KR100706981B1 - Method and system for indicating service-ready status on wibro network - Google Patents

Abstract

The present invention relates to a system and method for identifying a service availability state of a mobile communication terminal in a portable internet network.

The present invention relates to a method for determining a service availability state of a mobile communication terminal by allocating an uplink bandwidth, wherein the power of the mobile communication terminal is changed to an on state so that a radio access station (RAS) is provided. Initiating an uplink resource allocation counter for the mobile communication terminal by the radio access station when entering the area of the network; (b) the radio access station allocating a predetermined size of an uplink resource for transmitting a bandwidth request header to the uplink map (UpLink-MAP) at regular intervals; (c) checking whether a bandwidth request header has been received from the mobile communication terminal; (d) If it is determined in step (c) that the bandwidth request header is received from the mobile communication terminal, the uplink resource allocation counter is initialized, and the system resource of the portable internet network allocated to the mobile communication terminal is maintained. Making; (e) incrementing an uplink resource allocation counter if it is determined in step (c) that the bandwidth request header has not been received from the mobile communication terminal; (f) checking whether the resource allocation counter has exceeded a predetermined number set by the radio access station; And (g) recovering system resources of the mobile Internet allocated to the mobile communication terminal if it is determined in step (f) that the uplink resource allocation counter has exceeded a predetermined number of times set by the radio access station. The present invention provides a method for determining a service availability state of a mobile communication terminal in a portable internet network.

According to the present invention, a bandwidth request header is allocated when an uplink bandwidth having a predetermined size is allocated to an uplink map (UL-MAP) at a predetermined period in a mobile Internet network, and a mobile communication terminal is allocated an unrequested uplink bandwidth. The bandwidth request field in the packet) is filled with a certain value and transmitted to the mobile Internet network. If there is no response to the uplink bandwidth allocated to the mobile communication terminal at regular intervals, the mobile communication terminal is in an unserviceable state. By recognizing that there is, it is possible to recover the resources allocated to the mobile communication terminal in the service unavailable state to increase the resource utilization of the portable Internet network, and to prevent abnormal incoming call to prevent the charge generation error.

Mobile Internet, WiBro, Wibro, Mobile Terminal, Resource Allocation

Description

System and method for identifying service availability status of mobile communication terminal in portable internet network {Method and System for Indicating Service-Ready Status on Wibro Network}

1 is a block diagram showing an OFDMA frame structure of a conventional portable Internet network;

2 is a diagram schematically showing a system for identifying a service availability state of a mobile communication terminal according to an embodiment of the present invention;

3 is a flowchart illustrating a process of identifying a service availability state of a mobile communication terminal in a portable Internet network according to a first embodiment of the present invention;

4 is a flowchart illustrating a process of identifying a service availability state of a mobile communication terminal in a portable Internet network according to a second embodiment of the present invention;

5 is a flowchart illustrating a process of identifying a service availability state of a mobile communication terminal in a portable Internet network according to a third embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

100: assignable band 110: downlink

112: preamble 120: uplink

130: PUSC subchannel 140: diversity subchannel

142: Tile 150: AMC Subchannel

152: empty 160: TTG

170: RTG 200: mobile communication terminal

210: radio access station 220: access control router

230: home agent 240: IP network

250: Internet 260: Authentication Server

270: Data Service Server 280: NMS Server

290: Location Management Server

The present invention relates to a system and method for identifying a service availability state of a mobile communication terminal in a portable internet network. More specifically, when a certain amount of uplink bandwidth is allocated to an uplink map (UL-MAP) at a predetermined period in a mobile Internet network, and a mobile communication terminal is allocated an unrequested uplink bandwidth, a bandwidth request header is provided. The bandwidth request field in the packet) is filled with a predetermined value and transmitted to the mobile Internet network, and when there is no response for the uplink bandwidth allocated to the mobile communication terminal at regular intervals, the mobile communication terminal is in an unserviceable state. It relates to a system and method for determining that there is.

The mobile communication system has been developed through the first generation analog AMPS (Advanced Mobile Phone System) method and the second generation cellular (Cellular) / Personal Communication Service (PCS) method. The third generation mobile communication system IMT-2000 (International Mobile Telecommunication 2000), which is enacted as a standard in ITU-R, is commercially available.

The IMT-2000 is classified into the synchronous CDMA 2000 1X, 3X, and EV-DO systems proposed by 3GPP2 as the main axis, and the asynchronous WCDMA (Wideband CDMA) system proposed by the 3GPP (Generation Partnership Project).

In the CDMA-2000 system, a wireless access technology and a mobile communication technology are based on the CDMA method. Therefore, since it has backward compatibility with the existing second-generation IS-95 network, it is possible to provide a mobile communication service using both second and third generation communication networks. In addition, a mobile Internet Protocol (IP) function similar to a handoff of a voice call may be supported, and a roaming service using a removable user identity module (R-UIM) card may be provided. In addition, it is possible to provide wireless Internet service at 144 kbps (up to 307.2 kbps), which is much faster than 14.4 kbps or 56 kbps, which was supported in the existing network. In particular, 1x EV-DO, a packet dedicated network for high-speed packet transmission, may provide bidirectional high-speed data service at a transmission rate of up to 2.4 Mbps.

WCDMA system uses the CDMA method for wireless access technology, but mobile communication network technology is based on GSM network technology. The WCDMA communication method adopts Adaptive Multi-Rate Vocoder (AMR), which has a transmission rate of 4.75 kbps to 12.2 kbps for voice coding, and supports a high degree of mobility that allows a call even when the user moves at a speed of about 100 km per hour. . In addition, since the frequency bandwidth is widened to 5 Mhz and has a data transfer rate of 2 Mbps, it is suitable for high-speed data transmission. Diversity according to reverse call quality that cannot be provided by the IS-95 and GSM methods. Provides good call and data transmission performance even in poor communication environments.

On the other hand, the conventional CDMA network and WCDMA network is a dedicated circuit channel (Dedicated Circuit Channel) scheme that maintains a fixed channel resources until the call is terminated when the mobile communication terminal attempts a call. Therefore, it is possible to drop a call by determining an error or loss of a traffic frame transmitted in both directions on a fixed channel, and to release all internal and radio resources for the call. In case of a CDMA network, if a frame of 20 ms period becomes a bad frame for 5 seconds or is not transmitted, the call is terminated and the system and radio resources are released.

However, portable Internet networks and WiMAX networks based on Institute of Electrical and Electronics Engineers (IEEE) 802.16e and 802.16-2004 do not use a fixed channel allocation scheme for mobile communication terminals. When the mobile communication terminal registers with the mobile internet network after entering the mobile internet network, if there is no incoming packet or outgoing packet transmitted to the mobile internet network in the cell, an ID for identifying the mobile internet network (Identification) ), There is no communication with the mobile Internet network, and only broadcast messages such as downlink map (DL-MAP) or uplink map (UL-MAP) are transmitted every 5 ms. It checks and monitors whether there is an event to be answered by the mobile Internet network.

1 is a block diagram showing an OFDMA frame structure of a portable Internet network according to a preferred embodiment of the present invention.

Slots in the portable Internet standard are designated in two-dimensional space according to the number of symbols and the number of subcarriers in the time and frequency domain, respectively, and the symbols become the minimum unit of allocation.

Slots depend on how subchannels are actually configured on the uplink 120 and downlink 110. In the mobile Internet, subcarrier allocation is a diversity subchannel by grouping subcarriers scattered by permutation. And a method of configuring 140 and a method of configuring AMC (Adaptive Modulation and Coding) subchannel 150 by tying physically contiguous subcarriers for each band.

The first symbol of the downlink 110 is assigned a preamble 112, and the preamble is used for frame synchronization and cell division. A TTG (Transmit / recieve Transition Gap) 160 is inserted between the downlink 110 and the uplink 120, and a Receive / transmit Transition Gap (RTG) 170 is inserted between the end of the frame and the start of the frame, thereby providing a maximum coverage of 1 km. To accept. The 5 ms long frame consists of 42 OFDM symbols, TTG 160 and RTG 170. Downlink 110 transmission begins with one preamble symbol, a frame control header (FCH), a DL-MAP, and a data symbol. The two symbols immediately following the preamble 112 are always used as the Partial Usage SubChannel (PUSC) subchannel 130 and include a 24-bit FCH for transmitting frame configuration information. PUSC is a concept of allocating different subchannels by sector by dividing subchannels without using all subchannels in one sector. This is contrary to Full Usage SubChannel (FUSC), which uses all subchannels in a sector. .

In the case of the uplink 120, the first three symbols are used to transmit control information such as ranging and channel quality indicators. There are three types of subchannels in the downlink frame: PUSC subchannel 130, diversity subchannel 140, and AMC subchannel 150. There are two types of subchannels in the uplink frame: diversity subchannel 140 and AMC subchannel 150. The diversity subchannel 140 scatters the entire band to form a subcarrier and changes its permutation in symbol units, thereby obtaining a diversity effect in the frequency domain. For diversity subchannel 140, one slot in downlink 110 consists of one subchannel and one OFDMA symbol and one slot in uplink 120 includes one subchannel and three OFDMA It consists of a symbol.

Since the AMC subchannel 150 is configured by concatenating consecutive subcarriers for each band, it is possible to maximize bandwidth efficiency by selecting and allocating a band having a good channel state. In the case of the AMC subchannel 150, one slot in the downlink 110 and the uplink 120 are configured with one subchannel and one OFDMA symbol. The subchannels of the downlink 110 and the uplink 120 have separate transmission intervals consisting of consecutive symbols, and the PUSC subchannel 130 of the downlink 110 is defined over two symbols, one The PUSC subchannel 130 is composed of four pilot subcarriers and 48 data subcarriers. The diversity subchannel 140 of the downlink 110 is composed of 48 subcarriers selected from valid subcarriers available in one symbol. The basic allocation unit constituting the diversity subchannel 140 of the uplink 120 is a tile 142 formed by collecting three adjacent subcarriers in three consecutive symbol intervals, or in three consecutive symbol intervals. A tile (including four pilot subcarriers) 142 formed by collecting four adjacent subcarriers may be used.

The diversity subchannel 140 of the uplink 120 consists of six tiles 142, each tile 142 being distributed over the entire frequency band. The basic unit constituting the AMC subchannel 150 of the downlink 110 and the uplink 120 is a bin 152, and the bin 152 is composed of nine adjacent subcarriers in the same symbol. The AMC subchannel section of the link 110 and uplink 120 is composed of a plurality of bands and there are four bins 152 in one band.

The AMC subchannel 150 of the downlink 110 and uplink 120 is comprised of six adjacent bins 152 present in the same band. Here, the position of the pilot subcarrier is determined according to the position of the bin 152 and the position of the symbol. After the RTG 170, the subchannel in the first symbol after the preamble 112 of each frame is allocated an FCH, and is a region for transmitting a downlink frame prefix (DL_Frame_Prefix), and the downlink frame prefix is a DL-MAP that follows later. Information related to the current frame is transmitted, including the length of the message, the repetitive coding and the channel coding scheme applied to the DL-MAP. The downlink frame prefix consists of all 24 bits, which are repeated in a 48-bit FEC block, transmitted through QPSK modulation, R = 1/2 encoding, and sent four times.

For example, when receiving an incoming packet from a mobile communication terminal, the mobile Internet network unilaterally allocates a radio resource using a downlink map, and when transmitting an outgoing packet to the mobile communication terminal, the upload bandwidth request process is performed. After the link resource is allocated using the uplink map, the packet is transmitted to the portable Internet network using the uplink resource.

Therefore, there is no resource that is fixedly allocated to the mobile communication terminal, and only the one-way resource is allocated to the requester of resource allocation, instead of allocating a bidirectional resource during traffic transmission. use.

However, when the mobile terminal enters the shadow area after the mobile terminal enters the mobile internet network or when the power of the mobile terminal is turned off, the mobile internet network does not recognize the unserviceable state of the mobile terminal. There is a problem in keeping the system resources allocated. Since the mobile Internet network cannot grasp the service availability of the mobile communication terminal, it allocates resources for download traffic to the mobile communication terminal and transmits the packet. The mobile communication terminal does not receive the packet, but the mobile communication terminal does not receive the packet. There is a problem of judging received.

In addition, when the mobile communication terminal enters the shadow area while receiving the download traffic, the mobile Internet network does not grasp the service availability state of the mobile communication terminal and allocates resources for download traffic to the mobile communication terminal and transmits the packet. Although the mobile communication terminal does not receive the packet, there is a problem in that the mobile communication terminal determines that the packet has been received.

In order to solve this problem, the present invention allocates a certain amount of uplink bandwidth to an uplink map (UL-MAP) at regular intervals in a portable Internet network, and the mobile communication terminal requests a bandwidth request when an uplink bandwidth is not requested. Fills the bandwidth request field in the bandwidth request header with a certain value and transmits it to the mobile internet network.In the mobile internet network, if there is no response to the uplink bandwidth allocated to the mobile terminal at regular intervals, the mobile communication is performed. It is an object of the present invention to provide a system and method for determining that a terminal is in a service unserviceable state.

In order to achieve the above object, according to the first object of the present invention, in the method for determining the service availability state of the mobile communication terminal by allocating uplink bandwidth, (a) the power of the mobile communication terminal is On (On) state Initializing an uplink resource allocation counter for the mobile communication terminal when the radio access station is changed into a radio access station (RAS) within an area of the radio access station; (b) the radio access station allocating a predetermined size of an uplink resource for transmitting a bandwidth request header to the uplink map (UpLink-MAP) at regular intervals; (c) checking whether a bandwidth request header has been received from the mobile communication terminal; (d) If it is determined in step (c) that the bandwidth request header is received from the mobile communication terminal, the uplink resource allocation counter is initialized, and the system resource of the portable internet network allocated to the mobile communication terminal is maintained. Step of doing; (e) incrementing an uplink resource allocation counter if it is determined in step (c) that the bandwidth request header has not been received from the mobile communication terminal; (f) checking whether the resource allocation counter has exceeded a predetermined number set by the radio access station; And (g) recovering system resources of the mobile Internet allocated to the mobile communication terminal if it is determined in step (f) that the uplink resource allocation counter has exceeded a predetermined number of times set by the radio access station. The present invention provides a method for identifying a service availability state of a mobile communication terminal in a portable internet network.

According to a second aspect of the present invention, there is provided a method for determining a service availability state of a mobile communication terminal using a channel quality indicator (CQI) channel, the method comprising: (a) powering the mobile communication terminal to an on state; Assigning a CQI channel to the mobile communication terminal by the radio access station when it is changed and enters an area of a radio access station (RAS); (b) adjusting a downlink burst allocation method and size suitable for each mobile communication terminal while monitoring the CQI channel; (c) checking whether a carrier to interference and noise ratio report is transmitted from the mobile communication terminal; (d) stopping transmission of downlink traffic transmitted to the mobile communication terminal when the CINR report is not transmitted from the mobile communication terminal in step (c); (e) checking whether the report interrupt time, which is a time during which the CINR report is not received, exceeds a predetermined time; And (f) recovering system resources of the mobile Internet allocated to the mobile communication terminal if it is determined in step (e) that the report stop time exceeds a predetermined time. A method of identifying a service available state of a communication terminal is provided.

According to a third object of the present invention, there is provided a method of determining a service availability state of a mobile communication terminal using an acknowledgment (ACK) channel, wherein (a) the power of the mobile communication terminal is changed to an on state. Allocating an ACK channel to the mobile communication terminal when the radio access station enters an area of a radio access station (RAS); (b) checking whether an error report is transmitted from the mobile communication terminal using an ACK channel; (c) stopping transmission of downlink traffic transmitted to the mobile communication terminal when it is determined in step (b) that an error report is not transmitted using the ACK channel; (d) performing step (b) if it is determined in step (b) that an error report has been transmitted using the ACK channel; (e) checking whether the report interrupt time, which is a time during which an error report is not received, exceeds a predetermined time; And (f) recovering the system resources of the mobile Internet allocated to the mobile communication terminal when it is determined in step (e) that the report stop time exceeds a predetermined time. Provides a way to determine the service availability of a service.

In addition, according to a fourth object of the present invention, in a system for identifying a service availability state of a mobile communication terminal in a portable internet network, the access control is an access point (AP) of the portable internet network. It acts as a data repeater to wirelessly transmit data received from the router to the mobile communication terminal or to transmit data received from the mobile communication terminal to the access control router, and the controller function, orthogonal frequency division multiple access (OFDMA) / time division Supports Duplex (TDD) packet scheduling and channel multiplexing, MAC frame variable control according to service characteristics and propagation environment, and Hybrid-Autometic Repeat Request (H-ARQ), and uploads to an uplink map sent to a mobile terminal. A radio access station for allocating a link control channel; And a backbone network for data transmission and reception in a mobile Internet network, which connects an access control router, a home agent, an authentication server, and a network management server (NMS) server to each other, and provides the Internet and various kinds of contents. The present invention provides a system for identifying a service availability state of a mobile communication terminal, including an IP network receiving packet data from an external packet data service server including a data service server and transmitting the packet data to an access control router.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. First of all, in adding reference numerals to the components of each drawing, it should be noted that the same reference numerals are used as much as possible even if displayed on different drawings. In addition, in describing the present invention, when it is determined that the detailed description of the related well-known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

2 is a diagram schematically illustrating a system for identifying a service available state of a mobile communication terminal according to an exemplary embodiment of the present invention.

A system for determining a service availability state of a mobile communication terminal using a portable Internet network according to an embodiment of the present invention includes a mobile communication terminal 200, a radio access station (RAS) 210, and an access control router. (ACR: Access Control Router) 220, Home Agent (HA) 230, IP Network 240, Internet 250, Authentication Server 260, Database Server 270, NMS (Network) Management Server) server 280 and location management server 290.

Here, one network including a radio access station 210, an access control router 220, a home agent 230, an IP network 240, an authentication server 260, and a location management server 290 will be described. It will be referred to as a portable Internet network for.

The mobile communication terminal 200 according to the preferred embodiment of the present invention is a portable terminal provided with a portable Internet service from a portable Internet network, and is connected to the portable Internet network by an Orthogonal Frequency Division Multiple Access (OFDMA). It refers to a mobile communication terminal using a mobile Internet service, and it is equipped with a low power RF (Radio Frequency) / IF (Intermediate Frequency) module, and has a MAC (Media Access Control) frame variable control function and handoff according to service characteristics and radio wave environment. Function, multicast service reception function, interworking function with other network, user authentication and encryption function, and select the band to transmit / receive data through portable internet network, and select the ratio of signal-to-interference and noise of the selected band (SINR). Signal to Interference and Noise Ratio is measured and transmitted to the radio access station. It is a device with a function.

In addition, the mobile communication terminal 200 is equipped with a browser for accessing the Internet for accessing the portable Internet system to use the portable Internet service, accessing the radio access station 210, and initiating a connection with the portable Internet network. The access station 210 transmits and receives data used for any portable Internet service.

In the present invention, the mobile communication terminal 200 transmits the bandwidth request header to the mobile Internet network by filling the bandwidth request field in the bandwidth request header with 0 when the unrequested uplink bandwidth is allocated from the mobile internet network.

Here, the mobile communication terminal 200 is a personal digital assistant (PDA), hand-held PC (Hand-Held PC), notebook PC, smart phone, multi-mode multi-band (MM-MB) In general, a smart phone is a terminal that combines the advantages of a mobile communication terminal and a personal digital assistant, and integrates data communication functions such as schedule management, fax transmission and Internet access, etc. Means the terminal. In addition, the mobile communication terminal 200 according to a preferred embodiment of the present invention refers to a terminal capable of operating not only in a portable Internet system but also in other mobile communication systems, for example, a CDMA 2000 system, a WCDMA system, and the like.

The radio access station 210 according to the preferred embodiment of the present invention is an access point (AP) of a portable Internet network, and wirelessly transmits data received from the access control router 220 to the mobile communication terminal 200. Or as a data repeater for transmitting data received from the mobile communication terminal 200 to the access control router 220, the controller function, orthogonal frequency division multiple access (OFDMA) / time division duplex (TDD) packet scheduling and channel multiplexing MAC frame variable control function, 50 Mbps high-speed traffic real-time control function, handoff support function, downlink multicast function, billing, statistical information generation and notification function, authentication and security function, etc. Support.

In the present invention, the radio access station 210 allocates a predetermined size of uplink bandwidth to the mobile communication terminal 200 at regular intervals. For example, the radio access station 210 allocates a 6-byte uplink bandwidth as an uplink map so that the mobile terminal 200 can transmit a bandwidth request header, and the mobile terminal 200 The bandwidth request field in the bandwidth request header received from the controller is checked to determine that the mobile communication terminal 200 is in a serviceable state when the bandwidth request field is filled with zero.

The access control router 220 is a base station controller of the portable Internet system. The access control router 220 accommodates a plurality of radio access stations 210 and connects the IP network 130 with a plurality of radio access devices or between a plurality of radio access devices. As a packet access router, a handover control function between a plurality of radio access devices, a handover function between a plurality of access control routers 220, a base station of another network (for example, a CDMA 2000 network, a WCDMA network, etc.) and a plurality of radio access devices. It has a handover function, a packet routing function, an internet access function, and the like, and is connected to the IP network 240.

The home agent 230 refers to software that performs a function of routing a packet transmitted from the outside through the Internet 250 when the mobile IP is used in the portable Internet system, and hardware coupled thereto.

The location management server 290 refers to software for managing the subscriber's status information and location information and hardware associated therewith. When the location management server 290 provides an incoming service to the mobile communication terminal 200 from a specific node (for example, a switch connected to a mobile Internet network or a mobile communication network, an application server connected to the Internet 250, etc.), The location information of the communication terminal 200 is retrieved and transmitted to the access control router 220. In addition, the home agent 230 stores and manages subscriber status information, subscriber location information, subscriber service information, and the like.

IP network 240 according to a preferred embodiment of the present invention is a backbone network for transmitting and receiving data in a portable Internet network, and includes a plurality of network equipment such as a router. In addition, the IP network 240 connects the access control router 220, the home agent 230, the authentication server 260 and the NMS (Network Management Server) server 280, the Internet 250 and various kinds The packet data is received from an external packet data service server including a data service server 270 that provides the content of the packet data, and transmitted to the access control router 220.

The authentication server 260 performs an authentication on the packet data used by the mobile communication terminal 200 in cooperation with the access control router 220, and performs software for performing location identification on the mobile communication terminal 200 and coupled thereto. Means hardware.

The NMS server 280 functions to establish a central monitoring system of network equipment to monitor, plan, and analyze the data, and to store related data so that it can be immediately used as needed.

3 is a flowchart illustrating a process of identifying a service availability state of a mobile communication terminal in a portable Internet network according to a first embodiment of the present invention.

When the power of the mobile communication terminal 200 is changed to an on state and enters the area of the radio access station 210, the radio access station 210 initializes an uplink resource allocation counter for the mobile communication terminal 200. (S300).

In order to determine the service availability state of the mobile communication terminal 200, the radio access station 210 allocates uplink resources for transmitting a bandwidth request header to the uplink map at a predetermined size in a predetermined period (S302).

In the present invention, the predetermined period is set to a time smaller than the communication interruption time, which is a criterion for determining the interruption of communication between the mobile communication terminal 200 and the radio access station 210. This is because the radio access station 210 determines that the communication with the mobile terminal 200 is stopped when the period for allocating the bandwidth request header transmission uplink resource is greater than the communication stop time.

In the present invention, a predetermined size is designated as an uplink bandwidth of 6 bytes that can transmit a bandwidth request header.

The mobile communication terminal 200 receiving the uplink map from the radio access station 210 analyzes the received uplink map and, when there is an uplink resource that the mobile communication terminal 200 does not request, bandwidth in the bandwidth request header. The bandwidth field is sent to the radio access station 210 by filling the BR field with a predetermined value.

In the present invention, the predetermined value that the mobile communication terminal 200 fills in the bandwidth request field is a value promised between the mobile communication terminal 200 and the radio access station 210 and excludes a value used for allocation of uplink resources. Say

The radio access station 210 checks whether the bandwidth request header has been received from the mobile communication terminal 200 (S304).

If it is determined in step S304 that the bandwidth request header is received from the mobile communication terminal 200, the radio access station 210 analyzes the bandwidth request header received from the mobile communication terminal 200, and the bandwidth request field in the bandwidth request header is set to a predetermined value. Check whether or not (S306).

If it is determined in step S304 that the bandwidth request header has not been received from the mobile communication terminal 200, the radio access station 210 increments the uplink resource allocation counter (S308).

If it is determined in step S306 that the bandwidth request field in the bandwidth request header is a predetermined value, the radio access station 210 initializes the uplink resource allocation counter and controls to maintain the mobile Internet system resources allocated to the mobile communication terminal 200. (S310).

If it is determined in step S306 that the bandwidth request field in the bandwidth request header is not a predetermined value, the radio access station 210 controls the mobile communication terminal 200 to allocate an uplink resource with a value filled in the bandwidth request field, and the uplink resource The allocation counter is initialized and controlled to maintain the mobile Internet system resources allocated to the mobile communication terminal 200 (S312).

The radio access station 210 that has incremented the uplink resource allocation counter checks whether the uplink resource allocation counter has exceeded a predetermined number of times set by the radio access station 210 (S314).

If it is determined in step S314 that the uplink resource allocation counter has exceeded the predetermined number of times set by the radio access station 210, the radio access station 210 recovers the system resources of the portable Internet system allocated to the mobile communication terminal 200. (S316).

If it is determined in step S314 that the uplink resource allocation counter has not exceeded the predetermined number of times set by the radio access station 210, step S300 is repeatedly performed.

4 is a flowchart illustrating a process of identifying a service availability state of a mobile communication terminal in a portable Internet network according to a second embodiment of the present invention.

The mobile Internet network allocates and uses a CQI (Channel Quality Indicator) channel to identify the radio wave environment of the mobile communication terminal 200 and to change the transmission method to each mobile communication terminal 200 when transmitting and receiving traffic. .

The CQI channel is one of the uplink control channels, and is dynamically allocated when the radio access station 210 transmits / receives traffic using the UL-Map, and assigns the same CQI channel to a plurality of mobile communications. The terminal 200 may alternately share.

However, the mobile communication terminal 200 should transmit downlink carrier to interference and noise ratio (CINR) to the radio access station 210 at regular intervals by using the CQI channel during traffic transmission and reception.

When the power of the mobile communication terminal 200 is changed to an on state and enters the area of the radio access station 210, the radio access station 210 transmits a CQI to an uplink control channel allocated to the mobile communication terminal 200. Allocates a channel (S400).

The radio access station 210 allocating the CQI channel adjusts a downlink burst allocation method and size suitable for each mobile communication terminal 200 while monitoring the CQI channel (S402).

While the radio access station 210 monitors the CQI channel, it is checked whether a CINR report is transmitted from the mobile communication terminal 200 (S404).

If it is determined in step S404 that the CINR report has not been transmitted from the mobile communication terminal 200, the radio access station 210 stops transmitting downlink traffic transmitted to the mobile communication terminal 200 (S406).

If it is determined in step S404 that the CINR report is transmitted from the mobile communication terminal 200, the radio access station 210 performs step S402.

The radio access station 210 checks whether the report interrupt time, which is a time during which the CINR report is not received, exceeds a predetermined time (S408).

In the present invention, after a certain period of time, the mobile communication terminal 200 does not receive the downlink map or the uplink map from the radio access station 210, the mobile communication terminal 200 recognizes the unserviceable area and enters the serviceable area to enter the portable Internet network. Set the time beyond the retry procedure.

If it is determined in step S408 that the report interrupt time has exceeded a predetermined time, the radio access station 210 recovers the resources of the portable Internet system allocated to the mobile communication terminal 200 (S410).

If it is determined in step S408 that the report interrupt time has not exceeded a predetermined time, the radio access station 210 performs step S402.

5 is a flowchart illustrating a process of identifying a service availability state of a mobile communication terminal in a portable Internet network according to a third embodiment of the present invention.

When the mobile communication terminal 200 supports H-ARQ when establishing a connection with the radio access station 210, the radio access station 210 allocates an ACK (Acknowledgement) channel to the uplink map (S500). .

The ACK channel is one of the uplink control channels. The ACK channel is dynamically allocated when transmitting and receiving traffic using the uplink map, and transmits an error report of the packet received on the downlink to the radio access station 210. It is used for the purpose.

The radio access station 210 allocating the ACK channel monitors an error report for a packet received by each mobile communication terminal 200 using the downlink through the ACK channel (S502).

While the radio access station 210 monitors the ACK channel, it is checked whether an error report is transmitted from the mobile communication terminal 200 through the ACK channel (S504).

If it is determined in step S504 that no error report is transmitted from the mobile communication terminal 200, the radio access station 210 stops transmitting downlink traffic transmitted to the mobile communication terminal 200 (S506).

If it is determined in step S504 that the error report has been transmitted from the mobile communication terminal 200, the radio access station 210 performs step S502.

The radio access station 210 checks whether the report interrupt time, which is a time during which the error report is not received, exceeds a predetermined time (S508).

In the present invention, after a certain period of time, the mobile communication terminal 200 does not receive the downlink map or the uplink map from the radio access station 210, the mobile communication terminal 200 recognizes the unserviceable area and enters the serviceable area to enter the portable Internet network. Set the time beyond the retry procedure.

If it is determined in step S508 that the report interrupt time has exceeded a predetermined time, the radio access station 210 recovers the resources of the portable Internet system allocated to the mobile communication terminal 200 (S410).

If it is determined in step S508 that the report interrupt time has not exceeded a predetermined time, the radio access station 210 performs step S502.

As described above, the service availability state of the mobile communication terminal can be grasped in the portable Internet network through the first, second, or third embodiments of the present invention. The embodiment, the second embodiment, or the third embodiment may be used in duplicate.

The above description is merely illustrative of the technical idea of the present invention, and those skilled in the art to which the present invention pertains may make various modifications and changes without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention but to describe the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted by the following claims, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

As described above, according to the present invention, a bandwidth request is allocated when a predetermined amount of uplink bandwidth is allocated to an uplink map (UL-MAP) in a portable Internet network, and a mobile communication terminal is allocated an unrequested uplink bandwidth. The bandwidth request field in the bandwidth request header is filled with a predetermined value and transmitted to the mobile internet network. In the mobile internet network, when there is no response to the uplink bandwidth allocated to the mobile communication terminal at regular intervals, the mobile communication terminal By recognizing that the service is in the unserviceable state, it is possible to recover resources allocated to the mobile communication terminal in the unserviceable state, increase the resource utilization of the portable Internet network, and block abnormal incoming to prevent the charge generation error.

Claims (18)

In the method of allocating the uplink bandwidth to determine the service availability state of the mobile communication terminal, (a) When the power of the mobile communication terminal is changed to an on state and enters an area of a radio access station (RAS), the radio access station generates an uplink resource allocation counter for the mobile communication terminal. Initializing; (b) the radio access station allocating a predetermined size of an uplink resource for transmitting a bandwidth request header to an uplink map (UpLink-MAP) at regular intervals; (c) checking whether the bandwidth request header is received from the mobile communication terminal; (d) initializing the uplink resource allocation counter when determining that the bandwidth request header is received from the mobile terminal in step (c), and controlling to maintain system resources of the mobile Internet allocated to the mobile terminal. step; (e) incrementing the uplink resource allocation counter if it is determined in step (c) that the bandwidth request header has not been received from the mobile communication terminal; (f) checking whether the resource allocation counter has exceeded a predetermined number of times set by the radio access station; And (g) recovering the system resources of the portable Internet network allocated to the mobile communication terminal when it is determined in step (f) that the uplink resource allocation counter has exceeded the predetermined number of times set by the radio access station; How to determine the service available state of the mobile communication terminal in a mobile Internet network comprising a. The method of claim 1, wherein the predetermined period, And determining a service available state of the mobile communication terminal in a portable internet network, wherein the mobile communication terminal is set to be less than a communication interruption time which is a time for determining the stop of communication between the mobile communication terminal and the radio access station. The method of claim 1, wherein the predetermined size is, And a size of the bandwidth request header transmitted from the mobile communication terminal to the radio access station. The method of claim 1, wherein the mobile communication terminal, In the portable Internet network, if there is an uplink resource that is not requested by the mobile communication terminal in the uplink map, a predetermined value is recorded in the bandwidth request field in the bandwidth request header and transmitted to the radio access station. How to determine the service availability of the mobile communication terminal. The method of claim 4, wherein the predetermined value is, And a value set between the mobile communication terminal and the radio access station, excluding a value used for allocating the uplink resource. The method of claim 1, Step (d) is, (d1) if it is determined in step (c) that the bandwidth request header is received from the mobile communication terminal, checking whether the bandwidth request field in the bandwidth request header is a predetermined value; (d2) in step (d1), if it is determined that the bandwidth request field in the bandwidth request header is the predetermined value, the uplink resource allocation counter is initialized, and the system resources of the mobile Internet allocated to the mobile communication terminal are determined; Maintaining; And (d3) in step (d1), if it is determined that the bandwidth request field in the bandwidth request header is not the predetermined value, control to allocate an uplink resource to a value of the bandwidth request field, and initialize the uplink resource allocation counter. And maintaining the system resources of the mobile Internet allocated to the mobile communication terminal. How to determine the service available state of the mobile communication terminal in a mobile Internet network comprising a. The method of claim 1, After the step (f), (f1) repeatedly performing step (b) if it is determined in step (f) that the uplink resource allocation counter has not exceeded a predetermined number of times set by the radio access station; How to determine the service available state of the mobile communication terminal in a mobile Internet network comprising a. In the method for determining the service availability state of the mobile communication terminal using a Channel Quality Indicator (CQI) channel, (a) the radio access station assigning the CQI channel to the mobile communication terminal when the power of the mobile communication terminal is changed to an on state and enters an area of a radio access station (RAS); ; (b) adjusting a downlink burst allocation method and size suitable for each of the mobile communication terminals while monitoring the CQI channel; (c) checking whether a CINR report is transmitted from the mobile communication terminal; (d) stopping transmission of downlink traffic transmitted to the mobile communication terminal when it is determined in step (c) that the CINR report has not been transmitted from the mobile communication terminal; (e) checking whether the report interrupt time, which is a time during which the CINR report is not received, exceeds a predetermined time; And (f) recovering the system resources of the mobile Internet allocated to the mobile communication terminal when it is determined in step (e) that the report stop time exceeds the predetermined time; Method of determining the service availability state of the mobile communication terminal using a CQI channel comprising a. The method of claim 8, After step (c), (c1) performing step (b) if it is determined in step (c) that the CINR report has been transmitted from the mobile communication terminal; Method of determining the service availability state of the mobile communication terminal using a CQI channel characterized in that it further comprises. The method of claim 8, wherein the predetermined time, After recognizing that the mobile communication terminal has entered a non-serviceable area because it has not received a downlink map or an uplink map from the radio access station, the mobile terminal enters the serviceable area and retries the procedure of entering the portable Internet network. A method of identifying a service availability state of a mobile communication terminal using the CQI channel, characterized in that the above setting. The method of claim 8, After step (e), (e1) performing step (b) if it is determined in step (e) that the report stop time has not exceeded the predetermined time; Method of determining the service availability state of the mobile communication terminal using a CQI channel comprising a. In the method of identifying the service availability state of the mobile communication terminal using an ACK (Acknowledgement) channel, (a) the radio access station assigning the ACK channel to the mobile communication terminal when the power of the mobile communication terminal is changed to an on state and enters an area of a radio access station (RAS); ; (b) checking whether an error report is transmitted from the mobile communication terminal using the ACK channel; c) stopping transmission of downlink traffic transmitted to the mobile communication terminal when it is determined in step (b) that the error report is not transmitted using the ACK channel; (d) performing step (b) if it is determined in step (b) that the error report has been transmitted using the ACK channel; (e) checking whether the report interrupt time, which is a time during which the error report is not received, exceeds a predetermined time; And (f) recovering the system resources of the mobile Internet allocated to the mobile communication terminal when it is determined in step (e) that the report stop time exceeds a predetermined time; Method of determining the service available state of the mobile communication terminal using an ACK channel comprising a. The method of claim 12, wherein the mobile communication terminal, A method of identifying a service availability state of a mobile communication terminal using an ACK channel characterized in that it supports a hybrid-automatic repeat request (H-ARQ) function. The method of claim 12, After step (e), (e1) controlling to maintain the system resources of the mobile Internet allocated to the mobile communication terminal when it is determined in step (e) that the report stop time has not exceeded a predetermined time; Method of determining the service available state of the mobile communication terminal using an ACK channel comprising a. The method of claim 12, wherein the predetermined time, After recognizing that the mobile communication terminal has entered a non-serviceable area because it has not received a downlink map or an uplink map from the radio access station, the mobile terminal enters the serviceable area and retries the procedure of entering the portable Internet network. Method of determining the service available state of the mobile communication terminal using the ACK channel, characterized in that the above setting. In the system for identifying the service availability state of the mobile communication terminal in a portable Internet network, An access point (AP) of the portable Internet network, which wirelessly transmits data received from an access control router (ACR) to the mobile communication terminal or transmits data received from the mobile communication terminal. It acts as a data relay to the control router, controller function, orthogonal frequency division multiple access (OFDMA) / time division duplex (TDD) packet scheduling and channel multiplexing function, MAC frame variable control function according to service characteristics and propagation environment, and A radio access station (RAS) for supporting a hybrid-automatic repeat request (H-ARQ) function and allocating an uplink control channel to an uplink map transmitted to the mobile communication terminal; And As a backbone network for transmitting and receiving data in the portable Internet network, the access control router, a home agent, an authentication server, and a network management server (NMS) server are connected to each other, and the Internet and various kinds of contents are provided. An IP network receiving packet data from an external packet data service server including a data service server and transmitting the packet data to the access control router. System for grasping the service available state of a mobile communication terminal comprising a. The method of claim 16, wherein the radio access station, Allocating a bandwidth request header (Bandwidth Request Header) transmission uplink resources to the mobile terminal at a predetermined size, and confirms whether or not to receive a bandwidth request header from the mobile terminal at regular intervals, and to the mobile terminal The mobile communication terminal assigns the CQI channel or the ACK by allocating a channel quality indicator (CQI) channel or an acknowledgment (ACK) channel which is an UL control channel to the uplink map transmitted. A system for identifying a service availability state of a mobile communication terminal, comprising: monitoring a report transmitted from a channel. The method of claim 16, wherein the mobile communication terminal, Supporting the H-ARQ function, if an uplink resource that is not requested by the mobile terminal is allocated from the radio access station to store a certain value in the bandwidth request field in the bandwidth request header to transmit to the radio access station. A system for grasping a service available state of a mobile communication terminal.

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