KR20080094254A - Method for allocating reverse link resourse in based macro-diversity for cellular ofdma system - Google Patents

Abstract

A macro diversity-based uplink resource allocation method for a cellular OFDMA(Orthogonal Frequency Division Multiplexing Access) system is provided to be capable of assigning resources according to locations of terminals by dividing a cell into plural areas, thereby reducing ICS(Inter-Cell Interference) which uplink signals of the terminals located in external cell regions experience. A home BS(Base Station) is determined according to channel environmental states, and size of ICS between a terminal and another BS is measured(S101-S103). The home BS checks whether the terminal is located in an internal region of a cell or in an external region adjacent to another cell(S104). If the terminal is located in the external region, the home BS divides the external region into plural zones, and checks in which zone the terminal is located(S105,S107). The home BS confirms a resource set assigned to the zone where the terminal is located, and if resource selection is available, the home BS assigns resources of the corresponding zone to the terminal(S108-S111).

Description

Macro diversity based uplink resource allocation method for cellular OPDMA systems {METHOD FOR ALLOCATING REVERSE LINK RESOURSE IN BASED MACRO-DIVERSITY FOR CELLULAR OFDMA SYSTEM}

1 is a configuration diagram for explaining the interference of a conventional cellular system.

2 is a simplified schematic diagram of a cellular system according to an embodiment of the present invention.

FIG. 3 is a diagram for describing resource allocation of a cell of the cellular system of FIG. 2. FIG.

FIG. 4 is a diagram illustrating an example of resource allocation of FIG. 3. FIG.

5 is a flowchart illustrating a resource allocation method for a mobile terminal according to an embodiment of the present invention.

<Description of Symbols for Main Parts of Drawings>

10, 100: mobile terminal

20, 200: Signal connection between base station and mobile terminal

30: Internal interference between base station and mobile terminal

300: macro diversity based signal connection

400 ~ 600: base station

The present invention relates to a macro diversity based uplink resource allocation method for a cellular OFDMA system, and more particularly, by dividing a cell into a plurality of regions and allocating resources for each region, inter-cell interference. It is a technology to improve the uplink quality of service (QoS) in the outer region of the cell where communication quality is deteriorated due to the channel environment by reducing the Rx) to enable a smoother communication service in an OFDMA-based cellular network.

Orthogonal frequency division multiplexing (OFDM) based multi-carrier communication has been in the spotlight as the next generation wireless communication method due to advantages such as stiffness for multipath fading and efficient use of bandwidth.

In particular, Orthogonal Frequency Division Multiple Access (OFDMA), which is one of the OFDM-based multiple access technologies, is expected to be widely used as a major standard for next-generation communication businesses such as WiBro.

However, when performing wireless communication in a multi-cell environment, communication is often adversely affected by inter-cell interference from adjacent cells.

In the conventional CDMA method, it is possible to reduce the influence of interference by using a spread noise pseudo noise technique, but in the case of OFDMA, which is being spotlighted as a next-generation wireless communication method, signals from adjacent cells If the current communication uses the same carrier, the base station cannot distinguish between the normal signal and the inter-cell interference signal, and thus the desired received signal cannot be detected without an error.

1 is a view for explaining the inter-cell interference in a conventional cellular system, each of the base station has a cell 1, cell 2, cell 3 area and connected to a base station close to the base station according to the position of the mobile terminal 10 and frequency band Is assigned to communicate.

As shown in FIG. 1, when resources are allocated to the mobile terminal 10 in units of frequency bands, resource allocation efficiency decreases, and the mobile terminal 10 is connected to the base station at the upper left (20). Inter-cell interference acts on the base station (30).

As such, in order to avoid interference between cells in allocating a frequency band to the mobile terminal, there is a method of allocating different frequency bands according to the cells in which the mobile terminal is located by dividing the entire frequency band, but in this case, resource allocation efficiency is very low. There is this. On the other hand, if the entire frequency band is allocated to all cells in duplicate (frequency reuse factor = 1), the bandwidth can be gained in terms of efficiency but is exposed to strong inter-cell interference.

Therefore, conventionally, various interference reduction techniques have been developed to minimize the influence of inter-cell interference, but most of the interference reduction techniques have been performed in case of transmitting a signal from the base station to the mobile. It is true.

In addition, in the cellular communication of the cellular structure, mobiles in the outer region of the cell are often subjected to poor communication environments due to path-loss along distance.

As a method for reducing such inter-cell interference, the FFFR method ("Flexible Fractional Frequency Reuse Approach", 3GPP TSG RAN WG1 Meeting No. 43, Korea, November, 2005.) and the S. Yun method (S. Yun, SY Park, Y. Lee, E. Alsusa and CG Kang, "Spectrum efficient region-based resource allocation with fractional loading for FH-OFDMA cellular systems", IEE Electronics Letters, vol. 41, June 2005.

First, the FFFR method is a technique proposed for a downlink OFDMA system, and is a dynamic channel allocation method in which each cell is allocated a preferred frequency channel resource and uses a resource allocated to an adjacent cell when the traffic load is increased. This is a method of increasing the utilization of the entire system resource by using the characteristic that the traffic load changes according to the.

Meanwhile, the S. Yun method is a frequency loading scheme proposed for uplink using FH-OFDMA, and divides each cell into an inner cell and an outer cell region, and the inner side with less influence of inter-cell interference. In the cell area, all available resources (frequency hopping patterns are channel resources) are used, and in the outer cell area where the influence of inter-cell interference is large, only a portion of the available resources are allocated to terminals to the outer cells of adjacent cells. A method of reducing collision probability between assigned hopping patterns.

Although these conventional techniques have a function of reducing inter-cell interference, there is a point that the efficiency of resource utilization is not optimized.

According to the present invention, by dividing a cell into a plurality of regions and allocating resources according to the position of the terminal in the uplink OFDMA system, the inter-cell interference experienced by the uplink signals of the terminal located in the outer region of the cell is reduced, and at the same time, the entire cellular OFDMA system The purpose is to improve uplink capacity and increase resource utilization.

Macro diversity-based uplink resource allocation method for a cellular OFDMA system according to an embodiment of the present invention for achieving the above object, determines the home base station according to the channel environment, the size of the inter-cell interference between the other base station and the terminal A first step of measuring a second step of checking whether the mobile station is located in an inner region of a cell or an outer region adjacent to another cell according to the magnitude of the inter-cell interference in the home base station; In the case of being located in the outer region, the third step of the home base station divides the outer region into a plurality of zones and check which one of the plurality of zones, the terminal is a check result Check the resource set assigned to the zone and select the resource if the resource is available. And a fourth process of allocating resources.

In addition, according to an embodiment of the present invention, a macro diversity based uplink resource allocation method for a cellular OFDMA system includes: a first base station determining a home base station according to a channel environment state and measuring a magnitude of inter-cell interference between another base station and a user equipment; And a second step of checking whether the terminal is located in an inner region of a cell or an outer region adjacent to another cell according to the magnitude of the inter-cell interference in the home base station; and a base station allocated according to the position of the terminal. It characterized in that it comprises a third process of adjusting the number of.

The present invention proposes a resource allocation method based on macroscopic diversity in order to reduce inter-cell interference and to improve QoS in an out-of-cell area in an uplink OFDMA system. .

Hereinafter, with reference to the accompanying drawings will be described in detail a preferred embodiment of the present invention.

FIG. 2 is a simplified configuration diagram of a cellular system according to an embodiment of the present invention, and cell division for resource allocation will be described with reference to FIG. 2.

As shown in FIG. 2, each cell (cell 1, cell 2, cell 3) around each base station 400-600 is divided into four zones of A, B, C, and D, respectively. The three zones, except the located D zone, are connected to the same zone of each adjacent cell.

In other words, it can be seen that the three zones except the D zone located in the center of the cell are in contact with the same zones of adjacent cells. The areas of the outer area that are in contact with each other are treated as one area regardless of the cell to which they belong, and terminals located in the area are connected to two or more base stations sharing this area.

In FIG. 2, the mobile terminal 100 belongs to a zone A that shares all three base stations 400 to 600, and is originally connected to only the base station 400 at the upper left side of the mobile station 100. 500 is also connected (300). That is, the mobile terminal 100 located in the A zone may be connected to a plurality of base stations 400 to 600 sharing the A zone.

Here, the mobile terminal 100 does not need to be connected to all three base stations at the same time, it can select the base station to communicate with itself. In FIG. 2, the mobile terminal 100 is located in an area A and is connected to the base station 400 and also connected to another base station 500 to obtain macro diversity.

On the other hand, all of the base stations (400 ~ 600) sharing the A zone, whether or not communicating with the mobile terminal or not by using the resources used by the mobile terminal 100 overlapping so that the collision does not occur It is preferable that the resource allocated to the terminal 100 is no longer used.

That is, the present invention prevents inter-cell interference by preventing a specific resource in a cell outside area shared by several base stations from overlapping to multiple terminals, and applies frequency recycling through a resource distribution scheme according to the area where the terminal is located. Lower co-channel interference and higher resource utilization efficiency can be obtained.

In addition, different resource sets are allocated to the divided zones, which will be described below with reference to FIGS. 3 and 4.

First, three zones A, B, and C are allocated a resource set for each zone, and mobile terminals belonging to the zone are sequentially allocated resource units.

That is, the resource units may be sequentially selected in the order shown in FIG. 3, and the zone D selects the resource units in an order opposite to the order given to the zones A, B, and C. To prevent it.

Here, it is preferable that the resource set includes a plurality of resource units, and the resource set does not directly represent bandwidth, but the order of resource allocation regardless of the order of the subcarrier set of OFDM on the frequency axis. Only considering the expression.

That is, the resource unit is for logically representing a radio communication resource rather than a specific subcarrier or a carrier frequency band, and the resource unit in the present invention is a unit representing the subcarrier. In other words, one resource unit may be considered to include one or more subcarriers. In FIG. 3, the resource unit is designated as a resource unit rather than a subcarrier in order to avoid mistaken division of the resource as division of the bandwidth.

In FIG. 3, the total resource is divided into three, and this is not a principle in which the specific bandwidth divided by dividing the total bandwidth is divided into one resource set. However, one divided resource unit is divided into several resources distributed over the entire bandwidth. It includes a subcarrier, and one resource unit does not reflect the subcarriers sequentially on the frequency axis, but means a set of subcarriers distributed over several bands on the frequency axis.

This is because allocating resources over a wide bandwidth ensures frequency diversity. Frequency diversity can provide a wider variety of channel environments because subcarriers in bands farther from each other than in adjacent bands are less correlated with each other, and various channel environments can guarantee higher levels of communication.

For example, when a channel environment becomes poor over a specific bandwidth, mobile terminals communicating using subcarriers present in a specific bandwidth show a serious degradation in performance. However, if a mobile terminal is communicating over multiple bandwidths, the communication situation can be compensated for through a subcarrier with a different bandwidth in which the channel environment is stable in addition to the subcarriers existing in a specific bandwidth with a poor channel environment. It can be guaranteed.

On the other hand, the order of resource allocation may not be the same as the order on the frequency axis, and when the resource set corresponds to the actual frequency band, the order is mixed as shown in FIG. 3, which is a frequency selective channel. To increase diversity.

Meanwhile, a resource unit represented by gray in FIG. 4 means a resource unit that is not used. In the case where adjacent cells share an area, an area A is shared by all cells and the other area is not shared. Here, the non-shared outer B and C areas are shared with another adjacent cell.

In this case, the mobile terminal 100 to which resources are allocated is connected to a base station of a cell which is currently located in the case of zone D, and is connected to a plurality of adjacent base stations in zones A, B, and C. FIG.

Therefore, the mobile terminal 100, which originally acted as an interference to an adjacent cell, acts as a signal, thereby minimizing interference. In other words, from the standpoint of the base station of the adjacent cell, the mobile terminal, which originally acted as the interference, may no longer act as the interference, and thus the interference may be mitigated.

In other words, from the standpoint of the base station of the adjacent cell, the mobile terminal, which originally acted as the interference, may no longer act as the interference, and thus the interference may be mitigated.

In this case, the mobile terminal communicates with other adjacent base stations in addition to the originally assigned home base station, and all of the cells sharing a specific region to which the mobile terminal belongs use resources used by the mobile terminal. This can be allocated only in order to reduce interference due to no collision for the resource. Thus, all base stations enjoy a better communication environment as they are free from interference from adjacent outer regions of other adjacent cells.

In addition, considering the path-loss along the distance, the interference from the mobile terminal in the suburban area close to the base station of the adjacent cell has a significant effect. The mobile terminal in the suburban area no longer interferes. Interference can be minimized as it does not work.

In addition, the mobile terminal in the outlying region, which may easily degrade due to poor channel conditions, is connected to a plurality of base stations, thereby obtaining macro diversity, thereby ensuring better QoS.

Hereinafter, a resource allocation method for a mobile terminal according to an embodiment of the present invention will be described in detail with reference to FIG. 5.

First, some assumptions will be made before describing a resource allocation method for a mobile terminal.

That is, the receiving antenna can be largely divided into an omni-directional antenna and a directional antenna. The former receives the radio waves uniformly over 360 ^° in all directions, but the latter selectively receives radio waves from a specific direction. In the present invention, it can be assumed that the directional antenna basically has a reception area of 120 ^o . Therefore, when a signal is received from a terminal, it is assumed that the terminal is located in one of three directions divided by 120 ^o . In fact, many base stations use such an antenna.

At this time, unlike the reception antenna of the base station, the transmission antenna of the terminal assumes a forward antenna, which is the same as the specification of the general terminal. In other words, the terminal does not transmit the radio wave in a specific direction and the radio wave emitted from the terminal can be seen to spread uniformly over 360 ^o . In addition, it is assumed that the base station can know how much the signal of a specific terminal is being received by other base stations through communication with neighboring base stations.

Under the above assumption, first, the mobile terminal registers with the base station according to the location, and measures the channel environment with the base station (S101). Here, the mobile terminal transmits and receives radio waves with the base station for communication, and at this time, the channel state can be known through the magnitude of the radio waves coming and going.

As a result, the base station having the best channel environment, that is, the base station having the best channel condition with the mobile terminal is determined as a home base station (S102), and base stations other than the home base station propagate from the mobile terminal. That is, the magnitude of the inter-cell interference from the corresponding UE is measured (S103).

Accordingly, the home base station checks whether the magnitude of the inter-cell interference is greater than the threshold (S104), and if the magnitude of the inter-cell interference is greater than the threshold, determines that the mobile terminal 100 is located in the outer region (S105). When the magnitude of the inter-cell interference is smaller than the threshold, it is determined that the mobile terminal 100 is located in the internal region (S106).

 For example, if the threshold is set to 0.7, when the signal of the mobile terminal reaching the home base station is 1, the intensity of the signal of the terminal (that is, inter-cell interference signal) reaching another adjacent base station is 0.8 days. The terminal is then in the outer zone.

Thereafter, the home base station identifies the zone (A, B, C, D) to which the mobile terminal 100 belongs (S107). In this case, in order to identify the area to which the process S107 belongs, the characteristic of the directional antenna is used. That is, the home base station can know where the mobile terminal is located in three directions divided by 120 ^o and can know where the terminal is located in the A, B, C and D regions through communication with the mobile terminal.

Thereafter, the home base station checks the resource set assigned to the area to which it belongs (S108). At this time, through the resource allocation table shown in FIG. 4 stored in the base station, it is possible to check the allocated resource set for each cell zone.

Subsequently, the resources to be allocated to themselves are sequentially checked from the resource allocation table of FIG. 4 (S109), and it is checked whether the resource selection is possible, that is, whether there are remaining resources that can be selected (S110).

As a result, when selection is possible, the remaining resources of the corresponding area are allocated to the corresponding mobile terminal 100 (S111). At this time, resources are allocated in the order shown in the resource allocation table of FIG. 4, but if the resources that can be allocated are not selectable, that is, if other terminals are already in use or cannot communicate through the corresponding resources due to other reasons, they are selected. It checks the resource set and checks whether it can be selected until a possible resource appears.

The process of FIG. 5 will be described below with reference to a specific example.

For example, when the mobile terminal 100 is located in the C region of the cell 1, the base station 400 in the cell 1 area is determined as the home base station through the process S101, and the base station 400 is another base station 500, Check whether the ICI is greater than the threshold value by checking the signal magnitude (ICI) on 600) to determine whether the mobile terminal 100 is located in the D zone or the outer zones A, B and C. .

As a result, when the mobile terminal 100 is located in the C region of the outer region, the resource allocation table for the C region of the cell 1 is checked in the resource allocation table of FIG. 4. In the resource allocation table of FIG. 4, since the fourth resource unit of the C zone is empty in the resource set allocation state of the C zone of the cell 1, the fourth resource unit of the C zone is allocated to the mobile terminal 100.

On the other hand, when the mobile terminal 100 is located in the zone A of the outer region, the resource allocation table of the cell 1 in the resource allocation table of FIG. In the resource allocation table of FIG. 4, the resource set allocation state for the zone A of the cell 1 is allocated to the mobile terminal 100 because the sixth resource unit of the zone A is empty. In this case, the zone A is commonly connected to cell 1, cell 2, and cell 3, so that the interference between other base stations is the greatest, so the area A of cells 2 and 3 must be assigned the sixth resource unit in the same way. Can be minimized.

However, in the resource allocation table of FIG. 4, five resource units for the A zone of the cell 1 are allocated, and three resource units for the D zone are allocated, so that there are no remaining resource units for the cell 3. Allocate resources in several ways:

First, when a new terminal wants to communicate in a situation where there are no more resources to be allocated, the base station measures to wait until there is a resource that can be allocated, that is, another terminal moves to another area or terminates communication. The resource is not allocated to the new terminal until the resource is returned.

Secondly, in contrast to the first, when there is a terminal that wants to communicate newly, it deprives resources allocated to other terminals where the original communication continued and allocates the newly allocated terminal to the desired terminal.

Third, allocating a new resource to a terminal that does not matter even if a resource other than the currently used resource among the terminals currently using resources to return the resources that were originally used, and then assigns a new terminal to the desired communication.

In the present invention, in the A, B, or C region, only resources within the resource set allocated to each of the regions can be used. However, in the D region, the resources are insufficient in the A, B, or C region because they are not attributed to a specific resource set. A method of allocating a new resource to a terminal allocated to a region and assigning a resource originally used to a terminal to newly communicate with the terminal is possible.

As such, the present invention can improve the communication quality by reducing the interference that the communication of other mobile terminals act as a disturbance in the communication with the base station assigned to the mobile terminal, the path-loss different in distance (path-loss) QoS of the cell outside can be improved by making the communication between mobile terminals outside the cell having a poor channel situation more smoothly due to interference from the adjacent cell.

To this end, the present invention applies a frequency reuse method, which is one of interference reduction techniques, and uses a method of partially reusing resources by dividing one cell into a plurality of zones.

That is, in order to compensate for the inefficiency of the conventional FFFR method, it is possible to borrow and allocate resources not used in an adjacent cell, and allocate resources according to detailed regions in the cell rather than in units of cells, thereby providing a frequency such as FFFR. It shows a significantly higher frequency usage efficiency compared to reuse technology.

In addition, the present invention divides the cells into an inner region and an outer region, and reduces interference between uplink signals through differential resource allocation according to regions according to the method described above, and a plurality of base stations adjacent to each outer region share the same resources. By allocating the area and receiving the uplink signal generated in the area at the same time, the base station can obtain the macro diversity and improve the QoS of the outer cell.

As described above, the present invention divides one cell into a plurality of regions and allocates resources for each region in an uplink OFDMA system, thereby reducing interference between cells and making communication of the system more smooth. Due to the poor performance of the mobile terminal in the outlying region where the performance degradation can easily be connected to a plurality of base stations to obtain macro diversity, there is an effect that the QoS is improved.

In addition, the preferred embodiment of the present invention for the purpose of illustration, those skilled in the art will be able to various modifications, changes, replacements and additions through the spirit and scope of the appended claims, such modifications and changes are the following claims Should be seen as belonging to.

Claims (11)

Determining a home base station according to a channel environment state and measuring a magnitude of inter cell interference between another base station and a terminal; A second step of checking, by the home base station, whether the terminal is located in an inner region of a cell or an outer region adjacent to another cell according to the magnitude of the inter-cell interference; A third step of, when the terminal is located in the outer area, the home base station dividing the outer area into a plurality of zones and checking which one of the plurality of zones is located in the home base station; And And a fourth step of identifying a resource set allocated to the zone to which the terminal belongs and assigning a resource of the corresponding zone to the terminal when resource selection is possible. Macro Diversity Based Uplink Resource Allocation Method. The method of claim 1, wherein the first process comprises: A step 1-1 of registering the terminal with a plurality of base stations according to locations; A first and second process of measuring a channel environment according to a magnitude of radio waves transmitted and received between the terminal and a plurality of base stations; First to third steps of registering a base station having the largest magnitude of radio waves as a home base station; And  Macrodiversity-based uplink for the cellular OFDMA system, characterized in that the base stations other than the home base station measure the size of the inter-cell interference from the corresponding terminal, which is the size of radio waves from the corresponding terminal. Resource allocation method. The method of claim 1, wherein the second process comprises: The home base station determines that the terminal is located in the outer region of the cell if the size of the inter-cell interference is greater than a predetermined size, and determines that the terminal is located in the inner region of the cell if the size of the inter-cell interference is smaller than a predetermined size. Macro diversity based uplink resource allocation method for a cellular OFDMA system, characterized in that the. According to claim 1 or 3, wherein the third process, Macro diversity-based uplink resource allocation method for a cellular OFDMA system, characterized in that it is determined in which zone of the plurality of zones of the outer region according to the antenna direction of the home base station. The method of claim 1, wherein the fourth process, Step 4-1, wherein the home base station identifies a resource set allocated to the area to which the home base station belongs; Step 4-2 of sequentially checking whether resources to be allocated remain in the terminal corresponding to the belonging area; And And if the resources remain, macro diversity-based uplink resource allocation method for a cellular OFDMA system, characterized in that the step 4-3 to sequentially allocate the corresponding resources to the terminal. The method of claim 1, wherein the fourth process, Macro diversity based uplink for a cellular OFDMA system, wherein the resources allocated to the outer region are sequentially selected, but the resources allocated to the inner region are sequentially selected as opposed to the order of the outer region. Resource allocation method. The method of claim 6, wherein the fourth process, For allocating resources sequentially, but if the resources that can be allocated are not selectable, repeating the operation of checking the resource set and checking whether they can be selected until a selectable resource appears. Macro diversity based uplink resource allocation method. The method of claim 1, wherein the second process comprises: For the cellular OFDMA system, if the terminal is allocated to the inner region, a single base station is allocated to the terminal, and if the terminal is allocated to the outer region, the base station is assigned a plurality of base stations to the terminal. Macro diversity based uplink resource allocation method. Determining a home base station according to a channel environment state and measuring a magnitude of interference between cells between another base station and a terminal; A second step of checking, by the home base station, whether the terminal is located in an inner region of a cell or an outer region adjacent to another cell according to the magnitude of the inter-cell interference; And And a third process of adjusting the number of base stations allocated according to the location of the terminal. The method of claim 9, wherein the third process, Step 3-1 of the home base station, when the terminal is located in the outer area, dividing the outer area into a plurality of zones and checking which one of the plurality of zones is located in the home base station; And And a step 3-2 of checking the resource set allocated to the zone to which the terminal belongs, and allocating resources of the corresponding zone to the terminal if there are resources to be selected. A macro diversity based uplink resource allocation method for a cellular OFDMA system. The method of claim 10, wherein the step 3-2 is performed. Identifying, by the home base station, a resource set allocated to a region to which the home base station belongs; Sequentially checking whether there are resources left to be allocated to the terminal corresponding to the belonging area; And Macro diversity based uplink resource allocation method for a cellular OFDMA system, if the resources remain, sequentially allocating corresponding resources to the terminal.

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