Title of Invention	"A METHOD AND APPARATUS FOR BROADCASTING AND RECEIVING INFORMATION OF NEIGHBOR BASE STATIONS IN A COMMUNICATION SYSTEM"
Abstract	The invention relates to a method for transmitting to a mobile station (150) information of neighbor base stations by a base station (121-133) in a communication system, the method comprising the steps of: setting, (407) by a controller of the base station, a value of each of a plurality of fields comprised in each of m fragments of the information on the neighbor base station; and sequentially transmitting, by the base station, each of the m fragments of the information of the neighbor base stations to the mobile station (150); wherein the m fragments are generated by fragmenting a broadcast message comprising the information of the neighbor base stations into m fragments, wherein the plurality of fields comprise in each of the m fragments a first field, a second field, and a third field, the first field indicates a fragmentation index for a current fragment, the second field indicates a total number of fragments equal to m, where m is an integer greater than or equal to 1, and the third field indicates a number of the neighbor base stations comprised in the current fragment, wherein the current fragmentation comprises identifiers of the neighbor base stations comprised in the information of the current fragment, wherein the current fragment comprises physical frequencies for the neighbor base stations comprised in the information of the current fragmentation, and wherein the plurality of fields comprise an operator identifier, ID field and a Configuration Change Count field which is incremented each time when information for an associated neighbor base station has changed.

Title of Invention

"A METHOD AND APPARATUS FOR BROADCASTING AND RECEIVING INFORMATION OF NEIGHBOR BASE STATIONS IN A COMMUNICATION SYSTEM"

Abstract

The invention relates to a method for transmitting to a mobile station (150) information of neighbor base stations by a base station (121-133) in a communication system, the method comprising the steps of: setting, (407) by a controller of the base station, a value of each of a plurality of fields comprised in each of m fragments of the information on the neighbor base station; and sequentially transmitting, by the base station, each of the m fragments of the information of the neighbor base stations to the mobile station (150); wherein the m fragments are generated by fragmenting a broadcast message comprising the information of the neighbor base stations into m fragments, wherein the plurality of fields comprise in each of the m fragments a first field, a second field, and a third field, the first field indicates a fragmentation index for a current fragment, the second field indicates a total number of fragments equal to m, where m is an integer greater than or equal to 1, and the third field indicates a number of the neighbor base stations comprised in the current fragment, wherein the current fragmentation comprises identifiers of the neighbor base stations comprised in the information of the current fragment, wherein the current fragment comprises physical frequencies for the neighbor base stations comprised in the information of the current fragmentation, and wherein the plurality of fields comprise an operator identifier, ID field and a Configuration Change Count field which is incremented each time when information for an associated neighbor base station has changed.

Full Text	METHOD AND SYSTEM FOR FORMING AND TRANSMITTING/RECEIVING NEIGHBOR BASE STATION INFORMATION IN A BWA COMMUNICATION SYSTEM BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a Broadband Wireless Access (BWA) communication system, and more particularly to a method and a system for forming and transmitting/receiving neighbor Base Station (BS) information in order for a serving BS to send the neighbor BS information to a Mobile Station (MS) in a BWA communication system. 2. Description of the Related Art The communication system was initially developed for the purpose of voice service and is now being developed to provide data service and various multimedia services. However, the communication system developed for voice service has a relatively narrow bandwidth for data transmission and requires relatively expensive service charges, it cannot meet rapidly increasing user demands for various services. Further, the necessity for a communication system capable of efficiently providing Internet service is now increasing due to increasing demands for the Internet service together with the development in the communication industry. To this end, a Broadband Wireless Access (BWA) communication system, which has a broad enough bandwidth to meet rapidly increasing user demands and efficiently provide the Internet service, has been introduced. The BWA communication system is a communication system for supporting not only the voice service but also various data services of low and high speed and multimedia application services for providing high quality moving images, etc. The BWA communication system supports access to the Public Switched Telephone Network (PSTN), Packet Switched Data Network (PSDN), Internet network, International Mobile Telecommunication (IMT)-2000 network, Asynchronous Transfer Mode (ATM) network, etc. in a mobile or stationary environment based on wireless media using a broadband, and supports a high speed channel data rate. The BWA communication system can be classified into a broadband wireless subscriber network, a broadband mobile access network, and high speed wireless Local Area Network (LAN), according to the mobility (stationary or mobile) of a Subscriber Station (SS), the communication environment (outdoor or indoor), and the channel data rate. Meanwhile, 802.16 standardization group of Institute of Electrical and Electronics Engineers (IEEE), which is one of international standardization organizations, is arranging standards for wireless access schemes of the BWA communication system, and specifically, is now driving to establish an IEEE 802.16d standard for providing a broadband wireless Internet service to a stationary SS. The 802.16 system does not account for the mobility of the SS. A BWA system according to the IEEE 802.16d standard has a wider bandwidth for data transmission and thus can transmit a much larger quantity of data in a short time, in comparison with the conventional wireless technology for voice service. Further, in the BWA system according to the IEEE 802.16d standard, all of the users can share a channel, thereby achieving efficient use of the channel. Further, the BWA system according to the IEEE 802.16d standard can guarantee various Quality of Service (QoS) and thus can provide a user with services of different qualities according to the characteristics of service. In the IEEE 802.16d system, all of the users connected to the BS share a common channel, so the BS allocates intervals of the common channel for use by each user during every uplink and downlink frame. Therefore, the BS must send uplink and downlink access information to the users every frame in order to enable the users to share the channel. To this end, in the IEEE 802.16d system, channels are divided into uplink channel and downlink channel, information about each channel is defined according to Type, Length and Value (TLV), and the defined information is then inserted to Downlink Channel Descriptor (DCD) and Uplink Channel Descriptor (UCD) messages which are transmitted to all of the users, so that characteristic information about the channels is sent to the SS. Further, the IEEE 802.16 standardization group is now driving to establish an IEEE 802.16e standard for providing mobility to an SS of the IEEE 802.16d communication system. The IEEE 802.16e communication system has a wider bandwidth for data transmission and thus can transmit a much larger quantity of data in short time, in comparison with the conventional wireless technology for voice service. Further, in the IEEE 802.16e communication system, all of the users can share a channel, thereby achieving efficient use of the channel. Also, the IEEE 802.16e communication system can guarantee various Quality of Service (QoS) and thus can provide a user with services of difference qualities according to the characteristics of service. The IEEE 802.16e communication system supports handoff, thereby guaranteeing the mobility of a Mobile Station (MS). In order to support the mobility of an MS, a BS of the IEEE 802.16e communication system periodically broadcasts a mobile neighbor advertisement (MOBNBR-ADV) message that includes neighbor BS information to all MSs within a cell controlled by the BS, thereby sending status information of the neighbor cells to the MSs. Specifically, when an MS located within one cell moves to a neighbor cell, the MS can preliminarily obtain information of a neighbor BS of the neighbor cell (i.e. a BS controlling the neighbor cell), such as a network ID, channel characteristics, etc. of the neighbor BS, by receiving the MOBNBR-ADV message broadcast by the serving BS which controls the current cell in which the MS is currently located. Therefore, the IEEE 802.16e communication system can support handoff of the MS. However, in the IEEE 802.16e communication system, when the serving BS has too many neighbor cells or the neighbor cells have capacities much different from the capacity of the current cell, the quantity of the neighbor BS information transmitted from the serving BS to the MSs becomes too much, so that the MOB_NBR-ADV message transmitted from the serving BS to the MSs becomes too large. When the serving BS has too much neighbor BS information, it is impossible to transmit all of the information in one frame. In other words, the MOBNBR-ADV message including all the neighbor BS information becomes too large and thus cannot be transmitted in one frame. In the IEEE 802.16e communication system, a BS cannot fragment a Medium Access Control (MAC) management message to transmit the message. SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve at least the above-mentioned problems occurring in the prior art, and an object of the present invention is to provide a method and system for forming and transmitting/receiving a broadcast message for sending information of neighbor BSs to an MS in a BWA communication system. It is another object of the present invention to provide a method and system for fragmenting and transmitting/receiving a broadcast message for sending information of neighbor BSs to an MS in a BWA communication system. In order to accomplish this object, there is provided a method for transmitting neighbor base station information by a serving base station in a broadband wireless access communication system in which the serving base station broadcasts the neighbor base station information to a mobile station, the method includes the steps of scanning neighbor base stations adjacent to the serving base station, collecting information of the scanned neighbor base stations, and comparing a size of the information of the scanned neighbor base stations to a size of a frame for carrying the information of the neighbor base stations constructing at least one broadcast message including the information of the neighbor base stations according to a result of the comparison and setting up fields of the constructed broadcast message according to the information included in the constructed broadcast message and broadcasting the broadcast message including the setup fields. In accordance with another aspect of the present invention, there is provided a method for receiving neighbor base station information by a mobile station in a broadband wireless access communication system in which a serving base station broadcasts the neighbor base station information to the mobile station, the method includes the steps of receiving a first broadcast message transmitted from the serving base station by the mobile station obtaining information of neighbor base stations included in the first broadcast message and determining from the obtained information if the first broadcast message is a fragmented broadcast message and receiving at least one more fragmented broadcast message transmitted from the serving base station when the first broadcast message is a fragmented broadcast message. In accordance with another aspect of the present invention, there is provided a method for forming neighbor base station information by a serving base station in a broadband wireless access communication system in which the serving base station broadcasts the neighbor base station information to a mobile station, the method includes the steps of scanning neighbor base stations adjacent to the serving base station, collecting information of the scanned neighbor base stations, and comparing a size of the information of the scanned neighbor base stations with a size of a frame for carrying the information of the neighbor base stations and constructing at least one broadcast message including the information of the neighbor base stations according to a result of the comparison and setting up fields of the constructed broadcast message according to information included in the constructed broadcast message. In accordance with another aspect of the present invention, there is provided a method for transmitting and receiving neighbor base station information in a broadband wireless access communication system in which a serving base station broadcasts the neighbor base station information to a mobile station, the method includes the steps of scanning neighbor base stations adjacent to the serving base station, collecting information of the scanned neighbor base stations, comparing a size of the information of the scanned neighbor base stations with a size of a frame for carrying the information of the neighbor base stations, constructing at least one broadcast message including the information of the neighbor base stations according to a result of the comparison, setting up fields of the constructed broadcast message according to information included in the constructed broadcast message, and broadcasting by the serving base station the broadcast message including the setup fields, and receiving the broadcast message transmitted from the serving base station by the mobile station, obtaining information of neighbor base stations included in the broadcast message and determining from the obtained information if the broadcast message is a fragmented broadcast message, and receiving by the mobile station at least one more fragmented broadcast message transmitted from the serving base station when the broadcast message is a fragmented broadcast message. In accordance with another aspect of the present invention, there is provided a system for transmitting and receiving neighbor base station information in a broadband wireless access communication system in which a serving base station broadcasts the neighbor base station information to a mobile station, the system includes a serving base station for scanning neighbor base stations adjacent to the serving base station, collecting information of the scanned neighbor base stations, comparing a size of the information of the scanned neighbor base stations with a size of a frame for carrying the information of the neighbor base stations, constructing at least one broadcast message including the information of the neighbor base stations according to a result of the comparison, setting up fields of the constructed broadcast message according to information included in the constructed broadcast message, and broadcasting the broadcast message including the setup fields and a mobile station for receiving the broadcast message transmitted from the serving base station by the mobile station, obtaining information of neighbor base stations included in the broadcast message and determining from the obtained information if the broadcast message is a fragmented broadcast message, and receiving at least one more fragmented broadcast message transmitted from the serving base station when the broadcast message is a fragmented broadcast message. In accordance with another aspect of the present invention, there is provided a system for forming neighbor base station information by a serving base station in a broadband wireless access communication system in which the serving base station broadcasts the neighbor base station information to a mobile station, the system includes a serving base station for scanning neighbor base stations adjacent to the serving base station, collecting information of the scanned neighbor base stations, comparing a size of the information of the scanned neighbor base stations with a size of a frame for carrying the information of the neighbor base stations, constructing at least one broadcast message including the information of the neighbor base stations according to a result of the comparison, and setting up fields of the constructed broadcast message according to information included in the constructed broadcast message. BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS The above and other objects, features and advantages of the present invention will be more apparent from the following detailed description taken in conjunction with the accompanying drawings, in which: FIG. 1 illustrates a structure of a B WA communication system according to an embodiment of the present invention, which supports handoff of an MS moving between cells controlled by BSs supporting different operation modes; FIG. 2 illustrates a format of a MOBNBR-ADV message proposed in a BWA communication system according to an embodiment of the present invention; FIG. 3 illustrates a method of fragmentation of the MOB_NBR-ADV message according to an embodiment of the present invention; and FIG. 4 is a flowchart of a process according to an embodiment of the present invention, in which a serving BS forms and transmits/receives a broadcast message including neighbor BS information. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In the following description, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. As described here, the present invention proposes a method and system for forming a broadcast message, specifically a mobile neighbor advertisement (MOBNBR-ADV) message, for transmitting neighbor BS information from a serving BS (a BS currently providing service to an MS) to the MS in order to support handoff of the MS in a BWA communication system. Further, the present invention proposes a method and system for transmitting and receiving the MOB_NBR-ADV message including the neighbor BS information in a BWA communication system. The present invention proposes a method and system for constructing a MOBNBR-ADV message through fragmentation and then transmitting the constructed MOBNBR-ADV message to an MS, when the serving BS has too much neighbor BS information to transmit to the MS and thus the MOB_NBR-ADV message to be transmitted to the MS is too large. Also, the present invention can be applied to formation and transmission of all broadcast messages exchanged between a BS and an MS as well as the MOB_NBR-ADV message. For convenience, the following description is based on an assumption that a BWA communication system according to preferred embodiments of the present . invention is an IEEE 802.16e communication system which uses an Orthogonal Frequency Division Multiplexing (OFDM) scheme and an Orthogonal Frequency Division Multiple Access (OFDMA) scheme. Because the IEEE 802.16e communication system uses an OFDM/OFDMA scheme, it can transmit physical channel signals by using a plurality of sub-carriers, thereby achieving high speed data transmission. Also, the IEEE 802.16e communication system supports a multi-cell structure and the mobility of an MS. FIG. 1 illustrates a structure of a BWA communication system according to an embodiment of the present invention, which supports handoff of an MS moving between cells controlled by BSs supporting different operation modes. Referring to FIG. 1, the BWA communication system has a multi-cell structure including cell 1 101, cell 2 103, cell 3 105, cell 4 107, cell 5 109, cell 6 111, and cell 7 113. Also, the BWA communication system includes BSs 121, 123, 125, 127, 129, 131, 133 and an MS 150. The BSs 121, 123, 125, 127, 129, 131, 133 control the cells 101, 103, 105, 107, 109, 111, 113, respectively. The MS 150 can receive services from the BSs 121, 123, 125, 127, 129, 131, 133 while moving between the cells 101, 103, 105, 107, 109, 111, 113. The signal exchange between the MS 150 and the BSs 121, 123, 125, 127, 129, 131, 133 uses the OFDM/OFDMA scheme. When the MS 150 moves from cell 1 101 controlled by BS 1 121 to cell 2 103 controlled by BS 2 123, the serving BS (the BS which is currently providing a service to the MS 150) changes from BS 1 121 to BS 2 123, and BS 1 121 (the current serving BS) broadcasts a MOBNBR-ADV message that includes BS information of neighbor cells to the MS 150. Upon receiving the MOBNBR- ADV message, the MS 150 obtains the BS information of neighbor cells in advance. Then, as soon as the MS 150 gets the channel information of BS 2 123, the MS 150 starts a process for setting up a connection with BS 2 123, thereby performing a handoff process. That is, BS 1 121 (the current serving BS) broadcasts a MOBNBR-ADV message in order to preliminarily send neighbor BS information (i.e. information of BS 2 123) to the MS 150 moving to cell 2 103, and the MS 150 recognizes the information of BS 2 123 from the received MOBNBR-ADV message. As a result, the BWA communication system supports handoff of the MS 150. In a BWA communication system having the structure described above, the serving BS inserts the neighbor BS information in the MOBNBR-ADV message in order to transmit the neighbor BS information to the MS. Table 1 below shows the format of the MOBNBR-ADV message. As shown in Table 1, the MOB_NBR-ADV message includes a plurality of Information Elements (IEs), which include a 'Management Message Type' field of 8 bits which represents the type of transmitted/received message (Management Message Type = 49), an 'Operator ID' field of 24 bits which is assigned for identification of an operator, represents an identifier (ID) of the operator, and can be shared by a group of BSs, an 'NNEIGHBOR' field of 8 bits which represents the number of neighbor BSs, an 'HMAC Tuple' field of 21 bits, and information of all of the neighbor BSs. Further, the MOB NBR-ADV message includes a 'Fragmentation Index' field and a 'Total Fragmentation' field, each of which has a size of 4 bits and represents 'Neighbor Set' of neighbor BSs. That is, the 'Neighbor Set' field of the neighbor BSs is divided into the 'Fragmentation Index' field of 4 bits, which represents an index of the current fragmented MOBNBR-ADV message transmitted by the current frame among all of the fragmented MOBNBR-ADV messages, and the 'Total Fragmentation' field which represents the number of all of the fragmented MOBNBR-ADV messages, i.e. the number of all fragments divided from the entire MOBNBR- ADV message. FIG. 2 illustrates a format of a MOBNBR-ADV message including the newly added fragmentation information described above, i.e. the 'Fragmentation Index' field representing an index of the currently transmitted fragmented MOBNBR-ADV message and the 'Total Fragmentation' field representing the number of all the fragmented MOBNBR-ADV messages. Referring to FIG. 2, when the serving BS has too much neighbor BS information and a MOBNBR- ADV message which cannot be transmitted in one frame, the serving BS divides the MOBNBR-ADV message into fragmented MOBNBR-ADV messages of a size which can be carried by one frame, inserts the number of all of the fragmented MOBNBR-ADV messages into the 'Total Fragmentation' field and an index of a fragmented MOB_NBR-ADV message transmitted by a current frame into the 'Fragmentation Index' field, and then transmits the information- inserted message. When the MOBNBR-ADV message has been divided into more than one fragmented MOBNBR-ADV message, the serving BS sequentially transmits to the MS all of the fragmented MOBNBR-ADV messages by corresponding frames. In this case, the 'Fragmentation Index' field represents indices of neighbor BSs also included in the fragmented MOBNBR- ADV message transmitted by the current frame, so that the MS can differentiate the fragmented MOBNBR-ADV message transmitted by the current frame from the other fragmented MOBNBR-ADV messages. Further, because the 'Total Fragmentation' field represents the number of all of the fragmented MOBNBR- ADV messages transmitted to the MS, the MS can determine if there is any more fragmented MOBNBR-ADV message to be transmitted by another frame after the current frame. Through the 'Total Fragmentation' field, the MS can recognize the number of frames for carrying the entire MOBNBR-ADV message and can receive all of the fragmented MOBNBR-ADV messages transmitted through the corresponding number of frames, thereby acquiring the information of all of the neighbor BSs. Further, the 'N_NEIGHBORS' field includes a 'Neighbor BS ID' field of 48 bits representing IDs of the neighbor BSs, a 'PHY Profile ID' field of 32 bits representing downlink physical frequencies of the neighbor BSs, a 'Configuration Change Count' field of 8 bits representing a change count for the configuration of the MOBNBR-ADV message, and a 'TLV Encoded Neighbor information' field of variable bits representing TLV-encoded information of the neighbor BSs. In a BWA communication system according to an embodiment of the present invention, the MS can obtain information of neighbor BSs by receiving the MOBNBR-ADV message including the field as described above from the serving BS, and the MS can easily perform handoff when moving to another cell because the MS preliminarily obtains information of the BS controlling the other cell to which the MS will move. Therefore, the BWA communication system according to the present invention supports handoff of an MS. Further, in the BWA communication system, the MOB_NBR-ADV message includes the 'Fragmentation Index' field and the 'Total Fragmentation' field. Therefore, when the MOBNBR-ADV message is too large to be sent to the MS in one frame, the MOBNBR-ADV message is divided into fragmented messages each having a size transmittable in one frame, so that the fragmented messages can be transmitted to the MS in more than one frame. Therefore, according to the present invention, even when the serving BS has too much neighbor BS information and a MOBNBR-ADV message is to large to transmit, the serving BS can fragment the MOBNBR-ADV message and then transmit the fragmented MOBNBR- ADV messages to the MS and the MS can preliminarily get the neighbor BS information by receiving the fragmented MOBNBR-ADV messages. Table 2 shows a format of the MOBNBR-ADV message including information of neighbor BSs transmitted from a serving BS to an MS in a BWA communication system according to another embodiment of the present invention. As shown in Table 2, the MOBNBR-ADV message includes a plurality of IEs, which include a 'Management Message Type' field of 8 bits which represents the type of transmitted/received message (Management Message Type = 49), an 'Operator ID' field of 24 bits which is assigned for identification of an operator, represents an identifier (ID) of the operator, and can be shared by a group of BSs, a 'Configuration Change Count' field of 8 bits representing a change count for the configuration of the MOBNBR-ADV message, and a 'PHY Profile ID' field which represents physical layer information of the BS and includes a Co-located FA indicator bit, an FA Configuration indicator bit, a Time/Frequency Synchronization Indicator, a BS EIRP Indicator, a DCD/UCD Reference Indicator, an FA Index Indicator and an FA number. When the MOB_NBR-ADV message having the format as described above is too large to be transmitted in one frame, that is, when it is impossible to transmit all of the neighbor BS information in one frame, the serving BS may divide the MOB_NBR-ADV message into fragmented messages each having a size transmittable in one frame in order to transmit the MOBNBR-ADV message to the MS. Further, when the MOBNBR-ADV message is transmitted to the MS after being fragmented, each transmitted fragment of the MOBNBR- ADV message must indicate that the MOBNBR-ADV message has been fragmented. Also, when the MS has received one fragment of the MOBNBR- ADV message indicating that the MOBNBR-ADV message has been fragmented, the MS can receive directly after the first fragment information of all of the neighbor BSs by receiving all of the other fragments of the MOBNBR- ADV message transmitted by the frames. In order to indicate that the MOB_NBR-ADV message has been fragmented, it is necessary for the MOBNBR-ADV message to include the following fields. That is, the MOBNBR-ADV message includes a 'Fragmentation Mode' field of 1 bit representing the fragmentation mode, a 'TOT_N_NEIGHBORS' field of 7 bits representing the number of all of the neighbor BSs, a 'Start bit' field of 1 bit representing the start bit of the fragmented MOBNBR-ADV message, and a 'Number of Remaining Fragments' field of 6 bits representing the number of remaining fragmented MOB_NBR-ADV messages to be transmitted by frames directly after the frame carrying the very fragmented MOBNBR-ADV message. By the above-mentioned fields, it is noted that the MOBNBR-ADV message can be fragmented according to two types of fragmentation modes. The 'Fragmentation Mode' field of the MOBNBR-ADV message represents the type of indicating the fragmentation of the MOB_NBR-ADV message. When the fragmentation of the MOB_NBR-ADV message is expressed by the number of all of the neighbor BSs, i.e. by the quantity of neighbor BS information, the indication type is expressed in the 'TOT_N_NEIGHBORS' field and the 'Fragmentation Mode' field is set to '1'. Further, when the fragmentation of the MOB_NBR-ADV message is expressed by the number of the fragmented MOBNBR-ADV messages, the 'Fragmentation Mode' field is set to '0'. When the 'Fragmentation Mode' field has been set to '1', the 'TOT_N_NEIGHBORS' field represents the number of all of the neighbor BSs to which the serving BS broadcasts the MOBNBR-ADV message, and the 'N_NEIGHBORS' field of 8 bits represents the number of the neighbor BSs of which BS information is transmitted by the fragmented MOBNBR-ADV message, i.e. the quantity of the neighbor BS information. When the number of neighbor BSs of which BS information is transmitted by the 'N_NEIGHBORS' field of the fragmented MOB_NBR-ADV message, i.e. the quantity of the neighbor BS information, is less than the number of all of the neighbor BSs transmitted by the TOT_N_NEIGHBORS' field, i.e. the quantity of all of the neighbor BS information, the MS must continue to receive the remaining fragmented MOBNBR-ADV messages in order to obtain information of the remaining neighbor BSs. Meanwhile, the 'Fragmentation Mode' field has been set to '0', it is necessary to differentiate the fragmented MOBNBR-ADV messages. Therefore, the 'Start bit' field represents transmission of the first fragmented MOBNBR- ADV message and is set to ' 1' in the first fragmented MOBNBR-ADV message. In other words, the 'Start bit' field is set to '0' in the other fragmented MOBNBR-ADV messages than the first fragmented MOB_NBR-ADV message. The 'Number of Remaining Fragments' field represents the number of the other fragmented MOBNBR-ADV messages which the MS must receive. Further, the MOB_NBR-ADV message includes a 'TLV Encoded Neighbor information' field of variable bits representing TLV-encoded information of the neighbor BSs, a 'DCD Configuration Change Count' field representing a Downlink Channel Descriptor (DCD) change count for configuration of the MOBNBR-ADV message, a 'UCD Configuration Change Count' field representing an Uplink Channel Descriptor (UCD) change count for configuration of the MOB_NBR-ADV message, a 'Length' field of 8 bits representing the length of the neighbor BS information included in the 'N_NEIGHBOR' field, a 'Neighbor BS-ID' field of 48 bits representing the IDs of the neighbor BSs, a 'Preamble Index' field of 8 bits representing the preamble index, and an 'HO Process Optimization' field of 8 bits representing optimization of the handoff process. Hereinafter, a method for fragmenting the MOBNBR-ADV message including the neighbor BS information into fragmented MOBNBR-ADV messages each having a size able to be transmitted in one frame, which uses a configuration of newly defined MOBNBR-ADV messages, will be described. FIG. 3 illustrates a method of fragmenting the MOBNBR-ADV message into fragmented MOBNBR-ADV messages each having a size transmittable in one frame according to an embodiment of the present invention. Referring to FIG. 3, when the serving BS has too many neighbor BSs and too much neighbor BS information, the original MOB_NBR-ADV message 310 has a size exceeding a preset size of one frame 309. When the original MOBNBR-ADV message 310 has a size exceeding a preset size of one frame 309, it is impossible to transmit the original MOBNBR-ADV message 310 in one frame 309. However, in the present invention as described above, the original MOBNBR-ADV message 310 is fragmented into a first MOB_NBR-ADV message 320 and a second MOB_NBR-ADV message 330. The original MOBNBR-ADV message 310 includes a 'Management Message Type' field 301 representing the type of the message, an 'Operator ID' field 303 representing the ID of the operator, a field 305 representing information of the neighbor BSs and including the 'NNEIGHBORS' field representing the number of all neighbor BSs transmitted by one frame 309, and an 'HMAC Tuple' field 307. As described herein, it is assumed that the number of neighbor BSs included in the 'N_NEIGHBORS' field of the original MOB_NBR-ADV message 310 is 24 and the field 305 representing information of the neighbor BSs and including the 'N_NEIGHBORS' field includes information of 24 neighbor BSs. According to the present invention, the original MOBNBR-ADV message 310 is fragmented into fragmented messages each having a size not exceeding the size of one frame 327, for example, into the first MOBNBR-ADV message 320 and the second MOBNBR-ADV message 330. The first MOBNBR-ADV message 320, one of the fragmented messages, includes the 'Management Message Type' field 301 representing the same message type as that included in the original MOB_NBR-ADV message 310, the 'Operator ID' field 303 representing the ID of the operator and the 'HMAC Tuple' field 307. Further, the first MOBNBR-ADV message 320 includes a 'Fragmentation Index' field 321, a 'Total Fragmentation' field 323 and a field 325 representing information of the neighbor BSs and including the 'N_NEIGHBORS' field representing the number of all of the neighbor BSs included in the first MOBNBR-ADV message 320. The 'Fragmentation Index' field 321 represents an index of the first MOBNBR-ADV message 320 which is transmitted by the current frame 327, which represents that the MOBNBR-ADV message transmitted by the current frame 327 from among the fragmented MOBNBR-ADV messages (i.e. the first MOB_NBR-ADV message 320 and the second MOB_NBR-ADV message 330) is the first MOBNBR-ADV message 320. The 'Total Fragmentation' field 323 represents the number of all of the fragmented MOBNBR-ADV messages fragmented from the original MOBNBR-ADV message 310 (in the case of FIG. 3, the 'Total Fragmentation' field 323 is set to '2', because the first MOBNBR-ADV message 320 and the second MOBNBR-ADV message 330 are all of the fragmented MOBNBR- ADV messages). As used herein, it is assumed that the 'NNEIGHBORS' field of the first MOBNBR-ADV message 320 includes 16 BSs so that the first MOBNBR-ADV message 320 has a size not exceeding the size of the current frame 327. Therefore, the field 325 representing information of the neighbor BSs and including the 'N_NEIGHBORS' field includes 16 pieces of neighbor BS information. Further, the second MOBNBR-ADV message 330 is transmitted to the MS by the next frame 337 directly after the first MOB_NBR-ADV message 320 is transmitted to the MS by the current frame 327. The second MOB_NBR-ADV message 330 includes the same 'Management Message Type' field 301 as that include in the first MOBNBR-ADV message 320, the 'Operator ID' field 303 representing the ID of the operator and the 'HMAC Tuple' field 307. Further, the second MOBNBR-ADV message 330 includes a 'Fragmentation Index' field 331 representing that the MOB_NBR-ADV message transmitted by the next frame 337 from among the fragmented MOBNBR-ADV messages (i.e. the first MOB_NBR-ADV message 320 and the second MOB_NBR-ADV message 330) is the second MOBNBR-ADV message 330. As does the first MOB_NBR-ADV message 320, the second MOBNBR- ADV message 330 further includes a 'Total Fragmentation' field 333 and a field 335 representing information of the neighbor BSs and including the 'N_NEIGHBORS' field representing the number of all of the neighbor BSs included in the second MOBNBR-ADV message 330. The 'Total Fragmentation' field 333 represents the number of all of the fragmented MOBNBR-ADV messages fragmented from the original MOBNBR-ADV message 310 (in the case of FIG. 3, the 'Total Fragmentation' field 333 is set to '2', because the first MOBNBR-ADV message 320 and the second MOBNBR-ADV message 330 are all of the fragmented MOBNBR-ADV messages). According to the assumption that the 'N_NEIGHBORS' field of the first MOB_NBR-ADV message 320 includes 16 BSs so that the first MOB_NBR-ADV message 320 has a size not exceeding the size of the current frame 327, 16 pieces of neighbor BS information have already been transmitted to the MS by the first MOBNBR- ADV message 320. As a result, the "N_NEIGHBORS' field of the second MOBNBR-ADV message 330 transmitted to the MS by the next frame 337 includes 8 BSs remaining after transmission of the first MOBNBR-ADV message 320 and the field 335 representing information of the neighbor BSs and including the 'N_NEIGHBORS' field includes 8 pieces of neighbor BS information. Although the above description is based on an assumption that the first MOBNBR-ADV message 320 includes 16 pieces of neighbor BS information so that the first MOBNBR-ADV message 320 has a size not exceeding the size of the current frame 327, the first MOBNBR-ADV message 320 may include a different number of neighbor BSs, which changes the number of neighbor BSs included in the second MOBNBR-ADV message 330. Further, according to the present invention, when the second MOBNBR-ADV message 330 has a size greater than that of the next frame 337, the original MOBNBR-ADV message 310 may be fragmented into three or more fragmented MOBNBR-ADV messages and the fragmented MOBNBR-ADV messages may be transmitted to the MS by frames the number of which corresponds to the number of the fragmented MOBNBR-ADV messages. In this case, each of the fragmented MOBNBR-ADV messages includes the fields as described above. When the serving BS fragments the MOBNBR- ADV message, the fragmentation is based on the size of one frame so that each of the fragmented MOBNBR-ADV messages has a size not greater than the size of one frame and the number of BSs included in the field representing the neighbor BS information and including the 'NNEIGHBORS' field does not exceed the number of BSs transmittable in one frame. Further, each of the fragmented MOB_NBR-ADV messages commonly includes a 'Management Message Type' field having the same value, an 'Operator ID' field representing an ID of an operator, and an 'HMAC Tuple' field. Further, the serving BS inserts the number of fragmented MOBNBR- ADV messages into the 'Total Fragmentation' field, inserts an index of the current fragmented MOBNBR-ADV message transmitted by the current frame into the 'Fragmentation Index' field, inserts information of neighbor BSs into the corresponding field, and then transmits the current fragmented MOB_NBR-ADV message to the MS. Although the above description discusses the case of broadcasting the MOB_NBR-ADV message in order for a serving BS to notify neighbor BS information to an MS, the present invention can be applied to the formation and transmission of other broadcast messages from the serving BS to the MS as well as the MOBNBR-ADV message. Hereinafter, an operation of a serving BS for forming and transmitting a broadcast message including neighbor BS information will be described. FIG. 4 is a flowchart of a process according to an embodiment of the present invention, in which a serving BS forms and transmits a broadcast message including information of neighbor BSs. In step 401, the serving BS scans and collects information of neighbor BSs to transmit to an MS. In step 403, the serving BS compares the collected information of neighbor BSs with the size of the frame for carrying the collected information of neighbor BSs to the MS. When the collected information of neighbor BSs has a size not greater than the size of one frame, the serving BS proceeds to step 409, in which the serving BS constructs a broadcast message including the collected information and transmits the constructed broadcast message to the MS in one frame. Upon receiving the broadcast message through one frame, the MS obtains the information of the neighbor BSs included in the broadcast message. Therefore, the BWA system supports the handoff of the MS. When the collected information of neighbor BSs has a size greater than the size of one frame as a result of the determination in step 403, the serving BS proceeds to step 405, in which the serving BS divides the broadcast message including the collected information into fragmented broadcast messages each having a size not greater than the size of the frame. Then, in step 407, the serving BS sets up the fields constituting the fragmented broadcast message. For example, when the broadcast message has been divided into two fragmented MOBNBR-ADV messages in step 405, the 'Total Fragmentation' fields of the two fragmented MOB_NBR-ADV messages as shown in Table 1, which represent the number of all of the fragmented MOBNBR-ADV messages, are set to have the same binary value of '0010'. Further, the 'Fragmentation Index' field of the first fragmented MOBNBR-ADV message from among the two fragmented MOB_NBR-ADV messages, which represents an index of the first fragmented MOBNBR-ADV message carried by the first frame, is set to have a value of '0001', and the 'Fragmentation Index' field of the second fragmented MOBNBR-ADV message carried by the second frame is set to have a value of '0010'. Then, in step 409, the serving BS transmits the fragmented broadcast message including the setup fields to the MS in the corresponding frame. When the broadcast message has been divided into two fragmented broadcast messages, the serving BS transmits the two fragmented broadcast messages in two frames. The MS sequentially receives the fragmented broadcast messages as described above in the corresponding number of frames. Specifically, when the received broadcast messages are fragmented MOBNBR-ADV messages, the MS recognizes the field values of the fragmented MOBNBR-ADV messages and checks the value of the 'Total Fragmentation' field representing the number of all of the fragmented MOBNBR-ADV messages, thereby determining if the MOBNBR-ADV message transmitted by the current frame is a fragmented MOBNBR-ADV message. For example, when the 'Total Fragmentation' field of the currently received MOB_NBR-ADV message has a value of '0000', it implies the currently received MOB_NBR-ADV message is not a fragmented MOB_NBR-ADV message. Further, the MS can obtain information of neighbor BSs from the currently received MOBNBR-ADV message by decoding the currently received MOBNBR-ADV message. When the 'Total Fragmentation' field of the currently received MOBNBR-ADV message has any value other than '0000', the MS recognizes the number of all the fragmented MOB_NBR-ADV messages from the value of the 'Total Fragmentation' field and waits for reception of the next fragmented MOBNBR-ADV message to be transmitted in the next frame. That is, the MS receives the fragmented MOBNBR-ADV messages by sequentially transmitted multiple frames and obtains information of neighbor BSs by decoding the received fragmented MOBNBR-ADV messages. Also, the MS can obtain information of all of the neighbor BSs broadcast by the serving BS, by receiving all of the fragmented MOB_NBR-ADV messages. In a BWA communication system according to the present invention as described above, a serving BS can collect information of neighbor BSs, form a broadcast message including the information of the neighbor BSs, and fragment the broadcast message if the broadcast message is too large. Therefore, the serving BS can transmit a large amount of neighbor BS information to the MS. As a result, a BWA communication system according to the present invention can support handoff of an MS moving between cells because it is possible to transmit a large amount of neighbor BS information to the MS in the system. While the invention has been shown and described with reference to certain preferred embodiments thereof, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. WE CLAIM : 1. A method for transmitting to a mobile station (150) information of neighbor base stations by a base station (121-133) in a communication system, the method comprising the steps of: setting, (407) by a Controller of the base station, a value of each of a plurality of fields comprised in each of m fragments on the information of the neighbor base station; and Sequentially transmitting, by the base station, each of the m fragments of the information of the neighbor base stations to the mobile station (150); wherein the m fragments are generated by fragmenting a broadcast message comprising the information of the neighbor base stations into m fragments, wherein the plurality of fields comprise in each of the m fragments a first field, a second field, and a third field, the first field indicates a fragmentation index for a current fragment, the second field indicates a total number of fragments equal to m, where m is an integer greater than or equal to 1, and the third field indicates a number of the neighbor base stations comprised in the current fragment, wherein the current fragmentation comprises identifiers of the neighbor base stations comprised in the information of the current fragment, wherein the current fragment comprises physical frequencies for the neighbor base stations comprised in the information of the current fragmentation, and wherein the plurality of fields comprise an operator identifier, ID field and a Configuration Change Count field which is incremented each time when information for an associated neighbor base station has changed. 2. The method as claimed in claim 1, wherein the communication system is a Broadband Wireless Access (BWA) communication system which uses an Orthogonal Frequency Division Multiple Access (OFDMA) scheme using a plurality of sub-carriers, and supports a multi-cell structure and a mobility of a mobile station so that the mobile station obtains the information on the neighbor base stations by receiving the information of neighbor base stations from a serving base station, and the mobile station may perform a handoff process on moving to another cell after preliminarily obtaining the information on the neighbor base stations. 3. The method as claimed in claim 1, wherein the plurality of fields comprise a Downlink Channel Descriptor (DCD) Configuration Change Count field representing a DCD change count for the neighbor base stations comprised in the current fragment, and a Uplink Channel Descriptor (UCD) Configuration Change Count field representing a UCD change count for the neighbor base stations comprised in the current fragmentation. 4. The method as claimed in claim 1, wherein the plurality of fields comprise a preamble index representing a preamble index and a handoff optimization field representing optimization of the handoff process. 5. A method for receiving information on neighbor base stations (121-133) by a mobile station (150) in a communication system, the method comprising the steps of: sequentially receiving by the mobile station, m fragments of the information on the neighbor base stations from a base station; wherein the m fragments are generated, by the base station, by fragmenting a broadcast message comprising the information on the neighbor base stations into m fragments, wherein a plurality of fields comprised in each of the m fragments a first field, a second field, and a third field, the plurality of fields are comprised in each of the m fragments of the information on the neighbor base stations, the first field indicates a fragmentation index for a current fragment, the second field indicates a total number of fragments equal to m, where m is an integer greater than or equal to 1, and the third field indicates a number of the neighbor base stations comprised in the current fragment, wherein the current fragmentation comprise identifiers of the neighbor base stations comprised in the information of the current fragmentation, wherein the current fragmentation comprises physical frequencies for the neighbor base stations comprised in the current fragment; and wherein the plurality of fields comprise an operator ID field and a Configuration Change Count field which is incremented each time when information for an associated neighbor base station has changed. 6. The method as claimed in claim 5 wherein the communication system is a Broadband Wireless Access (BWA) communication system which uses an Orthogonal Frequency Division Multiple Access (OFDMA) scheme using a plurality of sub-carriers, and supports a multi-cell structure and a mobility of the mobile station so that the mobile station obtains the information of the neighbor base stations by receiving the information on the neighbor base stations from a serving base station, and the mobile station may perform a handoff process on moving to another cell after preliminarily obtaining the information on the neighbor base stations. 7. The method as claimed in claim 5, wherein the plurality of fields comprise a Downlink Channel Descriptor (DCD) Configuration Change Count field representing a DCD change count for the neighbor base station comprised in the current fragment, and an Uplink Channel Descriptor (UCD) Configuration Change Count field representing (UCD) change count for the neighbor base stations comprised in the current fragment. 8. The method as claimed in claim 8, wherein the plurality of fields comprise a preamble index representing a preamble index and a handoff optimization field representing optimization of the handoff process for an associated neighbor base station. 9. A mobile station MS (150) in a communication system, comprising: a receiver for sequentially receiving each of m fragmentations of information on the neighbor base stations from the base station, wherein the m fragmentations are generated, by the base station, by fragmenting a broadcast message comprising the information of the neighbor base stations into m fragmentations, and a plurality of the fields comprise a first field, a second field, and a third field in the each of m fragmentations, the plurality of fields are comprised in each of m fragmentations of the information on the neighbor base stations, the first field indicates a fragmentation index for a current fragmentation, the second field indicates a total number of fragmentation equal to m, where m is an integer equal to or greater than 1, and the third field indicates a number equal to the number of the neighbor base stations comprised in information on the current fragmentation; wherein the current fragment comprises identifiers of the neighbor base stations comprised in the information of the current fragment; wherein the current fragment comprises physical frequencies for the neighbor base stations comprised in the information of the current fragment, and wherein the plurality of fields comprise an operator identifier ID field and a Configuration Change Count field which is incremented each time when information for an associated neighbor base station has changed. 10. The mobile station as claimed in claim 9, wherein the communication system is a Broadband Wireless Access (BWA) communication system which uses an Orthogonal Frequency Division Multiple Access (OFDMA) scheme using a plurality of sub-carriers, and supports a multi-cell structure and a mobility of the mobile station so that the mobile station obtains the information on the neighbor base stations by receiving the information on the neighbor base stations from a serving base station, and the mobile station may perform a handoff process on moving to another cell after preliminarily obtaining the information on the neighbor base stations. 11. The mobile station as claimed in claim 9, wherein the plurality of fields comprise a Downlink Channel Descriptor (DCD) Configuration Change Count field representing a DCD change count for the neighbor base stations comprised in the current fragment, and an Uplink Channel Description (UCD) Configurartion Change Count filed representing a UCD change count for the current fragment. 12. The mobile station as claimed in claim 9, wherein the plurality of fields comprise a preamble index representing a preamble index and a handoff optimization field representing optimization of the handoff process for an associated neighbor base station. 13. A base station BS (121-133) in a communication system, the base station comprising: a controller for setting a value of each of a plurality of fields comprised in each of m fragments of information on the neighbor base stations; and a transmitter for sequentially transmitting to the mobile station each of the m fragments of the information on the neighbor base stations into m fragments, wherein the plurality of fields comprised in each of the m fragments a first field, a second field, a third field, the first field indicates a fragmentation index for a current fragment, the second field indicates a total number of fragments equal to m, where m is an integer greater than or equal to 1, and the third field indicates a number of the neighbor base stations comprised in the current fragment, wherein the current fragmentation comprises identifiers of the neighbor base stations comprised in the information of the current fragment; wherein the current fragment comprises physical frequencies for the neighbor base stations comprised in the information of the current fragment, and wherein the plurality of fields comprise an operator identifier, ID field and a Configuration Change Count field which is incremented each time when information for an associated neighbor base station has changed. 14. The base station as claimed in claim 13, wherein the communication system is a Broadband Wireless Access (BWA) communication system which uses an Orthogonal Frequency Division Multiple Access (OFDMA) scheme using a plurality of sub-carriers and supports a multi-cell structure and a mobility of the mobile station so that the mobile station obtains the information on the neighbor base stations by receiving the information on the neighbor base stations from a serving base station, and the mobile station may perform a handoff process on moving to another cell after preliminarily obtaining the information on the neighbor base stations. 15. The base station as claimed in claim 13, wherein the plurality of fields comprise a Downlink Channel Descriptor (DCD) Configuration Change Count field representing a DCD change count for the current fragment, and an Uplink Channel Descriptor (UCD) Configuration Change Count field representing a UCD change count for the current fragment. 16. The base station as claimed in claim 13, wherein the plurality of fields comprise a preamble index representing a preamble index, and a handoff optimization field representing optimization of the handoff process. ABSTRACT TITLE "A METHOD AND APPARATUS FOR BROADCASTING AND RECEIVING INFORMATION OF NEIGHBOR BASE STATIONS IN A COMMUNICATION SYSTEM" The invention relates to a method for transmitting to a mobile station (150) information of neighbor base stations by a base station (121-133) in a communication system, the method comprising the steps of: setting, (407) by a controller of the base station, a value of each of a plurality of fields comprised in each of m fragments of the information on the neighbor base station; and sequentially transmitting, by the base station, each of the m fragments of the information of the neighbor base stations to the mobile station (150); wherein the m fragments are generated by fragmenting a broadcast message comprising the information of the neighbor base stations into m fragments, wherein the plurality of fields comprise in each of the m fragments a first field, a second field, and a third field, the first field indicates a fragmentation index for a current fragment, the second field indicates a total number of fragments equal to m, where m is an integer greater than or equal to 1, and the third field indicates a number of the neighbor base stations comprised in the current fragment, wherein the current fragmentation comprises identifiers of the neighbor base stations comprised in the information of the current fragment, wherein the current fragment comprises physical frequencies for the neighbor base stations comprised in the information of the current fragmentation, and wherein the plurality of fields comprise an operator identifier, ID field and a Configuration Change Count field which is incremented each time when information for an associated neighbor base station has changed.

Full Text

METHOD AND SYSTEM FOR FORMING AND
TRANSMITTING/RECEIVING NEIGHBOR BASE STATION
INFORMATION IN A BWA COMMUNICATION SYSTEM
BACKGROUND OF THE INVENTION
1. Field of the Invention
The present invention relates to a Broadband Wireless Access (BWA)
communication system, and more particularly to a method and a system for
forming and transmitting/receiving neighbor Base Station (BS) information in
order for a serving BS to send the neighbor BS information to a Mobile Station
(MS) in a BWA communication system.
2. Description of the Related Art
The communication system was initially developed for the purpose of
voice service and is now being developed to provide data service and various
multimedia services. However, the communication system developed for voice
service has a relatively narrow bandwidth for data transmission and requires
relatively expensive service charges, it cannot meet rapidly increasing user
demands for various services. Further, the necessity for a communication system
capable of efficiently providing Internet service is now increasing due to
increasing demands for the Internet service together with the development in the
communication industry. To this end, a Broadband Wireless Access (BWA)
communication system, which has a broad enough bandwidth to meet rapidly
increasing user demands and efficiently provide the Internet service, has been
introduced.
The BWA communication system is a communication system for
supporting not only the voice service but also various data services of low and
high speed and multimedia application services for providing high quality moving
images, etc. The BWA communication system supports access to the Public
Switched Telephone Network (PSTN), Packet Switched Data Network (PSDN),
Internet network, International Mobile Telecommunication (IMT)-2000 network,
Asynchronous Transfer Mode (ATM) network, etc. in a mobile or stationary
environment based on wireless media using a broadband, and supports a high
speed channel data rate. The BWA communication system can be classified into a
broadband wireless subscriber network, a broadband mobile access network, and
high speed wireless Local Area Network (LAN), according to the mobility
(stationary or mobile) of a Subscriber Station (SS), the communication

environment (outdoor or indoor), and the channel data rate.
Meanwhile, 802.16 standardization group of Institute of Electrical and
Electronics Engineers (IEEE), which is one of international standardization
organizations, is arranging standards for wireless access schemes of the BWA
communication system, and specifically, is now driving to establish an IEEE
802.16d standard for providing a broadband wireless Internet service to a
stationary SS. The 802.16 system does not account for the mobility of the SS.
A BWA system according to the IEEE 802.16d standard has a wider
bandwidth for data transmission and thus can transmit a much larger quantity of
data in a short time, in comparison with the conventional wireless technology for
voice service. Further, in the BWA system according to the IEEE 802.16d
standard, all of the users can share a channel, thereby achieving efficient use of
the channel. Further, the BWA system according to the IEEE 802.16d standard
can guarantee various Quality of Service (QoS) and thus can provide a user with
services of different qualities according to the characteristics of service. In the
IEEE 802.16d system, all of the users connected to the BS share a common
channel, so the BS allocates intervals of the common channel for use by each user
during every uplink and downlink frame. Therefore, the BS must send uplink and
downlink access information to the users every frame in order to enable the users
to share the channel. To this end, in the IEEE 802.16d system, channels are
divided into uplink channel and downlink channel, information about each
channel is defined according to Type, Length and Value (TLV), and the defined
information is then inserted to Downlink Channel Descriptor (DCD) and Uplink
Channel Descriptor (UCD) messages which are transmitted to all of the users, so
that characteristic information about the channels is sent to the SS.
Further, the IEEE 802.16 standardization group is now driving to
establish an IEEE 802.16e standard for providing mobility to an SS of the IEEE
802.16d communication system. The IEEE 802.16e communication system has a
wider bandwidth for data transmission and thus can transmit a much larger
quantity of data in short time, in comparison with the conventional wireless
technology for voice service. Further, in the IEEE 802.16e communication system,
all of the users can share a channel, thereby achieving efficient use of the channel.
Also, the IEEE 802.16e communication system can guarantee various Quality of
Service (QoS) and thus can provide a user with services of difference qualities
according to the characteristics of service. The IEEE 802.16e communication
system supports handoff, thereby guaranteeing the mobility of a Mobile Station
(MS).
In order to support the mobility of an MS, a BS of the IEEE 802.16e

communication system periodically broadcasts a mobile neighbor advertisement
(MOBNBR-ADV) message that includes neighbor BS information to all MSs
within a cell controlled by the BS, thereby sending status information of the
neighbor cells to the MSs. Specifically, when an MS located within one cell
moves to a neighbor cell, the MS can preliminarily obtain information of a
neighbor BS of the neighbor cell (i.e. a BS controlling the neighbor cell), such as
a network ID, channel characteristics, etc. of the neighbor BS, by receiving the
MOBNBR-ADV message broadcast by the serving BS which controls the
current cell in which the MS is currently located. Therefore, the IEEE 802.16e
communication system can support handoff of the MS.
However, in the IEEE 802.16e communication system, when the serving
BS has too many neighbor cells or the neighbor cells have capacities much
different from the capacity of the current cell, the quantity of the neighbor BS
information transmitted from the serving BS to the MSs becomes too much, so
that the MOB_NBR-ADV message transmitted from the serving BS to the MSs
becomes too large. When the serving BS has too much neighbor BS information,
it is impossible to transmit all of the information in one frame. In other words, the
MOBNBR-ADV message including all the neighbor BS information becomes
too large and thus cannot be transmitted in one frame. In the IEEE 802.16e
communication system, a BS cannot fragment a Medium Access Control (MAC)
management message to transmit the message.
SUMMARY OF THE INVENTION
Accordingly, the present invention has been made to solve at least the
above-mentioned problems occurring in the prior art, and an object of the present
invention is to provide a method and system for forming and
transmitting/receiving a broadcast message for sending information of neighbor
BSs to an MS in a BWA communication system.
It is another object of the present invention to provide a method and
system for fragmenting and transmitting/receiving a broadcast message for
sending information of neighbor BSs to an MS in a BWA communication system.
In order to accomplish this object, there is provided a method for
transmitting neighbor base station information by a serving base station in a
broadband wireless access communication system in which the serving base
station broadcasts the neighbor base station information to a mobile station, the
method includes the steps of scanning neighbor base stations adjacent to the
serving base station, collecting information of the scanned neighbor base stations,

and comparing a size of the information of the scanned neighbor base stations to a
size of a frame for carrying the information of the neighbor base stations
constructing at least one broadcast message including the information of the
neighbor base stations according to a result of the comparison and setting up
fields of the constructed broadcast message according to the information included
in the constructed broadcast message and broadcasting the broadcast message
including the setup fields.
In accordance with another aspect of the present invention, there is
provided a method for receiving neighbor base station information by a mobile
station in a broadband wireless access communication system in which a serving
base station broadcasts the neighbor base station information to the mobile station,
the method includes the steps of receiving a first broadcast message transmitted
from the serving base station by the mobile station obtaining information of
neighbor base stations included in the first broadcast message and determining
from the obtained information if the first broadcast message is a fragmented
broadcast message and receiving at least one more fragmented broadcast message
transmitted from the serving base station when the first broadcast message is a
fragmented broadcast message.
In accordance with another aspect of the present invention, there is
provided a method for forming neighbor base station information by a serving
base station in a broadband wireless access communication system in which the
serving base station broadcasts the neighbor base station information to a mobile
station, the method includes the steps of scanning neighbor base stations adjacent
to the serving base station, collecting information of the scanned neighbor base
stations, and comparing a size of the information of the scanned neighbor base
stations with a size of a frame for carrying the information of the neighbor base
stations and constructing at least one broadcast message including the information
of the neighbor base stations according to a result of the comparison and setting
up fields of the constructed broadcast message according to information included
in the constructed broadcast message.
In accordance with another aspect of the present invention, there is
provided a method for transmitting and receiving neighbor base station
information in a broadband wireless access communication system in which a
serving base station broadcasts the neighbor base station information to a mobile
station, the method includes the steps of scanning neighbor base stations adjacent
to the serving base station, collecting information of the scanned neighbor base
stations, comparing a size of the information of the scanned neighbor base
stations with a size of a frame for carrying the information of the neighbor base

stations, constructing at least one broadcast message including the information of
the neighbor base stations according to a result of the comparison, setting up
fields of the constructed broadcast message according to information included in
the constructed broadcast message, and broadcasting by the serving base station
the broadcast message including the setup fields, and receiving the broadcast
message transmitted from the serving base station by the mobile station, obtaining
information of neighbor base stations included in the broadcast message and
determining from the obtained information if the broadcast message is a
fragmented broadcast message, and receiving by the mobile station at least one
more fragmented broadcast message transmitted from the serving base station
when the broadcast message is a fragmented broadcast message.
In accordance with another aspect of the present invention, there is
provided a system for transmitting and receiving neighbor base station
information in a broadband wireless access communication system in which a
serving base station broadcasts the neighbor base station information to a mobile
station, the system includes a serving base station for scanning neighbor base
stations adjacent to the serving base station, collecting information of the scanned
neighbor base stations, comparing a size of the information of the scanned
neighbor base stations with a size of a frame for carrying the information of the
neighbor base stations, constructing at least one broadcast message including the
information of the neighbor base stations according to a result of the comparison,
setting up fields of the constructed broadcast message according to information
included in the constructed broadcast message, and broadcasting the broadcast
message including the setup fields and a mobile station for receiving the
broadcast message transmitted from the serving base station by the mobile station,
obtaining information of neighbor base stations included in the broadcast message
and determining from the obtained information if the broadcast message is a
fragmented broadcast message, and receiving at least one more fragmented
broadcast message transmitted from the serving base station when the broadcast
message is a fragmented broadcast message.
In accordance with another aspect of the present invention, there is
provided a system for forming neighbor base station information by a serving
base station in a broadband wireless access communication system in which the serving base station broadcasts the neighbor base station information to a mobile
station, the system includes a serving base station for scanning neighbor base
stations adjacent to the serving base station, collecting information of the scanned
neighbor base stations, comparing a size of the information of the scanned
neighbor base stations with a size of a frame for carrying the information of the

neighbor base stations, constructing at least one broadcast message including the
information of the neighbor base stations according to a result of the comparison,
and setting up fields of the constructed broadcast message according to information included in the constructed broadcast message.
BRIEF DESCRIPTION OF THE ACCOMPANYING DRAWINGS
The above and other objects, features and advantages of the present
invention will be more apparent from the following detailed description taken in
conjunction with the accompanying drawings, in which:
FIG. 1 illustrates a structure of a B WA communication system according
to an embodiment of the present invention, which supports handoff of an MS
moving between cells controlled by BSs supporting different operation modes;
FIG. 2 illustrates a format of a MOBNBR-ADV message proposed in a
BWA communication system according to an embodiment of the present
invention;
FIG. 3 illustrates a method of fragmentation of the MOB_NBR-ADV
message according to an embodiment of the present invention; and
FIG. 4 is a flowchart of a process according to an embodiment of the
present invention, in which a serving BS forms and transmits/receives a broadcast
message including neighbor BS information.
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT
Hereinafter, preferred embodiments of the present invention will be
described with reference to the accompanying drawings. In the following
description, a detailed description of known functions and configurations
incorporated herein will be omitted when it may make the subject matter of the
present invention rather unclear.
As described here, the present invention proposes a method and system
for forming a broadcast message, specifically a mobile neighbor advertisement
(MOBNBR-ADV) message, for transmitting neighbor BS information from a
serving BS (a BS currently providing service to an MS) to the MS in order to
support handoff of the MS in a BWA communication system. Further, the present
invention proposes a method and system for transmitting and receiving the
MOB_NBR-ADV message including the neighbor BS information in a BWA
communication system. The present invention proposes a method and system for
constructing a MOBNBR-ADV message through fragmentation and then

transmitting the constructed MOBNBR-ADV message to an MS, when the
serving BS has too much neighbor BS information to transmit to the MS and thus
the MOB_NBR-ADV message to be transmitted to the MS is too large. Also, the
present invention can be applied to formation and transmission of all broadcast
messages exchanged between a BS and an MS as well as the MOB_NBR-ADV
message.
For convenience, the following description is based on an assumption that
a BWA communication system according to preferred embodiments of the present
. invention is an IEEE 802.16e communication system which uses an Orthogonal
Frequency Division Multiplexing (OFDM) scheme and an Orthogonal Frequency
Division Multiple Access (OFDMA) scheme. Because the IEEE 802.16e
communication system uses an OFDM/OFDMA scheme, it can transmit physical
channel signals by using a plurality of sub-carriers, thereby achieving high speed
data transmission. Also, the IEEE 802.16e communication system supports a
multi-cell structure and the mobility of an MS.
FIG. 1 illustrates a structure of a BWA communication system according
to an embodiment of the present invention, which supports handoff of an MS
moving between cells controlled by BSs supporting different operation modes.
Referring to FIG. 1, the BWA communication system has a multi-cell
structure including cell 1 101, cell 2 103, cell 3 105, cell 4 107, cell 5 109, cell 6
111, and cell 7 113. Also, the BWA communication system includes BSs 121, 123,
125, 127, 129, 131, 133 and an MS 150. The BSs 121, 123, 125, 127, 129, 131,
133 control the cells 101, 103, 105, 107, 109, 111, 113, respectively. The MS 150
can receive services from the BSs 121, 123, 125, 127, 129, 131, 133 while
moving between the cells 101, 103, 105, 107, 109, 111, 113. The signal exchange
between the MS 150 and the BSs 121, 123, 125, 127, 129, 131, 133 uses the
OFDM/OFDMA scheme.
When the MS 150 moves from cell 1 101 controlled by BS 1 121 to cell 2
103 controlled by BS 2 123, the serving BS (the BS which is currently providing
a service to the MS 150) changes from BS 1 121 to BS 2 123, and BS 1 121 (the
current serving BS) broadcasts a MOBNBR-ADV message that includes BS
information of neighbor cells to the MS 150. Upon receiving the MOBNBR-
ADV message, the MS 150 obtains the BS information of neighbor cells in
advance. Then, as soon as the MS 150 gets the channel information of BS 2 123,
the MS 150 starts a process for setting up a connection with BS 2 123, thereby
performing a handoff process. That is, BS 1 121 (the current serving BS)
broadcasts a MOBNBR-ADV message in order to preliminarily send neighbor
BS information (i.e. information of BS 2 123) to the MS 150 moving to cell 2 103,

and the MS 150 recognizes the information of BS 2 123 from the received
MOBNBR-ADV message. As a result, the BWA communication system
supports handoff of the MS 150.
In a BWA communication system having the structure described above,
the serving BS inserts the neighbor BS information in the MOBNBR-ADV
message in order to transmit the neighbor BS information to the MS. Table 1
below shows the format of the MOBNBR-ADV message.

As shown in Table 1, the MOB_NBR-ADV message includes a plurality
of Information Elements (IEs), which include a 'Management Message Type'
field of 8 bits which represents the type of transmitted/received message
(Management Message Type = 49), an 'Operator ID' field of 24 bits which is
assigned for identification of an operator, represents an identifier (ID) of the
operator, and can be shared by a group of BSs, an 'NNEIGHBOR' field of 8 bits

which represents the number of neighbor BSs, an 'HMAC Tuple' field of 21 bits,
and information of all of the neighbor BSs. Further, the MOB NBR-ADV
message includes a 'Fragmentation Index' field and a 'Total Fragmentation' field,
each of which has a size of 4 bits and represents 'Neighbor Set' of neighbor BSs.
That is, the 'Neighbor Set' field of the neighbor BSs is divided into the
'Fragmentation Index' field of 4 bits, which represents an index of the current
fragmented MOBNBR-ADV message transmitted by the current frame among
all of the fragmented MOBNBR-ADV messages, and the 'Total Fragmentation'
field which represents the number of all of the fragmented MOBNBR-ADV
messages, i.e. the number of all fragments divided from the entire MOBNBR-
ADV message.
FIG. 2 illustrates a format of a MOBNBR-ADV message including the
newly added fragmentation information described above, i.e. the 'Fragmentation
Index' field representing an index of the currently transmitted fragmented
MOBNBR-ADV message and the 'Total Fragmentation' field representing the
number of all the fragmented MOBNBR-ADV messages. Referring to FIG. 2,
when the serving BS has too much neighbor BS information and a MOBNBR-
ADV message which cannot be transmitted in one frame, the serving BS divides
the MOBNBR-ADV message into fragmented MOBNBR-ADV messages of a
size which can be carried by one frame, inserts the number of all of the
fragmented MOBNBR-ADV messages into the 'Total Fragmentation' field and
an index of a fragmented MOB_NBR-ADV message transmitted by a current
frame into the 'Fragmentation Index' field, and then transmits the information-
inserted message. When the MOBNBR-ADV message has been divided into
more than one fragmented MOBNBR-ADV message, the serving BS
sequentially transmits to the MS all of the fragmented MOBNBR-ADV
messages by corresponding frames. In this case, the 'Fragmentation Index' field
represents indices of neighbor BSs also included in the fragmented MOBNBR-
ADV message transmitted by the current frame, so that the MS can differentiate
the fragmented MOBNBR-ADV message transmitted by the current frame from
the other fragmented MOBNBR-ADV messages. Further, because the 'Total
Fragmentation' field represents the number of all of the fragmented MOBNBR-
ADV messages transmitted to the MS, the MS can determine if there is any more
fragmented MOBNBR-ADV message to be transmitted by another frame after
the current frame. Through the 'Total Fragmentation' field, the MS can
recognize the number of frames for carrying the entire MOBNBR-ADV message
and can receive all of the fragmented MOBNBR-ADV messages transmitted
through the corresponding number of frames, thereby acquiring the information

of all of the neighbor BSs.
Further, the 'N_NEIGHBORS' field includes a 'Neighbor BS ID' field of
48 bits representing IDs of the neighbor BSs, a 'PHY Profile ID' field of 32 bits
representing downlink physical frequencies of the neighbor BSs, a 'Configuration
Change Count' field of 8 bits representing a change count for the configuration of
the MOBNBR-ADV message, and a 'TLV Encoded Neighbor information' field
of variable bits representing TLV-encoded information of the neighbor BSs.
In a BWA communication system according to an embodiment of the
present invention, the MS can obtain information of neighbor BSs by receiving
the MOBNBR-ADV message including the field as described above from the
serving BS, and the MS can easily perform handoff when moving to another cell
because the MS preliminarily obtains information of the BS controlling the other
cell to which the MS will move. Therefore, the BWA communication system
according to the present invention supports handoff of an MS. Further, in the
BWA communication system, the MOB_NBR-ADV message includes the
'Fragmentation Index' field and the 'Total Fragmentation' field. Therefore, when
the MOBNBR-ADV message is too large to be sent to the MS in one frame, the
MOBNBR-ADV message is divided into fragmented messages each having a
size transmittable in one frame, so that the fragmented messages can be
transmitted to the MS in more than one frame. Therefore, according to the present
invention, even when the serving BS has too much neighbor BS information and
a MOBNBR-ADV message is to large to transmit, the serving BS can fragment
the MOBNBR-ADV message and then transmit the fragmented MOBNBR-
ADV messages to the MS and the MS can preliminarily get the neighbor BS
information by receiving the fragmented MOBNBR-ADV messages.
Table 2 shows a format of the MOBNBR-ADV message including
information of neighbor BSs transmitted from a serving BS to an MS in a BWA
communication system according to another embodiment of the present invention.

As shown in Table 2, the MOBNBR-ADV message includes a plurality
of IEs, which include a 'Management Message Type' field of 8 bits which
represents the type of transmitted/received message (Management Message Type
= 49), an 'Operator ID' field of 24 bits which is assigned for identification of an
operator, represents an identifier (ID) of the operator, and can be shared by a
group of BSs, a 'Configuration Change Count' field of 8 bits representing a
change count for the configuration of the MOBNBR-ADV message, and a 'PHY
Profile ID' field which represents physical layer information of the BS and
includes a Co-located FA indicator bit, an FA Configuration indicator bit, a
Time/Frequency Synchronization Indicator, a BS EIRP Indicator, a DCD/UCD
Reference Indicator, an FA Index Indicator and an FA number.
When the MOB_NBR-ADV message having the format as described
above is too large to be transmitted in one frame, that is, when it is impossible to
transmit all of the neighbor BS information in one frame, the serving BS may
divide the MOB_NBR-ADV message into fragmented messages each having a
size transmittable in one frame in order to transmit the MOBNBR-ADV
message to the MS. Further, when the MOBNBR-ADV message is transmitted
to the MS after being fragmented, each transmitted fragment of the MOBNBR-
ADV message must indicate that the MOBNBR-ADV message has been
fragmented. Also, when the MS has received one fragment of the MOBNBR-
ADV message indicating that the MOBNBR-ADV message has been
fragmented, the MS can receive directly after the first fragment information of all
of the neighbor BSs by receiving all of the other fragments of the MOBNBR-
ADV message transmitted by the frames.
In order to indicate that the MOB_NBR-ADV message has been
fragmented, it is necessary for the MOBNBR-ADV message to include the
following fields. That is, the MOBNBR-ADV message includes a
'Fragmentation Mode' field of 1 bit representing the fragmentation mode, a
'TOT_N_NEIGHBORS' field of 7 bits representing the number of all of the
neighbor BSs, a 'Start bit' field of 1 bit representing the start bit of the fragmented
MOBNBR-ADV message, and a 'Number of Remaining Fragments' field of 6
bits representing the number of remaining fragmented MOB_NBR-ADV
messages to be transmitted by frames directly after the frame carrying the very
fragmented MOBNBR-ADV message.
By the above-mentioned fields, it is noted that the MOBNBR-ADV
message can be fragmented according to two types of fragmentation modes. The

'Fragmentation Mode' field of the MOBNBR-ADV message represents the type
of indicating the fragmentation of the MOB_NBR-ADV message. When the
fragmentation of the MOB_NBR-ADV message is expressed by the number of all
of the neighbor BSs, i.e. by the quantity of neighbor BS information, the
indication type is expressed in the 'TOT_N_NEIGHBORS' field and the
'Fragmentation Mode' field is set to '1'. Further, when the fragmentation of the
MOB_NBR-ADV message is expressed by the number of the fragmented
MOBNBR-ADV messages, the 'Fragmentation Mode' field is set to '0'.
When the 'Fragmentation Mode' field has been set to '1', the
'TOT_N_NEIGHBORS' field represents the number of all of the neighbor BSs to
which the serving BS broadcasts the MOBNBR-ADV message, and the
'N_NEIGHBORS' field of 8 bits represents the number of the neighbor BSs of
which BS information is transmitted by the fragmented MOBNBR-ADV
message, i.e. the quantity of the neighbor BS information. When the number of
neighbor BSs of which BS information is transmitted by the 'N_NEIGHBORS'
field of the fragmented MOB_NBR-ADV message, i.e. the quantity of the
neighbor BS information, is less than the number of all of the neighbor BSs
transmitted by the TOT_N_NEIGHBORS' field, i.e. the quantity of all of the
neighbor BS information, the MS must continue to receive the remaining
fragmented MOBNBR-ADV messages in order to obtain information of the
remaining neighbor BSs.
Meanwhile, the 'Fragmentation Mode' field has been set to '0', it is
necessary to differentiate the fragmented MOBNBR-ADV messages. Therefore,
the 'Start bit' field represents transmission of the first fragmented MOBNBR-
ADV message and is set to ' 1' in the first fragmented MOBNBR-ADV message.
In other words, the 'Start bit' field is set to '0' in the other fragmented
MOBNBR-ADV messages than the first fragmented MOB_NBR-ADV message.
The 'Number of Remaining Fragments' field represents the number of the other
fragmented MOBNBR-ADV messages which the MS must receive.
Further, the MOB_NBR-ADV message includes a 'TLV Encoded
Neighbor information' field of variable bits representing TLV-encoded
information of the neighbor BSs, a 'DCD Configuration Change Count' field
representing a Downlink Channel Descriptor (DCD) change count for
configuration of the MOBNBR-ADV message, a 'UCD Configuration Change
Count' field representing an Uplink Channel Descriptor (UCD) change count for
configuration of the MOB_NBR-ADV message, a 'Length' field of 8 bits
representing the length of the neighbor BS information included in the
'N_NEIGHBOR' field, a 'Neighbor BS-ID' field of 48 bits representing the IDs

of the neighbor BSs, a 'Preamble Index' field of 8 bits representing the preamble
index, and an 'HO Process Optimization' field of 8 bits representing optimization
of the handoff process.
Hereinafter, a method for fragmenting the MOBNBR-ADV message
including the neighbor BS information into fragmented MOBNBR-ADV
messages each having a size able to be transmitted in one frame, which uses a
configuration of newly defined MOBNBR-ADV messages, will be described.
FIG. 3 illustrates a method of fragmenting the MOBNBR-ADV message
into fragmented MOBNBR-ADV messages each having a size transmittable in
one frame according to an embodiment of the present invention.
Referring to FIG. 3, when the serving BS has too many neighbor BSs and
too much neighbor BS information, the original MOB_NBR-ADV message 310
has a size exceeding a preset size of one frame 309. When the original
MOBNBR-ADV message 310 has a size exceeding a preset size of one frame
309, it is impossible to transmit the original MOBNBR-ADV message 310 in
one frame 309.
However, in the present invention as described above, the original
MOBNBR-ADV message 310 is fragmented into a first MOB_NBR-ADV
message 320 and a second MOB_NBR-ADV message 330. The original
MOBNBR-ADV message 310 includes a 'Management Message Type' field 301
representing the type of the message, an 'Operator ID' field 303 representing the
ID of the operator, a field 305 representing information of the neighbor BSs and
including the 'NNEIGHBORS' field representing the number of all neighbor
BSs transmitted by one frame 309, and an 'HMAC Tuple' field 307. As described
herein, it is assumed that the number of neighbor BSs included in the
'N_NEIGHBORS' field of the original MOB_NBR-ADV message 310 is 24 and
the field 305 representing information of the neighbor BSs and including the
'N_NEIGHBORS' field includes information of 24 neighbor BSs.
According to the present invention, the original MOBNBR-ADV
message 310 is fragmented into fragmented messages each having a size not
exceeding the size of one frame 327, for example, into the first MOBNBR-ADV
message 320 and the second MOBNBR-ADV message 330. The first
MOBNBR-ADV message 320, one of the fragmented messages, includes the
'Management Message Type' field 301 representing the same message type as
that included in the original MOB_NBR-ADV message 310, the 'Operator ID'
field 303 representing the ID of the operator and the 'HMAC Tuple' field 307.
Further, the first MOBNBR-ADV message 320 includes a
'Fragmentation Index' field 321, a 'Total Fragmentation' field 323 and a field 325

representing information of the neighbor BSs and including the
'N_NEIGHBORS' field representing the number of all of the neighbor BSs
included in the first MOBNBR-ADV message 320. The 'Fragmentation Index'
field 321 represents an index of the first MOBNBR-ADV message 320 which is
transmitted by the current frame 327, which represents that the MOBNBR-ADV
message transmitted by the current frame 327 from among the fragmented
MOBNBR-ADV messages (i.e. the first MOB_NBR-ADV message 320 and the
second MOB_NBR-ADV message 330) is the first MOBNBR-ADV message
320. The 'Total Fragmentation' field 323 represents the number of all of the
fragmented MOBNBR-ADV messages fragmented from the original
MOBNBR-ADV message 310 (in the case of FIG. 3, the 'Total Fragmentation'
field 323 is set to '2', because the first MOBNBR-ADV message 320 and the
second MOBNBR-ADV message 330 are all of the fragmented MOBNBR-
ADV messages). As used herein, it is assumed that the 'NNEIGHBORS' field of
the first MOBNBR-ADV message 320 includes 16 BSs so that the first
MOBNBR-ADV message 320 has a size not exceeding the size of the current
frame 327. Therefore, the field 325 representing information of the neighbor BSs
and including the 'N_NEIGHBORS' field includes 16 pieces of neighbor BS
information.
Further, the second MOBNBR-ADV message 330 is transmitted to the
MS by the next frame 337 directly after the first MOB_NBR-ADV message 320
is transmitted to the MS by the current frame 327. The second MOB_NBR-ADV
message 330 includes the same 'Management Message Type' field 301 as that
include in the first MOBNBR-ADV message 320, the 'Operator ID' field 303
representing the ID of the operator and the 'HMAC Tuple' field 307. Further, the
second MOBNBR-ADV message 330 includes a 'Fragmentation Index' field
331 representing that the MOB_NBR-ADV message transmitted by the next
frame 337 from among the fragmented MOBNBR-ADV messages (i.e. the first
MOB_NBR-ADV message 320 and the second MOB_NBR-ADV message 330)
is the second MOBNBR-ADV message 330.
As does the first MOB_NBR-ADV message 320, the second MOBNBR-
ADV message 330 further includes a 'Total Fragmentation' field 333 and a field
335 representing information of the neighbor BSs and including the
'N_NEIGHBORS' field representing the number of all of the neighbor BSs
included in the second MOBNBR-ADV message 330. The 'Total Fragmentation'
field 333 represents the number of all of the fragmented MOBNBR-ADV
messages fragmented from the original MOBNBR-ADV message 310 (in the
case of FIG. 3, the 'Total Fragmentation' field 333 is set to '2', because the first

MOBNBR-ADV message 320 and the second MOBNBR-ADV message 330
are all of the fragmented MOBNBR-ADV messages). According to the
assumption that the 'N_NEIGHBORS' field of the first MOB_NBR-ADV
message 320 includes 16 BSs so that the first MOB_NBR-ADV message 320 has
a size not exceeding the size of the current frame 327, 16 pieces of neighbor BS
information have already been transmitted to the MS by the first MOBNBR-
ADV message 320. As a result, the "N_NEIGHBORS' field of the second
MOBNBR-ADV message 330 transmitted to the MS by the next frame 337
includes 8 BSs remaining after transmission of the first MOBNBR-ADV
message 320 and the field 335 representing information of the neighbor BSs and
including the 'N_NEIGHBORS' field includes 8 pieces of neighbor BS
information.
Although the above description is based on an assumption that the first
MOBNBR-ADV message 320 includes 16 pieces of neighbor BS information so
that the first MOBNBR-ADV message 320 has a size not exceeding the size of
the current frame 327, the first MOBNBR-ADV message 320 may include a
different number of neighbor BSs, which changes the number of neighbor BSs
included in the second MOBNBR-ADV message 330. Further, according to the
present invention, when the second MOBNBR-ADV message 330 has a size
greater than that of the next frame 337, the original MOBNBR-ADV message
310 may be fragmented into three or more fragmented MOBNBR-ADV
messages and the fragmented MOBNBR-ADV messages may be transmitted to
the MS by frames the number of which corresponds to the number of the
fragmented MOBNBR-ADV messages.
In this case, each of the fragmented MOBNBR-ADV messages includes
the fields as described above. When the serving BS fragments the MOBNBR-
ADV message, the fragmentation is based on the size of one frame so that each of
the fragmented MOBNBR-ADV messages has a size not greater than the size of
one frame and the number of BSs included in the field representing the neighbor
BS information and including the 'NNEIGHBORS' field does not exceed the
number of BSs transmittable in one frame. Further, each of the fragmented
MOB_NBR-ADV messages commonly includes a 'Management Message Type'
field having the same value, an 'Operator ID' field representing an ID of an
operator, and an 'HMAC Tuple' field.
Further, the serving BS inserts the number of fragmented MOBNBR-
ADV messages into the 'Total Fragmentation' field, inserts an index of the current
fragmented MOBNBR-ADV message transmitted by the current frame into the
'Fragmentation Index' field, inserts information of neighbor BSs into the

corresponding field, and then transmits the current fragmented MOB_NBR-ADV
message to the MS.
Although the above description discusses the case of broadcasting the
MOB_NBR-ADV message in order for a serving BS to notify neighbor BS
information to an MS, the present invention can be applied to the formation and
transmission of other broadcast messages from the serving BS to the MS as well
as the MOBNBR-ADV message. Hereinafter, an operation of a serving BS for
forming and transmitting a broadcast message including neighbor BS information
will be described.
FIG. 4 is a flowchart of a process according to an embodiment of the
present invention, in which a serving BS forms and transmits a broadcast message
including information of neighbor BSs.
In step 401, the serving BS scans and collects information of neighbor
BSs to transmit to an MS. In step 403, the serving BS compares the collected
information of neighbor BSs with the size of the frame for carrying the collected
information of neighbor BSs to the MS. When the collected information of
neighbor BSs has a size not greater than the size of one frame, the serving BS
proceeds to step 409, in which the serving BS constructs a broadcast message
including the collected information and transmits the constructed broadcast
message to the MS in one frame. Upon receiving the broadcast message through
one frame, the MS obtains the information of the neighbor BSs included in the
broadcast message. Therefore, the BWA system supports the handoff of the MS.
When the collected information of neighbor BSs has a size greater than
the size of one frame as a result of the determination in step 403, the serving BS
proceeds to step 405, in which the serving BS divides the broadcast message
including the collected information into fragmented broadcast messages each
having a size not greater than the size of the frame.
Then, in step 407, the serving BS sets up the fields constituting the
fragmented broadcast message. For example, when the broadcast message has
been divided into two fragmented MOBNBR-ADV messages in step 405, the
'Total Fragmentation' fields of the two fragmented MOB_NBR-ADV messages
as shown in Table 1, which represent the number of all of the fragmented
MOBNBR-ADV messages, are set to have the same binary value of '0010'.
Further, the 'Fragmentation Index' field of the first fragmented MOBNBR-ADV
message from among the two fragmented MOB_NBR-ADV messages, which
represents an index of the first fragmented MOBNBR-ADV message carried by
the first frame, is set to have a value of '0001', and the 'Fragmentation Index'
field of the second fragmented MOBNBR-ADV message carried by the second

frame is set to have a value of '0010'. Then, in step 409, the serving BS transmits
the fragmented broadcast message including the setup fields to the MS in the
corresponding frame. When the broadcast message has been divided into two
fragmented broadcast messages, the serving BS transmits the two fragmented
broadcast messages in two frames.
The MS sequentially receives the fragmented broadcast messages as
described above in the corresponding number of frames. Specifically, when the
received broadcast messages are fragmented MOBNBR-ADV messages, the MS
recognizes the field values of the fragmented MOBNBR-ADV messages and
checks the value of the 'Total Fragmentation' field representing the number of all
of the fragmented MOBNBR-ADV messages, thereby determining if the
MOBNBR-ADV message transmitted by the current frame is a fragmented
MOBNBR-ADV message.
For example, when the 'Total Fragmentation' field of the currently
received MOB_NBR-ADV message has a value of '0000', it implies the currently
received MOB_NBR-ADV message is not a fragmented MOB_NBR-ADV
message. Further, the MS can obtain information of neighbor BSs from the
currently received MOBNBR-ADV message by decoding the currently received
MOBNBR-ADV message. When the 'Total Fragmentation' field of the currently
received MOBNBR-ADV message has any value other than '0000', the MS
recognizes the number of all the fragmented MOB_NBR-ADV messages from the
value of the 'Total Fragmentation' field and waits for reception of the next
fragmented MOBNBR-ADV message to be transmitted in the next frame. That
is, the MS receives the fragmented MOBNBR-ADV messages by sequentially
transmitted multiple frames and obtains information of neighbor BSs by decoding
the received fragmented MOBNBR-ADV messages. Also, the MS can obtain
information of all of the neighbor BSs broadcast by the serving BS, by receiving
all of the fragmented MOB_NBR-ADV messages.
In a BWA communication system according to the present invention as
described above, a serving BS can collect information of neighbor BSs, form a
broadcast message including the information of the neighbor BSs, and fragment
the broadcast message if the broadcast message is too large. Therefore, the
serving BS can transmit a large amount of neighbor BS information to the MS. As
a result, a BWA communication system according to the present invention can
support handoff of an MS moving between cells because it is possible to transmit
a large amount of neighbor BS information to the MS in the system.
While the invention has been shown and described with reference to
certain preferred embodiments thereof, it will be understood by those skilled in

the art that various changes in form and details may be made therein without
departing from the spirit and scope of the invention as defined by the appended
claims.

WE CLAIM :
1. A method for transmitting to a mobile station (150) information of
neighbor base stations by a base station (121-133) in a communication
system, the method comprising the steps of:
setting, (407) by a Controller of the base station, a value of each of a
plurality of fields comprised in each of m fragments on the information of
the neighbor base station; and
Sequentially transmitting, by the base station, each of the m fragments of
the information of the neighbor base stations to the mobile station (150);
wherein the m fragments are generated by fragmenting a broadcast
message comprising the information of the neighbor base stations into m
fragments, wherein the plurality of fields comprise in each of the m
fragments a first field, a second field, and a third field, the first field
indicates a fragmentation index for a current fragment, the second field
indicates a total number of fragments equal to m, where m is an integer
greater than or equal to 1, and the third field indicates a number of the
neighbor base stations comprised in the current fragment, wherein the
current fragmentation comprises identifiers of the neighbor base stations
comprised in the information of the current fragment, wherein the
current fragment comprises physical frequencies for the neighbor base
stations comprised in the information of the current fragmentation, and
wherein the plurality of fields comprise an operator identifier, ID field and
a Configuration Change Count field which is incremented each time when
information for an associated neighbor base station has changed.

2. The method as claimed in claim 1, wherein the communication system is a
Broadband Wireless Access (BWA) communication system which uses an
Orthogonal Frequency Division Multiple Access (OFDMA) scheme using a
plurality of sub-carriers, and supports a multi-cell structure and a mobility
of a mobile station so that the mobile station obtains the information on
the neighbor base stations by receiving the information of neighbor base
stations from a serving base station, and the mobile station may perform
a handoff process on moving to another cell after preliminarily obtaining
the information on the neighbor base stations.
3. The method as claimed in claim 1, wherein the plurality of fields comprise
a Downlink Channel Descriptor (DCD) Configuration Change Count field
representing a DCD change count for the neighbor base stations
comprised in the current fragment, and a Uplink Channel Descriptor (UCD)
Configuration Change Count field representing a UCD change count for
the neighbor base stations comprised in the current fragmentation.
4. The method as claimed in claim 1, wherein the plurality of fields comprise
a preamble index representing a preamble index and a handoff
optimization field representing optimization of the handoff process.
5. A method for receiving information on neighbor base stations (121-133)
by a mobile station (150) in a communication system, the method
comprising the steps of: sequentially receiving by the mobile station, m
fragments of the information on the neighbor base stations from a base
station;

wherein the m fragments are generated, by the base station, by
fragmenting a broadcast message comprising the information on the
neighbor base stations into m fragments, wherein a plurality of fields
comprised in each of the m fragments a first field, a second field, and a
third field, the plurality of fields are comprised in each of the m fragments
of the information on the neighbor base stations, the first field indicates a
fragmentation index for a current fragment, the second field indicates a
total number of fragments equal to m, where m is an integer greater than
or equal to 1, and the third field indicates a number of the neighbor base
stations comprised in the current fragment, wherein the current
fragmentation comprise identifiers of the neighbor base stations
comprised in the information of the current fragmentation, wherein the
current fragmentation comprises physical frequencies for the neighbor
base stations comprised in the current fragment; and
wherein the plurality of fields comprise an operator ID field and a
Configuration Change Count field which is incremented each time when
information for an associated neighbor base station has changed.
6. The method as claimed in claim 5 wherein the communication system is a
Broadband Wireless Access (BWA) communication system which uses an
Orthogonal Frequency Division Multiple Access (OFDMA) scheme using a
plurality of sub-carriers, and supports a multi-cell structure and a mobility
of the mobile station so that the mobile station obtains the information of
the neighbor base stations by receiving the information on the neighbor
base stations from a serving base station, and the mobile station may
perform a handoff process on moving to another cell after preliminarily
obtaining the information on the neighbor base stations.

7. The method as claimed in claim 5, wherein the plurality of fields comprise
a Downlink Channel Descriptor (DCD) Configuration Change Count field
representing a DCD change count for the neighbor base station comprised
in the current fragment, and an Uplink Channel Descriptor (UCD)
Configuration Change Count field representing (UCD) change count for the
neighbor base stations comprised in the current fragment.
8. The method as claimed in claim 8, wherein the plurality of fields comprise
a preamble index representing a preamble index and a handoff
optimization field representing optimization of the handoff process for an
associated neighbor base station.
9. A mobile station MS (150) in a communication system, comprising:
a receiver for sequentially receiving each of m fragmentations of
information on the neighbor base stations from the base station,
wherein the m fragmentations are generated, by the base station, by
fragmenting a broadcast message comprising the information of the
neighbor base stations into m fragmentations, and a plurality of the fields
comprise a first field, a second field, and a third field in the each of m
fragmentations, the plurality of fields are comprised in each of m
fragmentations of the information on the neighbor base stations, the first
field indicates a fragmentation index for a current fragmentation, the
second field indicates a total number of fragmentation equal to m, where
m is an integer equal to or greater than 1, and the third field indicates a
number equal to the number of the neighbor base stations comprised in
information on the current fragmentation;

wherein the current fragment comprises identifiers of the neighbor base
stations comprised in the information of the current fragment;
wherein the current fragment comprises physical frequencies for the
neighbor base stations comprised in the information of the current
fragment, and
wherein the plurality of fields comprise an operator identifier ID field and
a Configuration Change Count field which is incremented each time when
information for an associated neighbor base station has changed.
10. The mobile station as claimed in claim 9, wherein the communication
system is a Broadband Wireless Access (BWA) communication system
which uses an Orthogonal Frequency Division Multiple Access (OFDMA)
scheme using a plurality of sub-carriers, and supports a multi-cell
structure and a mobility of the mobile station so that the mobile station
obtains the information on the neighbor base stations by receiving the
information on the neighbor base stations from a serving base station,
and the mobile station may perform a handoff process on moving to
another cell after preliminarily obtaining the information on the neighbor
base stations.
11. The mobile station as claimed in claim 9, wherein the plurality of fields
comprise a Downlink Channel Descriptor (DCD) Configuration Change
Count field representing a DCD change count for the neighbor base
stations comprised in the current fragment, and an Uplink Channel
Description (UCD) Configurartion Change Count filed representing a UCD
change count for the current fragment.

12. The mobile station as claimed in claim 9, wherein the plurality of fields
comprise a preamble index representing a preamble index and a handoff
optimization field representing optimization of the handoff process for an
associated neighbor base station.
13. A base station BS (121-133) in a communication system, the base station
comprising:
a controller for setting a value of each of a plurality of fields comprised in
each of m fragments of information on the neighbor base stations; and
a transmitter for sequentially transmitting to the mobile station each of
the m fragments of the information on the neighbor base stations into m
fragments, wherein the plurality of fields comprised in each of the m
fragments a first field, a second field, a third field, the first field indicates
a fragmentation index for a current fragment, the second field indicates a
total number of fragments equal to m, where m is an integer greater than
or equal to 1, and the third field indicates a number of the neighbor base
stations comprised in the current fragment, wherein the current
fragmentation comprises identifiers of the neighbor base stations
comprised in the information of the current fragment;
wherein the current fragment comprises physical frequencies for the
neighbor base stations comprised in the information of the current
fragment, and
wherein the plurality of fields comprise an operator identifier, ID field and
a Configuration Change Count field which is incremented each time when
information for an associated neighbor base station has changed.

14. The base station as claimed in claim 13, wherein the communication
system is a Broadband Wireless Access (BWA) communication system
which uses an Orthogonal Frequency Division Multiple Access (OFDMA)
scheme using a plurality of sub-carriers and supports a multi-cell structure
and a mobility of the mobile station so that the mobile station obtains the
information on the neighbor base stations by receiving the information on
the neighbor base stations from a serving base station, and the mobile
station may perform a handoff process on moving to another cell after
preliminarily obtaining the information on the neighbor base stations.
15. The base station as claimed in claim 13, wherein the plurality of fields
comprise a Downlink Channel Descriptor (DCD) Configuration Change
Count field representing a DCD change count for the current fragment,
and an Uplink Channel Descriptor (UCD) Configuration Change Count field
representing a UCD change count for the current fragment.
16. The base station as claimed in claim 13, wherein the plurality of fields
comprise a preamble index representing a preamble index, and a handoff
optimization field representing optimization of the handoff process.

ABSTRACT

TITLE "A METHOD AND APPARATUS FOR BROADCASTING
AND RECEIVING INFORMATION OF NEIGHBOR BASE
STATIONS IN A COMMUNICATION SYSTEM"
The invention relates to a method for transmitting to a mobile station
(150) information of neighbor base stations by a base station (121-133) in
a communication system, the method comprising the steps of: setting,
(407) by a controller of the base station, a value of each of a plurality of
fields comprised in each of m fragments of the information on the
neighbor base station; and sequentially transmitting, by the base station,
each of the m fragments of the information of the neighbor base stations
to the mobile station (150); wherein the m fragments are generated by
fragmenting a broadcast message comprising the information of the
neighbor base stations into m fragments, wherein the plurality of fields
comprise in each of the m fragments a first field, a second field, and a
third field, the first field indicates a fragmentation index for a current
fragment, the second field indicates a total number of fragments equal to
m, where m is an integer greater than or equal to 1, and the third field
indicates a number of the neighbor base stations comprised in the current
fragment, wherein the current fragmentation comprises identifiers of the
neighbor base stations comprised in the information of the current
fragment, wherein the current fragment comprises physical frequencies
for the neighbor base stations comprised in the information of the current
fragmentation, and wherein the plurality of fields comprise an operator
identifier, ID field and a Configuration Change Count field which is
incremented each time when information for an associated neighbor base
station has changed.

"A METHOD AND APPARATUS FOR BROADCASTING AND RECEIVING INFORMATION OF NEIGHBOR BASE STATIONS IN A COMMUNICATION SYSTEM"

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