KR102147145B1 - Apparatus and method for receiving video service in hybrid network - Google Patents

Abstract

In a hybrid network, a receiving terminal receives a video stream through the broadcasting network. The receiving terminal receives a high-speed video stream streamed at high speed for a predetermined first period from the first time when switching from the broadcasting network to the communication network is determined according to the reception state of the broadcasting network, and streams live from any one of the first periods. A live video stream is received, and a continuous video stream is generated using the video stream received through a broadcasting network, the high-speed video stream, and the live video stream.

Description

Device and method for receiving video service in hybrid network {APPARATUS AND METHOD FOR RECEIVING VIDEO SERVICE IN HYBRID NETWORK}

The present invention relates to an apparatus and method for receiving a video service in a hybrid network, and more particularly, to an apparatus and method for receiving a video service for continuously providing a video service through a communication network when the reception state of a broadcasting network is poor.

A network that combines a broadcasting network and a communication network is called a hybrid network, and a service provided through a hybrid network is called a broadcast communication convergence service. In order to construct such a hybrid network, functions such as broadcast reception of a terminal, two-way communication, stream synchronization between heterogeneous networks, and linkage services are required. In the broadcasting service provided by the broadcasting network, hybrid broadcasting for providing a streaming service through convergence of a broadcasting network and a communication network, various types of additional services, and an additional module for linking wireless communication and methods for controlling the same are being studied.

For example, a broadcasting device such as a DMB receiving terminal is a mobile receiving device. However, when the reception environment rapidly deteriorates, such as when a user enters a broadcasting reception disorder or a broadcasting reception impossible area while moving, a phenomenon in which the broadcasting reception rate is significantly lowered may occur frequently, and in this case, it is difficult to reproduce DMB broadcasting contents normally. In this situation, it is also necessary to develop a technology necessary to provide a video-linked service that provides a seamless DMB service using a hybrid network.

When a video stream can be received from each of the broadcasting network and the communication network, a service may be provided by simply selecting a network receiving the stream, but such a simple switching method is difficult to provide a service without interruption.

The problem to be solved by the present invention relates to an apparatus and method for receiving a video service in a hybrid network capable of providing a seamless video service through a communication network when the reception state of a broadcasting network is not good.

According to an embodiment of the present invention, a method for receiving a video service by a receiving terminal in a hybrid network is provided. The method for receiving a video service includes receiving a video stream through the broadcasting network, receiving a high-speed video stream streamed at a rate higher than the original bit rate for a predetermined first period from a first time when switching from the broadcasting network to the communication network is determined. Receiving a live video stream streamed at an original bit rate from any one point in the first period, a continuous video stream using the video stream received through the broadcasting network, the high speed video stream, and the live video stream And decoding the continuous video stream.

Receiving the live video stream may include receiving the live video stream from the one point in time until a second point in time when switching to the broadcasting network is determined from the communication network.

The first period may be shorter than a period from any one point in time to the second point in time.

The video service reception method may further include requesting to stop receiving the live video stream at the second point in time.

Each of the video stream received through the broadcasting network, the high-speed video stream, and the live video stream may include timestamp time information, and the step of generating the continuous video stream includes the video stream received through the broadcasting network and the And generating the continuous video stream using the high speed video stream and each time stamp time of the live video stream.

The receiving of the high-speed video stream may include receiving a video stream from a position prior to the position of the video stream received through the broadcasting network at the first time point.

The one point in time may be the same as the first point in time or a point in time later than the first point in time.

Receiving a video stream through the broadcasting network includes receiving a packet stream corresponding to a video stream through the broadcasting network, and packet decoding the packet stream to generate the video stream, the high-speed video stream The receiving of may include determining the first time point based on a result of packet decoding of the packet stream.

The receiving of the live video stream may include determining a time point at which reception of the live video stream is stopped based on a result of packet decoding of the packet stream.

According to another embodiment of the present invention, an apparatus for receiving a video service of a receiving terminal in a hybrid network is provided. The video service receiving apparatus includes a broadcast reception processing unit, a high-speed streaming processing unit, a live streaming processing unit, a video stream selection control unit, and a video stream decoder. The broadcast reception processing unit receives a packet stream corresponding to a video stream through a broadcast network. The high-speed streaming processing unit requests and receives a packet stream corresponding to a high-speed video stream streamed at a first bit rate for a predetermined first period from a first point in time when switching from a broadcasting network to a communication network is determined. The live streaming processing unit is a packet corresponding to a live video stream streamed at a second bit rate slower than the first bit rate from any one point in the first period to a second point in time when switching from the communication network to the broadcasting network is determined. Request and receive streams. The video stream selection control unit generates a continuous video stream using the video stream, the high-speed video stream, and the live video stream. And the video stream decoder decodes the continuous video stream.

The video stream selection control unit may determine the first view point and the second view point, and control the high-speed streaming processing unit and the live streaming processing unit.

The video service receiving apparatus may further include a first packet decoder for generating the video stream by packet decoding a packet stream corresponding to the video stream, wherein the video stream decoder receives a packet decoding result of the first packet decoder. Based on the first viewpoint and the second viewpoint may be determined.

The video service receiving apparatus includes a second packet decoder configured to packet-decode a packet stream corresponding to the live video stream to generate the live video stream, and packet-decode the packet stream corresponding to the high speed video stream to obtain the high speed video stream. It may further include a third packet decoder to generate.

The video stream decoder may determine the one time point as the same as the first time point or later than the first time point.

The high-speed streaming processor may request streaming from a video stream at a position earlier than a position of a video stream received through the broadcasting network at the first time point under control of the video stream decoder.

The video stream decoder may request streaming from a video stream at a position of a video stream received through the broadcasting network at any one time under control of the stream selection controller.

Each of the video stream, the high-speed video stream, and the live video stream received through the broadcasting network may include timestamp time information, and the video service receiving apparatus includes the video stream and the high-speed video stream received through the broadcasting network. It may further include a stream time comparison unit comparing each time stamp time of the live video stream, and transmitting the comparison result to the stream selection control unit.

The live streaming processor may request to stop receiving the live video stream at the second time point.

The first period may be a period shorter than a period from any one point in time to the second point in time.

The video service receiving apparatus may further include first to third video stream buffers respectively buffering the video stream, the live video stream, and the high-speed video stream.

According to an embodiment of the present invention, in the case of temporary high-speed streaming, a continuous stream is provided by individually processing the request of each receiving terminal in a unicast method, but in live streaming, the same stream can be provided in a unicast method as well as multicast. B. Since it can be provided in a broadcast method, it is possible to provide a continuous video service during network switching while reducing the network load.

1 is a diagram showing a video service transmission apparatus in a hybrid network according to an embodiment of the present invention.
2 is a diagram illustrating an apparatus for receiving a video service in a hybrid network according to an embodiment of the present invention.
4 is a diagram showing an example of receiving a continuous video stream using a streaming method according to an embodiment of the present invention.
4 is a diagram illustrating another example of receiving a continuous video stream using a streaming method according to an embodiment of the present invention.
5 is a flowchart illustrating a video service receiving method according to an embodiment of the present invention.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those of ordinary skill in the art may easily implement the present invention. However, the present invention may be implemented in various forms and is not limited to the embodiments described herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and similar reference numerals are assigned to similar parts throughout the specification.

Throughout the specification and claims, when a certain part "includes" a certain component, it means that other components may be further included rather than excluding other components unless otherwise stated.

Now, an apparatus and method for receiving a video service in a hybrid network according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 is a diagram showing a video service transmission apparatus in a hybrid network according to an embodiment of the present invention.

Referring to FIG. 1, the video service transmission apparatus 100 includes packet encoders 112 and 114, packet buffers 122 and 124, packet DB 130, broadcast transmitter 140, high-speed streaming server 150, and live It includes a streaming server 160.

The packet encoders 112 and 114 respectively generate packet streams (A, B) by encoding a video stream source using a packet encoding method, and transmit the packet streams (A, B) to the packet buffers 122 and 124, respectively. . Also, the packet encoder 112 transmits the packet stream A to the packet DB 130.

Packet encoding refers to packetizing and packet multiplexing of a video stream source. Video stream sources include compressed video and audio frames. That is, video and audio frames are compressed through video encoding and input to the packet encoders 112 and 114.

The packet encoders 112 and 114 may use the same packet encoding method or different packet encoding methods.

The packet buffers 122 and 124 buffer the input packet streams A and B, respectively. In particular, the packet buffer 124 controls the delay time of the packet stream B according to the buffering time of the packet buffer 122 to synchronize the output time of the stream provided through the broadcasting network and the stream provided through the streaming of the communication network. Provides. In general, when a video stream is provided through a broadcasting network, a delay occurs due to the characteristics of the broadcasting network. Therefore, a function of adjusting a time difference between a stream transmitted through a broadcasting network and a stream provided in a live streaming of a communication network is required, and a function of adjusting this time difference is set in the packet buffer 124. That is, the packet buffer 124 sets a delay time corresponding to the buffering time of the packet buffer 122, delays the packet stream B by the delay time, and outputs the stream transmitted to the broadcasting network and the live streaming of the communication network. Minimizes the difference in output time of the provided stream.

The packet DB 130 stores the input packet stream A. The packet DB 140 finds a packet stream corresponding to a location of a packet stream individually requested by each receiving terminal connected to the high-speed streaming server 150 and transmits it to the high-speed streaming server 140.

The broadcast transmission unit 140 transmits the packet stream A buffered in the packet buffer 122 through a broadcast network. The broadcast transmission unit 140 constructs a transport frame from the input packet stream A, modulates the transport frame into a broadcast signal, and transmits it through a broadcast network. The transmission frame may be composed of a plurality of input packet streams (A). The broadcast transmission unit 140 may generate a packet stream having a fixed bit rate by stuffing the packet stream A. The broadcast transmitter 140 may perform outer encoding on the packet stream A to improve reception performance of a video service.

When the high-speed streaming server 150 receives a high-speed streaming request from the receiving terminal, the packet stream A stored in the packet DB 130 is encoded as an IP streaming packet, and the IP streaming packet is the original bit rate rate of the packet stream A. It is a server that streams at a faster rate. The original bit rate refers to the speed at which the original speed can be reproduced without overflow or underflow of the buffer during reproduction.

The high-speed streaming server 150 temporarily streams an IP streaming packet at a high bit rate at the initial stage of network switching in order to provide a continuous stream without interruption when switching a network from a broadcasting network to a communication network. The high-speed streaming server 150 individually processes the streaming request of each receiving terminal and IP-streams the packet stream to each receiving terminal in a unicast manner.

The high-speed streaming server 150 may perform streaming by encoding the packet stream into an IP streaming packet from the position of the packet stream individually requested by each receiving terminal. In addition to this method, the high-speed streaming server 150 may use various streaming methods. However, the high-speed streaming server 150 provides streaming at the highest speed capable of stably receiving streaming without errors according to the situation of the communication network to which each receiving terminal is connected.

In general, time stamp information is included in a packet stream, such as a program clock reference (PCR) of an MPEG-2 transport stream (TS), as well as a video or audio frame. The time stamp information corresponds to a specific position in the packet stream. Therefore, time stamp information may be used as the location information of the packet stream individually requested by each receiving terminal.

In addition, when the high-speed streaming server 150 encodes and transmits packets in a format different from the packet format used in the broadcasting network, the location information of the packet stream requested from each receiving terminal to the high-speed streaming server 150 is a time stamp of the packet stream. It can be used as a time stamp of video and audio frames included in the packet stream, not information. In this case, the packet DB 140 maps and stores the time stamp of the packet stream and the time stamp of the video and audio frames included in the packet stream so that the location of the requested packet stream can be quickly searched.

The live streaming server 160 is a server that encodes the packet stream (B) into an IP streaming packet and outputs the IP streaming packet by streaming at the original bit rate of the packet stream (B).

The live streaming server 160 receives the packet stream B to be output when the receiving terminal requests the stream from the packet buffer 124 and outputs the streaming.

The live streaming server 160 may IP-stream the same stream to each receiving terminal in a unicast manner, as well as IP-stream the same packet stream to a plurality of receiving terminals simultaneously in a multicast or broadcast manner.

2 is a diagram illustrating an apparatus for receiving a video service in a hybrid network according to an embodiment of the present invention.

Referring to FIG. 2, the video service reception device 200 is a reception terminal, and includes a broadcast reception processing unit 210, a high-speed streaming processing unit 220, a live streaming processing unit 230, a packet decoder 242, 244, 246, and video. Stream buffers 252, 254, 256, a video stream time comparison unit 260, a video stream selection control unit 270, and a video stream decoder 280 are included.

The broadcast reception processing unit 210 receives a broadcast signal and outputs a packet stream C from the broadcast signal. The packet stream C of the broadcast reception processing unit 210 is the same as the packet stream A transmitted through the broadcasting network of FIG. 1.

The packet decoder 242 corresponds to the packet encoder 110 of FIG. 1 and decodes and outputs the packet stream C using a packet decoding method. The output of the packet decoder 242 are video frames and audio frames of a video stream source. Hereinafter, for convenience of description, the output of the packet decoder 242 is referred to as a video stream.

The video stream buffer 252 buffers a video stream decoded by the packet decoder 242 to secure a time to ensure continuity of a video stream due to a delay in a communication network when switching a network from a broadcasting network to a communication network and to decode a stable video stream.

The video stream buffer 252 may have a buffering time longer than that of a buffer for decoding a general video stream. However, the video stream buffer 252 may limit the buffering time within a limited range of about 1 to 2 seconds in consideration of the network switching time.

The high-speed streaming processing unit 220 accesses the high-speed streaming server 150 and requests a video stream when it is determined to switch the network from the broadcasting network to the communication network due to poor reception of the broadcasting network.

The high-speed streaming processing unit 220 may request a video stream to receive high-speed streaming from a video stream at a position required for continuous video service provision. The high-speed streaming processing unit 220 may set a position of a video stream requested to provide a continuous video service to a position prior to a position of a video stream received through a broadcasting network at the time of network switching determination. In this way, a video stream received through a broadcasting network and a video stream received through a communication network partially overlap.

The high-speed streaming processing unit 220 receives the IP streaming packet transmitted by high-speed streaming according to the request, decodes the IP streaming packet into a packet stream D, and transmits it to the packet decoder 246.

An error may occur in some of the received video streams because the state of the broadcasting network signal is already unstable prior to the decision to switch the network from the broadcasting network to the communication network. Therefore, if the high-speed streaming processing unit 220 requests streaming from a video stream at a position earlier than the position of the video stream received through the broadcasting network at the time of network switching decision, the broadcast video stream in which an error has occurred is received by IP streaming of the communication network. By replacing it with a stream, it is possible to guarantee the quality of the video service.

The packet decoder 246 decodes the packet stream D into a video stream and transmits it to the video stream buffer 256.

The video stream buffer 256 buffers the video stream decoded by the packet decoder 246.

The live streaming processor 230 may request a video stream after the stream request point of the high-speed streaming processor 220. In addition, the live streaming processor 230 may request a video stream at the same time as the stream request time of the high-speed streaming processor 220 if the throughput of the communication network is sufficient according to the state of the communication network. In this case, as the request of the live streaming processing unit 230 is delayed, the high-speed streaming reception time of the high-speed streaming processing unit 220 may be relatively longer.

The live streaming processing unit 230 receives the IP streaming packet transmitted through live streaming, decodes the IP streaming packet into a packet stream E, and delivers it to the packet decoder 244.

As mentioned above, the packet stream B may be the same as the packet stream A or may be a different type of packet stream. When the packet stream (A) and the packet stream (B) are the same packet stream, the packet decoder 244 is the same as the packet decoder 242, and if different, a packet decoder conforming to the corresponding packet encoding standard may be used.

The packet decoder 244 decodes the packet stream E received through the communication network into a video stream and outputs it to the video stream buffer 254.

The video stream buffer 254 buffers the video stream decoded by the packet decoder 244.

The video stream buffers 252, 254, and 256 described above store video and audio frames of the same video stream source, and the video stream buffers 252, 254, and 256 each store time information of the buffered video stream, that is, a time stamp. The information is transferred to the video stream time comparison unit 260.

The video stream time comparison unit 260 compares the time stamp times of the video streams stored in each of the video stream buffers 252, 254, 256, and selects a video stream buffer and a video stream necessary to provide a continuous service. Pass it to (270).

The video stream selection control unit 270 controls the output of the video stream buffers 252, 254, 256 based on the buffer information and the video stream information transmitted from the video stream time comparison unit 260 to convert a continuous video stream into a video stream decoder. Provided to (280).

The video stream decoder 280 decodes and outputs a continuous video stream.

A continuous video stream is received through the broadcasting network before the network switch from the broadcasting network to the communication network is determined. The video stream selection control unit 270 may determine network switching from a broadcasting network to a communication network based on a packet decoding result of the packet stream D received through the broadcasting network. That is, the video stream selection control unit 270 may determine to switch the network from the broadcasting network to the communication network when continuous frames are not configured due to a packet decoding error of the packet decoder 242. The video stream selection control unit 270 controls the high-speed streaming processing unit 220 and the live streaming processing unit 230 to request streaming reception when it is determined to switch the network from the broadcasting network to the communication network.

Also, after the network switching from the broadcasting network to the communication network is determined, the video stream selection control unit 270 may determine the network switching from the communication network to the broadcasting network based on a packet decoding result of the packet stream D received through the broadcasting network. The video stream selection control unit 270 controls the live streaming processing unit 230 to request to stop receiving streaming when the communication network determines to switch the network back to the broadcasting network.

Since the streaming reception of the high-speed streaming processing unit 220 is temporarily performed at the time when the network switching is determined, the video stream selection controller 270 controls only the live streaming processing unit 230 when the network switching from the communication network to the broadcasting network is determined.

When the receiving terminal receives the streaming through the communication network, a delay time occurs due to the initial request/response process and network latency. In order to compensate for this delay time, the high-speed streaming server 150 of the video service transmission device 100 streams and outputs the stream at a higher rate than the original bit rate, and the video stream decoder 280 provides the video stream transmitted by high-speed streaming. Until received, the video stream stored in the video stream buffer 252 is decoded, thereby providing a seamless video service in temporal and scene terms.

As described above, the buffering time of the video stream buffer 252 should be set longer than the time from the high-speed streaming request to the high-speed streaming reception in order not to be temporally interrupted, but the longer the buttering time, the longer the channel switching time. Accordingly, the buffering time of the video stream buffer 252 may be appropriately set in consideration of a time from a high-speed streaming request to a high-speed streaming reception. At this time, the continuity of the scene can be guaranteed at any time because a continuous position is requested and received.

3 is a diagram showing an example of receiving a continuous video stream using a streaming method according to an embodiment of the present invention.

Referring to FIG. 3, frames (F _i-4 , F _i-3 , …, F _i , F _i+1 ,…, F _i+3 ,…) received through the broadcasting network are transferred to the video stream buffer 252. Is entered.

It is assumed that an error occurs in frames (F _i-2 , F _i , F _i+2 ) decoded by the packet decoder 242 because the reception state of the broadcast signal is poor.

The video stream selection control unit 270 checks the continuity of the normally decoded frame based on the packet decoding result of the packet decoder 242. The video stream selection control unit 270 checks that there is an error in the frame (F _i-2 , F _i , F _i+2 ) and determines the time point (T1) corresponding to the frame (F _i ) in which the error occurs in the broadcasting network. It can be determined by the time of network switchover.

The high-speed streaming processing unit 220 requests high _- speed streaming from the frame F _i-3 3 frames earlier than the position of the frame F _i at the time point T1 under the control of the video stream selection controller 270. Streaming request location is determined based on the frame (F _i-2) an error occurs, and can be made to the location of the previous frame of the error frame (F _i-2).

The high-speed streaming processing unit 220 starts reception from the frame F _i-3 after the network delay time after the request, and the received frames are buffered in the video stream buffer 256. The high-speed streaming processing unit 220 may request high-speed streaming from the frame (F _i-3 ) to the frame (F _i+4 ), and the frames (F _i-3 to F _i+4 ) are in the video stream buffer 256. Is buffered.

Next, live streaming processor 230, live streaming from the frame (F _{i + 2)} at the time (T1) after the frame (F _{i + 2),} the time (T2) corresponding to the control of the video stream, selection controller 270 Can be requested. The live streaming processing unit 230 starts reception from a frame (F _i+2 ) after a network delay time after the live streaming request, and the received frames (F _i+2 , …) are buffered in the video stream buffer 254. .

The streaming bit rate rate of the high-speed streaming server 150 is faster than the streaming bit rate rate of the live streaming server 160, so the reception time of each frame received from the high-speed streaming server 150 is the reception of the frame received from the live streaming server 160. It is shorter than the time and the buffer input speed is also faster than the live streaming server 160.

Next, the video stream time comparison unit 260 compares the time stamp times of frames stored in each of the video stream buffers 252, 254, and 256 to provide the necessary buffer information and frame information to enable continuous service provision. Transferred to 270, the video stream selection control unit 270 selects a continuous frame sequence from each buffer and outputs it to the video stream decoder 280.

As described above, at the time T1 when network switching is determined, a normal frame stored in the video stream buffer 252 is input to the video stream decoder 280, and an error occurs while the normal frame is reproduced by the video stream decoder 280. Since frames are quickly received through a communication network, the video stream decoder 280 can provide a seamless video service.

4 is a diagram illustrating another example of receiving a continuous video stream using a streaming method according to an embodiment of the present invention.

Referring to FIG. 4, after network switching from a broadcasting network to a communication network, a video service without interruption in time or scene is provided through a method as described in FIG. 3.

When the state of reception of the broadcast signal improves, it is decided to switch from the communication network back to the broadcast network. The video stream selection control unit 270 may determine to switch from the communication network back to the broadcasting network if an error does not occur in the frame continuously based on the packet decoding result of the packet decoder 242. For example, when an error does not occur continuously from the frame F _{j -2} of the video stream buffer 252, the video stream selection control unit 270 selects a time point T3 corresponding to the frame F _j It can be determined as the point of time to switch from the communication network to the broadcasting network again.

The live streaming processing unit 230 requests to stop receiving live streaming at a time point T3 under the control of the video stream decoder 280. The live streaming processing unit 230 receives up to the frame F _j through live streaming according to a request to stop receiving live streaming.

Then, the stream selection control unit 270 selects a frame of the video stream buffer 252 from after the frame F _j or the frame F _j and outputs it to the video stream decoder 280.

5 is a flowchart illustrating a video service receiving method according to an embodiment of the present invention.

Referring to FIG. 5, the video service receiving apparatus 200 receives packet streams through a broadcast signal through a broadcast network, decodes the received packet streams, and buffers the received packet streams in the video stream buffer 252 (S500).

The video service receiving apparatus 200 provides a video service by decoding the video stream buffered in the video stream buffer 252.

Meanwhile, when an error occurs during packet decoding due to a poor reception state of a broadcast signal, the video service receiving apparatus 200 determines network switching from a broadcast network to a communication network (S510).

The video service receiving device 200 requests the video service transmitting device 100 to receive high-speed streaming for a packet stream at a predetermined location at the time of network switching from a broadcasting network to a communication network (S520).

The video service receiving apparatus 200 receives the packet stream at a corresponding location transmitted through high-speed streaming, packet decodes the received packet streams, and buffers the received packet streams in the video stream buffer 256 (S530). The video service reception device 200 may request high-speed streaming reception only for a predetermined period from the time of network switching.

In addition, the video service reception device 200 requests the video service transmission device 100 to receive a live streaming for a packet stream at a predetermined location at a time point when switching a network from a broadcasting network to a communication network or after it (S540).

The video service receiving apparatus 200 receives the packet stream at a corresponding location transmitted through high-speed streaming, packet decodes the received packet streams, and buffers the received packet streams in the video stream buffer 254 (S550). The video service reception device 200 may request live streaming reception until a network switchover from a communication network to a broadcasting network is determined.

The video service receiving apparatus 200 compares the time stamp times of the streams stored in each of the video stream buffers 252, 254, and 256 to generate a temporally continuous video stream (S560), and decodes them (S570).

Meanwhile, when the reception state of the broadcast signal is improved again, the video service receiving device 200 determines network switching from the communication network to the broadcast network (S580).

When it is determined to switch the network from the communication network to the broadcasting network, the video service reception device 200 requests to stop receiving live streaming (S590). Then, a continuous video stream is generated by using the video stream buffered in the video stream buffer 252 from then on.

The embodiments of the present invention are not implemented only through the apparatus and/or method described above, but may be implemented through a program realizing a function corresponding to the configuration of the embodiment of the present invention or a recording medium in which the program is recorded, Such implementation can be easily implemented by an expert in the technical field to which the present invention belongs from the description of the above-described embodiment.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concept of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Claims (20)

As a method of receiving video service of a receiving terminal in a hybrid network,
Receiving a first video stream corresponding to a video stream source provided by a video service transmission device through a broadcasting network,
The video service transmission device receives, through the communication network, a high-speed video stream for streaming the first video stream at a rate faster than the original bit rate for a predetermined first period from a first point in time when switching from the broadcasting network to the communication network is determined. step,
Receiving, by the video service transmission device, a live video stream streaming a second video stream corresponding to the video stream source at an original bit rate through the communication network from any one point in the first period,
Generating a continuous video stream using the first video stream received through the broadcasting network, the high-speed video stream received through the communication network, and the live video stream, and
Decoding the continuous video stream
Video service receiving method comprising a. In claim 1,
The receiving of the live video stream through the communication network includes receiving the live video stream from the one point in time until a second point in time when switching from the communication network to the broadcasting network is determined. In paragraph 2,
The first period is shorter than a period from the one point in time to the second point in time. In paragraph 2,
Requesting to stop receiving the live video stream at the second time point
Video service receiving method further comprising a. In claim 1,
Each of the first video stream, the high-speed video stream, and the live video stream received through the broadcasting network includes timestamp time information,
The step of generating the continuous video stream includes generating the continuous video stream using the first video stream received through the broadcasting network, the high-speed video stream, and each time stamp time of the live video stream. How to receive video services. In claim 1,
The receiving of the high-speed video stream through the communication network includes receiving a video stream at a position prior to the position of the first video stream received through the broadcasting network at the first time point. In claim 1,
The method of receiving a video service in which the one point of time is the same as the first point of time or later than the first point of view. In claim 1,
Receiving the first video stream through a broadcasting network
Receiving a packet stream corresponding to the first video stream through the broadcasting network, and
Packet decoding the packet stream to generate the first video stream,
The receiving of the high-speed video stream through the communication network includes determining the first time point based on a packet decoding result of the packet stream. In clause 8,
The receiving of the live video stream through the communication network includes determining a time point of stopping reception of the live video stream based on a packet decoding result of the packet stream. As a video service receiving device of a receiving terminal in a hybrid network,
A broadcast reception processing unit for receiving a packet stream provided by packetizing a first video stream corresponding to a video stream source in a video service transmission device through a broadcast network,
The video service transmission device transmits a packet stream corresponding to a high-speed video stream for streaming the first video stream at a first bit rate through the communication network for a predetermined period from a first time point when it is determined to switch from the broadcasting network to the communication network. High-speed streaming processing unit to receive,
The video service transmission apparatus transmits a packet stream corresponding to a live video stream for streaming a second video stream corresponding to the video stream source at a second bit rate slower than the first bit rate from any one point in the first period. A live streaming processing unit for receiving through the communication network until a second point in time when switching from the communication network to the broadcasting network is determined,
A video stream selection control unit for generating a continuous video stream using the video stream, the high-speed video stream, and the live video stream, and
A video stream decoder for decoding the continuous video stream
Video service receiving device comprising a. In claim 10,
The video stream selection control unit determines the first view point and the second view point, and controls the high-speed streaming processing unit and the live streaming processing unit. In clause 11,
A first packet decoder for generating the first video stream by packet decoding a packet stream corresponding to the first video stream
Including more,
The video stream decoder determines the first view point and the second view point based on a packet decoding result of the first packet decoder. In claim 12,
A second packet decoder for packet decoding a packet stream corresponding to the live video stream to generate the live video stream, and
A third packet decoder for generating the high speed video stream by packet decoding a packet stream corresponding to the high speed video stream
A video service receiving device further comprising. In claim 10,
The video stream decoder determines the one point of time to be the same as the first point of view or a point of time later than the first point of view. In claim 10,
The video service receiving apparatus, wherein the high-speed streaming processor requests streaming from a video stream at a position earlier than a position of a first video stream received through the broadcasting network at the first time point under control of the video stream decoder. In claim 10,
The video stream decoder requests streaming from a video stream corresponding to a position of a first video stream received through the broadcasting network at any one point in time under the control of the stream selection controller. In claim 10,
Each of the first video stream, the high-speed video stream, and the live video stream received through the broadcasting network includes timestamp time information,
A stream time comparison unit that compares each time stamp time of the first video stream received through the broadcasting network with the high-speed video stream and the live video stream, and delivers the comparison result to the stream selection control unit
A video service receiving device further comprising. In claim 10,
The video service receiving device requests that the live streaming processing unit stop receiving the live video stream at the second point in time. In claim 10,
The first period is shorter than a period from the one point in time to the second point in time. In claim 10,
First to third video stream buffers respectively buffering the first video stream, the live video stream, and the high-speed video stream
A video service receiving device further comprising.

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