KR101211768B1 - Data segmentation device and method and data merging device and method for harmonic broadcasting method using time-divided video data - Google Patents

Abstract

PURPOSE: A data segmentation device and a method and a data merging device and a method for harmonic broadcasting method using time-divided video data are provided to reduce resource occupancy, the complexity of a receiving device and process load of a server by dividing data into pieces of data according to time. CONSTITUTION: A data division unit(611) divides one of segments into a lower segment. A segment is generated by time division of a video data according to a predetermined time period. A lower segment providing unit(612) provides lower rank segments. The data division unit arranges bits to the lower segment in order to keep the continuity of the bits included in at least one segment. [Reference numerals] (611) Data division unit; (612,621) Lower segment providing unit; (622) Segment connection unit

Description

TECHNICAL DATA SEGMENTATION DEVICE AND METHOD AND DATA MERGING DEVICE AND METHOD FOR HARMONIC BROADCASTING METHOD USING TIME-DIVIDED VIDEO DATA

Embodiments of the present invention relate to a data splitting apparatus and method and a data combining apparatus and method for a partial channel transfer method of time division video data.

The digital broadcasting service market is evolving from operator-oriented passive broadcasting service to user-demand service that enables two-way communication. Recently, as the barriers of the broadcasting and telecommunications industry have disappeared, the distribution of interactive contents in the form of Video on Demand (VoD) is spreading in the broadcasting market, which used to be a real-time channel. The reason is that anyone can produce and supply contents through the development of high definition, digitalization and communication environment of broadcasting, and it is possible to consume contents through video files anytime and anywhere. In particular, content consumers who are familiar with the Internet are leading the way to active content usage environments such as VoD services. With the digitalization of broadcasting, the convergence of broadcasting communication, and the change of viewing method, pay broadcasting such as digital cable TV and IPTV (Internet Protocol Television) are developing VoD service into a new service model.

There are two major considerations for broadcasters to provide VoD services. First, since VoD content is a collection of large-capacity data including video and audio, a large amount of data must be transmitted at the time of service provision, so sufficient bandwidth must be secured. In order to secure such bandwidth, service providers must spend a considerable amount of money for network enhancement such as frequency acquisition and cell division of subscriber networks. Second, the waiting time for watching the requested VoD content should be minimized. The existing pay per view (PPV) service broadcasts content at a scheduled delivery time, and users have to wait for a certain time to watch the content. However, users want to watch the selected content immediately, and service providers have to spend a lot of money to meet this demand.

As a conventional technique for solving this problem, methods for efficiently delivering VoD services have been proposed. In general, VoD is classified into TVoD (True VoD) and NVoD (Near VoD) according to service type. Since TVoD provides users with instant service in a point-to-point fashion, TVoD has the advantage of reducing the waiting time for users.However, since it provides individual contents to users, the bandwidth required when user requests increase There is a disadvantage to increase. NVoD has the advantage of increasing the bandwidth efficiency by delivering the content at regular intervals, but has a disadvantage in that the user's waiting time is longer than TVoD. As a method of improving viewing latency, which is a disadvantage of the NVoD service, there is a method of dividing and transmitting VoD content at a transmitting side and storing segments which are divided and transmitted using a storage device at a receiving side. For example, the Hybrid Harmonic Staggered Broadcasting method divides the video into short and long parts, transmits by applying a harmonic transmission method to the short front part and a staggered transmission method to the long part. That's the way. At this time, each part periodically transmits repeatedly through broadcast, and transmits the repetition period of the staggered transmission method to match the period of the harmonic transmission method.

Among the NVoD methods, pyramid broadcasting method and fast broadcasting method are characterized in that the server side divides the data by only time axis and transmits it periodically to transmit VoD contents to subscribers. . On the other hand, the staircase broadcasting method, the harmonic broadcasting method, and the hybrid harmonic staggered method not only divide the VoD content data into the time axis at the server side but also use the bit rate axis (Bit-). It is characterized by transmitting each segment to the partial channel after performing the second division by rate axis).

1 is a diagram illustrating a harmonic data partitioning method according to the prior art. First, the first graph 110 performs time division over time of the short preceding part D _a among the VoD content data divided into the short preceding part D _a and the long trailing part according to the harmonic method with a period of 'd'. Thus, the first time division is shown by four segments of 'S ₁ ', 'S ₂ ', 'S ₃ ', and 'S ₄ '. As shown in the first graph 110, the second graph 110 divides the segments divided by the first time division into bit rates according to the bit rate axis, which is the y-axis, and then divides the data into second segments. .

However, when implementing a server function, dividing the time-divided data back into the bit rate has a disadvantage of increasing process load and complexity. In addition, when the VoD content data is divided at a bit rate, there is a problem in that a continuous bit stream of data is distributed to each segment so that bit continuity of existing data cannot be maintained. In particular, when implementing the function of the receiving side, when receiving data segments divided by the bit rate axis and performing recombination into one content, all the divided segments are simultaneously read into the memory to restore the continuity of the bit stream scattered into the respective segments. There is a problem that a parallel joining process must be performed. This increases the resource occupancy and process load of the receiving device, which causes a problem of viewing delay. The problems are also a major factor in raising device prices.

In the present specification, an apparatus and method for more effectively providing a VoD service are proposed.

When segmenting video data, do not apply additional partitioning scheme to the complex bit rate, perform primary partitioning to divide the data according to time, and then apply the segments recursively using the same partitioning method. By finer partitioning, we can reduce server-side process load, resource occupancy, and complexity, while simultaneously mapping secondary time-divisioned data segments to partitioned data segments on a logical channel that is planned in the same way as conventional partial channel transmission. An apparatus and method are proposed that can maintain the effects of partial channel transmission, such as adjusting the latency of a viewer and the amount of buffer required.

When the receiving side receives the divided data segments and performs recombination into one original content, since each segment has sequential bit continuity between the segments, only the simplest method of combining the next-order segments after the current segment is used. By recombining, an apparatus and method for reducing resource occupancy and complexity are proposed because the receiving apparatus does not perform a process of simultaneously multiplexing a plurality of sub-segments at the same time.

A data dividing apparatus for dividing video data transmitted from a transmitting apparatus to a receiving apparatus, the data dividing apparatus further time-dividing at least one of the segments generated by time-dividing the video data with a predetermined period according to time. A data partitioning apparatus is provided that includes a subsegment providing unit that provides installments and subsegments.

According to one side, the data divider may time-divided the at least one segment into sub-segments by arranging the bits in the sub-segment so that the continuity of the bits included in the at least one segment is maintained.

According to another aspect, a channel may be allocated to each segment, and the lower segment providing unit may sequentially provide the lower segments to channels allocated to at least one segment.

According to another aspect, video data can be separated into two parts, a relatively short leading part and a relatively long trailing part, segments can be generated through time division for the short leading part, and at least one segment is These may include the remaining segments except the first generated segment. In this case, the lower segment provider may further provide the first generated segment by mapping the corresponding segment.

A data combining apparatus for combining segments of video data transmitted from a transmitting apparatus to a receiving apparatus, the sub-segment generated by time-dividing at least one segment of segments generated by time-dividing the video data with a predetermined period in time. There is provided a data combining apparatus including a sub-segment providing unit for providing the data and a segment combiner for sequentially combining the bits included in the sub-segments according to a predetermined bit rate and time.

A data partitioning method for dividing video data transmitted from a transmitting device to a receiving device, the method comprising: time-dividing at least one segment among segments generated by time-dividing video data in a predetermined period according to time; A data partitioning method is provided that includes providing sub-segments.

A data combining method for combining segments of video data transmitted from a transmitting apparatus to a receiving apparatus, the sub-segment generated by time-dividing at least one segment of segments generated by time-dividing the video data with a predetermined period in time; And combining the bits included in the lower segments sequentially according to a predetermined bit rate and time.

When segmenting video data, do not apply additional partitioning scheme to the complex bit rate, perform primary partitioning to divide the data according to time, and then apply the segments recursively using the same partitioning method. By finer partitioning, we can reduce server-side process load, resource occupancy, and complexity, while simultaneously mapping secondary time-divisioned data segments to partitioned data segments on a logical channel that is planned in the same way as conventional partial channel transmission. It can be used to maintain the effect of partial channel transmission, such as adjusting the latency of the viewer and the amount of buffer required.

When the receiving side receives the divided data segments and performs recombination into one original content, since each segment has sequential bit continuity between the segments, only the simplest method of combining the next-order segments after the current segment is used. By recombining, a resource occupancy and complexity can be reduced since the receiving apparatus does not perform a process of simultaneously multiplexing a plurality of sub-segments.

1 is a diagram illustrating a harmonic data partitioning method according to the prior art.
2 is a diagram for describing a data partitioning method according to an embodiment of the present invention.
3 is a diagram comparing bit rate division according to the prior art and time division according to an embodiment of the present invention.
4 illustrates a method of mapping segments to a harmonic channel according to an embodiment of the present invention.
FIG. 5 is a diagram comparing a combination of bit rate divided segments according to the prior art and a combination of time division segments according to an embodiment of the present invention.
6 is a block diagram illustrating an internal configuration of a data partitioning device and a data combining device according to an embodiment of the present invention.
7 is a flowchart illustrating a data partitioning method and a data combining method according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a diagram for describing a data partitioning method according to an embodiment of the present invention. The first graph 210 performs time division of the short preceding part Da among the VoD content data divided into the short leading part Da and the long trailing part with a period of 'd' according to time, thereby performing 'S ₁ ', 'S _The first time division is shown by 4 segments of ₂ ',' S ₃ 'and' S ₄ '. As shown in the first graph 110, the second graph 110 shows the second time-division by segmenting the segments divided by the first time-division. In this case, unlike the existing bit rate division, there is an advantage that data can be divided by maintaining bit continuity of each subsegment.

3 is a diagram comparing bit rate division according to the prior art and time division according to an embodiment of the present invention. That is, FIG. 3 illustrates a specific example of performing data partitioning using the segment 'S ₃ ', which is the segment described with reference to FIG. 2. Here, each of the rectangular figures illustrated in FIG. 3 may refer to data of an 'S ₃ ' segment. For example, in FIG. 3, one rectangular figure means one bit, but two or more bits may be determined as one data unit and used for division as needed. In addition, the numbers in the rectangular figures are assigned to identify each of the data of the 'S ₃ ' segment.

In the conventional harmonic method 310 according to the related art, the bits of the 'S ₃ ' segment are read into the memory, and the parallel data classifier 311 is used to classify each bit according to the partition coefficient and then simultaneously perform a write operation. have. In one example, data 1 and data 2 is lower segment "S _3,1 'by 312, data 3 and data 4 are sub-segments" S _{3, 2} "as 313, data 5, and data 6 is a sub-segment" S _{3 , 3} '314 can be classified and stored, this sorting and storage can be done simultaneously for the' Tb 'time.

On the other hand, in FIG. 3, in the data partitioning method 320 according to the exemplary embodiment of the present invention, the bits of data read from the 'S ₃ ' segment are sequentially used according to the partition coefficient by using the single data divider 321. Second time division and write operations may be performed during the time period. That is, in the data partitioning method 320, data 1 to data 6 are divided into sub-segments 'S _{3 , 1} ' 322, and data 7 to data 12 are divided into sub-segments 'S _{3 , 2} ' 323. , Data 13 and data 14 are divided into sub-segments 'S _{3 , 3} ' 324.

As described above, using the data partitioning method according to an embodiment of the present invention can overcome the problem of increased process load and complexity due to bit rate division, and maintain bit continuity of data.

4 illustrates a method of mapping segments to a harmonic channel according to an embodiment of the present invention. That is, FIG. 4 illustrates a method of mapping segments and sub-segments generated through 1-2th time division, to harmonic channels, as in the second graph 110 of FIG. 2. That is, FIG. 4 is an example of partial channel mapping of the harmonic method. As described above, using the data partitioning method using the 1st to 2nd time division as in the embodiment of the present invention, it is possible to reduce the process load, resource occupancy and complexity of the server side compared to the bit rate partitioning method, and at the same time Since the partial channel mapping can be used as it is, the effect of partial channel transmission, such as adjusting the latency of the viewer and the required buffer amount, can be maintained.

FIG. 5 is a diagram comparing a combination of bit rate divided segments according to the prior art and a combination of time division segments according to an embodiment of the present invention. That is, FIG. 5 illustrates a specific example of performing data combining using secondary bit rate-divided segments according to the prior art in FIG. 3 and secondary time-divided segments according to an embodiment of the present invention. Here, each of the rectangular figures illustrated in FIG. 5 may refer to data of an 'S ₃ ' segment as described with reference to FIG. 3.

In the conventional harmonic method 310 according to the related art, the parallel data combiner 511 alternately reads and combines data from respective sub-segments 512 to 514.

In contrast, in FIG. 5, in the data combining method 320 according to an embodiment of the present invention, the single data combiner 521 receives sub-segments 522 to 524 that maintain bit continuity of data, and sequentially Read and combine

Therefore, when another data combining method is used in an embodiment of the present invention, when receiving data segments divided on the receiving side and performing recombination into one original content, each segment has sequential bit continuity. In addition, the content can be recombined by performing a simple method of combining the next-order segments after the current segment. This recombination method reduces resource occupancy and complexity since the receiving device does not perform the process of simultaneously combining multiple sub-segments. Can be.

For example, the data combining apparatus according to the embodiment of the present invention starts to receive all the segments in the first step. In this case, the data combining apparatus may set the variable N to 1. Thereafter, the data combining apparatus decodes the first segment in the second step and checks whether the N + 1 th segment is received in the third step. If the N + 1 th segment is not received, the data combining apparatus may repeat the third step until the N + 1 th segment is received. In addition, when the N + 1 th segment is received, the data combining apparatus may rearrange the N + 1 th segment in the fourth step and check whether the N + 2 th segment is received in the fifth step. In this case, when the N + 2th segment is not received, the data combining apparatus may repeat the fifth step until the N + 2th segment is received. In this case, if the N + 2 th segment is received, the data combining apparatus may rearrange the N + 2 th segment in the sixth step and update N to N + 2 for the next two segments. After both the N + 1 th segment and the N + 2 th segment are rearranged, the data combining apparatus may combine the N + 1 th segment and the N + 2 th segment in the seventh step. In addition, the data combining apparatus may wait until the decoder memory is not full in the eighth step, and then start decoding if the decoder memory is not full.

6 is a block diagram illustrating an internal configuration of a data partitioning device and a data combining device according to an embodiment of the present invention. The data dividing apparatus 610 according to the present exemplary embodiment is an apparatus for dividing video data transmitted from a transmitting apparatus to a receiving apparatus, and may basically be an apparatus included in the transmitting apparatus. In addition, if necessary, the data dividing apparatus 610 may be configured as a separate apparatus associated with the transmitting apparatus. The data dividing apparatus 610 may include a data dividing unit 611 and a lower segment providing unit 612 as shown in FIG. 6.

The data dividing unit 611 time-divides at least one of the segments generated by time-dividing the video data according to time at predetermined intervals into lower segments. In this case, the data dividing unit 611 may time-dividing at least one segment into the sub-segments by arranging the bits in the sub-segment so that the continuity of the bits included in the at least one segment is maintained. The method of time division of the segment to maintain the continuity of bits has already been described in detail with reference to FIG. 3, and thus repetitive description thereof will be omitted.

Here, the video data may be divided into two parts, a relatively short leading part and a relatively long trailing part, and segments may be generated through time division for the short leading part. In this case, the at least one segment may include remaining segments except the first generated segment among the segments. That is, the first segment may not be divided into separate subsegments.

The lower segment providing unit 612 provides the lower segments. In this case, segments generated by time division of video data according to time at predetermined periods may be allocated to respective channels. In this case, the lower segment provider 612 may sequentially provide the lower segments to channels allocated to at least one segment.

In this case, as described above, when at least one segment includes remaining segments other than the first generated segment, the lower segment providing unit 612 may further provide the first generated segment by mapping the corresponding segment. can do. That is, all of the short preceding parts of the above-described video data may be provided through the lower segment providing unit 612.

The data combining device 620 according to the present embodiment is a device that combines segments of video data transferred from a transmitting device to a receiving device, and may be basically a device included in the receiving device. In addition, if necessary, the data combining device 620 may be configured as a separate device associated with the receiving device. The data combiner 620 may include a lower segment provider 621 and a segment combiner 622 as illustrated in FIG. 6.

The lower segment providing unit 621 may provide the lower segments generated by time-dividing at least one of the segments generated by time-dividing the video data according to time at predetermined intervals. For example, sub-segments may be generated by time-dividing at least one of the segments generated by time-dividing the video data with a predetermined period in the data partitioning apparatus 610 as described above. The transmission device may be transmitted to the data combining device 620 via the receiving device. In this case, the lower segment providing unit 621 may provide the received lower segments. In this case, the sub-segments may be provided by sequentially mapping the sub-segments to a channel allocated to at least one segment in the data splitting apparatus 610 as described above, and the sub-segments may be provided to the receiving apparatus through the channel. Can be sent to.

The segment combiner 622 sequentially combines the bits included in the lower segments according to a predetermined bit rate and time. For example, in the data partitioning apparatus 610, bits may be disposed in a lower segment so that the continuity of the bits included in the at least one segment may be maintained so that the at least one segment may be time-divided into lower segments. In this case, the segment combiner 622 may combine the bits corresponding to the predetermined bit rate according to the order of the lower segments arranged to maintain the continuity of the bits. Here, the bit rate means the bit rate described with reference to FIGS. 1 to 5.

7 is a flowchart illustrating a data partitioning method and a data combining method according to an embodiment of the present invention. The data partitioning method according to the present embodiment may be performed through the data partitioning device 610 described with reference to FIG. 6, and the data combining method may be performed through the data combining device 620. In FIG. 7, the data partitioning method and the data combining method will be described by describing a process in which each step is performed through the data partitioning device 610 and the data combining device 620.

In operation 710, the data dividing apparatus 610 time-divides at least one of the segments generated by time-dividing the video data in a predetermined period over time into lower segments. In this case, the data dividing apparatus 610 may time divide the at least one segment into the sub-segments by arranging the bits in the sub-segment so that the continuity of the bits included in the at least one segment is maintained. The method of time division of the segment to maintain the continuity of bits has been described in detail with reference to FIG.

Here, the video data may be divided into two parts, a relatively short leading part and a relatively long trailing part, and segments may be generated through time division for the short leading part. In this case, the at least one segment may include remaining segments except the first generated segment among the segments. That is, the first segment may not be divided into separate subsegments.

In operation 720, the data partitioning apparatus 610 provides the lower segments. In this case, segments generated by time division of video data according to time at predetermined periods may be allocated to respective channels. In this case, the data dividing apparatus 610 may sequentially provide sub-segments to channels allocated to at least one segment.

In this case, as described above, when at least one segment includes remaining segments other than the first generated segment, the data partitioning apparatus 610 may further provide the first generated segment by mapping the corresponding segment. Can be. That is, all of the short preceding parts of the above-described video data may be provided through the data dividing apparatus 610.

In operation 730, the data combining apparatus 620 may provide sub-segments generated by time-dividing at least one of the segments generated by time-dividing the video data with a predetermined period in time. For example, in operation 710, the sub-segments may be generated by time-dividing at least one of the segments generated by time-dividing the video data according to time by a predetermined period through the data dividing apparatus 610. These sub-segments may be transmitted to the data combining apparatus 620 via the transmitting apparatus and the receiving apparatus through step 720. In this case, the data combining device 620 may provide the received subsegments. In this case, the sub-segments may be provided by sequentially mapping the sub-segments to a channel allocated to at least one segment in the data splitting apparatus 610 as described above, and the sub-segments may be provided to the receiving apparatus through the channel. Can be sent to.

In operation 740, the data combining apparatus 620 sequentially combines bits included in the lower segments according to a predetermined bit rate and time. For example, in the data partitioning apparatus 610, bits may be disposed in a lower segment so that the continuity of the bits included in the at least one segment may be maintained so that the at least one segment may be time-divided into lower segments. In this case, the data combining device 620 may combine the bits corresponding to the predetermined bit rate according to the order of the lower segments arranged to maintain the continuity of the bits.

6 and 7 may refer to FIGS. 1 to 5.

As described above, according to embodiments of the present invention, after segmentation of video data, corresponding segments are equally partitioned after performing primary partitioning for partitioning data over time without additionally applying a partitioning scheme to a complex bit rate. By splitting the data more finely over time by applying a recursive approach, it is possible to reduce server-side process load, resource occupancy and complexity, while at the same time planning secondary time-segmented data segments as planned for traditional partial channel transmission. The method of mapping the divided data segments to the logical channel can be used to maintain the effect of partial channel transmission, such as adjusting the latency of the viewer and the amount of buffer required. In addition, when receiving the divided data segments at the receiving side and performing recombination into one original content, since each segment has sequential bit continuity, only a simple method of combining a next-order segment after the current segment is performed. By recombining the contents, the resource occupancy and complexity can be lowered because the receiving apparatus does not perform the process of multiplexing multiple sub-segments simultaneously.

Methods according to an embodiment of the present invention may be implemented in the form of program instructions that can be executed by various computer means and recorded in a computer readable medium. The computer readable medium may include program instructions, data files, data structures, etc. alone or in combination. The program instructions recorded on the medium may be those specially designed and constructed for the present invention or may be available to those skilled in the art of computer software.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above embodiments, and those skilled in the art to which the present invention pertains various modifications and variations from such descriptions. This is possible.

Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined by the equivalents of the claims, as well as the claims.

610: Data partitioning device.
620: data combiner

Claims (9)

A data dividing apparatus for dividing video data transmitted from a transmitting apparatus to a receiving apparatus,
A data partitioner for time-dividing at least one of the segments generated by time-dividing the video data according to time at predetermined intervals into lower segments; And
Lower segment providing unit for providing the lower segments
Including,
The data divider,
And time-dividing the at least one segment into the sub-segments by arranging the bits in the sub-segment so that the continuity of the bits included in the at least one segment is maintained. delete The method of claim 1,
Each channel is assigned a channel,
The lower segment providing unit,
And sequentially mapping the sub-segments to a channel allocated to the at least one segment. The method of claim 1,
The video data is divided into two parts, a relatively short leading part and a relatively long trailing part,
The segments are created through time division for the short preceding part,
And said at least one segment comprises remaining segments except the first one of said segments. 5. The method of claim 4,
The lower segment providing unit,
And providing the first generated segment by mapping the first generated segment through a corresponding channel. A data combining device for combining segments of video data transferred from a transmitting device to a receiving device,
A sub-segment providing unit configured to provide sub-segments generated by time-dividing at least one of the segments generated by time-dividing the video data in a predetermined period according to time; And
Segment combiner for sequentially combining the bits included in the lower segments according to a predetermined bit rate and time
Data combining device comprising a. The method according to claim 6,
Bits are arranged in the sub-segment so that the continuity of bits included in the at least one segment is maintained so that the at least one segment is time-divided into the sub-segments,
The segment coupling portion,
And combining bits corresponding to the predetermined bit rate according to the order of the lower segments arranged to maintain the continuity of the bits. A data segmentation method for segmenting video data transmitted from a transmitter to a receiver, the method comprising:
Time-dividing at least one of the segments generated by time-dividing the video data in a predetermined period in time into sub-segments; And
Providing the sub-segments
Including,
The time division step again,
And time-dividing the at least one segment into the sub-segments by arranging the bits in the sub-segment so that the continuity of the bits included in the at least one segment is maintained. A data combining method for combining segments of video data transferred from a transmitting device to a receiving device,
Providing sub-segments generated by time-dividing at least one of the segments generated by time-dividing the video data in a predetermined period over time; And
Sequentially combining bits included in the lower segments according to a predetermined bit rate and time;
Data combining method comprising a.

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