KR101354037B1 - Method and system for allocating a reverse supplemental channel while performing handoff, and base-station controller - Google Patents

Abstract

The present invention relates to a method and system for allocating a high speed data channel during handoff. The present invention relates to a high speed data service in a handoff area when a mobile communication terminal moves from a base station area capable of high speed data service to another base station area where high speed data service is not supported. Can be provided with a high-speed data service by being assigned a high-speed data channel for a predetermined time from a possible base station.

The method for allocating a high speed data channel during handoff according to the present invention is a method for allocating a high speed data channel to a mobile communication terminal in a handoff area of a source base station and a target base station. Receiving a power measurement report message (PMRM) for the source base station from the terminal and requesting allocation of a reverse high speed data channel (RSCH) to the target base station based on the received power measurement report message (PMRM); (b) receiving the RSCH assignment error message from the target base station; (c) maintaining an RSCH of the source base station; And (d) releasing the RSCH for the target base station.

Handoff, RSCH, PMRM, FCH, source, target, base station, CEC, BRC, ACC, AMC

Description

Method and system for allocating a high speed data channel during handoff, and a base station controller for the same

The present invention relates to a method and system for allocating a high speed data channel during handoff of a mobile communication terminal, and a base station controller for the same.

In general, a handoff in a mobile communication network is to maintain a call to continuously maintain a call when the mobile terminal moves out of one base station (or sector) area in service to another base station (or sector) area. It means to change to the cell of the moved base station.

1 is a diagram illustrating a conventional method of allocating a reverse channel during handoff.

Referring to FIG. 1, when the mobile communication terminal 110 is located in the region of the source base station 120, a reverse fundamental channel (hereinafter referred to as RFCH) and a reverse high speed data channel (Reverse Supplemental CHannel) from the source base station 120 may be used. , RSCH). In this state, when the mobile communication terminal 110 moves to the area of the target base station 130, the mobile communication terminal 110 is handoff that the area of the source base station 120 and the area of the target base station 130 overlaps. It will be located in the area. In this case, when only the reverse base channel (RFCH) is allocated by the target base station 130 and the reverse high speed data channel (RSCH) cannot be allocated, the mobile communication terminal 110 performs reverse fast data with the source base station 120. The channel (RSCH) is released, and only the reverse base channel (RFCH) is allocated from the target base station 130 of the new area to perform a handoff. Therefore, as the mobile communication terminal 110 moves from the area of the source base station 120 to the area of the target base station 130, the mobile communication terminal 110 cannot receive the high speed data service in the handoff area.

2 is a flowchart illustrating a call processing method when there is no high speed data channel in a target base station in the related art.

Referring to FIG. 2, an access media controller (AMC) of a base station controller (BSC) is a first power measurement report message (PMRM) from a mobile communication terminal after a base channel is allocated to a target base station. ), It requests the access call controller (ACC) to modify the reverse high speed data channel (RevSCH) (S202).

Accordingly, the access call controller (ACC) requests allocation of a reverse high speed data channel (RevSCH) to a base station resource manager (BRC) of the target base station according to a change request message from the access media controller (AMC) ( S203).

However, when the base station resource manager (BRC) of the target base station cannot allocate the reverse fast data channel (RevSCH), the allocation setup message of the reverse fast data channel (RevSCH) having an error value is transmitted to the access call controller (ACC). It transmits (S204).

Accordingly, the access call controller (ACC) transmits an extended high speed data channel (RSCH) allocation message for releasing the high speed data channel of the source base station to the mobile communication terminal (S205), and the mobile communication terminal sends a response message to the access call controller. Transmit to the ACC (S206).

Then, the access call controller (ACC) requests the base station resource manager (BRC) of the source base station to release the reverse high speed data channel (RSCH) for the mobile communication terminal (S207). Accordingly, the base station resource manager (BRC) instructs the channel element controller (CEC) to release the reverse high speed data channel (RSCH), and the channel element controller (CEC) sends the reverse high speed data channel to the mobile communication terminal. After releasing (RSCH), a response message for channel release is transmitted to the base station resource manager (BRC). The base station resource manager BRC transmits a release establishment message of a reverse high speed data channel to the mobile communication terminal to an access call controller (ACC) of the base station controller (S208).

In the conventional method of allocating a high speed data channel (RSCH) as described above, when the return value in the RSCH assignment setting message is not NO_ERROR, all previously allocated RSCH channels are released. Despite being able to operate, there is a disadvantage of releasing the RSCH. Therefore, high speed data service could not be provided in the handoff area.

In order to solve the above disadvantages and problems of the prior art, the present invention provides a high speed in the handoff area when the mobile communication terminal moves from a base station area capable of high speed data service to another base station area where high speed data service is not supported. It is an object of the present invention to provide a method and system for allocating a high speed data channel during handoff, by receiving a high speed data channel for a predetermined time from a base station capable of data service.

In addition, the present invention, when the base station of the reverse high-speed data channel and the base station of the reverse base channel is different for the mobile communication terminal in the handoff area, changing the transmission rate in accordance with the pilot strength (Pilot Strength) of the reverse base channel of the base station, It is an object of the present invention to provide a method and system for allocating a high speed data channel during handoff.

In addition, the present invention requests the allocation of a high-speed data channel to a base station capable of high-speed data service in a handoff region at a time period specified by an operator, and receives a high-speed data channel from a base station capable of high-speed data service to provide a high-speed data service for a predetermined time. It is an object of the present invention to provide a base station controller that can provide.

A method for allocating a high speed data channel during handoff according to the present invention for achieving the above object comprises the steps of: (a) an access call in a method for allocating a high speed data channel to a mobile communication terminal during handoff from a source base station to a target base station; An access call controller (ACC) receives a power measurement report message (PMRM) for the source base station from the mobile communication terminal, and based on this, a reverse high speed data channel to the target base station. Requesting allocation of Supplemental CHannel (hereinafter referred to as RSCH); (b) the ACC receiving the RSCH assignment error message from the target base station; (c) the ACC transmitting resource information on an RSCH of the source base station to an access media controller (hereinafter referred to as AMC); And (d) the AMC maintaining the RSCH of the source base station.

In addition, in step (d), the AMC re-requests when the Active Set information of the Fundamental Dedicated CHannel (FDCH) is changed with respect to RSCH reallocation of the base station that fails to allocate the RSCH.

In addition, after the AMC releases all the RSCHs, the RSCH is reassigned when an RSCH allocation request is requested by a supplemental channel request message (SCRM) of the mobile communication terminal.

In addition, after the step (d), the AMC determines the data rate of the RSCH based on the lowest data rate among the base stations that have successfully allocated the RSCH, and performs the RSCH allocation only to the base station that has succeeded in the RSHC allocation. do.

In addition, the resource information for the RSCH includes a Walsh ID, a data rate, and a channel element.

Also, in the step (d), the AMC allocates the RSCH having the same data rate to the source base station based on the base station which has successfully allocated the high speed data channel.

The RSCH assignment error message includes an allocation error or timeout of the RSCH.

On the other hand, the high-speed data channel allocation system according to the present invention for achieving the above object, to allocate a Reverse Supplemental CHannel (hereinafter referred to as RSCH) to the mobile communication terminal when the handoff from the source base station to the target base station, A high speed data channel allocation system, comprising: a base station resource manager (BRC) for allocating the RSCH of the source base station or the target base station; Receives a power measurement report message (PMRM) for the source base station from the mobile communication terminal and requests an RSCH allocation for the target base station to the BRC based on this, and allocates an RSCH from the BRC. In the case of receiving the ACC, an access call controller (ACC) requesting to maintain the RSCH of the source base station: and controls the data packet of the source base station or the target base station, and from the ACC of the source base station And if requested to maintain an RSCH, an access media controller (AMC) for maintaining the RSCH configuration of the source base station.

In addition, the ACC transmits resource information on the RSCH of the source base station to the AMC, and requests to maintain the RSCH of the source base station.

In addition, the resource information for the RSCH includes a Walsh ID, a data rate, and a channel element.

In addition, the AMC reassigns the RSCH when the active set information of the basic channel (FCH) is changed for the base station that fails to allocate the RSCH.

In addition, the AMC reassigns the RSCH when the RSCH allocation request is made by a supplemental channel request message (SCRM) of the mobile communication terminal after releasing all RSCHs.

In addition, the ACC determines the data rate of the RSCH based on the lowest data rate among the base stations that have successfully allocated the RSCH, and assigns the RSCH only to the base station that has successfully allocated the channel.

Further, when the active base station of the RSCH is different from the active base station of the base channel (RFCH), the AMC changes the data rate of the RSCH in accordance with the pilot strength of the base channel.

The ACC allocates the RSCH to the source base station and the target base station for the first time when the mobile communication terminal is handed off. When the RSCH allocation succeeds and the base station fails, the RSCH allocation succeeds. An RSCH of the same data rate is allocated based only on a base station, and information about the RSCH is transmitted to the AMC.

On the other hand, the base station controller according to the present invention for achieving the above object, the base station controller for controlling a reverse high-speed data channel (RSCH) is assigned to the mobile communication terminal when the handoff from the source base station to the target base station In Receiving a power measurement report message (PMRM) for the source base station from the mobile communication terminal based on this request for the RSCH allocation for the mobile communication terminal to the target base station, and the target base station An access call controller (ACC) requesting to maintain the RSCH of the source base station by transmitting resource information on the RSCH of the source base station when receiving an allocation error of the RSCH from the: When receiving resource information on the RSCH of the source base station, the phase And an Access Media Controller (AMC) for maintaining the RSCH configuration of the original base station.

Here, the resource information for the RSCH includes a Walsh ID, a data rate, and a channel element.

In addition, the ACC determines the data rate of the RSCH based on the lowest data rate among the base stations that have successfully allocated the RSCH.

Further, when the active base station of the RSCH is different from the active base station of the base channel (RFCH), the AMC changes the data rate of the RSCH in accordance with the pilot strength of the base channel.

The ACC allocates the RSCH to the source base station and the target base station for the first time when the mobile communication terminal is handed off. When the RSCH allocation succeeds and the base station fails, the RSCH allocation succeeds. An RSCH of the same data rate is allocated based only on a base station, and information about the RSCH is transmitted to the AMC.

Accordingly, according to the method and system for allocating a high speed data channel during handoff according to the present invention, a high speed data service for a predetermined time even in a handoff area when moving from a base station area capable of high speed data service to another base station area where high speed data service is not supported. There is an advantage that can be provided.

Further, even when the reverse high speed data channel for the mobile communication terminal is insufficient in the handoff area, the upload speed of the mobile communication terminal to the base station can be improved.

According to the present invention, even when the base station of the reverse fast data channel (RSCH) and the base station of the reverse base channel (RFCH) are different for the mobile communication terminal in the handoff area, the pilot strength of the reverse base channel (RFCH) of the base station ( According to Pilot Strength, the transmission rate can be changed.

The foregoing and other objects, features, and advantages of the present invention will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG.

First, FIG. 3 is an exemplary view for explaining a reverse channel allocation method during handoff according to an embodiment of the present invention.

Referring to FIG. 3, when the mobile communication terminal 110 moves to an area of the target base station 130 in a state where a reverse base channel (RFCH) and a reverse fast data channel (RSCH) are allocated from the source base station 120, The mobile communication terminal 110 is located in a handoff area where the area of the source base station 120 and the area of the target base station 130 overlap.

In this case, when only the reverse base channel (RFCH) is allocated by the target base station 130 and the reverse high speed data channel (RSCH) cannot be allocated, the mobile communication terminal 110 performs reverse fast data with the source base station 120. The channel RSCH is maintained for a predetermined time, and a handoff is performed while receiving a reverse base channel (RFCH) from the target base station 130 of the new region. Accordingly, as the mobile communication terminal 110 moves from the area of the source base station 120 to the area of the target base station 130, the mobile communication terminal 110 may be provided with a high-speed data service for a predetermined time in the handoff area.

4 is a configuration diagram schematically illustrating a configuration of a high speed data channel allocation system during handoff according to an embodiment of the present invention.

Referring to FIG. 4, the fast data channel allocation system 400 according to the present invention includes a mobile communication terminal 410, a source base station 420, a target base station 430, and a base station controller 440.

The mobile communication terminal 410 receives a basic channel (FCH) from the source base station 420 or the target base station 430, and transmits and receives low-speed data through the FCH. In this case, when the low speed data is transmitted from the mobile communication terminal 410 to the source base station 420 or the target base station 430, a reverse FCH (hereinafter referred to as RFCH) is used.

In addition, the mobile communication terminal 410 receives a high speed data channel (Supplemental CHannel, SCH) from the source base station 420 or the target base station 430, and transmits and receives high-speed data through the SCH. In this case, when the mobile communication terminal 410 transmits high speed data to the source base station 420 or the target base station 430, a reverse high speed data channel (hereinafter referred to as RSCH) is used.

The source base station 420 also includes a first channel element controller (CEC1) 422 and a first base station resource manager (BRC1) 424.

In addition, the target base station 430 includes a second channel element controller (CEC2) 432 and a second base station resource manager (BRC2) 434.

Here, the CEC1 422 and CEC2 432 perform control on the CDMA modem, provide information on the received power of the FCH, and transmit the quality of the channel to the BRC1 424 and BRC2 434.

The BRC1 424 and the BRC2 434 manage resources of the base station and perform scheduling, and allocate RSCHs such as Walsh ID, data rate, and channel element. Notify CEC1 422 and CEC2 432 of the information. In addition, the BRC1 424 and the BRC2 434 inform the base station controller 440 of the information on the determined data rate of the RSCH.

The base station controller 440 includes an access call controller (ACC) 442 and an access media controller (AMC) 444.

Here, the ACC 442 performs handoff and data call processing for the mobile communication terminal 410. Further, after receiving the message for the data rate of the RSCH from each base station, the ACC 442 performs a rate negotiation procedure when it is determined that rate negotiation is necessary.

The AMC 444 controls the data packet between the mobile communication terminal 410 and the base station 420. In addition, the AMC 444 configures the RSCH adjustment from the ACC 442 when the ACC 442 receives an RSCH allocation error from the BRC2 434 of the target base station 430 or times out for receiving a message. The RSCH is adjusted by receiving a (Modification Configure) message.

5 is a flowchart illustrating a method of allocating a fast data channel during handoff according to an embodiment of the present invention.

Referring to FIG. 5, when the mobile communication terminal 410 moves from the area of the source base station 420 to the area of the target base station 430, a power measurement report message (see FIG. 5) for the source base station 420 in the handoff area The Power Measurement Report Message (PMRM) is transmitted to the ACC 442 of the base station controller 440 (S502).

That is, when the mobile communication terminal 410 moves from the area of the source base station 420 to the area of the target base station 430, the mobile communication terminal 410 moves away from the source base station 420 and approaches the new target base station 430. The power state with the source base station 420 becomes lower and the power state with the target base station 430 becomes larger. Accordingly, the mobile communication terminal 410 transmits a PMRM message to the ACC 442 when it is located in the handoff area.

When the ACC 442 receives the PMRM message from the mobile communication terminal 410, the ACC 442 transmits a report of the PMRM to the AMC 444 through an Supplementary Channel Request Message (SCRM) ( S504). Here, SCRM is a message requesting allocation of a high speed data channel, and since the handoff occurs as the ACC 442 loses power to the source base station 420, not only the FCH but also the allocation of the high speed data channel (SCH) is also required. It is necessary to pass the SCRM to AMC 444.

The AMC 444 detects a change in the active set of the base channel (FCH) through a report of the PMRM received from the ACC 442, and assigns a modification of the high speed data channel (SCH) in response to the change in the FCH active set. In this case, a modification request (SCH_Modification_Req) message of the fast data channel (SCH) is transmitted to the ACC 442 (S506). At this time, the sector flag for the target base station 430 in the modification request message of the SCH is set to ADD.

When the ACC 442 receives the SCH_Modification_Req message of the SCH from the AMC 444, the BRC1 434 of the target base station 430 may be assigned to allocate a fast data channel (SCH) to the target base station 430. The SCH allocation request (SCH_Assignment_Reg) message is transmitted (S508).

That is, the ACC 442 recognizes the target base station 430 by the base station having the sector flag set to ADD based on the modification request message of the SCH, and transmits the fast data to the BRC1 434 of the target base station 430. This is to send an allocation request message for a channel.

The BRC1 434 of the target base station 430 determines link quality, that is, user power information request (User_Power_Req), to determine a data rate of a reverse high speed data channel (RSCH) for the corresponding mobile communication terminal 410. The message is transmitted to the CEC1 432 (S510).

That is, the BRC1 434 determines how much the FCH Rx power of the base channel of the mobile communication terminal 410 is when the CEC1 432 of the target base station 430 communicates with the mobile communication terminal 410. The user power information request (User_Power_Info_Req) message for inquiring is transmitted to the CEC1 432.

The CEC1 432 transmits power information on the FCH of the mobile communication terminal 410 to the BRC1 434 in a user power information response (User_Power_Info_Rsp) message (S512).

Based on the user power information response message (User_Power_Info_Rsp) received from the CEC1 432, the BRC1 434 may provide the RSCH allocation information indicating the high speed data channel (SCH) to the mobile communication terminal 410 to be set. The channel modification instruction message CE_Modification_Ind is transmitted to the CEC1 432 (S514).

Here, the RSCH allocation information includes a Walsh ID, a data rate, and a channel element.

In response to this, the CEC1 432 transmits a response to the channel modification indication message (CE_Modification_Rsp) to the BRC1 434 based on the RSCH allocation information (S516).

That is, the CEC1 432 responds to the channel modification indication message including the information indicating that the RSCH cannot be allocated to the mobile communication terminal 410 based on the RSCH allocation information received from the BRC1 434 (CE_Modification_Rsp). ) Message to the BRC1 434. Here, the content indicating that the RSCH cannot be allocated to the mobile communication terminal 410 includes a channel allocation error or a timeout.

When the BRC1 434 receives the response to the channel modification indication message from the CEC1 432 (CE_Modification_Rsp) message, the BRC1 434 receives an SCH assignment response message including information on the data rate of the RSCH, channel allocation error, timeout, and the like. 442) (S518).

When the ACC 442 receives the SCH assignment response message from the BRC1 434, the ACC 442 does not release the reverse high speed data channel (RSCH) for the source base station 420 despite the information on the channel allocation error or timeout. A source base station (BTS2) having the same content as it is, transmits an RSCH coordination configuration (SCH_Modification_Conf) message including the RSCH resource information to the AMC 444 (S520).

When the AMC 444 receives the RSCH coordination configuration (SCH_Modification_Conf) message from the AMC 444, the AMC 444 maintains the RSCH allocated to the source base station 420 without releasing it based on this (S522).

The ACC 442 allocates the first RSCH to the source base station 420 and the target base station 430 in the handoff situation of the mobile communication terminal 410, so that when there is a base station with a successful RSCH assignment and a failed base station, the RSCH The RSCH of the same data rate is allocated based only on the base station of which the allocation is successful, and information about the RSCH is transmitted to the AMC 444.

Thereafter, the AMC 444 sends a channel element release request (CE_Release_Req) message to the target base station 430 after a predetermined time elapses from the mobile communication terminal 410 leaving the handoff area and entering the area of the target base station 430. ) Is transmitted to BRC1 434 (S524).

Also, the AMC 444 re-requests the RSCH reassignment request for the base station that fails to allocate the RSCH when the active set information of the FDCH (Fundmental Dedicated CHannel) is changed, or releases all the RSCHs and then the mobile communication terminal. A request is made at the time of the RSCH allocation request by the Supplemental Channel Request Message (SCRM) of 410.

In addition, the AMC 444 determines the data rate of the RSCH based on the lowest data rate among the base stations that have successfully allocated the RSCH, and performs RSCH allocation only to the base stations that have successfully allocated the RSHC.

The BRC2 434 of the target base station 430 transmits a channel element release indication (CE_Release_Ind) message indicating release of the channel element to the CEC2 432 (S526).

The CEC2 432 of the target base station 430 releases the channel element of the RSCH for the mobile communication terminal 410 and transmits a response (CE_Release_Rsp) message to the BRC2 434 to release the channel element (S528).

Accordingly, the BRC2 434 of the target base station 430 transmits a response (CE_Release_Conf) message to the ACC 442 in response to the channel element release request (S530).

Meanwhile, when the ACC 442 determines that rate negotiation is necessary after receiving a message for the RSCH data rate from each base station, the ACC 442 transmits the corresponding message for rate negotiation to all BRCs to which the RSCH is assigned. The ACC 442 extracts the final result from the RSCH allocation result from the BRC, unconditionally taking a minimum value of all allocation results, a minimum value except failure, and a minimum value except a specific rate.

If there is a rate change for the base station for the RSCH negotiation indication message, the BRC performs a change procedure. Otherwise, the BRC ignores the RSCH negotiation indication message and transmits a response message to the ACC 442. The Walsh ID, channel element, etc. may be changed at the rate change. The CEC responds to the BRC in response to the RSCH negotiation indication message. The BRC forwards the RSCH negotiation response to the ACC 442.

The ACC 442 performs a rate negotiation procedure if the information on the data rate of the RSCH is different from each base station. A Supplemental Channel Assignment Message (ESCAM) is transmitted to the mobile communication terminal 410. At this time, the ESCAM message is transmitted as an L3 Ack request and if the Ack does not arrive within a certain time, the RSCH release procedure is entered. The ACC 442 transmits the final result of the RSCH allocation to the AMC 444, updates its DB according to the corresponding result of the AMC 444, and receives and processes the RSCH frame.

As described above, according to the present invention, when the mobile communication terminal moves from the base station area capable of high speed data service to another base station area not supported by the high speed data service, The present invention provides a method and system for allocating a high speed data channel during handoff to receive a high speed data service by allocating a data channel.

In addition, the present invention, when the base station of the reverse high-speed data channel and the base station of the reverse base channel is different for the mobile communication terminal in the handoff area, changing the transmission rate in accordance with the pilot strength (Pilot Strength) of the reverse base channel of the base station, Provided are a method and system for allocating a high speed data channel during handoff.

In addition, the present invention requests the allocation of a high-speed data channel to a base station capable of high-speed data service in a handoff region at a time period specified by an operator, and receives a high-speed data channel from a base station capable of high-speed data service to provide a high-speed data service for a predetermined time. It is possible to provide a base station controller that can provide.

As those skilled in the art to which the present invention pertains may implement the present invention in other specific forms without changing the technical spirit or essential features, the embodiments described above should be understood as illustrative and not restrictive in all aspects. Should be. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

1 is a diagram illustrating a conventional method for allocating a reverse channel during handoff;

2 is a flowchart illustrating a call processing method when there is no high speed data channel in a conventional target base station;

3 is an exemplary diagram for explaining a reverse channel allocation method during handoff according to an embodiment of the present invention;

4 is a block diagram schematically showing the configuration of a fast data channel allocation system during handoff according to an embodiment of the present invention; and

5 is a flowchart illustrating a method of allocating a fast data channel during handoff according to an embodiment of the present invention.

Description of the Related Art

400: high speed data channel allocation system 410: mobile communication terminal

420: source base station 430: target base station

422, 432: CEC 424, 434: BRC

440: base station controller 442: ACC

444: AMC

Claims (20)

A method for allocating a high speed data channel to a mobile communication terminal during handoff from a source base station to a target base station, the method comprising: (a) an access call controller (ACC) receives a power measurement report message (PMRM) for the source base station from the mobile communication terminal and reverses it to the target base station based on this; Requesting allocation of a fast supplemental channel (hereinafter referred to as RSCH); (b) the ACC receiving the RSCH assignment error message from the target base station; (c) the ACC transmitting resource information on an RSCH of the source base station to an access media controller (hereinafter referred to as AMC); And (d) the AMC maintaining an RSCH of the source base station; A high speed data channel allocation method at handoff comprising a. The method of claim 1, In step (d), the AMC re-requests when the Active Set information of the Fundamental Dedicated CHannel (FDCH) is changed for RSCH reallocation of the base station that fails to allocate the RSCH. Channel assignment method. The method of claim 2, And re-allocating the RSCH when the AMC releases all the RSCHs and requests the RSCH allocation according to a supplemental channel request message (SCRM) of the mobile communication terminal. The method of claim 1, After the step (d), the AMC determines the data rate of the RSCH on the basis of the lowest data rate among the base stations that have successfully allocated the RSCH, and performs the RSCH allocation only by the base station that has succeeded in the RSCH allocation. A high speed data channel allocation method at handoff. The method of claim 1, The resource information for the RSCH includes a Walsh ID, a data rate, and a channel element. The method of claim 1, In the step (d), the AMC allocates an RSCH having the same data rate to the source base station based on the base station which successfully allocates the high speed data channel to the source base station. The method of claim 1, The RSCH allocation error message includes an allocation error or timeout of the RSCH. In the high speed data channel allocation system, the mobile station is assigned a Reverse Supplemental CHannel (hereinafter referred to as RSCH) during handoff from a source base station to a target base station. A base station resource manager (BTS Resource Controller) for allocating the RSCH of the source base station or the target base station; Receives a power measurement report message (PMRM) for the source base station from the mobile communication terminal and requests an RSCH allocation for the target base station to the BRC based on this, and allocates an RSCH from the BRC. In case of receiving, the access call controller (ACC) requesting to maintain the RSCH of the source base station: An access media controller (AMC) for controlling data packets of the source base station or the target base station and maintaining the RSCH setting of the source base station when the ACC is requested to maintain the RSCH of the source base station; High speed data channel allocation system comprising a. 9. The method of claim 8, The ACC transmits resource information on the RSCH of the source base station to the AMC to request to maintain the RSCH of the source base station. The method of claim 9, The resource information for the RSCH includes a Walsh ID, a data rate, and a channel element. 9. The method of claim 8, And the AMC re-allocates the RSCH when the Active Set information of the basic channel (FCH) is changed for the base station that fails to allocate the RSCH. 9. The method of claim 8, The AMC, after releasing all RSCHs, reassigns the RSCH when an RSCH allocation request is made by a supplemental channel request message (SCRM) of the mobile communication terminal. 9. The method of claim 8, The ACC determines the data rate of the RSCH based on the lowest data rate among the base stations that have successfully allocated the RSCH, and assigns the RSCH only to the base station that has successfully allocated the channel. Stem. 9. The method of claim 8, And the AMC changes the data rate of the RSCH in accordance with the pilot strength of the base channel when the active base station of the RSCH is different from the active base station of the base channel (RFCH). 9. The method of claim 8, The ACC allocates the RSCH to the source base station and the target base station for the first time when the mobile communication terminal is handed off. And assigning an RSCH of the same data rate as a reference and transmitting information on the same to the AMC. A base station controller for controlling a reverse supplemental channel (RSCH) to be allocated to a mobile communication terminal during handoff from a source base station to a target base station. Receives a power measurement report message (PMRM) for the source base station from the mobile communication terminal and requests an RSCH allocation for the mobile communication terminal to the target base station based on the received power measurement report message (PMRM). An access call controller (ACC) requesting to maintain the RSCH of the source base station by transmitting resource information on the RSCH of the source base station when an allocation error is received; and An access media controller (AMC) for maintaining the RSCH configuration of the source base station when receiving resource information on the RSCH of the source base station from the ACC; / RTI > 17. The method of claim 16, The resource information for the RSCH includes a Walsh ID (Walsh ID), a data rate (Data Rate), and a channel element (Channel element). 17. The method of claim 16, The ACC is a base station controller, characterized in that for determining the data rate of the RSCH on the basis of the lowest data rate of the successful base station allocation. 17. The method of claim 16, The AMC, when the active base station of the RSCH is different from the active base station of the base channel (RFCH), the base station controller, characterized in that for changing the data rate of the RSCH in accordance with the pilot strength of the base channel. 17. The method of claim 16, The ACC allocates the RSCH to the source base station and the target base station for the first time when the mobile communication terminal is handed off. The base station controller, characterized in that the RSCH of the same data rate is allocated as a reference, and information about the same is transmitted to the AMC.

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