JP5863259B2 - Video server system - Google Patents

Description

  The present invention relates to a video server system in which program material is recorded on a video server in a video file data format, reproduced, decoded and on-air.

In HDTV (High Definition TeleVision) broadcasting business, a non-linear bank system equipped with a video server has been used in the past, and programs such as VTR (Video Tape Recorder) and broadcast materials such as CMs are stored on the video server. After recording (hereinafter abbreviated as “recording”), playback, decoding, on-air broadcasting is performed (see Patent Document 1). Video server input / output signals are converted from uncompressed video signals into a compressed video file data format, which is now called a tapeless system.
That is, in the tapeless system, the video signal of the broadcast material is compressed (encoded) into a moving image by MPEG (Moving Picture Experts Group) or the like, and recorded and reproduced as video file data.

FIG. 3 shows a schematic diagram of a data acquisition path during failure recovery when the material server 1 of the conventional network type video server system fails.
FIG. 3 shows a fully redundant redundant system, which has the same hardware configuration for both the first and second systems. The main hardware of a single video server system is a material (video file data registration) server that captures and stores video file data of material from an input source such as an editing machine or VTR, and the latest (for example, several days) transmission material The video file data is copied and transferred from the material server, stored and sent out by the built-in decoder and sent out by the built-in decoder, the sending server that receives the control signal from the host system and controls the decoder built in the sending server, etc. Has been. The material server uses an HDD (Hard Disk Drive) because a large capacity specification is required, and the sending server uses an SSD (Solid State Drive) because the disk stability is required.

  The material server has a function of storing the delivered material video and the material video recorded on the line or the like until the file is used for broadcasting or transferred to the archive system.

Archive systems often use data tape media that is inexpensive and large in capacity but takes a long time to store and play.
For this reason, video file data may exist only in the material server. Therefore, the material server is duplicated and the disk is also configured in RAID, so that operation availability is ensured and video file data is not lost. However, since there is a possibility that the video file data may be physically lost, a recovery means at the time of failure is necessary.
Even if the material server is duplicated and protects the material data as a RAID configuration, if a hardware failure occurs, the amount of video file data to be recovered is large. Performing the process in which the two are identical will stop the broadcast.

  Specifically, as shown in FIG. 2 of the schematic diagram of the video file data acquisition path at the time of failure of the material server 1 of the conventional video server system, the material recording is performed by the material server 2 when the material server 1 fails. Only material is recorded. Since the broadcast video file data exists only in the material server 2, the material acquisition destination of each transmission server is all from the material server 2, and it is not possible to stop the material server 2 and restore the material server 1.

  As shown in FIG. 3 of the schematic diagram of the video file data acquisition path during failure recovery in the case of failure of the material server 1 of the conventional video server system, when the material server 1 recovers due to failure, synchronization was performed from the material server 2 In this case, the difference between the material servers 1 and 2 is transferred to the material server 1, but if it takes time to synchronize, the video file data to be newly recorded is the new difference video file data if only the material server 2 is accumulated. Thus, the synchronization process is required again after the synchronization is completed, and the synchronization process is not completed.

Quantitatively, since HDTV data includes sound and about 100 Mbps, the file size when a one-hour program is recorded is as follows.
100 (Mbps) * 60 (minutes) × 60 (seconds) = 360 Gbit = 45 Gbyte
Assuming that a program for one month can be stored in the material server, 360 × 24 (hours) × 31 days = 268 Tbit = 34 Tbytes
If this data is transferred over a 1 Gbps network (assuming an execution speed of 600 Mbps), it takes about 5 days.

In other words, while recording the video file data in the material server 2 at the time of recovery, in the method in which the sending server is to get the image file data broadcast from the material server 2, the synchronization of the data material that is new recording, it is difficult .

JP 2009-117989 A

  The present invention efficiently restores lost video file data while operating even if a failure occurs on the active side or backup side in the active and backup side material servers that store video file data used in broadcasting. The purpose is to do it automatically.

  In order to achieve the above object, the present invention provides a material server that records a video file for broadcasting, a transmission server that decodes the video file data recorded and reproduced and outputs the video file data as a video signal In a video server system that is completely duplicated on the active side and the backup side, and has a control device that controls recording and playback of the material server and recording and output of the sending server, and synchronizes the material servers When one of the material servers fails, when one of the material servers is restored, excess of the material video file data between the one material server and the other material server of the material server is lost. List the shortage, start recording the material video file data also in the one of the material server, the one sending server and the other sending server, Video file data is obtained from the other material server, and the material video file data is transferred from the other material server to the one material server via the synchronization connection in order from the latest recording time of the listed differential materials. The other material server deletes from the video file data with the oldest recording date according to the storage deadline, and the list of difference material video file data is copied from the other material server to the one material server. When the list of differential material video file data that has not been copied to the one material server is no longer present in the other material server, the synchronization operation is terminated. It is a control method.

  Further, in the video server system, when one of the material servers fails, video file data is acquired from the one sending server to the one material server when the one material server is restored. The video server system control method is characterized by performing the video server system control method described above.

  In addition, the video server with a built-in decoder that decodes the video file data recorded and edited by recording and editing the video file data for broadcasting and outputs it as a video signal is completely duplicated on the active side and the backup side. A video server system having a control device that controls recording, playback, recording, and output of the video server, connecting the video servers for synchronization, and when one of the video servers becomes an obstacle, When one of the video servers is restored, a list of excesses or deficiencies in the material video file data of the one video server and the other of the video servers is listed, and recording of the material video file data is also started in the one video server. The built-in decoder of the one video server and the built-in decoder of the other video server The video file data is acquired from the server, and the video file data is copied from the other video server to the one video server via the synchronization connection in order from the newest recording time of the listed differential materials. The other video server deletes from the video file data with the oldest recording date according to the storage deadline, and the list of difference material video file data has been copied from the other video server to the one video server or A control method for a video server system, wherein the synchronization operation is terminated when the listed differential material video file data that has not been copied to the one video server does not exist in the other video server. is there.

  As described above, according to the present invention, even if a failure occurs on the active side or the backup side in the material server on the active side and the backup side that stores the video file data used in broadcasting, it is lost while operating. The recovered video file data can be efficiently performed.

The block diagram which shows the structure of the video server system of one Example of this invention. Schematic diagram of video file data acquisition path when material server 1 of the conventional video server system fails Schematic diagram of video file data acquisition path during failure recovery in case of failure of material server 1 of conventional video server system Schematic diagram of a video file data acquisition path during failure recovery when the material server 1 of the video server system of one embodiment of the present invention fails Schematic diagram of transfer of video file data during failure recovery when material server 1 of the video server system of one embodiment of the present invention fails

First, FIG. 1 shows an example of a block diagram of a video server system in which material servers are duplicated and HDDs are also configured in RAID. Although it is assumed that an archive system is connected to this system, it is not described because it is unnecessary in the description of the present invention.
In FIG. 1, 1 is a material (video) line, 2 is a material (video) VTR, 3 is a material (video) file player, 4 is a control signal received from the host system and controls a decoder built in the transmission server. Controllers 5 and 6 are material (video file data registration) servers for capturing and storing material video file data, 7 and 8 are material server HDDs, and 9 and 10 have built-in SSD and decoder. This is a transmission server that copies and accumulates video file data of a transmission material for a few days (for example, several days) from the material server, and stores the video decoded by a built-in decoder. The material servers 7 and 8 are connected for synchronization, for example, connected by a synchronization LAN.

In consideration of availability, the material server has two units, and the line data, the VTR, and the material video file data are simultaneously recorded independently by the material server. Thereby, even if one of them stops, it is possible to continuously record the material video file data. The material server can also store the input video as file data.
The sending server acquires and stores the material video file data from the material server in accordance with the acquisition destination instruction for the material video file data used in the broadcast of the controller.

  Next, FIG. 2 is a schematic diagram of the video file data acquisition path when the material server 1 of the conventional video server system fails, and the video file data acquisition path during recovery from the failure when the material server 1 of the conventional video server system fails. The present invention will be described based on a comparison between FIG. 3 of the schematic diagram and FIG. 4 of the schematic diagram of the video file data acquisition path during failure recovery when the material server 1 of the video server system according to one embodiment of the present invention fails.

The operation of the present invention is as follows.
(1) VTR, line data, and material video file data are recorded and stored by two material servers. Thereby, the material servers 1 and 2 hold the same video file data.
(2) Since line data is recorded at a predetermined time, material is recorded by timer recording.
(3) The material video file data stored in the material server is transferred to the sending server at a fixed time or in accordance with an acquisition request from the sending server.
(4) The transmission server broadcasts the acquired material video file data according to the program distribution time.
The transmission server acquires the video file data from the material server instructed by the upper device.

In this configuration, when one material server becomes a hardware failure and the video file data is lost, the video file data must be restored.
Since it takes 5 days (refer to the calculated value) to recover the video file data that has simply disappeared, it is not possible to stop broadcasting or stop recording during this time.
If the material server 1 becomes a failure, the material server 2 is operating normally, and all the material video file data exists in the material server 2.

  As shown in FIG. 2 of the schematic diagram of the data acquisition path at the time of failure of the material server 1 of the conventional video server system, when the material server 1 fails, the broadcast video file data exists only in the material server 2, The material acquisition destination of each sending server is all from the material server 2, and the material server 2 cannot be stopped and the material server 1 can be restored.

As shown in FIG. 3 of the schematic diagram of the video file data acquisition path during failure recovery at the time of failure of the material server 1 in the conventional video server system, the material server 2 records the video file data at the time of recovery. delivery server retrieves the data (or received), the method of performing broadcasting, synchronization source video file data to be newly From, becomes difficult.

Therefore, as shown in FIG. 5 of the schematic diagram of the video file data transfer during the failure recovery when the material server 1 of the video server system according to the embodiment of the present invention fails, the restoration is performed by the following method.
(1) When the material server 1 is restored, the excess and deficiency of the materials of the material servers 1 and 2 are listed.
(2) (1) Recording starts at the material server 1 from the point of completion.
Since there is no video file data in the material server, the transmission server obtains the video file data from the material server 2 and broadcasts as before.
(3) The material server 1 performs material synchronization. For synchronization, a synchronization LAN is used, and materials are acquired from the material server 2 in order from the latest recording time of the difference material acquired in (1).
(4) The material server 2 deletes the video file data with the oldest recording date in accordance with the accumulation time limit.
(5) In the material server 1, video file data that has been deleted from the material server 2 when the video file data included in the difference list but is no longer necessary from the material server is intentionally deleted, etc. is skipped. Then transfer the next material.
(6) When there is no video file data to be transferred by the material server 1, the synchronization ends.

  Synchronization LAN, synchronize while recording. In this system, since the recording date is deleted from the oldest, synchronization is performed without transferring unnecessary files by synchronizing from the new file of the difference. Can be taken.

Furthermore, it is possible to make the video file data between the material servers identical after restoring the video file data from the transmission server to the material server.
Description of the same part as Example 1 and Example 2 is abbreviate | omitted, and it demonstrates centering on a different part.

The configuration of FIG. 1 of the block diagram showing the configuration of the video server system of the first embodiment, the second embodiment, and the first embodiment of the present invention is the same.
The video file data of the latest transmission material stored in the transmission server (for example, several days) is transferred to the material server, and then the operation of the first embodiment is performed, and the video file data is the same in a shorter time than the first embodiment alone. Turn into.

It is also possible to make the video file data identical between the integrated servers in which the material server and the transmission server are integrated.
Description of the same part as Example 1 and Example 2 is abbreviate | omitted, and it demonstrates centering on a different part.

In the third embodiment, the material server 1 and the sending server 1 are integrated, and the material server 2 and the sending server 2 are integrated in FIG. 1 of the block diagram showing the configuration of the video server system of the first embodiment of the present invention. Since the material server and the transmission server are integrated, the built-in decoder of one video server and the built-in decoder of the other video server that have recovered from failure are different in that video file data is acquired from the other video server.
Other operations of the third embodiment are the same as those of the first embodiment.

In other words, a video server with a built-in decoder that decodes the video file data recorded and edited and records the video file data that has been recorded for broadcasting and outputs it as a video signal is completely duplicated on the active side and the backup side. A video server system having a control device for controlling recording, reproduction, recording and output of the video server, connecting the video servers for synchronization, and one of the video servers becomes an obstacle, Suppose the video server is restored.
At that time, the excess and deficiency of the material video file data of the one video server and the other of the video servers is listed, and the recording of the material video file data is also started in the one video server.
The built-in decoder of the one video server and the built-in decoder of the other video server obtain video file data from the other video server.
The material video file data is copied from the other video server to the one video server via the synchronization connection in order from the latest recording time of the differential material listed.
In the other video server, deletion is performed from the video file data whose recording date is old according to the storage deadline, and the listed differential material video file data has been copied from the other video server to the one video server, or When the listed differential material video file data that has not been copied to the one video server does not exist in the other video server, the synchronization operation is terminated.

1: material (video) line, 2: material (video) VTR, 3: material (video) file player, 4: controller,
5, 6: Material server, 7, 8: Material server HDD,
9, 10: Sending server with built-in SSD and decoder,

Claims (3)

Fully duplicated system 1 and system 2 for the material server that records video files for broadcasting and the transmission server that decodes the video file data recorded and played back and outputs it as video signals In a video server system having
A control device for controlling the recording and output of recording and reproducing with the delivery server of the material server, and a synchronization LAN for connecting the material between servers for synchronization,
If the said material server of one of the system failure has become necessary restoration of the video file data occurs, at the time the該片how the system material server of is restored,該片how the system material server and the other side of the system of to list the difference of depression image file data of the material server, starts the recording of even movies image file data in the material server of the one of the system, recording time before the Symbol list of the difference between the video file data is in order from the new one , the other via the synchronous LAN from the material server system copies the movies image file data into the system material server of the one,
And in the material server of the other system, even during the restoration of the image file data, and delete from the old image file data of the recording date in accordance with the accumulation period,
Or differential image file data described above listed finishes copying from said other material server to the system material server of the one or differential Film image file data described above listed not copied to the material server of the one is the When it no longer exists in the other material server, the synchronization operation is terminated .
During restoration of the video file data, the video server system in which the transmission server of the one system and the transmission server of the other system acquire and decode the video file data from the material server of the other system Mu . 2. The video server system according to claim 1, wherein when one of the material servers of the one system has failed, when the one of the material servers is restored, the one of the transmission servers in the past has been restored. after obtaining the image file data from the system material server of being copied transfer storage, the video server system which is characterized in that the synchronization with the other system material servers. Record a video file for broadcasting, record the edited video file data, decode the reproduced video file data and output it as a video signal. In the video server system
A control device for controlling recording , recording, reproduction and output of the video server; and a synchronization LAN for connecting the video servers for synchronization;
When one of the video servers fails, when the one video server is restored, the difference between the video file data of the one video server and the other video server is listed, and then the one of the video servers is listed. The video server also starts recording video file data, and in order from the latest recording time of the listed differential video file data, the video file is transferred from the other video server to the one video server via the synchronization LAN. Copy the data,
In the other video server, even during the restoration of the video file data, the oldest video file data is deleted according to the storage deadline,
The listed differential video file data has been copied from the other video server to the one video server, or the listed differential video file data not copied to the one video server is the other video server. When it no longer exists on the server, the synchronization operation is terminated.
Each of the decoders incorporated in the one video server and the other video server acquires and decodes the video file data from the other video server during the restoration of the video file data. Server system.