JP4144137B2 - VIDEO RECORDING / REPRODUCING DEVICE AND MONITOR SIGNAL OUTPUT METHOD - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a video recording / reproducing apparatus, such as an AV server, that simultaneously inputs / outputs video signals through a plurality of channels and outputs a currently input / output video signal for monitoring.
[0002]
[Prior art]
In recent years, with the spread of data provision due to the widespread use of CATV (cable television) and the like, unlike a conventional VTR (video tape recorder), a single video / audio video recording / reproducing apparatus can be used to generate a plurality of video / audio data ( (Hereinafter referred to as “AV data”) is being recorded, played back, and further played back while being recorded. In order to satisfy this requirement, an apparatus called a video server (also called an AV (Audio and / or Video) server) that records and reproduces video / audio using a randomly accessible recording medium such as a hard disk is becoming widespread. is there.
[0003]
In general, an AV server in a broadcasting station is required to have a high data transfer rate and a large capacity in order to record data for a long time due to demands for image quality and sound quality. Therefore, attempts to increase the data transfer rate and increase the capacity by using a plurality of hard disk (hereinafter referred to as “HD”) devices that can store AV data and perform parallel processing, and further record parity data. Thus, an attempt is made to ensure reliability even if any HD device fails.
[0004]
As a result, even when the number of channels required differs depending on the content of the program that the broadcast station intends to provide and the broadcast form, the material data consisting of a plurality of AV data is recorded in a distributed manner and transmitted in multiple channels. Can be used at the same time, or the same material data can be played back in multiple channels with different playback times to build a system such as VOD (Video On Demand) or NVOD (Near Video On Demand). It is possible to realize a multi-channel AV server that can handle this.
[0005]
HD devices used in such AV servers include a paper published by Patterson et al. In 1988 ('A Case for Redundant Arrays of Inexpensive Disks (RAID)', ACM SIGMOND Conference, Chicago, III, Jun. 1-3. , 1988.), a RAID (Redundant Arrays of Independent Disks) technology in which a plurality of hard disk drives (hereinafter referred to as “HDDs”) composed of a plurality of HDs are further arrayed is used.
[0006]
In the above paper, RAID is classified into five groups from RAID-1 to RAID-5. RAID-1 is a method for writing the same contents to two HDDs. RAID-3 divides input data into a certain length and records it on a plurality of HDDs, and generates parity data that is an exclusive OR of data blocks corresponding to each HDD, and generates another one This is a method of writing to the HDD. RAID-5 further increases the data division unit (block), records one piece of divided data as a data block in one HDD, and performs exclusive OR of the data blocks corresponding to each HDD. The result (parity data) is recorded as a parity block in another HDD and the parity block is distributed to other HDDs.
For other RAIDs, see the above paper.
[0007]
In order to simultaneously record / reproduce a plurality of AV data with this AV server, it is necessary to simultaneously input / output video / audio signals (hereinafter referred to as “AV signals”) on a plurality of channels. Therefore, the AV server is provided with a plurality of input / output ports that operate independently from each other, and one input port and one output port respectively input and output one channel.
[0008]
However, when each input / output port transfers AV data to / from the video recording / reproducing device at the same time, the AV data is transferred to the bus connecting the input / output port and the video recording / reproducing device in the AV server. Cannot be processed at the same time. Therefore, time slots (= time intervals) that permit the use of the bus are assigned in order to each input / output port, and each input / output port is synchronized with the reference video signal and is only in the assigned time slot. The AV data is transferred to and from the video recording / reproducing apparatus via the. Therefore, strictly speaking, a plurality of AV data is not recorded / reproduced at the same time. However, when viewed at a time interval longer than the time slot, a plurality of AV data can be recorded / reproduced simultaneously. It's okay.
[0009]
By the way, when such an AV server is used in a broadcasting station, what AV data is currently recorded / reproduced by the AV server (that is, what AV data is currently being input / output at each input / output port). ) Must be able to be confirmed from time to time on a monitor. Therefore, the AV server generally has a function of outputting the AV signal currently being input / output together with the synchronization signal for monitoring.
[0010]
In the conventional AV server, the synchronization signal for monitoring is reproduced and output from the synchronization signal extracted from the reference video signal.
[0011]
FIG. 3 shows an example of output of a monitor signal in a conventional AV server, taking an AV server having two input / output ports as an example.
[0012]
Extraction of a horizontal synchronization signal REFHD, a vertical synchronization signal REFVD, and a color frame synchronization signal (color subcarrier reference phase signal) REFCF from a reference video signal supplied to the AV server from the outside by a timing signal generation unit (not shown) and a clock signal REFCLK and time slot signal TS are generated. Signals REFHD, REFVD, REFCF, REFCLK and TS are given to the input / output ports 101 and 102, and signals REFHD, REFVD, REFCF and REFCLK are also given to the monitor output unit 103.
[0013]
The input / output ports 101 and 102 have the same configuration. For the AV signal input from the outside, the preprocessing circuit 104 first performs the following preprocessing of (a) to (d) in order. Is called.
[0014]
(A) A process of extracting the horizontal synchronization signal INHD, the vertical synchronization signal INVD, and the color frame synchronization signal INCF from the input AV signal to generate the clock signal INCLK.
(B) Time axis correction processing by the time base collector.
(C) Processing for reading the VITC code from the AV signal.
(D) A process of removing high-frequency components from the AV signal by a band filter.
[0015]
When the AV signal is a US standard NTSC signal, the process of adjusting the setup level to 0%, which is the same as the Japanese standard NTSC signal, is also performed as one of the pre-processes.
[0016]
The AV signal that has been preprocessed by the preprocessing circuit 104 is sent to the monitor output unit 103 and compressed by the encoder 105 using a predetermined encoding method (for example, MPEG). After the AV data obtained by this compression is stored in the buffer memory 106, RAID technology is adopted through a bus (not shown) in the time slot assigned to the input / output port by the time slot signal TS. To the recording / reproducing unit (not shown).
[0017]
On the other hand, AV data transferred from the recording / playback unit via the bus is stored in the buffer memory 107 and then decoded (expanded) by the decoder 108 (after decoding, various post-processing is performed by the decoder 108). In some cases). The AV signal obtained by this decoding is sent to the monitor output unit 103 and output to the outside of the AV server.
[0018]
In this manner, the input / output ports 101 and 102 simultaneously input an AV signal for one channel and output an AV signal for one channel, respectively, and the AV signals for a total of four channels are output to the monitor output unit. 103.
[0019]
In the monitor output unit 103, only one of the AV signals specified by the operation of the operator of the AV server among these AV signals is input to the synchronization signal reproduction circuit 110 through the switch circuit 109.
[0020]
The synchronizing signal reproduction circuit 110 uses the clock signal REFCLK as an operation clock, and the horizontal synchronizing signal REFHD ′ and the vertical synchronizing signal REFVD ′ that are in phase with the reference video signal from the horizontal synchronizing signal REFHD, the vertical synchronizing signal REFVD, and the color frame synchronizing signal REFCF. The color frame synchronization signal REFCF ′ is reproduced, and these synchronization signals REFHD ′, REFVD ′, and REFCF ′ are output together with the AV signal and the clock signal REFCLK.
[0021]
These signals output from the synchronization signal reproduction circuit 110 are sent from the monitor output unit 103 to a monitor (not shown) outside the AV server.
[0022]
As shown in FIG. 3, the monitor output synchronization signal is reproduced from the synchronization signal extracted from the reference video signal for the following reason.
In general, in an AV server, an AV signal synchronized with a reference video signal is input and output from an input / output port in phase with the reference video signal.
Therefore, in FIG. 3, the AV signal input to the preprocessing circuit 104 and the AV signal output from the decoder 108 are in phase with the reference video signal.
[0023]
However, since the processing in the preprocessing circuit 104 requires several lines, the AV signal output from the preprocessing circuit 104 is delayed by several lines from the AV signal input to the preprocessing circuit 104. (I.e. out of phase with the reference video signal). As a result, AV signals whose phases do not coincide with each other are sent to the monitor output unit 103 from the preprocessing circuit 104 and the decoder 108.
[0024]
When these AV signals whose phases do not coincide with each other are displayed on the monitor in synchronization with the synchronization signal included in the AV signal, image disturbance caused by discontinuity of synchronization occurs when the channel of the AV signal to be displayed is switched. Will occur.
[0025]
Therefore, a synchronization signal reproduced from the synchronization signal extracted from the reference video signal is sent to the monitor, and an image is always displayed in synchronization with this synchronization signal, so that synchronization discontinuity does not occur even when the channel is switched. ing.
[0026]
[Problems to be solved by the invention]
However, sending the synchronization signal reproduced from the synchronization signal extracted from the reference video signal to the monitor as described above has the following disadvantages (1) and (2).
[0027]
(1) When the AV signal currently being input to the input / output port 101 or 102 is displayed on the monitor, the image shift of several lines in the downward direction of the screen caused by the delay in the pre-processing circuit 104 remains as it is. It will remain.
[0028]
If a frame memory is provided in the monitor output unit 103 and the AV signal output from the sync signal reproduction circuit 110 is temporarily stored in the frame memory and then sent to the monitor, this image shift can be eliminated. It is. However, since the frame memory is expensive, the cost of the entire AV server is increased.
[0029]
(2) The AV signal transmitted from the outside to the AV server is not only an AV signal synchronized with the reference video signal but also an AV signal using, for example, SNG (Satellite News Gathering) or Ethernet. Thus, there is an AV signal that is asynchronous with the reference video signal. Since it is difficult to synchronize the AV signal asynchronous with the reference video signal with the reference video signal by the time base collector, conventionally, the AV signal is recorded once in the VTR and then reproduced in synchronization with the reference video signal from the VTR and then sent to the AV server. It is input, or is input to the AV server in synchronization with the reference video signal by a frame synchronizer.
[0030]
However, in recent years, particularly in news editing and the like, by directly inputting an AV signal that is asynchronous with the reference video signal to an AV server and recording it, there is a strong demand to simultaneously perform the editing operation when recording the material. Yes.
[0031]
As one of the methods for satisfying such a demand, in FIG. 3, the time base correction processing by the time base collector of (b) described above in the preprocessing circuit 104 is omitted, and the processing of (c) described above in the preprocessing circuit 104 is omitted. From the writing to the buffer memory 106 using the clock signal INCLK as an operation clock (that is, synchronized with the input AV signal), and reading from the buffer memory 106 using the clock signal REFCLK as the operation clock (that is, synchronized with the reference video signal). There is a method to do.
[0032]
The present applicant has already proposed this method in the patent application of Japanese Patent Application No. 11-109833. Hereinafter, this method is referred to as an “input lock method”. Conventionally, the processing from (b) in the pre-processing circuit 104 to reading from the buffer memory 106 has been performed using the clock signal REFCLK as an operation clock. Hereinafter, this conventional method is referred to as a “reference lock method”. I will call it.
[0033]
According to this input lock method, the buffer memory 106 can be used as a frame synchronizer, and an AV signal asynchronous with the reference video signal can be directly input to the input / output ports 101 and 102 and recorded in the recording / reproducing unit. .
[0034]
However, when an AV signal asynchronous with the reference video signal is directly input to the input / output ports 101 and 102 in this way, the AV signal asynchronous with the reference video signal is also sent from the preprocessing circuit 104 to the monitor output unit 103. It will be. When such an AV signal is sent from the monitor output unit 103 to the monitor, if an image is displayed in synchronization with the synchronization signal reproduced from the synchronization signal extracted from the reference video signal, the frequency difference between the AV signal and the reference video signal is displayed. As a result, a synchronization flow (a phenomenon in which a horizontal synchronization signal is displayed so as to flow to the left and right of the screen) appears.
[0035]
As described above, in the conventional AV server that sends the synchronization signal reproduced from the synchronization signal extracted from the reference video signal to the monitor, the AV signal currently input to the input / output port is displayed on the monitor when the input lock method is adopted. When doing so, a synchronization flow appears.
[0036]
In view of the above points, the present invention is directed to the downward direction of the screen caused by a delay in the preprocessing circuit of the input / output port when the AV signal currently being input to the input / output port is displayed on the monitor in the AV server. The problem is to eliminate the image shift without providing a frame memory and to eliminate the synchronization flow when the input lock method is adopted.
[0037]
[Means for Solving the Problems]
In order to solve this problem, the present applicant, as described in claim 1, has a recording / reproducing unit for recording and reproducing data using a non-linear accessible recording medium, and a video signal input from the outside. At least one input / output unit for transferring a video signal to a recording / reproducing unit through pre-processing including extraction of a synchronization signal from the signal and generation of a clock signal, and outputting the video signal transferred from the recording / reproducing unit to the outside; A timing signal generation unit that extracts a synchronization signal and generates a clock signal from a reference video signal supplied by the video signal; a video signal that has undergone preprocessing in the input / output unit; and a video signal that is output to the outside by the input / output unit And a monitor output unit that outputs the signal for monitoring. The monitor output unit extracts the synchronization signal / clock signal extracted and generated by the input / output unit and the timing signal generation unit. A selection means for selecting any one of the generated synchronization signal and clock signal, and a clock signal selected by the selection means as an operation clock, and a synchronization signal using the synchronization signal selected by the selection means There is proposed a video recording / reproducing apparatus including a synchronizing signal reproducing means for reproducing the image and outputting the synchronizing signal reproduced by the synchronizing signal reproducing means for monitoring.
[0038]
In this video recording / playback apparatus, the monitor output unit includes a synchronization signal / clock signal extracted / generated from an input video signal by an input / output unit and a synchronization signal / clock signal extracted / generated from a reference video signal by a timing signal generation unit. Selection means for selecting one of them, and synchronization signal reproduction means for reproducing the synchronization signal using the selected synchronization signal using the selected clock signal as an operation clock. The synchronization signal reproduced by the reproducing means is output for monitoring together with the video signal.
[0039]
When the video signal that has been pre-processed in the input / output unit is output for monitoring, if the synchronization signal / clock signal extracted / generated by the input / output unit is selected by the selection unit, Using the clock signal generated from the video signal itself as an operation clock, the synchronization signal is reproduced from the synchronization signal extracted from the video signal itself, and this synchronization signal is output for monitoring. By displaying the image on the monitor in synchronization with the synchronization signal, the image is not shifted downward due to the delay in the preprocessing.
[0040]
In addition, when an asynchronous video signal is input to the input / output unit and the pre-processing in the input / output unit is output to the input / output unit, the input / output unit also extracts and outputs the asynchronous video signal for monitoring. When the generated synchronization signal / clock signal is selected by the selection means, the synchronization signal reproduction means reproduces the synchronization signal from the synchronization signal extracted from the video signal itself, using the clock signal generated from the video signal itself as the operation clock. This synchronization signal is output for monitoring. By displaying the image on the monitor in synchronization with the synchronization signal, the synchronization flow as in the case of displaying the image in synchronization with the synchronization signal reproduced from the synchronization signal extracted from the reference video signal can be prevented.
[0041]
Therefore, for example, when the present invention is applied to an AV server, a delay in the preprocessing of the input / output port is caused even when an AV signal currently input to the input / output port is displayed on the monitor without providing a frame memory. When the input lock method is employed, the synchronization flow when displaying the AV signal currently being input to the input / output port on the monitor is eliminated.
[0042]
In this video recording / reproducing apparatus, as an example, the synchronizing signal reproducing means uses a synchronizing signal selected by the selecting means to generate a pulse indicating the start position of the color frame. A pulse generated by the pulse generator and a signal obtained by extracting the sync signal selected by the selector (the input video signal when the sync signal from the input / output unit is selected; Shift means for shifting until the phase coincides with the reference video signal when the synchronization signal from the signal generation unit is selected, and synchronization signal generation means for generating the synchronization signal from the pulse shifted by the shift means It is preferable to comprise.
[0043]
Next, as described in claim 3, the applicant of the present invention includes a recording / reproducing unit that records and reproduces data using a non-linear accessible recording medium, and a synchronization signal from an externally input video signal. At least one input / output unit for transferring the video signal to the recording / reproducing unit through preprocessing including extraction and clock signal generation, and outputting the video signal transferred from the recording / reproducing unit to the outside, and a reference supplied from the outside For monitoring by switching the timing signal generator that extracts the sync signal from the video signal and generates the clock signal, the video signal that has been preprocessed by the input / output unit, and the video signal that is output to the outside by the input / output unit In a method for outputting a monitor signal in a video recording / reproducing apparatus having a monitor output unit that outputs to a synchronization signal / clock signal and timing extracted / generated by an input / output unit The first step of selecting one of the synchronization signal and the clock signal extracted and generated by the signal generation unit, and the clock signal selected in the first step as the operation clock, and the synchronization selected in the first step A method including a second step of reproducing a synchronization signal using a signal and a third step of outputting the synchronization signal reproduced in the second step together with a video signal for monitoring is proposed.
[0044]
In this monitoring signal output method, the synchronization signal / clock signal extracted / generated from the input video signal by the input / output unit and the synchronization signal / clock signal extracted / generated from the reference video signal by the timing signal generation unit Is selected, the selected clock signal is used as an operation clock, the synchronization signal is reproduced using the selected synchronization signal, and the reproduced synchronization signal is output together with the video signal for monitoring.
[0045]
When the video signal that has been pre-processed in the input / output unit is output for monitoring, if the synchronization signal / clock signal extracted / generated in the input / output unit is selected in the first step, then in the second step, Using the clock signal generated from the video signal itself as an operation clock, the synchronization signal is reproduced from the synchronization signal extracted from the video signal itself. Since this synchronization signal is output for monitoring together with the video signal in the third step, by displaying the image on the monitor in synchronization with this synchronization signal, the screen is shifted downward due to the delay in the preprocessing. No image shift occurs.
[0046]
Furthermore, when the asynchronous video signal that is asynchronous with the reference video signal is input to the input / output unit, and the asynchronous video signal that has undergone the preprocessing in the input / output unit is output for monitoring, the display device according to claim 4 In addition, if the synchronization signal / clock signal extracted / generated at the input / output unit is selected in the first step, the video signal itself is used in the second step as a clock signal generated from the video signal itself. The synchronization signal is reproduced from the synchronization signal extracted from. Since this synchronization signal is output for monitoring together with the video signal in the third step, the image is displayed on the monitor in synchronization with this synchronization signal, so that it is synchronized with the synchronization signal reproduced from the synchronization signal extracted from the reference video signal. Thus, the synchronization flow as in the case of displaying an image does not appear.
[0047]
Therefore, for example, when the present invention is applied to an AV server, a delay in the preprocessing of the input / output port is caused even when an AV signal currently input to the input / output port is displayed on the monitor without providing a frame memory. When the input lock method is employed, the synchronization flow when displaying the AV signal currently being input to the input / output port on the monitor is eliminated.
[0048]
Also in this monitoring signal output method, in the second step, as an example, a pulse indicating the start position of the color frame is generated using the synchronization signal selected in the first step as described in claim 5. It is preferable to shift the pulse until the phase of the synchronization signal selected in the first step matches the phase of the extracted signal, and generate the synchronization signal from the shifted pulse.
[0049]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an example in which the present invention is applied to an AV server will be described.
FIG. 1 shows the overall configuration of an AV server to which the present invention is applied. This AV server has two input / output ports 1, 2, a monitor output unit 3, a timing management unit 4, a file management unit 5, and a recording / playback unit 6. The input / output ports 1 and 2 are connected to the recording / reproducing unit 6 via a down bus 7 and an up bus 8, respectively. The input / output ports 1 and 2 are connected to the file management unit 5 via the control bus 9.
[0050]
The input / output ports 1 and 2 have the same configuration, and the preprocessing circuit 10, the encoder 11 and the decoder 14 are mounted on the substrate S1, and the buffer memories 12 and 13 are mounted on another substrate S2. . Each substrate S1, S2 is also mounted with a CPU (not shown) for controlling each part on the substrate via a dual port memory.
[0051]
The monitor output unit 3 is configured by mounting a switch circuit 15, a synchronization signal reproducing circuit 16, and a CPU (not shown) for controlling them on a substrate S3. The configuration of the synchronization signal reproduction circuit 16 will be described later.
[0052]
The timing management unit 4 includes a timing signal generation circuit 17 and a control CPU (not shown) mounted on a substrate S4. The timing signal generation circuit 17 extracts the horizontal synchronization signal REFHD, the vertical synchronization signal REFVD, and the color frame synchronization signal REFCF from the reference video signal supplied to the AV server through the input terminal R from the outside, and from these synchronization signals, A clock signal REFCLK and a time slot signal TS for sequentially assigning time slots permitting use of the buses 7 and 8 to the input / output ports 1 and 2 are generated. The synchronization signals REFHD, REFVD, REFCF and the clock signal REFCLK are given to each part of the AV server, and the time slot signal TS is also given to the input / output ports 1 and 2.
[0053]
The file management unit 5 includes a file system 18 and a CPU (not shown) for controlling the file system 18 mounted on the substrate S5. The file system 18 shows information indicating the correspondence between the file name of the AV data currently recorded in the recording / reproducing unit 6 and the address of the recording area of the AV data, and the address of the current free area of the recording / reproducing unit 6. Create and manage information (file system information). To the input / output ports 1 and 2, the address of the recording area and the address of the empty area in the file system information are transmitted via the control bus 9.
[0054]
The recording / reproducing unit 6 includes a plurality of HDDs 19 for recording video data and two HDDs 20 for recording audio data, a disk array controller 21 for controlling the HDD 19, a disk array controller 22 for controlling the HDD 20, and a buffer memory. 23 and their control CPU (not shown) are mounted on a substrate S6. The recording / reproducing unit 6 is configured by using RAID technology, RAID-3 is adopted for video data, and RAID-1 is adopted for audio data.
[0055]
An AV signal input to the AV server from the outside through the input terminal I1 is sent to the input / output port 1, and an AV signal input from the outside to the AV server through the input terminal I2 is sent to the input / output port 2. In the input / output ports 1 and 2, the following preprocessing of (a) to (d) is first performed in order on the input AV signal by the preprocessing circuit 10 (however, in the input lock method, (b) ) Is omitted).
[0056]
(A) A process of extracting a horizontal synchronizing signal INHD, a vertical synchronizing signal INVD, and a color frame synchronizing signal INCF from the input AV signal, and generating a clock signal INCLK from these synchronizing signals.
(B) Time axis correction processing by the time base collector.
(C) Processing for reading the VITC code from the AV signal.
(D) A process of removing high-frequency components from the AV signal by a band filter.
[0057]
When the AV signal is a US standard NTSC signal, the process of adjusting the setup level to 0%, which is the same as the Japanese standard NTSC signal, is also performed as one of the pre-processes.
[0058]
The AV signal that has been preprocessed by the preprocessing circuit 10 is sent to the encoder 11. The AV signal and the synchronization signals INHD, INVD, INCF and clock signal INCLK extracted and generated by the preprocessing circuit 10 are also sent from the input / output port to the monitor output unit 3.
[0059]
In the encoder 11, the AV signal is compressed by a predetermined encoding method (for example, MPEG). AV data obtained by this compression is stored in the buffer memory 12, and then AV data to the empty area transmitted from the file management unit 5 is transferred to the input / output port by the time slot signal TS. Along with a command for instructing data recording, the data is transferred to the recording / reproducing unit 6 via the down bus 7.
[0060]
In the recording / reproducing unit 6, the transferred AV data is accumulated in the buffer memory 23, separated from the buffer memory 23 into video data and audio data, read out, and sent to the disk array controllers 21 and 22, respectively. Based on the recording instruction command, the disk array controller 21 divides the video data into blocks of a certain length and records them in a free area indicated by the command in a plurality of HDDs 19, and the HDDs 19 correspond to each other. Parity data that is the exclusive OR of the data blocks to be generated is generated and written in the free area indicated by the command in another HDD 19. Based on the recording instruction command, the disk array controller 22 writes the audio data in the empty areas indicated by the command in the two HDDs 20 respectively.
[0061]
On the other hand, when the input / output ports 1 and 2 transfer a command instructing reproduction of the AV data in the recording area transmitted from the file management unit 5 to the recording / reproducing unit 6 via the down bus 7, the disk array controller 21 Video data and parity data are read from the area indicated by the command in each HDD 19, and the video data is reproduced by unifying the video data and correcting the error using the parity data. Further, the disk array controller 22 reproduces audio data from an area indicated by the command in any one HDD 20 (or the remaining HDD 20 if there is a failure in the HDD 20).
[0062]
Video data and audio data reproduced by the disk array controllers 21 and 22 are stored in the buffer memory 23, respectively, and are converted from the buffer memory 23 to AV data in the time slot assigned to the input / output port by the time slot signal TS. The data is multiplexed and read out and transferred to the input / output port via the upstream bus 8.
[0063]
In the input / output ports 1 and 2, the AV data transferred from the recording / reproducing unit 6 is accumulated in the buffer memory 13, and then decoded (expanded) by the decoder 14 (after decoding, the decoder 14 performs various subsequent processes). Process). The AV signal obtained by this decoding is sent to the monitor output unit 3 and is output to the outside of the AV server through the data output terminal (terminal O1 at the input / output port 1 and terminal O2 at the input / output port 2).
[0064]
In this manner, the input / output ports 1 and 2 simultaneously input one channel of AV signals and one channel of AV signals simultaneously (that is, the entire AV server inputs two channels of AV signals). AV signals for two channels are simultaneously output), and the AV signals for a total of four channels are sent to the monitor output unit 3 and further extracted and generated from the input AV signals to the input / output ports 1 and 2 The synchronized signals INHD, INVD, INCF and the clock signal INCLK are also sent to the monitor output unit 3.
[0065]
In the monitor output unit 3, the AV signals for the four channels, the synchronization signals INHD, INVD, INCF, and the clock signal INCLK are input to the switch circuit 15. The operation key (not shown) of the AV server includes a key for designating one of the four channels of AV signals for monitor output. Only the AV signal designated by the operation of the key and the synchronization signals INHD, INVD, INCF and the clock signal INCLK sent from the input / output port which sent the AV signal are output. That is, for example, when the operator designates an AV signal being input or output at the input / output port 1, the sync signals INHD, INVD, INCF and the clock signal INCLK sent from the input / output port 1 are switched together with the AV signal. Output from the circuit 15.
[0066]
The AV signal, the synchronization signals INHD, INVD, INCF and the clock signal INCLK output from the switch circuit 15 are input to the synchronization signal reproduction circuit 16.
[0067]
FIG. 2 shows the configuration of the synchronization signal reproduction circuit 16. The synchronization signal reproduction circuit 16 includes a selector 31, a color frame start pulse generation circuit 32, a pulse shift circuit 33, and a synchronization signal generation circuit 34.
[0068]
The synchronization signals INHD, INVD, INCF and the clock signal INCLK input from the switch circuit 15 to the synchronization signal regeneration circuit 16 are input to the selector 31. The selector 31 also receives a horizontal synchronization signal REFHD, a vertical synchronization signal REFVD, a color frame synchronization signal REFCF, and a clock signal REFCLK given from the timing management unit 4.
[0069]
Among the operation keys of the AV server, whether the synchronization signal for monitor output is reproduced from the synchronization signals INHD, INVD, INCF, the clock signal INCLK, the synchronization signals REFHD, REFVD, the synchronization signal REFCF, and the clock signal REFCLK And a selector 31 selects a synchronization signal and a clock signal which are designated by operating the key. The synchronization signal selected by the selector 31 (represented as the horizontal synchronization signal HD, the vertical synchronization signal VD, and the color frame synchronization signal CF) is input to the color frame start pulse generation circuit 32 and the clock signal (CLK and CLK) selected by the selector 31 is selected. Is provided as an operation clock to the color frame start pulse generation circuit 32, the pulse shift circuit 33, and the synchronization signal generation circuit.
[0070]
The color frame start pulse generation circuit 32 generates a color frame start pulse SP indicating the start position of the color frame from the input horizontal synchronization signal HD, vertical synchronization signal VD, and color frame synchronization signal CF.
[0071]
In the pulse shift circuit 33, the color frame start pulse SP is shifted until the phase of the synchronizing signals HD, VD, CF selected by the selector 31 matches the extracted signal. That is, when the synchronizing signal INHD, INVD, INCF and the clock signal INCLK are selected by the selector 31, the color frame start pulse SP is sent to the AV signal input to the synchronizing signal reproduction circuit 16 in the input / output ports 1 and 2. Shift until the phase matches the phase of the input AV signal to the original input / output port. On the other hand, when the synchronization signal REFHD, REFVD, REFCF and the clock signal REFCLK are selected by the selector 31, the color frame start pulse SP is shifted until the phase coincides with the reference video signal.
[0072]
The synchronization signal generation circuit 34 generates a horizontal synchronization signal HD ′, a vertical synchronization signal VD ′, and a color frame synchronization signal CF ′ for monitoring from the shifted color frame start pulse SP.
[0073]
Therefore, when the synchronization signal INHD, INVD, INCF and the clock signal INCLK are selected by the selector 31, the clock signal INCLK is used as an operation clock to the input / output port of the source of the AV signal input to the synchronization signal reproduction circuit 16. Synchronization signals HD ′, VD ′, and CF ′ having the same phase as the input AV signal are reproduced. On the other hand, when the synchronization signal REFHD, REFVD, REFCF and the clock signal REFCLK are selected by the selector 31, the synchronization signals HD ′, VD ′, CF ′ having the same phase as the reference video signal are reproduced using the clock signal REFCLK as the operation clock. Is done.
[0074]
The synchronization signals HD ′, VD ′, and CF ′ are output from the synchronization signal regeneration circuit 16 together with the AV signal input to the synchronization signal regeneration circuit 16 and the clock signal CLK selected by the selector 31. As shown in FIG. 1, these signals output from the synchronization signal reproduction circuit 16 are output from the monitor output unit 3 to the outside of the AV server through the monitor output terminal M and sent to an external monitor (not shown). .
[0075]
Next, the output state of the monitoring signal in this AV server will be described separately for the reference lock method and the input lock method.
[0076]
[For reference lock method]
In the case of the reference lock method, not only the buffer memory 13 and the decoder 14 use the clock signal REFCLK as an operation clock, but also the processing from (b) in the preprocessing circuit 10 to reading from the buffer memory 12 are all clock signals. REFCLK is used as an operation clock. Then, the AV signal synchronized with the reference video signal is input and output from the input / output ports 1 and 2 in phase with the reference video signal, so that it is output from the AV signal input to the preprocessing circuit 10 or the decoder 14. The AV signal is in phase with the reference video signal. However, since the processing in the preprocessing circuit 10 requires several lines, the AV signal output from the preprocessing circuit 10 is delayed by several lines from the AV signal input to the preprocessing circuit 10. (I.e. out of phase with the reference video signal).
[0077]
In this case, when the operator of the AV server designates the AV signal currently being input to the input / output port 1 or 2 as the AV signal for monitor output, the sync signal for monitor output is set as the sync signal INHD, INVD, When reproduction from INCF and the clock signal INCLK is designated, the synchronization signal reproduction circuit 16 uses the clock signal INCLK created from the AV signal itself input to the input / output port as an operation clock, and extracts the synchronization signal from the AV signal itself. Synchronization signals HD ′, VD ′, and CF ′ are reproduced from INHD, INVD, and INCF. The synchronization signals HD ′, VD ′, and CF ′ are sent from the AV server to the monitor together with the AV signal and the clock signal INCLK.
[0078]
By displaying an image on a monitor in synchronization with the synchronization signals HD ′, VD ′, and CF ′, an image for several lines in the downward direction of the screen caused by a delay in the preprocessing circuit 10 as in the prior art. No shift occurs.
[0079]
As described above, in this AV server, when displaying the AV signal currently being input to the input / output ports 1 and 2 on the monitor, the image caused by the delay in the preprocessing circuit 10 is provided without providing a frame memory. This shift is eliminated.
[0080]
However, the synchronization signal for monitor output is not always reproduced from the synchronization signals REFHD, REFVD, REFCF and the clock signal REFCLK. Therefore, when switching the channel of the AV signal displayed on the monitor, the image is caused by the discontinuity of synchronization. Disturbance can occur.
[0081]
If the operator of the AV server specifies that the synchronization signal for monitor output is always reproduced from the synchronization signals REFHD, REFVD, REFCF and the clock signal REFCLK, the AV signal currently being input to the input / output ports 1 and 2 When the image is displayed on the monitor, the image is not disturbed due to the discontinuity of synchronization, instead of shifting the image by several lines in the lower direction of the screen.
[0082]
As described above, in this AV server, in the case of the reference lock method, when the channel of the AV signal to be displayed on the monitor is switched, the current input / output ports 1 and 2 are replaced instead of the image disturbance caused by the discontinuity of synchronization. This eliminates the image shift in the downward direction when the AV signal being input is displayed on the monitor without providing a frame memory, or monitors the AV signal currently being input to the input / output port 1 or 2 In order to prevent the image from being disturbed due to the discontinuity of synchronization when switching the channel of the AV signal displayed on the monitor instead of causing the image to shift downward in the screen when displayed on the screen. The operator can decide freely.
[0083]
[In case of input lock method]
When the input lock method is employed, the time base correction process by the time base collector in (b) described above in the preprocessing circuit 10 is omitted, and the buffer memory is changed from the processing in (c) in the preprocessing circuit 10. Until the data is written to 12, the clock signal INCLK is used as the operation clock (that is, in synchronization with the input AV signal), and reading from the buffer memory 12 is performed using the clock signal REFCLK as the operation clock (that is, in synchronization with the reference video signal). As a result, the buffer memory 12 is used as a frame synchronizer, and an AV signal asynchronous with the reference video signal, such as an AV signal using SNG or Ethernet, is directly input to the input / output ports 1 and 2. Thus, the recording / reproducing unit 6 can record the information.
[0084]
However, when an AV signal asynchronous with the reference video signal is directly input to the input / output ports 1 and 2, the AV signal asynchronous with the reference video signal is also sent from the preprocessing circuit 10 to the monitor output unit 3. It will be.
[0085]
In this case, when the operator of the AV server designates the AV signal currently being input to the input / output port 1 or 2 as the AV signal for monitor output, the selector 31 of the synchronization signal reproduction circuit 16 of the monitor output unit 3. Is selected to select the horizontal synchronizing signal INHD, the vertical synchronizing signal INVD, the color frame synchronizing signal INCF and the clock signal INCLK, the synchronizing signal reproducing circuit 16 generates a clock signal generated from the AV signal itself input to the input / output port. Using INCLK as an operation clock, the synchronization signals HD ′, VD ′, and CF ′ are reproduced from the synchronization signals INHD, INVD, and INCF extracted from the AV signal itself. The synchronization signals HD ′, VD ′, and CF ′ are sent from the AV server to the monitor together with the AV signal and the clock signal INCLK.
[0086]
By displaying an image on the monitor in synchronization with the synchronization signals HD ′, VD ′, and CF ′, the synchronization is performed when the image is displayed in synchronization with the synchronization signal reproduced from the synchronization signal extracted from the reference video signal. The flow will not appear.
[0087]
As described above, in this AV server, even if the input lock method is adopted, the synchronization flow does not appear when the AV signal currently being input to the input / output ports 1 and 2 is displayed on the monitor.
[0088]
In the above example, the present invention is applied to an AV server having two input / output ports. However, the present invention may be applied to an AV server having one or more input / output ports.
[0089]
In the above example, the present invention is applied to an AV server having one monitor output unit. However, each of the plurality of input / output ports has an individual monitor output unit (by the number of input / output ports). The present invention may also be applied to an AV server.
[0090]
In the above example, the present invention is applied to an AV server having an input / output port in which an input port and an output port are integrated. However, the present invention is also applied to an AV server having an input port and an output port as separate bodies. May be applied.
[0091]
In the above example, the present invention is applied to the AV server that records the AV data on the HDD using the RAID technology. However, the AV server that records the AV data on the HDD without adopting the RAID technology, or the HD The present invention may also be applied to an AV server that records AV data on a non-linear accessible recording medium (for example, a semiconductor memory or an optical disk).
[0092]
Further, the present invention may be applied to an AV server having a function of editing AV data in addition to a function of recording / reproducing AV data.
Further, the present invention may be applied to a video recording / reproducing apparatus other than the AV server, which simultaneously inputs / outputs video signals through a plurality of channels and outputs the currently input / output video signals for monitoring.
Further, the present invention is not limited to the above examples, and it is needless to say that various other configurations can be taken without departing from the gist of the present invention.
[0093]
【The invention's effect】
As described above, according to the video recording / playback apparatus and the monitor signal output method according to the present invention, the video signal that has been preprocessed by the input / output unit is displayed on the monitor when the video signal is output for monitoring. There is an effect that the image is not shifted downward due to a delay in the preprocessing of the input / output unit.
In addition, when a video signal that is asynchronous with the reference video signal is input to the input / output unit, and the asynchronous video signal that has undergone the preprocessing in the input / output unit is output for monitoring, a synchronous flow does not appear on the monitor. An effect is obtained.
[0094]
Therefore, if the present invention is applied to, for example, an AV server, a delay in the preprocessing of the input / output port is caused without providing a frame memory when displaying the AV signal currently input to the input / output port on the monitor. When the input lock method is adopted, the synchronization flow when the AV signal currently being input to the input / output port is displayed on the monitor is eliminated.
[Brief description of the drawings]
FIG. 1 is a block diagram showing an example of the overall configuration of an AV server to which the present invention is applied.
FIG. 2 is a block diagram showing a configuration example of a synchronization signal reproduction circuit of FIG.
FIG. 3 is a diagram illustrating how a monitor signal is output in a conventional AV server.
[Explanation of symbols]
1, 2 input / output ports, 3 monitor output section, 4 timing management section, 5 file management section, 6 recording / playback section, 7 downstream bus, 8 upstream bus, 9 control bus, 10 preprocessing circuit, 11 encoder, 12, 13, 23 Buffer memory, 14 Decoder, 15 Switch circuit, 16 Synchronization signal reproduction circuit, 17 Timing signal generation circuit, 18 File system, 19, 20 HDD, 21, 22 Disk array controller, 31 Selector, 32 Color frame start pulse generation Circuit, 33 pulse shift circuit, 34 synchronization signal generation circuit, S1-S6 substrate

Claims (5)

A recording / reproducing unit for recording and reproducing data using a non-linear accessible recording medium;
The video signal is transferred to the recording / playback unit through preprocessing including extraction of a synchronization signal from an externally input video signal and generation of a clock signal, and the video signal transferred from the recording / playback unit is output to the outside. At least one input / output unit that
A timing signal generator for extracting a synchronization signal and generating a clock signal from a reference video signal supplied from the outside;
A monitor output unit for switching the video signal that has been subjected to the pre-processing in the input / output unit and a video signal output to the outside by the input / output unit to output for monitoring;
The monitor output unit
Selection means for selecting one of the synchronization signal / clock signal extracted / generated by the input / output unit and the synchronization signal / clock signal extracted / generated by the timing signal generation unit;
A synchronizing signal reproducing means for reproducing the synchronizing signal using the synchronizing signal selected by the selecting means using the clock signal selected by the selecting means as an operation clock, and the synchronizing signal reproduced by the synchronizing signal reproducing means A video recording / reproducing apparatus for outputting to a monitor. The video recording / reproducing apparatus according to claim 1,
The synchronization signal reproducing means includes
Pulse generation means for generating a pulse indicating the start position of the color frame using the synchronization signal selected by the selection means;
Shift means for shifting the pulse generated by the pulse generation means until the phase of the synchronization signal selected by the selection means matches the extracted signal;
A video recording / reproducing apparatus comprising: synchronization signal generating means for generating a synchronization signal from the pulses shifted by the shift means. A recording / reproducing unit for recording and reproducing data using a non-linear accessible recording medium;
The video signal is transferred to the recording / playback unit through preprocessing including extraction of a synchronization signal from an externally input video signal and generation of a clock signal, and the video signal transferred from the recording / playback unit is output to the outside. At least one input / output unit that
A timing signal generator for extracting a synchronization signal and generating a clock signal from a reference video signal supplied from the outside;
A monitor signal in a video recording / reproducing apparatus having a video output signal that has been subjected to the preprocessing in the input / output unit and a video output signal that is output to the outside by the input / output unit and that is output for monitoring In the output method of
A first step of selecting one of the synchronization signal / clock signal extracted / generated by the input / output unit and the synchronization signal / clock signal extracted / generated by the timing signal generation unit;
A second step of regenerating the synchronization signal using the clock signal selected in the first step as an operation clock and using the synchronization signal selected in the first step;
And a third step of outputting the synchronizing signal reproduced in the second step together with the video signal for monitoring. The method for outputting a monitoring signal according to claim 3,
When the video signal that is asynchronous with the reference video signal is input to the input / output unit, and the video signal that has been preprocessed in the input / output unit is output for monitoring, in the first step, the input / output unit A method for outputting a monitor signal, wherein the synchronization signal / clock signal extracted and generated in step (1) is selected. 5. The method for outputting a monitoring signal according to claim 3, wherein in the second step, a pulse indicating a start position of a color frame is generated using the synchronization signal selected in the first step, and the first step is performed. A method for outputting a monitor signal, wherein the pulse is shifted until the phase of the synchronization signal selected in the step matches that of the extracted signal, and the synchronization signal is generated from the shifted pulse.

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