JP2013090203A - Radio communication system, handover control method, and base station - Google Patents

Abstract

PROBLEM TO BE SOLVED: To reduce a network device load which includes a base station by suppressing frequent occurrence of handover in a high-speed moving terminal.SOLUTION: The base station determines a base station for handover according to a residence time of a terminal in an adjacent cell which is to be a handover destination target candidate. As information to determine the handover target base station of the high-speed moving terminal, each base station measures and retains residence time information of a terminal having a moving speed of a constant value or higher. At handing over the high-speed moving terminal, the base station acquires an average residence time of the high-speed moving terminal from an adjacent base station or a log server retaining residence time information collected from each base station, and according to the residence time, offsets the handover reference value of each base station.

Description

The present invention relates to a radio communication system, a handover control method, and a base station, and more particularly to a cellular radio communication system, a handover control method in a cellular radio communication system, and a base station that implements the method.

In a cellular radio communication system, a mobile terminal connects to one of base stations and performs data communication. As the mobile terminal moves, the mobile terminal switches the connection destination to a base station with better communication quality than the currently connected base station (handover). In 3GPP (3rd Generation Partnership Project), which is a standardization organization for cellular communication systems, the procedure of handover processing in E-UTRAN (Evolved Universal Terrestrial Access Network), which is one of cellular communication systems, is defined in detail. It is described in Non-Patent Document 1.
In addition, when communication is performed using a mobile terminal in a train traveling at high speed or in a vehicle traveling on a highway, it is assumed that handovers occur more frequently than when walking.

Therefore, a technique for providing stable communication even in a high-speed mobile terminal by distinguishing a terminal moving at high speed (high-speed mobile terminal) from a terminal moving at low speed and performing different handover processing has been studied.

For example, in Patent Document 1, a mobile terminal determines the size of a cell radius of each base station, and a base station with a large cell radius or a base with a small cell radius based on the moving speed, transmission power, etc. of the mobile terminal. A technique for determining which of the stations should be selected with priority is disclosed.

JP2009-010989A

3GPP TS36.331 V10.2.0 Section 5.4 Intra-RAT mobility

When handovers frequently occur in the high-speed mobile terminals as described above, the load on the network device including the base station increases due to the handover process.

In addition, recently, home base stations (femtocell base stations) with a small communication area have become widespread, and it is expected that the communication area configuration due to cell arrangement will become complicated due to the mixture with conventional macro cell base stations. A handover control technology that takes into account a complex communication area environment is required.
However, in such a communication area environment, there is a possibility that a sufficient effect cannot be obtained by the technique described in Patent Document 1. In Patent Document 1, in order to reduce the frequency of handover, a base station having a large cell radius may be easily selected as a handover destination. However, the stay time of a mobile terminal is not always long in a base station having a large cell radius. Therefore, even if a base station with a large cell radius is selected, frequent handovers may not be prevented if the mobile terminal stays at the base station for a short time.
In view of the above points, an object of the present invention is to select a handover destination base station so that handover does not occur frequently for a terminal that moves at high speed in consideration of the communication area environment.
Another object of the present invention is to provide a stable communication environment for a high-speed mobile terminal by reducing the frequency of handover while maintaining required communication quality for the high-speed mobile terminal.

In order to solve the above-described problem, the base station according to the present invention determines that the handover destination base station is determined according to the average time information of the stay time of the terminal in the adjacent cell that is a handover destination candidate. Features.
In the present invention, as information for determining a handover destination base station of a high-speed mobile terminal, it is possible to use average time information of the stay time of a terminal having a moving speed of a certain value or more in each base station. The stay time at this time is, for example, the time from the start of communication to the end of communication in the base station.

Further, in the present invention, when the base station hands over the high-speed mobile terminal, an average of the high-speed mobile communication terminal stay time from the adjacent base station or a log server holding the stay time information collected from each base station Another feature is that time information is acquired and a base station with a long stay time is selected as a handover destination among the base stations of handover destination candidates. Further, as means for selecting a handover destination base station, in addition to the stay time information, an offset corresponding to the stay time is added to the handover reference value of each base station (eg, the reception quality of a signal from each base station). When there are a plurality of base stations that are candidates for handover, there can be used means for excluding one or a plurality of base stations whose reception quality at the handover target terminal is a certain value or less.

According to the first solution of the present invention,
In a wireless communication system,
When the base station in communication with the terminal determines the handover by comparing the communication quality of the own cell reported from the terminal and the communication quality of one or a plurality of neighboring cells, the base station It is determined whether or not the moving speed of the terminal is faster than a predetermined threshold,
The base station, when the moving speed of the terminal is greater than or equal to the predetermined threshold, based on the stay time information for each neighboring cell acquired from the log server or one or a plurality of neighboring base stations, for each handover candidate cell, Generate each offset value according to the stay time information, generate each offset communication quality value obtained by offsetting the communication quality of each handover candidate cell by each offset value,
The base station determines a handover destination cell based on each offset communication quality value,
A wireless communication system is provided in which the base station makes a handover request to any one of the adjacent base stations having the determined handover destination cell.

According to the second solution of the present invention,
A handover control method in a wireless communication system comprising a plurality of base stations that communicate with a terminal,
When the base station in communication with the terminal determines the handover by comparing the communication quality of the own cell reported from the terminal and the communication quality of one or a plurality of neighboring cells, the base station It is determined whether or not the moving speed of the terminal is faster than a predetermined threshold,
The base station, when the moving speed of the terminal is greater than or equal to the predetermined threshold, based on the stay time information for each neighboring cell acquired from the log server or one or a plurality of neighboring base stations, for each handover candidate cell, Generate each offset value according to the stay time information, generate each offset communication quality value obtained by offsetting the communication quality of each handover candidate cell by each offset value,
The base station determines a handover destination cell based on each offset communication quality value,
A handover control method is provided in which the base station makes a handover request to any one of the neighboring base stations having the determined handover destination cell.

According to the third solution of the present invention,
A base station in a wireless communication system,
When the base station in communication with the terminal determines the handover by comparing the communication quality of the own cell reported from the terminal and the communication quality of one or a plurality of neighboring cells, the base station It is determined whether or not the moving speed of the terminal is faster than a predetermined threshold,
The base station, when the moving speed of the terminal is greater than or equal to the predetermined threshold, based on the stay time information for each neighboring cell acquired from the log server or one or a plurality of neighboring base stations, for each handover candidate cell, Generate each offset value according to the stay time information, generate each offset communication quality value obtained by offsetting the communication quality of each handover candidate cell by each offset value,
The base station determines a handover destination cell based on each offset communication quality value,
The base station is provided with a base station that makes a handover request to any of the adjacent base stations that have the determined handover destination cell.

According to the present invention, it is possible to select a handover destination base station so that a terminal that moves at high speed does not frequently occur in consideration of a communication area environment.
Further, according to the present invention, it is possible to provide a stable communication environment for a high-speed mobile terminal by reducing the frequency of handover while maintaining required communication quality for the high-speed mobile terminal.

1 is an example of a configuration diagram of a wireless communication system of the present embodiment. The example of the block diagram of the base station of this Embodiment. The example of a block diagram of the terminal of this Embodiment. The example of a block diagram of the log server of this Embodiment. FIG. 5 is a sequence diagram in which a base station calculates, holds and reports stay time information reported from a terminal to a log server. The sequence diagram of the handover performed after a base station receives Measurement Report from a terminal. The flowchart of the residence time measurement process of a high-speed mobile terminal. The flowchart of a handover candidate cell determination process. The figure explaining the 1st method with which a base station determines a handover candidate cell. The figure explaining the 2nd method in which a base station determines a handover candidate cell. The flowchart of the 1st method with which a base station determines a hand-over destination cell. The flowchart of the 2nd method in which a base station determines a hand-over destination cell. The RS measurement result report value table for each terminal managed by the base station. A table for determining a handover destination of a high-speed mobile terminal managed by a base station. The stay time table of the high-speed mobile terminal of the own cell managed by the base station. A stay time table of high-speed mobile terminals in other cells managed by the base station. The flowchart of the stay time process of the high-speed mobile terminal in a log server. A stay time table of high-speed mobile terminals managed by a log server. The sequence diagram which shows the method in which a base station acquires direct residence time information from each base station of a handover candidate. The sequence diagram about a handover procedure. FIG. 11 is a sequence diagram for handover procedure 2; Explanatory drawing which shows the relationship between the movement path | route of a terminal, and stay time. Terminal movement speed table. A table for determining a handover destination of a high-speed mobile terminal when this embodiment is not applied. A table for determining a handover destination of a high-speed mobile terminal managed by the base station (another example).

Embodiments of the present invention will be described with reference to the drawings, taking E-UTRAN as an example.
In the following, the reference signal (RS) is a fixed or semi-fixed signal used as a reference signal for amplitude and phase when demodulating a received signal, or as a reference signal for estimating received power or propagation path information. A signal with the pattern For example, a pilot signal can be used as the reference signal. Further, the reference signal used as a reference signal for demodulation and the reference signal used as a reference signal for estimating received power or propagation path information may be the same or different signals. Further, the reference signal may be used in common by a plurality of terminals in the cell, or may be used individually for each terminal.
In the following, a cell is an area where a radio signal transmitted from a base station can be received, for example, and a terminal performs data communication with any one cell. A base station has one or more cells under its control. Further, the adjacent cell includes a cell under the control of a base station existing in the vicinity of a certain cell, and is not necessarily a geographically adjacent cell.

1. System configuration

FIG. 1 shows a configuration example of an E-UTRAN wireless communication system. As shown in FIG. 1, the wireless communication system includes a plurality of base stations, a plurality of terminals, and a core network device. In the system of FIG. 1, cells 101A to 104A indicate ranges in which terminals 111 to 114 to be connected can communicate with each base station 101 to 104 by wireless connection. The cell radius of the base station is determined by factors such as the operation mode of each base station, the frequency used, and the cell arrangement. For example, the cell radius of a macro base station for covering a large area becomes large, and the cell radius of a femto base station for covering a small area becomes small. In addition, like the cells 101B to 101D, 102B to 102D, and 103B to 103D in FIG. 1, the base station may have a plurality of cells in order to increase the frequency utilization efficiency. On the other hand, a base station having a small communication coverage area, such as the base station 104, may have only a single cell. The base stations 101 to 104 in FIG. 1 are connected to the core network device 122 through a NW (Network) 123 by a wired line. The base stations 101 to 104 are connected to the log server 121 through the NW 123. In FIG. 1, a terminal 111 is connected to the base station 101, a terminal 112 is connected to the base station 102, a terminal 113 is connected to the base station 103, and a terminal 114 is connected to the base station 104 by wireless to enable communication. It has become. In the following description, the base station refers to at least one of the base stations 101 to 104, and the terminal refers to any one of the terminals 111 to 114.

FIG. 2 shows a configuration example of the base station apparatus according to the present embodiment, which is an example of the base station shown in FIG. In addition, although the structure of the base station apparatus which has a single cell is shown in FIG. 1, the single base station may have a some cell as mentioned above. In FIG. 2, a base station communicates with a memory 201, a CPU 202, a wireless interface 203 for performing wireless communication with a terminal, a logic circuit 204 for performing error correction coding, a core network device 122, a log server 121, and an adjacent base station. A wired interface 205 for performing the above is provided.
The memory 201 includes an RS measurement result report value table 221, a high-speed mobile terminal stay time information table 222 in its own cell, and a high-speed mobile terminal stay time information table 223 in another cell. The RS measurement result report value table 221 stores reference signal reception quality information reported from the terminal. The stay time information table 222 of the own cell high-speed mobile terminal stores the stay time information of the high-speed mobile terminal of the subordinate cell. The stay time information table 223 of other cell high-speed mobile terminals stores the stay time information of high-speed mobile terminals of other cells. Details of each table will be described later.
The CPU 202 includes a transmission data processing unit 211, a reception data processing unit 212, a handover processing unit 213, a handover destination cell determination unit 214, a high-speed mobile terminal stay time measurement unit 215, and a handover candidate cell determination unit 216. The transmission data processing unit 211 processes data to be transmitted to the terminal. The reception data processing unit 212 processes data received from the terminal. The handover processing unit 213 performs processing for handing over a terminal to an adjacent cell. The handover destination cell determination unit 214 determines a handover destination cell with reference to the communication quality information of the reference signal reported from the terminal. The stay time measuring unit 215 of the high-speed mobile terminal measures the stay time of the high-speed mobile terminal in the cell and holds it in the stay time table 322 of the own cell high-speed mobile terminal. The handover candidate cell determination unit 216 determines whether or not to start the handover using communication quality information and the like transmitted from the terminal, and further determines a handover candidate cell from the neighboring cells.

FIG. 3 shows a configuration example of the terminal device according to the present embodiment, which is an example of the terminal shown in FIG. In FIG. 3, the terminal includes a memory 301, a CPU 302, a wireless interface 303 for performing wireless communication with a base station, and a logic circuit 304 for performing error correction coding.
The memory 301 includes an RS measurement value table 321 and a moving speed measurement value table 322. The RS measurement value table 321 stores reference signals and communication quality information measured by the terminal. The movement speed measurement value table 322 stores movement speed information measured by the terminal. Details of each table will be described later.
The CPU 302 includes a transmission data processing unit 311, a reception data processing unit 312, an RS power measurement unit 313, and a moving speed detection unit 314. The transmission data processing unit 311 processes data to be transmitted to the base station. The reception data processing unit 312 processes data received from the base station. The RS power measuring unit 313 measures the communication quality information of the communicating cell and the neighboring cell measured by the terminal, holds the RS quality value table 321 included in the memory 301, and is communicating through the wireless interface 303. To the base station. The moving speed detection unit 314 detects the moving speed of the terminal, holds the moving speed information measured by the terminal in the moving speed measurement value table 322 included in the memory 301, and transmits to the base station in communication via the wireless interface 303. Report. The movement speed of the terminal can be detected by, for example, providing the terminal with a GPS and using GPS information.

FIG. 4 shows the log server of this embodiment, and is an example of the log server shown in FIG. In FIG. 4, the log server includes a wired interface 403 for communicating with a memory 401, a CPU 402, a core network device 122, and base stations 101 to 104.
The memory 401 includes a stay time table 421 for high-speed mobile terminals in each cell. The high-speed mobile terminal stay time table 421 in each cell stores the high-speed mobile terminal stay time information in each base station reported from each base station 101-104.
The CPU 402 includes a transmission data processing unit 411, a reception data processing unit 412, and a stay time processing unit 413 of a high-speed mobile terminal. The transmission data processing unit 411 processes data to be transmitted to the base station. The reception data processing unit 412 processes data received from the base station. The stay time processing unit 1713 of the high-speed mobile terminal calculates the average time that the high-speed mobile terminal stays in each base station using the stay time information in each base station reported from each base station 101 to 104 so far. And stored in the stay time table 421 of the high-speed mobile terminal in each cell.

2. sequence

2.1 Stay Time Management In the wireless communication system of FIG. 1, base stations 101 to 104 hold the stay time information of high-speed mobile terminals in their subordinate cells. Next, a first embodiment of a method for selecting an optimal base station at the time of handover will be described.
FIG. 5 shows a sequence diagram regarding the stay time management of the high-speed mobile terminal in each base station. First, with reference to the sequence diagram of FIG. 5, a method for acquiring stay time information of a high-speed mobile terminal in which each base station is communicating with itself and a method for notifying a log server will be described. First, in the sequence 501, the terminal 511 detects its own movement speed at a movement speed detection unit 314 provided in the terminal periodically or at a predetermined time / timing, etc., and the terminal ID and the detected movement The base station 512 is notified of the speed.

FIG. 23 shows a table of the moving speed of the terminal.
The base station 512 stores the terminal moving speed in the terminal moving speed table 224 for the terminal ID. Note that the terminal 511 can send movement speed information to the base station 512 periodically or at an appropriate timing, and the base station 512 can store the information in the terminal movement speed table 224 for the terminal ID.

The operation of the base station 512 that has received the moving speed information from the terminal 511 will be described with reference to FIG. FIG. 7 is a flowchart showing the high-speed mobile terminal stay time measurement process performed by the base station in the high-speed mobile terminal stay time measuring unit 215. First, in step 701, the base station determines whether or not the moving speed notified from the terminal 511 is high compared with a predetermined threshold value. When the moving speed reported from the terminal 511 is equal to or higher than a certain value, in the flow 702, the base station 512 calculates and holds the stay time of the terminal 511. The stay time of the terminal 511 may be calculated, for example, based on the time from the communication start time to the end of the terminal 511. Thereafter, in flow 703, the base station 512 updates the stay time of the own cell high-speed mobile terminal using the following equation.

ただし、式中のｎはこれまでに通信の開始時刻、終了時刻を算出した端末の合計値である。

基地局５１２は、更新した高速移動端末の滞在時間を自セルの高速移動端末の滞在時間デーブル２２２に格納する。図１５は、自セルの高速移動端末の滞在時間テーブル２２２の例を示している。同図において、基地局５１２は、自身の傘下の各セルＩＤ１５０１それぞれについて高速移動端末の滞在時間１５０２を保持する。

However, n in the formula is the total value of the terminals for which the communication start time and end time have been calculated so far.

The base station 512 stores the updated stay time of the high speed mobile terminal in the stay time table 222 of the high speed mobile terminal of its own cell. FIG. 15 shows an example of the stay time table 222 of the high-speed mobile terminal in the own cell. In the figure, the base station 512 holds the stay time 1502 of the high-speed mobile terminal for each cell ID 1501 under its control.

On the other hand, when the moving speed notified from the terminal 511 in the flow 701 is equal to or less than a predetermined threshold, the processing in the flows 702 and 703 is not performed. In FIG. 7, the terminal 511 itself measures the moving speed of the terminal 511, but the base station 512 may measure the moving speed of the terminal 511. This is because, for example, the terminal 511 periodically reports the radio channel quality with the base station 512 to the base station 512, and the base station 512 indicates that the reported radio channel quality variation is greater than or equal to a certain threshold value. If there is, it is possible by determining that the terminal 511 is moving at high speed.

In sequence 503, the base stations 512 to 515 refer to the stay time table 222 of the own cell high speed mobile terminal, and notify the log server 516 of the own cell ID and the stay time information updated by the high speed mobile terminal in the own cell.

FIG. 17 shows a flowchart for the stay time processing of the high-speed mobile terminal.
The operation of the log server 516 that has received the stay time information of the high-speed mobile terminal from the base stations 512 to 515 will be described with reference to FIG. First, in a flow 1701, the log server 516 determines whether or not the stay time information of the high-speed mobile terminal has been received from the base station in the past. For example, the long server 516 refers to the stay time table 421 of the high-speed mobile terminal in each cell, and stores the data of the average stay time table 1802 or the number of reports 1803 of the high-speed mobile terminal corresponding to the cell ID received together with the stay time information. This determination can be made based on the presence or absence. When the stay time information of the high-speed mobile terminal has been received in the past, in the flow 1702, the stay time information of the high-speed mobile terminal that the base station has transmitted so far and the current cell ID are transmitted to the corresponding cell ID. The average value of the stay time information of the high speed mobile terminal is calculated using the stay time information of the high speed mobile terminal and the total number reported so far, and the stay time information of the high speed mobile terminal in the base station is updated in flow 1703 . When the stay time information of the high-speed mobile terminal has never been received from the base station in the flow 1701, the log server 516 holds the stay time information received in the flow 1703 for the cell ID.
FIG. 18 is an example of the stay time table 421 of the high-speed mobile terminal in each cell held by the log server 516. The log server 516, for each cell specified by the cell ID (1801), calculates the average stay time (average stay time) 1802 of the high-speed mobile terminal calculated in the flow 1702 and the number of reports 1803 of stay time information from the cell. Is stored as the stay time table 421 of the high-speed mobile terminal in each cell.

2.2 Handover control (first sequence)
FIG. 6 shows a sequence diagram for the handover procedure.
Next, a handover control method will be described using the sequence diagram of FIG. In sequence 601, the terminal 611 reports the terminal ID, the cell ID and communication quality of the communicating base station 612, and the cell ID and communication quality of the neighboring base station to the connection destination base station 612 as a Measurement Report. The communication quality at this time is, for example, reference signal received power (RSRP: Reference Signal Received Power), reference signal received quality (RSRQ: Reference Signal Received Quality), or the like. In addition, the terminal transmits a measurement report to the base station periodically or when the communication quality satisfies a certain standard in accordance with an instruction from the base station.

The base station 612 that has received the Measurement Report stores the communication quality information in the RS measurement result report value table 221.
FIG. 13 shows an example of the RS measurement result report value table 221. In the figure, the base station 612 holds the RS measurement result value 1302 for each of the own cell 1302A and the other cells 1302B to 1302D for each terminal ID 1301.

Next, the operation of the communicating base station 612 that has received the Measurement Report from the terminal 611 in the sequence 602 will be described with reference to FIG. FIG. 8 is a flowchart illustrating handover candidate cell determination processing performed by the base station in the handover candidate cell determination unit 216. First, the base station 612 refers to the RS measurement result report value table 221 in the flow 801, compares the communication quality of the own cell reported from the terminal 611 with the communication quality of the neighboring cell, and determines whether or not the handover determination condition is satisfied. Determine. For example, if the communication quality of the adjacent cell is better than a certain value with respect to the communication quality of the own cell, the base station 612 determines that the handover determination condition is satisfied. When the handover determination condition is not satisfied (NO in 801), the base station 612 determines not to execute the handover in the flow 803. When the handover determination condition is satisfied (YES in 801), the base station 612 refers to the terminal moving speed table 224 in the flow 802 and determines whether or not the moving speed of the terminal 611 to be handed over is high. . When the moving speed of the terminal is less than a predetermined threshold (NO in 802), the base station 612 activates a normal handover that does not use the algorithm of the present embodiment in the flow 805. That is, the base station performs the processing after sequence 606 without performing the processing of sequences 603 to 605 in FIG. On the other hand, in the flow 802, when the moving speed of the terminal 611 is equal to or higher than a certain threshold (YES in 802), the base station 612 performs communication with the terminal 612 in the flow 804 in order to ensure communication quality at the handover destination. A cell having good quality is extracted as a handover candidate. For example, the communicating base station 612 refers to the RS measurement result report value table 221 and sets one or a plurality of cells in which the RS measurement result value of the terminal ID of the terminal 611 is larger than a predetermined threshold as handover candidates. Can be extracted.
If such a restriction is not applied to the handover candidate cell, the communication quality of the terminal 612 may be greatly deteriorated after the handover, and the data rate may be lowered or the connection with the base station may be disconnected. However, by limiting the handover candidate cells using the communication quality between each cell and the terminal as an index, the terminal can be handed over while preventing deterioration of the communication quality after the handover.

FIG. 9 is an explanatory diagram of the handover candidate cell determination method (1). FIG. 10 shows an explanatory diagram of the handover candidate cell determination method (2).
Hereinafter, an example of a handover candidate cell determination method in the flow 804 will be described with reference to FIGS. 9 and 10. First, a handover candidate cell determination method in which a terminal selects a cell that can obtain a certain communication quality as a handover candidate will be described with reference to FIG. FIG. 9 is a diagram illustrating a handover candidate cell determination method in which a terminal selects a cell that can obtain a certain communication quality as a handover candidate. In FIG. 9, it is assumed that the communication quality of the cells 1 to 6 is reported from the terminal to the base station. The base station selects a cell having a communication quality equal to or higher than a predetermined threshold as a handover candidate. In the example of FIG. 9, cell 1, cell 2, cell 3, cell 4, and cell 6 are selected as handover candidates, and cell 5 is excluded from the handover candidates.
Next, a handover candidate cell determination method for selecting, as handover candidates, a cell in a range satisfying the allowable handover value from the cell with the highest communication quality reported by the terminal will be described with reference to FIG. FIG. 10 is a diagram illustrating a handover candidate cell determination method for selecting, as handover candidates, cells in a range satisfying the handover allowable value from the cell with the best communication quality reported by the terminal. In FIG. 10, it is assumed that the communication quality of the cells 1 to 6 is reported from the terminal to the base station. The base station selects, as a handover candidate, a cell that is within the allowable handover value from the cell with the best communication quality reported by the terminal (cell 6 in FIG. 10). In the example of FIG. 10, cell 1, cell 2, cell 4, and cell 6 are selected as handover candidates, and cell 3 and cell 5 are excluded from the handover candidates.

Returning to FIG. 6, next, in sequence 603, the base station 612 inquires the log server 616 about the stay time information of the high-speed mobile terminal in the handover candidate cell. In sequence 604, the log server 616 refers to the stay time table 421 of the high-speed mobile terminal in each cell, and notifies the base station 612 of the stay time information (average stay time of the high-speed mobile terminal) in the handover candidate cell.

The base station 612 stores the received stay time information in the stay time table 223 of the other cell high-speed mobile terminal corresponding to the handover candidate cell ID.
FIG. 16 shows an example of the stay time table 223 of the high-speed mobile terminal of another cell notified in sequence 604. In the figure, the stay time 1602 of the high-speed mobile terminal for each adjacent cell ID 1601 of the base station 512 is stored.

The base station 612 determines a handover destination cell and performs handover using the stay time information of the high-speed mobile terminal in the handover candidate cell notified from the log server 616.
A handover destination cell determination process performed by the base station 612 in the handover destination cell determination unit 214 will be described with reference to FIG. FIG. 11 is a flowchart of a first method of handover destination cell determination processing performed by the base station in the handover destination cell determination unit 214. First, the base station 612 generates an offset value in accordance with each stay time information (average stay time of a high-speed mobile terminal) received from the log server 616 in the flow 1101. For example, since the base station 612 determines a handover destination cell based on the value of communication quality, the base station 612 generates an offset value having a large value in a cell having a long stay time so that handover does not occur frequently, and the stay time is short. A small offset value is generated in the cell. In order to obtain the offset value, it is possible to use an appropriate method such as calculating with an equation proportional to the stay time information or referring to a table storing a predetermined value. Thereafter, in flow 1102, the RS measurement result report value table 221 is referred to, the offset value generated in flow 1101 is added to the communication quality of each handover candidate cell, and the communication quality value is updated. In the flow 1103, the base station 612 determines a handover destination cell based on the communication quality generated in the flow 1102.

A method in which the base station 612 determines a handover destination cell of the high-speed mobile terminal 611 will be described with reference to FIG. FIG. 14 shows details of the table 225 for determining the handover destination of the high-speed mobile terminal held in the memory 201 of the base station 612. In FIG. 14, it is assumed that cells 1 to 6 are determined as handover candidates for the high-speed mobile terminal 611. The base station 612 in communication with the high-speed mobile terminal 611 considers the average stay time 1402 (a value received from the log server) of the high-speed mobile terminal in the handover candidate cell, and the offset value increases as the average stay time 1402 increases. The offset value 1404 is generated so that becomes larger. Furthermore, the sum of the generated offset value 1404 and the communication quality 1403 of the handover candidate measured by the terminal (set from the RS measurement result report value table 221) is calculated, and the communication quality 1405 considering the offset value is generated. The base station 612 determines the priority order 1406 of the handover destination cell using the communication quality 1405 considering the offset value. That is, the base station 612 determines the cell 3 as a handover destination cell. In particular, the CPU 201 may use each value for calculation without providing the table 225 for determining the handover destination of the high-speed mobile terminal.
When this embodiment is not applied, the base station 612 determines the priority 1408 of the handover destination cell by paying attention only to the communication quality 1403 of the terminal. That is, the base station 612 determines the priority order of the handover destination cell as indicated by 1408 in FIG. 24, and selects the cell 4 as the handover destination cell. At this time, it is expected that the best communication quality can be realized for the terminal 611 after the handover to the cell 4, but since the cell having a short residence time is determined as the handover destination cell, the handover frequently occurs. There is a risk that. On the other hand, when the present invention is applied, the base station 612 determines a cell that satisfies the required communication quality and has a long residence time as a handover destination cell. That is, as described above, frequent handovers can be prevented by selecting a handover destination cell in consideration of the staying time.

Further, a means as shown in FIG. 12 may be used as means for determining the handover destination cell. FIG. 12 shows a flowchart of the handover destination cell determination process (2). In the means of FIG. 12, the base station 612 determines a cell having the longest stay time as a handover destination cell in the flow 1201.
Processing for determining a handover destination cell when the high-speed mobile terminal performs handover will be described with reference to FIG. FIG. 25 shows another example of a table for determining the handover destination of the high-speed mobile terminal. In FIG. 25, it is assumed that cells 1 to 6 are determined as handover candidates for the high-speed mobile terminal. The base station 612 determines 1407 the handover destination cell in consideration of the stay time of the handover candidate cell. That is, the base station 612 determines the cell 3 as a handover destination. Thus, frequent handovers can be prevented by handing over a terminal to a cell in which the high-speed mobile terminal stays long.

  Returning to FIG. 6, the base station 612 then initiates a handover in sequence 606. After the handover is activated, the base station 612 communicating with the terminal 611 makes a handover request in sequence 607 to the base station having the handover destination cell determined in sequence 605. In the example of FIG. 6, assuming that the handover destination cell is included in the base station 614, the base station 612 makes a handover request to the base station 614. The base station 614 that has received the handover request transmits a handover acceptance response to the base station 612 in communication with the terminal 611 in sequence 608 when the terminal 611 can be accepted. The base station 612 communicating with the terminal 611 that has received the handover acceptance response issues a handover instruction to the terminal 611 in sequence 609. Thereafter, the terminal 611 and the handover destination base station 614 instructed for handover establish a connection in sequence 610 and complete the handover.

2.3 Handover control (second sequence)
FIG. 20 shows a sequence diagram for the handover procedure.
In FIG. 6, acquisition of the stay time information of the high-speed mobile terminal in the neighboring cell is performed after the decision of the handover candidate cell 602. However, as shown in FIG. Information may be acquired. That is, the acquisition of the stay time information of the high-speed mobile terminal of the adjacent cell from the log server is performed periodically, for example, at a constant cycle, and the stay time information of the high-speed mobile terminal of the adjacent cell is obtained until the next acquisition time. It is held in the stay time table 223 of the high-speed mobile terminal (sequence 2004). In the handover procedure, the base station refers to the stay time table 223 of the other cell high-speed mobile terminal and uses the stay time information of the high-speed mobile terminal of the neighboring cell that is already held.

2.4 Handover control (third sequence)
Further, in the above-mentioned “2.2 Handover control (first sequence)” and “2.3 Handover control (second sequence)”, as shown in FIG. Although the acquisition is performed through the log server 616, the base station 612 may acquire the stay time information of the high-speed mobile terminal from the adjacent base stations 613 to 615. The operation in the case of acquiring the stay time information in the high-speed mobile terminal from the adjacent base stations 613 to 615 will be described with reference to FIG. FIG. 19 is a sequence diagram of the handover procedure when the base station 1912 obtains stay time information in the high-speed mobile terminal from the adjacent base stations 1913 to 1915. The base station 1912 determines a handover in sequence 1902, and after determining a handover candidate cell, each base station 1913 to 1915 receives the stay time information of the high-speed mobile terminal 1911 in each adjacent base station 1913 to 1915 in sequence 1903. Inquire. In sequence 1904, each adjacent base station 1913 to 1915 notifies the base station 1912 of the staying time information of the high-speed mobile terminal in the base station together with the cell ID. In sequence 1921, the base station 1912 stores the stay time information for the cell ID of the base station notified in the stay time table 223 of the high-speed mobile terminal of another cell as shown in FIG.
In FIG. 19, the stay time information of the high-speed mobile terminal in the adjacent cell is acquired after the decision 1902 of the handover candidate cell, but the stay time information of the high-speed mobile terminal in the adjacent cell may be acquired prior to this. . That is, the acquisition of the stay time information of the high-speed mobile terminal in the adjacent cell is periodically performed, for example, at a constant cycle through the inter-base station interface, and the stay time information of the high-speed mobile terminal in the adjacent cell is held until the next acquisition time. . In the handover procedure, the base station uses the stay time information of the high-speed mobile terminal in the neighboring cell already held.

2.5 Handover control (modification)
Furthermore, in the above description, information is exchanged between base stations for performing handover, such as sequences 607 to 608 in FIG. 6 and 1907 to 1908 in FIG. 19, using the inter-base station interface. However, the base station may exchange information with other base stations for performing handover via the core network device 122.

In the above-described embodiment, the terminal moving speed is classified into two stages as shown in FIG. 8 as to whether or not the terminal is moving at high speed, but the moving speed may be classified into three or more stages. By classifying the moving speed into three or more stages, for example, it is possible to distinguish a terminal moving on the Shinkansen, a terminal moving on a highway by car, etc., and handover control according to the moving speed of the vehicle can be performed. It becomes possible.

As described above, by handing over a high-speed mobile terminal to a cell having a long stay time, the number of connected terminals of the cell having a long stay time increases, and the depth of the base station having a cell having a long stay time increases. There is a case. Such concentration of load on a specific base station can be avoided, for example, by handing over a terminal that moves at a low speed to a cell having a short residence time.

FIG. 22 shows the relationship between the travel route of the terminal and the stay time. In FIG. 22, cells 2231 and 2232 indicate ranges in which communication with the respective base stations 2201 and 2202 is possible through wireless connection. It is assumed that a cell 2231 having a large radius and a cell 2232 having a small radius are adjacent to each other, and the terminal 2210 moves along a route 2220 at a high speed. At this time, the section 2222 and the section 2221 represent the stay sections of the terminal 2210 in the cells 2231 and 2232, respectively. When handed over to a base station 2201 with a large cell radius, the residence time of the terminal 2210 in the handover destination cell is shorter than when handed over to a base station 2202 with a small cell radius. However, by applying the present invention and this embodiment, the terminal 2210 can be handed over to the cell 2232 having a long residence time.

In the above embodiments, E-UTRAN has been mainly described as an example, but the present invention can be applied to various wireless communication systems such as cellular communication systems, handover control, and base stations. .

101, 102, 103, 104 Base station
101A to 104D Cell 121 of each base station Log server 122 Core network device 123 Network

201 Base station memory 202 Base station CPU
203 Base station wireless interface 204 Base station logic circuit 205 Base station wired interface 211 Base station transmission data processing unit 212 Base station reception data processing unit 213 Base station handover processing unit 214 Base station handover destination cell determination unit 215 Base station high-speed mobile terminal stay time measurement unit 216 Base station handover candidate cell determination unit 221 Base station RS measurement result report value table 222 Base station self-cell high-speed mobile terminal stay time table
223 Base station's residence time table for other cell high-speed mobile terminals

301 Terminal Memory 302 Terminal CPU
303 Terminal Wireless Interface 304 Terminal Logic Circuit 311 Terminal Transmission Data Processing Unit 312 Terminal Reception Data Processing Unit 313 Terminal RS Power Measurement Unit 314 Terminal Movement Speed Detection Unit 321 Terminal RS Measurement Value Table 322 Terminal Movement Speed Measurement value table

401 Log server memory 402 Log server CPU
403 Log server wired interface 411 Log server transmission data processing unit 412 Log server reception data processing unit 413 Log server high-speed mobile terminal stay time processing unit 421 Log server high-speed mobile terminal stay time table

501 Terminal speed information notification 502 High-speed mobile terminal stay time determination process 503 High-speed mobile terminal stay time information notification 504 High-speed mobile terminal stay time process 511 Terminal 512 to 515 Base station 516 Log server

601 Measurement Report
602 Handover candidate cell determination processing 603 Stay time information inquiry of each base station 604 Stay time information notification 605 Handover destination cell determination processing 606 Handover activation 607 Handover request 608 Handover acceptance response 609 Handover instruction 610 Connection establishment 611 Terminal 612 Communication base Stations 613 to 615 Handover candidate base station 616 Log server

701 Determining whether the terminal speed is equal to or higher than a certain threshold 702 Calculation of communication start time and end time, retention process 703 Update process of terminal stay time information

801 A process for determining whether the communication quality notified from the terminal satisfies the handover determination condition in the base station 802 A process for determining whether the moving speed of the terminal is equal to or greater than a certain threshold 803 A process for not executing the handover 804 Fixed as viewed from the terminal Processing for excluding cells having communication quality less than the value or cells that do not satisfy the allowable handover value based on the cell having the best communication quality from the handover candidates 805 Handover processing

1101 Processing for generating an offset according to the staying time 1102 Processing for updating communication quality by adding an offset appropriate for each cell 1103 Processing for determining a handover destination cell based on the updated communication quality

1201 Processing for selecting the cell with the longest stay time and determining it as the handover destination cell

1301 Terminal ID
1302 RS measurement result values 1302A to 1302D RS measurement result values in each cell

1401 Handover candidate cell of terminal
1402 Average stay time
1403 Terminal communication quality 1404 offset value
Communication quality considering 1405 offset
1406 Handover destination priority when offset is considered
1407 Handover destination priority when considering only stay time
1408 Handover destination priority not applying the present invention

1501 Own cell ID
1502 High-speed mobile terminal stay time

1601 Neighbor cell ID
1602 Time spent on high-speed mobile terminals

1701 Judgment whether or not the stay time information has been received in the past from the cell being served by the base station 1702 Processing for calculating the average value of the information sent so far and the current information 1703 Stay of the high-speed mobile terminal in the cell Processing to update time information

1801 Own cell ID
1802 Average time spent on high-speed mobile terminals 1803 Number of reports

1901 Measurement report
1902 Handover candidate cell determination processing 1903 Inquiry of stay time information of each base station 1904 Notification of stay time information 1905 Handover destination cell determination processing 1906 Handover activation 1907 Handover request 1908 Handover acceptance response 1909 Handover instruction 1910 Connection establishment 1911 Terminal 1912 Communication base Stations 1913 to 1915 Handover candidate base station 1916 Log server 1921 Retention time for each base station

2001 Inquiries about stay time information of each base station 2002 Notification of stay time information 2003 Measurement Report
2004 Retention time information retention 2005 Handover candidate cell determination processing 2006 Handover destination cell determination processing 2007 Handover activation 2008 Handover request 2009 Handover acceptance response 2010 Handover instruction 2011 Connection establishment 2012 Terminal 2013 Base stations 2014-2016 in communication 2017 log server


2101 Inquiry about stay time information of each base station 2102 Notification of stay time information 2103 Measurement report
2104 Handover candidate cell determination processing 2105 Handover destination cell determination processing 2106 Handover activation 2107 Handover request 2108 Handover acceptance response 2109 Handover instruction 2110 Connection establishment 2111 Terminal 2112 Communicating base station 2133 to 2115 Handover candidate base station 2116 Log server 2121 Each base Retention time for each station

Claims (10)

In a wireless communication system,
When the base station in communication with the terminal determines the handover by comparing the communication quality of the own cell reported from the terminal and the communication quality of one or a plurality of neighboring cells, the base station It is determined whether or not the moving speed of the terminal is faster than a predetermined threshold,
The base station, when the moving speed of the terminal is greater than or equal to the predetermined threshold, based on the stay time information for each neighboring cell acquired from the log server or one or a plurality of neighboring base stations, for each handover candidate cell, Generate each offset value according to the stay time information, generate each offset communication quality value obtained by offsetting the communication quality of each handover candidate cell by each offset value,
The base station determines a handover destination cell based on each offset communication quality value,
The wireless communication system in which the base station makes a handover request to any one of the neighboring base stations having the determined handover destination cell.
The wireless communication system according to claim 1,
The base station
Receiving the movement speed measured by the terminal from the terminal;
i) If the moving speed is equal to or higher than a predetermined value, determining that the moving speed of the terminal is high, or
ii) The base station determines that the moving speed of the terminal is high if the variation of the radio channel quality reported from the terminal is equal to or greater than another predetermined value. Wireless communication system.
The wireless communication system according to claim 1,
The terminal periodically detects the moving speed and notifies the base station in communication,
The base station determines whether the moving speed notified from the terminal is faster than the predetermined threshold,
When the moving speed reported from the terminal is equal to or greater than the threshold, the base station calculates the staying time of the terminal and updates the own cell staying time table storing the staying time information of the high-speed mobile terminal for each cell. And
The base station refers to the own cell stay time table and transmits the stay time information to the log server or one or more other base stations.
The wireless communication system according to claim 1,
The log server
Each cell has an average stay time of the high-speed mobile terminal and each cell stay time table that stores the number of reports of stay time information from the cell,
The log server refers to each cell stay time table, and uses the stay time information of the high-speed mobile terminal that the base station has transmitted so far, the stay time information of the high-speed mobile terminal that has been transmitted this time, and the number of reports Calculating the average stay time of the high-speed mobile terminal and updating or holding each cell stay time table,
When the base station inquires the log server about the stay time information including the average stay time of the high-speed mobile terminal in each handover candidate cell or each neighboring cell, the log server refers to each cell stay time table. Then, the base station is notified of stay time information.
The wireless communication system according to claim 1,
The base station inquires each neighboring base station about the staying time information of the high-speed mobile terminal in each neighboring base station at a certain period or periodically or in advance,
Each adjacent base station notifies the base station of the stay time information of the high-speed mobile terminal for each cell of its own station,
The base station retains the stay time information of the high-speed mobile terminal for each cell of each adjacent base station in the other cell stay time table.
The wireless communication system according to claim 1,
The base station generates an offset value so that the offset value increases as the average stay time of the high-speed mobile terminal in the handover candidate cell increases, and the communication quality of the handover candidate measured by the terminal To generate the offset communication quality value,
The base station determines a priority of a handover destination cell using the offset communication quality value.
The wireless communication system according to claim 1,
The base station performs acquisition of stay time information of high-speed mobile terminals in each adjacent cell after determining handover and / or determining handover candidate cells.
The wireless communication system according to claim 1,
The base station obtains the stay time information of the high-speed mobile terminal in each adjacent cell at a certain period or periodically or when predetermined, and the stay time information of the high-speed mobile terminal for each neighbor cell stays in another cell Keep in time table,
The radio communication system according to claim 1, wherein the base station executes handover using the stay time information of the high-speed mobile terminal of the adjacent cell already held in the other cell stay time table.
A handover control method in a wireless communication system comprising a plurality of base stations that communicate with a terminal,
When the base station in communication with the terminal determines the handover by comparing the communication quality of the own cell reported from the terminal and the communication quality of one or a plurality of neighboring cells, the base station It is determined whether or not the moving speed of the terminal is faster than a predetermined threshold,
The base station, when the moving speed of the terminal is greater than or equal to the predetermined threshold, based on the stay time information for each neighboring cell acquired from the log server or one or a plurality of neighboring base stations, for each handover candidate cell, Generate each offset value according to the stay time information, generate each offset communication quality value obtained by offsetting the communication quality of each handover candidate cell by each offset value,
The base station determines a handover destination cell based on each offset communication quality value,
The handover control method, wherein the base station makes a handover request to any one of the neighboring base stations having the determined handover destination cell.
A base station in a wireless communication system,
When the base station in communication with the terminal determines the handover by comparing the communication quality of the own cell reported from the terminal and the communication quality of one or a plurality of neighboring cells, the base station It is determined whether or not the moving speed of the terminal is faster than a predetermined threshold,
The base station, when the moving speed of the terminal is greater than or equal to the predetermined threshold, based on the stay time information for each neighboring cell acquired from the log server or one or a plurality of neighboring base stations, for each handover candidate cell, Generate each offset value according to the stay time information, generate each offset communication quality value obtained by offsetting the communication quality of each handover candidate cell by each offset value,
The base station determines a handover destination cell based on each offset communication quality value,
The base station is a base station that makes a handover request to any of the adjacent base stations that have the determined handover destination cell.

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