KR20220067901A - Method and apparatus for broadcasting production of based software definition - Google Patents

Abstract

Disclosed are a software definition-based broadcast production method and system that efficiently manage resources and facilitate remote management. The software definition-based broadcast production system according to an embodiment disclosed herein comprises: a management server that transmits a video function virtualized (VFV) installation command based on a preset broadcast production workflow; a VFV host that receives the VFV installation command from the management server, and downloads and installs a VFV module corresponding to the VFV installation command; and a networked media open specifications (NMOS) server that obtains detailed VFV operation information about the VFV module when the VFV module is driven in the VFV host.

Description

SOFTWARE DEFINITION BASED BROADCASTING PRODUCTION PRODUCTION OF BASED SOFTWARE DEFINITION

Embodiments of the present invention relate to broadcast production technology.

In the case of digital broadcast production, it is common to configure a broadcast production workflow by serially connecting devices performing a specific function. When this series of workflow configuration is completed, the equipment included in the workflow has the inconvenience of physically disconnecting, moving physically, and making a new connection to other workflows in order to use it in other workflows.

In order to solve this problem, broadcasting equipment capable of transmitting and receiving data through IP has been developed and used. However, IP-based broadcasting equipment is controlled through a control panel included in the broadcasting equipment, so there is a problem in that integrated management is difficult.

Korean Patent Publication No. 10-0734033 (2007.07.02)

SUMMARY OF THE INVENTION An embodiment of the present invention is to provide a method and system for producing a software-defined-based broadcast that efficiently manages resources and facilitates remote management.

A software definition-based broadcast production system according to an embodiment of the present disclosure includes: a management server that transmits a video function virtualized (VFV) installation command based on a preset broadcast production workflow; a VFV host that receives the VFV installation command from the management server, and downloads and installs a corresponding VFV module according to the VFV installation command; and a Networked Media Open Specification (NMOS) server for obtaining detailed VFV operation information for the VFV module when the VFV module is driven in the VFV host.

The management server may generate the VFV installation command including at least one of identification information and installation number information of a VFV module according to a connection relationship between VFV modules included in the broadcast production workflow and available resources of VFV hosts. .

The detailed VFV operation information may include at least one of identification information of the VFV module, function information of the VFV module, and input/output related information of the VFV module.

The NMOS server transmits the detailed VFV operation information to the management server, and the management server establishes interworking between VFV modules based on a connection relationship between VFV modules included in the broadcast production workflow and the detailed VFV operation information. It can handle the process of judging whether or not

The management server transmits a connection establishment request to the VFV module of the higher priority and the lower priority according to the connection order of each VFV module in the broadcast production workflow, respectively, and the senior VFV module is the sub-priority VFV module When the input/output related information is requested and received, and the input/output related information of the lower priority VFV module corresponds to the input/output related information of the corresponding senior VFV module, the corresponding senior VFV module is switched to an active state, and the lower priority VFV module is configured to: When the priority VFV module requests and receives input/output related information of the corresponding higher priority VFV module, and the input/output related information of the higher priority VFV module corresponds to the input/output related information of the corresponding lower priority VFV module, the corresponding lower priority VFV module is switched to the active state can do.

The NMOS server periodically receives operation state information from the VFV module installed in the VFV host, and the management server, when receiving a broadcast production workflow creation request, produces a broadcast corresponding to the broadcast production workflow creation request. A workflow may be extracted, and an inquiry about availability of VFV modules constituting the extracted broadcast production workflow may be transmitted to the NMOS server.

When the VFV modules are in a usable state, the management server checks whether a connection setting between VFV modules according to the broadcast production workflow exists, and when the connection setting does not exist, the connection of the VFV modules A connection establishment request can be transmitted to the corresponding VFV module according to the sequence.

The management server transmits a VFV installation command for installation of the VFV module to the VFV host where the VFV module is to be installed when there is a VFV module in an unusable state among the VFV modules constituting the broadcast production workflow. can

The NMOS server periodically receives operation state information from a VFV module installed in the VFV host, and the management server, when receiving a broadcast production workflow deletion request, produces a broadcast corresponding to the broadcast production workflow deletion request. Extract the workflow, check the list of VFV modules included in the extracted broadcast production workflow and the connection relationship between the VFV modules, and send an inquiry about the operation status of the VFV modules included in the broadcast production workflow to the NMOS server .

When the VFV modules included in the broadcast production workflow are in a normal state, the management server may transmit a connection release request to the corresponding VFV module according to a connection order of the VFV modules.

A software definition-based broadcast production method according to an embodiment of the present disclosure includes: transmitting, in a management server, a video function virtualized (VFV) installation command based on a preset broadcast production workflow; receiving, at the VFV host, the VFV installation command from the management server, and downloading and installing a corresponding VFV module according to the VFV installation command; and obtaining, in a Networked Media Open Specification (NMOS) server, detailed VFV operation information for the VFV module when the VFV module is driven in the VFV host.

According to the disclosed embodiment, by installing the VFV module in a VFV host, which is a general-purpose equipment, according to a preset broadcast production workflow, the VFV module can be freely installed according to the broadcast production workflow using a general-purpose workstation and controlled remotely becomes possible In addition, unlike conventional broadcasting equipment, the VFV host is not fixed to a specific function, but performs various functions according to an installed VFV module, thereby efficiently managing resources.

In addition, by sending the detailed VFV operation information to the NMOS server when the VFV module is running in the VFV host, even if the administrator who commands the installation of the VFV module and the administrator who executes it are different, which VFV module is driven in a certain VFV host and It can be easily identified whether

1 is a diagram showing the configuration of a software-defined broadcast production system according to an embodiment of the present invention;
2 is a flowchart illustrating a process of installing a VFV module in a VFV host according to an embodiment of the present invention;
3 is a flowchart illustrating a process of performing connection processing between VFV modules according to an embodiment of the present invention;
4 is a flowchart illustrating a process of implementing a broadcast production workflow in an embodiment of the present invention;
5 is a flowchart illustrating a process of deleting a broadcast production workflow in an embodiment of the present invention;
6 is a block diagram illustrating and describing a computing environment including a computing device suitable for use in example embodiments;

Hereinafter, specific embodiments of the present invention will be described with reference to the drawings. The following detailed description is provided to provide a comprehensive understanding of the methods, devices, and/or systems described herein. However, this is merely an example, and the present invention is not limited thereto.

In describing the embodiments of the present invention, if it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. And, the terms to be described later are terms defined in consideration of functions in the present invention, which may vary according to intentions or customs of users and operators. Therefore, the definition should be made based on the content throughout this specification. The terminology used in the detailed description is for the purpose of describing embodiments of the present invention only, and should in no way be limiting. Unless explicitly used otherwise, expressions in the singular include the meaning of the plural. In this description, expressions such as “comprising” or “comprising” are intended to indicate certain features, numbers, steps, acts, elements, some or a combination thereof, one or more other than those described. It should not be construed to exclude the presence or possibility of other features, numbers, steps, acts, elements, or any part or combination thereof.

In the following description, the terms "transmission", "communication", "transmission", "reception" and other similar meanings of a signal or information are not only directly transmitted from one component to another component, but also a signal or information This includes passing through other components. In particular, to “transmit” or “transmit” a signal or information to a component indicates the final destination of the signal or information and does not imply a direct destination. The same is true for "reception" of signals or information. In addition, in this specification, when two or more data or information are "related", it means that when one data (or information) is acquired, at least a part of other data (or information) can be acquired based thereon.

Also, terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The above terms may be used for the purpose of distinguishing one component from another component. For example, without departing from the scope of the present invention, a first component may be referred to as a second component, and similarly, a second component may also be referred to as a first component.

1 is a diagram illustrating the configuration of a software defined broadcast production system according to an embodiment of the present invention.

Referring to FIG. 1 , a software definition based broadcast production system 100 may include a broadcast production platform 102 , a video function virtualized (VFV) host 104 , and a manager terminal 106 . The broadcast production platform 102 , a video function virtualized (VFV) host 104 , and the manager terminal 106 are communicatively connected through a communication network (not shown), respectively.

In some embodiments, a communication network (not shown) is the Internet, one or more local area networks, wide area networks, cellular networks, mobile networks, other types of networks, or such It may include a combination of networks.

The broadcast production platform 102 may configure and manage a workflow for broadcast production (broadcast production workflow). Here, the broadcast production workflow may indicate a workflow in which a broadcast is produced through the operation of a plurality of video function virtualized (VFV) modules.

A video function virtualized (VFV) module is software for virtualized broadcast production processing, and may be composed of a video function, which is a basic unit of image processing, or a combination of video functions. In an exemplary embodiment, the VFV module may be provided to perform a broadcast video switcher, ingester, and player, etc. through a combination of video functions.

In an exemplary embodiment, a video function includes a video input source processing function, a video input source switching function, a video output source processing function, and a video processing function (eg, down-scaler, overlay, transition effect, etc.) and the like.

The broadcast production platform 102 may remotely manage installation, change, and deletion of the VFV module for the VFV host 104 according to a preset broadcast production workflow. In addition, the broadcast production platform 102 may collect events occurring in the VFV module operated and the events occurring in the VFV host 104 in which the VFV module is driven.

In the exemplary embodiment, the broadcast production platform 102 includes a Networked Media Open Specification (NMOS) server 111 , a management server 113 , a Video Function Virtualized (VFV) storage 115 , and a log server 117 . can do.

When a video function virtualized (VFV) module is driven in the VFV host 104 , the NMOS server 111 may receive detailed VFV operation information from the VFV module. The NMOS server 111 may perform a registration procedure for the corresponding VFV module according to the detailed VFV operation information. That is, when receiving the detailed VFV operation information, the NMOS server 111 may register the corresponding VFV module in the broadcast production platform 102 .

Here, the detailed VFV operation information may include identification information of the corresponding VFV module, function information of the corresponding VFV module (information on which function the corresponding VFV module performs), and input/output related information of the corresponding VFV module. The input/output related information of the VFV module may include information about how many input signals the VFV module receives from (ie, an input source) and how many output signals are transmitted to where (ie, an output source).

The NMOS server 111 may periodically receive operation state information (eg, keep-alive or heartbeat, etc.) from the VFV module installed in the VFV host 104 . The NMOS server 111 may transmit operation state information of each VFV module to the management server 113 .

The management server 113 may control installation, change, and deletion of the VFV module for each VFV host 104 according to a preset broadcast production workflow. In an exemplary embodiment, the management server 113 assigns a certain VFV module to a certain VFV host 104 according to the connection relationship of the VFV modules included in the preset broadcast production workflow and the available resources of each VFV host 104 . You can create a VFV installation command by setting whether to install or not. However, the present invention is not limited thereto, and a VFV installation command may be received from an administrator terminal (not shown).

The VFV installation command may include identification information and installation number information of VFV modules to be installed in the corresponding VFV host 104 . The management server 113 may transmit a VFV installation command to the corresponding VFV host 104 .

Also, the management server 113 may set which VFV module to be deleted or changed from which VFV host 104 according to a preset broadcast production workflow. Here, the broadcast production workflow may be received from the manager terminal 106, but is not limited thereto.

The management server 113 may receive detailed VFV operation information and operation state information of the VFV module from the NMOS server 111 , respectively. The management server 113 may receive log data of each VFV host 104 from the log server 117 . The management server 113 may monitor the status of all VFV hosts 104 through the log server 117 .

The management server 113 may process a process of determining whether to set interworking between each VFV module based on a preset broadcast production workflow and detailed VFV operation information. That is, the management server 113 may process a process of whether interworking between each VFV module is possible based on a preset broadcast production workflow and input/output related information of each VFV module.

For example, if the broadcast production workflow is connected in the order of "a first VFV module - a second VFV module", and the first VFV module has two input sources and three output sources, the management server 113 ) may determine whether the second VFV module has three or more input sources to process the process of whether interworking between VFV modules is possible. In this case, the management server 113 may check whether interworking between the VFV modules is possible based on whether the output information of the first VFV module and the input information of the second VFV module correspond to each other.

VFV storage 115 may store VFV modules. In an exemplary embodiment, the VFV storage 115 may store VFV modules each performing different functions. The VFV storage 115 may transmit a corresponding VFV module to the VFV host 104 according to a download request of the VFV host 104 .

The log server 117 may collect log data generated by each VFV host 104 . In an exemplary embodiment, log data generated by the VFV host 104 includes operation state information (eg, Live or Dead, etc.) of the VFV host 104 and information related to VFV driving of the VFV host 104 ( That is, information about which VFV module is being driven) may be included. The log server 117 may transmit the collected log data to the management server 113 .

The VFV host 104 may be a computing device in which the VFV module is installed and drives the VFV module. That is, the VFV host 104 may be a computing device for processing the VFV module based on software. The VFV host 104 may receive a VFV installation command from the management server 113 . The VFV installation command may include identification information and installation number information of VFV modules to be installed in the corresponding VFV host 104 .

The VFV host 104 may transmit a download request for the corresponding VFV module to the VFV storage 115 according to the VFV installation command, and may download and install the corresponding VFV module from the VFV storage 115 . In this case, the VFV host 104 may download and install the VFV module by using the Docker 104a.

The VFV host 104 may include a host manager 104b for managing the operation of the VFV host 104 . The host manager 104b may install and operate a corresponding VFV module in the VFV host 104 according to a VFV installation command. When the VFV module is operated, the host manager 104b may transmit detailed VFV operation information for the VFV module to the NMOS server 111 .

As such, when the VFV module is driven in the VFV host 104, detailed VFV operation information is transmitted to the NMOS server 111, so that even if the administrator who commands the installation of the VFV module and the administrator who executes it are different from each other, any VFV host At 104, it is possible to easily determine which VFV module is being driven.

According to the disclosed embodiment, the VFV module is installed in the VFV host 104, which is a general-purpose equipment, according to a preset broadcast production workflow, so that the VFV module is freely installed according to the broadcast production workflow using a general-purpose workstation. Remote control becomes possible. In addition, unlike conventional broadcasting equipment, the VFV host 104 is not fixed to a specific function, but performs various functions according to an installed VFV module, so that resource management can be performed efficiently.

2 is a flowchart illustrating a process of installing a VFV module in a VFV host according to an embodiment of the present invention. In the illustrated flowchart, the method is described by dividing the method into a plurality of steps, but at least some of the steps are performed in a different order, are performed in combination with other steps, are omitted, are performed in separate steps, or are not shown. One or more steps may be added and performed.

Referring to FIG. 2 , when the management server 113 receives the VFV installation command from the manager terminal 106 ( S101 ), the management server 113 transmits the VFV module included in the VFV installation command to the corresponding VFV host 104 . ) is checked (S103).

As a result of checking in step S103, if the VFV module does not exist in the corresponding VFV host 104, the management server 113 transmits a VFV installation command to the host manager 104b of the VFV host 104 (S105) .

Next, the host manager 104b transmits a download request for the VFV module to be installed in the VFV host 104 to the docker 104a according to the VFV installation command (S107). Then, the docker 104a downloads the corresponding VFV module from the VFV storage 115 (S109).

Next, the host manager 104b transmits a request to install the downloaded VFV module to the docker 104a (S 111). Then, the docker 104a installs the VFV module in the VFV host 104 and transmits the VFV installation result to the host manager 104b (S113).

Next, the host manager 104b transmits the VFV installation result to the management server 113 in response to the VFV installation command ( S115 ).

Meanwhile, the management server 113 may delete the VFV module installed in the VFV host 104 . Specifically, the management server 113 may transmit a VFV deletion command to the host manager 104b of the VFV host 104 . Then, the host manager 104b may transmit a VFV deletion request to the docker 104a, the docker 104a may delete the VFV module corresponding to the VFV deletion request, and transmit the VFV deletion result to the host manager 104b. The host manager 104b may transmit a VFV deletion result to the management server 113 in response to the VFV deletion command.

3 is a flowchart illustrating a process of performing connection processing between VFV modules according to an embodiment of the present invention. In the illustrated flowchart, the method is described by dividing the method into a plurality of steps, but at least some of the steps are performed in a different order, are performed in combination with other steps, are omitted, are performed in separate steps, or are not shown. One or more steps may be added and performed.

Referring to FIG. 3 , the management server 113 receives a broadcast production workflow execution command from the manager terminal 106 ( S201 ). The broadcast production workflow execution command may include identification information of the broadcast production workflow.

Next, the management server 113 checks the broadcast production workflow corresponding to the broadcast production workflow execution command among the pre-stored broadcast production workflows, and extracts a list of VFV modules included in the confirmed broadcast production workflow (S203).

Next, the management server 113 transmits a connection establishment request to the corresponding VFV module according to the connection order between the VFV modules in the corresponding broadcast production workflow (S205). For example, when the corresponding broadcast production workflow is connected in the order of "first VFV module (higher priority) - second VFV module (second priority)", the management server 113 is connected to the first VFV module M1 You can send a setup request.

Next, the first VFV module M1 requests and receives input/output related information of the second VFV module M2 from the second VFV module M2 according to the connection establishment request (S207). In this case, the second VFV module M2 may transmit an input/output related information of the second VFV module M2 to the first VFV module M1 by transmitting a Session Description Protocol (SDP) file.

Next, the first VFV module M1 checks whether the input/output related information of the first VFV module M1 corresponds to the input/output related information of the second VFV module M2 ( S209 ).

As a result of checking in step S 209 , when the input/output related information of the first VFV module M1 corresponds to the input/output related information of the second VFV module M2, the first VFV module M1 ) to an active state (that is, a state in which an IP address and port number for RTP (Real Time Protocol) transmission/reception with the second VFV module (M2) can be transmitted), and the connection setting result is transmitted to the management server 113 do (S 211).

As a result of checking in step S 209 , when the input/output related information of the first VFV module M1 does not correspond to the input/output related information of the second VFV module M2 , the first VFV module M1 is transferred to the management server 113 . to send a connection establishment failure message.

Next, when the first VFV module M1 is switched to the active state, the management server 113 transmits a connection setup request to the second VFV module M2 according to the connection sequence between VFV modules in the corresponding broadcast production workflow. do (S213).

Next, the second VFV module M2 requests and receives input/output related information of the first VFV module M1 from the first VFV module M1 according to the connection establishment request (S215). In this case, the first VFV module M1 may transmit an SDP (Session Description Protocol) file to transmit input/output related information of the first VFV module M1 to the second VFV module M2.

Next, the second VFV module M2 checks whether the input/output related information of the second VFV module M2 corresponds to the input/output related information of the first VFV module M1 ( S217 ).

As a result of the check in step S 217 , when the input/output related information of the second VFV module M2 corresponds to the input/output related information of the first VFV module M1 , the second VFV module M2 is connected to the second VFV module M2 ) to an active state (that is, a state in which an IP address and port number for RTP transmission/reception with the first VFV module M1 can be transmitted) and the connection setting result is transmitted to the management server 113 (S 219) .

As a result of checking in step S 217 , if the input/output related information of the second VFV module M2 does not correspond to the input/output related information of the first VFV module M1 , the second VFV module M2 is transferred to the management server 113 . to send a connection establishment failure message.

Meanwhile, although it has been described herein that the input/output related information of the VFV module is mutually transmitted, the present invention is not limited thereto, and the input/output related information of the VFV module may be mutually transmitted through the NMOS server 111 .

4 is a flowchart illustrating a process of implementing a broadcast production workflow in an embodiment of the present invention. In the illustrated flowchart, the method is described by dividing the method into a plurality of steps, but at least some of the steps are performed in a different order, are performed in combination with other steps, are omitted, are performed in separate steps, or are not shown. One or more steps may be added and performed.

Referring to FIG. 4 , the management server 113 receives a broadcast production workflow creation request from the manager terminal 106 ( S301 ). The broadcast production workflow creation request may include connection information between VFV modules in the broadcast production workflow. That is, the broadcast production workflow creation request may include information on which VFV modules will generate the connected broadcast production workflow in what order.

Next, the management server 113 checks whether there is a broadcast production workflow corresponding to the broadcast production workflow creation request among the pre-stored broadcast production workflows (S 303).

In step S 303, if there is no broadcast production workflow corresponding to the broadcast production workflow creation request, the management server 113 may newly create a broadcast production workflow corresponding to the broadcast production workflow creation request.

In step S 303, if there is a broadcast production workflow corresponding to the broadcast production workflow creation request, the management server 113 sends an inquiry about availability of VFV modules constituting the broadcast production workflow to the NMOS server 111 ) to (S305).

That is, the management server 113 may inquire to the NMOS server 111 as to whether the VFV modules constituting the corresponding broadcast production workflow are currently available or unavailable because they are being used in other broadcast production workflows. . In this case, the NMOS server 111 may check whether the VFV modules constituting the corresponding broadcast production workflow are available or unavailable based on the detailed VFV operation information received from each VFV host 104 .

As a result of checking in step S 305, when the VFV modules constituting the broadcast production workflow are available, the management server 113 checks whether a connection setting between VFV modules corresponding to the broadcast production workflow exists. do (S 307). The management server 113 may check whether a connection setting between VFV modules exists through the NMOS server 111 .

As a result of checking in step S305, if there is a VFV module in an unusable state among VFV modules constituting the broadcast production workflow, the management server 113 corresponds to the VFV host 104 where the VFV module is to be installed. You can send a VFV installation command to install the VFV module.

As a result of checking in step S307, if there is no connection setup between VFV modules, the management server 113 transmits a connection setup request according to the connection order between VFV modules in the corresponding broadcast production workflow (S309). Here, since the connection setting between the VFV modules is the same as or similar to that of FIG. 3 , a detailed description thereof will be omitted.

5 is a flowchart illustrating a process of deleting a broadcast production workflow according to an embodiment of the present invention. In the illustrated flowchart, the method is described by dividing the method into a plurality of steps, but at least some of the steps are performed in a different order, are performed in combination with other steps, are omitted, are performed in separate steps, or are not shown. One or more steps may be added and performed.

Referring to FIG. 5 , the management server 113 receives a broadcast production workflow deletion request from the manager terminal 106 ( S401 ). The broadcast production workflow deletion request may include identification information of the corresponding broadcast production workflow.

Next, the management server 113 extracts a broadcast production workflow corresponding to the broadcast production workflow deletion request from among the pre-stored broadcast production workflows (S403), and lists the VFV modules included in the broadcast production workflow and a connection relationship between the VFV modules is checked (S405).

Next, the management server 113 inquires of the operation status of the VFV modules included in the corresponding broadcast production workflow to the NMOS server 111 (S407). The NMOS server 111 may transmit operation state information of each VFV module to the management server 113 .

As a result of checking S 407, if the VFV modules included in the corresponding broadcast production workflow are in a normal state, the management server 113 transmits a connection release request to the corresponding VFV module according to the connection order between VFV modules in the corresponding broadcast production workflow do (S409).

For example, when the corresponding broadcast production workflow is connected in the order of "first VFV module - second VFV module", the management server 113 may configure the first VFV module (M1) and the second VFV module (M2) to send a disconnection request. Then, the first VFV module M1 deletes the input/output related information of the second VFV module M2, and the second VFV module M2 deletes the input/output related information of the first VFV module M1 to be interconnected Release is performed (S 411).

6 is a block diagram illustrating and describing a computing environment 10 including a computing device suitable for use in example embodiments. In the illustrated embodiment, each component may have different functions and capabilities other than those described below, and may include additional components in addition to those described below.

The illustrated computing environment 10 includes a computing device 12 . In one embodiment, computing device 12 may be broadcast production platform 102 . Computing device 12 may also be VFV host 104 .

Computing device 12 includes at least one processor 14 , computer readable storage medium 16 , and communication bus 18 . The processor 14 may cause the computing device 12 to operate in accordance with the exemplary embodiments discussed above. For example, the processor 14 may execute one or more programs stored in the computer-readable storage medium 16 . The one or more programs may include one or more computer-executable instructions that, when executed by the processor 14, configure the computing device 12 to perform operations in accordance with the exemplary embodiment. can be

Computer-readable storage medium 16 is configured to store computer-executable instructions or program code, program data, and/or other suitable form of information. The program 20 stored in the computer-readable storage medium 16 includes a set of instructions executable by the processor 14 . In one embodiment, computer-readable storage medium 16 includes memory (volatile memory, such as random access memory, non-volatile memory, or a suitable combination thereof), one or more magnetic disk storage devices, optical disk storage devices, flash It may be memory devices, other forms of storage medium accessed by computing device 12 and capable of storing desired information, or a suitable combination thereof.

Communication bus 18 interconnects various other components of computing device 12 , including processor 14 and computer readable storage medium 16 .

Computing device 12 may also include one or more input/output interfaces 22 and one or more network communication interfaces 26 that provide interfaces for one or more input/output devices 24 . The input/output interface 22 and the network communication interface 26 are coupled to the communication bus 18 . Input/output device 24 may be coupled to other components of computing device 12 via input/output interface 22 . Exemplary input/output device 24 may include a pointing device (such as a mouse or trackpad), a keyboard, a touch input device (such as a touchpad or touchscreen), a voice or sound input device, various types of sensor devices, and/or imaging devices. input devices, and/or output devices such as display devices, printers, speakers and/or network cards. The exemplary input/output device 24 may be included in the computing device 12 as a component constituting the computing device 12 , and may be connected to the computing device 12 as a separate device distinct from the computing device 12 . may be

Although representative embodiments of the present invention have been described in detail above, those of ordinary skill in the art to which the present invention pertains will understand that various modifications are possible within the limits without departing from the scope of the present invention with respect to the above-described embodiments. . Therefore, the scope of the present invention should not be limited to the described embodiments, and should be defined by the claims described below as well as the claims and equivalents.

100: Software-defined based broadcast production system
102: broadcast production platform
104: VFV host
104a : docker
104b: host manager
106: manager terminal
111 : NMOS Server
113: management server
115 : VFV storage
117 : log server

Claims (11)

a management server for transmitting a video function virtualized (VFV) installation command based on a preset broadcast production workflow;
a VFV host that receives the VFV installation command from the management server, and downloads and installs a corresponding VFV module according to the VFV installation command; and
and a Networked Media Open Specification (NMOS) server for obtaining detailed VFV operation information for the VFV module when the VFV module is driven in the VFV host.
The method according to claim 1,
The management server,
A software definition-based broadcast production system that generates the VFV installation command including at least one of identification information and installation number information of a VFV module according to a connection relationship between VFV modules included in the broadcast production workflow and available resources of VFV hosts .
The method according to claim 1,
The VFV operation detailed information is,
A software-defined based broadcast production system comprising at least one of identification information of the VFV module, function information of the VFV module, and input/output related information of the VFV module.
The method according to claim 1,
The NMOS server transmits the detailed VFV operation information to the management server,
The management server,
A software definition-based broadcast production system for processing a process of determining whether to set interworking between VFV modules based on a connection relationship between VFV modules included in the broadcast production workflow and the detailed VFV operation information.
5. The method according to claim 4,
The management server transmits a connection establishment request to VFV modules of higher priority and lower priority according to a connection order of each VFV module in the broadcast production workflow, respectively;
When the priority VFV module requests and receives input/output related information of the corresponding lower priority VFV module from the lower priority VFV module, the input/output related information of the lower priority VFV module corresponds to the input/output related information of the corresponding senior VFV module. turn the VFV module into an active state,
The sub-priority VFV module requests and receives input/output related information of the corresponding higher-priority VFV module from the higher-priority VFV module. A software-defined based broadcast production system that turns the VFV module into an active state.
The method according to claim 1,
The NMOS server periodically receives operation state information from a VFV module installed in the VFV host,
The management server,
When receiving a broadcast production workflow creation request, a broadcast production workflow corresponding to the broadcast production workflow creation request is extracted, and an inquiry about availability of VFV modules constituting the extracted broadcast production workflow is sent to the NMOS server. A software-defined based broadcast production system.
7. The method of claim 6,
The management server,
When the VFV modules are available, it is checked whether a connection setting between VFV modules according to the broadcast production workflow exists, and when the connection setting does not exist, connection is established according to the connection order of the VFV modules A software-defined based broadcast production system that sends requests to the corresponding VFV module.
7. The method of claim 6,
The management server,
If there is a VFV module in an unusable state among the VFV modules constituting the broadcast production workflow, a VFV installation command for installing the VFV module is transmitted to the VFV host where the VFV module is to be installed. production system.
The method according to claim 1,
The NMOS server periodically receives operation state information from a VFV module installed in the VFV host,
The management server,
When receiving a broadcast production workflow deletion request, extract a broadcast production workflow corresponding to the broadcast production workflow deletion request, and check the connection relationship between the list of VFV modules included in the extracted broadcast production workflow and the VFV module, , A software-defined based broadcast production system for transmitting a query on the operation status of the VFV modules included in the broadcast production workflow to the NMOS server.
10. The method of claim 9,
The management server,
When the VFV modules included in the broadcast production workflow are in a normal state, a connection release request is transmitted to the corresponding VFV module according to a connection order of the VFV modules.
transmitting, in the management server, a video function virtualized (VFV) installation command based on a preset broadcast production workflow;
receiving, at the VFV host, the VFV installation command from the management server, and downloading and installing a corresponding VFV module according to the VFV installation command; and
In a Networked Media Open Specification (NMOS) server, when the VFV module is driven in the VFV host, obtaining detailed VFV operation information for the VFV module.

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