KR100782236B1 - Handover method for uplink synchronous transmission scheme - Google Patents

Abstract

In the reverse link synchronous transmission method of the mobile communication system, in particular, a handover signaling method of combining soft handover and hard handover, the handover method in the reverse link synchronous transmission method according to the present invention In the reverse link synchronous transmission scheme of the mobile communication system, the mobile station measures the pilot strength of the current base station and the target base station, receives a handover message, performs a handover, and is connected to the existing base station and the target base station; Acquiring, by the control station, synchronization timing of a reverse link synchronous transmission scheme of the target base station after the step; Resetting a radio link between the target base station and the mobile station to a communication state in a reverse link synchronous transmission scheme with a new timing and code based on timing information obtained through the synchronization timing of the reverse link synchronous transmission scheme; Releasing a radio link with an existing mobile station when the mobile station leaves the handover area.

Mobile communication system, handover

Description

HANDOVER METHOD FOR UPLINK SYNCHRONOUS TRANSMISSION SCHEME

1 is a schematic configuration diagram of a mobile communication system for explaining a handover between two base stations in a conventional reverse link.

Fig. 2 is a diagram showing the structure of a radio access network during soft handover between base stations in a conventional control station.

3 is a diagram showing the structure of a radio access network in the case of conventional Inter RNS Soft-handover between different control stations.

4 is a flowchart illustrating a conventional handover method at the time of inter-RNS soft-handover between different control stations.

5 is a flowchart illustrating a method for soft handover between base stations in the same control station in a reverse link synchronous transmission scheme according to an embodiment of the present invention.

6 is a flowchart illustrating a soft handover method between different control stations in a reverse link synchronous transmission scheme according to another embodiment of the present invention.

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

Serving Control Station (SRNC)

Destination Control Station (DRNC)                 

403,502,503,603 ... base station in serving control station

404,604 ... base station within destination control station

405,504,605 ...

The present invention relates to a handover processing method in a mobile communication system, in particular, a hand combined with soft handover and hard handover in a reverse link transmission scheme for synchronizing reception times between mobile station signals at a base station. It's about the over way.

More specifically, the present invention, when performing the handover control of the mobile station in the reverse link synchronous transmission method applied to the mobile communication system, when the mobile station moves from the existing base station (cell) to the target base station (cell), the existing inter-station interface By using the protocol, it is possible to provide specific signal processing procedures, signaling messages required for each procedure, and parameters of the reverse link synchronous transmission scheme required for each message. The present invention relates to a handover method in a reverse link synchronous transmission scheme that enables hard handoff of a mode.

This Uplink Synchronous Transmission Scheme (USTS) reduces the multiple access interference in a cell by using the orthogonality of orthogonal codes by controlling the reception time of mobile station signals using a closed loop timing control method at a base station. Technology for.

In the following description of the handover type, a hard handover for terminating a call with an old base station before connection of a call channel with a new base station and a termination of a call with an old base station after connection with a new channel is connected. Soft handover and handover between sectors of the same base station during soft handoff are called softer handovers. In other words, soft and soft handover is a method of disconnecting a call and there is a dual connection to the same call simultaneously with two base stations involved in handover for a certain period of time. Hard handover, on the other hand, initiates a new call only after ending the current call, resulting in a discontinuity in the call. Handover is the same term as handoff.

The conventional soft (softer) handover scheme is a technology that allows a mobile station (user terminal / mobile terminal) to continuously maintain a communication channel while simultaneously communicating with a plurality of base stations during handover between cells or sectors.

1 is a diagram for explaining soft handover between two base stations in a conventional reverse link, and includes a core network (CN) including a selector 101a for selecting the best frame based on a received frame. And a control station (RNC), a mobile station 102 and one or more cells 103 and 104.

Soft handover between the base stations in the conventional reverse link, as shown in Figure 1, the transmission signal of the mobile station 102 in the reverse link is two base stations (cells) 103, 104, that is, the existing cell A (103) and It is received at the target cell B 104 at the same time.                         

The two base stations 103 and 104 respectively demodulate the received signal from the mobile station 102 and send the demodulated frames to the core network CN, respectively. The core network 101 selects the best frame among the received frames. ) To choose from.

On the other hand, in softer handover, when the mobile station 102 moves between different sectors in the same cell 103 or 104, the handover is performed by the same operation as the soft handover described above. The two signals received from 102 are demodulated and combined in the cell so that only one frame is sent to the control station (RNC).

FIG. 2 is a diagram illustrating a structure of a radio access network in an inter-node B soft-handover (Intra RNS) in a conventional control station.

Referring to FIG. 2, a soft handover between base stations in a control station is performed by a Serving RNC (SRNC) 211 existing in a UMTS radio access network within a Serving Radio Network Subsystem (SRNS). Manage dedicated radio resources allocated to the mobile station 220.

At this time, when the mobile station 220 moves from one base station 212 to another target base station 213 in the serving control station 211, the two base stations 212 and 213 demodulate signals received from the mobile station 220, respectively, The demodulated frame is sent to the serving control station 211, and the serving control station 211 selects the best frame among the received frames, thereby simultaneously communicating with the two base stations 102 and 103 while the mobile station 220 moves. Keep up. Here, the serving control station 211 and the base stations 212 and 213 are present in a Serving Radio Network Subsystem (SRNS).

3 is a diagram illustrating a structure of a radio access network during soft handover between different control stations 312 and 316. In a UMTS radio access network, a serving control station 316 and a destination control station 312 each include a plurality of base stations. Under a wireless environment controlling 313 and 317, the mobile station 320 is in a state of maintaining a talk channel simultaneously with each of the base stations 313 and 317 present in the two control stations 312 and 316 during soft handover.

Here, the serving control station 316 manages the dedicated radio resources allocated to each mobile station, and the destination control station (DRNC: Drift RNC) 312 is the mobile station 220 leaving the serving control station 316 itself. When moving to the area of the control station of the destination that provides radio resources to the mobile station 220 and is present in the destination radio network subsystem (DRNS: Drift RNS) (311).

FIG. 4 is a flowchart illustrating a handover method in the conventional case of Inter RNS Soft-handover between different control stations. In FIG. 1, when the mobile station moves from the existing base station 103 to the target base station 104, FIG. Shows the handover control procedure.

Referring to FIG. 4, the conventional soft handover procedure is largely divided into a radio link adding step (S410) and a radio link deleting step (S420), and the detailed steps thereof are as follows.

In the step of adding a radio link (S410), when the mobile station 405 enters the handover area, it establishes a new link with the target base station (S411). The serving control station (SRNC-existing control station) 401 is a destination link station (DRNC) 402. The radio link setup request (Radio Link Setup), which is one of RNSAP messages, is an interface protocol between control stations. Request) command to establish a new wireless link through the message (S412).

Then, the destination control station 402 is a base station (DRNS-BS) 404 in the destination RNS (DRNS), which is one of the NBAP (Node B application Part, where Node B is a base station) message, which is an interface protocol between the base station and the control station. Command to establish a new radio link through a radio link setup request message (S413).

After the base station 404 in the destination RNS successfully establishes the radio link according to the radio link setup message, it reports it to the destination control station 402 through a Radio Link Setup Response message, which is an NBAP message ( S414). The destination control station 402 reports to the serving control station 401 that the radio link has been successfully established to the target cell through a radio link setup request message which is an RNSAP message (S415).

Subsequently, the serving control station 441 uses the mobile set update command (Active Set Update Command) message, which is one of radio resource control (RRC) messages, which is an interface protocol between the mobile station 405 and the RNC. Command to update the activation set to enable soft handover to the new target cell (S416). Here, an active set is a set of cells in communication with a mobile station over the same forward traffic channel.

Then, the mobile station 405 adds a new target cell to the activation set according to the active set update command message and the serving control station SRNC through an Active Set Update Complete message, which is a Radio Resource Control (RRC) message. 401) (S417). After the radio link adding step, the radio link deletion step (S420) releases the radio link for the existing cell when the mobile station leaves the handover area (S421).

The Serving Control Station (SRNC) 401 then instructs the mobile station 405 to update the activation set via an Active Set Update Command message which is a Radio Resource Control (RRC) message to release the radio link between the existing base station and the mobile station. (S422).

At this time, the mobile station 405 removes the existing base station 403 from the activation set according to the active set update command message and reports it to the serving control station 401 through an active set update complete message, which is a radio resource control message (S423).

Then, the serving control station 401 instructs the existing base station 403 to release the radio link with the mobile station 405 through a Radio Link Deletion Request message, which is an NBAP message (S424).

The existing base station 403 releases the resources allocated to the radio link according to the radio link removal request message and reports to the serving control station 401 through a radio link removal response message which is an NBAP message (S425).

In addition, the soft handover method between base stations in the same control station is the same as FIG. 4 except for the RNSAP procedures S412 and S415, which are signaling between the control station and the control station.

However, the above-described handover scheme does not consider a transmission scheme supported for improving the basic performance of the reverse link at the base station, that is, a reverse link synchronous transmission scheme for synchronizing reception times between mobile station signals at the base station. . That is, the base station performs the handover without considering the transmission method of controlling the reception timing of the mobile station signals by the closed loop timing control method.

Therefore, along with the operation of the conventional soft (softer) handover scheme, hard handover transfer signaling of reverse synchronization timing, which is essential for the reverse link synchronous transmission scheme, should be considered. In this case, the reverse synchronization timing of the backward synchronization timing cannot be matched with the reverse synchronization timing of the current serving base station and the target base station, and is selected as either synchronization. Therefore, the reverse synchronization timing is a hard handover rather than a soft handover.

In addition, if the hard handover of the reverse synchronization timing is not considered as described above, the gain of the reverse synchronization transmission cannot be continuously obtained due to the inter-cell or sector movement of the mobile station. Accordingly, there is a need for a handover signaling procedure of a synchronous timing transfer method that can operate while considering a soft (soft) handover method proposed in the related art. That is, the reverse link synchronous transmission method may have advantages such as increased cell occupancy area as well as performance and capacity, but this is not considered in the conventional handover method.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems and implements a handover signaling procedure in which soft (soft) handover and hard handover are combined in a reverse link synchronous transmission scheme of a mobile communication system. An object of the present invention is to provide a handover method in a reverse link synchronous transmission scheme.                         

For another purpose, by using the existing base station system as it is, by allowing the base station to perform the measurement reporting procedure and mode switching procedure for timing acquisition in the reverse link synchronous transmission scheme to reset the reference timing to the mobile station, It is an object of the present invention to provide a handover method in a reverse link synchronous transmission scheme in which a mobile station can reconfigure a radio link synchronized with a target base station.

Another object of the present invention is to provide a signal processing procedure for soft handoff between base stations in the same serving control station and a signal processing procedure for soft handoff between base stations in different control stations in a reverse synchronous transmission scheme. It is an object of the present invention to provide a handover method in a reverse link synchronous transmission scheme.

Another object is a handover in a reverse link synchronous transmission scheme in which a message is included in an interface protocol between different control stations, control stations and base stations, control stations and mobile stations, and the required parameters can be transmitted. The purpose is to provide a method.

In order to achieve the above object, the handover method in the reverse link synchronous transmission method according to the present invention,

In the reverse link synchronous transmission scheme of the mobile communication system, the mobile station measures the pilot strength of the current base station and the target base station, receives a handover message, performs a handover, and is connected to the existing base station and the target base station;

Acquiring, by the control station, synchronization timing of the reverse link synchronous transmission scheme of the target base station after the step;

Resetting a radio link between the target base station and the mobile station to a communication state in a reverse link synchronous transmission scheme with a new timing and code based on timing information obtained through the synchronization timing of the reverse link synchronous transmission scheme;

Releasing a radio link with an existing mobile station when the mobile station leaves the handover area.

Preferably, the synchronization timing acquiring step, if the target base station and the existing base station is being controlled by the same control station, the control station forwards a dedicated measurement start request message for acquiring USTS timing to the target base station, the target And transmitting, by the base station, the measurement result according to the measurement start request message of the control station to the control station as a response message.

Preferably, the synchronizing timing acquiring step may include: when the target base station and the existing base station are not the same control station, the control station forwarding a dedicated measurement start request message for acquiring USTS timing to a destination control station; Transmitting the dedicated measurement start request message to the controlling target base station; transmitting, by the target base station, the measurement result according to the measurement report request message to the destination control station as a report message; And transmitting the received dedicated measurement report message to the control station.

Preferably, the radio link resetting step of the mobile station, when the target base station and the existing base station is being controlled by the same control station, the control station forwards a reset request message to the target base station to the USTS radio link, the wireless Resetting the radio link obtained by the link addition to the USTS mode; when the target base station is reset to the USTS mode, causing the control station to reset the radio link USTS mode set to the existing base station to the Non-USTS mode; And activating the target base station in the set USTS mode after resetting the base station, and reestablishing the existing link to the mobile station in a wireless link in synchronization with the target base station in the USTS mode.

Preferably, the step of resetting the radio link of the mobile station, when the target base station and the existing base station is controlled by different control stations, the existing control station via the destination control station to send a request for resetting the radio link to the USTS mode; Delivering to a target base station; Requesting the existing control station to reset the radio link USTS mode set to the existing base station to another non-USTS mode when the existing control station receives the radio link reconfiguration preparation message of the target base station from the destination base station through the destination control station; Transmitting a message for activating a USTS mode to a target base station through the destination control station after re-establishing a radio link of the existing base station; when the target base station is activated, the target base station and the mobile station are connected to a wireless link with USTS synchronization. It characterized in that it comprises a step of requesting a reset.

Preferably, the message information about the reverse link synchronous transmission includes an identifier of a reverse link synchronous transmission scheme, a scramble code of the transmission scheme, a scramble offset of the transmission scheme, timing reference information of a target cell of the transmission scheme, and a channel of the transmission scheme. Characterized by the number of code.

A handover method in the reverse link synchronous transmission method according to the present invention configured as described above will be described with reference to the accompanying drawings.

5 is a flowchart illustrating a method of an intra node B soft-handover (Intra RNS) in a same control station in a reverse link synchronous transmission scheme of the present invention. 6 is a flowchart illustrating a method for inter-RNS soft handover between different RNCs.

Referring to FIG. 5, the signaling processing procedure in the case of Intra RNS (Inter Node B Soft-handover) in the same control station in the reverse link synchronous transmission scheme is as follows.

First, when the mobile station 504 enters the handover area (base station 1-> base station 2), the serving control station 501 establishes a new link with the target base stations (base stations 2 and 502) (S510). Here, the new link setup requires the serving control station 501 to set up a radio link to the target base station (cell) and receive a response, and then to request the mobile station 504 to update the activation set, thereby creating a new target base station 502 in the activation set. ) Is the procedure of adding (see FIG. 4).

When the mobile station 504 enters the handover area, a new link with the target base station 502 is established (S511).

The serving control station (ie, the existing control station) 501 performs a measurement report procedure for acquiring USTS timing (S520), while synchronizing the target base station 502 while measuring and comparing the quality of the mobile station signals of both links. The timing determines whether to hard handover, and the timing information with the target cell is obtained through a dedicated measurement procedure.

To this end, the serving control station (SRNC) 501 transmits a DEDICATED MEASUREMENT INITIATION request message, which is an NBSP message, to the target base station (base station 2) 502 to obtain the synchronization timing of the target base station 502. (S512).

The dedicated measurement start request message includes a dedicated measurement type and a report characteristic information element and is transmitted. The dedicated measurement type is an on demand element and a report characteristic element is a RTT. (Round Trip Time) element.

Here, the on-demand is a parameter for the base station receiving the measurement report to immediately perform measurement and report, and the RTT is a parameter indicating the time until the base station transmits the forward DPCH frame and receives the reverse DPCH frame from the mobile station. to be. These two parameters allow a user to receive a measurement report command using a dedicated measurement start request message and to report a result of measurement by the parameter to be measured. This is because the RTT measurement value is needed to synchronize the reverse link when using the reverse synchronous transmission scheme.

The target base station 502 then includes the measurement result in the dedicated measurement report message and delivers the result to the serving control station 501.

Thereafter, the serving control station 501 performs a switching procedure of the USTS mode through the target base station 502 and the electromotive base station 503. The USTS mode switching procedure is performed by the serving control station for the measurement reporting procedure for obtaining the USTS timing. Based on the timing information obtained through the new timing and code, the radio link between the target cell and the mobile station is reconfigured to USTS mode, and then the radio link between the existing cell and the terminal is reset to non-USTS mode.

Here, there are three modes in USTS, a normal mode which is a method used in a system that does not support USTS and a mobile station, a USTS mode that supports USTS and a transmission timing controlled by the USTS method, There is a NON-USTS mode that supports USTS but does not control transmission timing by USTS.

Therefore, since it is used in a terminal and a system supporting USTS, mode conversion is performed for the USTS mode and the NON-USTS mode. That is, if one mobile station is in a soft handover area that spans two cells and both cells support the USTS scheme, the mobile station operates in USTS mode with one cell and NON-USTS mode with another cell. do. This is because one mobile station cannot operate in two cells and USTS mode, and needs to synchronize the backward synchronous transmission timing with one cell. Therefore, the NON-USTS mode corresponds to a case in which the USTS scheme is supported but the USTS scheme is not transmitted.

Accordingly, the USTS mode is a state in which a mobile station and a base station communicate using a reverse synchronous transmission method, and the Non-USTS mode uses a reverse synchronous transmission method between a mobile station and a base station, but it may be said that the reverse synchronization is not matched.

In addition, the serving control station 501 transmits a radio link obtained through a soft handover procedure (adding a radio link) to the target base station 502 through a radio link reset preparation message, which is an NBAP message, in a USTS mode. Command to reset to (S521).

Here, the radio link reconfiguration preparation message includes a USTS indicator information element (USTS Indicator), a scrambling code and a channelization code number information element of a new USTS radio link to be set.

The target base station 502 receiving the radio link reconfiguration preparation message resets the radio link based on the information included in the message in step S521, and indicates that the radio link reset is successfully completed. Report to the serving control station 501 through a RADIO LINK RECONFIGURATION PREPARE message (S522). At this time, the USTS indicator information element of the message is selected as USTS.

The serving control station 501 instructs the base station (base station 1, 503) to reset the radio link set to the USTS mode to the non-USTS mode through a radio link reset preparation message, which is an NBAP message (S523). . The message for resetting to the non-USTS mode includes a time information element, a USTS identifier information element, a scrambling code information element of a newly configured USTS radio link, and a channel code information element as a timing reference between the target cell and the serving base station. . At this time, USTS identifier should be set to Non-USTS mode.

After the step S523, the base station 503 resets the radio link based on the information obtained above, and reports to the serving control station 501 through a radio link reset preparation message, which is an NBAP message, that the radio link reset has been successfully completed. do. The USTS identifier information element of this message is selected in non-USTS mode.

In addition, the serving control station 501 instructs the target base station 502 to activate the USTS mode radio link established according to the procedures S521 to S524 through a radio link reset commit message which is an NBAP message (S525). In addition, the existing base station 503 is instructed to activate the Non-USTS mode radio link established according to the above S523 and S524 procedures through a radio link commit message, which is an NBAP message (S526).

Subsequently, the serving control station 501 transmits to the mobile station 504 through a physical channel reset message, which is one of radio resource control messages, to the mobile station 504 in a radio link in which USTS synchronization with the target base station 502 is synchronized. Command to reestablish link (S527).

Then, the mobile station 504 transmits a scrambling code, a channel code, and an accurate transmission timing adjustment value to the physical layer according to the physical channel reset message, thereby performing mode changing and timing adjustment (S528). When the setting is completed, the serving control station 501 reports a radio channel message through a physical channel reset message (S529).

When the mobile station moves out of the handover area, a radio link releasing procedure for releasing a radio link for the existing base station 503 is performed (S530).

FIG. 6 illustrates an INTER RNS Soft Handover method between different RNCs in a reverse synchronous link transmission method. When a mobile station 605 enters a handover region, a radio link addition procedure for establishing a new link with a target base station is shown. To perform (S610).

Thereafter, in order to perform a measurement reporting procedure for acquiring USTS timing (S620), the serving control station 601 measures and compares the quality of mobile station signals of different radio links, while synchronizing timing of the target base station DRNS-base station 604. Determine whether to hard handover, and obtain timing information with the target base station through a dedicated measurement procedure.

In the measurement report procedure (S620) for acquiring the USTS timing, the destination control station transmits a DEDICATED MEASUREMENT INITIATION request message, which is a RNSAP message, in order for the serving control station 601 to acquire the synchronization timing of the target base station 604. And transmits to step 602 (S611). The dedicated measurement type information element of the message is set to on demand, and the report specific information element is set to RTT.

Then, the destination control station DRNC 602 issues a timing acquisition command to the target base station 604 through the dedicated measurement start message in the Node B application part (NBAP) message (S612). The dedicated measurement type information element (IE) of the message is set on demand and the RTT is selected as the report specific information element.

Upon receiving the message from the destination control station 602, the target base station 604 measures the RTT as set in the report characteristic information element and immediately reports it to the destination control station 602 through a dedicated measurement report message which is an NBAP message ( In step S613, the destination control station 602 transfers the result received from the target cell to the serving control station through the dedicated measurement report message which is an RNSAP message (S614).                     

Thereafter, the serving control station 601 performs a radio link between the target base station 604 and the mobile station with a new timing and code based on the timing information obtained through the measurement report procedure for acquiring the USTS timing in order to perform the mode switching procedure. Resets to USTS mode, and the radio link between the existing cell and the terminal is reset to Non-USTS mode.

To this end, the serving control station 601 instructs the destination control station 602 to reset the radio link obtained by the soft handover procedure (add the radio link) to the USTS mode through the radio link reset preparation message, which is an RNSAP message. (S621). The USTS identifier information element of the message is selected as USTS.

Then, the destination control station 602 instructs the target base station 604 to reset the radio link obtained through the soft handover procedure (add the radio link) to the USTS mode through a radio link reset preparation message, which is an NBAP message ( S622). This message includes a USTS identifier information element and a scrambling code and channelization code number information element of a new USTS radio link.

The target base station 604 resets the radio link based on the information obtained in step S612, and reports to the destination control station 602 through a radio link reset preparation message, which is an NBAP message, that the radio link reset is completed ( S623). The USTS identifier information element of this message is selected as USTS.

Then, the destination control station 602 transmits the information on the USTS mode radio link between the newly changed target base station 604 and the mobile station to the serving control station 601 through a radio link reset preparation message which is an RNSAP message (S624). ). The message includes a time (T _ref ) information element, a USTS identifier information element, a scrambling code information element, a channel code information element, and a scrambling code offset of a new USTS radio link to be a timing reference between the target base station and the serving control station. ) Should be included.

Then, the serving control station 601 instructs the base station (SRNS-base station) 603 to reset the radio link set to the USTS mode to the non-USTS mode through a radio link reset preparation message, which is an NBAP message (S625). ). This message should include the time (Tref) information element obtained in step S624, the scrambling code information element and the channelization code number information element of the newly set USTS radio link. At this time, USTS identifier should be set as Non-USTS.

The existing base station 603 resets the radio link based on the information obtained in step S625, and reports to the serving control station 601 through a radio link reset preparation message, which is an NBAP message, that the radio link reset is completed. (S626). The USTS identifier information element of this message is selected as Non-USTS.

Then, the serving control station 601 instructs the destination control station 602 to activate the USTS mode radio link established according to the procedure of steps S621 to S624 through a radio link reset commit message which is an RNSAP message (S627). . Receiving this, the destination control station 602 instructs the target base station 604 to activate the USTS mode radio link established according to the procedure of steps S621 to S624 through a radio link reset commit message which is an NBAP message (S628).                     

In addition, the serving control station 601 instructs the existing base station 603 to activate the non-USTS mode radio link established according to the procedures of steps S625 and S626 through a radio link reset commit message which is an RNSAP message (S629). .

As such, when the target base station 604 is reset to the USTS mode and the existing base station 603 is reset to the Non-USTS mode, the serving control station 601 may transmit a physical channel reset message, which is one of radio resource control messages. The mobile station 605 is instructed to reestablish an existing link to a radio link in which USTS synchronization with the target base station 604 is performed according to the procedure of steps S621 to S628 (S630).

Then, the mobile station 605 performs a mode change and timing adjustment by transmitting a scrambling code, a channel code, and an accurate transmission timing adjustment value to the physical layer according to the physical channel reset message by the serving control station 601 (S631). When the setting of the lower layer is completed, the serving control station 601 reports a radio channel control message through a physical channel reset message (S632).

Thereafter, when the mobile station leaves the handover area, a radio link release procedure for releasing a radio link for an existing cell is performed (S640).

As described above, in the present invention, when the mobile stations 604 and 605 enter the handover region, soft handover is performed while measuring the pilot strength of the current base station and the target base stations 502 and 604. Hard handover is performed at the synchronization timing of the target base station while measuring the strength of the pilot, and then soft handover to the target base station is completed by measuring the pilot strength of the existing base station. The hard handover is combined to perform handover in the reverse link synchronous transmission scheme.

In addition, in case of hard handover of the reverse link synchronous transmission (USTS) mode in the soft handover region, a specific signal processing procedure is provided, and signaling messages necessary for each procedure and parameters required for each message are defined. Asynchronous systems (eg 3GPP) and mobile stations allow hard handover of the mode of reverse link synchronous transmission in the soft handover area.

In addition, in the reverse link synchronous transmission scheme, not only the signal processing procedure for soft handover between base stations in the same wireless network control station but also the signal processing procedure for soft handover between different wireless network control stations are defined.

As described above, according to the handover method in the reverse link synchronous transmission method according to the present invention, since the handover is performed by a combination of soft (softer) handover and hard handover, a handover method that is generally applied is used. Not only can it be used as it is, but it is hard to be provided from the base station to the base station so that the mobile station is provided with the reference timing without any additional complicated elements for controlling the signal transmission timing of the mobile station for the hard handover of the synchronous timing to the existing handover method. All you have to do is select the timing to handover and send control parameters accordingly. Therefore, due to the increase in performance and capacity, as well as the cell occupancy area of the reverse link synchronous transmission method, only the hard handover of timing can be considered separately, and it is possible to maintain the base station timing which has been previously synchronized, so that the overall handover is possible. It leads to an improvement in performance.

In addition, in hard handover of all modes of the reverse link synchronous transmission in soft handover, a measurement reporting procedure and a mode switching procedure for timing measurement are defined, and signaling messages required in each procedure and required in each message are required. By defining the parameters of the reverse link synchronous transmission scheme, a hand-off mode of the reverse link synchronous transmission scheme can be performed in the soft handover region in the asynchronous system and the mobile station.

In addition, by defining not only the signal processing procedure for soft handoff between base stations in the same radio network control station, but also the signal processing procedure for soft handoff between different radio network control stations, the mobile station can be handed over more efficiently. It allows you to.

Claims (17)

Step in which the mobile station is associated with an existing base station and the target base station to execute handover measures the pilot strength of the existing base station and the target base station receives a handover message from the reverse link synchronous transmission scheme in a mobile communication system; Transmitting , by the control station controlling the target base station, a dedicated measurement start request message for obtaining synchronization timing of a USTS (reverse synchronous transmission method) to the target base station; Transmitting, by the target base station, the measurement result according to the measurement start request message of the control station to the control station as a response message; Resetting the radio link between the target base station and the mobile station to a communication state in a reverse link synchronous transmission scheme with a new timing and code based on the timing information obtained through the response message; And releasing a radio link with an existing base station when the mobile station is out of the handover region.  The method of claim 1, In the synchronizing timing obtaining step, if the control station controlling the target base station is not the control station controlling the existing base station, the control station controlling the existing base station sends a dedicated measurement start request message for obtaining the USTS timing to the destination control station. The handover method of the reverse link synchronous transmission method characterized in that it further comprises the step of transmitting. The method according to claim 1 or 2, And the dedicated measurement initiation request message includes a dedicated specific time information element and a reporting characteristic information element. The method of claim 3, wherein The dedicated measurement time information element is an on-demand parameter, and the reporting feature information element is set to RTT. The method of claim 1, The resetting of the radio link of the mobile station may include: reestablishing, by the control station, a radio link obtained by adding the radio link to the USTS radio link request message to a target base station to a USTS mode; When the control station resets the radio link USTS mode to the non-USTS mode of the existing base station, activating the target base station to the set USTS mode after resetting the mode of the base station; And re-establishing an existing link with a USTS-synchronous radio link. The method of claim 5, When the target base station and the existing base station are controlled by different control stations, the step of reestablishing a radio link of the mobile station may include a control station controlling the existing base station performing an existing link with a wireless link that is USTS-synchronized with the control station. And requesting to reset the handover method in a reverse link synchronous transmission scheme. The method according to claim 5 or 6, The radio link resetting request message of the target base station from the control station includes a USTS identifier, a USTS scrambling code, and a USTS channelization code number. The method according to claim 5 or 6, And a USTS identifier is included in the radio link reset request message of the base station from the control station. The method according to claim 5 or 6, And a USTS scrambling code is included in the radio link resetting request message of the base station from the control station. The method according to claim 5 or 6, And a number of USTS channelization codes in the radio link reconfiguration request message of the base station from the control station. The method of claim 7, wherein The radio link reconfiguration request message from the control station to the existing base station includes a USTS identifier, a USTS scrambling code, a USTS channelization code number, a USTS scramble code offset, and a time information element as a timing reference between the target base station and the control station. Handover method in the reverse link synchronous transmission method characterized in that transmitted. The method of claim 7, wherein And transmitting the USTS identifier to the control station controlling the target base station and the existing base station in a message resulting from the radio link reset request message. The method of claim 7, wherein The mobile station receiving a request for resetting a physical channel from the control station transmits a scrambling code, a channel code, an accurate transmission timing value, and the like to the physical layer according to the message to perform mode change and timing adjustment. Handover Method in Synchronous Transmission Method. The method of claim 1, And a message transmitted between the control stations, between the control station and the base station, and between the control station and the mobile station is included in a corresponding interface interface protocol. The control station controlling one of at least two adjacent base stations transmitting and receiving traffic data of the same signal source simultaneously with one mobile station transmits information on reverse link synchronous transmission to the base station under its control and rearranges the radio link. Requesting; Receiving, by the base station, information about reverse link synchronous transmission, rearranging the radio link, and reporting to the control station; And adjusting a reverse link synchronization time of a mobile station controlled based on one of the base stations to a reverse link synchronization time of another base station. The method of claim 15, When the control stations for controlling the base stations are different, any one of the different control stations transmits the information on the reverse link synchronous transmission to the other base station. . The method according to claim 15 or 16, The information on the reverse link synchronous transmission includes an identifier of the reverse link synchronous transmission scheme, a scramble code of the transmission scheme, and a channelization code number of the transmission scheme.

Images