KR20090017323A - Method of controlling bearers for multiple layer data transmission - Google Patents

Abstract

A method of controlling bearer for multiple layer data transmission is provided to reduce time consumed in generation and authentication of bearers additionally necessary for data transmission of a multi layer, thereby securing service quality. A layer number of data coded by a multiple layer is determined in advance. When generating initial bearers to transmit the data coded by the multi layer, at least two bearers are generated. Bearers are generated as many as the layer number. Data is transmitted by using one of the two generated bearers. A PDP context is generated as many as the layer number and a different PDP address is assigned per each layer to generate bearers as many as the layer number. When generating the bearers as many as the layer number, the maximum transmission rate of the remaining bearers except one is set at 0Kbps.

Description

Bearer control method for multi-layer data transmission {Method of Controlling Bearers for Multiple Layer Data Transmission}

The present invention relates to a bearer control method for multi-layer data transmission. According to the present invention, when a bearer is first created for multi-layer data transmission, as many bearers as the number of data layers are generated, and the maximum data rate of the remaining bearers except one bearer is set to 0 Kbps. If the user later transmits the multi-layer data, the maximum data rate of the remaining bearer is changed to transmit the multi-layer data through the bearer generated in advance. Therefore, it is possible to transmit the coded data in multiple layers without delay caused by bearer generation.

IMS is a new core network based on SIP (Session Initiation Protocol), which overlaps with existing mobile packet network, to enable users to use voice / video call service and multimedia supplementary service regardless of communication terminal anytime, anywhere and on any network platform. to be.

1 is a schematic diagram of an IMS and a Wibro All-IP based communication network. As defined in 3GPP / 3GPP2, Call Setup Control Function (CSCF) provides SIP-based call control function to provide various multimedia services on 3G communication network, and performs SIP-based session management function. Specifically, P-CSCF (Proxy-CSCF) serves as an initial access point for the user terminal to access the IMS core network, and the quality of service associated with an access control router (ACR) through a policy definition function (PDF) function. Quality of Service (QoS) is guaranteed. Interrogating-CSCF (I-CSCF) serves as an intermediate access point for connecting a call to the IMS to which the called terminal user belongs, and provides a function such as interworking with a home subscriber server (HSS). On the other hand, S-CSCF (Serviec-CSCF) downloads the subscriber profile in conjunction with all session management functions and HSS of the IMS, and interworks with the AS (Application Server) through this.

In order to efficiently transmit high-capacity multimedia data such as video data to improve quality of service (QoS), a method of coding video data into multiple layers has been attempted.

FIG. 2 is a diagram illustrating that video data is coded in multiple layers. FIG. 2 illustrates coding of one video data into one base layer and one or more enhancement layers.

In this case, the base layer is coded to mainly include data which greatly affects the quality of service when users watch a video image, and the enhancement layer includes data that can further improve the quality of service when transmission is possible. The information actually included in the two layers may vary according to a coding method. For example, the low frequency part representing the basic color and the shape of the object may be included in the base layer, and the high frequency part representing the outline and the text of the object may be enhanced. There are various coding methods such as a method of including the layer in the layer, an area in which the viewer's vision stays long, and a background of the other layer in the enhancement layer.

When transmitting multi-layer data generated through these methods, the base layer containing more important data is allocated to a good channel to ensure the transmission, the condition of the channel is measured, and the base layer is transmitted through the channel. By transmitting the enhancement layer additionally, the quality of the video image can be improved.

However, in comparison with the development of technology such as multi-layer coding at the application level for efficiently transmitting video data, the technology development for efficiently transmitting data coded in multiple layers is poor at the session level.

PDP Context (Packet Data Protocol Context) is a protocol used to create and maintain a session between an access control router (ACR) and a user terminal. It has three commands: create, change, and remove. To manage sessions.

To establish an All-IP session between two terminals, first establish a session at the application level by exchanging SIP and Session Description Protocol (SDP) containing session information and exchanging necessary information for session establishment. In addition, it reserves the resources of the actual bearer and performs all processes to communicate without delay when a call is made.

Since the bearer for initial session creation uses the PDP context of the General Packet Radio Service (GPRS), this bearer setup procedure uses the existing GPRS procedure. At this time, the connection between the existing GPRS procedure and the newly added application procedure is required, and this is called a binding mechanism, and is supported in the Policy Definition Fuction (PDF) and the Access Control Router (ACR), respectively. .

The policy definition function unit requests a new request when a coder or a data rate needs to be modified on an application session after a bearer is reserved and a call is established according to SDP information exchanged between two terminals during initial call setup. Determine whether service quality is acceptable.

In order to use a multi-layer codec for coding video data into multiple layers in a conventional GPRS system, a bearer must be newly generated whenever an additional multiple layer is generated. This not only needs to negotiate a codec between two terminals using SIP / SDP, but also has a problem in that a time required for generating a bearer in a GPRS system is added.

That is, when a user uses data of a single layer while using data of a single layer, a large delay time is generated in order to secure additional bearers. Authentication is needed to ensure that the quality of service requested on the network is acceptable. The time it takes for ACR to go through this authentication process via PDF is a delay. As described above, there is a problem that the time required for generating a bearer for data of multiple layers is long.

The present invention has been made to solve the above-described problems, in the present invention, when the first bearer is created for multi-layer data transmission, the bearer as many data layers are generated and the data of the remaining bearers except one bearer is generated. When the maximum data rate is set to 0 Kbps, and the user subsequently transmits the multi-layer data, the present invention provides a method of changing the maximum data rate of the remaining bearers to transmit the multi-layer data through the bearer previously generated. Through this, coded data can be transmitted in multiple layers without delay time due to bearer generation.

The present invention relates to a bearer control method for multi-layer data transmission. The method comprises the steps of: (a) generating at least two bearers upon initial bearer creation for transmitting coded data in multiple layers; And (b) transmitting data using only one bearer of the created two or more bearers.

According to the present invention, it is possible to ensure the quality of service by reducing the time required for the creation and authentication of bearers additionally necessary for data transmission of multiple layers.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. However, the present invention is not limited by the following examples.

3 is a diagram illustrating controlling a session by allocating a plurality of different PDP addresses for data transmission coded in multiple layers according to an embodiment of the present invention. In the present invention, when a bearer is first generated to transmit data coded in multiple layers, the number of layers of data coded in multiple layers is determined in advance, and the number of bearers is generated.

To this end, as many PDP contexts as the number of data layers are generated, and as shown in FIG. 3, different PDP addresses are assigned to each layer to create a session. In this case, the PDP address is necessary for generating a session, and different QoS parameters may be applied to each address.

However, if frequency resources are normally allocated to bearers as many as the number of data layers generated as described above, waste of resources occurs. Therefore, the highest transmission rate among QoS parameters of the PDP context of the other bearer except for one bearer, that is, the bearer for transmission of the base layer, is limited to 0 Kbps. Through this, waste of frequency resources can be minimized.

In order to transmit (or transmit) data coded in a multi-layer to a user who is performing data communication through one of the bearers generated as described above, the highest data rate of the remaining bearers may be appropriate for transmission of the multi-layer data. You must change it.

4 is a flowchart illustrating a process of changing session information according to an embodiment of the present invention.

First, when a user terminal transmits a PDP context update request message requesting a change of PDP context information of a bearer to an access control router (ACR) (S10), the ACR is sent to a P-CSCF having a policy definition function (PDF). In step S20, the user transmits a COPS: REQ requesting a policy decision regarding a session change requested by the user. Accordingly, the P-CSCF determines the QoS parameter of the change request bearer to be suitable for multi-layer data transmission (S30). At this time, according to the embodiment of the present invention, the P-CSCF adjusts the maximum data rate of the bearer for the enhancement layer to a value suitable for transmission of the corresponding layer, and adjusts the maximum data rate of the bearer for the base layer downward.

Thereafter, the P-CSCF sends to the ACR COPS: DEC informing the policy information determined in relation to the bearer for which the change is requested, for example, the QoS parameter value (S40), and the ACR accordingly sends the highest rate of the plurality of bearers to P. Change according to the decision made in the CSCF (S50).

Thereafter, the ACR transmits a COPS RPT message for notifying the PDP context information change to the PDF of the P-CSCF (S60), and transmits the processing result of the PDP context update request to the user terminal (S70). In addition, the transmission of the COPS RPT message and the transmission of the processing result may be performed simultaneously or in a reversed order.

The embodiment according to the present invention is not limited to the above-described embodiments, and various alternatives, modifications, and changes can be made without departing from the scope of the present invention.

According to the present invention, it is possible to ensure the quality of service by reducing the time required for the creation and authentication of bearers additionally required for data transmission of multiple layers.

1 is a schematic configuration diagram of an IMS and a mobile Internet (Wibro) All-IP based communication network.

2 shows that video data is coded into multiple layers.

3 is a diagram illustrating controlling a session by allocating a plurality of different PDP addresses for data transmission coded in multiple layers according to an embodiment of the present invention.

4 is a flowchart illustrating a process of changing session information according to an embodiment of the present invention.

Claims (7)

(A) generating at least two bearers upon initial bearer creation for transmitting coded data in multiple layers; And And (b) transmitting data using only one bearer of the created two or more bearers. The method of claim 1, Before the step (a), further comprising the step of determining in advance the number of layers of the data coded in the multi-layer, The step (a), bearer control method characterized in that for generating the bearer as many as the number of layers. The bearer control method of claim 2, wherein the number of PDP contexts is generated as many as the number of layers, and different PDP addresses are allocated for each layer. The bearer control method of claim 2, wherein the maximum data rate of the remaining bearers except one bearer is set to 0 Kbps when generating as many bearers as the number of layers. Method of initiating multi-layer coded data transmission while generating data using only one bearer by creating two or more bearers for data transmission and setting the maximum data rate of other bearers except one bearer to 0 Kbps As (A) requesting, by the user terminal, to change the PDP context information of the generated bearer to the ACR;  (B) the ACR requesting a policy decision on the information change requested by the user to the P-CSCF; (C) determining, at the P-CSCF, the highest data rate of the change requested bearer to be suitable for multi-layer data transmission; (D) transmitting, by the P-CSCF, the determined policy information to the ACR; And (E) the ACR changing the highest data rate of two or more bearers according to the determined policy information. The method of claim 5, In the step (c), the P-CSCF up-determinates the highest data rate of the bearer for the enhancement layer and down-scales the top data rate of the bearer for the base layer. . The method of claim 5, After step (e), Notifying, by the ACR, of the information change of a PDP context to the P-CSCF; And And transmitting, by the ACR, a result of changing the PDP context information to the user terminal.

Images