JP4026189B2 - Multi-channel broadcasting system - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a multi-channel broadcasting system, and more particularly to a multi-channel broadcasting system that can flexibly cope with a device failure and system down and can reduce the overall cost.
[0002]
[Prior art]
In recent years, multi-channel broadcasting using satellites or communication cables has attracted attention. This multi-channel broadcasting is different from conventional single-channel broadcasting using terrestrial waves, and different broadcasting is simultaneously performed from one broadcasting station to many channels. Therefore, the broadcast station must send a program and a commercial message inserted between the programs and advertisements (hereinafter referred to as CMs for the sake of simplicity) to a large number of channels.
[0003]
In order to send materials such as different programs and commercials to a large number of channels, for example, a broadcasting system in which a plurality of broadcasting transmission system units capable of supporting several channels is arranged is used. This broadcast transmission system unit has a video server that can temporarily store and transmit material data such as CMs and a video cart machine that reproduces programs, and material data and programs according to a playlist given to each transmission channel. Is sent out. A transmission control apparatus that controls these video servers, video cart machines, and the like is composed of, for example, a personal computer and the like, and holds software for transmission, a database necessary for transmission, and the like.
[0004]
In a broadcasting system, the most important thing is to send a material such as a program or CM to each transmission channel without interruption according to the transmission schedule. For that purpose, it is necessary to increase the reliability of the broadcast transmission system unit constituting the broadcast system and to suppress the occurrence of a failure such as a system down. Alternatively, it is necessary to construct a system that can recover immediately even if a failure occurs.
[0005]
[Problems to be solved by the invention]
However, the cause of the failure includes a failure of the hardware itself such as a hard disk crash and a failure due to a bug in the software. In order to make the failure occurrence rate to zero as much as possible, it is very Expensive hardware and software must be built. As a means for avoiding this, there is a method of duplicating the system by providing spare devices in all the elements constituting the system. However, this method also increases the cost.
[0006]
Therefore, the purpose of the present invention is to Broadcast An object of the present invention is to provide a multi-channel broadcasting system capable of minimizing interruptions and reducing costs.
[0007]
Furthermore, an object of the present invention is to provide a simple multi-channel broadcasting system that can flexibly cope with the occurrence of a failure with a minimum cost increase.
[0008]
It is another object of the present invention to provide a multi-channel broadcasting system that can automatically detect a device failure and automatically cope with it.
[0009]
[Means for Solving the Problems]
The multi-channel broadcasting system of the present invention has at least m + 1 transmission control devices for controlling the transmission controlled devices of m (m is a plurality) units that reproduce, store or transmit the material data transmitted to the transmission channel. A unit is provided. A matrix switcher that can connect the sending control device and the sending controlled device in any combination is provided between them. During normal control, m units of transmission controlled devices and m units of transmission control devices that respectively control them are connected via a matrix switcher. When the sending control device under control fails, the matrix switcher is switched, and the backup sending control device is connected to the sending controlled device controlled by the failed sending control device.
[0010]
The backup sending control unit stores the control software and control database stored in the main sending control unit, and the control database is updated together with the main unit so that switching can be performed immediately when a failure occurs. Is done.
[0011]
That is, the present invention provides a multi-channel broadcasting system that transmits material data to a plurality of transmission channels.
A transmission controlled device of m (m is a plurality) units for reproducing, storing or transmitting the material data transmitted to the transmission channel;
At least m + 1 units of transmission control devices associated with the transmission controlled devices, controlling the reproduction, storage or transmission of the corresponding transmission controlled devices and interconnected by a network;
A matrix switcher that enables arbitrary connection between the sending control device and the sending controlled device;
Among the transmission control devices, the backup transmission control device stores control software and a control database stored in the main transmission control device.
[0012]
Furthermore, in another invention, the operation state of the transmission control device is monitored, and when a failure is detected, the matrix switcher is switched, and the backup transmission control device and the transmission control device in which the failure occurs are controlled. It further has an operation management device for performing connection with the transmission controlled device. As a result, it is possible to automatically detect a failure and switch to a backup transmission control device.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings. However, the technical scope of the present invention is not limited to the embodiment.
[0014]
FIG. 1 is a diagram showing a basic configuration of a broadcast transmission system unit used in an embodiment of the present invention. In this example, the broadcast can be transmitted to three transmission channels. The broadcast transmission system 1 includes a transmission control device 10 constituted by a personal computer, an interface 20, a CM, and a transmission controlled device 30 that transmits program materials.
[0015]
For example, a material of a relatively short time such as a CM is copied to the video server 34 and transmitted according to a playlist in which a broadcast schedule is described. The video server 34 has, for example, a file system in which a plurality of hard disks have a redundant configuration as its basic configuration. Conventionally, video tapes that have been used as means for recording and reproducing video and audio signals are difficult to access and reproduce recorded material randomly in a short time. Also, it takes a relatively long time to record the material. Therefore, it is a very complicated process to record a material having a great number of types in a short time, such as a material such as CM, on a video tape and send it according to a playlist.
[0016]
Therefore, in a multi-channel broadcasting system, it has been proposed to use a video server using a hard disk or the like that can be recorded in a short time and can be randomly accessed in a short time. As shown in FIG. 1, a video tape 31 provided by a producer such as a CM is reproduced by a video reproduction device 32, and the reproduced video and audio signals are compressed by a compression device 33 and recorded in a video server 34. Record in the medium. By using the compression technique, the time for recording to and reading from the recording medium is shortened. The material data such as CM recorded in the video server 34 is decoded by the decoder 35 in response to a transmission command from the transmission control device 10 and transmitted to the corresponding transmission channel.
[0017]
Alternatively, the material data such as CM may be supplied from the removable disk 12 and transferred from the transmission control device 10 to the video server 34 when it is sufficiently compressed or has a sufficient capacity. In addition, material management data, which will be described later, is given by the removable disk 12 in addition to manual input or download from a host computer.
[0018]
On the other hand, relatively long-term material data such as programs are rarely repeatedly transmitted unlike CMs and the like. Accordingly, each time the program is sent, the video tape 38 on which the program is recorded is played back by the video playback device 37 such as a video cart machine and sent to the corresponding sending channel. This reproduction and transmission control is also performed by a command from the transmission control device 10. However, even relatively long-time material data such as a program may be repeatedly recorded in the video server 34 and transmitted in the same manner as a CM or the like.
[0019]
The multiplex switcher 36 is a switching device for supplying the material data from the decoder 35 and the material data from the video reproduction device 37 to the corresponding transmission channels.
[0020]
The transmission control device 10 is connected to a network 10 connected to a host control computer, another transmission control device, or the like, and records a material such as a CM on the video server 34 or a material from the video playback device 37 or the video server 34. Controls when sending data to the sending channel. In general, a play list describing a material transmission schedule is created for each transmission channel. This playlist is created by the operator on the transmission control apparatus 10 or is given from a host control computer (not shown). Then, a filing list is created for materials that have an early transmission time on the playlist and are not recorded in the video server 34. This filing list is also created by the operator on the sending control device 10 or given from a higher-level control computer (not shown).
[0021]
Therefore, a database necessary for transmission control such as a filing list and a playlist is stored in the recording area 11 of the transmission control device 10. Naturally, the transmission control apparatus 10 includes system software such as operation software and application software for recording, reproduction, and transmission described above.
[0022]
The transmission control device 10 constituted by a personal computer or the like controls the above-mentioned material data recording, reproduction, transmission, and the like by giving corresponding commands to the interface 20. In response to these commands, the interface 20 gives each device a control signal corresponding to each device in the transmission controlled apparatus 30. In that sense, this interface is an intelligent device controller IDS ( Intelligent Device Controller). The sending control device 10 may be configured by being distributed by a plurality of personal computers.
[0023]
Since the above-mentioned broadcast transmission system 1 can support only a few channels, in order to support a large number of transmission channels, the broadcast transmission system needs to be unitized and provided with a plurality of units. However, when a failure occurs in this broadcast transmission system, it is necessary to respond without interrupting the transmission of material data.
[0024]
What should be noted here is that the video server 34 is configured by a file system having redundancy as described above. That is, it is a RAID (Redundancy Array of Inexpensive Disk) structure in which standardized inexpensive hard disks are arranged in an array with redundancy. Therefore, it has the property that it can flexibly cope with failures such as hardware crashes. In other words, video / audio material data is more resistant to failure.
[0025]
On the other hand, the transmission control device 10 composed of a general-purpose personal computer or the like is an inexpensive device, but compared with the occurrence of a failure such as a system hang-up or a hardware crash that records a control database. Vulnerable.
[0026]
Therefore, in the embodiment of the present invention, the control system of the broadcasting system is configured to be robust against failure by providing redundancy to the transmission control apparatus 10 which is inexpensive but vulnerable.
[0027]
FIG. 2 is a schematic configuration diagram of the first embodiment of the present invention. In this example, 301 to 30 m and m units are provided as the controlled apparatus 30 shown in FIG. Each of the transmission controlled devices 301 to 30m supports three transmission channels, and enables 3m channel broadcasting as a whole. In this example, m + 1 units are provided as the sending control devices 10 for controlling these sending controlled devices 301 to 30m. The sending control device controls the recording, reproduction, and sending of the material data in correspondence with the sending controlled device 30 on a one-to-one basis. Therefore, in this example, the transmission control device 10 is configured to be one unit more than necessary. By providing this redundancy, when the transmission control device 10 fails, a backup transmission control device can be used instead of the failed device. Therefore, it is possible to flexibly cope with a failure. Note that the safety can be further improved by increasing the number of the transmission control devices 10 by more than m.
[0028]
In principle, the transmission control devices 101 to 10m + 1 configured with redundancy can control any of the transmission controlled devices 301 to 30m. Therefore, the matrix switcher 40 capable of connecting both in an arbitrary combination is provided between the interfaces 201 to 20m of the respective transmission controlled devices 301 to 30m and the transmission control devices 101 to 10m + 1. Then, instead of the failed transmission control device, the backup transmission control device continues to control the corresponding transmission controlled device. The failed transmission control device then returns and waits for backup.
[0029]
Suppose now that the sending control devices 101 to 10m are in an active state and controlling the corresponding controlled devices 301 to 30m. In this case, each transmission control device has transmission control software and a database. In order for the sending control device 10m + 1 being backed up to be immediately replaced in the event of a failure, it is necessary to have all the software and databases held by the sending control devices 101 to 10m in the active state and to be updated. For this purpose, the database is transferred via the network 10 as indicated by the arrows in the figure. However, the capacity of the medium required to record them is very small compared to a video signal or the like. Therefore, even if the transmission control device is provided with redundancy and the backup transmission control device stores the software and database necessary for the control, it can cope with a slight increase in cost.
[0030]
[Simple backup system]
FIG. 3 is a more detailed configuration diagram of the present embodiment. This example is a simplified backup system for a broadcast transmission control system, and the basic configuration is as described in FIG. The transmission control devices 101 to 10m include video tape playback, recording of material data to the video server 34, and transmission of material data from the video playback device 37 or the video server 34 in the transmission controlled devices 301 to 30m. To control. For this purpose, each of the transmission control devices 101 to 10m has system software and application software necessary for control. Further, a database such as the above-described filing list, play list, and control data of the controlled device being supported is also stored in the recording medium 11. If the transmission control devices 101 to 10m are now in an active state, the software and database held by all the active transmission control devices 101 to 10m are stored in the recording medium 11R of the backup transmission control device 10m + 1. . In each transmission control device, when the control database is updated during the control, the corresponding control database in the backup transmission control device is also updated.
[0031]
A characteristic feature of this backup system is that the video signal system such as video and audio such as material data such as CM and material data of the program takes the minimum necessary configuration for the transmission channel, while the control signal Regarding the system, the control signal lines from the control devices 101 to 101m + 1 and the controlled devices 301 to 30m are made redundant. In particular, since material data such as CM is stored and transmitted in the video server 34 having a RAID configuration, it has resilience against failure. Therefore, the video signal system has a configuration adapted to the number of transmission channels. On the other hand, the control signal system provides redundancy to a transmission control device using a relatively inexpensive personal computer, and realizes robustness against failure with a slight increase in cost.
[0032]
For that purpose, what is necessary is that the control program and database are stored and updated in the apparatus so that the transmission control apparatus being backed up can be coped with at any time.
[0033]
In this simple backup system, a failure of the transmission control device is detected by, for example, an operator in the studio. In general, during broadcasting, an operator is stationed for transmission control, and instructs the final transmission of material data while observing a broadcast monitor. Therefore, the operator can easily and accurately detect a failure of the delivery control device. In this manner, when a failure of the transmission control device is detected, the operator switches to the backup transmission control device, and the switching setting of (m + 1) × m matrix switcher 40 is performed. This switching setting may be performed manually, for example.
[0034]
When the transmission control device that has been down due to a failure is restored, it will stand by as a backup transmission control device. In the example of FIG. 3, the matrix switcher for switching to the transmission channel in the controlled devices 301 to 30m is omitted for the sake of simplicity.
[0035]
FIG. 4 is a flowchart of overall broadcast control by the simplified backup system of FIG. With reference to this flowchart, the broadcast control and the response at the time of failure will be described.
[0036]
When the broadcasting system is activated, first, the correspondence between the transmission channel and the transmission controlled devices 301 to 30m that transmit the material data thereto, and the correspondence between the transmission controlled devices 301 to 30m and the transmission control devices 101 to 10m + 1 that control the transmission controlled devices. Is set (S1).
[0037]
Then, a playlist according to the broadcast transmission schedule is created or received from the upper control computer (S2). FIG. 5 is a diagram showing an example of the playlist. In this example, it has attribute data such as a transmission date and time, an identification code, a material type, a material title, a transmission time length, and a status regarding the presence or absence of transmission. This playlist is created for each transmission channel and stored in the recording medium of the corresponding transmission control device 101 to 10m. In the recording medium of the backup transmission control device 10m + 1, playlists stored in all the transmission control devices 101 to 10m are stored.
[0038]
Next, it is checked whether the playlist material, in particular CM, has been stored in the video server 34 in the transmission controlled devices 301 to 30m, and a filing list is created for the unstored material ( S3). The filing list is created by the transmission control devices 101 to 10m. However, a filing list may be created for a material that has been created regardless of the playlist. For example, materials that should be broadcast urgently are included in the filing list and filed before the playlist is created.
[0039]
FIG. 6 is a diagram illustrating an example of a filing list. This filing list has an identification code, a material name, a transmission channel, a transmission date and time, and the like as attribute data. In the system shown in FIG. 3, since the material on the playlist is reproduced and recorded on the video server in each transmission controlled device, a filing list is created for each transmission controlled device. Therefore, the attribute data of the transmission buffer device No shown in FIG. 6 is not used in the example of FIG. 3, but is used in an embodiment described later.
[0040]
The filing list for each transmission controlled apparatus is created by the filing control program of the corresponding transmission control apparatus 101 to 10 m and stored in each recording medium 11. At the same time, all filing lists are also stored in the recording medium 11R of the backup transmission control device 10m + 1.
[0041]
The transmission control apparatus checks whether there is a material to be filed on the filing list (S4), and reproduces the material and stores it in the video server 34 in the order of the transmission date and time. For this purpose, the sending control device refers to the capacity management table in the sending controlled device and checks whether there is sufficient free space (S5). FIG. 7 is a diagram showing an example of the capacity management table. This table includes attribute data such as the number of the transmission controlled device assigned to each transmission channel, the usable capacity assigned to the video server in the apparatus, and the used capacity. This capacity management table is also held in each of the transmission control devices 101 to 10m, and is also stored in the backup transmission control device. In this example, the capacity data of the sending buffer device (OABUF) corresponding to the sending controlled device is shown in accordance with another embodiment described later.
[0042]
If there is a free space in the capacity of the corresponding video server, the video playback device 32 is activated from the transmission control devices 101 to 10m to play the material, and the material data is stored (filed) in the video server 34 ( S6). If there is no free space, the material data is not stored until free space is generated. When the material data is stored, the used capacity attribute data in the capacity management table is changed, and the attribute data in the capacity management table in the backup transmission control apparatus is also updated.
[0043]
Therefore, after waiting for the transmission time on the playlist (S9), a video command such as a video cartridge machine is used from the video server 34 in the case of a material such as CM by a transmission command from the transmission control device. The material data is sent from the playback device 37 to the sending channel (S10).
[0044]
When it is sent out, the already sent flag is written in the status attribute data in the playlist (S12). At the same time, the same change is made to the playlist in the backup transmission control device. Unnecessary material that has been sent and is not repeatedly sent is then deleted from the video server 34 (S11). A database of material data stored in the video server 34 is stored in, for example, the corresponding transmission control devices 101 to 10m. Similarly, it is also stored in the backup control device.
[0045]
The above transmission control is repeated until all events in the playlist are completed (S13).
[0046]
If any of the transmission control devices 101 to 10m breaks down during the above series of playlist creation, filing list creation, material reproduction, storage, and transmission control, the failure is detected, for example, by an operator. (S7). When a failure is detected, for example, an operator switches the switch of the matrix switcher 40 to connect the transmission controlled device corresponding to the failed transmission control device and the backup transmission control device 10m + 1. Then, connection setting between the transmission control apparatus 10m + 1 and the corresponding transmission controlled apparatus 30n is performed (S8). The backup transmission control device 10m + 1 stores software necessary for transmission control and an updated database. Therefore, when connection by the matrix switcher 40 and connection confirmation setting of both are completed, transmission is performed without delay. Control can be continued.
[0047]
[Automatic backup system]
In the simple backup system described above, a failure of the transmission control device is detected by the operator, and the matrix switcher 40 is switched. However, if the number of transmission channels is further increased and the number of transmission control devices is correspondingly increased, the failure detection by the operator is limited. Therefore, it is desirable to have a function of automatically detecting a failure and a function of automatically switching the matrix switcher when a failure is detected. However, in that case, it is necessary to develop additional control software for the automation.
[0048]
FIG. 8 is a diagram showing an automatic broadcast control backup system according to the second embodiment. This system is the same as the first embodiment described above in that the transmission control devices 101 to 10m + 1 have redundancy. The difference is that an operation management device 50 for monitoring the operation status of the entire system is newly provided.
[0049]
The operation management device 50 is configured by a personal computer, for example, and is connected to the transmission control devices 101 to 10m + 1 and the like via the network 10. In addition, the operation management device 50 is directly connected to the transmission control devices 101 to 10m + 1 by the management signal lines 511 to 51m + 1. By doing so, the operation management device 50 monitors the operation log (as run log) reported from each transmission control device by its self-diagnosis function, and detects a failure of the transmission control device. Similarly, the control signal lines 531 to 53m are also connected to the interfaces 201 to 20m on the controlled devices 301 to 30m side, and the operation logs reported from the respective interfaces are also monitored.
[0050]
This operation log is data that each device reports to the operation management device as data indicating the self-diagnosis status. For example, for a command sent from the sending control device to the controlled device, the controlled device reports the implementation status of the command. By comparing the command log with the implementation status log, the operation status of the transmission control device and the transmission controlled device can be monitored. That is, the time when the execution of the instruction is completed is predicted for the instruction, and the implementation status reported at that time is monitored.
[0051]
As described above, the interfaces 201 to 20m control all devices in the controlled devices 301 to 30m, and monitor their operation status. Therefore, the interface reports the failure status in the controlled device.
[0052]
The operation management device 50 manages a correspondence table between the sending control device and the sending controlled device. Then, according to the correspondence, switching control of the matrix switcher 40 is performed by the control signal 52.
[0053]
The operation management device 50 can appropriately detect the failure of the transmission control devices 101 to 10m + 1 by monitoring the operation of the transmission control device and the operation of the interface. For example, when the interface side is operating normally but the transmission control device side reports an abnormality or no notification at all, the possibility of a failure on the transmission control device side is determined. In that case, the operation management apparatus 50 notifies the operator that there is a possibility of abnormality in the transmission control apparatus using a screen or other visual and auditory means.
[0054]
FIG. 9 is a flowchart of failure detection and transmission control device switching by the operation management device 50. Therefore, this corresponds to steps S7 and S8 in the overall flowchart of FIG.
[0055]
The operation management device 50 monitors the self-diagnosis function of each device via the management signal lines 511 to 51m + 1 and 531 to 53m (S20). It is monitoring by the above-mentioned operation log. When the operation management device 50 detects that there is an abnormality notification from the transmission control devices 101 to 10m + 1 or that the notification is interrupted (S21), the operation management device 50 identifies a transmission control device that may be abnormal (S22). . Then, the operation management device 50 causes the matrix switcher 40 to connect the backup transmission control device 10m + 1 and the controlled device corresponding to the failed transmission control device by the control signal 52.
[0056]
Then, the operation management device 50 sets the setup conditions of the backup transmission control device 10m + 1 via the network 10 and sets up a database such as a corresponding playlist or filing list. As a result, the switched transmission control device 10m + 1 confirms the interface and connection of the corresponding controlled device. Therefore, the operation management device 50 confirms the operation of this connection by the management signal lines 51m + 1 and 531 to 53m (S24). If it is confirmed, the operation management device 50 instructs the transmission control device 10m + 1 to continue the transmission control (S25).
[0057]
As described above, the operation management device 50 is added, and the failure of the transmission control device can be automatically detected by monitoring the report by the self-diagnosis function of each device with the management signal line. Then, the operation management device 50 performs the switching automatically by performing the switching control directly on the matrix switcher 40. Then, the broadcast transmission can be automatically restarted by issuing a setup instruction to the switched backup transmission control device 10m + 1, issuing a continuation command after confirming the connection.
[0058]
The degree of automation is designed according to the scale of the entire system, the cost of automation, and the like.
[0059]
FIG. 10 is a diagram showing an embodiment when the present invention is applied to a multi-channel broadcasting system using a common video server and a transmission buffer device for transmitting material data to each transmission channel. When the number of transmission channels is further increased, a material such as a common CM is transmitted from a plurality of transmission channels. On the other hand, the process of reproducing a material from a video tape or the like and filing it on a video server requires time for reproduction and takes a long time.
[0060]
Therefore, a method of reproducing a material such as CM and recording it on the common video server 60 and copying it from there to each output buffer as necessary becomes more efficient. That is, the compressed material data filed in the common video server 60 is copied to the video servers of the transmission buffers 701 to 70m via the video cable 64 by file transfer. This copying is merely a file transfer of the compressed data, and can be performed in a very short time.
[0061]
As shown in FIG. 10, the material in the video tape 63 is reproduced and recorded (filed) on the nearline server 60 which is a common video server. This recording is controlled by the filing control PC 62. The filing control PC 62 manages the filing list and the material database recorded in the server 60.
[0062]
In the example shown in FIG. 10, the filling control PC 62 is connected to each of the transmission control devices 101 to 10 m + 1 via the network 10. Therefore, the transmission control apparatus creates a copy list that lists materials that are not stored in the transmission buffers 701 to 70m among the materials with early transmission times in the playlist. According to this copy list, the material data is transferred from the common video server 60 to the transmission buffer and copied. The filing list shown in FIG. 6 is a copy list in the present embodiment.
[0063]
Various methods can be considered for this copy control. As an example, for example, a copy request from the transmission control device is sent to the filing control PC 62 via the network 10. The filing control PC 62 transmits a signal in response to the transmission control device, and the file transfer of the material data is performed at a predetermined timing. At that time, the transmission control apparatus instructs the interface to receive a file via a normal control system.
[0064]
In the example shown in FIG. 10, the transmission buffers 701 to 70m have a configuration in which, for example, the video playback device 32 and the encoder 33 are deleted from the configuration of the controlled devices 301 to 30m in FIG. Then, the video / audio signal from the common video server 62 is copied to the video server 34. The material of the program specific to the transmission channel is reproduced and transmitted by the video reproduction device 37 as shown in FIG.
[0065]
Also in the multi-channel broadcasting system shown in FIG. 10, the transmission control device is made redundant. Then, the operation management device 50 detects the failure, switches to backup, and continues the transmission in the same manner as described above.
[0066]
In the above embodiment, m + 1 units of transmission control devices are provided for m units of transmission controlled devices. However, when one unit of the sending control device controls a plurality of sending controlled devices, the sending control device is provided with a larger number of units than the number of sending control devices required to control the sending controlled device. It is done. Thereby, redundancy can be given to the transmission control device.
[0067]
【The invention's effect】
As described above, according to the present invention, the number of transmission control devices is configured with redundancy, and the matrix switcher is used so that the connection with the transmission controlled devices can be in any combination. Even if a control system failure occurs due to a control device failure, switch immediately. Broadcast You can continue with minimal interruptions.
[0068]
In addition, the transmission control device can be configured by a low-priced device such as a personal computer, and the cost increase associated with backup can be minimized.
[0069]
In the case of a simple backup system, the backup transmission control device need only store the same control software and control database as the normal transmission control device, and uses the normal operation style as it is. It is not necessary to prepare special software for backup.
[0070]
Furthermore, an automatic backup system can be automated by monitoring the operation status and switching at the time of failure by the operation management device.
[Brief description of the drawings]
FIG. 1 is a diagram showing a basic configuration of a broadcast transmission system unit.
FIG. 2 is a schematic configuration diagram of a first embodiment.
FIG. 3 is a more detailed configuration diagram of the first embodiment.
FIG. 4 is a flowchart of overall broadcast control by a simple backup system.
FIG. 5 is a diagram illustrating an example of a playlist.
FIG. 6 is a diagram illustrating an example of a filing list or a copy list.
FIG. 7 is a diagram illustrating an example of a capacity management table.
FIG. 8 is a diagram showing an automatic broadcast control backup system according to a second embodiment;
FIG. 9 is a flowchart of automatic failure detection and switching of the transmission control device.
FIG. 10 is a diagram showing an embodiment when the present invention is applied to a multi-channel broadcasting system using a common video server and a transmission buffer device that transmits material data to each transmission channel.
[Explanation of symbols]
101-10m + 1 sending control device
40 Matrix switcher
201-20m interface
301 ~ 30m sending controlled device
50 Operation management device

Claims (3)

In a multi-channel broadcasting system that sends material data to multiple sending channels,
A controlled device of m (m is a plurality) units, each executing reproduction, storage or transmission processing of material data corresponding to the transmission channel ;
M units of main transmission control devices for controlling the processing operations of the controlled devices, each of which is associated one-to-one, based on a playlist prepared for each transmission channel, each of which includes a transmission control program and the A main transmission control device for m units for storing playlists ;
A backup transmission control device interconnected with each of the main transmission control devices via a network, receiving all of the transmission control programs and playlists possessed by each of the main transmission control devices via the network. A backup transmission control device having the same structure as the main transmission control device, which is kept in the latest state;
A control matrix switcher for arbitrarily connecting the m-unit main delivery control device and the backup delivery control device to the m-unit controlled device, and switching operation of an operator who has confirmed the failure of the main delivery control device And a matrix switcher for switching the connection between the failed main transmission control device and the corresponding controlled device to the backup transmission control device side . In a multi-channel broadcasting system that sends material data to multiple sending channels,
A controlled device of m (m is a plurality) units, each executing reproduction, storage or transmission processing of material data corresponding to the transmission channel ;
M units of main transmission control devices for controlling the processing operations of the controlled devices, each of which is associated one-to-one, based on a playlist prepared for each transmission channel, each of which includes a transmission control program and the A main transmission control device for m units for storing playlists ;
A backup transmission control device interconnected with each of the main transmission control devices via a network, receiving all of the transmission control programs and playlists possessed by each of the main transmission control devices via the network. A backup transmission control device having the same structure as the main transmission control device, which is kept in the latest state;
A control matrix switcher for arbitrarily connecting the m unit main transmission control device and the backup transmission control device to the m unit controlled device;
An operation management device that monitors the operation status of the m unit main transmission control device and the backup transmission control device through individual management signal lines, and when a failure is detected, the failed main transmission is switched by switching the control matrix switcher. An operation management device for switching a connection between a control device and a corresponding controlled device to the backup transmission control device side and instructing the backup transmission control device to continue control of the corresponding controlled device. Multi-channel broadcasting system. In a multi-channel broadcasting system that sends material data to multiple sending channels,
A plurality of units of transmission controlled devices, each executing reproduction, storage or transmission processing of material data corresponding to the transmission channel ;
One or a plurality of main transmission control devices, each of which controls the processing operation of the controlled device associated with a plurality of the transmission controlled devices based on a playlist prepared for each transmission channel, A main transmission control device of one or a plurality of units for storing a transmission control program and the playlist ;
A backup transmission control device interconnected with each of the main transmission control devices via a network, receiving all of the transmission control programs and playlists possessed by each of the main transmission control devices via the network. A backup transmission control device having the same structure as the main transmission control device, which is kept in the latest state;
A control matrix switcher for arbitrarily connecting the one or a plurality of units of the main transmission control device and the backup transmission control device and the m-unit controlled device;
An operation management device that monitors the operation status of the m unit main transmission control device and the backup transmission control device through individual management signal lines, and when a failure is detected, the failed main transmission is switched by switching the control matrix switcher. An operation management device for switching a connection between a control device and a corresponding controlled device to the backup transmission control device side and instructing the backup transmission control device to continue control of the corresponding controlled device. Multi-channel broadcasting system.

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