KR20000013073A - Call processing method between base station controller and mobile switching center - Google Patents

Abstract

PURPOSE: A call processing method between a base station controller and a mobile switching center is provided to reduce the overload element within the mobile switching center by decreasing signal elements and required memory capacity in the mobile switching center. CONSTITUTION: The call processing method includes the steps of: transmitting a message including a circuit identity code to a mobile switching center; translating 16 bits after CIC and confirming ID of a trunk line to which a corresponding message is transmitted by an A-interface block of the mobile switching center; and sending a signal including the ID of the trunk line to a subscriber call processing block and transmitting a response message by the A-interface block; and directly transmitting a message to the base station controller by the subscriber call processing block by means of the ID of the trunk line. This invention removes the unnecessary signal processing step and improves the hand-off function.

Description

Call processing method between base station controller and mobile switching center in cellular system

The present invention relates to a call processing method between a base station controller and a mobile switching center in a cellular system. In particular, the present invention adds a message transmitted between a base station controller and a mobile switching center in a cellular system using a code division multiple access (CDMA) technique. It is about how to.

The cellular mobile communication system divides the entire service area into a plurality of wireless base station areas, constitutes cells, which are small service areas, and centrally controls these wireless base stations with a switching system to allow subscribers to move calls between cells. Allow you to continue. In cellular systems, a handoff function allows a call to continue when the mobile phone leaves a cell of a base station and enters a new cell.

1 is a block diagram of a conventional code division multiple access system. A base station transceiver subsystem (BTS) 20, 22, 24 provides a mobile communication service to a mobile station (MS) 10 through an air interface. A base station controller (BSC) 30, 32 connects a plurality of base stations to a mobile switching center (MSC) 40, 42 via a relay line. The mobile switching center connects a number of base station controllers to another mobile switching center or a public switching telephone network (PSTN) 50. The interface between the base station controller and the mobile switching center is called an A-interface.

The mobile switching center has a home location register (HLR) 44, which is a database that stores information on mobile phones registered to it, and a visitor location register, which is a database that stores information on mobile phones in its area. (Visitor Location Register: VLR) 41, 43 obtains information of the mobile telephone and processes the call of the subscriber.

Base stations 20, 22 and 24 and base station controllers 30 and 32 are collectively referred to as a base station subsystem (BSS). Network Management Center (NMC) 34 manages a network consisting of a base station controller, mobile switching center, and home locator.

The subscriber attempts to call using the mobile telephone 10. Mobile phone 10 requests a call to base station controller 30 through the base station. When the base station controller requests a call to the mobile switching center 40, an access switching processor (ASS) of the mobile switching center processes the call. The mobile switching center has a call processing block such as an A-interface block, a subscriber call processing block, etc. for processing a subscriber's call.

When the base station controller first requests a call, the A-interface block translates the call request data delivered from the base station controller to process the interface with the base station controller, and requests the call processing to the subscriber call processing block. One subscriber call processing block processes a call for one subscriber.

However, many signals are transmitted and received inside the mobile switching center during the above call processing. Therefore, a lot of running time inside the mobile switching center is required, and the system is likely to be overloaded.

For example, the capacity of memory required by the mobile switching center's access exchange processor to service one mobile subscriber is as follows. The A-interface block needs 4kbytes to process one mobile subscriber, and the subscriber call processing block needs 4-8kbytes. An access exchange processor with 16 Mbytes of memory may serve approximately 1300-2000 subscribers. However, there are 2048 base station controller relay lines connected to one mobile switching center. Therefore, a problem arises that the access switching processor cannot handle all subscribers connected with the mobile switching center.

SUMMARY OF THE INVENTION The present invention has been made to solve the problems of the prior art operating as described above, in a cellular system which reduces the overload factor inside the mobile switching center by reducing the memory requirement inside the mobile switching center and reducing the signal elements therein. An object of the present invention is to provide a call processing method between a base station controller and a mobile switching center.

Other objects and advantages of the present invention will become more apparent from the following detailed description of the invention and the accompanying drawings.

1 is a block diagram of a conventional code division multiple access system.

2 is a flowchart illustrating a call processing method between a base station controller and a mobile switching center according to the present invention.

3 is a message flow diagram illustrating an outgoing call processing method between a base station controller and a mobile switching center according to the present invention.

4 is a message flow diagram illustrating an incoming call processing method between a base station controller and a mobile switching center according to the present invention.

5 is a message flow diagram illustrating a subscriber release call processing method between a base station controller and a mobile switching center according to the present invention.

6 is a message flow diagram illustrating a failure call recovery processing method between a base station controller and a mobile switching center according to the present invention.

7 is a message flow diagram illustrating a handoff call processing method between a base station controller and a mobile switching center according to the present invention.

8 to 21 illustrate a format of a message between a base station controller and a mobile switching center according to the present invention.

<Explanation of symbols for the main parts of the drawings>

10: mobile phone 20, 22, 24: base station

30,32: base station controller 34: network management center

40,42: Mobile Exchange Office 41,43: Visitor Locator

44: home locator 50: general telephone network

A preferred embodiment of a call processing method between a base station controller and a mobile switching center in a cellular system according to the present invention devised to achieve the above object is a base station controller for connecting a plurality of base stations to a mobile switching center, and a plurality of base station controllers. 10. A cellular system comprising a mobile switching center which connects to a general telephone network or another mobile switching center, the mobile switching center comprising an A-interface block for interfacing with a base station controller and a subscriber call processing block for performing actual call processing.

Sending, by the base station controller, a message containing a circuit identification code (CIC) to the mobile switching center;

The A-interface block of the mobile switching center, translating 16 bits after the CIC to determine the ID of the relay line to which the message is transmitted;

Sending, by an A-interface block, a signal including the identified relay line ID to a subscriber call processing block, and sending a response message to a base station controller; And

The subscriber call processing block sends a message directly to the base station controller using the identified trunk line ID.

In the embodiment of the present invention, it is preferable that the call processing method is an outgoing call processing method between the base station controller and the mobile switching center.

Preferably, the call processing method is an incoming call processing method between the base station controller and the mobile switching center.

Preferably, the call processing method is a recovery call recovery method between a base station controller and a mobile switching center.

The call processing method is preferably a handoff call processing method between the base station controller and the mobile switching center.

Another preferred embodiment of a call processing method between a base station controller and a mobile switching center in a cellular system according to the present invention is a base station controller connecting a plurality of base stations to a mobile switching center, and a plurality of base station controllers to a general telephone network or another mobile switching center. And a mobile switching center comprising an A-interface block for interfacing with a base station controller and a subscriber call processing block for performing actual call processing.

Sending, by the mobile switching center, a message to the base station controller, the message including as a tag the processor ID in the A-interface block to analyze the response message;

A base station controller analyzing the tag to determine a processor ID;

Sending, by a base station controller, a response message including the identified processor ID as a tag to a mobile switching center;

The mobile switching center analyzing the tag to determine a processor ID; And

And analyzing, by the processor corresponding to the ID, the response message.

In another embodiment of the present invention, the call processing method is preferably a handoff call processing method between a base station controller and a mobile switching center.

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. Terms to be described later are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators. Therefore, the definition should be made based on the contents throughout the specification.

The present invention adds an information element called a circuit identity code (CIC) to the traffic channel message of the A-interface, thereby improving outgoing and incoming performance. The mobile switching center receiving the signal translates the 16 bits after the CIC to determine the ID of the relay line to which the message is transmitted. That is, the 16 bits after the CIC are the relay line IDs to which the corresponding message is transmitted. The mobile switching center can send and receive signals directly using the relay line ID. Therefore, the subscriber call processing block sends a signal to the base station controller directly through the relay line without passing through the A-interface block.

The present invention also adds a tag value to the control channel message of the A-interface, thereby improving handoff performance. The base station controller translates the tag of the message received from the mobile switching center to determine the processor ID in the A-interface block that will later receive the response message. The mobile station also analyzes the tag to determine the processor ID to receive the message. Therefore, the mobile switching center can eliminate the unnecessary process of setting up a processor to handle handoff.

2 is a flowchart illustrating a call processing method between a base station controller and a mobile switching center according to the present invention. As shown, the mobile switching center receives a message from the base station controller (s10) and checks whether the message includes a circuit identification code (CIC). (S20) If the message does not contain CIC, normal call processing is performed. (S30) If the message includes a CIC, the A-interface block of the mobile switching center translates the 16 bits after the CIC to determine the ID of the relay line to which the message is transmitted. (S40) The A-interface block The subscriber call processing block sends a signal including the identified relay line ID, and sends a response message to the base station controller. (S50) The subscriber call processing block sends a message directly to the base station controller using the identified relay line ID. (s60)

3 to 7 are message flow diagrams illustrating a call processing method between a base station controller and a mobile switching center according to the present invention. Hereinafter, the operation principle of the preferred embodiment of the present invention will be described in detail with reference to FIGS. 1 and 3 to 7.

3 is a message flow diagram illustrating an outgoing call processing method between a base station controller and a mobile switching center according to the present invention.

The calling subscriber requests call setup by sending a Call Request (CR) message called s_Setup to the mobile switching center 40 through the base station controller 30. (s110) The mobile switching center includes a CIC included in s_Setup. By translating the base station controller to determine the trunk trunk (BSC trunk: Btrunk), and manages the subscriber in the relay unit. The A-Interface block of the mobile switching center translates the CIC, sends a call setup signal to the subscriber call processing block, and sends a Call Confirm (CC) message called s_CallProc to the base station controller, indicating that the initial setup has been successfully processed. (s120)

The subscriber call processing block carries out an outgoing service for one subscriber. Since the interface with the base station controller is managed in units of relay lines already found from the CIC, the subscriber call processing block sends a data transfer (DT) message called s_Alerting when the mobile switching center occupies the called subscriber (s130). Responds, it sends a data transfer message called s_Connect (s140).

At this time, the subscriber call processing block directly sends s_Alerting and s_Connect to the base station controller without passing through the A-interface block. Therefore, the mobile switching center can eliminate unnecessary signal processing inside. The base station controller then responds to the s_connectAck with the CIC from the mobile switching center (s150) and enters the busy state (s160).

4 is a message flow diagram illustrating an incoming call processing method between a base station controller and a mobile switching center according to the present invention. The mobile switching center 40 sends an s_Paging to the base station controller 30 to call the called subscriber. (S210) The base station controller informs the mobile switching center that a normal call has been made through s_PageResp including the CIC. The A-interface block of the CIC translates the CIC, sends a call setup signal to the subscriber call processing block, and sends s_CallConfirm to the base station controller to inform that the setup has been processed normally.

The mobile switching center transmits the called subscriber information to the base station controller through s_Alerting to request the occupancy of the called subscriber (s240). The switching center notifies the base station controller that the connection is successfully connected with the calling subscriber through s_ConnectAck (s260), and the mobile switching center and the base station are in a normal busy state (s270).

5 is a message flow diagram illustrating a subscriber release call processing method between a base station controller and a mobile switching center according to the present invention. Either of the base station controller 30 or the mobile switching center 40 sends s_Release to the counterpart system to request the release. (S310) The counterpart system sends s_RelComp to inform that the release is completed. CIC is included in s_Release or s_RelComp sent to the exchange.

6 is a message flow diagram illustrating an incomplete call recovery processing method between a base station controller and a mobile switching center according to the present invention. As shown in (a) of FIG. 6, if the data requested by the mobile switching center is abnormal and it is difficult to proceed with the call anymore, the base station controller 30 sends the s_CallFailRP including the CIC to the mobile switching center 40 to cause a call failure. The mobile switching center responds by sending s_CallFailRP to the base station controller.

As shown in (b) of FIG. 6, the mobile switching center 40 sends an s_FailCodeReport to the base station controller 30 to process the recovery (s510).

As mentioned above, the base station controller includes the CIC in the traffic channel message sent to the mobile switching center to eliminate unnecessary signal processing generated at the mobile switching center.

The base station controller also includes a tag in the control channel message sent to the mobile switching center to improve handoff performance.

7 is a message flow diagram illustrating a handoff call processing method between a base station controller and a mobile switching center according to the present invention. A handoff occurs when an initially busy subscriber moves from the area of the originating base station controller to the area of the terminating base station controller. Then, the terminating base station controller 30 requests the handoff by sending s_HORequired including the CIC to the originating mobile switching center 40 (s610). A handoff is requested by sending an s_HORequest including a tag to the base station controller 32 (s620). The terminating base station controller analyzes the tag to determine the processor ID to which the s_HORequestAck is sent. The terminating base station controller sends an s_HORequestAck tagged with the identified processor ID to the terminating mobile switching center (s630) to indicate that a normal handoff has occurred. The called mobile switching center notifies the calling mobile switching center, and the calling mobile switching center sends an s_HOCommand to the calling base station controller to indicate that a normal handoff has occurred (s640).

As mentioned above, the CIC is included in the message sent from the base station controller to the mobile switching center to eliminate unnecessary signal flow generated at the mobile switching center. The mobile switching center also includes a tag in the message sent to the base station controller to inform the processor ID to send s_HORequestAck. The base station controller analyzes the tag to determine the processor ID, and sends an s_HORequestAck to the mobile switching center that retags the processor ID. The mobile switching center causes the processor having the corresponding ID to analyze s_HORequestAck without going through a separate processor setting process. Thus, the mobile switching center can eliminate unnecessary signal processing.

The terminating base station controller normally performs a handoff, and sends a s_HOComplete to the terminating mobile switching station to inform that the handoff is completed. It is instructed to release the existing call. (S660) The originating base station controller releases the existing call through a normal handoff procedure and sends s_RelComp to the originating mobile switching center to completely terminate the existing call.

8 to 21 illustrate a format of a message between a base station controller and a mobile switching center according to the present invention. 8 shows a format of an s_Setup message according to the present invention. As shown, it contains a 24-bit (3 byte) long CIC. 9 shows a format of an s_Connect message according to the present invention. As shown, it contains a 24-bit (3 byte) long CIC. 10 shows a format of an s_ConnectAck message according to the present invention. As shown, it contains a 24-bit (3 byte) long CIC. 11 shows the format of an s_PageResp message according to the present invention. As shown, it contains a 24-bit (3 byte) long CIC. 12 shows the format of an s_Release message according to the present invention. As shown, it contains a 24-bit (3 byte) long CIC. 13 shows a format of an s_RelComp message according to the present invention. As shown, it contains a 24-bit (3 byte) long CIC. 14 shows a format of an s_CallFailRP message according to the present invention. As shown, it contains a 24-bit (3 byte) long CIC. 15 shows a format of an s_FlashWithInfo message according to the present invention. As shown, it contains a 24-bit (3 byte) long CIC. 16 shows a format of an s_HORequired message according to the present invention. As shown, it contains a 24-bit (3 byte) long CIC.

17 shows the format of an s_HORequest message according to the present invention. As shown, it contains a 32-bit (4 byte) long tag (processor ID). 18 shows the format of an s_HORequestAck message according to the present invention. As shown, it contains a 24-bit (3 byte) long CIC and a 32-bit (4 byte) long tag.

19 shows the format of an s_HOFailure message according to the present invention. As shown, it contains a 24-bit (3 byte) long CIC. 20 shows the format of an s_HOCancel message according to the present invention. As shown, it contains a 24-bit (3 byte) long CIC. 21 shows a format of an s_HOPerformed message according to the present invention. As shown, it contains a 24-bit (3 byte) long CIC.

The present invention can be variously modified and can take various forms and only the specific embodiments thereof are described in the detailed description of the invention. It is to be understood, however, that the present invention is not limited to the specific forms mentioned in the detailed description of the invention, but rather includes all modifications, equivalents, and substitutions within the spirit and scope of the invention as defined by the appended claims. It should be understood to do.

In the present invention operating as described above, the effects obtained by the representative ones of the disclosed inventions will be briefly described as follows.

By adding a CIC that specifies the relay line ID between the base station controller and the mobile switching center in a message sent by the base station controller to the mobile switching center on the A-interface, the subscriber call processing block of the mobile switching center goes to the base station controller through the relay line without passing through the A-interface block. You can send a signal directly. Therefore, unnecessary signal processing between the A-interface block and the subscriber call processing block is eliminated, thereby reducing the operating time in the mobile switching center and eliminating an overload factor that may occur at the mobile switching center.

In addition, by including the ID of the processor which will process the message of the base station controller as a tag in the message between the base station controller and the mobile switching center, unnecessary signal processing is eliminated and handoff performance is improved.

Claims (7)

A base station controller that connects multiple base stations to the mobile switching center, an A-interface block that connects the multiple base station controllers to a public telephone network or other mobile switching center, and interfaces with the base station controller and subscriber calls that perform actual call processing. A cellular system comprising a mobile switching center comprising a processing block, Sending, by the base station controller, a message containing a circuit identification code (CIC) to the mobile switching center; The A-interface block of the mobile switching center, translating 16 bits after the CIC to determine the ID of the relay line to which the message is transmitted; Sending a signal including the identified relay line ID to the subscriber call processing block by the A-interface block and sending a response message to the base station controller; And a subscriber call processing block sending a message directly to a base station controller using the identified relay line ID. 2. The method of claim 1, wherein the call processing method is a method of processing an outgoing call between a base station controller and a mobile switching center. The method of claim 1, wherein the call processing method is a method of processing an incoming call between a base station controller and a mobile switching center. 2. The method of claim 1, wherein the call processing method is a method for recovering a failed call between a base station controller and a mobile switching center. 2. The method of claim 1, wherein the call processing method is a method for processing a handoff call between a base station controller and a mobile switching center. A base station controller that connects multiple base stations to the mobile switching center, an A-interface block that connects the multiple base station controllers to a public telephone network or other mobile switching center, and interfaces with the base station controller and subscriber calls that perform actual call processing. A cellular system comprising a mobile switching center comprising a processing block, Sending, by the mobile switching center, a message to the base station controller, the message including as a tag the processor ID in the A-interface block to analyze the response message; A base station controller analyzing the tag to determine a processor ID; Sending, by a base station controller, a response message including the identified processor ID as a tag to a mobile switching center; How the mobile station analyzes the tag to determine the processor ID, and And analyzing, by the processor corresponding to the ID, the response message in the mobile switching center. The call processing method between the base station controller and the mobile switching center in a cellular system. 7. The method of claim 6, wherein the call processing method is a method for processing a handoff call between a base station controller and a mobile switching center.