KR20080087611A - Method for supporting fast base station switching in wireless communication system using multiple frequency bands - Google Patents

Abstract

A method for supporting FBSS(Fast Base Station Switching) in a multi-FA(Frequency Allocation) wireless communication system is provided to offer services to MSs(Mobile Stations) seamlessly by supporting FBSS in a wireless communication system which uses a plurality of FAs. A first BS(Base Station), which operates two FAs, transmits neighbor BS information to an MS through FA 1 having BSID 1(305). The MS executes scanning, based on the neighbor BS information(307). Then, if the MS transmits a diversity set update request message to request the first BS to update a diversity set(309), the first BS exchanges FBSS-associated backbone information with neighbor BSs(311). Then the first BS transmits a diversity set update response message to the MS(313). Receiving the diversity set update response message, the MS transmits a diversity set update indication message to the first BS through FA 1(315). Using a CQI(Channel Quality Indicator) channel allocated through FA 1, the MS monitors the FAs contained in the diversity set. As a result, if it is judged that switching to one of the FAs is required, the MS transmits a switch indication message to the first BS through the CQI channel(319). In this case, the switch indication message contains the BSID information of a new FA. On the assumption that the new FA is the second BS's FA 1 having BSID 3, the first BS informs the second BS that the MS will execute switching to FA 1 having BSID 3(321).

Description

METHOD FOR SUPPORTING FAST BASE STATION SWITCHING IN WIRELESS COMMUNICATION SYSTEM USING MULTIPLE FREQUENCY BANDS}

1 is a diagram schematically illustrating a structure supporting a single frequency band and a structure supporting two frequency bands in a typical wireless mobile communication system.

2 is a signal flow diagram illustrating a procedure for supporting overlay mode according to a first embodiment of the present invention.

3 is a signal flow diagram illustrating an FBSS support procedure in a system using multiple FAs according to a second embodiment of the present invention.

4 is a flowchart illustrating a process of performing an FBSS by a mobile station according to the present invention.

5 is a flowchart illustrating an operation process associated with performing FBSS of a serving base station according to the present invention.

6 is a flowchart illustrating an operation process of a neighbor base station targeted for FBSS according to the present invention.

The present invention relates to a wireless communication system using multiple frequency bands, and more particularly, to a method for supporting fast base station switching (FBSS).

As the wireless communication system develops, the type and amount of services to be provided in the wireless communication system are increasing. Broadband wireless mobile communication systems are emerging to meet these demands. On the other hand, since frequency resources are limited in a wireless mobile communication system, a frequency band in which a broadband wireless mobile communication system can also be used is limited. Therefore, increasing frequency bands are required to provide broadband services.

FIG. 1 schematically illustrates a structure supporting a single frequency band and a structure supporting two frequency bands in a typical wireless mobile communication system.

Prior to the description of FIG. 1, a base station (BS) in a wireless mobile communication system, in particular, a broadband wireless mobile communication system represented by Institute of Electrical and Electronics Engineers (IEEE) 802.16, has one operating frequency (Frqeuency Assignment). Or hereinafter referred to as 'FA') or two or more FAs. The base station provides a service to a mobile station (MS) through the FA.

Referring to FIG. 1, the mobile station 100 may be located at FA1 120 and then move to FA2 140. If the mobile station 100 is a terminal capable of operating only one FA or the two FAs 120 and 140 are operated in different base stations, the mobile station 100 performs handover between FAs. The service is provided by the FA2 140.

 In contrast, if the mobile station 150 is a terminal capable of operating at least two or more FAs, or if the two FAs 160 and 180 are operated in the same base station, the mobile station 150 may be configured to the FAs 160 and 180. ) To be provided with services. As such, when the mobile station and the base station transmit and receive signals with each other through a plurality of frequency bands, it is advantageous for high speed and large data transmission and reception. However, up to now, there is no procedure promised between a mobile station and a base station to use multiple frequency bands, and the mobile station can switch at high speed from a frequency band in use to another frequency band or from a serving base station to another base station at high speed. This does not exist.

The present invention has been made to solve the above problems, the present invention is to provide a method that can use multiple frequency bands in a wireless communication system.

The present invention provides a method for switching a base station or a frequency band at high speed in a wireless communication system using multiple frequency bands.

The first method of the present invention as described above; In a wireless communication system, a method for performing a fast base station connection switching by a mobile station capable of using multiple frequency bands (FA), comprising: performing an initial network entry through one FA of a base station operating at least two FAs; Acquiring overlay mode support information and the FA information, which determine whether the base station supports the use of multiple FAs by performing the initial network entry, and using the obtained information to provide the multiple FAs to the base station. And notifying the start of the overlay mode execution indicating that it will use, and transmitting and receiving a signal through at least two FAs with the base station.

The second method of the present invention as described above; In a wireless communication system having base stations operating at least two or more frequency bands (FAs), a method for switching a fast base station connection of a mobile station using multiple frequency bands (FAs), the FA list of neighboring base stations from a serving base station being serviced Receiving neighboring base station information including; and scanning the entire FAs with reference to the FA list; selecting a target FA for connection switching according to the scanning result; Transmitting a connection switching instruction including target FA information, performing a connection switching to the target FA, receiving overlay mode information through the target FA, and overlaying the corresponding FA through the target FA Notifying the start of the execution, and the signal through the target FA and other FA of the base station It includes a process of transmitting and receiving.

The third method of the present invention as described above; In a wireless communication system having base stations operating at least two frequency bands (FAs), a method for supporting fast base station connection switching of a serving base station providing a service to a mobile station, the method comprising: exchanging an FA list with neighboring base stations; Transmitting neighbor base station information including the FA list to the mobile station, whether the neighbor base stations and the mobile station are capable of overlay mode support, exchanging service level information desired by the mobile station, and connecting from the mobile station When receiving the switch instruction, the step of informing the connection switching target FA information to the base station operating the corresponding FA included in the connection switch instruction.

The fourth method of the present invention as described above; In a wireless communication system having base stations operating at least two frequency bands (FAs), a method of supporting fast base station connection switching of an adjacent base station, the method comprising: exchanging an FA list with a serving base station and other neighbor base stations, and the serving base station Receiving a signal indicating that the mobile station will perform a fast connection switching to a specific FA of the neighboring base station from the mobile station; performing a connection switching through the specific FA with the mobile station; And transmitting overlay mode information including basic FA and sub FA information used for signal transmission and reception, and transmitting and receiving a signal using the basic FA and sub FA with the mobile station.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, only parts necessary for understanding the operation of the present invention will be described, and other background art will be omitted so as not to distract from the gist of the present invention.

The present invention provides a method for supporting fast base station switching (FBSS) in a wireless mobile communication system using a plurality of frequency bands. The frequency band may be an operating frequency (hereinafter referred to as 'FA'). Hereinafter, a mode in which a mobile station and a base station can transmit and receive data to each other using a plurality of frequency bands, that is, FAs, will be referred to as an 'overlay mode'. An IEEE 802.16 communication system will be described as an example. . Of course, the present invention is applicable not only to the IEEE 802.16 communication system but also to other communication systems such as Mobile WiMAX.

2 is a signal flowchart illustrating a procedure for supporting overlay mode according to a first embodiment of the present invention.

Referring to FIG. 2, the base station 240 operates an FA 1 250 having a base station identifier (BSID) 1 and an FA 2 260 having a BSID 2. The mobile station 200 performs an initial network entry through FA 1 250 of the base station 240 (step 201). The mobile station 200 may obtain overlay mode support information and FA information as the initial network entry is performed. The initial network entry of the mobile station 200 will be described in more detail.

Mobile station 200 obtains synchronization with base station 240 via FA 1 250. Thereafter, the base station 240 and the mobile station 200 perform initial ranging through exchange of ranging messages.

The mobile station 200 transmits a basic capacity negotiation request (SBC-REQ) message to the base station 240. The SBC-REQ message may include information on whether the mobile station 200 supports the overlay mode and the maximum number of FAs available. The information may be included in a registration request (REG-REQ) message used in a registration procedure instead of the SBC-REQ message.

The base station 240 transmits a basic capacity negotiation response (SBC-RSP) message to the mobile station 200 in response to the SBC-REQ message. The SBC-RSP message may include whether the base station 240 supports the overlay mode and FA number information provided by the base station 240 when the overlay mode is supported. In addition, the SBC-RSP message may include all FA index information managed by the base station 240, center frequency information and synchronization information of each FA, and correspond to the number that the mobile station 200 can support. It may include only information on some FAs.

Meanwhile, information included in the SBC-RSP message may be included in a Registration Response (REG-RSP) message used in a registration procedure instead of the SBC-RSP message. Thereafter, the base station 240 and the mobile station 200 perform an authentication and registration procedure.

Upon completion of the initial network entry as described above, the mobile station 200 transmits a signal indicating that the overlay mode is to be performed to the base station 240 through the FA 1 250 (steps 203 and 205). In this case, the mobile station 200 recognizes that the mobile station 200 can perform the overlay mode because the base station 240 supports the overlay mode as well as itself, and the overlay mode is transmitted to the base station 240 through the FA 1 250. It is sending a signal to inform the performer. The signal for notifying the execution of the overlay mode may be a bandwidth request header in which a bandwidth request (BR) field value is set to '0', or may correspond to a separate medium access control (MAC) control message.

Although the mobile station 200 notifies the execution of the overlay mode after the initial network entry, the mobile station 200 may inform the start time of the overlay mode execution during the initial network entry procedure.

Meanwhile, in FIG. 2, the mobile station 200 notifies the execution of the overlay mode through the FA1 250 as in steps 203 and 205. However, the mobile station 200 may inform that it is possible to perform an overlay mode through the FA2 260 after completing the ranging procedure through the FA2 260. At this time, the mobile station 200 may be already transmitting and receiving data with the base station 240 through the FA1 (250). Here, the time point indicating that the overlay mode can be performed may be a time point at which the mobile station 200 determines that it is possible to transmit and receive data through the FA2 260. For example, the mobile station 200 It may be a time point at which the ranging between the base station 240 and the FA2 260 is successfully performed.

Thereafter, the mobile station 200 and the base station 240 transmit and receive data through the FA 1 250 and the FA 2 260 (steps 207 and 209).

Meanwhile, the base station 240 assigns channel quality information (CQI) channels to the mobile station 200 to determine the channel status of the FA 1 250 and the FA 2 260. Can be assigned. The mobile station 200 reports channel quality for the FA 1 250 and the FA 2 260 using the allocated CQI channel (step 211 and step 215). Here, the mobile station 200 may transmit a signal related to the FBSS using the CQI channel allocated through the FA 1 250, and report the CQI using a separate MAC control message instead of the allocation of the CQI channel. Can be. This will be described in more detail with reference to FIG. 3.

3 is a signal flow diagram illustrating an FBSS support procedure in a system using multiple FAs according to a second embodiment of the present invention.

Referring to FIG. 3, it is assumed that the mobile station 300 belongs to a first base station 320 which is a serving base station, and the first base station 320 operates two FAs. It is assumed that the second base station 340 and the third base station 360 exist as neighbor base stations of the first base station 320, and each neighbor base station also operates two FAs.

The first base station 320 periodically exchanges base station information with neighboring base stations 340 and 360 (steps 301 and 303). The base station information includes an FA list of each base station. The FA list includes an index and center frequency information for each FA.

The first base station 320 transmits adjacent base station information to the mobile station 300 through FA 1 325 having BSID 1 (step 305). The neighbor base station information also includes information of the first base station 320.

The mobile station 300 performs scanning to measure signal strength of each base station using the neighbor base station information (step 307). The scanning result may be a signal to noise ratio. The mobile station 300 requests the first base station 320 to update the diversity set according to the scanning result (step 309). The diversity set update request message includes FAs that may be included in a diversity set desired by the mobile station 300 in the FA list. Accordingly, a plurality of FAs managed by the same or different base stations may be included in the diversity set update request message. In addition, the diversity set update may be requested by the base station to the mobile station. The resulting operation is similar to the diversity set update procedure described or described previously and later.

When the first base station 320 receives the diversity set update request message, the first base station 320 exchanges backbone information related to FBSS with an adjacent base station managing the FA included in the message (step 311). The FBSS-related backbone information may include information on whether the mobile station 300 is capable of overlay support, information on the maximum number of FAs available to the mobile station, and service level information provided by the mobile station. In addition, the FBSS-related backbone information may include CQI channel information to be allocated to the mobile station. Here, the service level information refers to a service level that can be obtained by the mobile station 300 when the first base station 320 transmits data using all FAs used for communication with the mobile station 300. And, when the neighbor base stations (340, 360) transmits data using all FAs that can support the mobile station 300 means a service level that can be obtained by the mobile station (300).

Thereafter, the first base station 320 transmits a diversity set update response message to the mobile station 300 through the FA 1 325 (step 313). Upon receiving the diversity set update response message, the mobile station 300 transmits a diversity set update indication message indicating that the diversity set has been updated through FA 1 325 of the first base station (step 315).

Meanwhile, when the first base station and the neighboring base stations 340 and 360 include information of a plurality of FAs managed by one base station in the diversity set update request message received from the mobile station 300, each base station Only one FA among a plurality of FAs is selected, and the selected FA is included in the diversity set update response message. That is, the diversity set update response message includes only one FA per base station.

The mobile station 300 reports the CQI to the first base station 320 using the CQI channel allocated through the FA 1 345. If, as a result of monitoring the FAs included in the diversity set, it is determined that connection switching to one of the FAs included in the diversity set is necessary, the mobile station 300 In operation 319, a switch indication message is transmitted to the first base station 320 using a CQI channel. It is assumed here that the new FA desired by the mobile station 300 is FA 1 345 of the second base station 340 having BSID 3. Accordingly, the connection switch indication message includes BSID 3 information.

The first base station 320 informs the second base station 340 that the mobile station 300 will perform the connection switching to the FA having the BSID 3 through a backbone network in response to receiving the connection switching instruction message (321). step). If the mobile station 300 has not been previously allocated a CQI channel to use for communication with the FA 1 345 having the BSID 3, the first base station 320 receives the FA from the second base station 340. After acquiring CQI channel information to be used for 1 345, the CQI channel information is transmitted to the mobile station 300 using Anchor_Switch_IE (step 323). The Anchor_Switch_IE is described in detail in the IEEE 802.16 standard document.

Thereafter, the mobile station 300 performs the connection switching to the FA 1 345 of the second base station 340 (step 325), and the second base station 340 overlays the FA 1 345 through the connection. The mode information is transmitted to the mobile station 300 (step 327). The overlay mode information includes information on whether the second base station 340 uses the overlay mode, primary and sub FA information when supporting the overlay mode, the number of FAs to be used in the overlay mode, At least one of indexes and center frequency information of respective FAs and starting frame information for performing the overlay mode may be included. This may be provided to the mobile station 300 in the form of an extended sub header or a MAC control message. The basic FA becomes FA 1 345 of the second base station 340, and the sub FA becomes FA 2 350 of the second base station 340. Of course, when there are at least three FAs operated by the second base station 340, the number of the sub FAs may increase.

The mobile station 300 includes a bandwidth request header or an extended subheader in which a bandwidth request (BR) field value including the overlay mode execution start information is set through FA 1 345 of the second base station 340, or Send a MAC control message (step 329). Thereafter, the mobile station 300 transmits and receives data to and from the second base station 340 using the FA 1 345 and the FA 2 350 of the second base station 340 (step 331).

Meanwhile, in the description with reference to FIG. 3, the mobile station 300 has described a procedure of notifying the start of performing the overlay mode through the FA 1 345 of the second base station 340 in step 329. The overlay mode execution start notification may be transmitted through the FA2 350 of the second base station 340 or another sub FA. At this time, the mobile station 300 performs a ranging procedure with the second base station 340 through the FA2 350 or another sub-FA as needed and the ranging through the FA2 350 or another sub-FA is successful. If performed, the overlay mode execution start notification may be transmitted through the FA2 350 or another sub FA. In this case, the mobile station 300 may be already transmitting and receiving data through the FA1 345 of the second base station 340.

Meanwhile, in FIG. 3, the target base station that the mobile station 300 decides to switch to is the FA2 330 of the first base station 320, that is, the sub FA, or the base FA in the same base station as required by the mobile station. If a change between sub FAs is required, the base station may reconfigure the data path to the base FA or sub FA. That is, in FIG. 3, when the FA 2 330 is set as the basic FA of the mobile station 300, the data path set to the FA 1 325, which is an existing basic FA, is deleted and is transferred to the FA 2 330. You can set the data path. Alternatively, instead of establishing a data path to the FA 2 330, a connection with the FA 2 330 may be provided using the data path to the FA 1 325.

4 is a flowchart illustrating a process of performing an FBSS by a mobile station according to the present invention.

Referring to FIG. 4, first, in step 402, the mobile station acquires an FA list from its serving base station and proceeds to step 404. The FA list includes an index and center frequency information for each FA. In step 404, the mobile station performs scanning for each FA and proceeds to step 406. In step 406, the mobile station performs diversity set update through a diversity set update procedure with a serving base station. The diversity set update procedure may be requested by the mobile station first or the base station first.

In step 408, the mobile station reports the CQI of the FA to the serving base station and proceeds to step 410. In step 410, the mobile station instructs connection switching to the base station to which the connection is to be switched, and proceeds to step 412. The connection switching target base station may be the serving base station, or a neighboring base station different from the serving base station may be the target. In step 412, the mobile station performs connection switching, that is, FBSS, to the connection switching target base station.

In step 414, the mobile station receives overlay mode information from the connection switching target base station and proceeds to step 416. In step 416, the mobile station notifies the connection switching target base station to start performing the overlay mode, and proceeds to step 418. In step 418, the mobile station performs data transmission and reception using a plurality of FAs operated by the connection switching target base station.

5 is a flowchart illustrating an operation process associated with performing FBSS of a serving base station according to the present invention.

Referring to FIG. 5, in step 502, the serving base station exchanges base station information with neighboring base stations and proceeds to step 504. Here, the base station information includes an FA list of each base station. In step 504, the serving base station transmits neighbor base station information including the FA list to the mobile station, and proceeds to step 506. In step 506, when the serving base station receives a diversity set update request from the mobile station or requests a diversity set update from the mobile station, the serving base station exchanges FBSS-related backbone information with neighboring base stations and proceeds to step 508.

In step 508, the serving base station proceeds to step 510 when it receives a connection switching instruction indicating that the mobile station will switch to a specific target base station. In step 510, the serving base station exchanges FBSS-related backbone information with the specific target base station and proceeds to step 512. In step 512, the serving base station transmits CQI channel information related to CQI channel allocation of the target base station to the mobile station.

6 is a flowchart illustrating an operation process of a neighbor base station targeted for FBSS according to the present invention.

Referring to FIG. 6, in step 602, the neighbor base station exchanges FBSS-related backbone information with a serving base station and proceeds to step 604. The FBSS related backbone information may include overlay mode support information and service level information. In step 604, the neighbor base station performs connection switching through the mobile station and the first FA, which is a basic FA, and proceeds to step 606. In step 606, the neighbor base station transmits overlay mode information to the mobile station, and proceeds to step 608. In step 608, the neighboring base station is notified of the start of the overlay mode from the mobile station, and proceeds to step 610. In step 610, the neighbor BS performs data transmission / reception with the mobile station through a base FA and a sub FA.

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

As described above, the present invention enables seamless service provision by supporting base station connection switching at high speed to a mobile station in a wireless communication system.

Claims (13)

In a wireless communication system, a method for a mobile station capable of using multiple frequency bands (FA) to perform fast base station connection switching, Performing an initial network entry through one FA of a base station operating at least two FAs, Acquiring overlay mode support information and the FA information that determine whether the base station supports the use of multiple FAs by performing the initial network entry; Notifying the base station to start performing an overlay mode by using the obtained information to inform the base station of using multiple FAs; And transmitting and receiving a signal through at least two FAs with the base station. The method of claim 1, And the FA information includes at least one of a number of FAs provided by the base station, a center frequency of each FA, and synchronization information. The method of claim 1, The mobile station overlay mode start notification of the mobile station using a bandwidth request header (bandwidth request header) message is set to the bandwidth request (BR) field value is set to zero. The method of claim 3, The overlay mode start notification of the mobile station may be performed during the initial network entry procedure. In a wireless communication system having base stations operating at least two frequency bands (FAs), a method for switching a fast base station connection of a mobile station using multiple frequency bands (FAs), Receiving neighbor base station information including an FA list of neighbor base stations from a serving base station receiving a service; Scanning the entire FAs with reference to the FA list; Selecting a connection switching target FA according to the scanning result and transmitting a connection switching instruction including the target FA information selected as the serving base station; Performing a connection conversion to the target FA; Receiving overlay mode information through the target FA; Notifying the base station to start performing an overlay; And transmitting and receiving a signal through a target FA and another FA of the corresponding base station. The method of claim 5, And performing a diversity set update by using the scanning result. The method of claim 5, The overlay mode information includes information on whether a base station operating the connection switching target FA uses multiple FAs, basic and sub FA information when supporting overlay mode, the number of FAs to be used in the overlay mode, and an index of each FA. And at least one of center frequency information and overlay mode execution start frame information. The method of claim 7, wherein And wherein the base FA is a target FA and the sub FA is another FA. The method of claim 5, The mobile station overlay mode start notification of the mobile station using a bandwidth request header (bandwidth request header) message is set to the bandwidth request (BR) field value is set to zero. In a wireless communication system having base stations operating at least two frequency bands (FAs), a method for supporting fast base station connection switching of a serving base station providing a service to a mobile station, Exchanging FA lists with neighboring base stations, Transmitting neighbor base station information including the FA list to the mobile station; Exchanging service level information desired by the mobile station, whether the neighboring base stations and the mobile station support overlay mode; And receiving a connection switching instruction from the mobile station, informing the base station operating the corresponding FA included in the connection switching instruction to the base station in operation. 11. The method of claim 10, further comprising: exchanging service level information desired by the mobile station and whether the neighboring base stations and the mobile station are capable of overlay mode support; And after the diversity set update request is received from the mobile station or after the diversity set update request is made to the mobile station. In a wireless communication system having base stations operating at least two or more frequency bands (FA), a method for supporting fast base station connection switching of a neighboring base station, Exchanging an FA list with a serving base station and other neighbor base stations, Receiving a signal from the serving base station indicating that the mobile station will perform a fast connection switch to a specific FA of the neighboring base station; Performing connection switching through the mobile station and the specific FA; Transmitting overlay mode information including basic FA and sub-FA information used for signal transmission and reception to the mobile station through the specific FA; And transmitting and receiving a signal by using the base station and the sub-FA with the mobile station. The method of claim 12, The overlay mode information includes information on whether a base station operating the connection switching target FA uses multiple FAs, basic and sub FA information when supporting overlay mode, the number of FAs to be used in the overlay mode, and an index of each FA. And information including at least one of center frequency information and overlay mode execution start frame information.

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