KR100985156B1 - Apparatus and method for allocation resource in a multi sector communication system - Google Patents

Abstract

The present invention is to identify the channel state of a plurality of mobile stations present in a plurality of sectors in a given cell in order to support diversity in a communication system having a multi-sector structure, and to determine the channel state of the mobile station. Correspondingly, it is determined whether diversity support is required for the mobile station, and if it is determined that diversity support is required, a diversity area is allocated to a serving sector frame and a diversity sector frame of the mobile station, and the serving sector frame and the A burst is assigned to each diversity area of the diversity sector frame.

Description

Apparatus and method for allocation resource in a multi sector communication system}

The present invention relates to a communication system, and more particularly, to an apparatus and method for allocating resources for supporting diversity in a communication system having a multi-sector structure.

The Institute of Electrical and Electronics Engineers (IEEE) 802.16 communication system uses Orthogonal Frequency Division Multiplexing (OFDM) to support a broadband transmission network on a physical channel of a wireless network system. ) Or a Orthogonal Frequency Division Multiple Access (OFDMA) scheme. The IEEE 802.16 communication system is a system that considers the mobility of the SS as well as the fixed subscriber station (SS) (hereinafter referred to as SS). Station, hereinafter referred to as 'MS').

In addition, the IEEE 802.16 communication system has a multi-cell structure or a multi-sector structure, and a plurality of cells or sectors divide and use a limited frequency resource. In this case, when a plurality of cells divide and use a limited frequency resource in an IEEE 802.16 communication system, inter-cell interference (ICI: Interfering Interval, hereinafter referred to as 'ICI') causes a performance degradation of the system. The frequency resource is reused to increase capacity. Here, if the frequency reuse factor (FRF: Frequency Reuse Factor (FRF)), which is determined according to frequency reuse, is greater than 1, the ICI is reduced to prevent performance degradation of the system, but is available in one cell. The amount of frequency resources is reduced, which reduces the overall capacity of the system. In addition, when the FRF is 1, since all cells constituting the IEEE 802.16 communication system use the same frequency resources, ICI increases and performance decreases. This increases.

Meanwhile, if the IEEE 802.16 communication system has a multi-sector structure and the FRF is 1, a resource allocation method for providing a service to an MS existing in each sector of each predetermined cell is required. In particular, a base station (BS), which manages the predetermined cell and provides a service to an MS, supports diversity when transmitting signals to the MS using a plurality of sector antennas. A specific resource allocation plan is needed. In addition, there is a need for a specific resource allocation scheme for supporting diversity in accordance with a communication environment in each sector, for example, a communication environment of MSs provided and serviced in each sector.

Accordingly, an object of the present invention is to provide an apparatus and method for allocating resources for diversity support corresponding to a communication environment in each sector in a communication system having a multi-sector structure.

Another object of the present invention is to provide a diversity zone and a diversity zone for supporting diversity in accordance with a communication environment of mobile stations which are provided within each sector and provided with a service in a communication system having a multi-sector structure. A resource allocation device and method for allocating a diversity burst are provided.

The method of the present invention for achieving the above objects comprises the steps of: checking the channel status of a plurality of mobile stations present in a plurality of sectors in a given cell; Determining whether diversity support is required for the mobile station according to the channel state of the mobile station; Allocating a diversity area to a serving sector frame and a diversity sector frame of the mobile station if the diversity support is determined to be necessary; And assigning a burst to each diversity region of the serving sector frame and the diversity sector frame, respectively.

Another method of the present invention for achieving the above object comprises the steps of: verifying the channel status of a plurality of mobile stations present in a plurality of sectors in a given cell; Determining whether to transmit a signal using a diversity sector antenna to the mobile station in accordance with the channel state of the mobile station; If it is determined that signal transmission using the diversity sector antenna is necessary, a diversity area is allocated to a serving sector frame and a diversity sector frame of the mobile station, and if it is determined that signal transmission using the diversity sector antenna is unnecessary, the serving is performed. Allocating a normal region to a sector frame; And when it is determined that signal transmission using the diversity sector antenna is necessary, a burst is allocated to each of the diversity regions of the serving sector frame and the diversity sector frame, and it is determined that signal transmission using the diversity sector antenna is unnecessary. And assigning the burst to a normal region of the serving sector frame.

An apparatus of the present invention for achieving the above objects comprises a receiver for receiving channel quality information (CQI) from a plurality of mobile stations present in a plurality of sectors in a given cell; A confirmation unit for confirming a channel state of the mobile station through the received CQI; A determining unit determining whether diversity support is required for the mobile station according to the checked channel state of the mobile station; And when the determining unit determines that the diversity support is required, allocates a diversity region to the serving sector frame and the diversity sector frame of the mobile station, and then bursts the diversity regions of the serving sector frame and the diversity sector frame. It includes a scheduler for assigning each.

Another apparatus of the present invention for achieving the above objects is to provide a diversity area to a serving sector frame and a diversity sector frame of the mobile station when the channel state of the mobile station located in the multi-sector is determined to require diversity support. And assigning a burst for the mobile station to each diversity region of the serving sector frame and the diversity sector frame so that signal transmission is made to the mobile station through at least two diversity sector antennas.

In the multi-sector communication system, the present invention checks the channel state of a mobile station existing in each sector to determine whether diversity support is required for the mobile station, and performs scheduling according to the determination. Correspondingly, diversity of a multi-sector communication system can be supported. In particular, the present invention, by assigning the diversity area to the frame of the serving sector and the frame of the diversity sector to support the diversity to the mobile station, and by assigning a burst of the mobile station to the same position of the diversity area, respectively Diversity to mobile stations can be supported.

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

The present invention relates to an apparatus and method for allocating resources in an Institute of Electrical and Electronics Engineers (IEEE) 802.16 communication system, which is a communication system, for example, a broadband wireless access (BWA) communication system. Suggest. Here, in the embodiment of the present invention to be described later, orthogonal frequency division multiplexing (OFDM) / orthogonal frequency division multiple access (OFDM) in the IEEE 802.16 communication system for convenience of description. Although a communication system employing an Orthogonal Frequency Division Multiple Access (OFDMA) scheme will be described as an example, the resource allocation apparatus and method proposed by the present invention can be applied to other communication systems. .

In addition, the present invention is a base station (BS) that manages a predetermined cell in a communication system (hereinafter, referred to as a "multi-sector communication system") to which a multi-sector structure is applied. The present invention proposes a resource allocation apparatus and method for supporting diversity when transmitting a signal to a mobile station (MS) located in multiple sectors of the predetermined cell. . In an embodiment of the present invention to be described later, the IEEE 802.16 communication system identifies a communication environment in each sector, and uses a plurality of sector antennas to transmit signals to MSs present in the sectors. Allocate resources to support diversity according to your environment. In the IEEE 802.16 communication system, a frequency reuse factor (FRF) of a multi-sector is 1 (hereinafter, referred to as 'FRF').

In this case, in the present invention, the BS receives channel quality information (CQI: hereinafter referred to as 'CQI') from MSs present in the respective sectors, and the channel state of the MSs through the CQI. Check each of them. In addition, the BS determines whether diversity support is required for each MS based on channel states of the MSs, and the BS scheduler determines a diversity zone to support diversity to MSs requiring diversity support. And a diversity burst are allocated to the frames corresponding to the sectors. In this case, the diversity area is an area allocated to a burst area of a frame in order to support an inter-sector transmit diversity function. In addition, the present invention checks the channel status of each MS and allocates resources to support diversity by transmitting signals to the MSs through all sector antennas or one or more some sector antennas including the corresponding sector antennas.

Here, in the IEEE 802.16 communication system according to an embodiment of the present invention to be described later, the time and frequency of the serving sector and candidate sectors for a predetermined MS of a plurality of sectors are synchronized. In this case, when the BS provides a communication service to an MS currently existing in a predetermined sector, the serving sector means the predetermined sector in which the MS currently exists, and the candidate sector supports the diversity of the BS to the MS. This means all possible sectors, and the diversity sector means a sector in which the BS transmits the same signal as the signal currently transmitted from the serving sector to the MS.

In the IEEE 802.16 communication system, a path delay difference value between all sectors in one cell is smaller than a cyclic prefix (CP), and the BS manages a predetermined value. The MSs present in each sector of the cell of the cell support the functionality associated with dedicated pilots. For example, the MSs measure a channel state through a pilot included in a transmission signal of a BS to generate a CQI, and then feed back the CQI to the BS. Next, a communication system according to an exemplary embodiment of the present invention will be described in detail with reference to FIG. 1.

1 is a view schematically showing the structure of a communication system according to an embodiment of the present invention.

Referring to FIG. 1, in a communication system, a cell 100 is divided into a plurality of sectors, for example, sector 1 110, sector 2 120, and sector 3 130, and the cell 100. BS 102 that manages the MS 102, and MS1 112, MS2 122, and MS3 132 that exist within the sectors 110, 120, and 130 and receive services from the BS 102. Here, the MSs 112, 122, and 132 have both mobility and fixedness. Signal transmission and reception between the BS 102 and the MSs 112, 122, and 132 are performed using the OFDM / OFDMA scheme.

In addition, the BS 102 includes sector antennas that transmit signals to the MSs 112, 122, and 132 present in the sectors 110, 120, and 130, and the scheduler of the BS 102 is a channel of the MSs 112, 122, and 132. Depending on the state, the BS 102 allocates resources to enable signal transmission to the MSs 112, 122, 132 via one or more diversity sector antennas, including the serving sector antennas of the MSs 112, 122, 132. That is, the scheduler of the BS 102 allocates a diversity area to a frame to support diversity to the MSs 112, 122, and 132 according to the channel states of the MSs 112, 122, and 132 in the sectors 110, 120, and 130. In addition, a burst of an MS requiring diversity support is allocated to the diversity area. In this case, the scheduler of the BS 102 allocates not only the diversity region but also the normal zone to the frame, and allocates bursts of MSs that do not require diversity support to the normal region. Next, a resource allocation apparatus for supporting diversity by checking the channel state of the MS in the communication system according to the embodiment of the present invention will be described in more detail with reference to FIG. 2.

2 is a diagram schematically illustrating a structure of a resource allocation apparatus of a BS in a communication system according to an embodiment of the present invention.

Referring to FIG. 2, the resource allocation apparatus 200 of the BS 102 may include a receiver 210 that receives a CQI from MSs 112, 122, and 132 existing in the cell 100, and the received CQI through the received CQI. Diversity determination for determining whether to support diversity of the MSs 112, 122, and 132 according to the channel state checker 220 for checking the channel states of the MSs 112, 122, and 132 and the channel states of the MSs 112, 122, and 132; A unit 230 and a scheduler 240 for allocating bursts of the MSs 112, 122, and 132 according to the determination of the diversity determiner 230.

The receiver 210 receives CQIs from the MSs 112, 122, and 132 through a feedback channel, respectively. The MSs 112, 122, and 132 may use a carrier to interference noise ratio (CINR) in a DL using a strength of a signal received in downlink (DL, hereinafter referred to as 'DL'), for example, a pilot. Noise ratio, hereinafter referred to as "CINR"). The MSs 112, 122, and 132 check the channel state through the measured CINR, and then generate a CQI corresponding to the channel state and transmit the CQI to the BS 102, respectively. Then, the receiving unit 210 receives the CQIs transmitted by the MSs 112, 122, and 132, and the channel state checking unit 220 uses the CQIs received by the receiving unit 210 of each of the MSs 112, 122, and 132. The diversity state determiner 230 determines whether diversity support is required for each of the MSs 112, 122, and 132 according to the checked channel state of the MSs 112, and the scheduler 240 The scheduling is performed according to the determined diversity support.

In this case, the diversity determiner 230 determines whether diversity support is required for each of the MSs 112, 122, and 132 according to the channel state of the MSs 112, 122, and 132, and includes a first scheme, a second scheme, or a third scheme. A method is used to transmit a signal to each of the MSs 112, 122, and 132 using a scheme. In other words, the diversity determiner 230, if the MS can successfully receive the signal even though the MS transmits a signal to the MS through only the sector antenna, the MS determines the MS using the first scheme. Determine to send a signal. The diversity determiner 230 transmits a signal to the MS through a corresponding sector antenna and some sector antennas, and if the MS can successfully receive the signal, the diversity method uses the second scheme. Decide to send a signal to the MS. In addition, the diversity determiner 230 determines that the MS transmits a signal to the corresponding MS using the third scheme if the MS can successfully receive the signal after transmitting signals through all sector antennas. . Here, the first scheme transmits a signal to the MS through only a sector antenna (hereinafter, referred to as a 'serving sector antenna') of a serving sector corresponding to the MS to transmit a signal to the MS through only the corresponding sector antenna. That's the way it is. In the second scheme, a sector antenna (hereinafter, referred to as 'diversity sector antenna') of a diversity sector among the serving sector antenna and candidate sectors of the MS to transmit a signal to the MS through the corresponding sector antenna and some sector antennas. The signal is transmitted to the MS through the MS. In addition, the third method transmits a signal to the MS through a serving sector antenna of the MS and a sector antenna of a candidate sector (hereinafter referred to as a 'candidate sector antenna') to transmit signals through all sector antennas. That's the way.

Then, the scheduler 240 divides the burst region of the frame into a normal region and a diversity region according to the determination of the diversity determiner 230 for each MS 112, 122, and 132 as described above. In addition, the burst of the MS requiring diversity support is allocated to the diversity area, and the burst of the MS not requiring diversity support is allocated to the normal area. In this case, the MS requiring diversity support is an MS in which a BS transmits a signal to the MS through a second scheme or a third scheme as described above. The MS sends a signal to the MS. Hereinafter, for convenience of description, the MS1 112 existing in the sector 1 110 will be described in more detail.

The receiver 210 receives the CQI from the MS1 112 and the diversity checker 220 checks the CINR of the MS1 112 included in the CQI. Then, the diversity determiner 230 compares the CINR with a first threshold value or a second threshold value. Here, the CINR indicates the channel state of the MS1 112 in the serving sector in which the MS1 112 is registered when the network enters and currently provides the service to the MS1 112. In other words, since the sector 1 110 is a serving sector of the MS 1 112, the CINR is a CINR measured by the MS 1 112 in the sector 1 110 and represents a channel state of the MS 1 112.

The diversity determiner 230 compares the CINR of the serving sector signal transmitted by the sector antenna corresponding to the sector 1 110, which is the serving sector of the MS 1 112, with the first threshold. In this case, the diversity determiner 230 determines that diversity support is required to the MS1 112 when the CINR of the serving sector signal is smaller than the first threshold. In other words, when the channel state of the MS1 112 is poor in the sector 1 110 and the MS1 112 transmits a signal to the MS1 112 through the first scheme, the MS1 112 cannot receive the signal successfully. As the MS, the diversity determiner 230 determines to transmit a signal to the MS1 112 using the second method or the third method.

In addition, the diversity determiner 230 compares the CINR of the candidate sector signal transmitted by a sector antenna corresponding to sector 2 120 or sector 3 130, which is a candidate sector, with the second threshold. In this case, the diversity determiner 230 determines that diversity support is required to the MS1 112 when the CINR of the candidate sector signal is greater than the second threshold. That is, when the candidate sector antenna transmits a signal to the MS1 112 because the state of the channel formed between the candidate sector antenna and the reception antenna of the MS1 112 is excellent, the MS1 112 successfully receives the signal. As the MS, the diversity determiner 230 determines to transmit a signal to the MS1 112 through the candidate sector antenna.

Here, the diversity determiner when the CINR of the candidate sector signal transmitted by the sector antenna of the sector 2 120 and the CINR of the candidate sector signal transmitted by the sector antenna of the sector 3 130 are greater than the second threshold. 230 determines to transmit the signal in a third manner. That is, the diversity determiner 230 determines to transmit a signal to the MS1 112 through the sector antennas of the sector 1 110, the sector 2 120, and the sector 3 130. In addition, when the CINR of one candidate sector signal among the CINRs of the two candidate sector signals is greater than the second threshold value, the diversity determiner 230 determines to transmit the signal in a second manner. For example, if only the CINR of the candidate sector signal transmitted by the sector antenna of the sector 2 120 is greater than the second threshold, the diversity determiner 230 may determine the sector antenna and sector 2 120 of the sector 1 110. To transmit a signal to the MS1 112 via a sector antenna.

In addition, the diversity determiner 230, if there is a resource available in at least one candidate sector for diversity transmission support, or if the MS1 112 is not the MS that is entering or handing over an initial network, MS1 112 determines that diversity support is required.

As described above, when the diversity determiner 230 needs the diversity support to the MS1 112, the scheduler 240 selects a frame from the normal region according to the determination of the diversity determiner 230. The allocation is performed by dividing into the diversity area, and the burst of the MS1 112 is allocated to the diversity area. In this case, the scheduler 240 divides the frame of the sector 1 (110) and the frame of the diversity sector into a normal area and a diversity area, respectively, and allocates the frame of the sector 1 (110) and the frame of the diversity sector. The burst of MS1 112 is allocated to the same position in the diversity region of.

More specifically, if the CINR of the signal transmitted by the sector antenna of the sector 1 (110) is smaller than the first threshold and the CINR of the signal transmitted by the sector antenna of the sector 2 (120) is greater than the second threshold The diversity determiner 230 determines to transmit a signal to the MS1 112 through the sector antennas of the sector 1 110 and the sector 2 120. The scheduler 240 allocates the normal region and the diversity region to the frame of the sector 1 110 and the frame of the sector 2 120, respectively, according to the determination of the diversity determiner 230. The burst of MS1 112 is allocated to the same position of each diversity area. In this case, the sector 1 110 is a serving sector of the MS 1 112 as described above, the sector 2 120 is a diversity sector of the MS 1 112, and is allocated to a frame of the sector 1 110. The burst of MS1 112 is a serving burst and the burst of MS1 112 assigned to the frame of sector 2 120 is a diversity burst.

In addition, if the CINR of the signal transmitted by the sector antenna of the sector 1 (110) is less than the first threshold and the CINR of the signal transmitted by the sector antenna of the sector 3 (130) is greater than the second threshold, the diversity The determination unit 230 determines to transmit a signal to the MS1 112 through the sector antennas of the sector 1 110 and the sector 3 130. The scheduler 240 allocates the normal region and the diversity region to the frame of the sector 1 110 and the frame of the sector 3 130, respectively, according to the determination of the diversity determiner 230. The burst of MS1 112 is allocated to the same position of each diversity area. Here, sector 1 110 is a serving sector of MS1 112 as described above, sector 3 130 is a diversity sector of MS1 112, and is assigned to a frame of sector 1 110. The burst of MS1 112 is a serving burst, and the burst of MS1 112 assigned to the frame of sector 3 130 is a diversity burst.

In addition, the CINR of the signal transmitted by the sector antenna of the sector 1 (110) is less than the first threshold and the CINR of the signal transmitted by the sector antenna of the sector 2 (120) and sector 3 (130) is a second threshold. If greater than the value, the diversity determiner 230 determines to transmit a signal to the MS1 112 through the sector antennas of the sector 1 110, the sector 2 120, and the sector 3 130. In addition, the scheduler 240 generates a normal region and a diversity region in the frame of the sector 1 110 and the frames of the sector 2 120 and the sector 3 130 according to the determination of the diversity determiner 230. After each assignment, a burst of the MS1 112 is assigned to the same location of each of the allocated diversity regions. Here, the sector 1 (110) is the serving sector of the MS1 (112) as described above, the sector 2 (120) and the sector 3 (130) is the diversity sector of the MS1 (112), the sector 1 ( The burst of MS1 112 assigned to the frame of 110 is a serving burst, and the burst of MS1 112 assigned to the frames of sector 2 120 and sector 3 130 is a diversity burst.

Here, the serving burst and the diversity burst are bursts in which the same signal is transmitted to the MS1 112. In other words, the serving burst and the diversity burst are bursts in which the DL signal of the MS1 112 is transmitted having the same modulation and coding scheme (hereinafter, referred to as 'MCS') level.

Then, the CINR of the signal transmitted by the serving sector antenna is greater than the CINR of the signal transmitted by the diversity sector antenna, and the CINR of the combined signal of the signal transmitted by the diversity sector antenna and the serving sector antenna is the third threshold value. If greater, the diversity determiner 230 determines that diversity support of the diversity sector is not necessary. That is, the diversity determiner 230 determines not to transmit a signal through the diversity sector antenna. The scheduler 240 releases the diversity burst allocated to the diversity area of the diversity sector according to the determination of the diversity determiner 230. Here, the first threshold value and the second threshold value are initially set according to the performance of the communication system and the communication environment, and the first threshold value may perform communication using only the serving sector antenna without the support of the diversity sector antenna. The second threshold value is a reference value for determining whether or not to support diversity sector antennas, and the third threshold value is a hysteresis margin (or a third threshold value). hysteresis margin).

In addition, the diversity determiner 230 determines that diversity support of some of the diversity sectors is unnecessary if there are no resources available in some of the diversity sectors. That is, the diversity determiner 230 determines not to transmit a signal through the sector antenna of the some diversity sectors. As described above, the scheduler 240 releases the allocation of diversity bursts allocated to the diversity regions of the some diversity sectors according to the determination of the diversity determiner 230.

For example, the CINR of the signal transmitted by the sector antenna of the sector 1 (110) is greater than the CINR of the signal transmitted by the sector antenna of the sector 2 (120) or sector 3 (130), the sector 2 (120) or sector 3 If the CINR of the combined signal of the signal transmitted by the sector antenna of the 130 and the sector 1 (110) is greater than the third threshold value, the diversity determiner 230 is the sector 2 (120) or sector 3 (130) Determine that diversity support is unnecessary, and not transmit a signal to MS1 112 through the sector antenna of sector 2 (120) or sector 3 (130). The scheduler 240 releases the burst allocation of the MS1 112 allocated to the diversity region of the sector 2 120 or the sector 3 130 according to the determination of the diversity determiner 230. . In addition, if there is no resource available in the sector 2 (120) or the sector 3 (130), the determination unit 230 is not necessary to support the diversity of the sector 2 (120) or sector 3 (130) And not transmitting a signal to MS1 112 through the sector antenna of sector 2 120 or sector 3 130. The scheduler 240 allocates the burst of the MS1 112 allocated to the diversity region of the frame of the sector 2 120 or the sector 3 130 according to the determination of the diversity determiner 230. Release it.

The MS1 112 transmits a handover indication message to release the connection with the cell 100, or the MS1 112 is an MS entering an initial network, or supports diversity transmission. If no resources are available in all diversity sectors, or no data is transmitted to the MS1 112 in the serving sector, the diversity determiner 230 supports diversity to the MS1 112. Determine this unnecessary. That is, the diversity determiner 230 determines not to transmit a signal through the sector antennas of all the diversity sectors. In addition, the scheduler 240 releases the burst allocation of the MS1 112 allocated to the diversity region of the frame of all the diversity sectors according to the determination of the diversity determiner 230, and then releases the burst of the sector 1 110. The burst of MS1 112 allocated to the diversity area of the frame is reassigned to the normal area of the frame of sector 1 110. That is, the scheduler 240 allocates the burst of the MS1 112 to the normal region of the frame of the sector 1 110 so as to transmit a signal to the MS 1 112 through only the sector antenna of the sector 1 110.

Meanwhile, the diversity determiner 230 determines that diversity support is unnecessary to the MS1 112 when the CINR is greater than the first threshold. In other words, the inter-cell interference (ICI: referred to as "ICI") of the adjacent cells in the sector 1 (110) is small, so that the channel state of the MS 1 (112) is good, and thus, through the first scheme. When the MS1 112 transmits a signal, the MS1 112 is an MS that successfully receives the signal. The diversity determiner 230 transmits the signal to the MS1 112 through the first scheme. Determine to send. The scheduler 240 allocates the burst of the MS1 112 to the normal region of the frame of the sector 1 110 according to the determination of the diversity determiner 230. Next, the frame structure in the communication system according to the embodiment of the present invention will be described in detail with reference to FIG. 3.

3 is a diagram schematically illustrating a frame structure in a communication system according to an embodiment of the present invention. 3 is a frame and diversity sector of a serving sector corresponding to each MSs formed by receiving a CQI from MSs present in each sector in one cell by a resource allocation apparatus of a BS according to an embodiment of the present invention. Figure of a frame.

Referring to FIG. 3, the apparatus for allocating resources checks channel states of respective MSs through CQIs received from MSs present in respective sectors, and diversity of MSs in correspondence with channel states of the respective MSs. It is determined whether support is required, and scheduling according to the determination forms a frame 300 of a serving sector and a frame 350 of a diversity sector corresponding to the respective MSs.

The frame 300 of the serving sector and the frame 350 of the diversity sector include frame control headers (FCH) (312, 362) and normal regions (310.360). , And diversity regions 320, 370, respectively. In this case, the apparatus for allocating resources determines whether the MS needs diversity support among MSs in a serving sector by checking the channel state of each MS, and bursts the frame 300 of the MS in the serving sector requiring diversity support. The area is divided into a normal area 310 and a diversity area 320 and allocated. In addition, the resource allocation apparatus divides and allocates a burst area of the frame 350 of the diversity sector of the MS requiring diversity support into a normal area 360 and a diversity area 370.

In addition, all of the diversity regions 320 and 370 allocated to the frames of the sectors in one cell have the same permutation type and the DL_PermBase (PermBase: PermBase). And a pseudo random bit sequence (PRBS) identifier (ID). In addition, all of the diversity regions 320 and 370 allocated to the frames of the sectors in the cell do not use a space time code (hereinafter, referred to as STC), and have the same OFDMA symbol offset. Or may have the same symbol length. In addition, as described above, when the serving burst 322 and the diversity burst 372 allocated to the diversity regions 320 and 370 are allocated to the same position and transmit the same signal, and the MS supports the dedicated pilot function, Diversity regions 320 and 370 may use dedicated pilots. That is, the diversity regions 320 and 370 have the same at least one of a start symbol offset, a symbol length, and whether a dedicated pilot is used.

In this case, the MS that needs diversity support is an MS that successfully receives a signal only when the BS transmits a signal through a serving sector antenna and at least one diversity sector antenna as described above. The resource allocation device allocates a diversity area to a frame of all diversity sectors of the MS requiring the diversity support. In this case, the diversity sector of the MS requiring the diversity support includes all candidate sectors except the serving sector of the MS among all sectors divided in one cell according to the determination of the diversity determiner 230 as described above. Or some of the candidate sectors.

Then, the apparatus for allocating the resource allocates the burst of the MS requiring the diversity support to the diversity regions 320 and 370 of the frame 300 of the serving sector and the frame 350 of the diversity sector. As described above, the serving burst 322 and the diversity burst 372 allocated to the diversity regions 320 and 370 are allocated to the same position in the frames 300 and 350 so that the DL signal of the MS is transmitted in the same manner.

In addition, the apparatus for allocating a resource allocates the burst of the MS that does not require the diversity support to the normal region 310 of the frame 300 of the serving sector. The apparatus for allocating a resource allocates a burst of the MS existing in the diversity sector and for which diversity support is not required to the normal region 360 of the frame 350 of the diversity sector. Here, positions between normal bursts 314 and 364 assigned to the normal areas 210 and 260 are irrelevant. Next, a process of allocating resources by the resource allocating apparatus in the communication system according to the exemplary embodiment of the present invention will be described in detail with reference to FIG. 4.

4 is a diagram illustrating a resource allocation process of a resource allocation apparatus in a communication system according to an embodiment of the present invention.

Referring to FIG. 4, first, in step S405, a CQI is received from each MS present in each sector. Then, after checking the channel status of each MS through the CQI received from each MS in step S410, in step S415 of the MS that needs diversity support among the MS corresponding to the channel status of each MS Check for existence. That is, it is determined whether diversity support of each MS is required. Here, whether diversity support to the MS is required has been described above in detail, so a detailed description thereof will be omitted.

As a result of the check in step S415, if there is an MS requiring diversity support, it is checked in step S420 whether a diversity region exists in a frame of a serving sector and candidate sectors corresponding to the MSs in which the diversity support is required. If the diversity area does not exist in step S420, the burst area of the frame of the serving sector and the frame of the candidate sectors is divided and allocated to the normal area and the diversity area in step S425.

Next, in step S430, it is determined whether the predetermined MS to which the resource is to be allocated is an MS requiring diversity support. In other words, in step S430, it is determined whether the predetermined MS is a MS to which a signal should be transmitted through a first scheme, or a MS to which a signal should be transmitted through a second scheme or a third scheme. Here, the operations in steps S415 and S420 are performed using the CINR of the MS through the CQI as described above, and the operation of determining the diversity support of the MS has been described above in detail. The description will be omitted.

If the predetermined MS is the MS that needs diversity support in step S430, in step S435, each burst of the predetermined MS is located at the same position of the diversity region allocated to the serving sector and the diversity sector frame of the predetermined MS. Assign. In step S435, if the predetermined MS is the MS for which signal transmission in the third scheme is determined, the burst of the predetermined MS is allocated to the same position of the diversity area allocated to the frames of all sectors in one cell. That is, a burst of the predetermined MS is allocated to a serving region of the predetermined MS and a diversity area of a frame of candidate sectors. Further, if the predetermined MS is the MS for which the signal transmission is determined in the second scheme, the serving MS of the predetermined MS and the diversity area allocated to a frame of some candidate sectors among candidate sectors are located at the same position of the predetermined MS. Allocates a burst.

On the other hand, if there is no MS that needs diversity support as a result of checking in step S415, in step S440 the burst area of the frame of all sectors is allocated to the normal area. Then, in step S445, the burst of the predetermined MS is allocated to the normal area allocated to the frame of the serving sector of the predetermined MS. In addition, if there is a diversity region in the frame of the serving sector and the diversity sector as a result of the checking in step S420, in step S430, it is determined whether the predetermined MS is an MS requiring diversity support. In operation S430, when the predetermined MS is an MS that does not need diversity support, the burst of the predetermined MS is allocated to the normal region allocated to the frame of the serving sector in operation S445. Next, a process of reallocating resources by the resource allocating apparatus in the communication system according to the exemplary embodiment of the present invention will be described in detail with reference to FIG. 5.

5 is a diagram illustrating a resource reallocation process of a resource allocation apparatus in a communication system according to an embodiment of the present invention.

Referring to FIG. 5, first, in step S505, as illustrated in FIG. 3, a CQI is received from each MS present in each sector to allocate a burst of each MS, and a CQI is received from a predetermined MS to which the burst is allocated. Check the channel state of the predetermined MS. Thereafter, the MS checks the channel state in step S510 to determine whether the MS needs diversity support. That is, it is determined whether diversity support of the MS is required.

As a result of the checking in step S510, if the predetermined MS is the MS requiring diversity support, in step S515, it is checked whether there is a diversity burst to be released for the predetermined MS. In other words, as described above, the diversity bursts of the predetermined MS allocated to the diversity regions of the plurality of diversity sectors so that the BS transmits signals to the predetermined MS through a serving sector antenna and a plurality of diversity sector antennas. Check whether there is a diversity burst to deallocate. In this case, no resources are available in some of the diversity sectors, or the CINR of the signal transmitted by the serving sector antenna of the predetermined MS is greater than the CINR of the signal transmitted by the diversity sector antenna. If the CINR of the combined signal of the signal transmitted by the sector antenna and the serving sector antenna is larger than the third threshold value, the diversity burst assigned to the diversity region of the diversity sector is the diversity burst to be deassigned.

If there is no diversity burst to release allocation for the predetermined MS as a result of the checking in step S515, in step S520, a serving burst is allocated to the diversity area of the serving sector of the predetermined MS, and the diversity area of the diversity sector. Assigns a diversity burst to If there is a diversity burst to be deallocated with respect to the predetermined MS as a result of the checking in step S515, the allocation of the predetermined diversity burst allocated to the diversity area of the diversity sector to be deallocated is released in step S525. do. Next, in step S520, the serving burst is allocated to the diversity area of the serving sector, and the diversity burst is allocated to the diversity area of the diversity sector except for the unassigned diversity sector.

On the other hand, if it is determined in step S510 that the predetermined MS does not need diversity support, in step S530 it is checked whether there is a diversity burst allocated for the predetermined MS. In other words, as described above, the BS determines whether there are diversity bursts allocated to the diversity regions of the plurality of diversity sectors so that the BS transmits a signal to the predetermined MS through a serving sector antenna and a plurality of diversity sector antennas. .

At this time, the predetermined MS sends a handover indication message to release the connection with the cell, or the predetermined MS is an MS entering an initial network, or resources available to all diversity sectors for diversity transmission support are provided. The predetermined MS to de-allocate all diversity bursts allocated for the predetermined MS because the predetermined MS is an MS that does not need diversity support if there is no data or if there is no data transmitted from the serving sector to the predetermined MS. Check the diversity burst assigned for.

If there is a diversity burst assigned for the predetermined MS as a result of the checking in step S530, the allocation of all diversity bursts allocated for the predetermined MS is released in step S535. Then, in step S540, the serving burst is allocated to the normal area of the serving sector. In addition, if there is no diversity burst assigned for the predetermined MS as a result of the checking in step S530, the predetermined MS is a MS having a good channel state and thus does not need diversity support, and thus serving in the normal region of the serving sector in step S540. Allocates a burst.

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

1 schematically illustrates the structure of a communication system according to an embodiment of the invention.

2 is a diagram schematically illustrating a structure of an apparatus for allocating a resource of a BS in a communication system according to an embodiment of the present invention.

3 schematically illustrates a frame structure in a communication system according to an embodiment of the present invention.

4 is a diagram illustrating a resource allocation process in a communication system according to an embodiment of the present invention.

5 is a diagram illustrating a resource reallocation process in a communication system according to an embodiment of the present invention.

Claims (25)

delete delete delete delete delete delete delete delete delete delete delete delete delete In the resource allocation method in a multi-sector communication system, (a) checking the channel state of a mobile station present in a plurality of sectors in a given cell; (b) determining whether to transmit a signal using a diversity sector antenna to the mobile station according to the channel state of the mobile station; (c) If it is determined that signal transmission using the diversity sector antenna is necessary, a diversity area is allocated to a serving sector frame and a diversity sector frame of the mobile station, and signal transmission using the diversity sector antenna is unnecessary. Allocating a normal region to the serving sector frame if determined; And (d) If it is determined that signal transmission using the diversity sector antenna is necessary, a burst is allocated to each of the diversity regions of the serving sector frame and the diversity sector frame, and signal transmission using the diversity sector antenna is unnecessary. If it is determined that the burst is allocated to a normal region of the serving sector frame. The method of claim 14, If it is determined that signal transmission using the diversity sector antenna is necessary, in step (d), the burst is allocated to the same position of each diversity area, and the diversity sector antenna is used as the burst allocated to each diversity area. And a serving sector antenna transmit the same signal, respectively. The method of claim 15, wherein in step (b), The signal transmission necessity determination using the diversity sector antenna is performed by determining that the carrier-to-interference noise ratio of the signal transmitted from the serving sector antenna to the mobile station is smaller than the first threshold value, and that the diversity sector antenna transmits the signal to the mobile station. If the carrier-to-interference noise ratio is greater than the second threshold, it is determined that signal transmission using the diversity sector antenna is necessary. The first threshold is a reference value for determining whether to perform communication with only the serving sector antenna without the support of the diversity sector antenna, and the second threshold is for determining whether to support the diversity sector antenna. Resource allocation method characterized in that the reference value. The method of claim 14, and (e) if it is determined that signal transmission using the diversity sector antenna is unnecessary, the serving sector antenna transmits a signal in a burst allocated to the normal region. The method of claim 17, wherein in step (b), The signal transmission unnecessary determination using the diversity sector antenna may include a carrier to interference noise ratio of a signal transmitted by the serving sector antenna to the mobile station being greater than a carrier to interference noise ratio of a signal transmitted by the diversity sector antenna to the mobile station. If the carrier-to-interference noise ratio of the combined signal of the signal transmitted by the sector antenna and the diversity sector antenna is greater than the third threshold, it is determined that the signal transmission using the diversity sector antenna is unnecessary. The third threshold is a resource in which a hysteresis margin is added to a first threshold, which is a value used to determine whether to perform communication using only a serving sector antenna without support of a diversity sector antenna. Assignment method. A resource allocation apparatus in a multi-sector communication system, A receiver for receiving channel quality information (CQI) from a plurality of mobile stations existing in a plurality of sectors in a predetermined cell; A confirmation unit for confirming a channel state of the mobile station through the received CQI; A determination unit for determining whether to transmit a signal using a diversity sector antenna to the mobile station according to the checked channel state of the mobile station; And If the determination unit determines that signal transmission using the diversity sector antenna is necessary, the diversity area is allocated to a serving sector frame and a diversity sector frame of the mobile station, and then each diver of the serving sector frame and the diversity sector frame. When each burst is assigned to the city area and the determination unit determines that signal transmission using the diversity sector antenna is unnecessary, the normal area is allocated to a serving sector frame of the mobile station and then a burst is applied to the normal area of the serving sector frame. Resource allocation apparatus comprising a scheduler to allocate. delete The method of claim 19, And the identification unit checks the channel state of the mobile station using a carrier to interference and noise ratio (CINR) included in the CQI. The method of claim 21, The determining unit may determine that the carrier to interference noise ratio of the signal transmitted from the serving sector to the mobile station is less than a first threshold and the carrier to interference noise ratio of the signal transmitted from the diversity sector to the mobile station is greater than a second threshold. Decide that you need diversity support, The first threshold is a reference value for determining whether to perform communication with only the serving sector antenna without the support of the diversity sector antenna, and the second threshold is for determining whether to support the diversity sector antenna. The resource allocation device, characterized in that the reference value. The method of claim 21, The determining unit may further include a carrier to interference noise ratio of a signal transmitted from the serving sector to the mobile station is greater than a carrier to interference noise ratio of a signal transmitted from the diversity sector to the mobile station, and a signal transmitted from the serving sector and the diversity sector. If the carrier-to-interference noise ratio of the combined signal of is greater than the third threshold, the diversity support is determined to be unnecessary. The third threshold is a resource in which a hysteresis margin is added to a first threshold, which is a value used to determine whether to perform communication using only a serving sector antenna without support of a diversity sector antenna. Allocation unit. The method of claim 19, The diversity area of the serving sector frame and the diversity frame uses the same permutation type, a DL_Permation Base, and Pseudo Random Bit Sequence (PRBS) identifier. And a space time code (STC) is not used. delete

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