JP2009182747A - Method and device for estimating geographical distribution of mobile station - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a method and system for estimating a geographical distribution of mobile stations. <P>SOLUTION: This geographical distribution estimation device 12 is a device for estimating a geographical distribution of mobile stations UE in a cell A controlled by a base station Node B and includes an adjacent cell information accumulating part 203 for accumulating the number of notifications Cmr of each adjacent cell on the basis of adjacent cell information of a cell notified by a plurality of mobile stations UE located within the cell A, and a geographical distribution determining part 205 for determining a geographical distribution of the mobile stations UE within the cell A on the basis of the number of notifications in each adjacent cell. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a mobile communication system, and more particularly to a method and apparatus for estimating a distribution state of a plurality of mobile stations.

  In the cellular mobile communication system, the cell coverage can be adjusted by changing the angle of the antenna of the base station. For example, if the population is expected to increase rapidly in a certain area due to residential land development or condominium construction, etc., if many users move around the area during commuting hours, or if an event is held, many users will When concentrating at a location, it is possible to optimize the area by adjusting the cell coverage of an existing base station so as to avoid a congestion state.

  From the viewpoint of efficient use of radio resources, a radio resource sharing control method has been proposed in which mobile stations are grouped and the base stations to which the mobile stations are connected are changed so that the radio resources are evenly used. (For example, patent document 1).

JP 2006-115291 A

  However, in area optimization, when the coverage is adjusted by changing the angle of the antenna, if many users are distributed on the cell boundary in the area after the change, when the load on the cell increases, the mobile station is located at a position with poor communication quality. More users will use it.

  Further, in the distributed control using the radio resource proposed in Patent Document 1, the connection destination is changed according to the usage state of the radio resource, so even if the user located at the cell boundary is changed, the connection destination is still Forced to use with low communication quality.

  Such a situation is caused by adjusting the coverage and controlling the radio resources without grasping the user distribution in the cell. Until now, no means for grasping the geographical distribution of users has been proposed.

  Therefore, an object of the present invention is to provide a method and system for estimating the geographical distribution of mobile stations.

  A geographical distribution estimation apparatus according to the present invention is an apparatus for estimating a geographical distribution of mobile stations in a cell controlled by a base station, and is adjacent to the cell notified by a plurality of mobile stations located in the cell. Neighboring cell information counting means for counting the number of notifications for each adjacent cell based on cell information; and geographic distribution determining means for determining the geographical distribution of mobile stations in the cell based on the number of notifications for each neighboring cell; It is characterized by having.

  According to the present invention, the geographical distribution of mobile stations located in a cell can be estimated.

  Hereinafter, a WCDMA (Wideband Code Division Multiple Access) system will be described as an example, but the present invention is not limited to this.

1. FIG. 1 is a block diagram of a mobile communication system to which a geographical distribution estimation system according to an embodiment of the present invention is applied. Here, in order not to make the description complicated, an example in which two adjacent base stations (NodeB) 10 and 11 are connected to the geographical distribution estimation device 12 is illustrated, but three or more base stations NodeB are connected. May be.

  The geographical distribution estimation device 12 is provided with at least an adjacent cell information totaling unit and a resource consumption totaling unit, and uses the adjacent cell information from the mobile station UE and the resource consumption information from the base station NodeB to Estimate the geographical distribution of the mobile station UE at. The geographical distribution estimation device 12 and each base station NodeB may be connected via a network. However, as will be described later, the geographical distribution estimation device 12 is connected to the base station controller RNC (in order to collect necessary information. A configuration that connects to a radio network controller is desirable.

  Each base station covers one or more cells. When the base station is sectorized by a plurality of antennas, each sector is called a cell. In the example illustrated in FIG. 1, the base station 10 covers the cells 10A to 10C, and the base station 11 covers the cells 11A to 11C. In the cell positional relationship shown in FIG. 1, for example, the adjacent cells of the cell 10 </ b> A are the cells 10 </ b> B and 10 </ b> C of the same base station 10 and the cell 11 </ b> C of the adjacent base station 11.

  A plurality of mobile stations UE (User Equipment) are located in the cell, and are connected to the base station of the cell via a radio interface. As will be described later, when the mobile station UE approaches the cell boundary, the mobile station UE reports the quality of neighboring cells to the base station controller RNC with a Measurement Report Message (hereinafter referred to as Measurement Report notification) for handover. Also, each base station monitors the resource consumption proportional to the call volume and periodically reports it to the base station controller RNC.

  The geographical distribution estimation apparatus 12 according to the present embodiment collects neighboring cell information and resource consumption using the measurement report notification received by the base station controller RNC and the resource consumption that is periodically reported, and the mobile station Estimate the geographical distribution of the UE.

  Thus, according to the present embodiment, since the geographical distribution of the mobile stations UE located in each cell can be estimated, in addition to the surface tuning that simulates radio wave propagation, the actual traffic situation This makes it possible to perform more accurate placement design and area tuning. Hereinafter, a specific implementation example will be given and described in detail.

2. System Configuration FIG. 2 is a block diagram showing the configuration of a geographical distribution estimation system according to an embodiment of the present invention. Here, a case where the geographical distribution estimation system is implemented in the base station controller RNC is illustrated.

  The base station NodeB is connected to the radio interface 101 that performs radio communication with the mobile station UE, the base station control unit 102 that controls the overall operation of the base station, the resource management unit 103 that manages radio resources, and the base station control device 20 The interface 104 is provided. The resource management unit 103 monitors the consumption of resources allocated to the mobile station UE located in the cell to be covered for each cell, and periodically sends the resource consumption of each cell and each base station to the base station controller 20. Report.

  Further, each mobile station UE located in a cell covered by the base station NodeB detects that the cell boundary is approaching due to a decrease in the electric field strength of the cell and an increase in the electric field strength of the surrounding cells. When approaching the cell boundary, the mobile station UE reports the radio quality of neighboring cells to the base station controller 20 using a Measurement Report notification for handover. Since each cell is assigned a scrambling code, the mobile station UE can identify the cell by the scrambling code.

  In addition to the interface 201 for connecting to the base station NodeB and the control unit 202 for controlling the overall operation of the base station control device, the base station control device 20 performs radio quality tabulation as a geographical distribution estimation device according to the present embodiment. A unit 203, a base station resource consumption totaling unit 204, and a geographical distribution determining unit 205. Furthermore, by storing the geographical positional relationship of the cells, the geographical distribution determining unit 205 can grasp the distribution of mobile stations in the cell in more detail.

  FIG. 3 is a sequence diagram showing an example of data transmission in the geographical distribution estimation system according to this embodiment. For example, it is assumed that a plurality of mobile stations UE exist in a cell A of a certain base station NodeB, and some mobile stations UE approach a cell boundary. These mobile stations UE transmit a measurement report notification including the radio quality of neighboring cells to the base station controller 20 via the base station NodeB. Further, the base station NodeB monitors the total (resource consumption) of resources allocated to the mobile stations UE in the cell to be covered, and notifies the base station control device 20 at regular time intervals (S301, S302, S303,...). ).

  The radio quality totaling unit 203 implemented in the base station control device 20 analyzes the measurement report notification and totals the number of appearances of adjacent cells for each cell, and the base station resource consumption totaling unit 204 calculates the resource consumption of each base station NodeB. The amount is totaled for each cell. By combining these total values, the geographical distribution determination unit 205 can estimate the relative geographical bias of the mobile station UE, as will be described later. Furthermore, the geographical distribution determination unit 205 can also estimate in which direction the mobile stations UE are biased by counting the number of occurrences of Measurement Report notification for each neighboring cell of a certain cell.

3. Data Aggregation FIG. 4A is a flowchart showing a radio quality aggregation procedure, and FIG. 4B is a flowchart showing a base station resource consumption aggregation procedure.

  In FIG. 4A, when the radio quality totaling unit 203 receives a measurement report notification from a mobile station UE located in each cell (hereinafter referred to as a target cell for convenience) (step S401), the radio quality totaling unit 203 sends the measurement report notification. Analyzing and extracting the scrambling code of the neighboring cell as the handover destination, and identifying the neighboring cell of the target cell (step S402). And about the attention cell, the frequency | count of measurement report notification which makes it a handover destination is counted for every adjacent cell. By performing the same counting process for all measurement report notifications transmitted from the target cell, the number of measurement report notifications for each adjacent cell is totaled (step S403). Under the control of the control unit 202, the tabulation results obtained in this way are output to the geographical distribution determination unit 205 at regular time intervals (step S404).

  In FIG. 4 (B), the base station resource consumption totalization unit 204 receives the resource consumption for each cell of the base station from the resource management unit 103 of the base station NodeB (step S410), and totalizes for each cell (step S410). Step S411). Then, the resource consumption total result for each cell is output to the geographical distribution determination unit 205 at regular time intervals (step S412).

  Hereinafter, a radio quality aggregation, a base station resource consumption aggregation, and an aggregation sequence serving as a determination material of the geographical distribution determination unit 205 will be described using specific examples.

  FIG. 5A is a schematic diagram showing an example of the cell A and its neighboring cells, FIG. 5B is a diagram showing an example of data aggregated by the radio quality aggregating unit 203, and FIG. It is a schematic diagram which shows the totaling sequence which totaled quality tabulation and resource consumption for every fixed time.

  As an example, as shown in FIG. 5A, the target cell is cell A, and scrambling codes (SC) “100”, “101”, “102”. Assume that there is an adjacent cell. As described above, the mobile station UE located in the cell A and located near the cell boundary transmits a measurement report notification including the reception quality of the neighboring cells to the base station controller 20.

  When a measurement report notification is received from a certain mobile station UE located in the cell A, the radio quality totaling unit 203 of the base station control device 20 analyzes the measurement report notification and scrambles the cells listed in the neighboring cell list. The neighboring cell is identified from the ring code, and the number of measurement report notifications is counted. By performing the same counting process for all measurement report notifications transmitted from the cell A, the number of measurement report notifications for each adjacent cell for the cell A can be totaled.

  An example of the total result obtained in this way is shown in FIG. For example, the measurement report notification in which the adjacent cell with the scrambling code SC = 100 is selected as the handover destination cell is generated 30 times in total. The total Cx of measurement report notification counts for all adjacent cells is the total number of measurement report notifications received from the cell A.

  The geographic distribution determination unit 205 receives the wireless quality tabulation data shown in FIG. 5B from the radio quality tabulation unit 203, and receives the base station resource consumption tabulation from the base station resource consumption tabulation unit 204. Then, it is possible to estimate the distribution bias in the cell A of the mobile station UE by combining these tabulated data, and to estimate the temporal change of the distribution based on the tabulated data sequence shown in FIG.

  FIG. 5C shows a totaling sequence when the data totaling time is 1 hour. However, the aggregation period can be set arbitrarily. The resource consumption Ry indicates the ratio of the resource consumption of the cell A to the total resources of the base station NodeB. For example, the total data 501 indicates radio quality total data and resource consumption (ratio) from 0:00 to 1:00, and the total data 502 indicates radio quality total data and resource consumption (ratio) from 1 o'clock to 2 o'clock. Show.

4). Estimation of Geographic Distribution 4.1) First Example FIG. 6 is a flowchart showing a geographical distribution estimation method according to a first example of the present invention. First, the control unit 202 starts a timer for measuring a totaling period for data totaling, and causes the wireless quality totaling unit 203 and the base station resource consumption totaling unit 204 to perform the above-described data totaling until time is up.

  When the timer times out and the data aggregation is completed (step S601), the geographical distribution determination unit 205 inputs the wireless quality aggregation data for each adjacent cell for the cell A from the wireless quality aggregation unit 203 (step S602). Resource consumption total data for each cell of the station NodeB is input from the base station resource consumption totaling unit 204 (step S603). The geographical distribution determination unit 205 uses the wireless quality tabulation data and the resource consumption tabulation data to summarize the tabulation data as shown in FIG. 5C, and the total number Cx of measurement report notifications about the cell A and the resource consumption The amount Ry is calculated (step S604).

  The geographical distribution determination unit 205 includes a threshold function a (x) for determining the central distribution in which the threshold of the resource consumption (ratio) changes depending on the total number x of measurement report notifications, and the total number of measurement report notifications. A threshold distribution function b (x) for determining a boundary distribution in which a threshold value of resource consumption (ratio) changes depending on x is set in advance (see FIG. 7 for a specific example). These threshold functions a (x) and b (x) are criteria for distribution determination, but are relative criteria that depend on the total number of measurement report notifications of other cells. When estimating only whether or not the distribution of the mobile stations UE is gathered at the cell boundary, the threshold function b (x) for determining the boundary distribution is appropriately translated in the direction in which the resource consumption increases. Use it.

  The geographical distribution determination unit 205 determines whether or not the point (Cx, Ry) determined by the summed MR total number x = Cx and the resource consumption y = Ry is in an area above the threshold function a (x). Is determined (step S605).

  If Ry> a (Cx) (step S605: YES), it is estimated that the mobile stations UE located in the cell A are distributed unevenly around the antenna (center part) of the cell (step S606).

  If Ry <b (Cx) (step S605: NO, step S607: YES), it is estimated that the mobile stations UE located in the cell A are biased and distributed near the cell boundary (step S608).

  If b (Cx) ≦ Ry ≦ a (Cx) (step S607: NO), it is estimated that the mobile station UE located in the cell A has a relatively small distribution bias (step S609). A specific example of this distribution estimation will be described with reference to FIG.

  FIG. 7 is a schematic diagram showing an example of a geographical distribution estimation method according to the first embodiment. The horizontal axis x is the total number of measurement report notifications Cx in any cell, and the vertical axis y is the resource consumption (ratio) Ry in any cell.

  As shown in FIG. 7, when the resource consumption Ry with respect to the summed MR total number Cx is in a region 701 exceeding the threshold function a (Cx) for determining the central distribution, it is estimated that there are many mobile stations UE around the antenna. it can. This is because the fact that the number of measurement report notifications Cx is small compared to other cells despite the large call volume (Ry is large) is considered to be because the movement of users around the cell is small. On the contrary, when it is in the region 702 that is below the threshold function b (x) for boundary distribution determination, it can be estimated that there are many mobile stations UE on the cell boundary.

  As described above, according to the present embodiment, the radio quality totaling unit 203 totals the frequency for each adjacent cell from the Measurement Report notification transmitted from the mobile station UE and reports the frequency to the geographical distribution determining unit 205. The base station resource consumption totaling unit 204 totals the resource consumption notified from the resource management unit 103 of the base station for each cell and reports it to the geographical distribution determination unit 205. The geographical distribution determination unit 205 estimates the distribution bias of the mobile station UE by comparing the total number of measurement report receptions and the ratio of resource consumption with a predetermined distribution determination threshold.

4.2) Second Embodiment As shown in FIGS. 5B and 5C, the mobile station UE in the cell A that is the cell of interest is the main cell by counting the number of measurement report notifications Cmr for each adjacent cell. It is possible to estimate the direction in which the adjacent cells are distributed, that is, which adjacent cell side is biased. For example, in the aggregated data 501 in FIG. 5C, the number of adjacent cell measurement report notifications Cmr with the scrambling code SC = 102 is 100, which is higher than other adjacent cells. Therefore, it can be estimated that the distribution of the mobile stations UE is biased toward the boundary in the vicinity of the adjacent cell (SC = 102) in the time band of the total data 501.

  Therefore, the geographical distribution estimation apparatus according to the second embodiment of the present invention is provided with a cell position memory storing the cell position relation, and estimates the mobile station distribution bias and its direction by referring to the cell position relation. .

  FIG. 8 is a flowchart showing a geographical distribution estimation method according to the second embodiment of the present invention. First, the control unit 202 starts a timer for measuring a totaling period for data totaling, and causes the wireless quality totaling unit 203 to perform the above-described data totaling until time-out.

  When the timer times out and the data aggregation is completed (step S801), the geographical distribution determination unit 205 inputs the wireless quality aggregation data for each adjacent cell for the cell A from the wireless quality aggregation unit 203 (step S802). As shown in FIG. 5B, the geographical distribution determination unit 205 summarizes the radio quality summary data and calculates the measurement report notification count Cmr for each cell adjacent to the cell A (step S803).

  Subsequently, the geographical distribution determination unit 205 refers to the measurement report notification count Cmr for each adjacent cell and the positional relationship between the own cell A and the adjacent cell, and estimates the distribution bias of the mobile stations UE in the cell A. (Step S804).

  FIG. 9 is a schematic cell configuration diagram showing an example of the positional relationship between the cell A and the adjacent cell in the second embodiment. In such a cell configuration, for example, if the number of measurement report notifications Cmr of adjacent cell B Cmr = 10 and Cmr = 90 of adjacent cell C, the mobile stations UE in cell A are mainly distributed in the vicinity of cell C. Thus, it can be estimated that the cell B is not unevenly distributed.

  As described above, according to the present embodiment, the radio quality totaling unit 203 totals the frequency for each adjacent cell from the Measurement Report notification transmitted from the mobile station UE and reports the frequency to the geographical distribution determining unit 205. The geographical distribution determination unit 205 estimates the distribution bias of the mobile station UE from the number of times measurement report notifications are received for each neighboring cell and the positional relationship between the own cell and the neighboring cell.

  It is also possible to combine the first embodiment and the second embodiment. That is, the geographical distribution determination unit 205 estimates the distribution bias of the mobile station UE by comparing the total number of receptions of the measurement report notification and the ratio of the resource consumption amount with a predetermined distribution determination threshold, It is also possible to estimate the distribution deviation of the mobile station UE in more detail from the number of measurement report notifications received for each neighboring cell and the positional relationship between the own cell and the neighboring cell.

5. Other Embodiments In the above-described embodiments, an example in which a geographical distribution estimation device is mounted on the base station control device 20 has been described, but the present invention is not limited to this. For example, a geographical distribution estimation device including a radio quality totaling unit 203, a base station resource consumption totaling unit 204, and a geographical distribution determination unit 205 is provided outside the base station control device RNC, and a measurement report notification and resource consumption from the RNC are provided. It is also possible to configure to receive the information. Specifically, the geographical distribution estimation device and the RNC are connected via a network or the like.

  The present invention is applicable to station location design and area optimization of WCDMA systems.

1 is a block diagram of a mobile communication system to which a geographical distribution estimation system according to an embodiment of the present invention is applied. It is a block diagram which shows the structure of the geographical distribution estimation system by one Example of this invention. It is a sequence diagram which shows an example of the data transmission in the geographical distribution estimation system by a present Example. (A) is a flowchart showing a procedure for counting radio quality, and (B) is a flowchart showing a procedure for counting base station resource consumption. (A) is a schematic diagram showing an example of cell A and its neighboring cells, (B) is a diagram showing an example of data aggregated by the radio quality aggregating unit 203, and (C) is radio quality aggregation and resource consumption. It is a schematic diagram which shows the totaling sequence which totaled for every fixed time. 4 is a flowchart illustrating a geographical distribution estimation method according to the first embodiment of the present invention. It is a schematic diagram which shows an example of the geographical distribution estimation method by 1st Example. It is a flowchart which shows the geographical distribution estimation method by 2nd Example of this invention. It is a typical cell block diagram which shows an example of the positional relationship of the cell A and 2nd cell in 2nd Example.

Explanation of symbols

10, 11 Base station 12 Geographic distribution estimation device 20 Base station control device 101 Radio interface 102 Base station control unit 103 Resource management unit 104 Interface 201 Interface 202 Control unit 203 Radio quality totaling unit 204 Base station resource consumption totaling unit 205 Geography Distribution determination unit

Claims (13)

In an apparatus for estimating a geographical distribution of mobile stations in a cell controlled by a base station,
Neighboring cell information counting means for counting the number of notifications for each neighboring cell based on the neighboring cell information of the cell notified by a plurality of mobile stations located in the cell;
Geographical distribution determination means for determining the geographical distribution of mobile stations in the cell based on the number of notifications for each adjacent cell;
A geographical distribution estimation apparatus characterized by comprising: Further comprising resource consumption totalization means for totalizing the resource consumption of the cell based on the resource consumption information notified from the base station;
The geographical distribution determining means determines the geographical distribution of mobile stations in the cell by comparing the total number of notifications for each neighboring cell and the resource consumption amount with a predetermined distribution determination threshold. The geographical distribution estimation apparatus according to claim 1, wherein:   The distribution determination threshold is set so that the mobile stations in the cell are determined to be distributed near the boundary of the cell when the total number of notifications is relatively large and the resource consumption is relatively small. The geographical distribution estimation apparatus according to claim 2, wherein:   2. The geographical distribution determining means determines the geographical distribution of mobile stations in the cell based on the number of notifications for each adjacent cell and the positional relationship between the cell and the adjacent cell. The geographical distribution estimation apparatus described in 1.   The geographical distribution estimation apparatus according to claim 1, wherein the geographical distribution estimation apparatus is mounted on a base station control apparatus that controls a plurality of base stations in a mobile communication system. In a method for estimating a geographical distribution of mobile stations in a cell controlled by a base station,
Aggregating the number of notifications for each adjacent cell based on the adjacent cell information of the cell notified by a plurality of mobile stations located in the cell,
Determining the geographical distribution of mobile stations in the cell based on the number of notifications for each neighboring cell;
A geographical distribution estimation method characterized by that. Aggregating the resource consumption of the cell based on the resource consumption information notified from the base station,
7. The geographic distribution of mobile stations in the cell is determined by comparing the total number of notifications for each adjacent cell and the resource consumption with a predetermined distribution determination threshold value. The described geographical distribution estimation method.   The distribution determination threshold is set so that the mobile stations in the cell are determined to be distributed near the boundary of the cell when the total number of notifications is relatively large and the resource consumption is relatively small. The geographical distribution estimation method according to claim 7, wherein:   The geographical distribution estimation method according to claim 6, wherein the geographical distribution of mobile stations in the cell is determined based on the number of notifications for each adjacent cell and the positional relationship between the cell and the adjacent cell. .   A mobile communication system, wherein the geographical distribution estimation apparatus according to claim 1 is mounted on a base station control apparatus.   A mobile communication system, wherein the geographical distribution estimation device according to any one of claims 1 to 6 is connected to an outside of a base station control device. In a program for causing a computer to function as an apparatus for estimating a geographical distribution of a mobile station in a cell controlled by a base station,
A neighboring cell information counting function for counting the number of notifications for each neighboring cell based on neighboring cell information of the cell notified by a plurality of mobile stations located in the cell;
A geographical distribution determination function for determining a geographical distribution of mobile stations in the cell based on the number of notifications for each adjacent cell;
A program characterized by realizing the above on a computer. Further realizing a resource consumption totaling function for totaling the resource consumption of the cell based on the resource consumption information notified from the base station,
The geographical distribution determination function determines the geographical distribution of mobile stations in the cell by comparing the total number of notifications for each neighboring cell and the resource consumption amount with a predetermined distribution determination threshold. The program according to claim 12.

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