read information is recorded at a high-speed recording or storage unit. 26, recording or storage is performed at a speed n times the normal recording or storage speed, and the recording or storage unit 22, the signal processing unit 25, and the high-speed recording or storage unit 26 are controlled by the control unit 28. As a result, when editing information, the information to be edited can be reproduced, and the reproduction information can be transferred at a speed that is transferred and after the editing, and the recording speed can be greatly improved.
  Furthermore, according to the configuration of the first editing system of the present invention, even when a semiconductor memory is used, it is possible to reproduce and transfer information to be edited at a normal speed n times.
  Furthermore, according to the configuration of the second editing system of the present invention, even when a semiconductor memory is used, edited information can be recorded and transferred at a speed n times the normal speed. At the time of reproduction, a reproduction signal at a normal speed can be obtained.
[0044]
Furthermore, according to the configuration of the editing system of the present invention as described above, the information of the transfer rate n times the normal transfer rate is divided into n pieces of information by the first demultiplexer 61, and the input information of the normal transfer rate is changed to the first information. The information is divided into n pieces of information by two demultiplexers 75, and each piece of n pieces of information from the first or second demultiplexer 61, 75 is recorded or stored in a storage means 78-1, 78-2,. -M, 80-1, 80-2, ... 80-m are recorded or stored, and a plurality of information read from the recording or storage means is selectively output by the matrix switcher 65. Or storage means 78-1, 78-2,... 78-m, 80-1, 80-2,... With a transfer rate n times the normal transfer rate read from 80-m. The n pieces of information are converted to the original information by the multiplexer 81. To output. As a result, information on a transfer rate n times the normal transfer rate is recorded or stored, information on a transfer rate n times the recorded or stored normal transfer rate is read, and a transfer rate n times the normal transfer rate is read. Can be output.
[0045]
Furthermore, according to the configuration of the editing system of the present invention described above, the first demultiplexer 61, the recording or storage means 78-1, 78-2,... 78-m, 80-1, 80-2,. .. between the 80-m and the matrix switcher 65, the first or second demultiplexers 61 and 75, recording or storing means 78-1, 78-2,... 78-m, 80-1, 80 ,..., Connected by the same number of buses 62-1, 62-2,... 62-m as the number of information from 80-m, and the buses 62-1, 62-2,. ... Time distribution of input / output information on 62-m is controlled by the control units 64 and 76. As a result, recording, storage, reading, or the like in the recording or storage unit 22 can be performed efficiently.
[0048]
Further, according to the configuration of the editing system of the present invention described above, the expansion means 23-1, 23-2,... 23-k provided between the output side of the recording or storage unit 22 and the input side of the signal processing unit 25. Thus, the compression means provided between the input side of the recording or storage unit 22 and the output side of the signal processing unit or the outside extends the information of the transfer rate n times the normal speed from the high-speed playback unit 21 by time. Thus, the output of the signal processing unit or the input information from the outside is temporally compressed. As a result, information at a transfer rate n times the normal speed recorded or stored in the recording or storage unit 22 can be output so that it can be used by the signal processing unit 25, and n times the normal transfer rate from the recording or storage unit 22. Information can be output at a transfer rate and supplied to the high-speed recording or storage unit 26 for high-speed recording or storage.
[0049]
Furthermore, according to the configuration of the editing system of the present invention described above, information on the transfer rate n times the normal transfer rate read from the recording or storage unit 22 is stored in the buffer memory means 91-1, 91-2,. 91-n, 92-1, 92-2,... 92-n, 94, and this buffer memory means 91-1, 91-2,... 91-n, 92-1, 92-2,... 92-n, 94 are subjected to variable speed reproduction processing means 96, 97 to perform variable speed reproduction processing of normal transfer rate output information, and output information from the variable speed reproduction processing means 96, 97 is output. Based on the control signal from the control unit 27, the reproduction control communication means 107 outputs the data from the means 102, 104, 98, 100, and the buffer memory means 91-1, 91-2, ... 91-n, 92-1. , 92-2, ... 92-n, 94, variable speed playback To control the processing section 96 and 97. As a result, information of a transfer rate n times the normal transfer rate recorded or stored in the recording or storage unit 22 can be output at the normal transfer rate.
[0051]
Furthermore, according to the configuration of the editing system of the present invention described above, information on the normal transfer rate from the signal processing unit 25 or the outside is input by the input means 111, 113, 116, 118, and the input means 111, 113, 116, 118 are input. Output information from 118 is temporarily stored in the buffer memory 121, and the input means 111, 113, 116, 118 and the buffer memory 121 are controlled by the recording control communication means 124. As a result, the information on the normal transfer rate recorded or stored in the recording or storage unit 22 can be output at a transfer rate n times the normal transfer rate.
[0053]
【Example】
Hereinafter, an embodiment of the editing method and system of the present invention will be described in detail with reference to FIG. First, the case where the high-speed transfer devices 21 and 26 shown in FIG.
[0054]
[First embodiment]
[0055]
In FIG. 1, reference numeral 20 denotes a video tape cassette as a so-called material medium in which materials to be edited are recorded. The video tape cassette 20 is set in a high-speed transfer device 21. A specific internal configuration example of the high-speed transfer device 21 will be described later with reference to FIG. 2. When the high-speed transfer device 21 is a VTR, the recording or storage medium 20 is a video tape cassette. When the high-speed transfer device 21 is a VTR, the high-speed transfer device 21 generates a large number of video and audio signals recorded or recorded on the storage medium 20 based on a reproduction control signal Pc from a control unit 27 described later. The video and audio signals are reproduced by scanning at high speed with the head of No. 1 and reproduced at a normal transfer speed of n times.
[0056]
In other words, in the case of the NTSC system, a normal number of tapes that are running on a rotating drum that is rotated at a rotational speed n times the normal rotational speed of a tape that is traveling at a speed that is n times the normal tape traveling speed. By scanning with the head, the reproduced video and audio signals are transferred at a transfer rate n times the normal transfer rate.
[0057]
As a result, the high-speed transfer device 21 compresses and outputs the time axis, so that the playback video and audio signal 48p, which is n times the normal transfer rate, are supplied to the temporary recording or storage device 22. In this case, the reproduced video and audio signal 48p is digital video and audio data, but may be analog video and audio signals. In the case of analog video and audio signals (that is, when the high-speed transfer device 21 of FIG. 1 is an analog VTR), naturally, these analog video and audio signals must once be converted into digital data by an A-D converter.
[0058]
As the digital format, for example, various digital formats such as a component digital D1 format, a composite digital D2 format, or a component or composite digital format using compression encoding can be used.
[0059]
The temporary recording or storage device 22 records a playback video and audio signal 48p, which is n times the normal transfer rate from the high-speed transfer device 21, based on a high-speed recording / playback control signal FPc from the control unit 27 described later. Recording is performed at high speed in the area Ar1. Here, the recording medium used in the temporary recording or storage device 22 may be an optical disk (a magneto-optical disk, a write-once optical disk, an optical disk as a phase change medium), a hard disk (a fixed type or a removable type). It is possible to use a so-called silicon disk (semiconductor memory as a medium) or a flexible disk capable of recording information of at least 20 Mbytes on one disk.
[0060]
At the present time, it is better to use a hard disk that is fast in access and inexpensive per unit capacity. However, a silicon disk is better when considering the fastest access.
[0061]
The area Ar1 of the temporary recording or storage device 22 is composed of, for example, a plurality of units composed of a plurality of disks and one head, or is composed of a unit composed of one disk and a plurality of heads, or one disk And a single head and an output memory, a plurality of recorded materials can be reproduced simultaneously.
[0062]
In other words, the temporary recording or storage device 22 records or stores one or more materials in the area Ar1 of the temporary recording or storage device 22, and reproduces or records a single material recorded or stored in the area Ar1. Can be played.
[0063]
Further, as shown in the figure, this temporary recording or storage device 22 is an output interface circuit 23-1, 23-2 for outputting the video and audio data transferred at high speed at a reading rate of 60 fields / second. .. having 23-k The output interface circuits 23-1, 23-2,..., 23-k can be processed by a video special effect mixer 25 including a DME (digital multi-effector), an audio mixer, and the like which will be described later. This is what is needed. That is, a plurality of materials simultaneously reproduced from the area Ar1 are output at 60 fields / second via the output interface circuits 23-1, 23-2,... 23-k shown in FIG. It is supplied to the mixer 25.
[0064]
Also, as shown in the figure, the temporary recording or storage device 22 temporarily records the processed video and audio data from the video special effect mixer 25 at a transfer rate of 60 fields / second or the external video and audio data again. Alternatively, an input interface circuit 24 for recording or storing in the area Ar2 of the storage device 22 is provided. The input interface circuit 24 is necessary for temporarily recording or recording the video and audio data of the normal transfer speed from the video special effect mixer 25 and the video and audio data from the outside in the area Ar 2 of the storage device 22. is there.
[0065]
Now, the video and audio data supplied to the temporary recording or storage device 22 from the high-speed transfer device 21 and recorded at high speed is read out at high speed by the high-speed recording / reproduction control signal FPc from the control unit 27, and reproduced video and audio are reproduced. The data is supplied to the output interface circuit 23-1, 23-2,.
[0066]
The video and audio data supplied to the output interface circuit 23-1, 23-2,..., Or 23-k is output from the control unit 27 at a normal speed (60 field / Are output at 60 fields / second on the basis of the reproduction control signal NPc for k channels at a speed of 2 seconds) and supplied to the video special effect mixer 25, respectively.
[0067]
The video special effect mixer 25, which has already been described, includes, for example, a DME, a switcher, and an audio mixer. Each video and audio from the output interface circuits 23-1, 23-2,... 23-k. Of video and audio data from the data or output interface circuits 23-1, 23-2,..., Or 23-k, video data is subjected to video special effect processing, and audio data is processed by an audio mixer. Apply. These video and audio processes are performed based on the effect control signal Ec from the control unit 27.
[0068]
The various processed 60 field / second output from the video special effect mixer 25 is again supplied to the temporary recording or storage device 22, and at this time, it is recorded at 60 fields / second in the area Ar2 shown in FIG. The recorded video and audio data is read at high speed based on the high-speed recording / reproducing control signal FPc from the control unit 27, and as shown in the figure, the video and audio data 31r is read at 60 fields / second. Is supplied to the high-speed transfer device 26 at a transfer speed of n times.
[0069]
A specific internal configuration example of the high-speed transfer device 26 will be described later with reference to FIG. 2. When the high-speed transfer device 26 is a VTR, the high-speed transfer device 26 receives a recording control signal from a control unit 27 described later. Based on Rc, the video and audio data 31r supplied to the video tape cassette 29 are recorded at high speed.
[0070]
In the case of the NTSC system, a normal number of recording / reproducing heads mounted on a rotating drum rotated at a rotation speed n times the normal rotation speed of a tape running at a speed n times the normal tape traveling speed. By sequentially scanning, video and audio signals are recorded at a speed n times the normal speed. This recording speed is n times the normal speed (60 fields / second in the NTSC system and 50 fields / second in the PAL system).
[0071]
When reproduction is performed by the high-speed transfer device 26, reproduction is performed at a normal reproduction speed. As a result, the time axis is expanded (for recording) and output, so that it is output as a video and audio signal of 60 fields / second in digital or analog form. If this editing system is connected to a transmission system or the like, video and audio signals output at 60 fields / second are supplied to the transmitter via the master switcher under the control of the control system of the transmission system. Then, it is transmitted as radio waves from the antenna of this transmitter. The reproduced video and audio signals in this case are digital video and audio data, but may be analog video and audio signals.
[0072]
In the editing system described above, various control signals as described above by the control unit 27 based on the operation of the operation unit 28 shown in FIG. 1 are transferred to the high-speed transfer device 21, the temporary recording or storage device 22, the video special effect mixer 25, and the high-speed transfer. This is done by supplying to the machine 26. Although not shown, the operation unit 28 includes high-speed transfer devices 21 and 26, temporary recording or storage device 22, operation keys that can directly operate the video special effect mixer 25, and video and audio data recorded in the temporary recording or storage device 22. It is assumed that a display unit for displaying various keys for setting the reading method, editing information, editing menu, and time code from the high-speed transfer devices 21 and 26 in hour, minute, second, and frame is provided.
[0073]
Here, the editing process of the editing system described above will be described in consideration of the operation of the operation unit 28 by the operator, the control of the control unit 27 by this operation, and the operation of each component by this control.
[0074]
First, the operator loads the video tape cassette 20 as the material medium onto the high-speed transfer device 21. Thereafter, the operator operates an operation key (not shown) or an operation panel (not shown) of the operation unit 28 or the high-speed transfer device 21 to cut a material cut (one or continuous image and audio data used as one material) used for editing. look for.
[0075]
When the head of the material cut to be used during reproduction is determined, the operator presses the operation key of the operation unit 27 or the high-speed transfer device 21, for example, or displays it on the display unit of the operation unit 28 or the high-speed transfer device 21 at that time. When the recorded time code is written down electronically or on paper or the like, and the last part of the material cut to be used is determined in the same manner, the operator presses the operation key of the operation unit 27 or the high-speed transfer machine 21, for example. Alternatively, the time code displayed on the operation unit 28 or the display unit of the high-speed transfer device 21 at that time is recorded electronically or on paper.
[0076]
When a memo, for example, an operation key is pressed electronically, the first and last time codes of the material cut (hereinafter referred to as start time code and end time code) are stored in a memory (not shown) of the control unit 27. . When a note is made on paper or the like, the time code written by the operator via the operation key of the operation unit 28 is input. Whichever method is used, the start time code and the end time code of the material are stored in the memory of the control unit 27.
[0077]
The processing of setting the tape position of the video tape cassette 20 to the position of the starting time code of the material may be performed manually by the operator operating the high-speed transfer device 21, or the operator operating the operation key of the operation unit 28. In such a case, the control unit 27 performs rewinding or fast-forwarding control on the high-speed transfer device 21, and control is performed so that the time code supplied from the high-speed transfer device 21 at this time matches the start time code held. You may do it. Also, the time code may be VITC (Vertical Interval Time Code) or LTC (Longitudinal Time Code).
[0078]
After the start time code and the end time code of the material are stored in the memory of the control unit 27, for example, when the operator operates an operation key for instructing the start of editing of the operation unit 28 (not shown), the control unit 27 causes the high-speed transfer machine to operate. A playback control signal Pc is supplied to 21 and a high-speed recording / playback control signal FPc is supplied to the temporary recording or storage device 22. When the reproduction control signal Pc is supplied from the control unit 27, the high-speed transfer device 21 reproduces video and audio signals recorded on the set video tape cassette 20 at high speed. As described above, the normal number of tapes on which the high-speed transfer machine 21 is running at a speed n times the normal tape running speed is mounted on a rotating drum that rotates at a speed n times the normal speed. By scanning with the recording / reproducing head, the reproduced video and audio signals are transferred to the temporary recording or storage device 22 at a speed of n times 60 fields / second.
[0079]
As a result, the video and audio signals transferred at a transfer rate n times the normal transfer rate are temporarily recorded or recorded or stored in the area Ar1 of the storage device 22. It should be noted that the manual operation, that is, the high-speed transfer device 21 is manually reproduced without operating the operation key of the operation unit 28 indicating the start of editing, and the reproduction signal is supplied to a television monitor or the like on the tube surface. The image can be projected and temporarily recorded while being monitored, or manually recorded in the storage device 22 by operating the operation unit 28. Of course, since manual operation (recording start and recording end) is performed while monitoring, the output transfer rate of the high-speed transfer device 21 in this case needs to be 60 fields / second.
[0080]
It should be noted that materials other than the video tape cassette 20, for example, still image materials such as camera images and graphics, and audio materials such as announcements and background music, are temporarily recorded or externally stored in the storage device 22 by an operation of the operation unit 28. Temporary recording from the input terminal or recording or storage in the area Ar1 of the storage device 22 is used for editing in the same manner as other materials. Either the material from the outside or the material obtained by reproducing the video tape cassette 20 may be temporarily recorded or recorded in the storage device 22 first.
[0081]
After all materials are recorded or stored in the area Ar1 of the temporary recording or storage device 22, editing is performed using the operation unit 28, the control unit 27, the temporary recording or storage device 22, and the video special effect mixer 25. Become. When the operator operates an operation key for designating a certain reproduction pattern on the operation unit 28, commands assigned to the operation key from the control unit 27 to the temporary recording or storage device 22, for example, slow motion reproduction, quick motion reproduction Various reproduction commands such as are supplied. When such commands indicating playback at various playback speeds are supplied to the output interface circuits 23-1, 23-2,... 23-k of the temporary recording or storage device 22, the temporary recording or storage device Each of the output interface circuits 23-1, 23-2,..., 23-k outputs a material that is temporarily recorded or read from the area Ar1 of the storage device 22 at a speed based on the command.
[0082]
This output is supplied to the video special effect mixer 25. The video special effect mixer 25 is supplied with an effect control signal Ec supplied from the control unit 27 when the operator operates the operation unit 28. The effect control signal Ec is a signal for effect control to be synchronized with the transfer timing of video and audio data output from the temporary recording or storage device 22.
[0083]
The video and audio data processed by the video special effect mixer 25 is again supplied to the temporary recording or storage device 22 at a transfer rate of 60 fields / second, and recorded or recorded in the area Ar2 of the temporary recording or storage device 22 through the input interface circuit 24. Remembered.
[0084]
When editing of all materials is completed, the edited material is recorded or stored as one program material in the area Ar2 of the temporary recording or storage device 22, for example. When the operator operates an operation key for designating high-speed reading of the operation unit 28, a high-speed recording / reproduction control signal Pc is supplied from the control unit 27 to the temporary recording or storage device 22. The material recorded or stored in the area Ar2 is read at high speed, transferred at high speed to the high speed transfer device 26, and recorded at high speed on the video tape cassette 29 set in the high speed transfer device 26.
[0085]
When the material recorded on the video tape cassette 29 is used, for example, for transmission, the high-speed transfer device 26 sets the running speed of the tape of the video tape cassette to the normal speed in order to output at 60 fields / second. Perform playback. As a result, video and audio signals of 60 fields / second are output from the high-speed transfer device 26.
[0086]
Next, configuration examples of the high-speed transfer devices 21 and 26, the temporary recording or storage device 22, and the video special effect mixer 25 shown in FIG. 1 will be described with reference to FIGS.
[0087]
First, the case where the high-speed transfer devices 21 and 26 shown in FIG. 1 are VTRs will be described with reference to FIG. Note that FIG. 2 shows a configuration example in which both the high-speed transfer devices 21 and 26 are capable of recording / reproducing. Therefore, the high-speed transfer device 21 may be constituted only by the reproduction system shown in FIG. 2, and the high-speed transfer device 26 may be constituted only by the recording system shown in FIG.
[0088]
In FIG. 2, reference numeral 30 denotes an external input terminal for the high-speed transfer device 21, and video and audio data 31r transferred at high speed from the temporary recording or storage device 22 shown in FIG. Input terminal.
[0089]
Video and audio data 31 r transferred at high speed via the input terminal 30 is supplied to the input interface circuit 31. This input interface circuit 31 buffers and outputs the video and audio data transferred at high speed.
[0090]
Data from the input interface circuit 31 is supplied to an ECC (Error Correction Code) adding circuit 33-1. The ECC adding circuit 33-1 adds ECC to video and audio data. The video and audio data to which the ECC is added by the ECC adding circuit 33-1 is supplied to a CHCOD (channel coding) circuit 34-1 and subjected to recording modulation processing (digital modulation processing).
[0091]
The video and audio signals that have undergone recording modulation processing in the channel coding circuit 34-1 are supplied to the movable contact 36c of the switch 36-1 via the recording amplification circuit 35-1.
[0092]
One fixed contact 36a of the switch 36-1 is connected to the primary side of the rotary transformer 37-1, and the other fixed contact 36b of the switch 36-1 is connected to the primary side of the rotary transformer 37-2.
[0093]
The switch 36-1 switches the recording / reproducing heads 38-1 and 38-2 by connecting the movable contact 36c to one or the other fixed contact 36a or 36b based on a switching signal SW1 from the system controller 50 described later. I do. The controller 40 controls a tape transport unit including the rotary transformer 37-1, a tape loading mechanism (not shown), and a recording / reproducing head 38-1.
[0094]
Accordingly, at the time of recording, the video and audio signals from the recording amplifier circuit 35-1 are recorded via the one or other fixed contact 36a or 36b of the switch 36-1 and the rotary transformers 37-1 and 37-2, respectively. / Sequentially supplied to the reproducing heads 38-1 and 38-2 and recorded on the magnetic tape 39 so as to form an inclined track.
[0095]
The recording / reproducing heads 38-1 and 38-2 are mounted so that they face each other on a rotating drum (not shown) and the intervals between the recording / reproducing heads 38-1 and 38-2 are equal. Here, the number of recording / reproducing heads 38-1 and 38-2 is such that the magnetic tape 39 travels at n times the normal traveling speed, and the rotational speed of the rotating drum is n times the normal rotational speed. When the data transfer rate is set to n times the normal transfer rate in such a state, the normal number (for example, two) is obtained.
[0096]
At the time of recording, the magnetic tape 39 is run at a speed n times the normal running speed, and the rotation speed of a rotating drum (not shown) is set to a rotation speed n times the normal speed.
[0097]
In this example, since the video and audio data to be recorded is supplied from the channel coding circuit 33-1 to the recording amplification circuit 35-1, each recording / reproducing head 38-1, 38-2 is connected to the recording amplification circuit 35-. 1, the recording current is sequentially supplied.
[0098]
Now, the recording data recorded on the magnetic tape 39 is sequentially reproduced by the recording / reproducing heads 38-1, 38-2. As described above, the traveling speed of the magnetic tape 39 is n times the normal traveling speed, and the rotation speed of the rotating drum is n times the normal rotating speed, so that the reproduction data transfer speed is n times the normal speed. Can be.
[0099]
Reproduced signals from the recording / reproducing heads 38-1 and 38-2 are sequentially (reproduced in the order of reproduction) to one and the other fixed contacts 36a and 36b of the switch 36-1 via rotary transformers 37-1 and 37-2. ) Supplied. The switch 36-1 is supplied with a switching signal SW1 from the system controller 50 in the same manner as in recording. As a result, the switch 36-1 connects the movable contact 36c to one or the other fixed contact 36a or 36b.
[0100]
Accordingly, the reproduced signal sequentially reproduced is sequentially supplied to the data extraction circuit 43-1 via one or the other fixed contact 36a or 36b of the switch 36-1 and the reproduction amplifier circuit 42-1. The data extraction circuit 43-1 extracts a clock signal from the reproduction signal supplied from the reproduction amplifier circuit 42-1, and extracts video and audio signals using the extracted clock signal. The video and audio data extracted by the data extraction circuit 43-1 is supplied to a CHDEC (channel decoding) circuit 44-1.
[0101]
The channel decoding circuit 44-1 demodulates the video and audio signals (digitally modulated) from the data extraction circuit 43-1 to obtain the original video and audio data, and error-corrects the demodulated video and audio data. Supply to circuit 45-1.
[0102]
The error correction circuit 45-1 performs error correction processing on the video and audio data based on the ECC added to the video and audio data supplied from the channel decoding circuit 44-1, and performs error correction processing. Video and audio data are supplied to the output interface circuit 47. Here, when error correction is performed using ECC added to video and audio data, error correction processing is performed on data that cannot be corrected, and data closest to the original data is restored.
[0103]
The output interface circuit 47 temporarily buffers and outputs the video and audio data 46O1 supplied from the error correction circuit 45-1. The output 46O1 is output from the output terminal 48, and is supplied to the temporary recording or storage device 22 as video and audio data 48p in the high-speed transfer device 21 shown in FIG.
[0104]
By the way, in the case of the high-speed transfer device 26, if the high-speed transfer device 26 is used for output in the transmission system, if the reproduced video and audio data are compressed data, the next stage of the transmission system (for example, cassette Auto changer, master switcher, and transmitter) must have a circuit for extending the time axis. In order not to modify the next stage system, the output of the error correction circuit 45-1 is output by the output interface circuit 41. It is necessary to extend the time axis.
[0105]
That is, when the configuration shown in FIG. 2 is applied to the high-speed transfer device 26 shown in FIG. 1, the output terminal of the error correction circuit 45-1 is connected to the input terminal of the output interface circuit 41 as shown in FIG. The output interface circuit 41 may convert the original data and output the data. In this way, for example, it is possible to connect a television monitor or the like to the output terminal 41a of the output interface circuit 41 and monitor the video image displayed on the tube surface.
[0106]
49 is an operation unit (not shown) having a display unit and a group of operation keys, for example. When the operation unit 49 is operated, or the recording / reproduction control signal from the control unit 27 shown in FIG. 1 is supplied to the system controller 50 via the input terminal 51, the system controller 50 is connected to the system clock / A control signal is supplied to the synchronization signal generation circuit 52.
[0107]
As a result, the system clock / synchronization signal generation circuit 52 has the above-described input interface circuit 31, ECC addition circuit 33-1, channel coding circuit 34-1, data extraction circuit 43-1, channel decoding circuit 44-1, error correction circuit. 45-1 and supply the necessary system clock and synchronization signal to the output interface circuit 47, respectively.
[0108]
As can be seen from the above description, in the above-described example, the transfer rate has been described as being four times the normal transfer rate, but the transfer rate can also be varied. That is, the transfer rate required by the operator can be set to the transfer rate designated by the operation key of the operation unit 28 shown in FIG.
[0109]
For this, it is possible to adopt a method of changing the number of rotations of the rotating drum in accordance with the designated transfer speed. This method has the advantage that the recording / reproducing head mounted on the rotating drum can be completed with the minimum necessary number (ordinary number of heads). In any case, in order to vary the transfer rate in this way, the system clock of the circuit must be varied in conjunction with this, but the system clock can be a known VCO (voltage controlled oscillator) or a high frequency. This can be easily realized with a crystal oscillator and frequency divider and a low-frequency crystal oscillator and multiplier.
[0110]
In this method, since the number of heads is determined, the transfer speed can be changed by changing the rotational speed of the rotary drum and the traveling speed of the magnetic tape 39. That is, the running speed of the magnetic tape 39 and the rotational speed of the rotary drum may be determined so that the number of tracks to be recorded or reproduced in the same time as normal reproduction or recording can be increased to n times the normal number.
[0111]
Next, the operation of the high-speed transfer device 21 or 26 shown in FIG. 2 will be described with reference to FIGS.
[0112]
It demonstrates from FIG. In FIG. 6, FD indicates frame data, TD indicates track-corresponding data, and TP indicates a track pattern. In this example, frame data P, P + 1, P + 2, and P + 3 (explained only by the amount shown in FIG. P + 4, P + 5,... Are transferred in one frame period as real time. Dn / F is data for one frame, the code in parentheses attached to TDn indicates the head number, Tn / F indicates the track for one frame, and the solid line arrow in the upper part of the figure indicates the transfer In the order, the solid line arrows shown in the lower part indicate the tracks recorded in one frame period of the real time Tn in the tape running direction (in this example, quadruple speed running).
[0113]
First, focusing on the frames P and P + 1, the frame P is the first track TD1 (H1), TD2 (H2),... TD8 (H2),. That is, the first track corresponding data TD1 of the frame P is “H1”, that is, recorded by the recording / reproducing head 38-1 shown in FIG. 2, and the second track corresponding data TD2 is “H2”, that is, FIG. The eighth track corresponding data TD8 is “H2”, that is, recorded by the recording / reproducing head 38-2 shown in FIG. The 12-track correspondence data TD12 is “H2”, that is, recorded by the recording / reproducing head 38-2 shown in FIG.
[0114]
Subsequently, the first track corresponding data TD1 of the frame P + 1 is “H1”, that is, recorded by the recording / reproducing head 38-1 shown in FIG. 2, and the second track corresponding data TD2 is “H2”, that is, FIG. Are recorded by the recording / reproducing head 38-2 shown in FIG. 2,... The TD12 corresponding data TD12 is "H2", that is, recorded by the recording / reproducing head 38-2 shown in FIG. In other words, in this example, the recording / reproducing heads 38-1 and 38-2 record the data corresponding to the track six times for one frame to form a track. Of course, this is because the tape format of the VTR in this example is 12 tracks per frame. Therefore, when the number of tracks in one frame is 8, the recording / reproducing heads 38-1 and 38-2 record the track-corresponding data four times in one frame to form a track.
[0115]
As a result, tracks T1, T2,... T12 are formed on the tape corresponding to the frame P as indicated by diagonal lines in the figure, and the track T1 corresponding to the frame P + 1 is indicated as indicated by dots in the figure. , T2, ... T12 are formed. Of course, each of the twelve tracks T1, T2,... T12 of each frame is recorded within one frame / 4 of real time. Accordingly, all the tracks T1 to T12 shown in the track pattern TP (for a total of 48 tracks in the figure) are recorded during one frame of real time.
[0116]
Next, referring to FIG. 7, data is transferred to the high-speed transfer device 26 shown in FIG. 2 at a speed four times the normal transfer speed, and the two recording / reproducing heads 38-1, 38- of the high-speed transfer device 26 are transferred. The operation in the case of recording video and audio data in 2 will be described. For easy understanding, the reference numerals of the signals shown in FIG. 7 are also shown in FIG.
[0117]
Reference numeral 31r is an input (high-speed transfer data) of the input interface circuit 31 of FIG. 2, 32I1 is an input of the ECC adding circuit 33-1 of FIG. 2, 35O1 is a recording amplification output of the recording amplification circuit 35-1 of FIG. 2 is a switching signal supplied from the system controller 50 to the switch 36-1, 38r1 is a recording signal of the recording / reproducing head 38-1 in FIG. 2, and 38r2 is a recording signal of the recording / reproducing head 38-2 in FIG. is there.
[0118]
The switching signal SW1 includes numbers “1” to “1” indicating the recording / reproducing heads 38-1 and 38-2 selected according to the high level “1” and the low level “0” of the switching signal SW1. 2 "is attached.
[0119]
First, the input interface circuit 31 shown in FIG. 2 receives video and audio data 31r having a transfer rate four times the normal transfer rate from the temporary recording or storage device 22 shown in FIG. Supplied. In FIG. 7, reference numerals T12D, T1D, T2D,..., T3D shown in the video and audio data 31r, respectively, indicate the configuration data of the twelfth track, the first track, the second track,. .
[0120]
The video and audio data 31r is supplied to the ECC adding circuit 33-1 via the input interface circuit 31. The output of the input interface circuit 31 is video and audio data 32I1 as shown in FIG. This video and audio data 32I1 is input to the ECC adding circuit 33-1.
[0121]
The video and audio data 32I1 is added with ECC by the ECC adding circuit 33-1, further digitally modulated by the channel coding circuit 34-1, and supplied to the amplifying circuit 35-1 for recording and amplification. The output 35O1 of the recording amplification circuit 35-1 is delayed from the input video and audio data 32I1 of the ECC addition circuit 33-1 as shown in FIG. This delay time is due to the processing in the ECC addition circuit 33-1 and the channel coding circuit 34-1. For example, the video and audio data 32I1 changes from the shaded portion to the shaded portion of the output 35O1 of the recording amplification circuit 35-1 as indicated by the solid arrow. Accordingly, the delay time for each video and audio data is the time indicated by the symbol RD in the figure. The video and audio signal (current signal) 35O1 output from the recording amplification circuit 35-1 is supplied to the movable contact 36c of the switch 36-1.
[0122]
When the switching signal SW1 supplied from the system controller 50 to the switch 36-1 is high level “1”, the switch 36-1 connects the movable contact 36c to one fixed contact 36a, and when the switching signal SW1 is low level “0”. The switch 36-1 connects the movable contact 36c to the other fixed contact 36b. Therefore, as shown on the switching signal SW1, the video and audio data T1D of the first track output from the recording amplification circuit 35-1 forms an inclined track on the magnetic tape 39 by the recording / reproducing head 38-1. The video and audio data T2D of the second track recorded and output from the recording amplification circuit 35-1 are recorded so as to form an inclined track on the magnetic tape 39 by the recording / reproducing head 38-2. Similarly, the recording / reproducing head 38-1 or 38-2 is selected by the switching signal SW1, and the video and audio data T3D after the third track are selected by the selected recording / reproducing head 38-1 or 38-2. ˜T12D are recorded alternately on the magnetic tape 39 so as to form an inclined track.
[0123]
Next, an operation when the video tape cassette 20 is reproduced by the high-speed transfer device 21 shown in FIG. 2 will be described with reference to FIG. In FIG. 8, video and audio data are reproduced by the two recording / reproducing heads 38-1 and 38-2 of the high-speed transfer device 21 shown in FIG. 2, and reproduced at a transfer rate four times the normal transfer rate. An operation for transferring data will be described. For ease of explanation, the reference numerals of the signals shown in FIG. 8 are also shown in FIG.
[0124]
8, 38p1 is a reproduction signal reproduced by the recording / reproduction head 38-1 shown in FIG. 2, 38p2 is a reproduction signal reproduced by the recording / reproduction head 38-2 shown in FIG. 2, and SW1 is a system controller. 50 is a switching signal, 42I1 is an input of the reproduction amplifier circuit 42-1, 46O1 is an output of the error correction circuit 45-1, and 48p is an output of the output interface circuit 47.
[0125]
When the switching signal SW1 supplied from the system controller 50 to the switch 36-1 is high level “1”, the switch 36-1 connects the movable contact 36c to one fixed contact 36a, and when the switching signal SW1 is low level “0”. The switch 36-1 connects the movable contact 36c to the other fixed contact 36b. Therefore, as indicated by the numbers “1” and “2” attached to the switching signal SW1, when the switching signal SW1 is at the high level “1”, the reproduction signal 38p1 from the recording / reproducing head 38-1 is reproduced by the reproducing amplifier circuit. When the switching signal SW1 is at a low level “0”, the reproduction signal 38p2 from the recording / reproducing head 38-2 is supplied to the reproducing amplifier circuit 42-1.
[0126]
As shown in FIG. 8, the reproduction signal 42I1 is supplied to the reproduction amplifier circuit 42-1, output after being reproduced and amplified in the reproduction amplifier circuit 42-1, and supplied to the data extraction circuit 43-1, where the data extraction is performed. A clock signal is reproduced in the circuit 43-1, and data is extracted by the reproduced clock signal. The video and audio signals from the data extraction circuit 43-1 are supplied to the channel decoding circuit 44-1, demodulated in the channel decoding circuit 44-1, converted into the original video and audio data, and error correction in the next stage. It is supplied to the circuit 45-1 and subjected to error correction processing as described above. The video and audio data 46O1 subjected to the error correction processing is supplied to the output interface circuit 47.
[0127]
PD indicates a delay time due to a processing time in the channel decoding circuit 44-1 and the error correction circuit 45-1.
[0128]
The compressed video and audio data 46O1 is supplied to the output interface circuit 47. The compressed video and audio data 46O1 supplied to the output interface circuit 47 is once buffered and then output from the output terminal 48 as high-speed video and audio data 48p, and is stored in the temporary recording or storage device 22 shown in FIG. Supplied.
[0129]
As can be seen from FIG. 8, the compressed video and audio data indicated by diagonal lines indicate the first track corresponding data T1D, the fifth track corresponding data T5D, and the ninth track corresponding data T9D, and the compressed video and audio data indicated by the dots are the first track corresponding data T1D. 2 track corresponding data T2D, 6th track corresponding data T6D, 10th track corresponding data T10D, compressed video and audio data indicated by diagonal lines opposite to the compressed video and audio data of the first, fifth and ninth tracks, The third track corresponding data T3D, the seventh track corresponding data T7D, and the eleventh track corresponding data T11D are shown. The white (indicating that there is no pattern) compressed video and audio data correspond to the fourth track corresponding data T4D and the eighth track. Data T8D and twelfth track corresponding data T12D are shown.
[0130]
Next, a configuration example of the temporary recording or storage device 22 shown in FIG. 1 will be described with reference to FIG.
[0131]
Reference numeral 60 denotes an input terminal to which the high-speed video and audio data 48p from the high-speed transfer device 21 shown in FIG. 1 is supplied. The high-speed video and audio data 48p reproduced through this input terminal 60 is supplied to the demultiplexer 61. Is done. The demultiplexer 61 divides and decompresses the high-speed video and audio data 48p, for example, by dividing the data into one-second data (4 times the transfer speed and 240 fields in the NTSC system), and dividing and decompressing each data. The 8-bit video and audio data 61p1, 61p2,... 61pm are obtained, and the video and audio data 61p1, 61p2,... 61pm are transferred to the buses 62-1, 62-2,. Are supplied to the disk controllers 80-1, 80-2,... 80-m as video and audio data 80r1, 80r2,. Here, the buses 62-1, 62-2,... 62-m are each composed of 8 bit lines for transmitting 8-bit video and audio data 62p1, 62p2,. Is done.
[0132]
The disk controllers 80-1, 80-2,... 80-m are sent from the buses 62-1, 62-2,... 62-m based on disk access control signals from the system controller 76 described later. The video and audio data 80r1, 80r2,... 80rm are supplied to the disk drives 78-1, 78-2,.
[0133]
Here, the disk drives 78-1, 78-2,... 78-m have already been described. However, the disk drives 78-1, 78-2,... 78-m can be configured by a hard disk, an optical disk, and a drive using a flexible disk having a recording capacity of at least 20 Mbytes as a medium. The disk controllers 80-1, 80-2,... 80-m are disk drives 78-1, 78-2,... 78-m based on disk access control signals from the system controller 76, respectively. Write to the medium set in the disk drive, and read data from the medium set in the disk drives 78-1, 78-2,... 78-m.
[0134]
Further, the system controller 76 records / reproduces control signals supplied from the control unit 27 shown in FIG. 1 via the input / output terminal 77, output interface circuits 23-1, 23-2,. In addition to supplying a disk access control signal to the disk controllers 80-1, 80-2,... 80-m based on a data reproduction control signal from k and a data recording control signal from the input interface circuit 24, an output interface .., 23-k, a recording control signal to the input interface circuit 24, a control signal to the demultiplexer 75 and the multiplexer 81, and buses 62-1, 62- 2,... 62-m, for example, a flag FLG for transfer synchronization control is set in a matrix to be described later. Supplying each of the selection control signal to the switcher 65.
[0135]
Here, the recording / playback control signal supplied from the control unit 27 records the high-speed video and audio data 48p supplied to the demultiplexer 61 in the disk drives 78-1, 78-2,... 78-m. In the case of indicating that this is to be done, the operator operates the operation unit 28 shown in FIG. 1 and designates the start frame and the end frame by inputting the time code while viewing the material necessary for editing. The media set in the disk drives 78-1, 78-2,... 78-m of the temporary recording or storage device 22 are subjected to a plurality of processes linked to the operation of the operator. A plurality of materials to be edited are recorded or stored in media set in the disk drives 78-1, 78-2,... 78-m, respectively.
[0136]
After the video and audio data transferred at high speed to the media set in the disk drives 78-1, 78-2,... 78-m are divided and recorded for one second as described above. When the recording / reproduction control signal supplied from the control unit 27 shown in FIG. 1 via the input / output terminal 77 indicates reproduction, the system controller 76 sends the disk access control signal to the disk controllers 80-1 and 80-2. ..., 80-m.
[0137]
The disk controllers 80-1, 80-2, ... 80-m control the disk drives 78-1, 78-2, ... 78-m, respectively, based on the disk access control signal from the system controller 76. The video and audio data recorded from the media set in each of the disk drives 78-1, 78-2,... 78-m are read, and the read video and audio data 80p1, 80p2,. .. 80 pm is supplied to the buses 62-1, 62-2,... 62-m, respectively.
[0138]
The video and audio data 80p1, 80p2, ... 80pm supplied to the buses 62-1, 62-2, ... 62-m are supplied to the matrix switcher 65, respectively. The matrix switcher 65 receives video and audio data 80p1, 80p2,..., 62-m supplied via the buses 62-1, 62-2,... 62-m based on a selection control signal from the system controller 76.・ ・ Select 80pm.
[0139]
This selection method is such that 8-bit parallel video and audio data 80p1, 80p2,... 80pm supplied via buses 62-1, 62-2,. Select and supply selectively to the output interface circuits 23-1, 23-2,... 23-k. Therefore, the video and audio data supplied to the output interface circuits 23-1, 23-2,... 23-m is 8 bits × m.
[0140]
The video and audio data 80p1, 80p2,... 80pm selected by the matrix switcher 65 are supplied to the output interface circuits 23-1, 23-2,. That is, the matrix switcher 65 shows m video and audio data 80p1, 80p2,... 80pm supplied via the buses 62-1, 62-2,. The number k used for the video special effect mixer 25. Of course, “n”, “m”, and “k” described above may be equal to each other, but as a merit, the video special effect mixer 25 currently used can be used.
[0141]
The output interface circuits 23-1, 23-2,... 23-k convert k video and audio data from the matrix switcher 65 into 60 fields / second and output terminals 67-1, 67-2. ,... 67-k are supplied to the video special effect mixer 25 shown in FIG. These output interface circuits 23-1, 23-2,..., 23-k are controlled as shown in FIG. 1 through input / output terminals 68-1, 68-,. A reproduction control signal from the unit 27 is supplied. The output interface circuits 23-1, 23-2,..., 23-k supply data reproduction control signals to the system controller 76, respectively.
[0142]
Now, the video special effect processing performed in the video special effect mixer 25 shown in FIG. 1 and the normal video and audio data subjected to the audio processing are supplied to the input interface circuit 24 via the input terminal 72. The Of course, external video and audio data having a normal transfer rate may be used. The input interface circuit 24 supplies a recording control signal to the system controller 76 based on the recording control signal supplied from the control unit 27 shown in FIG. The input interface circuit 24 once buffers and outputs video special effect mixer 25 or video and audio data from the outside.
[0143]
An output of the input interface circuit 24 is supplied to a demultiplexer 75, and the demultiplexer 75 divides the original video data into m pieces of video and audio data for one second. The divided m pieces of data are recorded on the disk controllers 80-1, 80-,... 80-m via buses 62-1, 62-2,. And audio data 80r1, 80r2,... 80rm.
[0144]
The disk controllers 80-1, 80-2,... 80-m are video and audio data 80r1, supplied from the demultiplexer 75 via the buses 62-1, 62-2,. ... 80 rm are recorded on the media set in the disk drives 78-1, 78-2,... 78 -m based on the disk access control signal from the system controller 76.
[0145]
Here, the relationship between the areas Ar1 and Ar2 of the temporary recording or storage device 22 shown in FIG. 1 and the disk drives 78-1, 78-2,... 78-m shown in FIG. There are two ways of thinking about the area. One is the idea that the media set in each disk drive 78-1, 78-2,... 78-m is divided into areas Ar1 and Ar2. One is the idea that the disk drives 78-1, 78-2,... 78-m are divided for the area Ar1 and the area Ar2.
[0146]
Further, although close to the former concept, for example, when a hard disk is used as a medium, when the hard disk is composed of a plurality of disks, the areas Ar1 and Ar2 may be set for each disk, or for each cylinder. Area Ar1 and Ar2 may be set, and a table is provided in the disk controllers 80-1, 80-2,... 80-m, and the video supplied from the demultiplexer 61 and The address of audio data and the address of video and audio data obtained by processing by the video special effect mixer 25 may be stored.
[0147]
In any case, at the time of editing, the material to be edited and the material obtained by editing exist, and the material to be edited may not be necessary in one editing ( In order to provide a convenient editing environment for the operator (for example, when editing is performed again), it is necessary to automatically manage the material to be edited and the material obtained by editing. Therefore, when the operator gives a name to the material for each editing unit recorded in the disk drives 78-1, 78-2,. Various information such as the name of each material and the data length (time data, etc.) may be displayed on the section (which may of course be provided in the operation section 28).
[0148]
That is, even if the material to be edited is not recorded or stored in the disk drives 78-1, 78-2,... 78-m in units of editing materials, the operator considers the editing work in units of editing materials and operates them. Will be able to.
[0149]
Also for playback by the disk controllers 80-1, 80-2,... 80-m, the operator operates a predetermined operation key of the operation unit 27 or executes a command displayed on the display unit. It may be possible to select a material and specify a playback method by clicking an icon with a mouse. For example, slow motion playback can be performed by intermittently reading video and audio data from the media set in the disk drives 78-1, 78-2,... 78-m, and once every few frames. As described above, reproduction called so-called quick motion can be performed by skipping frames and reading out.
[0150]
When the operator operates the operation unit 28 to cause the control unit 27 to issue a command to record the edited video and audio data in the high-speed transfer VTR 26, the system controller 76 causes the recording / reproduction control signal from the control unit 27 to be issued. Is supplied. The system controller 76 supplies a disk access control signal to each of the disk controllers 80-1, 80-2,... 80-m based on the recording / reproduction control signal from the control unit 27.
[0151]
Each of the disk controllers 80-1, 80-2,... 80-m controls the disk drives 78-1, 78-2,... 78-m based on a disk access control signal from the system controller 76. To do. As a result, the video and audio data subjected to special effect processing, audio processing, and the like by the video special effect mixer 25 are read from the disk drives 78-1, 78-2,... 78-m. The disk access control signal at this time performs reading control at a speed n times as high as the normal transfer speed.
[0152]
The video and audio data 80p1, 80p2,... 80pm respectively read from the disk drives 78-1, 78-2,... 78-m are supplied to the multiplexer 81. It is converted into continuous data, output as high-speed video and audio data 81p from the output terminal 82, supplied to the high-speed transfer device 26 shown in FIG. 1, and on the magnetic tape of the video tape cassette set in the high-speed transfer device 26. Recorded to form an inclined track.
[0153]
By the way, due to the limitation of the transfer speed of currently known disk drives, a plurality (m) of disk drives 78-1, 78-2,... 78-m are used in this example. In this case, the demultiplexers 61 and 75 and the multiplexer 81 shown in FIG. 3 need not be used.
[0154]
Next, the operation of the temporary recording or storage device 22 shown in FIG. 3 will be described with reference to FIGS. 9 and 10 sequentially. 9 is a timing chart for explaining the high-speed transfer recording operation of the temporary recording or storage device 22 shown in FIG. 3, and FIG. 10 is for explaining the high-speed transfer reproduction operation of the temporary recording or storage device 22 shown in FIG. It is a timing chart. In the following description, a case where the transfer rate is four times the normal transfer rate will be described as an example. That is, this is a case where eight recording / reproducing heads are used in the high-speed transfer devices 21 and 26 shown in FIG.
[0155]
First, FIG. 9 will be described. In FIG. 9, 48p denotes high-speed video and audio data supplied from the high-speed transfer device 21 shown in FIG. 1 to the demultiplexer 61 via the input terminal 60 shown in FIG. 3, and 61p1, 61p2, 61p3 and 61p4 denote demultiplexers. The video and audio data 62p1, 62p2, 62p3, and 62p4 divided by 61 are expanded by the demultiplexer 61, and then supplied to the buses 62-1, 62-2, 62-3, and 62-4. And voice data 80r1, 80r2, 80r3 and 80r4 to the disk controllers 80-1, 80-2, 80-3 and 80-4 via the buses 62-1, 62-2, 62-3 and 62-4, respectively. This is video and audio data supplied for recording.
[0156]
When the high-speed video and audio data 48p from the high-speed transfer device 21 shown in FIG. 1 is supplied to the demultiplexer 61 via the input terminal 60, the demultiplexer 61 is supplied. Indicates that the high-speed video and audio data 48p is divided into units indicated by broken lines (for example, 1 second) and video and audio data 61p1 indicated by diagonal lines, video and audio data 61p2 indicated by dots, and diagonal lines opposite to video and audio data 61p1. The video and audio data 61p3 and the video and audio data 61p4 indicated by plain color (meaning that there is no pattern) are obtained. Here, it should be noted that in this example, the high-speed video and audio data 48p is cut by 12 seconds, and since the data is divided by 1 second, the transfer speed is 4 times, so 1 second. Thus, 240 fields of video and audio data are included.
[0157]
These video and audio data 61p1, 61p2, 62p3, and 61p4 are time-axis expanded in the demultiplexer 61 to be time-axis expanded video and audio data 62p1, 62p2, 62p3, and 62p4, as indicated by solid arrows. Are supplied to the buses 62-1, 62-2, 62-3 and 62-4, respectively.
[0158]
The video and audio data 62p1, 62p2, 62p3, and 62p4 that are time-axis expanded and supplied to the buses 62-1, 62-2, 62-3, and 62-4 are stored in the disk controllers 80-1, 80-2, 80-3 and 80-4, and recorded or stored on the media set in the disk drives 78-1, 78-2, 78-3 and 78-4. FIG. 9 shows recording or storage timing. The video and audio data 80r1, 80r2, 80r3 and 80r4 are recorded or stored in the media set in the disk drives 78-1, 78-2, 78-3 and 78-4, respectively, at the timing shown in FIG. The
[0159]
Next, a description will be given with reference to FIG. 10, 80p1, 80p2, 80p3 and 80p4 are supplied to the input interface circuit 24 from the video special effect mixer 25 shown in FIG. After being converted to data, the data is supplied to the disk controllers 80-1, 80-2, 80-3 and 80-4 via the buses 62-1, 62-2, 62-3 and 62-4, and these disk controllers are further supplied. 80-1, 80-2, 80-3 and 80-4 are recorded or stored in the media set in the disk drives 78-1, 78-2, 78-3 and 78-4, and then the disk controller 80- 1, 80-2, 80-3, and 80-4, and the video and audio data read by FIG. The video and audio data 62p1, 62p2, 62p3 and 62p4 read out from the Ar1 are read out from the area Ar1 shown in FIG. 1 and then transferred to the buses 62-1, 62-2, 62-3 and 62-4. The supplied video and audio data 81p1, 81p2, 81p3, and 81p4 are read from the area Ar2 shown in FIG. 1 and then supplied to the multiplexer 81. After being divided and stored in the multiplexer 81, they are written. The video and audio data that is temporally compressed by being read out at a speed four times higher than that of the video and audio data 81p is the video and audio data that is output as the original continuous data after being temporally compressed by the multiplexer 81.
[0160]
The operator operates the operation unit 28 shown in FIG. 1 to reproduce the material temporarily recorded in the control unit 27 or recorded or stored in the storage device 22 and transferred to the video tape cassette set in the high-speed transfer device 26. When the controller 27 is notified of the recording instruction, the controller 27 supplies a recording / reproduction control signal to the system controller 76 shown in FIG.
[0161]
The system controller 76 supplies a disk access control signal to each of the disk controllers 80-1, 80-2, 80-3 and 80-4 based on the recording / reproduction control signal from the control unit 27, and each of them supplies a disk drive 78- 1, 78-2, 78-3 and 78-4 are controlled to reproduce video and audio data from the media set in the disk drives 78-1, 78-2, 78-3 and 78-4. When the video and audio data 80p1, 80p2, 80p3, and 80p4 are read from the area Ar1, they are supplied to the data buses 62-1, 62-2, 62-3, and 62-4, and the area Ar2 In the case of video and audio data read out from, the data is supplied to the multiplexer 81.
[0162]
In addition, when performing editing by adding or inserting newly edited video and audio data to the video and audio data recorded or stored in the area Ar2, the operator operates the operation unit 28 shown in FIG. It can be carried out. In other words, if video and audio data further edited after the temporary recording or editing in the storage device 22 are added or inserted, it is possible to transfer and record them collectively to the high-speed transfer device 26. In this case, it is possible to obtain a so-called seamless edited material tape, rather than recording or storing the edited result in the high-speed transfer device 26 many times.
[0163]
The video and audio data 62p1, 62p2, 62p3, and 62p4 from the data buses 62-1, 62-2, 62-3, and 62-4 are supplied to the multiplexer 81 and temporarily written in a memory (not shown) of the multiplexer 81. Then, reading from the memory is performed at a speed four times the writing speed, thereby obtaining video and audio data 81p1, 81p2, 81p3 and 81p4 having a transfer speed four times the normal transfer speed. It is converted into serial data and output from the output terminal 82 as high-speed video and audio data 81p and supplied to the high-speed transfer device 26 shown in FIG.
[0164]
Next, a configuration example of the output interface circuits 23-1, 23-2,... 23-k shown in FIGS.
[0165]
4, reference numeral 91 denotes an input terminal to which the selected video and audio data (8 m) is supplied from the matrix switcher 65 shown in FIG. 3. Through this input terminal 91, a FIFO (First In First Fast) is provided. Out) Video and audio data from the matrix switcher 65 are supplied to 92-1, 92-2,... 92-m, respectively.
[0166]
91-m is a decode and write control circuit, and these decode and write control circuits 91-1, 91-2, ... 91-m are connected via an input terminal 91. The video and audio data (8 bits × m) supplied are decoded to obtain flags FLG1, FLG2,... FLGm, and flags FLG1, FLG2,. 1, 92-2,... 92-m. Therefore, video and audio data supplied via the input terminal 91 is written in each of the FIFOs 92-1, 92-2,... 92-m.
[0167]
The video and audio data written in the FIFOs 92-1, 92-2,... 92-m are read by a read control signal from the read control circuit 94. The read control circuit 94 supplies a read control signal to each of the FIFOs 92-1, 92-2,... 92-m based on the buffering control signal from the reproduction control communication controller 107.
[0168]
The reproduction control communication controller 107 generates a buffering control signal, an audio transmission reproduction control signal, and a video transmission reproduction control signal based on the reproduction control signal from the control unit 27 shown in FIG. Then, a data reproduction control signal is supplied to the system controller 76 of the temporary recording or storage device 22 shown in FIG.
[0169]
95 is a compression / decoding processing circuit, and this compression / decoding circuit 95 is a compression in which video and audio data supplied from the FIFOs 92-1, 92-2,... This is used for video and audio data. If the compression mode is DCT (Discrete Cosine Transform), quantization, variable length coding such as run length or Huffman, the compression decoding circuit 95 includes a decoding circuit, an inverse quantization circuit, an IDCT (Inverse Discrete Cosine). Conversion) circuit. Of course, the same applies to wavelet transform and ADRC (adaptive dynamic range coding).
[0170]
The variable speed reproduction processing circuit 97 performs variable speed reproduction processing on the video data supplied from the compression / decoding processing circuit 95 or the bus 93. When the variable speed reproduction processing circuit 97 has a memory, video data is written to the memory at a high speed with reference to a transfer rate that is four times the normal transfer rate, and then read from the memory at a rate of 1/4 of the write rate. The read video data is supplied to the output interface circuit 98 {eg, RS232C, RS422, various serial or parallel interface circuits such as a SCSI (Small Computer Systems Interface) interface}. The output interface circuit 98 converts the video data from the variable speed reproduction processing circuit 97 into a format that can be used by the video special effect mixer 25, and supplies the processed video data to the video special effect mixer 25 shown in FIG. .
[0171]
On the other hand, reference numeral 100 denotes a DA converter. The DA converter 100 converts the video data from the variable speed reproduction processing circuit 97 into an analog video signal and outputs it through an output terminal 101. As an application of the analog video signal output from the output terminal 101, for example, when the equipment used in the next stage is an analog specification, or is supplied to a television monitor (not shown) and displayed as an image on the tube surface. It can be used for monitoring.
[0172]
The variable speed reproduction processing circuit 96 performs variable speed reproduction processing on the audio data supplied from the bus 93. When the variable speed reproduction processing circuit 96 has a memory, audio data is written to the memory at a high speed based on a transfer rate that is four times the normal transfer rate, and then read from the memory at a rate that is 1/4 of the write rate. The read audio data is supplied to the output interface circuit 102. The output interface circuit 102 (for example, RS232C, RS422, various serial or parallel interface circuits such as a SCSI (Small Computer Systems Interface) interface)} converts the video data from the variable speed playback processing circuit 96 into a format that can be used by the video special effect mixer 25. The processed audio data is supplied to the video special effect mixer 25 shown in FIG.
[0173]
On the other hand, reference numeral 104 denotes a DA converter. The DA converter 104 converts audio data from the variable speed reproduction processing circuit 96 into an analog audio signal and outputs the analog audio signal via the output terminal 105. As an application of the analog audio signal output from the output terminal 105, for example, when a device used in the next stage is an analog specification, or supplied to an audio amplifier (not shown) and audio is output from a speaker connected to the audio amplifier. For example, it can be used for monitoring as output.
[0174]
Next, operations of the temporary recording or storage device 22 shown in FIG. 3 and the output interface circuits 23-1, 23-2,... 23-k shown in FIG. . Also in this example, a case where the transfer rate is four times the normal transfer rate will be described.
[0175]
In FIG. 11, FLG indicates a bus transfer control flag supplied from the system controller 76 shown in FIG. 3 to the bus controller 64, and 62p1, 62p2, 62p3, and 62p4 denote the bus 62-1 shown in FIG. , 62-2,... 62-m, and the video and audio data 62p1, 62p2,... 62pm indicate the reproduction data and the recording data, and FLG1, FLG2. FLG3 and FLG4 are flags obtained by decoding the video and audio data 62p1, 62p2, 62p3 and 62p4 by the decoding and writing control circuits 91-1, 91-2,... 91-m shown in FIG. 92I1, 92I2, 92I3 and 92I4 are the FIFOs 92-1, 922 shown in FIG. 2 is supplied to · · · · 92-m, shows a video and audio data to be written, 93p is a video and audio data output from the bus 93.
[0176]
As shown in FIG. 3, a flag FLG is supplied from the system controller 76 to the bus controller 64. In this flag FLG, each period of low level “0” is a time slot, and in this example, the fourth and eighth time slots are recording time slots, and the other time slots are playback time slots.
[0177]
That is, in FIG. 11, the transfer contents on the buses 62-1, 62-2, 62-3 and 62-4 and the disk drive 78-1 by the disk controllers 80-1, 80-2, 80-3 and 80-4. 78-2, 78-3, and 78-4. That is, in the disk drive 78-1, the video and audio data Dp11 is reproduced in the first reproduction time slot, the video and audio data Dp21 is reproduced in the next reproduction time slot, and the video and audio data Dpk1 is reproduced in the next reproduction time slot. The video and audio data Dr1 supplied from the input interface circuit 24 at the next recording time slot is recorded on the medium set in the disk drive 78-1, and the video and audio data at the next playback time slot are recorded. The audio data Dp15 is reproduced in the next reproduction time slot, the video and audio data Dp24 is reproduced in the next reproduction time slot, and the video and audio data Dpk5 is reproduced and supplied to the bus 62-1, and the input interface circuit in the next recording time slot. 24, the video and audio data Dr5 supplied from It is recorded in the media that is set to click the drive 78-1.
[0178]
In the disk drive 78-2, the video and audio data Dp12 is reproduced in the first reproduction time slot, the video and audio data Dp22 is reproduced in the next reproduction time slot, and the video and audio data Dpk2 is reproduced in the next reproduction time slot. 2 and the video and audio data Dr2 supplied from the input interface circuit 24 in the next recording time slot are recorded on the medium set in the disk drive 78-2, and the video and audio data are recorded in the next reproduction time slot. Dp16 is reproduced in the next reproduction time slot as video and audio data Dp25, and in the next reproduction time slot as video and audio data Dpk6 is reproduced and supplied to the bus 62-2, and is input from the input interface circuit 24 in the next recording time slot. The supplied video and audio data Dr6 It is recorded in the media that is set to blanking 78-2.
[0179]
In the disk drive 78-3, the video and audio data Dp13 is reproduced in the first reproduction time slot, the video and audio data Dp23 is reproduced in the next reproduction time slot, and the video and audio data Dpk3 is reproduced in the next reproduction time slot. 3 and the video and audio data Dr3 supplied from the input interface circuit 24 in the next recording time slot are recorded on the medium set in the disk drive 78-3, and the video and audio data are recorded in the next reproduction time slot. Dp17 is reproduced in the next reproduction time slot as video and audio data Dp26, and in the next reproduction time slot as video and audio data Dpk7 is reproduced and supplied to the bus 62-3, and is input from the input interface circuit 24 in the next recording time slot. The supplied video and audio data Dr7 It is recorded in the media that is set to blanking 78-3.
[0180]
In the disk drive 78-4, the video and audio data Dp14 is reproduced in the first reproduction time slot, the video and audio data Dp24 is reproduced in the next reproduction time slot, and the video and audio data Dpk4 is reproduced in the next reproduction time slot. 4 and the video and audio data Dr4 supplied from the input interface circuit 24 in the next recording time slot are recorded on the medium set in the disk drive 78-4, and the video and audio data are recorded in the next reproduction time slot. Dp18 is reproduced in the next reproduction time slot as video and audio data Dp27, and in the next reproduction time slot as video and audio data Dpk8 is reproduced and supplied to the bus 62-4, and is input from the input interface circuit 24 in the next recording time slot. The supplied video and audio data Dr8 It is recorded in the media that is set to blanking 78-4.
[0181]
In this example, among the video and audio data 62p1, 62p2, 62p3 and 62p4 on the buses 62-1, 62-2, 62-3 and 62-4, video and audio data Dp11 to Dp14 and Dp15 to Dp18 are stored. For example, the case of supplying to the video special effect mixer 25 will be described.
[0182]
The video and audio data 62p1, 62p2, 62p3 and 62p4 on the buses 62-1, 62-2, 62-3 and 62-4 are respectively supplied to the matrix switcher 65 and selected, and then output interface circuit 23-1, 23-2,... 23-k.
[0183]
.., 91-4 to the decode circuits 91-1, 91-2,... 91-4 via the input terminals 91 of the output interface circuits 23-1, 23-2,. When the video and audio data on the buses 62-1, 62-2, 62-3, and 62-4 are supplied, the decode and write control circuits 91-1, 91-2, 91-3, and 91-4 are Only the data supplied to the video special effect mixer 25 is decoded to generate data reproduction flags FLG1, FLG2, FLG3 and FLG4, and the generated data reproduction flags FLG1, FLG2, FLG3 and FLG4 are converted into FIFOs 92-1, 92-2, A write control signal is also supplied to 92-3 and 92-4, respectively.
[0184]
As a result, video and audio data 92I1, 92I2, 92I3, and 92I4 are written in the FIFOs 92-1, 92-2, 92-3, and 92-4, respectively. Therefore, the data reproduction flags FLG1, FLG2, FLG3, and FLG4 can be considered as write enable signals for the FIFOs 92-1, 92-2, 92-3, and 92-4. That is, the video and audio data 62p1, 62P2 supplied to the FIFOs 92-1, 92-2, 92-3, and 92-4 when the data reproduction flags FLG1, FLG2, FLG3, and FLG4 are at the high level “1”. , 62p3 and 62p4, video and audio data Dp11, Dp12, Dp13, Dp14, Dp15, Dp16, Dp17 and Dp18 are written in the FIFOs 92-1, 92-2, 92-3 and 92-4.
[0185]
The video and audio data 92I1, 92I2, 92I3, and 92I4 written in the FIFOs 92-1, 92-2, 92-3, and 92-4 are sequentially read by the read control signal from the read control circuit 94, and are shown in FIG. As shown, the video and audio data Dp11, Dp12,...
[0186]
Next, a configuration example of the input interface circuit 24 shown in FIGS. 1 and 3 will be described with reference to FIG.
[0187]
5, 110 is an input terminal to which video special effect mixer 25 shown in FIGS. 1 and 3 or video data (in the case of digital data) having a transfer rate of 60 fields / second from the outside is supplied, and 112 is a figure. 1 and the video special effect mixer 25 shown in FIG. 3 or an input terminal to which a video signal (digital video signal) having a transfer rate of 60 fields / second from the outside is supplied, 115 is the video special effect shown in FIG. 1 and FIG. The effect mixer 25 or an input terminal to which audio data (digital audio data) having a transfer rate of 60 fields / second from the outside is supplied, 117 is the video special effect mixer 25 shown in FIGS. 1 and 3, or 60 fields from the outside This is an input terminal to which an audio signal (analog audio signal) having a transfer rate of / sec is supplied.
[0188]
Here, it is assumed that the video special effect mixer 25 processes digital video and audio data when the external input is digital video data and digital audio data, and the external input is analog video signal and analog audio signal. In this case, the video special effect mixer 25 has a specification for processing analog video and audio signals. Therefore, 111 is an input interface circuit for digital video data (for example, various serial or parallel interface circuits such as RS232C, RS422, and SCSI interface), 112 is an AD converter for converting an analog video signal into digital video data, 115. Is an input interface circuit for digital audio data (for example, various serial or parallel interface circuits such as RS232C, RS422, and SCSI interface), and 117 is an AD converter for converting an analog audio signal into digital audio data.
[0189]
The output end of the input interface circuit 111 is connected to one fixed contact 114d of the switch 114, the output end of the AD converter 113 is connected to the other fixed contact 114a of the switch 114, and the movable contact 114c of the switch 114 is compressed. Connected to the input terminal of the conversion circuit 120, the output terminal of the input interface circuit 116 is connected to one fixed contact 119d of the switch 119, and the output terminal of the AD converter 118 is connected to the other fixed contact 119a of the switch 119. The movable contact 119 c of the switch 119 is connected to the input end of the buffer memory 121.
[0190]
Reference numeral 124 denotes a recording control communication controller. The recording control communication controller 124 obtains a switching signal based on a recording / reproduction control signal indicating recording from the control unit 27 shown in FIG. A switching signal is supplied to each of the switches 114 and 119, and a data recording control signal is supplied to the system controller 76 shown in FIG. In addition, a data buffering control signal is supplied to the buffer memory 121, and video and audio data supplied from the switch 114 and the switch 119 are controlled to be written to and read from the buffer memory 121.
[0191]
As described above, the compression encoding circuit 120 performs various compression processes such as DCT, quantization, variable length encoding such as run length and Huffman, ADRC, and wavelet transform on the video data supplied via the switch 114. If the compression is not performed, the movable contact 114c of the switch 114 is connected to the buffer memory 121.
[0192]
Video data is supplied to one fixed contact 114d of the switch 114 via the input terminal 110 and the input interface circuit 111, and audio data is supplied to one fixed contact 119d of the switch 119 via the input terminal 115 and the input interface circuit 116. Is supplied by the switching signal from the recording control communication controller 124, the movable contacts 114c and 119c of the switches 114 and 119 are connected to one fixed contact 114d and 119d, respectively.
[0193]
As a result, the video data from the input interface circuit 111 is supplied to the compression encoding processing circuit 120 via the switch 114, and the video data is compressed and encoded in the compression encoding processing circuit 120 and then supplied to the buffer memory 121. Is done. Also, the audio data from the input interface circuit 116 is supplied to the buffer memory 121 via the switch 119.
[0194]
The buffer memory 121 is supplied with a data buffering control signal from the recording control communication controller 124, whereby video and audio data are sequentially written into the buffer memory 121. The video and audio data written in the buffer memory 121 is read by a data buffering control signal and supplied to the demultiplexer 75 shown in FIG.
[0195]
On the other hand, video data is supplied to the other fixed contact 114a of the switch 114 via the input terminal 112 and the AD converter 113, and to the other fixed contact 119a of the switch 119 via the input terminal 117 and the AD converter 118. When the audio data is supplied, the movable contacts 114c and 119c of the switches 114 and 119 are connected to the other fixed contacts 114a and 119a by a switching signal from the recording control communication controller 124, respectively.
[0196]
As a result, the video data from the A-D converter 113 is supplied to the compression encoding processing circuit 120 via the switch 114, and the video data is compression encoded in the compression encoding processing circuit 120, and then stored in the buffer memory 121. Supplied. Also, the audio data from the AD converter 118 is supplied to the buffer memory 121 via the switch 119.
[0197]
The buffer memory 121 is supplied with a data buffering control signal from the recording control communication controller 124, whereby video and audio data are sequentially written into the buffer memory 121. The video and audio data written in the buffer memory 121 is read by a data buffering control signal and supplied to the demultiplexer 75 shown in FIG.
[0198]
As described above, in this example, video and audio data obtained by reproducing at high speed transfer device 21 at a normal speed n times are output at a normal transfer speed n times, and this normal transfer speed is output. The video and audio data having a transfer speed of n times is temporarily recorded or stored in the storage device 22 at high speed, and the video and audio data recorded or stored in the temporary recording or storage device 22 is output to the output interface circuit 23-1. 23-2,... 23-k is converted to a normal transfer speed, and the video special effect mixer 25 performs video special effect processing and audio signal processing on the video and audio data converted to the normal transfer speed. The video special effect mixer 25 outputs video and audio data at a normal transfer rate, and is recorded or stored in the temporary recording or storage device 22. Are output as video and audio data having a transfer speed n times the normal transfer speed, and the video and audio data having the normal transfer speed are recorded at a recording speed four times the normal recording speed by the high-speed transfer device 26. Therefore, only the processing in the video special effect mixer 25 required by the operator in the editing system can be performed at a normal transfer speed, and in other processes, transfer is performed at a transfer speed n times the normal transfer speed. Therefore, the editing efficiency is greatly improved, and the high-speed transfer device 26 is used to record the time to record or store the material to be edited in the temporary recording or storage device 22 and the video and audio data read from the temporary recording or storage device 22. The recording or storing time (which is a waiting time for the operator) can be greatly shortened. Further, since the material is temporarily recorded or stored in the temporary recording or storage device 22 and the material once recorded or stored in the temporary recording or storage device 22 is edited, the high-speed transfer device is used after all editing is completed. 26, the edited material is recorded, and at the time of the next editing, a new edited material is added to the edited material recorded or stored in the temporary recording or storage device 22, or a new material is added. It is possible to temporarily record the material after the insert portion of the edited material that has been previously edited and recorded or stored, or to record or store the material for insert, and to record or store the material for the insert in the portion to be inserted. Since it can be performed in the recording or storage device 22, so-called relaying is performed on the tape of the video tape cassette set in the high-speed transfer device 26. Can to eliminate eye, can be created very precise edited tape, for example, a tape for delivery of such CM1 unified tape.
[0199]
Further, when the high-speed transfer devices 21 and 26 are constituted by VTRs, when a high-speed reproduction is performed by a reproduction system, a rotating drum equipped with a normal number of recording / reproducing heads 38-1 and 38-2 is set to a normal rotation speed. The recording track of the magnetic tape 39, which is rotated at a rotational speed n times the normal speed and scanned at a traveling speed n times the normal traveling speed, is scanned and reproduced by the recording / reproducing heads 38-1 and 38-2. The reproduced video and audio data obtained in this manner are signal-processed by the data extraction circuit 43-1, the channel decoding circuit 44-1, and the error correction circuit 45-1, respectively. The video and audio data subjected to the signal processing are output by the output interface circuit 47. Since video and audio data having a transfer rate n times the normal transfer rate are serially output and temporarily recorded or stored at 1 / n the normal processing time. It can be recorded or stored in 22.
[0200]
On the other hand, when the high-speed transfer devices 21 and 26 are configured with a VTR, when recording at high speed with a recording system, video and audio data having a transfer rate n times the normal transfer rate is buffered by the input interface circuit 31. The video and audio data are signal-processed by the ECC adding circuit 33-1 and the channel coding circuit 34-1, and the video / audio data subjected to the signal processing are mounted with a normal number of recording / reproducing heads 38-1 and 38-2. Since the rotating drum is rotated at a rotational speed n times the normal rotational speed and the magnetic tape 39 running at a traveling speed n times the normal traveling speed is scanned and recorded, a normal transfer speed is obtained. The video and audio data having a transfer speed of n times the recording speed can be recorded on the magnetic tape 39 at a speed 1 / n the normal processing time.
[0201]
Also, the video and audio data having a transfer rate n times the normal transfer rate is divided into m video and audio data for each time slot by the demultiplexer 61 of the temporary recording or storage device 22 and obtained by dividing. The m video and audio data are recorded or stored in the media set in the m disk drives 78-1 to 78-m, and the recorded or stored m video and audio data is 1 by the matrix switcher 65. The one video and audio data is selectively supplied to the output interface circuits 23-1 to 23-k, and is connected via the input interface circuit 24. The demultiplexer 75 converts the video and audio data supplied from the video special effect mixer 25 or audio data from the outside with m demultiplexers 75. The video data and audio data are divided into image and audio data, and the divided m video and audio data are recorded or stored in the media set in the disk drives 78-1 to 78-m, respectively, and recorded or stored in these media. Since the video and audio data are read out and supplied to the multiplexer 81, converted into serial data by the multiplexer 81 and output, the editing efficiency is greatly improved, and the waiting time for the recording and reproduction processing is at least 1/1 of the normal one. In addition, since the temporary recording or storage device 22 is interposed between the high-speed transfer machines 21 and 26, for example, a plurality of materials to be edited are set in the disk drives 78-1 to 78-m, respectively. It is recorded or stored in each medium or one medium, and recorded or recorded in these temporary recording or storage devices 22. It is possible to easily supply a plurality of processed materials in parallel to the video special effect mixer 25 for editing, and to make it easier for the operator to perform editing with the same materials over and over again. become.
[0202]
In addition, in the output interface circuits 23-1 to 23-k, when the video and audio data are compression-encoded, the compression-decoding processing circuit 95 can perform the compression-decoding process, and the input interface circuit 24 Since the video and audio data can be compression-encoded, it is possible to select the compression-encoding for the video data and to perform the editing work regardless of the selection. In the above example, the case where compression encoding can be performed only on video data has been described. However, it is obvious that audio data can be compressed and decoded in the same manner as video data. As described above, in the editing system in which compression encoding can be selected, if compression encoding is performed, the recording or storage capacity of the temporary recording or storage device 22 can be greatly increased equally.
[0203]
In addition, when a normal number of heads are mounted on a rotating drum and a normal transfer speed is required, the magnetic tape 39 is rotated at a normal traveling speed and the rotating drum is rotated at a normal rotating speed. Therefore, in the editing work, for example, confirmation, monitoring and the like can be performed without adding a configuration for that purpose.
[0204]
When a normal number of heads are mounted on the rotating drum and the transfer speed 1 / n of the normal transfer speed is required, the magnetic tape 39 is rotated at 1 / n times the normal travel speed. Since the drum is rotated at a rotation speed that is 1 / n times the normal rotation speed, in editing work, for example, by selecting video and audio data with less errors, a more accurate editing result is obtained. be able to.
[0205]
In the above example, the video and audio data has been described as being in the NTSC format. However, in the PAL format, SECAM format, or high-definition television format, each component such as the frequency of the system clock and the rotational speed of the rotating drum is used. This can be realized by setting various parameters in. Of course, when the video and audio data is a high-definition television system, the transfer rate can be further improved by using compression encoding and decoding processing.
[0206]
[Second Embodiment]
[0207]
Next, an example in which the high-speed transfer device 21 and the high-speed transfer device 26 are configured by semiconductor memory devices in the editing system shown in FIG. 1 will be described with reference to FIG. Accordingly, in this case, the video tape cassettes 20 and 29 shown in FIG. 1 are card-type memories in this example, or large-capacity memory devices provided in the high-speed transfer devices 21 and 26. For the sake of convenience, in the description of FIG. 12, a case where a large-capacity memory device is mounted inside the high-speed transfer devices 21 and 26 will be described.
[0208]
When a high-capacity memory device is provided in the high-speed transfer device 21, the video and audio data are naturally transmitted serially or in parallel at a transfer rate n times the normal transfer rate. Of course, the high-speed transfer device 21 is constituted by a semiconductor memory device, and video and audio data having a transfer rate n times the normal transfer rate from the high-speed transfer device further configured by a VTR or the like is further supplied to the high-speed transfer device 21. However, this is not a good solution because it increases the number of devices for transfer by one.
[0209]
However, for example, in a broadcasting station, a high-speed transfer device configured with a VTR is installed in a room, and video and audio data having a transfer rate n times the normal transfer rate from this high-speed transfer device is installed in another room. In the case of supplying to the high-speed transfer device 21 of the editing system shown in FIG. 1, the high-speed transfer device 21 may be constituted of a semiconductor memory device for buffering before temporary recording or recording or storage in the storage device 22. One method.
[0210]
In addition, the high-speed transfer device 26 has no problem in configuring with a semiconductor memory device. Of course, this is not the case when an edited medium is required in the video tape cassette, but there is a problem when the high-speed transfer device 26 is used for transmission or when an edited medium is required in a card type memory. Can be used.
[0211]
In FIG. 12, in the case of the high-speed transfer device 21, reference numeral 150 denotes an input terminal to which video and audio data having a transfer rate n times the normal transfer rate from the outside (of course, a normal transfer rate may be used) is supplied. In the case of the transfer device 26, for example, it is an input terminal to which video and audio data having a transfer rate n times the normal transfer rate from the temporary recording or storage device 22 is supplied.
[0212]
The video and audio data supplied via the input terminal 150 is supplied to the time axis expansion circuit 151 (of course, it is a case where the transfer rate is n times the normal transfer rate, and is necessary for the normal transfer rate). In this time axis extension circuit 151, the time axis is extended. The video and audio data whose time axis has been expanded by the time axis expansion circuit 151 is supplied to an ECC (error correction code) addition circuit 152, where ECC is added by the ECC addition circuit 152, and thereafter an input / output control circuit. 154.
[0213]
The input / output control circuit 154 includes an input / output circuit for supplying video and audio data from the ECC addition circuit 152 to the semiconductor memory 155, a compression encoding circuit, and a decoding circuit. Since this compression encoding circuit is video and audio data, it is a circuit that performs the above-described variable length encoding such as DCT, quantization, Huffman and run length, or ADRC and wavelet transform. Is a circuit that decompresses video and audio data that has been compression-encoded by performing the reverse process of the compression-encoding circuit.
[0214]
The input / output circuit includes a table (memory) that stores in which area of the semiconductor memory 155 video and audio data is stored, for example, for each field, each frame, or each segment, A configuration such as a switching circuit for switching the direction can be considered.
[0215]
The semiconductor memory 155 is constituted by a battery backup circuit (including a primary or secondary battery) for SRAM or DRAM, such as SRAM (static RAM), DRAM (dynamic RAM), or EEPROM. Writing / reading of video and audio data to / from the semiconductor memory 155 is performed by a writing / reading circuit 156. The write / read circuit 156 generates a write / read control signal based on the system clock and the synchronization signal from the system clock / synchronization signal generation circuit 160 and supplies the generated write / read control signal to the semiconductor memory 155.
[0216]
Further, for example, 157 is an operation unit for instructing various operation contents such as resetting data stored in the semiconductor memory 155 and instructing writing and reading in the semiconductor memory 155 by manual operation, and 158 based on the operation of the operation unit 157. The system controller notifies the system clock / synchronization signal generation circuit 160 of the operation content. The system controller 158 supplies a recording / reproduction control signal to the control unit 27 shown in FIG.
[0217]
Video and audio data read from the semiconductor memory 155 is decompressed by a decoding circuit (not shown) of the input / output circuit 154 and then supplied to the error correction circuit 163 to be subjected to error correction processing. Thereafter, the time axis compression circuit 164 is processed. And the output signal processing circuit 165.
[0218]
The output signal processing circuit 165 converts the video and audio data from the error correction circuit 163 into a 60 field / second digital or analog video and audio signal, and outputs the digital or analog video and audio signal from the output terminal 166 if the NTSC system is used. Output.
[0219]
The time axis compression circuit 164 compresses the time axis of the video and audio data from the error correction circuit 163 by reading out the time axis of the video and audio data from the internal memory at high speed (for example, n times at the time of writing), and outputs the compressed video and audio data to the output terminal 165. Output via.
[0220]
The system clock / synchronization signal generation circuit 160 obtains a synchronization signal from the video and audio data supplied via the input terminal 150, generates a system clock and a synchronization signal based on the synchronization signal, and generates the system clock and the synchronization signal as time. This is supplied to the axis extension circuit 151, the ECC addition circuit 152, the write / read circuit 156, the error correction circuit 163, the time axis extension circuit 164, and the output signal processing circuit 165, respectively.
[0221]
When the high-speed transfer device 26 shown in FIG. 1 has the configuration shown in FIG. 12, the writing and reading speed of video and audio data in the high-speed transfer devices 21 and 26 are written, and the writing / reading generated by the reading circuit 156 is performed. This is possible by varying the timing of the control signal. Therefore, although the case where the time axis expansion circuit 151 and the time axis compression circuit 164 are used has been described with reference to FIG. 12, the writing / reading circuit 156 can be realized by changing the write / read timing without using these circuits. be able to. Further, the ECC addition circuit 152 and the error correction circuit 163 may be omitted.
[0222]
As described above, if the high-speed transfer devices 21 and 26 shown in FIG. 1 are configured using a semiconductor memory device, the configuration and processing can be simplified, and the processing speed can be increased when used in an editing system. Further improvement can be achieved.
[0223]
In the above example, the case where the high-speed transfer devices 21 and 26 are constituted by semiconductor memory devices has been described. However, a video tape cassette currently used as a medium for video and audio data most is a large capacity card type memory ( Of course, the memory may be a memory that requires backup such as RAM, or a memory that does not require backup such as flash memory), and the high-speed transfer devices 21 and 26 serve as card-type memory drives, and the storage medium is a card. If a type memory is used, it can be handled without problems.
[0224]
In addition to the above-described examples (examples in which the high-speed transfer devices 21 and 26 are each configured by a VTR or a semiconductor memory device), the high-speed transfer devices 21 and 26 are, for example, optical disks (magneto-optical disks, write-once optical disks, phase change media). Or an optical disk, etc.) or a drive for driving a hard disk.
[0225]
When the high-speed transfer machines 21 and 26 are constituted by disk drives, a plurality of heads are provided corresponding to a required transfer speed for one disk, and reproduction data from the plurality of heads is signal-processed by a plurality of systems. And a plurality of systems for performing signal processing of a plurality of data to be recorded, or a plurality of heads provided for each of the plurality of disks corresponding to a required transfer rate. It can be realized by a method of providing a plurality of signal processing circuits for recording and reproduction.
[0226]
As a merit of using a disk as a medium, access is easier and faster than a video tape cassette, so it can be easily performed when an operator redoes editing, and a material required for the high-speed transfer machine 21 can be obtained. The search operation can be performed easily. Further, when the high-speed transfer device 21 is configured by a disk drive, a format in which one disk is divided into a plurality of areas for use or a plurality of disks (for example, a plurality of disks such as a hard disk) is used. In the case of using a format in which each medium is a single area, the temporary recording or storage device 22 shown in FIG. 1 can also be used.
[0227]
Further, when the temporary recording or storage device 22 is constituted by a disk drive, the edited video and audio data can be added to and inserted into the video and audio data recorded or stored in the edited area Ar2. In this case, since recording can be performed on the medium of the high-speed transfer device 26 (especially in the case of a video tape) at one time, a so-called seamless video tape cassette 29 can be obtained. When the image is reproduced and the reproduction signal is supplied to a television monitor or the like and projected on the tube surface, for example, image disturbance caused by reproducing the seam can be eliminated.
[0228]
[Third embodiment]
[0229]
Next, a third embodiment of the editing method and system according to the present invention will be described with reference to FIGS. In the third embodiment, the configuration of the high-speed transfer machines 21 and 26 shown in FIG. 1 is changed. Specifically, the recording / reproducing head is set so that the recording / reproducing head scans n tracks in a stopped state where the magnetic tape is not running. When a transfer speed n times the normal transfer speed is required, the number of recording / reproducing heads mounted on the rotating drum is xn (where x is the number of heads required at the normal transfer speed). The magnetic tape is run at n times the normal running speed, and the lead angle is formed on the recording medium when the recording medium is scanned by the head with the running of the recording medium stopped. Set to straddle nm tracks (where m is the normal lead angle and the number of tracks that one head spans when the rotating drum is rotated once with the movement of the recording medium stopped) The rotating drum is rotated at a normal rotation speed. In the following description, the configuration of the high-speed transfer devices 21 and 26 is changed in the system shown in FIG. 1, and the configuration of the other circuits and the like shown in FIG. Only 21 and 26 will be described.
[0230]
In FIG. 13, reference numeral 30 denotes an external input terminal for the high-speed transfer device 21, and video and audio data 31p transferred at high speed from the temporary recording or storage device 22 shown in FIG. Input terminal.
[0231]
The video and audio data 31p transferred at high speed via the input terminal 30 is supplied to the demultiplexer 31. The demultiplexer 31 divides and outputs video and audio data transferred at high speed. Even if the division is considered, for example, if it is considered as data from the temporary recording or the storage device 22, the data for each reproducing head of the high-speed transfer device 21, that is, the data for each track is supplied as one data string. It is converted into data for each column, that is, for each track (referred to as segment division or the like).
[0232]
Each data divided into data for each track by the demultiplexer 31 is supplied to the time axis expansion circuits 32-1, 32-2,. These time-axis expansion circuits 32-1, 32-2,..., 32-n each have, for example, a dual port memory and a write / read circuit. These time-axis expansion circuits 32-1, 32-2,..., 32-n intermittently transfer the intermittently supplied data to the dual port memory at the same speed as n times the normal transfer rate. By writing data and reading the data written in the dual port memory at a normal transfer rate, the time axis of the data having a transfer rate n times the normal transfer rate is expanded.
[0233]
The video and audio data whose time axis has been expanded by the time axis expansion circuits 32-1, 32-2,..., 32-n are ECC (Error Collection Code) addition circuits 33-1, 33-2, ... are supplied to 33-n, respectively. These ECC addition circuits 33-1, 33-2,... 33-n are time-axis-expanded videos supplied from the time-axis expansion circuits 32-1, 32-2,. ECC is added to the audio data. Video and audio data to which ECC is added by the ECC adding circuits 33-1, 33-2,... 33-n are respectively CHCOD (channel coding) circuits 34-1, 34-2,. The recording modulation process (digital modulation process) is applied to each of -n.
[0234]
Each of the video and audio signals subjected to the recording and modulation processing in the channel coding circuits 34-1, 34-2,... 34-n is recorded and amplified in the recording amplifier circuits 35-1, 35-2,. Are supplied to the movable contacts 36c of the switches 36-1, 36-2, ... 36-n, respectively.
[0235]
Each of the fixed contacts 36a of the switches 36-1, 36-2, ... 36-n is connected to the primary side of the rotary transformers 37-1, 37-2, ... 37-n. The other fixed contact 36b of these switches 36-1, 36-2, ... 36-n is connected to the primary side of the rotary transformer 37-n + 1, 37-n + 2, ... 37-2n. To do.
[0236]
These switches 36-1, 36-2,... 36-n fix the movable contact 36c to one or the other based on switching signals SW1, SW2,. Connected to the contact 36a or 36b, the recording / reproducing heads 38-1, 38-2,... 38-n,. In addition, these rotary transformers 37-1, 37-2, ... 37-n, ... 372n, a tape loading mechanism (not shown), recording / reproducing heads 38-1, 38-2, ... 38 The tape transport unit composed of -n, ..., 38-2n is controlled by the controller 40.
[0237]
Therefore, at the time of recording, the video and audio signals from the recording amplifier circuits 35-1, 35-2,... 35-n are supplied to the switches 36-1, 36-2,. Recording / reproducing heads 38-1, 38-2 via one or the other fixed contact 36a or 36b and rotary transformers 37-1, 37-2, ... 37-n, ... 37-2n, respectively. ,... 38-n,... 38-2n are sequentially supplied and recorded on the magnetic tape 39 so as to form inclined tracks.
[0238]
Each of the recording / reproducing heads 38-1, 38-2, ... 38-n, ... 38-2n is opposed to each other on a rotating drum (not shown), and each recording / reproducing head 38-1, 38-2, ... 38-n, ... 38-2n are attached so that the distance between them is uniform. Here, the number of the recording / reproducing heads 38-1, 38-2,... 38-n,... 38-2n causes the magnetic tape 39 to travel at n times the normal traveling speed, and When the transfer speed is n times the normal transfer speed with the rotation speed of the rotary drum being the normal rotation speed, the number is 2n.
[0239]
Here, the recording / reproducing heads 38-1, 38-2,... 38-n will be described with reference to FIG.
[0240]
14A shows an example in which recording / reproducing heads 38-1, 38-2,... 38-n are mounted on a rotating drum, FIG. 14B shows a section of the rotating drum 200, and FIG. 14D shows the lead angle of the recording / reproducing head (illustrated by taking the recording / reproducing head 38-1 as an example), FIG. 14D shows the normal lead angle of the recording / reproducing head, and FIG. 14E shows the recording / reproducing head according to this example. The read head lead angle is shown.
[0241]
First, in this example, as shown in FIG. 14A, recording / reproducing heads 38-1, 38-2,... / Reproducing heads 38-1 and 38-5, recording / reproducing heads 38-2 and 38-6, recording / reproducing heads 38-3 and 38-7, and recording / reproducing heads 38-4 and 38-8 are opposed to each other. Attached to the rotating drum 200.
[0242]
Next, as shown in FIG. 14B, the rotary drum 200 is stepped up and down, and when the magnetic tape 39 is guided by the stepped portion, the recording / reproducing head (recording / reproducing head 38- 1 is illustrated as an example), and the magnetic tape 39 is scanned at the intended lead angle. A view of this from the front is FIG. 14C, where the lead angle is θ.
[0243]
FIG. 14D shows a normal lead angle θ1. When the normal lead angle θ1 is set, when the rotating drum 200 on which the recording / reproducing head is mounted is rotated once while the traveling of the magnetic tape 39 is stopped, the recording / reproducing head is indicated by a solid arrow as shown in FIG. , Scan the track once from bottom to top.
[0244]
FIG. 14E is an example of the lead angle set in this example, and this figure shows the lead angle θ2 when a transfer rate four times the normal transfer rate is obtained. When the lead angle θ2 is set, when the rotary drum 200 on which the recording / reproducing heads 38-1, 38-2,... 38-8 are mounted is rotated with the traveling of the magnetic tape 39 stopped, The recording / reproducing heads 38-1, 38-2,... 38-8 scan across the tracks T1, T2, T3, and T4 as indicated by solid arrows.
[0245]
As shown in FIG. 14E, when a transfer rate four times the normal transfer rate is obtained, the read angle θ2 is set to 1 for each of the recording / reproducing heads 38-1, 38-2,. It is sufficient to set the lead angle across four tracks in one scan, the traveling speed of the magnetic tape 39 is four times the normal traveling speed, and the rotational speed of the rotary drum 200 is the normal rotational speed.
[0246]
A recording / reproducing head that scans tracks T1, T2, T3, and T4 when the magnetic tape 39 travels at a traveling speed that is four times the normal traveling speed and the rotational speed of the rotary drum 200 is the normal rotational speed. The scanning trajectory of 38-1, 38-2, ... 38-8 stands more than when the magnetic tape 39 is stopped. In other words, when the scanning trajectory of the recording / reproducing heads 38-1, 38-2,... 38-8 is above the magnetic tape 39, the angle formed by the lower end of the magnetic tape 39 and the scanning trajectory is large. It becomes. When one recording / reproducing head among the recording / reproducing heads 38-1, 38-2,... 38-8 is considered, the one recording / reproducing head has the tracks T1, T2, T3, T4. Any one of the tracks T1, T2, T3, or T4 is scanned once during one rotation of the rotary drum 200, as shown in FIG. 14D.
[0247]
In order to obtain a transfer rate n times the normal transfer rate under the above conditions, 2 × n recording / reproducing heads are required. That is, in this example, 2 × n. Here, x is set to “2” when “ordinary tape running speed” (so-called 1 × speed, etc.) is set on the rotating drum at 180 degrees opposite to each other and a total of two recording / reproducing heads are provided. Considering the time during which the inclined track is formed for one frame on the magnetic tape 39 while the rotating drum is rotated by y, the frame is inclined by one frame by 2 × n recording / reproducing heads during the same rotation of the rotating drum y. This is because in order to make it possible to form the track on the magnetic tape 39, it is only necessary to run the magnetic tape 39 at n times the normal running speed.
[0248]
For example, in the component digital format (D1 format or the like), so-called segment recording is performed in which a rotating drum is rotated at 150 revolutions / second using four heads to form inclined tracks at a rate of 10 tracks per field. Therefore, if an n-times speed transfer speed is obtained in this format, 4n heads are required if the rotating speed of the rotary drum is kept normal and the traveling speed of the magnetic tape is n-times speed. If the number of heads remains four and the magnetic tape travels at a speed n times the normal speed, the rotation speed of the rotary drum is n times the normal speed, and 4n heads are used. In order to set the transfer speed to 1 times the normal transfer speed, the tape running speed is set to 1 time, the rotation speed of the rotary drum is set to 1 time, and the transfer speed is set to 1 of the normal transfer speed by using 4n heads. To achieve / n times, the tape running speed is set to 1 × speed, and the rotation speed of the rotating drum is set to 1 / n times speed. Of course, the same applies to the D2 format and other digital formats.
[0249]
In this example, video and audio to be recorded from the channel coding circuits 33-1, 33-2,... 33-n in order to the recording amplifier circuits 35-1, 35-2,. Since data is supplied, the recording / reproducing heads 38-1, 38-2,... 38-n, ... 38-2n are connected to the recording amplifier circuits 35-1, 35-2,. ... Recording current is sequentially supplied by 35-n.
[0250]
The recording data recorded on the magnetic tape 39 is sequentially reproduced by the recording / reproducing heads 38-1, 38-2,... 38-n,. Although not shown in FIG. 13, the recording / reproducing heads 38-1, 38-2,... 38-n,. / The reproducing heads 38-1, 38-2,... 38-n,. As shown in FIG. 13, in the case where the recording system and the reproducing system are configured as one VTR, recording / reproducing heads 38-1, 38-2,. ... 38-2n may be mounted on the rotating drum, or the recording head and the reproducing head may be mounted on the rotating drum adjacent to each other. The traveling speed of the magnetic tape 39 is n times the normal traveling speed as described above, and the rotational speed of the rotating drum (the magnetic tape 39 and the recording / reproducing heads 38-1, 38-2,... 38-n,. ... relative speed with respect to 38-2n), the transfer speed can be increased to n times the normal speed.
[0251]
Reproducing signals from the recording / reproducing heads 38-1, 38-2,... 38-n,... 38-2n are rotary transformers 37-1, 37-2,. ,..., 37-2n are sequentially supplied to the one or other fixed contact 36a or 36b of the switches 36-1, 36-2,. Switching signals SW1 to SW4 from the system controller 50 are supplied to these switches 36-1, 36-2,. Accordingly, the switches 36-1, 36-2,... 36-n connect the movable contact 36c to one or the other fixed contact 36a or 36b.
[0252]
Therefore, the reproduced signals sequentially reproduced are the one or the other fixed contact 36a or 36b of the switches 36-1, 36-2,... 36-n and the reproduction amplifier circuits 42-1, 42-2,. .. Are sequentially supplied to the data extraction circuits 43-1, 43-2,... 43-n via 42-n. These data extraction circuits 43-1, 43-2,... 43-n extract clock signals from the reproduction signals supplied from the reproduction amplifier circuits 42-1, 42-2,. The video and audio signals are extracted using the extracted clock signal. The video and audio data extracted in the data extraction circuits 43-1, 43-2,... 43-n are supplied to CHDEC (channel decoding) circuits 44-1, 44-2,. Supplied.
[0253]
Channel decoding circuits 44-1, 44-2,... 44-n are video and audio signals (digitally modulated) from the data extraction circuits 43-1, 43-2,. The original video and audio data are obtained, and the demodulated video and audio data are supplied to error correction circuits 45-1, 45-2,... 45-n.
[0254]
The error correction circuits 45-1, 45-2,... 45-n are added to the video and audio data supplied from the channel decoding circuits 44-1, 44-2,. The video and audio data are subjected to error correction processing based on the existing ECC, and the video and audio data subjected to the error correction processing are supplied to the time axis compression circuits 46-1, 46-2, ... 46-n. To do. Here, when error correction is performed using ECC added to video and audio data, error correction processing is performed on data that cannot be corrected, and data closest to the original data is restored.
[0255]
The time axis compression circuits 46-1, 46-2,..., 46-n each have a dual port memory and a write / read circuit. These time axis compression circuits 46-1, 46-2,... 46-n are video and audio data from the error correction circuits 45-1, 45-2,. Are read at a normal speed and read from the dual port memory at a speed n times the normal speed. The video and audio data read from the time axis compression circuits 46-1, 46-2,... 46-n at a speed n times the normal speed are sequentially (compression circuits 46-1, 46-2, ... (In the order 46-n) to the multiplexer 47.
[0256]
The multiplexer 47 selects and outputs the video and audio data sequentially supplied from the time axis compression circuits 46-1, 46-2,... 46-n in the order of transmission. This output is output from the output terminal 48, and if it is the high-speed transfer device 21 shown in FIG.
[0257]
By the way, in the case of the high-speed transfer device 26, if the high-speed transfer device 26 is used for output in the transmission system, if the reproduced video and audio data are compressed data, the next stage of the transmission system (for example, the cart system). And the master switcher and transmitter), the time axis compression circuits 46-1, 46-2,... 46 must be provided so as not to modify the next stage system. It is necessary to use the output of the error correction circuits 45-1, 45-2,... 45-n without using the output of -n.
[0258]
That is, when the configuration shown in FIG. 13 is applied to the high-speed transfer device 26 shown in FIG. 1, the output terminals of the error correction circuits 45-1, 45-2,. The output interface circuit 40 may be connected to the input terminal, converted to the original data by the output interface circuit 40, and output. In this way, for example, a television monitor or the like can be connected to the output interface circuit 30 to monitor the image projected on the tube surface.
[0259]
49 is an operation unit (not shown) having a display unit and a group of operation keys, for example. When the operation unit 49 is operated, or the recording / reproduction control signal from the control unit 27 shown in FIG. 1 is supplied to the system controller 50 via the input terminal 51, the system controller 50 is connected to the system clock / A control signal is supplied to the synchronization signal generation circuit 52.
[0260]
As a result, the system clock / synchronization signal generation circuit 52 has the above-described demultiplexer 31, time axis expansion circuits 32-1, 32-2,..., 32-n, ECC addition circuits 33-1, 33-2,. ... 33-n, channel coding circuits 34-1 and 34-2,... 34-n, data extraction circuits 43-1 and 43-2,... 43-n, channel decoding circuit 44- 44-n, error correction circuits 45-1, 45-2,... 45-n, time axis compression circuits 46-1, 46-2,. -N, supplying necessary system clock and synchronization signal to the multiplexer 47, respectively.
[0261]
In the configuration shown in FIG. 13, the recording / reproducing heads 38-1, 38-2,... 38-n,. Each circuit system is halved by switching each time.
[0262]
In the above example, 2n heads are mounted on the rotating drum for recording and reproduction, the rotating drum is rotated at a normal rotation speed, and the magnetic tape 39 is run at a speed n times the normal speed. The case where recording and reproduction are performed has been described. However, a method of performing high-speed transfer by rotating the rotating drum at a higher speed than the normal rotating speed, further increasing the number of heads, and increasing the rotating speed of the rotating drum. It is also possible to adopt a method of Therefore, in order to increase the transfer rate to n times the normal transfer rate, the number of recording / reproducing heads is not necessarily 2n.
[0263]
Here, the relationship between the transfer speed to be obtained, the rotational speed of the rotating drum, and the number of recording / reproducing heads will be described by taking several patterns as examples.
[0264]
First, as a premise, one or a plurality of recording / reproducing heads are arranged side by side in the height direction of the rotating drum, and one or a plurality of recording / reproducing heads arranged side by side in this height direction are arranged as one. When a set is used, the number of sets mounted on the rotating drum is set so that all the sets are equidistant (or the same angular interval) between the sets. In addition, the lead angle is set such that the number of tracks that the recording / reproducing head straddles while rotating the rotary drum 200 once when the magnetic tape 39 is stopped is based on the normal number of tracks. Here, the normal number of tracks refers to the number of tracks scanned by one head when the rotating drum 200 is rotated once with the magnetic tape 39 stopped, for example.
[0265]
Based on the above assumptions, the number of recording / reproducing heads, the traveling speed of the magnetic tape, the rotational speed of the rotating drum, and the traveling of the magnetic tape are stopped when a transfer speed that is four times the normal transfer speed is obtained. As an example, the relationship of the number of tracks that one recording / reproducing head straddles in the state of being recorded is shown.
[0266]
Number of heads Tape running speed Drum rotation speed Track straddling when tape is stopped 84 x normal speed 1 x normal speed 4 x m (m is the normal number)
4 4 × Normal speed 2 × Normal speed 2 × m 3 4 × Normal speed 8/3 × Normal speed 3/2 × m 2 4 × Normal speed 4 × Normal speed 1 × m
[0267]
In other words, if the number of heads for obtaining a normal transfer speed is x, if the number of heads is xn and the tape traveling speed is n times the normal traveling speed, the rotational speed of the rotating drum is the normal rotational speed. Good, but if the number of heads decreases, the rotational speed of the rotating drum must be increased accordingly. Therefore, when the magnetic tape 39 is run at a normal speed n times, when the magnification with respect to the normal rotation speed of the rotary drum is d and the number of heads is h, the rotation drum is set so that hd = xn. The magnification d for the normal speed or the number h of heads is set, and T times the number of normal tracks that the recording / reproducing head straddles with the magnetic tape running stopped, that is, Td = n. What is necessary is just to set a lead angle.
[0268]
As can be seen from the above description, in the above-described example, the transfer rate has been described as being four times the normal transfer rate, but the transfer rate can also be varied. That is, the transfer rate required by the operator can be set to the transfer rate designated by the operation key of the operation unit 28 shown in FIG.
[0269]
For this purpose, it is possible to adopt a method in which a large number of recording / reproducing heads are mounted in advance on a rotating drum and the number of recording / reproducing heads used is varied in accordance with a designated transfer speed. The “number of uses” herein refers to the number of heads to which a recording current is applied during recording, and the number of heads for which a reproduction signal is valid during reproduction. Of course, by changing the number of recording / reproducing heads to be used and the transfer speed, a circuit that does not need to be used can be generated. Therefore, it is necessary to automatically select a circuit to be used and a circuit not to be used. is there. In this variable method, the recording / reproducing head must be mounted on a rotating drum in advance and the lead angle must be changed. In any case, in order to change the transfer speed in this way, the system clock and lead angle of the circuit must be changed in conjunction with this, but the system clock is a well-known VCO (voltage controlled oscillator). It can be easily realized if there is a high frequency crystal oscillator and frequency divider or a low frequency crystal oscillator and multiplier.
[0270]
In order to change the lead angle, a step is provided above and below the tape guide, the magnetic tape is guided by at least two tape guides, and the height of the two tape guides is changed by a motor. As a result, the lead angle can be varied.
[0271]
Next, the operation of the high-speed transfer device 21 or 26 shown in FIG. 13 will be described with reference to FIGS. 15 to 17 in the case where n is “4”. In order to increase n by “4” and increase the transfer speed by four, it is necessary to use eight recording / reproducing heads shown in FIG. Therefore, the number of heads for realizing an n-times transfer speed is 2n if the number of recording / reproducing heads used in a normal transfer speed VTR is two. 13, eight recording / reproducing heads, that is, recording / reproducing heads 38-1, 38-2,... 38-8 are used.
[0272]
It demonstrates from FIG. In FIG. 15, FD indicates frame data, TD indicates track-corresponding data, and TP indicates a track pattern. In this example, frame data P, P + 1, P + 2, and P + 3 (explained only by the amount shown in FIG. P + 4, P + 5,... Are transferred in one frame period as real time. Dn / F is data for one frame, the code in parentheses attached to TDn indicates the head number, Tn / F indicates the track for one frame, and the solid line arrow in the upper part of the figure indicates the transfer In the order, the solid line arrows shown in the lower part indicate the tracks recorded in one frame period of the real time Tn in the tape running direction (in this example, quadruple speed running).
[0273]
First, focusing on the frames P and P + 1, the frame P is the first track TD1 (H1), TD2 (H2),... TD8 (H8),. That is, the first track corresponding data TD1 of the frame P is “H1”, that is, recorded by the recording / reproducing head 38-1 shown in FIG. 13, and the second track corresponding data TD2 is “H2”, that is, FIG. The eighth track corresponding data TD8 is “H8”, that is, recorded by the recording / reproducing head 38-8 shown in FIG. The 12-track correspondence data TD12 is “H4”, that is, recorded by the recording / reproducing head 38-4 (12-8 = 4) shown in FIG.
[0274]
Subsequently, the first track corresponding data TD1 of the frame P + 1 is “H5”, that is, recorded by the recording / reproducing head 38-5 shown in FIG. 13, and the second track corresponding data TD2 is “H6”, that is, FIG. The TD12-corresponding data TD12 is recorded as “H8”, that is, the recording / reproducing head 38-8 shown in FIG. In other words, in this example, the recording / reproducing heads 38-1, 38-2,..., 38-8 record the data corresponding to the track three times in two frames to form a track. . Of course, this is because the tape format of the VTR in this example is 12 tracks per frame. Therefore, when the number of tracks in one frame is 8, the recording / reproducing heads 38-1, 38-2, ... 38-8 record the track-corresponding data once in one frame to form a track. .
[0275]
As a result, tracks T1, T2,... T12 are formed on the tape corresponding to the frame P as indicated by diagonal lines in the figure, and the track T1 corresponding to the frame P + 1 is indicated as indicated by dots in the figure. , T2, ... T12 are formed. Of course, each of the twelve tracks T1, T2,... T12 of each frame is recorded within one frame / 4 of real time. Accordingly, all the tracks T1 to T12 shown in the track pattern TP (for a total of 48 tracks in the figure) are recorded during one frame of real time.
[0276]
Next, referring to FIG. 16, transfer is performed to the high-speed transfer device 26 shown in FIG. 13 at a normal transfer speed four times, and the eight recording / reproducing heads 38-1, 38- of the high-speed transfer device 26 are transferred. 2, ... 38-8, the operation when video and audio data is recorded will be described. For easy understanding, the reference numerals of the signals shown in FIG. 16 are also shown in FIG.
[0277]
31r is an input (high-speed transfer data) of the demultiplexer 31 in FIG. 13, 32I1 to 32I4 are inputs to the time axis expansion circuits 32-1 to 32-4 in FIG. 13, and 32O1 to 32O4 are time axis expansion circuits 32- in FIG. 1 to 32-4, the time axis expansion outputs 35O1 to 35O4 are the recording amplification outputs of the recording amplification circuits 35-1 to 35-4 in FIG. 13, and SW1 to SW4 are supplied to the switches 36-1 to 36-4 in FIG. The switching signal from the system controller 50, 38p1 is a recording signal of the recording / reproducing head 38-1 in FIG. 13, and 38r5 is a recording signal of the recording / reproducing head 38-5 in FIG.
[0278]
The recording signals of the recording / reproducing heads 38-2, 38-3,... 38-4, 38-6, and 38-8 are not shown. The switching signals SW1 to SW4 include recording / reproducing heads 38-1, 38-2,... Selected according to the high level “1” and low level “0” states of the switching signals SW1 to SW4. Numbers “1” to “8” for indicating 38-8 are added.
[0279]
First, the demultiplexer 31 shown in FIG. 13 is supplied with video and audio data 31r having a transfer rate four times the normal transfer rate from the temporary recording or storage device 22 shown in FIG. Is done. In FIG. 16, reference numerals T12D, T1D, T2D,..., T3D shown in the video and audio data 31r, respectively, indicate the configuration data of the twelfth track, the first track, the second track,. .
[0280]
When the video and audio data 31r is supplied to the demultiplexer 31, it is divided by the demultiplexer 31 for each track. As shown in FIG. 16, the divided video and audio data become video and audio data 32I1, 32I2, 32I3, and 32I4, and are input to the time axis expansion circuits 32-1, 32-2, 32-3, and 32-4. Become.
[0281]
The video and audio data 32I1 as the input of the time axis expansion circuit 32-1 becomes data such as the first track T1D, the fifth track T5D, and the ninth track T9D for each frame, as indicated by the oblique lines, and the time axis expansion circuit As shown by dots, the video and audio data 32I2 as the input of 32-2 becomes data such as the second track T2D, the sixth track T6D, and the tenth track T10D for each frame. The video and audio data 32I3 as input becomes data such as the third track T3D, the seventh track T7D, and the eleventh track T11D for each frame as shown by the diagonal lines opposite to the video and audio data 32I1, and the time axis is expanded. The video and audio data 32I4 as the input of the circuit 32-4 is painted white (meaning no pattern) As shown, for each frame, the fourth track T4d, eighth track T8D, the data such as the 12th track T12D. That is, when viewed from the output timing, the first track T1D, the second track T2D, the third track T3D, the fourth track T4D, the fifth track T5D, the sixth track T7D,... The eleventh track T11D, the twelfth track. The signals are output in the order of T12D, and are sequentially supplied to the time axis expansion circuits 32-1, 32-2, 32-3, and 32-4 in this order.
[0282]
The video and audio data 32I1, 32I2, 32I3, and 32I4 supplied to the time axis expansion circuits 32-1, 32-2, 32-3, and 32-4 are converted into time axis expansion circuits 32-1, 32-2. , 32-3 and 32-4, the time axis is expanded like the time axis extension outputs 32O1, 32O2, 32O3 and 32O4. For example, the video and audio data T1D, T5D, and T9D of the first track, the fifth track, and the ninth track of the video and audio data 32I1 that are input to the time axis extension circuit 32-1 are indicated by solid arrows. It is extended to 4 times longer in time. The same applies to the other video and audio data 32I2, 32I3 and 32I4.
[0283]
The time axis extension outputs 32O1, 32O2, 32O3, and 32O4 of the time axis extension circuits 32-1, 32-2, 32-3, and 32-4 are respectively added to the ECC addition circuits 33-1, 33-2, 33-3, and 33. -4 is added with ECC, and is further digitally modulated in the channel coding circuits 34-1, 34-2, 34-3 and 34-4, and is supplied to the amplifier circuits 35-1, 35-2, 35-3 and 35-4. Supplied and recorded and amplified.
[0284]
The outputs 35O1, 35O2, 35O3, and 35O4 of the recording amplifier circuits 35-1, 35-2, 35-3, and 35-4 are more than the time axis extended outputs 32O1, 32O2, 32O3, and 32O4 as shown in FIG. There is a delay. This delay time is due to processing in the ECC addition circuits 33-1, 33-2, 33-3 and 33-4 and the channel coding circuits 34-1 34-2, 34-3 and 34-4. For example, among the outputs 32O1 of the time axis extension circuit 32-1, the time axis extension output 32O1 of the first track T1D is a hatched line of the output 35O1 of the recording amplification circuit 35-1 from this hatched portion, as shown by the solid line arrow. Part. Accordingly, the delay time for each video and audio data is the time indicated by the symbol RD in the figure.
[0285]
The video and audio signals (current signals) 35O1, 35O2, 35O3, and 35O4 output from the recording amplifier circuits 35-1, 35-2, 35-3, and 35-4 are switches 36-1, 36-2, It is supplied to each of the movable contacts 36c of 36-3 and 36-4. Here, it should be noted that in this example, a case where a transfer rate four times the normal transfer rate is obtained is described, so that 2 × n recording heads, that is, eight are required. It is to be.
[0286]
Therefore, in this example, one fixed contact 36a of the switch 36-1 is connected to the primary side of the rotary transformer 37-1, and the other fixed contact 36b of the switch 36-1 is connected to the primary side of the rotary transformer 37-5. , One fixed contact 36a of the switch 36-2 is connected to the primary side of the rotary transformer 37-2, and the other fixed contact 36b of the switch 36-2 is connected to the primary side of the rotary transformer 37-6. Then, one fixed contact 36a of the switch 36-3 is connected to the primary side of the rotary transformer 37-3, and the other fixed contact 36b of the switch 36-3 is connected to the primary side of the rotary transformer 37-7. One fixed contact 36a of the switch 36-4 is connected to the primary side of the rotary transformer 37-4, and the other fixed contact 36b of the switch 36-4 is connected to the rotary transformer. 7-8 will be connected to the primary side of the.
[0287]
When the switching signal SW1 supplied from the system controller 50 to the switch 36-1 is high level “1”, the switch 36-1 connects the movable contact 36c to one fixed contact 36a, and when the switching signal SW1 is low level “0”. The switch 36-1 connects the movable contact 36c to the other fixed contact 36b. Therefore, as shown on the switching signal SW1, the video and audio data T1D of the first track output from the recording amplification circuit 35-1 forms an inclined track on the magnetic tape 39 by the recording / reproducing head 38-1. The video and audio data T5D of the fifth track recorded and output from the recording amplification circuit 35-1 are recorded so as to form an inclined track on the magnetic tape 39 by the recording / reproducing head 38-5, and the recording amplification circuit The video and audio data T9D of the ninth track output from 35-1 is recorded by the recording / reproducing head 38-1 so as to form an inclined track on the magnetic tape 39 (this is not shown).
[0288]
Next, when the switching signal SW2 supplied from the system controller 50 to the switch 36-2 is at the high level “1”, the switch 36-2 connects the movable contact 36c to the one fixed contact 36a, and the low level “0”. In this case, the switch 36-2 connects the movable contact 36c to the other fixed contact 36b. Therefore, as shown on the switching signal SW2, the video and audio data T2D of the second track output from the recording amplification circuit 35-2 forms an inclined track on the magnetic tape 39 by the recording / reproducing head 38-2. The audio / video data T6D of the sixth track recorded and output from the recording amplification circuit 35-2 is recorded by the recording / reproducing head 38-6 so as to form an inclined track on the magnetic tape 39, and the recording amplification circuit The video and audio data T10D of the 10th track output from 35-2 is recorded so as to form an inclined track on the magnetic tape 39 by the recording / reproducing head 38-2 (this is not shown).
[0289]
Next, when the switching signal SW3 supplied from the system controller 50 to the switch 36-3 is at the high level “1”, the switch 36-3 connects the movable contact 36c to the one fixed contact 36a, and the low level “0”. In this case, the switch 36-3 connects the movable contact 36c to the other fixed contact 36b. Therefore, as shown on the switching signal SW3, the video and audio data T3D of the third track output from the recording amplifier circuit 35-3 forms an inclined track on the magnetic tape 39 by the recording / reproducing head 38-3. The video and audio data T7D of the seventh track recorded and output from the recording amplification circuit 35-3 are recorded by the recording / reproducing head 38-7 so as to form an inclined track on the magnetic tape 39, and the recording amplification circuit The video and audio data T11D of the eleventh track output from 35-3 is recorded so as to form an inclined track on the magnetic tape 39 by the recording / reproducing head 38-3 (this is not shown).
[0290]
Next, when the switching signal SW4 supplied from the system controller 50 to the switch 36-4 is at the high level “1”, the switch 36-4 connects the movable contact 36c to the one fixed contact 36a, and the low level “0”. In this case, the switch 36-4 connects the movable contact 36c to the other fixed contact 36b. Therefore, as shown on the switching signal SW4, the video and audio data T4D of the fourth track output from the recording amplifier circuit 35-4 forms an inclined track on the magnetic tape 39 by the recording / reproducing head 38-4. The video and audio data T8D of the eighth track recorded and output from the recording amplification circuit 35-4 are recorded by the recording / reproducing head 38-8 so as to form an inclined track on the magnetic tape 39, and the recording amplification circuit The video and audio data T12D of the twelfth track output from 35-4 is recorded so as to form an inclined track on the magnetic tape 39 by the recording / reproducing head 38-4 (this is not shown). That is, as shown in FIG. 16, video and audio signals 38r1, 38r2,... 38r8 are recorded by the recording / reproducing heads 38-1, 38-2,.
[0291]
Next, the operation when the video tape cassette 20 is reproduced by the high-speed transfer device 21 shown in FIG. 13 will be described with reference to FIG. In FIG. 17, video and audio data are reproduced by the eight recording / reproducing heads 38-1,... 38-8 of the high-speed transfer device 21 shown in FIG. An operation when transferring reproduction data at a transfer rate will be described. For easy understanding, the reference numerals of the signals shown in FIG. 17 are also shown in FIG.
[0292]
In FIG. 17, 38p1 is a reproduction signal reproduced by the recording / reproduction head 38-1 shown in FIG. 13, and 38p5 is a reproduction signal reproduced by the recording / reproduction head 38-5 shown in FIG. 38p4, 38p6 to 38p8 are not shown), SW1, SW2, SW3 and SW4 are switching signals from the system controller 50, 42I1, 42I2, 42I3 and 42I4 are reproduction amplifier circuits 42-1, 42-2, respectively. The inputs 42-3 and 42-4, 46I1, 46I2, 46I3 and 46I4 are the inputs of the time axis compression circuits 46-1, 46-2, 46-3 and 46-4, 46O1, 46O2, 46O3 and 46O4 are Respective time axis compression outputs of the time axis compression circuits 46-1, 46-2, 46-3 and 46-4, 48p are multiplexed. Which is the output of the sub 47.
[0293]
Here, it should be noted that, in this example, the case where a transfer rate that is four times the normal transfer rate is obtained as in FIG. 16, the recording / reproducing head is 2 × n, that is, , 8 are required. Therefore, in this example, one fixed contact 36a of the switch 36-1 is connected to the primary side of the rotary transformer 37-1, and the other fixed contact 36b of the switch 36-1 is connected to the primary side of the rotary transformer 37-5. , One fixed contact 36a of the switch 36-2 is connected to the primary side of the rotary transformer 37-2, and the other fixed contact 36b of the switch 36-2 is connected to the primary side of the rotary transformer 37-6. Then, one fixed contact 36a of the switch 36-3 is connected to the primary side of the rotary transformer 37-3, and the other fixed contact 36b of the switch 36-3 is connected to the primary side of the rotary transformer 37-7. One fixed contact 36a of the switch 36-4 is connected to the primary side of the rotary transformer 37-4, and the other fixed contact 36b of the switch 36-4 is connected to the rotary transformer. 7-8 will be connected to the primary side of the.
[0294]
When the switching signal SW1 supplied from the system controller 50 to the switch 36-1 is high level “1”, the switch 36-1 connects the movable contact 36c to one fixed contact 36a, and when the switching signal SW1 is low level “0”. The switch 36-1 connects the movable contact 36c to the other fixed contact 36b. Accordingly, as indicated by the numbers “1” and “5” attached to the switching signal SW1, when the switching signal SW1 is at the high level “1”, the reproduction signal 38p1 from the recording / reproducing head 38-1 is reproduced by the reproducing amplifier circuit. When the switching signal SW1 is at a low level “0”, the reproduction signal 38p5 from the recording / reproducing head 38-5 is supplied to the reproducing amplifier circuit 42-1.
[0295]
Next, when the switching signal SW2 supplied from the system controller 50 to the switch 36-2 is at the high level “1”, the switch 36-2 connects the movable contact 36c to the one fixed contact 36a, and the low level “0”. In this case, the switch 36-2 connects the movable contact 36c to the other fixed contact 36b. Therefore, as indicated by the numbers “2” and “6” attached to the switching signal SW2, when the switching signal SW2 is at the high level “1”, the reproduction signal 38p2 from the recording / reproducing head 38-2 is reproduced by the reproducing amplifier circuit. When the switching signal SW2 is at a low level “0”, the reproduction signal 38p6 from the recording / reproducing head 38-6 is supplied to the reproducing amplifier circuit 42-2.
[0296]
Next, when the switching signal SW3 supplied from the system controller 50 to the switch 36-3 is at the high level “1”, the switch 36-3 connects the movable contact 36c to the one fixed contact 36a, and the low level “0”. In this case, the switch 36-3 connects the movable contact 36c to the other fixed contact 36b. Accordingly, as indicated by the numbers “3” and “7” attached to the switching signal SW3, when the switching signal SW3 is at the high level “1”, the reproduction signal 38p3 from the recording / reproducing head 38-3 is reproduced by the reproduction amplifier circuit. When the switching signal SW3 is at a low level “0”, the reproduction signal 38p7 from the recording / reproducing head 38-7 is supplied to the reproducing amplifier circuit 42-3.
[0297]
Next, when the switching signal SW4 supplied from the system controller 50 to the switch 36-4 is at the high level “1”, the switch 36-4 connects the movable contact 36c to the one fixed contact 36a, and the low level “0”. In this case, the switch 36-4 connects the movable contact 36c to the other fixed contact 36b. Therefore, as indicated by the numbers “4” and “8” attached to the switching signal SW4, when the switching signal SW4 is at the high level “1”, the reproduction signal 38p4 from the recording / reproducing head 38-4 is reproduced signal 42I1. Is supplied to the reproduction amplifier circuit 42-4. When the switching signal SW4 is at a low level "0", the reproduction signal 48p8 from the recording / reproduction head 40-8 is supplied as the reproduction signal 42I1 to the reproduction amplification circuit 42-4. .
[0298]
As shown in FIG. 17, the reproduction signals 42I1, 42I2, 42I3, and 42I4 are respectively supplied to the reproduction amplifier circuits 42-1 to 42-4, and are output after being reproduced and amplified by these reproduction amplifier circuits 42-1 to 42-4. The data extraction circuits 43-1 to 43-4 are supplied to the data extraction circuits 43-1 to 43-4, respectively. The data extraction circuits 43-1 to 43-4 reproduce the clock signal, and the data is extracted by the reproduced clock signal. The video and audio signals from the data extraction circuits 43-1 to 43-4 are sequentially supplied to the channel decoding circuits 44-1 to 44-4, and demodulated by the channel decoding circuits 44-1 to 44-4. The original video and audio data are supplied to the error correction circuits 45-1 to 45-n in the next stage and subjected to the error correction process as described above.
[0299]
The video and audio data subjected to the error correction process are supplied to the time axis compression circuits 46-1 to 46-4, respectively. The inputs 46I1, 46I2, 46I3 and 46I4 of the time axis compression circuits 46-1 to 46-4 are shown in FIG.
[0300]
For example, in FIG. 17, in this example, when the switching signal SW1 is at a low level “0” indicating “5”, the reproduction signal 38p5 from the recording / reproduction head 38-5 and the reproduction amplification circuit 42-1 are supplied. There is no deviation from the playback signal 42I1 at the time point. Similarly, when the switching signal SW1 is at a high level “1” indicating “1”, the playback signal 38p1 from the recording / playback head 38-1 and the playback amplification circuit 42- There is no deviation from the reproduction signal 42I1 at the time of being supplied to 1.
[0301]
However, at the time when the signals are supplied to the time axis compression circuits 46-1 to 46-4, for example, as indicated by the solid line arrow from the time axis compression circuit 46-1 input 46I1, there is a certain delay. This delay time depends on the processing time in the channel decoding circuits 44-1 to 44-4 and the error correction circuits 45-1 to 45-4, and the time PD shown in the figure indicates the delay time. .
[0302]
The video and audio data 46I1 to 46I4 supplied to the time axis compression circuits 46-1 to 46-4 are once written in the dual port memories of the time axis compression circuits 46-1 to 46-4, and then written. By reading out at a speed four times the speed, the time axis is compressed to ¼. The compressed video and audio data 46O1 to 46O4 are sequentially supplied to the multiplexer 47. The compressed video and audio data 46O1 to 46O4 supplied to the multiplexer 47 are converted into serial data, output from the output terminal 48 as high-speed video and audio data 48p, and supplied to the temporary recording or storage device 22 shown in FIG. .
[0303]
As can be seen from FIG. 17, the compressed video and audio data 46O1 indicated by diagonal lines includes the first track corresponding data T1D, the fifth track corresponding data T5D, and the ninth track corresponding data T9D, and the compressed video and audio data 46O2 indicated by dots. Is composed of the second track corresponding data T2D, the sixth track corresponding data T6D, and the tenth track corresponding data T10D. The compressed video and audio data 46O3 indicated by the diagonal lines opposite to the compressed video and audio data 46O1 is the third track corresponding data T3D. , The seventh track corresponding data T7D and the eleventh track corresponding data T11D. The white (indicating no pattern) compressed video and audio data 46O4 is the fourth track corresponding data T4D, the eighth track corresponding data T8D and the twelfth track. Consists of track-corresponding data T12D
[0304]
As described above, in this example, video and audio data reproduced by the high-speed transfer device 21 at n times the normal speed are output at a transfer speed n times the normal transfer speed, and the normal transfer speed is reduced. Video and audio data having a transfer speed of n times is temporarily recorded or stored in the storage device 22 at high speed, and the video and audio data recorded or stored in the temporary recording or storage device 22 are output interface circuits 23-1 and 23-23. -2, ... 23-k to convert to a normal transfer rate, and the video special effect mixer 25 performs video special effect processing and audio signal processing on the video and audio data converted to the normal transfer rate. The video special effect mixer 25 outputs video and audio data at a normal transfer rate are temporarily recorded or stored in the storage device 22, and the temporary recording or storage device 22 stores the high-speed video and audio data. Are output as video and audio data having a transfer speed n times the normal transfer speed, and the video and audio data having the normal transfer speed are recorded at a recording speed four times the normal recording speed by the high-speed transfer device 26. Therefore, only the processing in the video special effect mixer 25 required by the operator in the editing system can be performed at a normal transfer speed, and in other processes, transfer is performed at a transfer speed n times the normal transfer speed. Therefore, the editing efficiency is greatly improved, and the high-speed transfer device 26 is used to record the time to record or store the material to be edited in the temporary recording or storage device 22 and the video and audio data read from the temporary recording or storage device 22. The recording or storing time (which is a waiting time for the operator) can be greatly shortened. Further, since the material is temporarily recorded or stored in the temporary recording or storage device 22 and the material once recorded or stored in the temporary recording or storage device 22 is edited, the high-speed transfer device is used after all editing is completed. 26, the edited material is recorded, and at the time of the next editing, a new edited material is added to the edited material recorded or stored in the temporary recording or storage device 22, or a new material is added. It is possible to temporarily record the material after the insert portion of the edited material that has been previously edited and recorded or stored, or to record or store the material for insert, and to record or store the material for the insert in the portion to be inserted. Since it can be performed in the recording or storage device 22, so-called relaying is performed on the tape of the video tape cassette set in the high-speed transfer device 26. Can to eliminate eye, can be created very precise edited tape, for example, a tape for delivery of such CM1 unified tape.
[0305]
Further, when the high-speed transfer devices 21 and 26 are constituted by VTRs, xn recording / reproducing heads 38-1, 38-2,... 38-2n (in this case) In this case, x is “2”), and the recording drum of the magnetic tape 39 that is running at a running speed n times the normal running speed is scanned and rotated. / Playback heads 38-1, 38-2, ... 38-2n Playback video and audio data obtained by playback with n data extraction circuits 43-1 to 43-n, n channel decoding Each of the circuits 44-1 to 44-n, n error correction circuits 45-1 to 45-n, and n time-axis compression circuits 46-1 to 46-n performs signal processing. The data is converted into serial data by the multiplexer 47. Since the data is output, video and audio data having a transfer speed n times the normal transfer speed is serially output and temporarily recorded or recorded or stored in the storage device 22 at a speed 1 / n of the normal processing time. be able to.
[0306]
On the other hand, when the high-speed transfer devices 21 and 26 are configured with a VTR, when recording at a high speed with a recording system, video and audio data having a transfer rate n times the normal transfer rate is demultiplexed with n video and audio data. The video data and audio data are divided into n pieces of time axis expansion circuits 32-1 to 32-n, n ECC addition circuits 33-1 to 33-n, and n channel coding circuits 34-. 1 to 34-n, and the signal-processed n video and audio data are converted into xn recording / reproducing heads 38-1, 38-2,... 38-2n (in this case, x is “ 2 ”) is rotated at a normal rotational speed, and the magnetic tape 39 running at a traveling speed n times the normal traveling speed is scanned and recorded. Video with a transfer speed n times the transfer speed Fine audio data can be recorded on the magnetic tape 39 at a rate of 1 / n of the normal processing time.
[0307]
Also, the video and audio data having a transfer rate n times the normal transfer rate is divided into m video and audio data for each time slot by the demultiplexer 61 of the temporary recording or storage device 22 and obtained by dividing. The m video and audio data are recorded or stored in the media set in the m disk drives 78-1 to 78-m, and the recorded or stored m video and audio data is 1 by the matrix switcher 65. The one video and audio data is selectively supplied to the output interface circuits 23-1 to 23-k, and is connected via the input interface circuit 24. The demultiplexer 75 converts the video and audio data supplied from the video special effect mixer 25 or audio data from the outside with m demultiplexers 75. The video data and audio data are divided into image and audio data, and the divided m video and audio data are recorded or stored in the media set in the disk drives 78-1 to 78-m, respectively, and recorded or stored in these media. Since the video and audio data are read out and supplied to the multiplexer 81, converted into serial data by the multiplexer 81 and output, the editing efficiency is greatly improved, and the waiting time for the recording and reproduction processing is at least 1/1 of the normal one. In addition, since the temporary recording or storage device 22 is interposed between the high-speed transfer machines 21 and 26, for example, a plurality of materials to be edited are set in the disk drives 78-1 to 78-m, respectively. It is recorded or stored in each medium or one medium, and recorded or recorded in these temporary recording or storage devices 22. It is possible to easily supply a plurality of processed materials in parallel to the video special effect mixer 25 for editing, and to make it easier for the operator to perform editing with the same materials over and over again. become.
[0308]
In addition, in the output interface circuits 23-1 to 23-k, when the video and audio data are compression-encoded, the compression-decoding processing circuit 95 can perform the compression-decoding process, and the input interface circuit 24 Since the video and audio data can be compression-encoded, it is possible to select the compression-encoding for the video data and to perform the editing work regardless of the selection. In the above example, the case where compression encoding can be performed only on video data has been described. However, it is obvious that audio data can be compressed and decoded in the same manner as video data. As described above, in the editing system in which compression encoding can be selected, if compression encoding is performed, the recording or storage capacity of the temporary recording or storage device 22 can be greatly increased equally.
[0309]
Also, when xn heads are mounted on the rotating drum and the normal transfer speed is required, the magnetic tape 39 is rotated at the normal running speed and the rotating drum is rotated at the normal rotating speed. In the editing work, for example, confirmation, monitoring, and the like can be performed without adding a configuration therefor.
[0310]
Further, when xn heads are mounted on the rotating drum and the transfer speed of 1 / n of the normal transfer speed is required, the magnetic tape 39 is operated at the normal traveling speed and the rotating drum is operated at the normal rotation speed. In the editing operation, for example, by selecting video and audio data with few errors, a more accurate editing result can be obtained.
[0311]
In the above example, the video and audio data are described as being in the NTSC format. However, the system clock frequency and the recording / reproducing heads 38-1 to 38- are also used in the PAL format, SECAM format, or high-definition television format. This can be realized by setting various parameters in each component such as the number of 2n and the number of rotations of the rotating drum. Of course, when the video and audio data is a high-definition television system, the transfer rate can be further improved by using compression encoding and decoding processing.
[0312]
[Fourth embodiment]
[0313]
In the third embodiment, the case where the recording / reproducing heads 38-1, 38-2,... 38-8 are arranged at equal intervals on the rotary drum 200 has been described. Two sets may be arranged so as to face each other. In this case, unlike the case where they are arranged at equal intervals, the timing of recording and reproduction differs for each group. As an effect, the recording and reproduction timings of the four heads constituting at least one set are the same, so that the processing is easy, and the mounting of the heads for each set (four heads are mounted on one head mount). In other words, the assembly process is simplified.
[0314]
[Fifth embodiment]
[0315]
In the third embodiment, the case where the lead angle is set has been described. However, when the high-speed transfer device 21 reproduces a tape recorded at a high speed at a high speed, the lead angle may be kept at a normal setting.
[0316]
【The invention's effect】
  According to the editing system of the present invention described above, the information to be edited is reproduced at a speed n times the normal reproduction speed by the high speed reproduction unit, and the information is output at a transfer speed n times the normal transfer speed. Reproduction information from the high-speed reproduction unit is recorded or stored in a recording or storage unit, information read from the recording or storage unit is subjected to predetermined signal processing by a signal processing unit, and output from the signal processing unit for recording. Alternatively, when the information recorded or stored in the storage unit is read out, the read out information is recorded or stored at a high speed recording or the storage unit at a normal recording speed or at a speed n times the storage speed. Since the storage unit, signal processing unit, high-speed recording, or storage unit is controlled by the control unit, when editing information, the information to be edited is reproduced, and the reproduction information is transferred at a speed and after the editing. And record Thus, when applied to an editing system, it is possible to provide an operator-friendly environment, greatly improve editing accuracy and editing efficiency, and, for example, Additions to the edited material, various processes such as inserts are performed later, and after that, by recording or storing the edited material, it is possible to eliminate the occurrence of so-called seams on the finally obtained medium, etc. There is an effect that applicability can be given to the editing process.
  Furthermore, according to the first editing system of the present invention, even when a semiconductor memory is used, the information to be edited can be reproduced and transferred at a normal speed n times. In addition, the editing work efficiency in the editing system can be improved, and the configuration of the editing system can be simplified.
  Furthermore, according to the second editing system of the present invention, even when a semiconductor memory is used, the edited information can be recorded and transferred at a speed n times the normal speed. Therefore, it is possible to obtain a reproduction signal at a normal speed, and in addition to the above-mentioned effects, it is possible to obtain a transfer speed required with a simple configuration and simple processing, and to improve editing work efficiency. There is an effect that can be.
[0325]
Further, according to the editing system of the present invention described above, the information of the transfer rate n times the normal transfer rate is divided into n pieces of information by the first demultiplexer, and the input information of the normal transfer rate is changed to the second demultiplexer. The information is divided into n pieces of information by a multiplexer, and each piece of n pieces of information from the first or second demultiplexer is recorded or stored by a recording or storing means, and a plurality of information read from the recording or storing means is stored. Since it is selectively output by the matrix switcher, n pieces of information having a transfer rate n times the normal transfer rate read from the recording or storage means are converted to the original information by the multiplexer and output. Recording or storing information on a transfer rate n times the normal transfer rate, reading information on a transfer rate n times the recorded or stored normal transfer rate, and transferring information n times the normal transfer rate In addition to the above-described effects, data can be matched well in the editing system, and an editing system with high editing efficiency can be obtained. is there.
[0326]
Further, according to the editing system of the present invention described above, the number of information from the first or second demultiplexer, recording or storage means and between the first and second demultiplexers, recording or storage means and the matrix switcher Since the same number of buses are connected, and the time distribution of input / output information on the bus is controlled by the control unit, recording, storage, reading, etc. in the recording or storage unit can be performed efficiently. Thus, in addition to the effects described above, there is an effect that a plurality of processes such as recording, reproduction, and editing can be performed simultaneously.
[0329]
Furthermore, according to the editing system of the present invention described above, information on the transfer rate n times the normal speed from the high-speed playback unit is stored in time by the decompression means provided between the output side of the recording or storage unit and the input side of the signal processing unit. The output of the signal processing unit or the input information from the outside is temporally compressed by compression means provided between the input side of the recording or storage unit and the output side of the signal processing unit or the outside. Therefore, information at a transfer rate n times the normal speed recorded or stored in the recording or storage unit can be output so that it can be used by the signal processing unit, and information can be output from the recording or storage unit at a transfer rate n times the normal transfer rate. Can be output to a high-speed recording or storage unit, and high-speed recording or storage can be performed. In addition to the above-described effects, a device with a normal transfer speed can be used in the editing system. The or a new specification, there is an effect that it is possible to obtain a new good editing system with edit efficiency have not produced devices of this specification.
[0330]
Furthermore, according to the editing system of the present invention described above, information on a transfer rate n times the normal transfer rate read from the recording or storage unit is stored in the buffer memory means, and the normal transfer rate from the buffer memory means is stored. Is output by the variable speed reproduction processing means, the output information from the variable speed reproduction processing means is output by the output means, and the reproduction control communication means is the buffer memory means variable speed reproduction processing based on the control signal from the control unit. Since the unit is controlled, it is possible to output information of a transfer rate n times the normal transfer rate recorded or stored in the recording or storage unit at a normal transfer rate, and in addition to the above effects, There is an effect that decompression processing in the editing system can be performed with a simple configuration.
[0332]
Furthermore, according to the editing system of the present invention as described above, information on the normal transfer rate from the signal processing unit or the outside is input by the input means, and output information from the input means is temporarily stored in the buffer memory, and the input means Since the buffer memory is controlled by the recording control communication means, the normal transfer rate information recorded or stored in the recording or storage unit can be output at a transfer rate n times the normal transfer rate. Thus, in addition to the above-described effects, there is an effect that data can be recorded or stored at high speed in the recording or storage unit, and data of different transfer rates can be matched in the editing system.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a first embodiment of an editing method and system according to the present invention.
FIG. 2 is a block diagram showing an example of a main part of a first embodiment of the editing method and system according to the present invention, in which the high-speed transfer machines 21 and 26 shown in FIG.
FIG. 3 is a block diagram of a temporary recording or storage device 22 shown in FIG. 1, showing an example of a main part of a first embodiment of the editing method and system of the present invention.
4 is a block diagram of an input interface circuit 24 shown in FIG. 1, showing an example of a main part of a first embodiment of the editing method and system of the present invention.
5 shows an example of a main part of the first embodiment of the editing method and system of the present invention, and is a configuration diagram of the output interface circuits 23-1, 23-2,... 23-k shown in FIG. is there.
FIG. 6 is an explanatory diagram for explaining the relationship between a transfer format and a tape recording track pattern for explaining the first embodiment of the editing method and system of the present invention;
FIG. 7 is a timing chart for explaining the signal processing in the recording system of the high-speed transfer machine for explaining the first embodiment of the editing method and system of the present invention.
FIG. 8 is a timing chart for explaining signal processing in the reproduction system of the high-speed transfer machine for explaining the first embodiment of the editing method and system of the present invention.
FIG. 9 is a timing chart for explaining a high-speed transfer recording or storage operation in a temporary recording or storage device for explaining the first embodiment of the editing method and system of the present invention;
FIG. 10 is a timing chart for explaining the high-speed transfer reproduction operation in the temporary recording or storage device for explaining the first embodiment of the editing method and system of the present invention.
FIG. 11 is a timing chart for explaining operations during normal speed reproduction and recording in the input interface circuit 24 for explaining the first embodiment of the editing method and system of the present invention;
FIG. 12 is a configuration diagram showing a configuration example of a main part of a second embodiment of the editing method and system according to the present invention.
13 is a block diagram showing an example of a main part of a third embodiment of the editing method and system according to the present invention, wherein the high-speed transfer devices 21 and 26 shown in FIG.
FIG. 14A is an explanatory diagram showing an example of mounting of a recording / reproducing head on a rotating drum for explaining a third embodiment of the editing method and system of the present invention.
B is explanatory drawing for demonstrating the level | step difference of a rotating drum with which it uses for description of 3rd Example of this invention editing method and system.
C is an explanatory diagram for explaining a lead angle for explaining a third embodiment of the editing method and system of the present invention. FIG.
D is an explanatory diagram for explaining an example of a normal lead angle for explaining a third embodiment of the editing method and system of the present invention.
E Explanation for explaining an example of a lead angle that is four times the normal lead angle (that is, when a transfer rate that is four times the normal transfer rate is obtained) used to explain the third embodiment of the editing method and system of the present invention. FIG.
FIG. 15 is an explanatory diagram for explaining the relationship between a transfer format and a tape recording track pattern for explaining a third embodiment of the editing method and system of the present invention.
FIG. 16 is a timing chart for explaining the signal processing in the recording system of the high-speed transfer machine for explaining the third embodiment of the editing method and system of the present invention.
FIG. 17 is a timing chart for explaining signal processing in the reproduction system of the high-speed transfer machine for use in explaining the third embodiment of the editing method and system of the present invention.
FIG. 18 is a configuration diagram illustrating an example of a conventional editing system.
[Explanation of symbols]
20, 29 Video tape cassette, 21, 26 High-speed transfer machine, 22 Temporary recording or storage device, 23-1, 23-2, ... 23-k, 98, 102 Output interface circuit, 24, 111, 116 inputs Interface circuit
25, video special effect mixer, 27, 49, 157 control unit, 28 operation unit, 31, 61, 75 demultiplexer, 32-1, 32-2, ... 32-n, 151 time base extension circuit, 33- 1, 33-2,... 33-n, 152 ECC (Error Correction Code) addition circuit, 34-1, 34-2,... 34-n CHCOD (channel coder), 35-1 , 35-2,... 35-n recording amplifier circuit, 36-1, 36-2,.
37-1, 37-2, ... 37-n, 37-n + 1, 37-n + 2, ... 37-2n Rotary transformer, 38-1, 38-2, ... 38-n, 38-n + 1, ... 38-2n recording / reproducing head, 39 magnetic tape, 42-1, 42-2, ... 42-n reproduction amplification circuit, 43-1, 43-2, ... 43-n data extraction circuit, 44-1, 44-2, ... 44-n CHDEC (channel decoder), 45-1, 45-2, ... 45-n, 163 error correction circuit, 46-1, 46-2, ... 46-n, 164 Time axis compression circuit, 47 Multiplexer, 50, 76, 158 System controller, 52, 160 System clock / synchronization signal generation circuit, 65 Matrix switcher, 78- 1, 8-2, ... 78-m disk drive, 80-1, 80-2, ... 80-m disk controller, 91-1, 91-2, ... 91-m decoding and writing 92-m FIFO (first in first out memory), 94 read control circuit, 95 compression decoding processing circuit, 96, 97 variable speed reproduction processing circuit, 100, 104 DA converter, 107 reproduction control communication controller, 113, 118 AD converter, 120 compression encoding circuit, 121 buffer memory, 123 recording control communication controller, 152 ECC (error correction code) addition circuit, 154 I / O control circuit, 155 semiconductor memory, 156 write / read circuit

Claims (10)

A semiconductor memory and write / read control means, and when the input information is stored in the semiconductor memory, the write / read control means supplies a control signal for writing to the semiconductor memory, and When reading the stored information from the semiconductor memory, the writing / reading control means uses at least the input information to be stored in the semiconductor memory so that it can be read at a transfer rate n times the normal transfer rate. By supplying a control signal for reading at a speed n times the control signal for writing to the semiconductor memory, the information to be edited is reproduced at a speed n times the normal reproduction speed, and the information is transferred normally. A high-speed playback unit that outputs at a transfer speed n times the speed;
A recording or storage unit for recording or storing the reproduction information from the high-speed reproduction unit;
A signal processing unit for performing predetermined signal processing on the information read from the recording or storage unit;
When the information output from the signal processing unit and recorded or stored in the recording or storage unit is read at a transfer rate n times the normal transfer rate, the read information is stored in the normal storage. A high-speed recording or storage unit for recording or storing at a speed n times the speed;
A control unit for controlling the high-speed playback unit, the recording or storage unit, the signal processing unit, and the high-speed recording or storage unit;
Have
A first demultiplexer that divides information of a transfer rate n times the normal transfer rate into a plurality of pieces of information; and the input information of the normal transfer rate is divided into a plurality of pieces of information. A second demultiplexer, a recording or storing means for recording or storing a plurality of pieces of information from the first or second demultiplexer, and a plurality of information read from the recording or storing means. A matrix switcher that selectively outputs, and a multiplexer that converts a plurality of pieces of information with a transfer rate n times the normal transfer rate read from the recording or storage means into original information and outputs the information.
An editing system characterized by that. Between the first and second demultiplexers, the recording or storage means and the matrix switcher, the same number of buses as the number of information from the first or second demultiplexer or recording or storage means 2. The editing system according to claim 1, further comprising a control unit connected to control temporal distribution of input / output information on the bus. Decompression means for temporally extending information of a transfer rate n times the normal speed from the high-speed reproduction unit between the output side of the recording or storage unit and the input side of the signal processing unit; and the recording or storage unit 2. The compression means for temporally compressing the output of the signal processing unit or input information from the outside between the input side and the output side of the signal processing unit or the outside. Editing system. The expansion means shifts the output information of the normal transfer rate from the buffer memory means for storing information of transfer speed n times the normal transfer speed read from the recording or storage unit. Variable speed reproduction processing means for performing reproduction processing, output means for outputting output information from the variable speed reproduction processing means, and reproduction control for controlling the buffer memory means and the variable speed reproduction processing section based on a control signal from the control section 4. The editing system according to claim 3, wherein the editing system comprises communication means. The compression means includes an input means for inputting normal transfer rate information from the signal processing unit or the outside, a buffer memory for temporarily storing output information from the input means, the input means, and the input means. 4. The editing system according to claim 3, further comprising recording control communication means for controlling the buffer memory. A high-speed playback unit that plays back information to be edited at a speed n times the normal playback speed and outputs the information at a transfer speed n times the normal transfer speed;
A recording or storage unit for recording or storing the reproduction information from the high-speed reproduction unit;
A signal processing unit for performing predetermined signal processing on the information read from the recording or storage unit;
A semiconductor memory and write / read control means, and the information output from the signal processing unit and recorded or stored in the recording or storage unit is n times the normal transfer rate. When the read / write control means stores the read information in the semiconductor memory, the write / read control means supplies a control signal for writing to the semiconductor memory. Information read at a transfer speed n times the normal transfer speed is stored at a speed n times the normal storage speed, and when the stored information is read from the semiconductor memory, it can be read at a normal transfer speed. As described above, the write / read control means supplies the semiconductor memory with a read control signal at a speed 1 / n times as high as the write control signal used when storing information in the semiconductor memory. And
A control unit for controlling the high-speed playback unit, the recording or storage unit, the signal processing unit, and the high-speed storage unit;
Have
A first demultiplexer that divides information of a transfer rate n times the normal transfer rate into a plurality of pieces of information; and the input information of the normal transfer rate is divided into a plurality of pieces of information. A second demultiplexer, a recording or storing means for recording or storing a plurality of pieces of information from the first or second demultiplexer, and a plurality of information read from the recording or storing means. A matrix switcher that selectively outputs, and a multiplexer that converts a plurality of pieces of information with a transfer rate n times the normal transfer rate read from the recording or storage means into original information and outputs the information.
An editing system characterized by that. Between the first and second demultiplexers, the recording or storage means and the matrix switcher, the same number of buses as the number of information from the first or second demultiplexer or recording or storage means 7. The editing system according to claim 6, further comprising a control unit connected to control temporal distribution of input / output information on the bus. Decompression means for temporally extending information of a transfer rate n times the normal speed from the high-speed reproduction unit between the output side of the recording or storage unit and the input side of the signal processing unit; and the recording or storage unit 7. The compression means for temporally compressing the output of the signal processing unit or input information from the outside between the input side and the output side of the signal processing unit or the outside. Editing system. The expansion means shifts the output information of the normal transfer rate from the buffer memory means for storing information of transfer speed n times the normal transfer speed read from the recording or storage unit. Variable speed reproduction processing means for performing reproduction processing, output means for outputting output information from the variable speed reproduction processing means, and reproduction control for controlling the buffer memory means and the variable speed reproduction processing section based on a control signal from the control section 9. The editing system according to claim 8, further comprising communication means. The compression means includes an input means for inputting normal transfer rate information from the signal processing unit or the outside, a buffer memory for temporarily storing output information from the input means, the input means, and the input means. 9. The editing system according to claim 8, wherein the editing system comprises recording control communication means for controlling the buffer memory.

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