KR20060130352A - Apparatus and method for transmitting data in a portable internet system - Google Patents

Abstract

A data transmission device in a portable Internet system and a method thereof are provided to enable an SS(Subscriber Station) or a BS(Base Station) to process data identical with a service flow during a DSC(Dynamic Service Change) procedure, if active connection does not exist because the service flow identical with the data to be transmitted is not an active QoS(Quality of Service) parameter set, thus improvement of more effective performance is expected. A data classifier(220) searches an active service flow identical with QoS of data to be transmitted, if being supplied with the data, and transmits the data through an active connection substituted for the corresponding service flow if the identical active service flow does not exist. A service flow setup unit(230) carries out a DSC procedure for the service flow identical with the QoS of the data to be transmitted. A transmitter(250) transmits the data.

Description

APPARATUS AND METHOD FOR TRANSMITTING DATA IN A PORTABLE INTERNET SYSTEM

1 is a diagram showing the configuration of a general portable Internet system;

2 is a diagram illustrating a message flow when setting a service flow between a terminal and a base station;

3 is a block diagram of a terminal in a preferred embodiment of the present invention;

4 is a diagram illustrating a control flow during data transmission in a terminal according to an embodiment of the present invention.

The present invention relates to a method and apparatus for guaranteeing QoS of data in a portable Internet system.

1 is a diagram illustrating a configuration of a general portable Internet system. Referring to FIG. 1, a subscriber station (SS) 30 is generally mobile and connected to an IP network 10 through a base station (BS) 20. The terminal 30 allows access between the base station 20 and the subscriber. The base station (BS) 20 provides control, management, and connectivity for the terminal 10. The IP network 10 provides the terminal 10 with an Internet service. The IP network 10 includes not only the Internet providing Internet applications such as electronic mail or WWW but also all networks using IP (Internet Protocol) technology.

In order to use the portable Internet service, after the network entry is terminated (see IEEE 802.16D5 6.3.9 Network Entry and Initialization), it is necessary to generate a service flow for data transmission. The service flow refers to a unidirectional flow of data (SDU) delivered through a connection that guarantees a specific QoS.

Portable Internet is a technology that can receive high-speed data wirelessly on the go. In addition, the portable Internet is basically a technology that provides a quality of service (QoS). That is, various QoS parameters such as bandwidth that can be transmitted vary according to the service of the upper layer. Data such as VoIP and video services are sensitive to delay, so different QoS parameters are used than basic best-effort services such as Internet content. To this end, the terminal receives various QoS parameter sets from a base station (hereinafter referred to as a BS).

The 802.16 specification classifies three QoS parameter sets that a service flow can have, namely, provisioned QoS parameter sets, admitted QoS parameter sets, and active QoS parameter sets (IEEE 802.16D5 6.3. See 14.2 Service Flow). That is, there are three types of service flows. The first provisioned is a state in which a service flow characteristic is set and only a service flow identifier (SFID) is assigned. A service flow identifier (SFID) is an ID assigned to a service flow by a base station. The terminal logically exists with multiple connections and service flows with the base station, and conections exist for each service flow. In the portable Internet, Service Flow ID (hereinafter referred to as SFID) and Connection ID (hereinafter referred to as CID) are used to distinguish between different service flows and connections.

Second Admitted is a state in which resources are reserved, but are not actually active, and a 16 bit CID (Connection Identifier) identifying a connection is allocated by a base station. Finally, Active is using the actual resources. Among these, the QoS parameter set through which data can be transmitted and received is an active QoS parameter set to which an active connection for transmission is assigned.

2 is a diagram illustrating a message flow when setting a service flow between a terminal and a base station.

Referring to FIG. 2, the terminal 30 transmits a service flow addition (DSA) REQ message to the base station 20 in step 112. Subsequently, the base station 20 transmits a DSA-RSP message including the provisioned service flow information to the terminal in step 114. That is, when the terminal 30 requests the possible service flow to the base station 20, the base station 20 performs the DSA procedure 110 by transmitting the possible service flow information to the terminal 30.

Subsequently, the terminal 30 transmits a dynamic service change (DSC) REQ message requesting a desired service flow among the service flows proposed by the base station 20 in step 122. Then, the base station 20 establishes an active connection with the terminal 30 by transmitting a Dynamic Service Change (DSC) RSP message to the terminal 30 in step 124. As such, the terminal 30 and the base station 20 may establish an active connection only after passing through the DSA procedure 110 and the DSC procedure 120. That is, when a service flow, which is a provisioned QoS parameter set, is changed to a service flow, which is an active QoS parameter set, a transmittable active connection is allocated.

The terminal may transmit data through the connection allocated to the service flow configured as described above. Specifically, if there is data to be transmitted, the terminal finds a service flow that matches the QoS of the data to be transmitted. The terminal parses the data to be transmitted to find the service flow and checks whether it matches with an IP destination address, a source port, etc. (see IEEE 802.16D5 11.13.19.2 CS Parameter Encoding). Therefore, if all items match, the terminal finds a service flow that matches the QoS of the data to be transmitted. However, if the matching Service Flow is a Provisioned QoS Parameter Set or an Admitted QoS Parameter Set, the UE must perform a DSC (Dynamic Service Change) process with the BS to change to the Active QoS parameter set. In this case, the UE needs to store or discard data in a buffer until the end of the DSC process and the service flow is changed to the active QoS parameter set. Because Provisioned QoS Parameter Set or Admitted QoS Parameter Set has SFID but service is not enabled, Active connection is not assigned (see IEEE 802.16D5 6.3.14 QoS). does not exist. That is, if the service flow is not active, there is no active connection corresponding to the service flow, so data cannot be transmitted.

When this happens, several problems arise. Data that needs to be transferred until the end of DSC with BS may fail or, in the worst case, data discard may occur due to buffer overflow.

The present invention provides a method and apparatus capable of minimizing data transfer without using a buffer in order to remedy this problem.

To this end, the data transmission apparatus in the portable Internet system according to an embodiment of the present invention finds an active service flow matching the QoS of the data to be transmitted when receiving data to be transmitted, and if there is no matching active service flow, an active alternative to the corresponding service flow. And a data classification unit for transmitting the data through a connection, and a service flow setting unit for performing a DSC procedure for a service flow matching the QoS of the data to be transmitted.

According to another aspect of the present invention, there is provided a method of transmitting data in a portable Internet system, the method comprising: finding an active service flow matching a QoS of data to be transmitted when data is transmitted; and matching the QoS of the data to be transmitted if there is no matching active service flow. Performing a DSC procedure for the service flow, and transmitting the data over an alternative active connection.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In addition, detailed descriptions of well-known functions and configurations that may unnecessarily obscure the subject matter of the present invention will be omitted.

According to an embodiment of the present invention, if there is data to be transmitted in the portable Internet system, the terminal searches for a service flow matching the QoS of the data to be transmitted. If there is no service flow that matches the QoS of the data to be transmitted, the terminal stores the service flow ID (SFID) of the corresponding service flow and performs the BS and DSC process based on the stored SFID in the case of the provisioned QoS parameter or the admitted QoS parameter set. . Thereafter, if the terminal has an alternative active connection, the terminal transmits data through the alternative active connection, and if not, discards the data.

After storing the SFID used in the DSC process in the list, the UE does not request the DSC from the base station when there is a request for data transmission through the same service flow in a state in which the DSC process for the SFID is not completed. The terminal then transmits the requested data through an alternative active connection. This alternative active connection may be an active connection for a BE that does not guarantee QoS. That is, the terminal stores the SFID to request the DSC in the list when the terminal transmits data in the corresponding service flow (ie SFID) until the end of the DSC process, so that the DSC request or buffer data is not stored or discarded. Can be sent over BE Active connection.

After the successful completion of the DSC process, the UE is assigned a corresponding service flow that is enabled, changed to an active QoS parameter set, and an active connection capable of data transmission. In addition, the terminal deletes the SFID stored for the DSC after the DSC (Initiation). The configuration of the terminal according to the embodiment of the present invention described above will be described with reference to FIG. 3.

3 is a block diagram of a terminal in a preferred embodiment of the present invention.

Referring to FIG. 3, the terminal 200 includes a data receiver 210, a data classifier 220, a service flow setup unit 230, a data processor 240, and a transmitter 250. The data receiver 210 receives data to be transmitted from an upper layer. The upper layer may be an application layer. When data transmission is requested from a higher layer, the data receiver 210 receives data from a higher layer. When the data receiver 210 receives data to be transmitted, the data receiver 210 transmits the data to the data classifier 220. When the data classifier 220 receives the data to be transmitted from the data receiver 210, the data classifier 220 classifies the data to be transmitted according to the QoS. That is, data to be transmitted may be classified according to its service, that is, according to QoS.

For example, when describing services in IEEE 802.16, services in IEEE 802.16 include Unsolicited Grant Services (UGS), Real-Time Polling Services (rtPS), Non-Real-Time Polling Services (nrtPS), and Best Effort (BE) Services. Can be classified as UGS supports Constant Bit Rate (CBR) such as T1 / E1 emulation and Voice Over IP (VoIP) without silence suppression. rtPS supports real-time services that generate variable size data packets on a periodic basis, such as MPEG video or VoIP without silence compression. nrtPS supports non-real-time services that require a variable size data grant burst type on a regular basis. Finally, BE (Best Effort) Services are typically provided by the Internet for web surfing today. Among these services, since UGS service such as VoIP and rtPS service such as MPEG video are provided in real time, even if an error occurs in the currently transmitted data, it is not necessary to correct the error data at the next transmission. As such, the data to be transmitted is transmitted through a connection of different service flows according to the service.

Therefore, the data classifying unit 220 appropriately determines the service flow according to the service of the data to be transmitted. That is, the data classifier 220 searches for which service flow the QoS of the data to be transmitted matches the provided QoS. The data classifying unit 220 parses the received data, checks an IP destination address, a source port, and the like and checks which service flows provide QoS. Then, if all items match, the data classifier 220 finds a service flow that matches the QoS of the data to be transmitted. The data classifier 220 may search and determine which connection should be transmitted when a matching service flow is found. If the QoS parameter set of the corresponding service flow is active, the data classifier 220 outputs data to be transmitted to the data processor 240 so that data is transmitted through an active connection allocated to the corresponding service flow. The data processor 240 processes the data to be suitable for transmitting data and outputs the data to the transmitter 250. The transmitter 250 transmits the data to the receiver when data is input from the data processor 240.

If the QoS parameter set of the searched service flow is a provisioned QoS parameter set or an admitted QoS parameter set, the data classifier 220 performs a DSC procedure on the corresponding service flow through the service flow setting unit 230. The service flow setting unit 230 performs a DSC procedure on the service flow when receiving the request for the progress of the DSC procedure from the data classifying unit 220. To this end, the service flow setting unit 230 generates a message according to the DSC procedure and transmits it through the transmitter 250. At this time, the service flow setting unit 230 stores the SFID of the initiated DSC. Thereafter, the service flow setting unit 230 deletes the SFID that the DSC procedure has successfully completed among the stored SFIDs.

 If the service flow that has been requested to proceed with the DSC procedure is a service flow that is already in the DSC procedure, the service flow setting unit 230 disregards the progress request of the DSC procedure for the corresponding service flow.

In addition, the data classifier 220 searches for an alternative active connection if there is no service flow matching the QoS of the data to be transmitted. Specifically, the data classifier 220 checks whether there is no active service flow that matches the QoS of the data to be transmitted, but there are alternative active connections. If there is an alternative active connection, the data classifier 220 outputs data to be transmitted to the data processor 240 to transmit data through the alternative active connection. The alternative active connection is an active active connection that does not match the QoS of the data to be transmitted. In general, a connection established basically between a terminal and a base station is a connection for BE (Best Effort) Services. This BE active connection can be an alternative active connection. Of course, if there are several connections established between the base station and the terminal, it is preferable that the alternative active connection is a similar or high QoS active connection.

Subsequently, when DSC is successfully completed with the base station, the QoS parameter set of the service flow is changed to the active QoS parameter set, and when the service flow is enabled, the data classifier 220 is active to match the data transmitted through the alternative active connection. Send over the connection.

Accordingly, when the data classification unit 220 needs to transmit new data again, if the searched service flow is a service flow that has previously been DSC, it is already changed to an active QoS parameter set by the DSC, and thus the data classification unit 220 transmits data to the assigned active connection. will be.

4 is a diagram illustrating a control flow during data transmission in a terminal according to an embodiment of the present invention.

Referring to FIG. 4, the terminal 200 determines whether there is a data transmission request in step 302. This data transfer request may occur at the application layer. When the data transmission is requested, the terminal 200 proceeds to step 304 and classifies the data to be transmitted according to the QoS of the corresponding data. In operation 306, the terminal 200 searches for a service flow that matches the QoS of data to be transmitted. That is, the terminal 200 finds out which service flow the QoS of the data to be transmitted corresponds to. In step 308, the terminal 200 determines whether the QoS parameter set of the corresponding service flow is active. If the matching service flow is the active service flow, the terminal 200 transmits data through the active connection of the corresponding service flow in step 310.

If the corresponding service flow is not the active service flow, the terminal 200 proceeds to step 312 to determine whether the DSC procedure is in progress for the service flow. If the service flow is not in the DSC procedure, the terminal 200 proceeds to step 314 to initiate a DSC procedure for the service flow, stores the SFID of the initiated DSC, and proceeds to step 316. If the service flow that has been requested to proceed with the DSC procedure is a service flow that is already in the DSC procedure, the service flow setting unit 230 disregards the progress request of the DSC procedure for the corresponding service flow.

If the corresponding service flow is in the process of DSC, the terminal 200 proceeds to step 316 to check whether there is an alternative active connection. If there is an alternative active connection, the data classifier 220 transmits data via the alternative active connection at step 318. As described above, an alternative active connection refers to an active active connection that does not match the QoS of the data to be transmitted. If there is no alternative active connection, the data classifying unit 220 proceeds to step 320 and discards the data to be transmitted.

After the successful completion of the DSC with the base station, the QoS parameter set of the service flow is changed to an active QoS parameter set. When the service flow is enabled, the terminal transmits data transmitted through an alternative active connection through a matching active connection. . The terminal 200 deletes the SFID from which the DSC procedure is successfully completed, among the stored SFIDs.

In the above description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be defined by the described embodiments, but should be determined by the equivalent of claims and claims.

According to the present invention as described above, unnecessary use of the buffer will be reduced when used in the terminal or the BS. During the DSC process, if the service flow that matches the data to be transmitted is not an active QoS parameter set in the terminal or BS, and there is no active connection, the data proposed by the present invention can be processed. More effective performance improvement can be expected in the terminal or the BS used.

Claims (11)

A data transmission apparatus in a portable internet system, A data classification unit for finding an active service flow matching the QoS of the data to be transmitted when receiving the data to be transmitted, and transmitting the data through an alternative active connection to the corresponding service flow if there is no matching active service flow; And a service flow setting unit for performing a DSC procedure for a service flow that matches the QoS of the data to be transmitted. The transmission apparatus according to claim 1, further comprising a transmission unit for transmitting the data. The transmission apparatus of claim 1, wherein the service flow setting unit ignores the request for proceeding of the requested DSC procedure if the service flow ID of the DSC procedure currently requested is a service flow of a DSC procedure being performed. The apparatus of claim 1, wherein the data classifying unit parses data to be transmitted to determine an service flow of the data to be transmitted based on an IP destination address or a source port. The apparatus of claim 1, wherein the service flow setting unit stores the service flow ID of the DSC procedure and deletes the stored service flow ID when the DSC procedure is successfully terminated. 2. The transmission apparatus of claim 1, wherein the alternative active connection is an active connection for a best effort (BE) that does not guarantee QoS. In the data transmission method in the portable Internet system, Finding an active service flow that matches the QoS of the data to be transmitted when provided with data to transmit; Performing a DSC procedure for a service flow that matches the QoS of the data to be transmitted if there is no matching active service flow; Transmitting the data over an alternative active connection. 8. The method of claim 7, further comprising ignoring the request for progress of the requested DSC procedure if the service flow ID of the currently requested DSC procedure is a service flow of the DSC procedure being performed. 8. The method of claim 7, wherein the step of finding an active service flow comprises parsing data to be transmitted and referencing an IP destination address or source port. 8. The method of claim 7, further comprising storing the service flow ID of the DSC procedure and deleting the stored service flow ID if the DSC procedure is successfully terminated. 8. The method of claim 7, wherein the alternative active connection is an active connection for Best Effort (BE) that does not guarantee QoS.

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