KR20200137865A - Method for monitoring of transfer process for boradcast content in ip based broadcasting system and apparatus using the same - Google Patents

Abstract

Disclosed are a method for monitoring transmission processing of broadcast content in an IP-based broadcasting system and an apparatus therefor. According to an embodiment of the present invention, a method for monitoring transmission processing comprises the steps of: measuring a processing time by comparing an input time and an output time for each broadcast content encapsulated in segments; and determining whether the broadcast contents are normally transmitted based on the processing time and detailed information on each broadcast content.

Description

Transmission processing monitoring method for broadcasting contents in IP-based broadcasting system, and apparatus therefor {METHOD FOR MONITORING OF TRANSFER PROCESS FOR BORADCAST CONTENT IN IP BASED BROADCASTING SYSTEM AND APPARATUS USING THE SAME}

The present invention relates to a technology for monitoring the operation of a broadcast service in an IP-based broadcast system. In particular, in a next-generation broadcast system based on ATSC 3.0, the system performance is verified by measuring and analyzing the processing time of equipment required for broadcast content transmission. It's about technology.

Next-generation broadcasting services including ATSC 3.0 transmission method aim to provide hybrid broadcasting service using broadcasting network and communication network based on IP-based transmission method. For such a broadcast communication convergence service, broadcast content has a service transmission structure in the form of a segment based on IP transmission different from the stream form of the existing MPEG-2 system.

In response to this, the broadcasting network is also evolving into an IP network and is changing to a structure that provides broadcasting communication convergence multimedia services, and by reorganizing the existing MPEG2-TS-based broadcasting system into a segment-based system, more diverse forms of convergence services are provided. You can try.

In connection with the application of such a new broadcasting system, operation verification for introducing new equipment and performance verification of a broadcast stream received through a hybrid network are also required.

Korean Patent Publication No. 10-2017-0109296, published on September 29, 2017 (Name: service verification apparatus and method in ATSC 3.0 based broadcasting system)

An object of the present invention is to verify the operation of an IP-based next-generation broadcast system and to verify the performance of a broadcast stream received through a hybrid network.

In addition, an object of the present invention is to determine whether or not broadcast content is normally transmitted by monitoring input/output segment processing time corresponding to broadcast content.

In addition, an object of the present invention is to measure processing time and delay time of equipment required for transmission of a broadcast service based on the ATSC 3.0 scheme, and to provide real-time monitoring information for this.

The transmission processing monitoring method according to the present invention for achieving the above object is a transmission processing monitoring method for broadcasting contents in a segment type corresponding to a next-generation broadcasting service, the input time for each of the broadcasting contents encapsulated in segments and Comparing the output time to measure a processing time; And determining whether the broadcast contents are normally transmitted based on the processing time and detailed information about each of the broadcast contents.

In this case, the step of measuring may check the input time and the output time based on a preset reference time scale.

In this case, the input time may correspond to a time at which the broadcast contents are input based on the input/output interface, and the output time may correspond to a time at which the broadcast contents are output based on the input/output interface.

In this case, the detailed information may include styp including information on the transmitted segment and moof, which is information about mdat representing actual media data.

In this case, the broadcast contents are segment-encapsulated and generated based on a protocol of a data link layer corresponding to ALP (ATSC 3.0 LINK-LAYER PROTOCOL), and may be in a format that can be processed by a physical layer.

In addition, the monitoring device according to an embodiment of the present invention determines the input time and output time for each of the broadcast contents encapsulated in segment units to monitor transmission processing of broadcast contents in a segment type corresponding to a next-generation broadcast service. A processor that compares, measures a processing time, and determines whether the broadcast contents are normally transmitted based on the processing time and detailed information about each of the broadcast contents; And a memory for storing the broadcast contents of each segment, the processing time, and detailed information.

In this case, the processor may check the input time and output time based on a preset reference time scale.

In this case, the input time may correspond to a time at which the broadcast contents are input based on the input/output interface, and the output time may correspond to a time at which the broadcast contents are output based on the input/output interface.

In this case, the detailed information may include styp including information on the transmitted segment and moof, which is information about mdat representing actual media data.

In this case, the broadcast contents are segment-encapsulated and generated based on a protocol of a data link layer corresponding to ALP (ATSC 3.0 LINK-LAYER PROTOCOL), and may be in a format that can be processed by a physical layer.

According to the present invention, operation verification of an IP-based next-generation broadcasting system and performance verification of a broadcast stream received through a hybrid network can be performed.

In addition, according to the present invention, it is possible to determine whether or not broadcast content is normally transmitted by monitoring an input/output segment processing time corresponding to broadcast content.

In addition, the present invention can measure the processing time and delay time of equipment required for transmission of a broadcast service based on the ATSC 3.0 scheme, and provide real-time monitoring information for this.

1 is a flowchart illustrating a transmission process monitoring method according to an embodiment of the present invention.
2 is a diagram showing an example of a segment according to the present invention.
3 is a diagram illustrating an example of an IP packet encapsulated in units of segments according to the present invention.
4 to 6 are diagrams showing exemplary operations of a transmission processing monitoring apparatus according to the present invention.
7 is a block diagram showing a monitoring device according to an embodiment of the present invention.
8 is a block diagram showing a monitoring device according to another embodiment of the present invention.

The present invention will be described in detail with reference to the accompanying drawings as follows. Here, repeated descriptions, well-known functions that may unnecessarily obscure the subject matter of the present invention, and detailed descriptions of configurations are omitted. Embodiments of the present invention are provided to more completely explain the present invention to those with average knowledge in the art. Accordingly, the shapes and sizes of elements in the drawings may be exaggerated for clearer explanation.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a flowchart illustrating a transmission process monitoring method according to an embodiment of the present invention.

Referring to FIG. 1, in a method for monitoring transmission processing for broadcast content in a segment type corresponding to a next-generation broadcast service, a processing time is measured by comparing an input time and an output time for each of the broadcast contents encapsulated in segments (S110). ).

In this case, the broadcast contents encapsulated in units of segments may mean broadcast contents in the form of segments generated for efficient data transmission in ATSC (Advanced Television System Committee) 3.0, which is a next-generation broadcast system.

In this case, the broadcast contents are segment-encapsulated and generated based on a protocol of a data link layer corresponding to ALP (ATSC 3.0 LINK-LAYER PROTOCOL), and may be in a format that can be processed by a physical layer.

For example, in ATSC 3.0, through the Data Link Layer, the Delivery/Presentation Layer, and the Service Management Layer in the delivery area of an IP-based hybrid broadcast service. Broadcast service can be delivered.

In this case, in the data link layer, all input packet types can be encapsulated in a format that can be processed in the physical layer so that the packet input corresponding to the broadcast content can be flexible and expandable.

At this time, ATSC defines ALP (ATSC 3.0 Link-layer Protocol) as a 3.0-based link layer protocol, provides link layer signaling information, efficient encapsulation of IP and MPEG-2 TS packets, and packet compression. I can. That is, the encapsulated packet may include information for processing input packets such as IP and MPEG2-TS of the network layer and mapping to a specific physical layer, and transmission efficiency may also be improved by applying various header compression and removal algorithms. .

At this time, when it is determined that the size of the network layer packet is large to be processed by the physical layer, the packet must be divided into two or more pieces to be processed. For this purpose, it is necessary to perform encapsulation in segment units as shown in FIG. There is. That is, as illustrated in FIG. 3, by encapsulating one packet into a plurality of segments 310 to 330 and mapping them to the physical layer, it may be possible to efficiently process the packet in the physical layer.

In this case, packets encapsulated using a link layer protocol defined as ALP may also be referred to as ALP packets.

In addition, in the Delivery/Presentation Layer, there are two types of UDP/IP-based Real-Time Object Delivery over Unidirectional Transport (ROUTE) and MMTP (MPEG Media Transport Protocol) for broadcasting network transmission as transport protocols for broadcast services. The method is defined, and the HTTP protocol based on TCP/IP is used for communication network transmission.

In this case, ROUTE may use a Dynamic Adaptive Streaming over HTTP (DASH) segment in ISO Base Media File Format (ISOBMFF) format, and a Media Processing Unit (MPU) may be used in MMTP.

That is, ROUTE is designed to transmit content of media streaming expressed in DASH, such as a real-time broadcasting service, using a broadcasting network, and can configure various types of media objects as LCT sessions and transmit them to Source Flow. In addition, MMTP defines an MPU encapsulation format as a media processing unit, and defines a format for signaling messages and packet delivery.

In addition, the service management layer may provide information on a service type such as a linear TV or an app service, and may provide signaling information for broadcast service acquisition and technology in a receiver.

In this case, the broadcast service may be composed of a set of several content components, and each content component may be delivered to a receiver through a terrestrial broadcasting network or a communication network. Accordingly, the service management layer may signal not only information on hybrid service configuration including configuration information of each content component, but also information delivered for each content.

At this time, ATSC 3.0 is divided into a Service List Table (SLT) for channel scan and bootstrap signaling information and Service Layer Signaling (SLS) including broadcast service configuration information.

With the introduction of a next-generation broadcasting system including such a functional layer, it is expected that the development of a headend device or a receiving terminal device constituting the system and various types of broadcasting services using respective devices will be performed.

However, there is not yet a definition of an actual data transmission method and system configuration based on this, and there is no concretely proposed method for a method of verifying and monitoring a received signal.

Accordingly, the present invention proposes a new method for verifying the performance of a next-generation broadcast service by monitoring a transmission processing process for a segment type of broadcast content.

In this case, the input time and the output time may be checked based on a preset reference time scale.

For example, the input time and the output time may use time information measured through a reference time scale such as GPS or UTC. That is, if different reference time scales are used to monitor the input time and the output time, an error may occur in the measured processing time. Therefore, the same reference time scale is applied to compare the input time and the output time, and measure and monitor the processing time.

In this case, the input time may correspond to a time at which broadcast contents are input based on the input/output interface, and the output time may correspond to a time at which broadcast contents are output based on the input/output interface.

For example, in the present invention, broadcast content input to each device constituting a broadcast system may be stored in segment units, and output content for each segment may also be stored in the broadcast content stored in segment units. In this case, an input time and an output time to be used to measure a processing time may be obtained based on an input broadcast content segment and an output content segment corresponding thereto.

In addition, the transmission process monitoring method according to an embodiment of the present invention determines whether or not broadcast contents are normally transmitted based on the processing time and detailed information about each of the broadcast contents (S120).

For example, the monitoring device according to an embodiment of the present invention may operate in the form of a browser shown in FIG. 4, wherein the browser includes an IP address setting menu 410 for setting a network IP address, an IP address setting menu. It may be composed of IP setting information 420 set through 410, a first monitoring screen 430 indicating segment operation time, and a second monitoring screen 440 indicating detailed information.

First, an Ethernet-based network IP address may be set using the IP address setting menu 410 for an input/output interface for broadcast content.

Thereafter, when the input/output interface is executed according to the IP setting information 420, the contents of the broadcast content input to the respective equipment constituting the broadcast system and the output broadcast content are stored in segments, respectively, as shown in FIG. Information including a file name and a stored packet size for each segment stored through the first monitoring screen 410 may be displayed.

In addition, on the first monitoring screen 410, as illustrated in FIG. 5, for each segment, a start time and an operation end time of a packet for a corresponding segment may be displayed. Based on this information, segment operation time or processing time is analyzed and displayed on a browser, so that it can be used to monitor whether broadcast contents are normally transmitted.

In this case, the detailed information may include styp including information on the transmitted segment and moof, which is information about mdat representing actual media data.

For example, in the second monitoring screen 440 shown in FIG. 4, as shown in FIG. 6, a styp 610 including information on a transmission segment and a moof 620 that is information about mdat representing actual media data Can be displayed by printing.

As such, it is possible to check whether the corresponding segment has been normally processed through monitoring of detailed information of the segment.

In addition, although not shown in Fig. 1, the transmission processing monitoring method according to an embodiment of the present invention stores various information generated in the transmission processing monitoring process according to an embodiment of the present invention in a separate storage module as described above. Can be saved.

Through the transmission process monitoring method according to an embodiment of the present invention, operation verification of an IP-based next-generation broadcast system and performance verification of a broadcast stream received through a hybrid network may be performed.

In addition, by monitoring the processing time of the input/output segment corresponding to the broadcast content, it is possible to determine whether or not the broadcast content has been transmitted normally, and measure the processing time and delay time of the equipment required for transmission of the broadcast service based on the ATSC 3.0 method. It can also provide real-time monitoring information.

7 is a block diagram showing a monitoring device according to an embodiment of the present invention.

Referring to FIG. 7, a monitoring device according to an embodiment of the present invention includes a communication unit 710, a processor 720, and a memory 730.

The communication unit 710 may play a role of transmitting and receiving information necessary for monitoring transmission processing of broadcast content in a segment type corresponding to a next generation broadcast service through a network such as a broadcast network or a communication network.

The processor 720 measures the processing time by comparing the input time and the output time of each of the broadcast contents encapsulated in segments to monitor transmission processing of broadcast content in the form of a segment corresponding to the next-generation broadcast service.

In this case, the broadcast contents encapsulated in units of segments may mean broadcast contents in the form of segments generated for efficient data transmission in ATSC (Advanced Television System Committee) 3.0, which is a next-generation broadcast system.

In this case, the broadcast contents are segment-encapsulated and generated based on a protocol of a data link layer corresponding to ALP (ATSC 3.0 LINK-LAYER PROTOCOL), and may be in a format that can be processed by a physical layer.

For example, in ATSC 3.0, through the Data Link Layer, the Delivery/Presentation Layer, and the Service Management Layer in the delivery area of an IP-based hybrid broadcast service. Broadcast service can be delivered.

In this case, in the data link layer, all input packet types can be encapsulated in a format that can be processed in the physical layer so that the packet input corresponding to the broadcast content can be flexible and expandable.

At this time, ATSC defines ALP (ATSC 3.0 Link-layer Protocol) as a 3.0-based link layer protocol, provides link layer signaling information, efficient encapsulation of IP and MPEG-2 TS packets, and packet compression. I can. That is, the encapsulated packet may include information for processing input packets such as IP and MPEG2-TS of the network layer and mapping to a specific physical layer, and transmission efficiency may also be improved by applying various header compression and removal algorithms. .

At this time, when it is determined that the size of the network layer packet is large to be processed by the physical layer, the packet must be divided into two or more pieces to be processed. For this purpose, it is necessary to perform encapsulation in segment units as shown in FIG. There is. That is, as illustrated in FIG. 3, by encapsulating one packet into a plurality of segments 310 to 330 and mapping them to the physical layer, it may be possible to efficiently process the packet in the physical layer.

In this case, packets encapsulated using a link layer protocol defined as ALP may also be referred to as ALP packets.

In addition, in the Delivery/Presentation Layer, there are two types of UDP/IP-based Real-Time Object Delivery over Unidirectional Transport (ROUTE) and MMTP (MPEG Media Transport Protocol) for broadcasting network transmission as transport protocols for broadcast services. The method is defined, and the HTTP protocol based on TCP/IP is used for communication network transmission.

In this case, ROUTE may use a Dynamic Adaptive Streaming over HTTP (DASH) segment in ISO Base Media File Format (ISOBMFF) format, and a Media Processing Unit (MPU) may be used in MMTP.

That is, ROUTE is designed to transmit content of media streaming expressed in DASH, such as a real-time broadcasting service, using a broadcasting network, and can configure various types of media objects as LCT sessions and transmit them to Source Flow. In addition, MMTP defines an MPU encapsulation format as a media processing unit, and defines a format for signaling messages and packet delivery.

In addition, the service management layer may provide information on a service type such as a linear TV or an app service, and may provide signaling information for broadcast service acquisition and technology in a receiver.

In this case, the broadcast service may be composed of a set of several content components, and each content component may be delivered to a receiver through a terrestrial broadcasting network or a communication network. Accordingly, the service management layer may signal not only information on hybrid service configuration including configuration information of each content component, but also information delivered for each content.

At this time, ATSC 3.0 is divided into a Service List Table (SLT) for channel scan and bootstrap signaling information and Service Layer Signaling (SLS) including broadcast service configuration information.

With the introduction of a next-generation broadcasting system including such a functional layer, it is expected that the development of a headend device or a receiving terminal device constituting the system and various types of broadcasting services using respective devices will be performed.

However, there is not yet a definition of an actual data transmission method and system configuration based on this, and there is no concretely proposed method for a method of verifying and monitoring a received signal.

Accordingly, the present invention proposes a new method for verifying the performance of a next-generation broadcast service by monitoring a transmission processing process for a segment type of broadcast content.

In this case, the input time and the output time may be checked based on a preset reference time scale.

For example, the input time and the output time may use time information measured through a reference time scale such as GPS or UTC. That is, if different reference time scales are used to monitor the input time and the output time, an error may occur in the measured processing time. Therefore, the same reference time scale is applied to compare the input time and the output time, and measure and monitor the processing time.

In this case, the input time may correspond to a time at which broadcast contents are input based on the input/output interface, and the output time may correspond to a time at which broadcast contents are output based on the input/output interface.

For example, in the present invention, broadcast content input to each device constituting a broadcast system may be stored in segment units, and output content for each segment may also be stored in the broadcast content stored in segment units. In this case, an input time and an output time to be used to measure a processing time may be obtained based on an input broadcast content segment and an output content segment corresponding thereto.

Also, the processor 720 determines whether broadcast contents are normally transmitted based on the processing time and detailed information about each of the broadcast contents.

For example, the monitoring device according to an embodiment of the present invention may operate in the form of a browser shown in FIG. 4, wherein the browser includes an IP address setting menu 410 for setting a network IP address, an IP address setting menu. It may be composed of IP setting information 420 set through 410, a first monitoring screen 430 indicating segment operation time, and a second monitoring screen 440 indicating detailed information.

First, an Ethernet-based network IP address may be set using the IP address setting menu 410 for an input/output interface for broadcast content.

Thereafter, when the input/output interface is executed according to the IP setting information 420, the contents of the broadcast content input to the respective equipment constituting the broadcast system and the output broadcast content are stored in segments, respectively, as shown in FIG. Information including a file name and a stored packet size for each segment stored through the first monitoring screen 410 may be displayed.

In addition, on the first monitoring screen 410, as illustrated in FIG. 5, for each segment, a start time and an operation end time of a packet for a corresponding segment may be displayed. Based on this information, segment operation time or processing time is analyzed and displayed on a browser, so that it can be used to monitor whether broadcast contents are normally transmitted.

In this case, the detailed information may include styp including information on the transmitted segment and moof, which is information about mdat representing actual media data.

For example, in the second monitoring screen 440 shown in FIG. 4, as shown in FIG. 6, a styp 610 including information on a transmission segment and a moof 620 that is information about mdat representing actual media data Can be displayed by printing.

As such, it is possible to check whether the corresponding segment has been normally processed through monitoring of detailed information of the segment.

The memory 730 may store broadcast contents, processing time, and detailed information in units of segments.

In addition, the memory 730 may support a monitoring function according to an embodiment of the present invention as described above. In this case, the memory 730 may operate as a separate mass storage, and may include a control function for performing the operation.

Meanwhile, a monitoring device for measuring processing time is equipped with a memory and can store information in the device. In one implementation, the memory is a computer-readable medium. In one implementation, the memory may be a volatile memory unit, and in another implementation, the memory may be a non-volatile memory unit. In one implementation, the storage device is a computer-readable medium. In various different implementations, the storage device may include, for example, a hard disk device, an optical disk device, or some other mass storage device.

By using the monitoring device according to an embodiment of the present invention, operation verification of an IP-based next-generation broadcast system and performance verification of a broadcast stream received through a hybrid network may be performed.

In addition, by monitoring the processing time of the input/output segment corresponding to the broadcast content, it is possible to determine whether or not the broadcast content has been transmitted normally, and measure the processing time and delay time of the equipment required for transmission of the broadcast service based on the ATSC 3.0 method. It can also provide real-time monitoring information.

8 is a block diagram showing a monitoring device according to another embodiment of the present invention.

Referring to FIG. 8, a monitoring device according to another embodiment of the present invention includes an input content storage unit 811, an output content storage unit 812, a processing time measurement unit 820, and a segment analysis unit 830. May be.

First, the processing time measurement unit 820 compares the input time and the output time of each of the broadcast contents encapsulated in segment units to monitor the transmission processing of the broadcast content in the form of a segment corresponding to the next-generation broadcast service. Measure

In this case, the broadcast contents encapsulated in units of segments may mean broadcast contents in the form of segments generated for efficient data transmission in ATSC (Advanced Television System Committee) 3.0, which is a next-generation broadcast system.

In this case, the input time and the output time may be checked based on a preset reference time scale.

For example, the input time and the output time may use time information measured through a reference time scale such as GPS or UTC. That is, if different reference time scales are used to monitor the input time and the output time, an error may occur in the measured processing time. Therefore, the same reference time scale is applied to compare the input time and the output time, and measure and monitor the processing time.

In this case, the input time may correspond to a time at which broadcast contents are input based on the input/output interface, and the output time may correspond to a time at which broadcast contents are output based on the input/output interface.

For example, in the present invention, broadcast content input to each device constituting a broadcast system through the input content storage unit 811 is stored in segment units, and stored in segment units through the output content storage unit 812 Output content for each broadcast content may also be stored in units of segments. In this case, an input time and an output time to be used to measure a processing time may be obtained based on an input broadcast content segment and an output content segment corresponding thereto.

The segment analysis unit 830 determines whether broadcast contents are normally transmitted based on the processing time and detailed information about each of the broadcast contents.

For example, the monitoring device according to an embodiment of the present invention may operate in the form of a browser shown in FIG. 4, wherein the browser includes an IP address setting menu 410 for setting a network IP address, an IP address setting menu. It may include IP setting information 420 set through 410, a first monitoring screen 430 indicating segment operation time, and a second monitoring screen 440 indicating detailed information.

First, an Ethernet-based network IP address may be set using the IP address setting menu 410 for an input/output interface for broadcast content.

Thereafter, when the input/output interface is executed according to the IP setting information 420, the contents of the broadcast content input to the respective equipment constituting the broadcast system and the output broadcast content are stored in segments, respectively, as shown in FIG. Information including a file name and a stored packet size for each segment stored through the first monitoring screen 410 may be displayed.

In addition, on the first monitoring screen 410, as illustrated in FIG. 5, for each segment, a start time and an operation end time of a packet for a corresponding segment may be displayed. Based on this information, segment operation time or processing time is analyzed and displayed on a browser, so that it can be used to monitor whether or not broadcast contents are normally transmitted.

In this case, the detailed information may include styp including information on the transmitted segment and moof, which is information on mdat indicating actual media data.

For example, in the second monitoring screen 440 shown in FIG. 4, as shown in FIG. 6, a styp 610 including information on a transmission segment and a moof 620 that is information about mdat representing actual media data Can be displayed by printing.

As such, it is possible to check whether the corresponding segment has been normally processed through monitoring of detailed information of the segment.

As described above, the method and apparatus for monitoring transmission processing of broadcast content in the IP-based broadcasting system according to the present invention are not limited to the configuration and method of the embodiments described as described above, but the implementation. Examples may be configured by selectively combining all or part of each embodiment so that various modifications may be made.

310~330: segment 410: IP address setting menu
420: IP setting information 430: first monitoring screen
440: second monitoring screen 510~540: segment time information
610: styp 620: moof
710: communication unit 720: processor
730: memory 811: input content storage unit
812: output content storage unit 820: processing time measurement unit
830: segment analysis unit

Claims (1)

In the transmission processing monitoring method for broadcast content in a segment type corresponding to a next-generation broadcast service,
Measuring a processing time by comparing an input time and an output time for each of the broadcast contents encapsulated in segments; And
Determining whether the broadcast contents are normally transmitted based on the processing time and detailed information about each of the broadcast contents
Transmission process monitoring method comprising a.

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