KR100849495B1 - Method for producing bit-rate based on RTP packet mode - Google Patents

Abstract

1. TECHNICAL FIELD OF THE INVENTION

The present invention relates to a method of generating a bit rate for each RTP packetization mode.

2. The technical problem to be solved by the invention

The present invention provides an RTP for efficiently streaming SVC video without overhead by generating a bit rate in consideration of an RTP / UDP / IP header, an MTU size, and an RTP packetization mode during SVC video streaming. Its purpose is to provide a bit rate generation method for each packetization mode.

3. Summary of Solution to Invention

According to the present invention, in the method of generating a bit rate for each RTP packetization mode in a non-interleaved mode, a bit rate is generated by using the size of NAL units per layer and a corresponding header size for a packet of a single NAL unit (SNU) type. Generating a first bit rate; And generating STAP-A type packets by using Network Abstraction Layer (NAL) units for layers to be transmitted in the same frame for the STAP-A (Simple-Time Aggregation Packet-A) type packet. And generating a bit rate in consideration of the header size of the generated STAP-A type packet.

4. Important uses of the invention

The present invention is used for SVC-based streaming system.

SVC-based streaming system, RTP packetization mode, SNU mode, SNU type, STAP-A type, bit rate

Description

Method for producing bit rate by RTP packetization mode {Method for producing bit-rate based on RTP packet mode}

1 is a configuration diagram of an embodiment of an SVC-based streaming system to which the present invention is applied;

2 is an exemplary diagram of a streaming protocol stack used in the present invention;

3 is a flowchart illustrating a method of generating a bit rate for each RTP packetization mode in an SVC-based streaming system according to the present invention;

4 is a flowchart illustrating another embodiment of a method of generating bit rates for RTP packetization modes in an SVC-based streaming system according to the present invention.

* Explanation of symbols for the main parts of the drawings

11: SVC Encoder 12: Extractor

13: streaming server

The present invention relates to a method for generating a bit rate for each RTP packetization mode applied to an SVC-based streaming system. More specifically, the present invention relates to an RTP / UDP / IP header, an MTU size, and an RTP packetization mode during SVC video streaming. By generating a bit rate in consideration, the present invention relates to an RTP packetization mode-specific bit rate generation method for efficiently streaming SVC video without overhead.

Scalable video coding (SVC), H.264's scalable encoding technology, has low compression efficiency, inability to support complex scalability, and high implementation complexity, which have disadvantages of scalability based on hierarchical coding attempted by MPEG-2 and MPEG-4. It is a new scalable coding technique developed to solve the problems of.

SVC encodes several video layers into one bit string. The SVC layer is composed of one base layer and a scalable layer that can be stacked on the base layer continuously. In this case, each enhancement layer may express the maximum bit rate, frame rate, and resolution given to each other based on lower layer information.

In SVC, as the number of extension layers is continuously stacked, it is possible to support various bit rates, screen rates, and resolutions. Therefore, bandwidth diversity problems in heterogeneous network environments, receiver performance and resolution diversity, and content consumers It is a coding technology suitable for multimedia contents service of UMA (Universal Multimedia Access) environment that can solve various preference problems of.

In the video coding layer (VCL) layer, the SVC encoder generates base layer encoding information and scalable encoding information of a scalable layer in slice units. Each slice thus generated is generated in a NAL unit in the NAL layer and stored in the SVC bitstream.

In conventional SVC video streaming, Supplemental Enhancement Information (SEI) is used as shown in Table 1 below to control bit rate, and the following SEI merely classifies the bit rate for video data. As a result, there is a problem of generating a considerable difference from the actual transmitted bit rate.

That is, since the conventional SEI only considers the bit rate of the SVC bitstream, an overhead of at least 40 bytes per IP packet due to the size of the RTP / UDP / IP header added when transmitted over the actual network. There is a problem that generates.

In particular, since SVC supports three Real Time Transport Protocol (RTP) packetization modes, the difference in the actual bit rate according to the size of the maximum transmission unit (MTU) becomes larger.

Hereinafter, the RTP packet type for SVC will be described in more detail.

RTP packet types for NAL units of SVC include Single NAL Unit (SNU), Simple-Time Aggregation Packet-A (STAP-A), Simple-Time Aggregation Packet-B (STAP-B), and Multi-Time Aggregation (MTAP 16). Packet 16), MTAP 24 (Multi-Time Aggregation Packet 24), Fragmentation Unit-A (FU-A), Fragmentation Unit-B (FU-B), and a total of seven.

First, the SNU type may carry only one NAL unit in one RTP, and STAP may simultaneously carry a plurality of NAL units belonging to the same presentation time instant in one RTP packet. In the same order as, STAP-A type in which NAL units are loaded in the RTP packet and STAP-B type in which NAL units are loaded in the RTP packet without considering the decoding order for interleaving.

MTAP can load multiple NAL units belonging to different screen presentation time in one RTP packet at the same time and support interleaving by default, and time offset for displaying the difference in screen presentation time between each NAL unit offset) According to the size of the field section, it is divided into MTAP 16 type that supports 16-bit time offset and MTAP 24 type that supports 24-bit time offset.

Of these seven RTP packet types, only the packet types needed according to the application are grouped into three types of RTP packetization modes. [Table 2] below shows the SNU (Single NAL Unit) mode and non-interleaved. RTP packet type supported by three types of RTP packetization modes such as) mode and interleaved mode.

Here, in the SNU mode, only an SNU type capable of loading only one NAL unit encoding information having a NAL unit type of 1 to 23 in an RTP packet can be supported and its application field is very limited. In contrast, the non-interleaved mode can support not only the SNU type but also STAP-A and FU-A, so that the practical application range is quite wide.

In addition, the interleaved mode is a method in which an interleaving function is added to the non-interleaved mode, and has a disadvantage in that it does not support the SNU type. The interleaving function of the interleaved mode allows the NAL units to be placed in the RTP packet differently from the decoding order to effectively cope with burst errors in the channel. However, RTP packetization and depacketization (de- packetization) and the SVC decoding process is very complicated.

Accordingly, there is a need for a method of generating bit rate information in consideration of an RTP / UDP / IP header, an MTU size, and an RTP packetization mode during SVC video streaming.

The present invention has been proposed to solve the above problems and to meet the above requirements, by generating a bit rate in consideration of the RTP / UDP / IP header, MTU size, and RTP packetization mode during SVC video streaming. An object of the present invention is to provide a method of generating bit rates for RTP packetization modes for efficiently streaming SVC video without overhead.

Other objects and advantages of the present invention can be understood by the following description, and will be more clearly understood by the embodiments of the present invention. Also, it will be readily appreciated that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

The method of the present invention for achieving the above object, in the non-interleaved mode bit rate generation method for each RTP packetization mode, the size of the layer-specific NAL units and corresponding header for the SNU (Single NAL Unit) type of packet A first bit rate generating step of generating a bit rate using the magnitude; And generating STAP-A type packets by using Network Abstraction Layer (NAL) units for layers to be transmitted in the same frame for the STAP-A (Simple-Time Aggregation Packet-A) type packet. And generating a bit rate in consideration of a header size of the generated STAP-A type packet.

In addition, another method of the present invention for achieving the above object is, in the non-interleaved mode bit rate generation method for each RTP packetization mode, the size of the layer-specific NAL units for the SNU (Single NAL Unit) type of packet And a first bit rate generating step of generating a bit rate using the corresponding header size. And STAP-A type packet and FU-A using NAL (Network Abstraction Layer) units for layers to be transmitted within the same frame for a STAP-A type packet. And generating a bit rate in consideration of header sizes of the generated STAP-A type packet and the FU-A type packet after generating the packet of the type.

In addition, another method of the present invention for achieving the above object, in the bit rate generation method for each RTP packetization mode in the case of SNU (Single NAL Unit) mode, Network Abstraction Layer (NAL) units per layer (Layer) Classifying; Calculating a total size of the classified layer NAL units; Calculating a total header size of the classified layer NAL units; And generating a bit rate using the total size and the total header size of the NAL units for each layer.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, whereby those skilled in the art may easily implement the technical idea of the present invention. There will be. In addition, in describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

1 is a diagram illustrating an embodiment of an SVC-based streaming system to which the present invention is applied.

As shown in FIG. 1, the SVC-based streaming system to which the present invention is applied encodes a video at high quality in an SVC encoder 11 to support various bit rates, screen rates, and resolutions. By using the SEI in the extractor 12, the SVC bitstream is extracted according to the network situation between the streaming server 13 and the client, and transmitted to the streaming server 13, thereby controlling bit rate. Is done.

2 is an exemplary diagram of a streaming protocol stack used in the present invention.

As shown in FIG. 2, the extracted bitstream is packetized into an RTP packet and then packetized into a UDP packet, and then packetized into an IP packet and transmitted.

The factors that determine the size of the IP packet actually transmitted are the size of each NAL unit, the size of the RTP header, the size of the UDP header, the size of the IP header, the RTP packetization mode, and the size of the MTU.

Here, the size of the RTP header is 12 bytes, the size of the UDP header is 8 bytes, the size of the IP header is 20 bytes, and the size is fixed to 40 bytes unless the extension portion of the header is used.

On the other hand, the size of the MTU is 1500 bytes in an Ethernet environment that is generally used, but in a mobile communication network such as CDMA, the size of the MTU is reduced to a few hundred bytes.

On the other hand, even if the size of the NAL unit is larger than the MUT and the RTP packetization mode is not SNU affects the bit rate.

3 is a flowchart illustrating a method of generating a bit rate for each RTP packetization mode in an SVC-based streaming system according to the present invention, and illustrates a case of SNU (Single NAL Unit) mode.

First, network abstraction layer (NAL) units are classified for each layer, a total size and total header size of the classified layer NAL units are calculated, and a bit rate for each layer is calculated to generate a bit rate.

That is, after classifying NAL units having the same D, T, and Q values (layer value), the sizes of the classified NAL units are respectively added (301). Here, having the same D, T, and Q values means being included in the same layer.

Thereafter, the number of NAL units added for each D, T, and Q is multiplied by the size of the header (for example, 40 bytes) (302).

Subsequently, the bit amount is calculated for each D, T, Q by adding a value obtained by multiplying the number of the corresponding NAL units by the header size to the size values of NAL units added for each of the same D, T, Q (303).

Thereafter, the bit rate is calculated using the calculated bit amount (304).

For example, the size of the NAL units included in the 1, 1, 0 is 100, 200, the size of the NAL units included in the layer values 1, 1, 1 are 100, 150, 200, the layer value 1 Assume that the sizes of NAL units included in, 1,2 are 150 and 200.

First, the total size of NAL units included in 1,1,0 is 300 (100 + 200), and the total size of NAL units included in 1,1,1 is 450 (100 + 150 + 200), 1, The total size of the NAL units contained in 1,2 is 350 (150 + 200).

Next, the total header size of the NAL units included in 1, 1, 0 is 80 (40 × 2), the total header size of the NAL units included in 1, 1, 1 is 120 (40 × 3), and 1, The total header size of the NAL units included in 1,2 is 80 (40 × 2).

Next, the bit amount of 1,1,0 is 380 (300 + 80), the bit amount of 1,1,1 is 570 (450 + 120), and the bit amount of 1,1,2 is 430 (350 + 80). )to be.

Expressed in bits per time (usually seconds), the bit rate is obtained.

4 is a flowchart illustrating a method of generating a bit rate for each RTP packetization mode in an SVC-based streaming system according to the present invention, and illustrates a case in a non-interleaved mode.

First, when the packet type is the SNU (Single NAL Unit) type, the bit rate is calculated in the same manner as in the SNU (Single NAL Unit) mode as shown in FIG. Here, the SNU (Single NAL Unit) type and the SNU (Single NAL Unit) mode are different division elements, as can be seen from [Table 2].

Subsequently, when the packet type is STAP-A (Simple-Time Aggregation Packet-A), the size of NAL units for layers to be transmitted in the same frame is checked (402).

Subsequently, the number of NAL units is added one by one to the transmission priority for layers to be transmitted in the same frame, but not exceeding the threshold to generate a plurality of STAP-A type packets that do not exceed the threshold, and then the number thereof. 403 is calculated.

That is, the sizes of NAL units are sequentially added as transmission priorities for layers to be transmitted in the same frame.

Then, it is checked whether the added magnitude value exceeds a threshold.

As a result of the checking, if the threshold is not exceeded, the size summing process is continued. If the threshold is exceeded, the size of the NAL unit added at the end is subtracted to generate a STAP-A type packet.

Thereafter, the number of generated STAP-A type packets is calculated.

Here, the transmission priority refers to the order of data to be sent first in relation to data reproduction, and the threshold means a value obtained by subtracting the header size (40 bytes) from the maximum transmission unit (MTU).

In this case, when the size of one NAL unit is larger than the value obtained by subtracting the header size (40 bytes) from the MTU, a packet of FU-A type is generated, but the minimum is larger than the value obtained by dividing the NAL unit size by the value obtained by subtracting the header size from the MTU. An integer of represents the number of FU-A packets.

Subsequently, the sum of the number of STAP-A type packets generated by the layers to be transmitted and the number of FU-A type packets is multiplied by a corresponding header size, and then the amount of bits of the generated STAP-A type packets and FU-A type packets ( In addition to the amount of transmission bits, a bit rate is generated (404).

As described above, the method of the present invention may be implemented as a program and stored in a recording medium (CD-ROM, RAM, ROM, floppy disk, hard disk, magneto-optical disk, etc.) in a computer-readable form. Since this process can be easily implemented by those skilled in the art will not be described in more detail.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the technical spirit of the present invention for those skilled in the art to which the present invention pertains. It is not limited by the drawings.

As described above, the present invention generates the bit rate in consideration of the RTP / UDP / IP header, MTU size, and RTP packetization mode during SVC video streaming, thereby efficiently streaming SVC video without overhead. It can work.

Claims (14)

In the bit rate generation method for each RTP packetization mode in the non-interleaved mode, A first bit rate generating step of generating a bit rate using a size of NAL units per layer and a corresponding header size for a packet of a single NAL unit (SNU) type; And After generating a STAP-A type packet by using Network Abstraction Layer (NAL) units for the layers to be transmitted in the same frame for a STAP-A type packet A second bit rate generation step of generating a bit rate in consideration of a header size of the generated STAP-A type packet; Bit rate generation method for each RTP packetization mode comprising a. The method of claim 1, The second bit rate generating step, Checking the size of Network Abstraction Layer (NAL) units for layers to be transmitted in the same frame for a STAP-A (Simple-Time Aggregation Packet-A) type packet; A packet number calculating step of generating a STAP-A type packet based on the size of the inspected NAL units and calculating the number of packets; And A third bit rate generation step of generating a bit rate by multiplying the calculated number of STAP-A type packets by a header size and adding the bit amount of the STAP-A type packet Bit rate generation method for each RTP packetization mode comprising a. The method of claim 2, The packet number calculating step, After adding the size of NAL units one by one to the transmission priority for the layers to be transmitted in the same frame, but not exceeding a threshold, the packet is generated after generating a plurality of STAP-A type packets that do not exceed the threshold. And calculating the number of STAP-A type packets. The method of claim 3, wherein The packet number calculating step, A size summing step of sequentially adding sizes of NAL units in transmission priority for layers to be transmitted in the same frame; Confirming that the added magnitude value exceeds the threshold; Continuing to add the size if the threshold is not exceeded; Generating a STAP-A type packet after subtracting the size of the last added NAL unit if the threshold is exceeded; And Calculating the number of generated STAP-A type packets Bit rate generation method for each RTP packetization mode comprising a. In the bit rate generation method for each RTP packetization mode in the non-interleaved mode, A first bit rate generating step of generating a bit rate using a size of NAL units per layer and a corresponding header size for a packet of a single NAL unit (SNU) type; And STAP-A type packet and FU-A type using Network Abstraction Layer (NAL) units for layers to be transmitted in the same frame for a STAP-A (Simple-Time Aggregation Packet-A) type packet A second bit rate generation step of generating a bit rate in consideration of the header sizes of the generated STAP-A type packet and the FU-A type packet after generating a packet of? Bit rate generation method for each RTP packetization mode comprising a. The method of claim 5, wherein The second bit rate generating step, Checking the size of Network Abstraction Layer (NAL) units for layers to be transmitted in the same frame as the packet type is Simple-Time Aggregation Packet-A (STAP-A); A packet number calculating step of generating a STAP-A type packet based on the size of the inspected NAL units and calculating the number of packets; And The amount of bits of the generated STAP-A type packet and the FU-A type packet after multiplying the corresponding header size by the sum of the calculated number of STAP-A type packets and the calculated number of FU-A type packets (transmission bits) Third bit rate generating step of generating a bit rate in addition to the Bit rate generation method for each RTP packetization mode comprising a. The method of claim 6, The packet number calculating step, After adding the size of NAL units one by one to the transmission priority for the layers to be transmitted in the same frame, but not exceeding a threshold, the packet is generated after generating a plurality of STAP-A type packets that do not exceed the threshold. Calculating a number of STAP-A type packets for calculating the number of STAP-A type packets; And If one NAL unit size is larger than the threshold, generating a packet of FU-A type, and calculating a minimum integer (number of FU-A packets) larger than the NAL unit size divided by the threshold; Bit rate generation method for each RTP packetization mode comprising a. The method of claim 7, wherein The step of calculating the number of packets of the STAP-A type, A size summing step of sequentially adding sizes of NAL units in transmission priority for layers to be transmitted in the same frame; Confirming that the added magnitude value exceeds the threshold; Continuing to add the size if the threshold is not exceeded; Generating a STAP-A type packet after subtracting the size of the last added NAL unit if the threshold is exceeded; And Calculating the number of generated STAP-A type packets Bit rate generation method for each RTP packetization mode comprising a. The method according to claim 3 or 7, The transmission priority is, RTP packetization mode bit rate generation method characterized in that the order of the data to be sent first with respect to the data reproduction. The method according to claim 3 or 7, The threshold is Method for generating a bit rate for each RTP packetization mode, characterized in that the value is obtained by subtracting the header size from the maximum transmission unit (MTU). The method according to any one of claims 1 to 8, The first bit rate generating step, Classifying NAL units by layer and adding sizes of the classified NAL units, respectively; Multiplying a header size by the number of NAL units added for each corresponding layer; Calculating a bit amount for each corresponding layer by adding a value obtained by multiplying the number of the corresponding NAL units by the header size to the size values of the NAL units added for each same layer; And Calculating a bit rate using the calculated bit amount Bit rate generation method for each RTP packetization mode of the SVC-based streaming system comprising a. The method of claim 11, The header size is 12 bytes of RTP header size, 8 bytes of UDP header size, 40 bytes plus 20 bytes of IP header size. In the bit rate generation method for each RTP packetization mode in SNU (Single NAL Unit) mode, Classifying NAL (Network Abstraction Layer) units by layer; Calculating a total size of the classified layer NAL units; Calculating a total header size of the classified layer NAL units; And Generating a bit rate using the total size of the NAL units of each layer and the total header size Bit rate generation method for each RTP packetization mode comprising a. The method of claim 13, The header size is A method of generating a bit rate for each RTP packetization mode, wherein the size of the RTP header is 12 bytes, the size of the UDP header is 8 bytes, and the size of the IP header is 20 bytes.

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