KR20090015781A - System and method for using frequency resource in a communication system - Google Patents

Abstract

A frequency resource usage system and a method thereof in a communications system capable of controlling ICI through simple adjustment operation are provided to reduce a problem about ICI(Inter Cell Interference) by using frequency resource by using segment sequence. A multi cell communications system uses frequency resource by using segment sequence. The usable frequency band is classified into the segments of A. One segment is classified into the sub bands of B. One sub band is classified into the channels of C. The order using the segment of A is shown by the segment sequence. The frequency assignment use sequence calls a segment sequence. The segment sequence is determined in consideration of ICI. The segment sequence is determined in consideration of the frequency reuse factor and sectorization coefficient in order to minimize ICI.

Description

SYSTEM AND METHOD FOR USING FREQUENCY RESOURCE IN A COMMUNICATION SYSTEM}

The present invention relates to a system and method for using frequency resources in a communication system.

In general, a communication system is implemented in the form of a multi-cell communication system including a plurality of cells in order to increase the number of acceptable mobile terminals (hereinafter, referred to as MSs).

Meanwhile, in a wireless communication environment, a frequency reuse scheme is used to increase the number of channels per unit area using frequency resources, which are limited resources. The frequency reuse scheme is a scheme that can increase system capacity without special modification to the multi-cell communication system structure. However, reuse of frequency has a fatal problem in terms of interference such as inter-cell interference (ICI).

Therefore, there is a need for a method for increasing frequency resource efficiency while minimizing interference in a multi-cell communication system.

The present invention proposes a frequency resource use system and method in a communication system.

The system proposed in the present invention; In a frequency resource using system in a multi-cell communication system, each cell included in the multi-cell communication system is controlled to use frequency resources using a preset segment sequence, and available frequency bands available for each cell are determined. The same frequency band is divided into A segments, one segment is divided into B subbands, one partial band is divided into C channels, and the segment sequence uses the A segments. It is characterized by showing the order.

Another system proposed by the present invention; A frequency resource use system in a multi-cell communication system including at least two cells, wherein the at least two cells are controlled to use resources using a preset frequency resource use sequence, wherein the at least two cells use When the available frequency bands are the same and the available frequency bands are divided into at least two frequency bands, the frequency resource use sequence is characterized by indicating an order of using the at least two frequency bands.

The method proposed in the present invention; A method of using frequency resources in a multi-cell communication system, the method comprising: using a frequency resource using a segment sequence in which each cell included in the multi-cell communication system is preset, and available frequencies available for each cell The bands are the same, and the available frequency band is divided into A segments, one segment is divided into B partial bands, one partial band is divided into C channels, and the segment sequence corresponds to the A segments. It is characterized by showing the order of use.

Another method proposed by the present invention; A method of using a frequency resource in a multi-cell communication system including at least two cells, the method comprising: using the resource using a preset frequency resource use sequence of the at least two cells, wherein the at least two cells When the usable available frequency bands are the same and the available frequency band is divided into at least two frequency bands, the frequency resource use sequence is characterized by indicating an order of using the at least two frequency bands.

The present invention has the advantage of reducing the problems caused by ICI by using frequency resources using segment sequences in a multi-cell communication system. In addition, the present invention has the advantage that each cell in the multi-cell communication system using the frequency sequence using the segment sequence can control the generation of the ICI through a relatively simple adjustment operation. In addition, the present invention has the advantage of reusing the frequency resources according to the situation of the multi-cell communication system by determining the segment sequence in consideration of the various parameters of the multi-cell communication system in the multi-cell communication system. In addition, the present invention has the advantage that the frequency resource use operation is relatively simple because each cell of the multi-cell communication system uses a frequency resource using a segment sequence.

Hereinafter, with reference to the accompanying drawings in accordance with the present invention will be described in detail. 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 proposes an apparatus and method for using frequency in a communication system. In particular, the present invention proposes an apparatus and method for using frequency resources by using a frequency resource use sequence in which each of the plurality of cells is preset in a multi-cell communication system including a plurality of cells.

First, in order to maximize frequency reuse efficiency in a multi-cell communication system, frequency reuse factor 1 must be used. However, as the frequency reuse coefficient decreases, inter-cell interference from adjacent cells (ICI: referred to as 'ICI') increases, so setting the frequency reuse coefficient to 1 in a multi-cell communication system is described above. ICI has its limitations. As a result, the ICI problem must be solved to increase the frequency reuse efficiency. Accordingly, the present invention proposes an Incremental Frequency Reuse (IFR) method, which is referred to herein as an IFR method. In the IFR method proposed in the present invention, each cell included in a multi-cell communication system is preset. A frequency resource usage sequence is used to indicate how to use frequency resources.

Meanwhile, prior to describing the present invention, terms used in the present invention are defined as follows.

(1) Available frequency band

The frequency reuse factor used by each cell included in the multi-cell communication system is 1, and thus the available frequency resources available to each cell are the same. Here, the available frequency resources available to each cell will be referred to as an "available frequency band".

(2) channel, partial band, segment

One segment includes at least one partial band and one partial band includes at least one channel. Here, the partial band will be described in detail. First, available frequency bands are divided into a plurality of subbands, for example, N subbands, and the sizes of the N subbands may be the same or different. In addition, the number of channels included in one partial band may also be the same or different. When one partial band includes a plurality of channels, the plurality of channels may be physically continuous or spaced apart. Of course you can. In addition, when one segment includes a plurality of partial bands, the plurality of partial bands may be physically continuous or may be spaced apart. Hereinafter, for convenience of description, the case in which the size of the partial bands are the same will be described as an example.

First, a segment usage method according to an embodiment of the present invention will be described with reference to FIGS. 1A and 1B.

1A is a diagram illustrating a method of using a first type segment according to an embodiment of the present invention.

As shown in FIG. 1A, the first type segment usage scheme represents a scheme in which all segments have the same size. That is, in FIG. 1A, one segment includes one partial band, and the N segments, that is, the sizes of the first to Nth segments are the same.

In FIG. 1A, a method of using a first type segment according to an embodiment of the present invention has been described. Next, a method of using a second type segment according to an embodiment of the present invention will be described with reference to FIG. 1B.

1B is a diagram illustrating a method of using a second type segment according to an embodiment of the present invention.

As shown in FIG. 1B, the second type segment usage scheme represents a scheme of using segments having different sizes. That is, in FIG. 1B, one segment may include one partial band, may include two partial bands, and M segments, that is, the first to Mth segments are not all the same size. For example, it can be seen that the first segment includes one partial band, and the second segment includes two partial bands and has different sizes.

Meanwhile, in each cell of the multi-cell communication system, transmission power may be controlled in units of partial bands or segments, which is illustrated in FIG. 1C.

1C is a diagram illustrating a method of controlling transmission power in units of segments according to an embodiment of the present invention.

In FIG. 1C, an operation of controlling transmission power in units of segments is illustrated, and it can be seen that transmission powers are different for each segment. Of course, depending on the situation, the transmission power may be the same for each segment. In FIG. 1C, the first to fourth segments represent segments currently in use, and unused segments represent segments not currently in use.

Next, an operation of using frequency resources using a frequency resource use sequence according to an embodiment of the present invention will be described with reference to FIG. 2.

2 is a diagram schematically illustrating an operation of using a frequency resource by using a frequency resource use sequence according to an embodiment of the present invention.

Referring to FIG. 2, the frequency resource use sequence is a sequence illustrating a sequence of using segments. That is, each cell uses a segment using a frequency resource use sequence that is pre-assigned to each cell. Therefore, the length of the frequency resource use sequence is equal to the number of segments available in each cell.

In FIG. 2, the frequency resource use sequence is shown as a 'segment sequence', and the segment sequence is a ₁ a ₂ a ₃ ... a _N , and corresponds to the segment sequence a ₁ a ₂ a ₃ ... a _N. Segments are allocated. That is, since the segment sequence is a ₁ a ₂ a ₃ ... a _N , segment 1, segment 2, ..., segment N are used sequentially. In addition, since the frequency reuse coefficient is assumed to be 1 in each cell, the frequency reuse coefficient becomes 1 when the segment N is finally allocated.

In addition, although the transmission power used in each segment is illustrated in FIG. 2, the transmission power used in each segment may be different as described above.

In the following description, a frequency resource use sequence will be referred to as a 'segment sequence', and an operation of determining a segment sequence will be described below.

(1) First, the segment sequence indicates the order of segment use, and each cell uses a unique segment sequence having a length equal to the number of segments available for each cell.

(2) Segments first allocated between adjacent cells must be orthogonal to each other. Herein, a segment allocated first in each cell will be referred to as a 'base segment'.

(3) The segment sequence is determined in consideration of the ICI, and the segment sequence is determined in consideration of the frequency reuse coefficient and the sectorization coefficient in order to minimize the ICI.

First, when the segment sequence is determined in consideration of the frequency reuse coefficient, the case in which the type of the segment sequence used in each cell and the existing frequency reuse coefficient are the same will be described with reference to FIG. 3. In the present invention, since each cell of the multi-cell communication system assumes that the frequency reuse coefficient 1 is used, the multi-cell communication system using the frequency reuse coefficient 1 is intended to operate as if the frequency reuse coefficient K is used. In the case of convenience, it will be referred to as using the existing frequency reuse factor.

3 is a diagram illustrating segment sequences when the type of a segment sequence used in each cell and the existing frequency reuse coefficient are the same according to an embodiment of the present invention.

3 shows four segment sequences in the case where the existing frequency reuse factor 4 is assumed. In FIG. 3, for example, when a multi-cell communication system includes four cells, that is, a cell C0, a cell C1, a cell C2, and a cell C3, segment sequences allocated to each cell are illustrated. The segment sequence assigned to cell C0 is segment sequence C0, the segment sequence assigned to cell C1 is segment sequence C1, the segment sequence assigned to cell C2 is segment sequence C2, and the segment sequence assigned to cell C3 is segment sequence C3. to be. Here, the segment sequence C0, the segment sequence C1, the segment sequence C2, and the segment sequence C3 are as shown below.

Segment sequence C0: A-segment-> B-segment-> C-segment-> D-segment

Segment Sequence C1: B-Segment-> C-Segment-> D-Segment-> A-Segment

Segment Sequence C2: C-Segment-> D-Segment-> A-Segment-> B-Segment

Segment Sequence C3: D-Segment-> A-Segment-> B-Segment-> C-Segment

Secondly, when determining the segment sequence in consideration of the sectorization coefficient, the case in which the type of the segment sequence and the sectorization coefficient used in each cell are the same will be described with reference to FIG. 4.

4 is a diagram illustrating segment sequences when the type of a segment sequence used in each cell and the sectorization coefficient are the same according to an embodiment of the present invention.

4 shows three segment sequences in the case where the existing frequency reuse factor 3 is assumed. FIG. 3 shows, for example, segment sequences allocated to each sector when any cell C0 of the multi-cell communication system includes three, that is, sector α, sector β, and sector γ. The segment sequence assigned to sector α of cell C0 is segment sequence C0-α, the segment sequence assigned to sector β of cell C0 is segment sequence C0-β, and the segment sequence assigned to sector γ of cell C0 is segment sequence C0. -γ. Here, the segment sequence C0-α, the segment sequence C0-β, and the segment sequence C0-γ are as shown below.

Segment Sequence C0-α: A-Segment-> B-Segment-> C-Segment

Segment sequence C0-β: B-segment-> C-segment-> A-segment

Segment Sequence C0-γ: C-Segment-> A-Segment-> B-Segment

Then, the IFR scheme proposed by the present invention will be described with reference to the existing frequency reuse coefficient 3, the existing frequency reuse coefficient 4, and the existing frequency reuse coefficient 7 as an example.

FIG. 5 is a diagram illustrating an IFR scheme when an existing frequency reuse factor 3 is used, a first type segment use scheme, and an omnidirectional cell structure are used according to an embodiment of the present invention.

FIG. 5 illustrates three segment sequences in the case of using the existing frequency reuse factor 3, using the first type segment using scheme, and using the omni-directional cell structure. FIG. 5 shows, for example, segment sequences allocated to each cell when the multi-cell communication system uses the existing frequency reuse factor 3, that is, when cells are configured based on the cell C0, the cell C1, and the cell C2. The segment sequence assigned to cell C0 is segment sequence C0, the segment sequence assigned to cell C1 is segment sequence C1, and the segment sequence assigned to cell C2 is segment sequence C2. Here, the segment sequence C0, the segment sequence C1, and the segment sequence C2 are as shown below.

Segment Sequence C0: A-Segment-> B-Segment-> C-Segment

Segment Sequence C1: B-Segment-> C-Segment-> A-Segment

Segment Sequence C2: C-Segment-> A-Segment-> B-Segment

FIG. 6 is a diagram illustrating an IFR scheme in case of using an existing frequency reuse factor 3 according to an embodiment of the present invention, using a second type segment using scheme, and using an omnidirectional cell structure.

6 shows three segment sequences in the case of using the existing frequency reuse factor 3, using the second type segment using scheme, and using the omni-directional cell structure. FIG. 6 shows, for example, segment sequences allocated to each cell when a multi-cell communication system uses the existing frequency reuse factor 3, that is, when a cell is configured based on the cell C0, the cell C1, and the cell C2. The segment sequence assigned to cell C0 is segment sequence C0, the segment sequence assigned to cell C1 is segment sequence C1, and the segment sequence assigned to cell C2 is segment sequence C2. Here, the segment sequence C0, the segment sequence C1, and the segment sequence C2 are as shown below.

Segment Sequence C0: A-Segment-> Join Segment (B-Segment + C-Segment)

Segment Sequence C1: B-Segment-> Join Segment (A-Segment + C-Segment)

Segment Sequence C2: C-Segment-> Join Segment (A-Segment + B-Segment)

Here, the combined segment refers to a segment in which some or all of the segments except the basic segment are combined among the segments used in each cell. In FIG. 6, the combined segment shows a segment in which all of the segments except the basic segment are combined among the segments used in each cell.

FIG. 7 is a diagram illustrating an IFR method using an existing frequency reuse factor 3, using a first type segment, and using a sector cell structure according to an embodiment of the present invention.

FIG. 7 illustrates three segment sequences in the case of using the existing frequency reuse factor 3, using the first type segment using scheme, and using the sector cell structure.

FIG. 7 shows, for example, segment sequences allocated to each sector of cell C0, which is an arbitrary cell when each of the cells included in the multi-cell communication system includes three, that is, sector α, sector β, and sector γ. . The segment sequence assigned to sector α of cell C0 is segment sequence C0-α, the segment sequence assigned to sector β of cell C0 is segment sequence C0-β, and the segment sequence assigned to sector γ of cell C0 is segment sequence C0. -γ. Here, the segment sequence C0-α, the segment sequence C0-β, and the segment sequence C0-γ are as shown below.

Segment Sequence C0-α: A-Segment-> B-Segment-> C-Segment

Segment sequence C0-β: B-segment-> C-segment-> A-segment

Segment Sequence C0-γ: C-Segment-> A-Segment-> B-Segment

FIG. 8 is a diagram illustrating an IFR method using an existing frequency reuse factor 4, using a first type segment, and using an omni-directional cell structure according to an embodiment of the present invention.

8 shows four segment sequences in the case of using the existing frequency reuse factor 4, using the first type segment using scheme, and using the omnidirectional cell structure. In FIG. 8, for example, when a multi-cell communication system uses the existing frequency reuse factor 4, that is, when a cell is configured based on the cell C0, the cell C1, the cell C2, and the cell C3, segment sequences allocated to each cell are shown. Is shown. The segment sequence assigned to cell C0 is segment sequence C0, the segment sequence assigned to cell C1 is segment sequence C1, the segment sequence assigned to cell C2 is segment sequence C2, and the segment sequence assigned to cell C3 is segment sequence C3. to be. Here, the segment sequence C0, the segment sequence C1, the segment sequence C2, and the segment sequence C3 are as shown below.

Segment sequence C0: A-segment-> B-segment-> C-segment-> D-segment

Segment Sequence C1: B-Segment-> C-Segment-> D-Segment-> A-Segment

Segment Sequence C2: C-Segment-> D-Segment-> A-Segment-> B-Segment

Segment Sequence C3: D-Segment-> A-Segment-> B-Segment-> C-Segment

FIG. 9 is a diagram illustrating a first example of an IFR scheme in which an existing frequency reuse factor 4, a second type segment use scheme, and an omnidirectional cell structure are used according to an embodiment of the present invention.

FIG. 9 illustrates four segment sequences in the case of using the existing frequency reuse factor 4, using the second type segment using scheme, and using the omni-directional cell structure. In FIG. 9, for example, when a multi-cell communication system uses the existing frequency reuse factor 4, that is, when a cell is configured based on cell C0, cell C1, cell C2, and cell C3, segment sequences allocated to each cell are shown. Is shown. The segment sequence assigned to cell C0 is segment sequence C0, the segment sequence assigned to cell C1 is segment sequence C1, the segment sequence assigned to cell C2 is segment sequence C2, and the segment sequence assigned to cell C3 is C3. Here, the segment sequence C0, the segment sequence C1, the segment sequence C2, and the segment sequence C3 are as shown below.

Segment Sequence C0: A-Segment-> Join Segment (B-Segment + C-Segment)-> D-Segment

Segment Sequence C1: B-Segment-> Join Segment (C-Segment + D-Segment)-> A-Segment

Segment Sequence C2: C-Segment-> Join Segment (A-Segment + D-Segment)-> B-Segment

Segment Sequence C3: D-Segment-> Join Segment (A-Segment + B-Segment)-> C-Segment

9 shows a case in which some of the segments except the basic segment are combined among the segments used in each cell.

FIG. 10 illustrates a second example of an IFR scheme in which an existing frequency reuse factor 4 is used, a second type segment use scheme, and an omnidirectional cell structure are used according to an embodiment of the present invention.

FIG. 10 shows four segment sequences in the case of using the existing frequency reuse factor 4, using the second type segment using scheme, and using the omni-directional cell structure. In FIG. 10, for example, when a multi-cell communication system uses the existing frequency reuse factor 4, that is, when a cell is configured based on cell C0, cell C1, cell C2, and cell C3, segment sequences allocated to each cell are shown. Is shown. The segment sequence assigned to cell C0 is segment sequence C0, the segment sequence assigned to cell C1 is segment sequence C1, the segment sequence assigned to cell C2 is segment sequence C2, and the segment sequence assigned to cell C3 is C3. . Here, the segment sequence C0, the segment sequence C1, the segment sequence C2, and the segment sequence C3 are as shown below.

Segment Sequence C0: A-Segment-> B-Segment-> Join Segment (C-Segment + D-Segment)

Segment Sequence C1: B-Segment-> C-Segment-> Join Segment (A-Segment + D-Segment)

Segment Sequence C2: C-Segment-> D-Segment-> Join Segment (A-Segment + B-Segment)

Segment Sequence C3: D-Segment-> A-Segment-> Join Segment (B-Segment + C-Segment)

FIG. 11 illustrates a third example of an IFR scheme in which an existing frequency reuse factor 4 is used, a second type segment use scheme, and an omnidirectional cell structure are used according to an embodiment of the present invention.

11 shows four segment sequences in the case of using the existing frequency reuse factor 4, using the second type segment using scheme, and using the omni-directional cell structure. In FIG. 11, for example, when a multi-cell communication system uses the existing frequency reuse factor 4, that is, when a cell is configured based on the cell C0, the cell C1, the cell C2, and the cell C3, segment sequences allocated to each cell are shown. Is shown. The segment sequence assigned to cell C0 is segment sequence C0, the segment sequence assigned to cell C1 is segment sequence C1, the segment sequence assigned to cell C2 is segment sequence C2, and the segment sequence assigned to cell C3 is C3. Here, the segment sequence C0, the segment sequence C1, the segment sequence C2, and the segment sequence C3 are as shown below.

Segment Sequence C0: A-Segment-> Join Segment (B-Segment + C-Segment + D-Segment)

Segment Sequence C1: B-Segment-> Join Segment (A-Segment + C-Segment + D-Segment)

Segment Sequence C2: C-Segment-> Join Segment (A-Segment + B-Segment + D-Segment)

Segment Sequence C3: D-Segment-> Join Segment (A-Segment + B-Segment + C-Segment)

12 is a diagram illustrating an IFR method using an existing frequency reuse factor 4, using a first type segment, and using a sector cell structure according to an embodiment of the present invention.

FIG. 12 shows twelve segment sequences in the case of using the existing frequency reuse factor 3, using the first type segment using scheme, and using the sector cell structure.

In FIG. 12, for example, when each cell included in the multi-cell communication system includes three cells, that is, sectors α, sector β, and sector γ, segment sequences allocated to respective sectors of cells C0 to C3, which are arbitrary cells, are shown. Is shown. The segment sequence assigned to sector α of cell C0 is segment sequence C0-S00, the segment sequence assigned to sector β of cell C0 is segment sequence C0-S01, and the segment sequence assigned to sector γ of cell C0 is segment sequence C0. Segment sequence assigned to sector α of cell C1 is segment sequence C1-S03, segment sequence assigned to sector β of cell C1 is segment sequence C1-S04, segment sequence assigned to sector γ of cell C1 Is a segment sequence C1-S05, the segment sequence assigned to sector α of cell C2 is segment sequence C2-S06, the segment sequence assigned to sector β of cell C2 is segment sequence C2-S07, and to sector γ of cell C2. The segment sequence assigned is segment sequence C2-S08, the segment sequence assigned to sector α of cell C3 is segment sequence C3-S09, and the segment assigned to sector β of cell C3. The bit sequence is a sequence segment C3-S10, is the segment sequence assigned to sector γ of the cell C3 sequence segments C3-S11. Here, segment sequence C0-S00, segment sequence C0-S01, segment sequence C0-S02, segment sequence C1-S03, segment sequence C1-S04, segment sequence C1-S05, segment sequence C2-S06, , Segment sequence C2-S07, segment sequence C2-S08, segment sequence C3-S09, segment sequence C3-S10, and segment sequence C3-S11 are as shown below.

Segment Sequence C0-S00: A-Segment-> B-Segment-> C-Segment-> D-Segment-> E-Segment-> F-Segment-> G-Segment-> H-Segment-> I-Segment- > J-segment-> K-segment-> L-segment

Segment Sequence C0-S01: B-Segment-> C-Segment-> D-Segment-> E-Segment-> F-Segment-> G-Segment-> H-Segment-> I-Segment-> J-Segment- > K-segment-> L-segment-> A-segment

Segment Sequence C0-S02: C-Segment-> D-Segment-> E-Segment-> F-Segment-> G-Segment-> H-Segment-> I-Segment-> J-Segment-> K-Segment- > L-segment-> A-segment-> B-segment

Segment Sequence C1-S03: D-Segment-> E-Segment-> F-Segment-> G-Segment-> H-Segment-> I-Segment-> J-Segment-> K-Segment-> L-Segment- > A-segment-> B-segment-> C-segment

 Segment Sequence C1-S04: E-Segment-> F-Segment-> G-Segment-> H-Segment-> I-Segment-> J-Segment-> K-Segment-> L-Segment-> A-Segment- > B-segment-> C-segment-> D-segment

 Segment Sequence C1-S05: F-Segment-> G-Segment-> H-Segment-> I-Segment-> J-Segment-> K-Segment-> L-Segment-> A-Segment-> B-Segment- > C-segment-> D-segment-> E-segment

Segment Sequence C2-S06: G-Segment-> H-Segment-> I-Segment-> J-Segment-> K-Segment-> L-Segment-> A-Segment-> B-Segment-> C-Segment- > D-segment-> E-segment-> F-segment

Segment Sequence C2-S07: H-Segment-> I-Segment-> J-Segment-> K-Segment-> L-Segment-> A-Segment-> B-Segment-> C-Segment-> D-Segment- > E-segment-> F-segment-> G-segment

Segment Sequence C2-S08: I-Segment-> J-Segment-> K-Segment-> L-Segment-> A-Segment-> B-Segment-> C-Segment-> D-Segment-> E-Segment- > F-segment-> G-segment-> H-segment

Segment Sequence C3-S09: J-Segment-> K-Segment-> L-Segment-> A-Segment-> B-Segment-> C-Segment-> D-Segment-> E-Segment-> F-Segment- > G-segment-> H-segment-> I-segment

Segment Sequence C3-S10: K-Segment-> L-Segment-> A-Segment-> B-Segment-> C-Segment-> D-Segment-> E-Segment-> F-Segment-> G-Segment- > H-segment-> I-segment-> J-segment

Segment Sequence C3-S11: L-Segment-> A-Segment-> B-Segment-> C-Segment-> D-Segment-> E-Segment-> F-Segment-> G-Segment-> H-Segment- > I-segment-> J-segment-> K-segment

FIG. 13 is a diagram illustrating an IFR scheme using an existing frequency reuse factor 7 according to an embodiment of the present invention, a first type segment use scheme, and an omnidirectional cell structure.

FIG. 13 illustrates seven segment sequences in the case of using the existing frequency reuse factor 7, using the first type segment using scheme, and using the omni-directional cell structure. In FIG. 13, for example, when a multi-cell communication system uses the existing frequency reuse factor 7, that is, cell C0, cell C1, cell C2, cell C3, cell 3, cell 4, cell 5, and cell 6 When a cell is configured based on the segment sequences allocated to each cell are shown. The segment sequence assigned to cell C0 is segment sequence C0, the segment sequence assigned to cell C1 is segment sequence C1, the segment sequence assigned to cell C2 is segment sequence C2, and the segment sequence assigned to cell C3 is segment sequence C3. , The segment sequence assigned to cell C4 is segment sequence C4, the segment sequence assigned to cell C5 is segment sequence C5, and the segment sequence assigned to cell C6 is segment sequence C6. Here, the segment sequence C0, the segment sequence C1, the segment sequence C2, the segment sequence C3, the segment sequence C4, the segment sequence C5, and the segment sequence C6 are as shown below.

Segment sequence C0: A-segment-> B-segment-> C-segment-> D-segment-> E-segment-> F-segment-> G-segment

Segment Sequence C1: B-Segment-> C-Segment-> D-Segment-> E-Segment-> F-Segment-> G-Segment-> A-Segment

Segment Sequence C2: C-Segment-> D-Segment-> E-Segment-> F-Segment-> G-Segment-> A-Segment-> B-Segment

Segment Sequence C3: D-Segment-> E-Segment-> F-Segment-> G-Segment-> A-Segment-> B-Segment-> C-Segment

Segment Sequence C4: E-Segment-> F-Segment-> G-Segment-> A-Segment-> B-Segment-> C-Segment-> D-Segment

Segment Sequence C5: F-Segment-> G-Segment-> A-Segment-> B-Segment-> C-Segment-> D-Segment-> E-Segment

Segment Sequence C6: G-Segment-> A-Segment-> B-Segment-> C-Segment-> D-Segment-> E-Segment-> F-Segment

The embodiments described above divide the entire frequency band into a predetermined number of partial bands, and then reduce the inter-cell interference by systematically controlling the resource usage order of the partial bands for each cell.

However, through systematic inter-cell interference control through sequential resource utilization, the average performance improvement is achieved compared to the existing frequency reuse schemes, but it is quite difficult to guarantee the SINR required for cell-bound users with poor signal characteristics. Hard.

In the following embodiments, in order to compensate for the disadvantage, the partial band usage order as well as the partial band usage order are also reflected by reflecting factors such as distribution characteristics of users, interference relations due to resource allocation, and frequency load ratio of the center cell. to provide. In the following description, load factor means frequency load factor. In addition, in the following description, the load ratio refers to the ratio of the frequency band allocated to the current user among all the allocated frequency bands.

First, embodiments of the present invention divide a whole frequency into a certain number of partial bands, and some partial bands of the divided bands are quasi-orthogonal in which adjacent cells do not cause interference below a reference load factor. fundamental) as a band, which will be described in detail with reference to FIG. 14.

14 is a diagram for describing a quasi-orthogonal base band according to the present invention.

In order to systematically control interference between cells in a multi-cell environment, each cell sequentially uses subbands according to a predefined sequence, and resource allocation is performed within a corresponding band until all the resources within the allocated subband are exhausted. In this case, the quasi-orthogonal baseband is a band to which resources are allocated first in each cell, and the interference between adjacent cells is always kept low since no interference between adjacent cells is caused in the quasi-orthogonal basebands below a certain load factor. .

Referring to FIG. 14, the total available frequency band is divided into six partial bands 10 to 60. The resource usage order of the partial bands, i.e., the segment sequence, for each cell C1, C2 and C3 is determined. For example, in cell C1, the second partial band 20 is assigned first. Similarly, in cell C2 and cell C3 the fourth partial band 40 and the sixth partial band 60 are respectively assigned first. Thus, the second, fourth and sixth partial bands 20, 40 and 60 become quasi-orthogonal fundamental bands of cells C1, C2 and C3, respectively.

When allocating the quasi-orthogonal base band, dynamic channel allocation (DCA) may be performed in consideration of a user's SINR, a high signal quality request from a user, and the like. For example, by first assigning a quasi-orthogonal baseband with relatively low inter-cell interference to users located in a cell-boundary region with low SINR, inter-cell interference can be greatly reduced.

Hereinafter, embodiments of the present invention will be described in detail.

15 is a flowchart illustrating a method of using frequency resources according to an embodiment of the present invention. This frequency resource usage method is preferably performed in a base station for controlling radio resource allocation of cells.

Referring to FIG. 15, first, a fundamental frequency reuse factor is set in step 110. At this time, the set fundamental frequency reuse coefficient becomes a reference for band division. Subsequently, in step 120 the entire available frequency band is divided into a series of subbands based on the fundamental frequency reuse coefficient.

For example, the entire available frequency band is preferably divided by an integer multiple of the fundamental frequency reuse coefficient. For example, if the fundamental frequency reuse factor is 3, the total available frequency band is divided into six subbands (two times the fundamental frequency reuse coefficient), and if the fundamental frequency reuse factor is 4, the total available frequency bands are eight partial bands. It can be divided into As the number of divided bands increases, systematic interference control from an interfering cell layer far from the center-cell is possible. Therefore, the larger the fundamental frequency reuse coefficient is, the farther the distance between the affected interfering cells from the center cell is. That is, the fundamental frequency reuse coefficient determines the range of cells in which the center-cell causes interference in the initial partial band allocation. For example, in the design based on the frequency reuse factor 3, the resources of the center cell can be used first so that interference occurs only to the Tier-2 cells, and as the load ratio increases, the cells causing the interference expand to Tier-1 cells. . However, in the design based on the frequency reuse factor 7, interference occurs only to Tier-3 cells first, and as the load rate increases, interference occurs to Tier-2 and Tier-1 cells in turn.

Subsequently, the reference load factor is set. If all cells operate below the reference load factor, the quasi-orthogonal basebands have the same intercell interference characteristics as the system with the fundamental frequency reuse coefficient.

The reference load ratio is set differently when the sizes of all the partial bands are the same and when the sizes of the divided partial bands differ according to the size of the quasi-orthogonal base band.

(1) When all partial bands are the same size

When the partial bands are divided by a multiple of the fundamental frequency reuse coefficient, the reference load ratio may be defined by Equation 1 below.

Here, M, which is a plurality of band division criteria, is defined as an integer of 2 or more. For example, if M = 2, if the fundamental frequency reuse factor is 3, the reference load factor is 2/3. If the fundamental frequency reuse factor is 4, 5/8; if the fundamental frequency reuse factor is 7, 8/14. In addition, M is a parameter for determining the size of the quasi-orthogonal base band at the time of band division.

(2) When the size of the divided partial bands differs according to the size of the quasi-orthogonal base band

The number of divided partial bands is the same as M × FRF, but since the sizes of the quasi-orthogonal base band and the general partial band are different, the reference load ratio is defined by Equation 2 below.

Here, when M is 2, the quasi-orthogonal baseband is twice the size of the normal partial band, the base load reuse factor is 3, the reference load factor is 5/9, and the base frequency reuse factor is 4, 2/3, If the fundamental frequency reuse factor is 7, it is 3/7.

Subsequently, in step 140, the band allocation sequence is defined so that the sub-orthogonal base band below the reference load factor does not cause interference with adjacent cells in the quasi-orthogonal base bands. The quasi-orthogonal base band is a partial band allocated first to each cell. Thus, the band allocation sequence is set such that the quasi-orthogonal base band is assigned first, and other partial bands are allocated.

With reference to FIG. 16, the partial band allocation sequence in the case of the fundamental frequency reuse factor 3 and the reference load ratio 2/3 is demonstrated.

FIG. 16 is a diagram for describing inter-cell interference between a quasi-orthogonal band and the remaining general partial bands in the case of a fundamental frequency reuse factor 3 and a reference load ratio 2/3.

Referring to FIG. 16, the allocation order of partial bands (first to sixth bands) in each of the cells C1, C2, and C3 is shown. In the C1 cell, the first partial band allocated is the quasi-orthogonal base band. When the size of each partial band is the same, the quasi-orthogonal base band does not cause interference to Tier-1 cells under the reference load ratio ≤ 2/3 according to the above-described reference load ratio condition. In other words, no inter-cell interference occurs in the quasi-orthogonal base band until the partial bands corresponding to the fourth sequence in each cell are allocated.

17, the partial band allocation sequence in the case of the fundamental frequency reuse factor 4 and the reference load ratio 5/8 will be described.

FIG. 17 is a diagram for describing intercell interference between a quasi-orthogonal band and the remaining general subbands when the fundamental frequency reuse factor 4 and the reference load factor 5/8 are used.

Referring to FIG. 17, the allocation order of the partial bands (first band to eighth band) in each of the cells C1, C2, C3, and C4 is shown. In cell C1, the first partial band allocated first becomes the quasi-orthogonal base band. In the C2 cell, the first partial band allocated first becomes the quasi-orthogonal base band. In cell C3, the fifth partial band allocated first becomes the quasi-orthogonal base band. In cell C4, the seventh partial band allocated first becomes the quasi-orthogonal base band.

When the size of each partial band is the same, the quasi-orthogonal base band does not cause interference to the Tier-1 cells under the reference load rate, that is, LF (Loading Factor) ≤ 5/8, according to the aforementioned reference load rate condition. In other words, no inter-cell interference occurs in the quasi-orthogonal base band until partial bands corresponding to the fifth sequence in each cell are allocated.

The quasi-orthogonal baseband has a corresponding interference structure because inter-cell interference satisfies the fundamental frequency reuse structure below the load factor corresponding to the fundamental frequency reuse structure. Therefore, when used above the maximum acceptable load factor in the fundamental frequency reuse structure, the cells causing interference by the central cell due to the use of additional partial bands are increased as shown in FIG. 18.

FIG. 18 is a diagram illustrating a conceptual increase of incremental interference cells according to an increase in load rate when the fundamental frequency reuse factor is 3 and the reference load rate is 2/3.

For example, when M = 2, when the fundamental frequency reuse factor is 3, the reference load ratio is 2/3. Referring to FIG. 18A, a quasi-orthogonal base band in each cell (eg, a second band in a C1 cell, a fourth band in a C2 cell, and a C3 cell in a case where the load ratio is 2/3 or less) 6 bands) no interference occurs between cells. Referring to FIG. 18B, when the load ratio is 5/6 or less, for example, since the quasi-orthogonal baseband of the C1 cell is allocated to the C2 cell, interference with the C2 cell occurs in the quasi-orthogonal baseband of the C1 cell. Done. Similarly, referring to FIG. 18 (c), in the case where the load ratio is 6/6 or less, for example, the quasi-orthogonal baseband of the C1 cell is allocated to the C3 cell as well as the C2 cell, so that Interference with the C2 cell and the C3 cell occurs.

As described above, after the partial band allocation sequence is set, the partial bands are allocated to each cell upon a service request from the user according to the band allocation sequence set in step 150. For example, when a new user requests a service in each cell, the base station preferentially allocates to the quasi-orthogonal base band and may assign any empty subchannel of the quasi-orthogonal base band to the user.

In addition, when allocating partial bands, SINR, user's required signal quality, and the like may be considered.

Considering the SINR, the quasi-orthogonal baseband may be first assigned to cell-boundary users with low SINR because the inter-neighbor interference remains relatively low. Therefore, the base station arranges users in the order of low SINR in the partial band allocation process, and assigns the users to the quasi-orthogonal base band from the low SINR. Optionally, the base station periodically evaluates the SINR again, allowing users with relatively low SINRs to move to the quasi-orthogonal baseband, and users with SINRs that exceed the relatively high quasi-orthogonal baseband size to the normal partial band. You can move it.

In consideration of the required signal quality of the user, the quasi-orthogonal baseband may be allocated to users who need to maintain high signal quality or users who need a lot of performance improvement because the interference between adjacent cells is relatively low.

As such, in consideration of the required signal quality and SINR of the users in the partial band allocation process, the quasi-orthogonal baseband may be preferentially allocated to users who require high signal quality or users having low SINR.

Hereinafter, the sequence setting method will be described in more detail.

According to an embodiment of the present invention, the band allocation sequence can be largely divided into a sequence for semi-orthogonal base band allocation and a sequence for general partial band allocation.

In general, the quasi-orthogonal baseband has a different length depending on the number of adjacent cells. If a quasi-orthogonal band is set between N adjacent cells, interference should not occur between the bands below the reference load factor. In this case, the length of the quasi-orthogonal baseband sequence is N, and a cyclic sequence in which the partial band is shifted by one step may be set to allocate the quasi-orthogonal baseband to each cell.

Practical implementation example (for base frequency reuse factor 4 = semi-orthogonal baseband setting between four adjacent cells)

In this case, the first partial bands allocated for each cell are set to the quasi-orthogonal base band of the cell, and the remaining partial bands of the quasi-orthogonal base band sequence cause mutual interference to the quasi-orthogonal base bands of adjacent cells. Because of the allocation of the general partial band is finally allocated.

On the other hand, since the total number of partial bands according to the division result is an integer multiple of the fundamental frequency reuse coefficient, if the length of the quasi-orthogonal baseband sequence is N, the number of general partial bands is an integer multiple of N. Since the interference between adjacent cells should increase on average in the general partial band allocation, a sequence in which the partial band is shifted by one step in a predetermined allocation sequence may be set for each cell.

Example of practical implementation (for base frequency reuse factor 4 = if there are 4 common subbands)

The above-described allocation sequence of the quasi-orthogonal base band and the allocation sequence of the general partial band may be combined, and thus the partial band allocation sequence of each cell may be configured as shown in FIG. 19.

19 is a diagram illustrating an entire sequence design principle for partial band allocation.

Referring to FIG. 19, the first partial bands of the quasi-orthogonal baseband sequence of each cell are selected as the quasi-orthogonal band of the cell. Then, the general partial band allocation sequence of each cell is combined. Finally, the other quasi-orthogonal baseband sequences except the quasi-orthogonal baseband of each cell are combined.

As described above, in the present invention, by controlling the order of use of the divided partial bands, it is possible to form a quasi-orthogonal base band capable of keeping the interference from adjacent cells as low as possible while maintaining the frequency reuse coefficient 1. In other words, below the reference load factor, the center cell quasi-orthogonal band is set so as not to cause interference in the quasi-orthogonal base bands of each of the adjacent cells. By preferentially allocating such quasi-orthogonal basebands to cell-boundary users with poor signal characteristics, it is possible not only to greatly improve cell-boundary user performance but also to improve overall system performance. In addition, since the present invention is a flexible resource utilization structure based on the frequency reuse coefficient 1, by adjusting the order of partial band use, it can be operated by the traditional frequency reuse technique (eg, FRF = 3, 4, 7…), and the allocation of some bands. By adjusting the order and inter-cell interference, various frequency reuse schemes such as SFR and FFR can be used.

1A illustrates a method of using a first type segment according to an embodiment of the present invention.

1B is a view illustrating a second type segment use scheme according to an embodiment of the present invention.

1C is a diagram illustrating a method of controlling transmission power in units of segments according to an embodiment of the present invention.

2 is a diagram schematically illustrating an operation of using a frequency resource using a frequency resource use sequence according to an embodiment of the present invention.

3 is a diagram illustrating segment sequences when the type of segment sequence used in each cell and the existing frequency reuse coefficient are the same according to an embodiment of the present invention.

4 is a diagram illustrating segment sequences when the type of a segment sequence used in each cell and the sectorization coefficient are the same according to an embodiment of the present invention.

FIG. 5 is a diagram illustrating an IFR method using an existing frequency reuse factor 3 according to an embodiment of the present invention, using a first type segment, and using an omni-directional cell structure. FIG.

FIG. 6 is a diagram illustrating an IFR scheme using an existing frequency reuse factor 3 according to an embodiment of the present invention, a second type segment using scheme, and an omnidirectional cell structure.

FIG. 7 is a diagram illustrating an IFR method using an existing frequency reuse factor 3, using a first type segment, and using a sector cell structure according to an embodiment of the present invention.

8 is a diagram illustrating an IFR method using an existing frequency reuse factor 4, using a first type segment, and using an omni-directional cell structure according to an embodiment of the present invention.

FIG. 9 illustrates a first example of an IFR scheme in which an existing frequency reuse factor 4 is used, a second type segment use scheme, and an omni-directional cell structure are used according to an embodiment of the present invention.

FIG. 10 is a diagram illustrating a second example of an IFR scheme in which an existing frequency reuse factor 4 is used, a second type segment use scheme, and an omnidirectional cell structure are used according to an embodiment of the present invention.

FIG. 11 illustrates a third example of an IFR scheme in which an existing frequency reuse factor 4 is used, a second type segment use scheme, and an omnidirectional cell structure are used according to an embodiment of the present invention.

12 is a diagram illustrating an IFR method using an existing frequency reuse factor 4, using a first type segment, and using a sector cell structure according to an embodiment of the present invention.

FIG. 13 is a diagram illustrating an IFR method using an existing frequency reuse factor 7, using a first type segment, and using an omni-directional cell structure according to an embodiment of the present invention.

14 is a diagram for describing a quasi-orthogonal base band according to the present invention.

15 is a flowchart illustrating a method of using frequency resources according to an embodiment of the present invention.

FIG. 16 is a diagram illustrating inter-cell interference of a quasi-orthogonal band and the remaining general subbands in the case of a fundamental frequency reuse factor 3 and a reference load ratio 2/3;

FIG. 17 is a diagram illustrating inter-cell interference between a quasi-orthogonal band and the remaining general subbands at a fundamental frequency reuse factor of 4 and a reference load ratio of 5/8; FIG.

18 is a diagram illustrating a conceptual increase of incremental interference cells according to an increase in the load ratio when the fundamental frequency reuse factor is 3 and the reference load ratio is 2/3.

19 illustrates the overall sequence design principle for partial band allocation.

Claims (30)

A method of using frequency resources in a multi-cell communication system, Using a frequency resource using a segment sequence in which each cell included in the multi-cell communication system is preset; The available frequency bands available for each cell are the same, the available frequency band is divided into A segments, one segment is divided into B partial bands, and one partial band is divided into C channels. The segment sequence indicates a sequence of using the A segments. The method of claim 1, The size of the partial band and segment is the same in each cell, characterized in that the frequency resource usage method. The method of claim 1, And when B is an integer of 2 or more, the two or more segments exist in physically contiguous positions. The method of claim 1, And when B is an integer of 2 or more, the two or more segments are located at physically discontinuous positions. The method of claim 1, And if C is an integer greater than or equal to 2, the two or more channels are physically contiguous. The method of claim 1, And when C is an integer greater than or equal to 2, the two or more channels are located at physically discontinuous positions. The method of claim 1, And the segment sequence is determined using a frequency reuse coefficient and a sectorization coefficient. The method of claim 1, Segment first used in each cell is orthogonality between adjacent cells or sectors. A method of using frequency resources in a multi-cell communication system including at least two cells, Using resources using a frequency resource use sequence in which the at least two cells are preset; When the available frequency bands available for the at least two cells are the same and the available frequency band is divided into at least two frequency bands, And the frequency resource usage sequence indicates an order of using the at least two frequency bands. The method of claim 9, A frequency band using method, characterized in that the first frequency band used in each cell are orthogonal to each other. The method of claim 9, The frequency resource usage sequence is determined using a frequency reuse coefficient and a sectorization coefficient. In the frequency resource using system in a multi-cell communication system, Each cell included in the multi-cell communication system is controlled to use a frequency resource using a preset segment sequence, The available frequency bands available for each cell are the same, the available frequency band is divided into A segments, one segment is divided into B partial bands, and one partial band is divided into C channels. And said segment sequence indicates the order of using said A segments. The method of claim 12, And the size of the partial band and the segment is the same in each cell. The method of claim 12, And if B is an integer greater than or equal to 2, the at least two segments are in physically contiguous positions. The method of claim 12, And if B is an integer greater than or equal to 2, the two or more segments are located at physically discontinuous positions. The method of claim 12, And if C is an integer greater than or equal to 2, the at least two channels are in physically contiguous positions. The method of claim 12, And when C is an integer greater than or equal to 2, the two or more channels are located at physically discontinuous positions. The method of claim 12, And said segment sequence is determined using a frequency reuse coefficient and a sectorization coefficient. The method of claim 12, Segment first used in each cell is orthogonal to each other between adjacent cells or sectors. A frequency resource using system in a multi-cell communication system including at least two cells, The at least two cells are controlled to use resources by using a preset frequency resource use sequence. When the available frequency bands available for the at least two cells are the same and the available frequency band is divided into at least two frequency bands, And the frequency resource usage sequence indicates an order of using the at least two frequency bands. The method of claim 20, A frequency resource using system, characterized in that the first frequency band used in each cell is orthogonal to each other. The method of claim 20, The frequency resource usage sequence is determined using a frequency reuse coefficient and a sectorization coefficient. A method of using frequency resources in a multi-cell communication system, Dividing the entire available frequency bands of cells included in the multi-cell communication system into a series of partial bands based on a fundamental frequency reuse factor; Setting a reference frequency load ratio by using the fundamental frequency reuse factor; Defining a quasi-orthogonal fundamental band for each cell, in which adjacent cells do not cause interference below a reference frequency load factor of the series of partial bands, Determining an allocation sequence such that the quasi-orthogonal baseband is assigned first for each cell; And allocating the partial bands to each cell upon service request from a user according to the allocation sequence. 24. The method of claim 23, wherein the reference frequency load ratio is defined by the following equation when the sizes of the partial bands are all the same. Equation

Where M is the band division criterion and is an integer greater than or equal to 2 and FRF is the fundamental frequency reuse factor. 24. The method of claim 23, wherein allocating the partial bands to each cell is a process of allocating the partial bands to each cell in consideration of user's required signal quality. 24. The method of claim 23, wherein the allocating the partial bands to each cell is a process of allocating the partial bands to each cell in consideration of SINRs of users. In the frequency resource using system in a multi-cell communication system, Dividing the entire available frequency bands of cells included in the multi-cell communication system into a series of subbands based on a fundamental frequency reuse coefficient, setting a reference frequency load ratio using the fundamental frequency reuse coefficient, and the series of portions Below the reference frequency load factor of the bands, a quasi-orthogonal fundamental band is defined for each cell where neighboring cells do not cause interference, and the quasi-orthogonal fundamental band is first assigned to each cell. And a base station for allocating the partial bands to each cell upon service request from a user according to the allocation sequence. 28. The system of claim 27, wherein the reference frequency load rate is defined by the following equation when the magnitudes of the partial bands are all the same. Equation

Where M is the band division criterion and is an integer greater than or equal to 2 and FRF is the fundamental frequency reuse factor. 28. The system of claim 27, wherein the base station allocates the partial bands to each cell in consideration of required signal quality of users. 28. The system of claim 27, wherein the base station allocates the partial bands to each cell in consideration of SINRs of users.

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