KR20060078814A - A call setup apparatus and method in a mobile communication system - Google Patents

Abstract

The present invention relates to an apparatus and method for efficient traffic path establishment when a mobile terminal accesses a call in a CDMA 2000 system based on an asynchronous transmission scheme. The apparatus of the present invention checks a link state with a BSC and provides a call for a call connection. Call setup calculated using at least two AOPs for checking call setup data and an AEP connecting traffic path for call setup with at least two AOPs and one of the two AOPs and call setup data of the AOPs And a BMP_AMP that controls call setup between the AEP and the AOP based on a success rate. The method of the present invention periodically checks the link state to generate link state information including call establishment success / failure data, transmits the link state information to the main processor, and transmits the link state information. And calculating a call establishment success rate based on the AEP and transmitting a signal including an ID of an AOP having a high call connection success rate to the AEP when receiving a call setup request signal from the AEP.

The present invention selects an AOP having a high call establishment success rate when setting up a call. Also, since the link state between the AOP of the target BSC and the AOP of the anchor BSC uses an actual signaling process, the AOP of the call setup failure is known. Connection is possible.

BMP_AMP, AOP, call connection success rate

Description

A call setup device and method in a mobile communication system {A CALL SETUP APPARATUS AND METHOD IN A MOBILE COMMUNICATION SYSTEM}             

1 is a diagram showing the configuration of a general CDMA 2000 system.

2 is a signal flow diagram illustrating a handoff call setup procedure between BSCs in a typical CDMA 2000 system.

3 is a block diagram illustrating the target BSC in FIG. 1 in detail;

4 and 5 are signal flow diagrams illustrating a process for the AEP to determine an AOP for delivering an ERQ message.

6 is a block diagram showing a call processing apparatus according to a preferred embodiment of the present invention.

7 is a signal flow diagram illustrating a call processing setup method according to a preferred embodiment of the present invention.

The present invention relates to a Code Division Multiple Access 2000 (CDMA 2000) system based on an asynchronous transfer mode (ATM). Specifically, the present invention relates to an efficient traffic path setting when a mobile terminal accesses a call in the CDMA 2000 system. An apparatus and method are provided.

1 is a diagram showing the configuration of a general CDMA 2000 system.

Referring to FIG. 1, a base transceiver station (BTS) 110 is a relay board board processor (BTS) for connection between a channel element board (CEP) 112 of a channel card and a node. 111 is provided to process voice and data transmitted and received with the mobile terminal 101. The base station controller (BSC) 120 is located between the global ATM switch network (GAN) 150 and the BTS 110 and has an optical connection between the relay board processor AEP (ATM E1 Processor) 125 and the BSC. AOP (ATM Optical STM-1 Processor) 125 which is a board processor for connection. The BSC 120 performs various functions such as location registration, call and session control, real time traffic processing, and handoff processing of the mobile terminal. Each BSC manages a number of BTSs. In general, one BSC includes 128 BTSs. Next, the GAN 150 provides a communication path and a handoff path between BSC # 0 to 11 as an ATM switch, and the BSM (Base Station Manager Operation System) 200 can control the BSC and the BTS connected to each BSC. To provide a path. One gan 150 manages 12 BSCs. The BSM 200 is an operator is a system controller (System Controller) for system management and operation. The BSM 200 is connected to one GAN 150 in a one-to-one structure.                         

In the CDMA 2000 system, when the mobile terminal 101 makes a call request in a mobile area, the BTS 110 transmits a TCP (Transcoder Control Processor) which is a vocoder of the BSC 120 from the BTS 110. (Traffic Path) to the (not shown) to transmit the traffic data. In general, a traffic path is set from the CEP 112, the channel card of the BTS 110, to the vocoder (TCP) of the BSC managing the BTS. However, when the mobile terminal 101 moves out of the management area of the corresponding BSC to the management area of another BSC, a handoff occurs, and the traffic path must be connected to the first connected vocoder. Thus, in order to maintain a call with the first connected vocoder, the BSC in the mobile area is reestablished a traffic path with the first connected vocoder through the GAN 150. In this case, the BSC first connected to the mobile terminal is called an anchor BSC, and the BSC of the mobile area is called a target BSC.

Next, a description will be given of a method for setting a traffic path when a handoff occurs in a mobile terminal in a general CDMA 2000 system.

2 is a signal flow diagram illustrating a handoff call setup procedure between BSCs in a general CDMA 2000 system. In this case, the mobile terminal 101 moves from the BTS 140 of FIG. 1 to the BTS 110 of the mobile station so that the BSC 120 of the mobile region is the anchor BSC 130 of the target region of the first BSC. Assumed

Referring to FIG. 2, when the mobile terminal 101 moves between BSCs, a fixed virtual circuit (PVC) between the BSCs from the CEP 112, which is a channel card of the target BSC 120, to the anchor BSC 140. Permanent Virtual Circuit (PVC) must set up traffic path. Here, the CDMA 200 system is an ATM-based system. In order to deliver a cell from the ATM-based system, a CDMA 200 system sets a transmission interval to be delivered to an address called a VPI (Virtual Path Identifier) and a VCI (Virtual Circuit Identifier). Done. The transmission section is called PVC. In such a PVC section, the VPI and VCI should be entered in the header of the traffic path.

Therefore, in order to transfer the traffic path from the mobile terminal 101 to the TCP 140, the traffic path must be set. A block for processing this role is an AAL type 2 call processor (A2CP) (not shown). The A2CP is a software block for setting a path for transmitting traffic data transmitted and received by the mobile terminal 101 from the channel card to the TCP 140, and is provided between nodes. That is, the A2CP establishes a switched virtual circuit (SVC) between nodes in order to transmit a traffic path for call setup. The SVC refers to a method of temporarily establishing / releasing communication paths between nodes.

First, when the mobile terminal 101 moves, the BTS 110 of the region allocates one CEP 112 to the call processing block provided therein, and then the destination for the first vocoder TCP 140 to the A2CP. A call establishment request is made while passing an address. The A2CP inputs an A2P and a CID (Channel Identifier) in turn to a signaling node and delivers a Establish ReQuest (ERQ) message. Here, the A2P is a key value used for sharing the PVC between nodes and nodes, and is set to a unique value for one PVC. The CID is a channel identifier assigned to the user who has requested a call setup in the mobile terminal 101.

When the above process is described in sequence, the CEP 112 first transmits an ERQ (A2P, CID1) message, which is a call setup message including the A2P and CID1 preset in the BIP 111 in step 151. Upon receiving the ERQ (A2P, CID1) message, the BIP 111 transmits the newly generated ERQ (A2P, CID2) value to the AEP 125 of the target BSC 120 in step 152. When the ERQ message reaches the AEP 125, the target BSC 120 first determines whether a call establishment request is a local call or a handoff call. If the call establishment request is a handoff call, an ERQ (A2P, CID3) message is transmitted to the AOP 121 to the next node. The AOP 121 is divided into two AOP3 and two AOP4 for load balancing. Accordingly, the AEP 125 transmits a newly set ERQ message to the corresponding AOP in step 153. Since the AEP 125 distributes the load to the AOP, it will be omitted here.

The AOP 121 of the target BSC 120 that has received the ERQ (A2P, CID3) message newly generates the ERQ (A2P, CID4) message to the AOP 131 of the anchor BSC 130 first connected in step 154. send. Thereafter, the AOP 131 transmits ERQ (A2P, CID5) to the TCP 140, which is a vocoder processor, in step 155. Upon receiving the ERQ (A2P, CID5), the TCP 140 transmits a call establishment confirmation (Establish ConFirm: ECF) message to the AOP 131 in step 153. The ECF message is sent back to the path where the ERQ message was sent. Then, when the CEP 112 receives the ECF message and is sent to all the CEP 112, call setup is completed.

Next, a method of setting the AOP 125 by the AEP 125 in the target BSC 120 will be described with reference to FIGS. 3, 4, and 5 below.

3 is a block diagram illustrating the target BSC 120 in FIG. 1 in more detail. Referring to FIG. 3, the target BSC 120 includes a BMP_AMP 170, an AEP 125, and an AOP 121. The AOP 121 is a processor of an optical link board connected to the GAN 150 of FIG. 1 and is divided into an AOP3 122 and an AOP 123 for actual load balancing. The BMP_AMP 170 is a processor that controls the selection paths of the AOP3 122 and the AOP4 123 during handoff between BSCs.

4 is a diagram illustrating a process for the AEP 125 to determine the AOP 121 to deliver the ERQ message. Referring to FIG. 4, first, the AEP 125 transmits a route request message (Route_Req) 181 to the BMP_AMP 170 to determine the AOP 121. Upon receiving the Route_Req 181, the BMP_AMP 170 inputs an AOP ID to be delivered to the routing confirmation message (Route_Conf) 182 and transmits the AOP ID to the AEP 121.

Next, a method of determining the AOP 121 in which the BMP_AMP 170 establishes the traffic path will be described with reference to FIG. 5. Referring to FIG. 5, the BMP_AMP 170 transmits a status request (Poll_Req) message 183 to the AOP3 122 and the AOP4 123 every two seconds. The AOP3 122 and the AOP4 123 receiving the Poll_Req 183 message receive a status check (Poll_Conf) message 184 to which the Alive State and the Call Setup Count are input, and the BMP_AMP. Transmit to 170. The state information is information for confirming whether normal communication is performed through an optical link of the corresponding AOP. The state information checks whether the link is normal by periodically pinging the AOP 121 to a link connected to the AOP. The call setup count indicates the number of calls set to the corresponding AOP. That is, a large number of call setup counts means that a lot of traffic data flows to the corresponding AOP.

In the conventional system, when the AEP 125 transmits a Route_Req 181 message to the BMP_AMP 170, the BMP_AMP 170 first checks state information to confirm that the corresponding AOP operates normally. Thereafter, the BMP_AMP 170 notifies the AEP 125 of an AOP ID having a low call setup count.

In such a system, it is implemented for load balancing, but there is a problem in that proper routing is not possible for abnormal cases. For example, when one of the two AOPs fails to process a message normally, the troubled AOP has a large number of call setup failures. It will have a value that is mostly smaller than the call setup count. In this case, since the problem setting AOP has a small call setup count, the BMP_AMP 170 continuously selects the corresponding AOP, and thus, call setup failure may continue.

 Accordingly, an object of the present invention is to provide an apparatus and method for efficient traffic path establishment in a CDMA 2000 system.

Another object of the present invention is to provide an apparatus and method for establishing a traffic path by identifying an AOP in which a problem does not occur.

In order to achieve the above object, the call setup apparatus of the present invention includes at least two optical link processors (AOPs) for checking a link state with a BSC and checking call setup data regarding a call connection. Call setup calculated using the call setup data of the trunk line board processor (AEP) and the trunk line board processor (AEP) connecting the optical path processor of one of the two optical link processors and the traffic path for call setup. And a BMP_AMP that controls call setup between the AEP and the AOP based on a call setup success rate.

The call setup data may be data related to call setup success and / or failure between the AOPs.

The control unit comprises a control unit for receiving a link state and call setup data from the AOP to calculate the call establishment success rate and a routing unit for selecting one path among the AOPs when receiving a route request message from the AEP. do.

In order to achieve the above object, the call setup method of the present invention periodically checks the link state to generate link state information including call establishment success / failure data, and transmits the link state information to the main processor. And calculating a call establishment success rate based on the link state information, and transmitting a signal including an ID of an AOP having a high call connection success rate to the AEP when receiving a call setup request signal from the AEP. Characterized in that made.

The step of checking the link state by the AOP is characterized in that it comprises the step of transmitting and receiving a ping message on the link to check and a signaling process on the link to confirm the call connection success / failure.

DETAILED DESCRIPTION Hereinafter, detailed descriptions of preferred embodiments of the present invention will be described with reference to the accompanying drawings. It should be noted that the same components in the drawings represent the same numerals wherever possible. Specific details are set forth in the following description, which is provided to aid a more general understanding of the invention. In the following description of the present invention, if it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

First, a traffic path setting apparatus and method according to the present invention will be described with reference to FIGS. 6 and 7. 6 is a block diagram showing a BSC according to a preferred embodiment of the present invention. The BSC 210 assumes a target BSC of a mobile area when the mobile terminal moves between BSCs and a handoff occurs. Prior to the description of the present invention, the system is connected to 11 BSCs based on the target BSCs, and each BSC has two AOPs. Therefore, although the target BSC is described in the present invention for convenience of description, the eleven BSCs have the same structure.

Referring to FIG. 6, the BSC 210 according to the present invention includes a BMP_AMP 220, an AEP 225, and an AOP3 / 4 227 and 229. The AOP3 / 4 (227, 229) transmits and receives a predetermined message with the AOP of the anchor BSC (230) to check whether the call setup failure (Call Setup Fail). The BMP_AMP 220 includes a controller 221 and a routing unit 223. The controller 221 stores call setup data indicating a call setup success rate based on the call setup failure of the AOP3 / 4 (227, 229). The control unit 221 also includes a memory for storing the call setting data. The routing unit 223 plays a role of selecting and routing an optimal AOP based on the call establishment success rate of the control unit 221. Here, the controller 221 is connected between the AOP3 227 and the AOP4 229 by an optical link.

Hereinafter, the BSC 210 according to the present invention will be described in more detail with reference to FIG. 7.

7 is a signal flow diagram for traffic path establishment in the BSC 210 in accordance with the present invention. Referring to FIG. 7, first, the traffic path setting method of the BSC 210 is composed of two processes. The first process is a process of transmitting and receiving a predetermined message between the AOP of the target BSC 210 and the AOP of the anchor BSC 230 to detect a call establishment success or failure, and then transmit the detection result to the BMP_AMP 220. In the second process, the BMP_AMP 220 stores the detection result, calculates a call setup success rate, and determines an optimal AOP to transmit to the AEP 225.

Each process will be described in detail. In the first process, each AOP of the target BSC 210 transmits and receives a predetermined message to all links for each AOP of the anchor BSC 230 at a predetermined period. In the above process, a conventional signaling message and a signaling process are used. Accordingly, the AOP3 / 4 (227, 229) of the target BSC 210 transmits an ERQ message to the AOP of the anchor BSC 230 and receives an ECF message. In addition to detecting, it checks the state of the line. Thereafter, the AOP3 / 4 (227, 229) transmits the detection result to the control unit 221 to calculate the call setup data for the call setup success rate. That is, the AOP3 / 4 (227, 229) of the target BSC 210 allocates a specific CID for the corresponding function to establish a call, and then transmits a status request (Aop_Poll_Req) message including the CID in step 241. After receiving the Aop_Poll_Req message, the AOP of the anchor BSC 230 transmits a status confirmation (Aop_Poll_Conf) message, which is a confirmation signal, to the AOP3 / 4 (227, 229) of the target BSC 210 in step 242. Through this process, when the AOP3 / 4 (227, 229) of the BSC 210 normally transmits the ERQ message and receives the ECF message, the AOP3 / 4 (227, 229) manages the call connection success, otherwise it manages the call establishment failure. The call setup result obtained by the above-described process is transmitted to the controller 221.

The second process is a method in which the controller 221 selects an optimal AOP using the call setup result. First, the AOP3 / 4 (227, 229), in step 243, delivers an information indication (Inform_Ind) message including data on the call setup result confirmed in the signaling process to the BMP_AMP 220. Thereafter, the controller 221 stores the call setup result periodically transmitted from the AOP3 / 4 (227, 229) to the N arrays (Araay) for each AOP3 / 4 (227, 229) in the memory. In step 244, the controller 221 transmits an information response (Inform_Resp) message, which is an acknowledgment message, to the AOP3 / 4 (227, 229).

An example of the call setup result in the memory is shown in Table 1 below.

 Memory array One 2 3 … N-2 N-1 N  AOP3 One 0 One … One 0 0  AOP4 One One One … One 0 One

The memory is provided for all AOPs, but in the present invention, since there are two AOP3 / 4s (227, 229), two memories are provided. Referring to Table 1, N arrays are provided from array 1 to array N for each AOP. The memory receives and stores a call transmission result from each AOP3 / 4 (227, 229). If the call setup succeeds, it records '1' and if the call setup fails, it records '0'. The memory storage order is initially initialized to '1', and when the call setup result is received from each AOP3 / 4 (227, 229), the memory storage order is stored in order from the first array to the N array. The array is then stored up to array N again.

Here, the control unit 221 calculates the call setup success rate for the call setup data stored in the memory through the following equation.

은 N번 어레이의 호 설정 데이터를 나타낸다.Where R is the call setup success rate,

Represents call setup data of array N.

The control unit 221 calculates a call setup success rate by dividing the N arrays by sum N. Thereafter, when the request signal route_req for the call setup path is received from the AEP 255, the controller 221 calculates the call connection success rate and transmits the AOP ID having a high success rate to the AEP 255.

It is very important to set N in the present invention. N is an interval in which data checked when a call setup succeeds or fails is refreshed. The reason for resetting new data every N times is to prevent the data from growing indefinitely. Wherein N should not be too large or small. I will explain why.

First of all, N is large. For example, assume that many call connection failures have occurred in the AOP3 227, but that the call has not occurred in the AOP3 2270 but continuously occurs in the AOP4 229. In this case, until the call connection failure occurs in the AOP4 229 as much as the number of the call connection failures in which the AOP3 227 has occurred in the past, the AOP4 229 having a problem has a high call connection success rate and thus the AOP4 229. The problem of constant selection may occur. In addition, if the N is large, it means that there is a large amount of call setup data, and thus it takes a long time for the previous data to be reset, which takes an unnecessarily long processing time.

On the contrary, it is assumed that when the call setup success rate of each AOP3 / 4 (227, 229) is the same, the AOP3 227 is basically selected when the size of N is too small in the situation where the call setup failure does not occur frequently. lets do it. If the AOP3 227 occasionally encounters a problem, the control unit 221 selects the AOP3 227 because the call connection success rates of the two AOP3 / 4s 227 and 229 are the same. This is an error due to the lack of discretion to determine routing because it is not data obtained over a long enough time. That is, since the call establishment success rate is not calculated as sufficient data, the reliability of the system is lowered. Therefore, N should be appropriately determined based on the frequency statistic that call establishment failure occurs in the system.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be determined not only by the scope of the following claims, but also by the equivalents of the claims.

As described above, the present invention selects an AOP having a high call establishment success rate when setting up a call. Also, since the link state between the AOP of the target BSC and the AOP of the anchor BSC uses an actual signaling process, an AOP of a call setup failure is performed. Knowing this, more efficient call connection is possible.

Claims (8)

In the CDMA2000 system based on the Asynchronous Transfer Mode (ATM), the mobile terminal handles the call setup when the mobile station is handed off between the base station controller (BSC), At least two optical link processors (AOPs) for checking link status with the BSC and checking call setup data regarding call connection; A trunk line board processor (AEP) connecting an optical link processor of one of the two optical link processors and a traffic path relating to call setup; And a BMP_AMP for controlling call setup between the AEP and the AOP based on a call setup success rate calculated using call setup data of the relay board processor. The method of claim 1, wherein the call setup data, Call setup apparatus, characterized in that the data on the call setup success and / or failure (Fail) between the AOP. The method of claim 2, wherein the BMP_AMP, A control unit for receiving a link state and call setup data from the AOP and calculating the call setup success rate; And a routing unit for selecting one path of the AOP when receiving a path request message from the AEP. The method of claim 3, wherein the call establishment success rate, The apparatus, characterized in that by using the following equation (2),

Where R is the call setup success rate,

Means call setup data of N array. The method of claim 3, wherein the control unit, And a memory having N arrays for each AOP, and storing the call setup data in order. A base station controller of a code division multiple access system based on an asynchronous transmission method (ATM), comprising a first processor for interfacing traffic with a base station and at least two second processors for interfacing traffic to be transmitted to an adjacent base station controller. A method for transferring traffic between the first processor and the second processor when a main processor is handed off at Periodically checking the link state by the second processor to generate link state information including call establishment success / failure data; Transmitting the link state information to the main processor; Calculating a call establishment success rate based on the link state information; And transmitting a signal including an ID of a second processor having a high call connection success rate to the first processor when receiving a call setup request signal from the first processor. The method of claim 6, wherein the checking of the link state comprises: Sending and checking a ping message on the link; And determining a call connection success / failure by performing a signaling process on the link. The method of claim 7, wherein the call establishment success rate, The above method, characterized in that by using the following equation (3),

Where R is the call setup success rate,

Means call setup data of N array.

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