KR101119252B1 - System and method for supporting handover in a wireless communication system - Google Patents

Abstract

The present invention provides a handover in a wireless communication system including a mobile terminal, a serving access point for providing a communication service to the mobile terminal, and a target access point to which the mobile terminal is to handover. In the supporting method, if it is detected that the mobile terminal should be handed over, receiving the location information of the mobile terminal, predicting the handover time of the mobile terminal corresponding to the location information, and And controlling the target access point to allocate resources to the target access point at the handover time point, and establishing a connection between the target access point and the mobile terminal.

Handover, Received Signals, Location Information, Viewpoint Prediction, Satellite Positioning System (GPS)

Description

System and method for supporting handover in wireless communication system {SYSTEM AND METHOD FOR SUPPORTING HANDOVER IN A WIRELESS COMMUNICATION SYSTEM}

1 is a view schematically showing the structure of a general wireless communication system.

2 is a diagram schematically illustrating a structure of a system for handover in a wireless communication system according to an embodiment of the present invention.

3 is a diagram schematically illustrating a controller structure of a system for handover in a wireless communication system according to an embodiment of the present invention.

4 is a diagram schematically illustrating a structure of a system for performing handover in a wireless communication system according to an embodiment of the present invention.

5 is a diagram illustrating an operation process of a controller for performing handover in a wireless communication system according to an embodiment of the present invention.

6 is a schematic block diagram of a controller structure of a system for handover in a wireless communication system according to another embodiment of the present invention.

7 is a diagram schematically illustrating a structure of a system for performing handover in a wireless communication system according to another embodiment of the present invention.

8 is a diagram illustrating an operation process of a controller for performing handover in a wireless communication system according to another embodiment of the present invention.

The present invention relates to a system and method for supporting a handover of a terminal moving between cells managed by different access points (APs) in a wireless communication system. .

In a wireless communication system having a general cell structure, one AP manages one cell, and the AP serves a mobile station (MS) located in the cell. To provide. The MS may move from a cell currently receiving a service to another adjacent cell, wherein the MS is an AP that manages the current serving cell, that is, an AP that manages the adjacent other cell in a serving AP, that is, a target AP. Handover to the AP).

1 is a diagram schematically illustrating a structure of a general wireless communication system.

Referring to FIG. 1, the wireless communication system includes a multi-cell structure, that is, a cell 1 (110), a cell 2 (120), and a cell 3 (130), and the AP 1 (112) managing the cell 1 (110). ), The AP2 122 that controls the Cell 2 120, the AP3 132 that manages the Cell 3, and the MS1 114, MS2 124, and MS3 134 located in each cell region. Include. The MSs, that is, MS1 114, MS2 124, and MS3 134, may move from the cell in which they are currently located to another cell. That is, MS1 114 located in cell 1 110 may move to adjacent cell 2 120 or cell 3 130, and MS2 124 located in cell 2 120 may move to cell 1 110. Alternatively, the cell 3 130 may be moved, and the MS3 134 located in the cell 3 130 may be moved to the cell 1 110 or the cell 2 120. When the MSs 114, 124, and 134 move from one cell to another cell, the MSs 114, 124, and 134 perform handover from the serving AP to the target AP.

In performing the handover, a method of determining a target AP among two or more neighboring APs, after the MS measures the strength of the signal received from the neighboring APs and corresponds to the target AP corresponding to the measured signal strength It may be divided into a method of determining and a method of determining a target AP through the MS's past mobility information.

Among the above methods, the method of performing a handover by determining a target AP by the former method is performed by the MS after measuring the strength of a signal received from all APs including the current serving AP and neighboring APs. The AP having the largest strength of the received signal is determined as a target AP, that is, a new serving AP, and the strength of the signal received from the new serving AP and the strength of the signal received from the current serving AP are determined by the starting point of the handover. The handover is performed at the same time. That is, the target AP is determined by the former method, and then a handover is performed to the target AP through a general handover process at the above point in time. As described above, a method of performing a handover after determining a target AP by the former method performs a general handover process after determining a target AP, thus causing a large time delay in performing the handover process. .

In addition, a method of performing a handover by determining a target AP by the latter method may use a statistical probability based on past movement information of the MS to predict a cell to be moved later in the current cell, and to determine the predicted cell. The AP that manages is determined as a target AP. That is, when the MS moves to each other cell in Cell 1 (110), Cell 2 (120), and Cell 3 (130), respectively, the probability of the MS moving from each cell to another cell is calculated based on the movement information of the MS. . Accordingly, when MSs 114, 124, and 134 located in each cell move to another cell, the cell is predicted to move according to the calculated probability, and a target AP is determined from among adjacent APs.

For example, the probability that the MS moves from cell 1 110 to cell 2 120 is 5/7, and the probability of moving from cell 1 110 to cell 3 130 based on the past movement information of the MS is 2 /. 7, the probability of moving from cell 2 (120) to cell 1 (110) is 3/8, the probability of moving from cell 2 (120) to cell 3 (130) is 5/8, and from cell 3 (130) to cell 1 (110). Assuming that the probability of moving to () is 3/5, and the probability of moving from cell 3 (130) to cell 2 (120) is calculated as 2/5, MS1 (114) located in cell 1 (110) is determined as cell 2 (120). Since cell 2 120 is most likely to move to the cell to be predicted, AP 2 122 is determined as the target AP. In addition, MS2 124 located in cell 2 120 determines AP3 132 as the target AP, and MS3 134 located in cell 3 130 determines AP1 112 as the target AP. When the target AP is determined in this way, the determined target AP allocates resources for the MS to move to the cell that manages it. Then, if a predetermined time elapses and the MS moves to a cell managed by the target AP, the MS performs a handover to the target AP.

In this way, the target AP allocates resources for the MS that is expected to move to the cell area that it manages, and there is a problem that causes a waste of resources. For example, in MS1 114 located in cell 1 110, MS1 114 is predicted to move to cell 2 120 based on the probability of past movement information of MS1 114, and thus the cell. AP2 122, which governs 2 120, allocates resources for the MS1 114 as a target AP. However, the MS1 114 may actually move to the cell 3 130 instead of the cell 2 120, or may be continuously positioned in the cell 1 110. In addition, the MS1 114 may move to the cell 2 120 after a predetermined time does not move to the cell 2 120 immediately after the AP2 122 allocates resources for itself. Accordingly, the AP2 122 occupies the unnecessary resource for a long time by pre-allocating the resource for the MS1 114 who may not accurately move to the cell 2 120. That is, the MS does not exactly know when to start handover from the serving AP to the target AP, and as a result, the target AP always wastes resources by allocating resources in advance so that the MS can perform the handover. there is a problem.

Accordingly, an object of the present invention is to provide a system and method for supporting handover in a wireless communication system capable of preventing waste of resources without time delay.

The method proposed in the present invention is a wireless communication including a mobile terminal, a serving access point for providing a communication service to the mobile terminal, and a target access point to which the mobile terminal is to handover, different from the serving access point. In the method for supporting handover in the system, when the mobile terminal detects that the mobile terminal should be handed over, receiving the location information of the mobile terminal and predicting the handover time of the mobile terminal according to the location information And controlling the target access point so that the target access point allocates resources at the handover time point, and establishing a connection between the target access point and the mobile terminal; When the mobile terminal detects that the mobile terminal should be handed over, comparing the location information of the mobile terminal with a threshold of prestored location information, and as a result of the comparison, the threshold value of the location information of the mobile terminal is stored. If exceeded, the method may further include receiving location information of the mobile terminal again.

The system proposed by the present invention is a wireless communication including a mobile terminal, a serving access point for providing a communication service to the mobile terminal, and a target access point to which the mobile terminal will handover, which is different from the serving access point. In a system that supports handover in the system,
When the mobile terminal detects that the mobile terminal should be handed over, the mobile station receives location information of the mobile terminal, predicts a handover time of the mobile terminal according to the location information, and then accesses the target at the predicted handover time. A controller for controlling the target access point to allocate resources and for establishing a connection between the target access point and the mobile terminal; When the controller detects that the mobile terminal should be handed over, the controller compares the position information of the mobile terminal with a threshold value of the previously stored position information, and as a result of the comparison, the threshold of the position information at which the position information of the mobile terminal is previously stored. When the value is exceeded, the location information of the mobile terminal is re-received.

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

The present invention manages a cell providing a current service when a mobile station (MS) in a wireless communication system moves from a cell receiving a current service to another adjacent cell. AP (Access Point, hereinafter referred to as 'AP'), that is, from the serving AP (Serving AP) to the AP that manages the other cells, that is, the target AP (Target AP) without time delay and waste of resources We propose a system and method for handover. The present invention predicts a time to perform a handover to the target AP by recognizing the current position of the MS through the location information of the MS, and the target AP allocates resources for the MS according to the predicted handover time. Assign it.

In the following description of the present invention, the serving AP is based on recognizing the location information of the MS using a GPS signal of a satellite positioning system (GPS: Global Positioning System (GPS)). However, the present invention is applicable to a wireless communication system that performs handover through a signal including location information of the MS as well as the GPS signal.

2 is a diagram schematically illustrating a structure of a system for handover in a wireless communication system according to an embodiment of the present invention.

 Referring to FIG. 2, the wireless communication system may include APs AP1, AP2, and AP3 210, 220, and 230 that manage different cells, and an MS 240 capable of moving to cells managed by the APs 210, 220, and 230. And a controller 250 that controls the APs 210, 220, and 230. In addition, the APs 210, 220, 230 and the MS 240 each have a GPS receiver capable of receiving a GPS signal provided by the GPS 260, and thus the MS 240 is provided by the GPS 260. The APs 210, 220, and 230 may receive location information of the MS 240 provided by the GPS 260. Hereinafter, for convenience of explanation, the serving AP of the MS 240 is assumed to be AP1 210 and the target AP will be described with reference to AP2220.

The MS 240 receives a GPS signal including its own location information from the GPS 260 and transmits the GPS signal including its own location information to the AP1 210 serving as a serving AP. The AP1 210 receiving the GPS signal transmits the location information of the MS 240 included in the GPS signal to the controller 250, and the controller 250 transmits the location information of the MS 240. The MS 240 recognizes the current location and movement information of the MS 240 to predict when the MS 240 performs handover to AP2 220, which is a target AP. At this predicted handover time, the controller 250 controls the AP2 220 to allocate resources for the MS 240 and also establishes a wireless connection between the AP2 220 and the MS 240. .

Here, the controller 250 may exist at an upper end of the APs 210, 220, 230 or inside an access router that is inside the APs 210, 220, 230, as well as the controller 250 of the MS 240. It can be present inside. In this case, when the controller 250 is present at the upper end of the APs 210, 220, and 230, the controller 250 has all information about the APs 210, 220, and 230, and the controller 250 is inside the APs 210, 220, and 230. And when present in the MS 240, all of information on neighboring APs. Hereinafter, for convenience of description, it is assumed that the controller 250 exists in the upper stages of the APs 210, 220, and 230, and the case in which the controller 250 exists inside the MS 240. The location information is applicable to all wireless communication systems performing handover. In addition, hereinafter, the controller 250 will be described with reference to FIGS. 3 to 5 when the controller 250 is present in the APs 210, 220, and 230, and the controller 250 will be described with reference to FIGS. 6 to 8. It will be described in the case where it exists inside).

FIG. 3 is a diagram schematically illustrating a controller structure of a system for handover in a wireless communication system according to an embodiment of the present invention.

Referring to FIG. 3, the controller 310 includes a measurement information storage unit 311, a fixed information storage unit 313, a viewpoint predictor 315, and a handover trigger 317.

The measurement information storage unit 311 is the position information of the MS 320, that is, the current position information, the movement direction information and the movement speed information of the MS 320, the signal strength between the MS 320 and the serving AP 330 Save it. The current location information, the movement direction information, and the movement speed information of the MS 320 may be transmitted to the serving AP 330 by the MS 320 receiving the GPS signal including its location information from the GPS. The controller 310 measures the position information of the MS 320 included in the GPS signal received by the serving AP 330 and is stored in the measurement information storage unit 311. That is, the controller 310, the current position information, the movement direction information and the movement speed information of the MS 320 included in the GPS signal through the GPS signal received by the serving AP 330 from the MS 320. After the measurement, the measured information is stored in the measurement information storage unit 311. In addition, the signal strength between the MS 320 and the serving AP 330 is the channel quality information between the MS 320 and the serving AP 330, that is, the MS 320 from the serving AP 330. The controller 310 measures the signal quality of the received downlink channel and is stored in the measurement information storage 311.

Here, the controller 310 determines whether the MS 320 will perform a handover based on the signal strength. At this time, if it is determined that the MS 320 performs the handover, the MS 320 measures location information of the MS 320 and stores the location information in the measurement information storage unit 311. In addition, the controller 310 predicts a cell to which the MS 320 will move based on the movement direction information included in the position information of the MS 320, and the target AP 340 among neighboring APs corresponding to the prediction. Determine.

The fixed information storage unit 313 may include a threshold value of the information stored in the measurement information storage unit 311, that is, a threshold value of the signal strength, a threshold value of a moving direction, and a threshold value of a moving speed, and the MS 320. ) Stores information about the time required in hardware to perform the handover. Here, the threshold values are preset values stored by a system user or an administrator.

The threshold of the signal strength is a criterion for determining whether the MS 320 performs handover through the signal strength stored in the measurement information storage 311. That is, if the quality of the signal received by the MS 320 from the serving AP 330 is degraded and the stored signal strength is less than the threshold of the signal strength, the controller 310 determines that the MS 320 It is determined that handover is performed to the target AP 340. Accordingly, the controller 310 periodically measures the current position information, the movement direction information, and the movement speed information of the MS 320 included in the GPS signal from the time when the controller 310 becomes smaller than the threshold value, thereby measuring the measurement information storage unit ( 311).

The threshold value of the moving direction becomes a criterion for determining the reliability of the moving direction information of the MS 320 stored in the measurement information storage unit 311 when the MS 320 changes the moving direction. That is, if the stored movement direction information is smaller than the threshold value of the movement direction, it means that the MS 320 does not move to the cell predicted by the controller 310, so that the controller 310 again returns the MS 320. The new target AP may be determined by measuring the moving direction information through the position information of. In addition, the re-measured moving direction information is stored in the measurement information storage unit 311.

Since the moving speed of the MS 320 is variable, the threshold of the moving speed becomes a criterion for determining the reliability of the moving speed information of the MS 320 stored in the measurement information storage 311. That is, when the change speed of the movement speed of the MS 320 is smaller than the threshold value of the movement speed, the controller 310 again measures the movement speed information through the position information of the MS 320 and stores the measurement information. Stored in the unit 311.

The viewpoint predictor 315 predicts a start time for the MS 320 to perform a handover by using the information stored in the measurement information storage 311 and the information stored in the fixed information storage 313. . At this time, when the MS 320 changes the moving direction or the moving speed is variable, the controller 310 again moves through the position information of the MS 320 and the moving direction information including the current position information of the MS 320. And measure the moving speed and store in the measurement information storage unit 311. Then, the time predictor 315 again predicts the start time for the MS 320 to perform the handover by using the measured and stored information.

Then, the viewpoint predictor 315 is configured to perform the actual MS 320 through information about the starting time point and the time required for hardware handover by the MS 320 stored in the fixed information storage unit 313 to perform a handover. Predict the handover time of. Accordingly, the viewpoint predictor 315 predicts a reliable handover timing of the MS 320. The time predictor 315 predicting the handover time of the MS 320 transmits a control command corresponding to the handover time to the handover trigger 317. The handover trigger 317 causes the target AP 340 to allocate resources for the MS 320 at the handover time by a control command received from the time predictor 315. 340 establishes a wireless connection between 340 and MS 320.

4 is a diagram schematically illustrating a structure of a system for performing handover in a wireless communication system according to an embodiment of the present invention.

Referring to FIG. 4, when the MS 430 located in the serving cell 410 and receiving a service from the serving AP 412 moves from the serving cell 410 to the target cell 420, the MS 430 Needs to perform a handover from the serving AP 412 to the target AP 422 managing the target cell 420. In order for the MS 430 to perform such handover at an appropriate point, the controller 310 may transmit the current location information and the moving direction of the MS 430 through the location information of the MS 430 received from the serving AP 412. Information and movement speed information are measured and stored in the measurement information storage unit 311. In addition, the controller 310 stores the signal strength of the channel that the MS 430 receives from the serving AP 412 in the measurement information storage 311. Hereinafter, for convenience of explanation, it will be described on the assumption that an appropriate point of handover is an intermediate point between the serving AP 412 and the target AP 422. Accordingly, when the distance from the serving AP 412 to the target AP 422 is D, a proper point of handover becomes a point D / 2.

If the strength of the signal stored in the measurement information storage unit 311 is less than the threshold of the signal strength stored in the fixed information storage unit 313 of the controller 310, the controller 310 is the MS (430) Determines that the serving AP 412 performs the handover from the target AP 422. Then, the controller 310 measures the current position information, the movement direction information and the movement speed information of the MS 430 and stores it in the measurement information storage unit 311. Accordingly, the viewpoint predictor 315 of the controller 310 uses the current position information, movement direction information, and movement speed information of the MS 430 to hand the MS 430 to the target AP 422. The start time T to perform the over, i.e., the time at which the MS 430 arrives at the handover appropriate point is predicted.

In other words, the viewpoint predictor 315 may recognize the distance d from the serving AP 412 to the MS 430 through the current position information of the MS 430, and may indicate movement direction information. Through the movement direction θ of the MS 430, the movement speed v of the MS 430 may be known through the movement speed information. Accordingly, the viewpoint predictor 315 may know the distance x to the appropriate handover point through the current position of the phase 30 and the moving direction θ, and as a result, the MS 430 determines that the MS 430 is a hand. The time T arriving at the over titration point, that is, the start time T at which the MS 430 performs handover is predicted.

In addition, the viewpoint predictor 315 performs hardware handover through information on a time required for hardware for the MS 320 stored in the fixed information storage unit 313 of the controller 310 to perform a handover. Note the execution delay time t. Accordingly, the time predictor 315 transmits a control command corresponding to the start time T and the delay time t, that is, the handover time T-t, to the handover trigger 317. The handover trigger 317 receiving the control command controls the target AP 422 to allocate resources for the MS 430 after a Tt time elapses, and after the Tt time elapses, the target AP. A wireless connection is established between 422 and the MS 430.

Here, when the MS 430 switches the moving direction or the moving speed is variable and the moving direction information and the moving speed information are smaller than each threshold as described above, the controller 310 again moves to the position of the MS 430. The moving direction information and the moving speed information are measured through the information and stored in the measurement information storage unit 311. Then, the time point for performing the handover is calculated by the time predictor 315 and the handover trigger 317 as described above. As a result, the target AP 420 allocates resources for the MS 430. The wireless connection is established between the target AP 420 and the MS 430.

5 is a diagram illustrating an operation process of a controller performing a handover in a wireless communication system according to an embodiment of the present invention.

Referring to FIG. 5, in step 501, the controller measures channel quality information between a serving AP and the MS, that is, the strength of a received signal received by the MS from the serving AP and stores the measured quality in the measurement information storage unit. In step 503, the MS determines whether to perform a handover by comparing the measured strength of the received signal with a threshold of the signal strength already stored in the fixed information storage unit of the controller. If the measured intensity of the received signal is greater than the threshold of the signal strength, the controller determines that the MS does not perform the handover and proceeds to step 501 again.

On the other hand, if the measured intensity of the received signal is less than the threshold of the signal strength, the controller determines that the MS will perform a handover to proceed to step 505. In step 505, the position information of the MS is measured from the time when the strength of the received signal is smaller than the threshold value, and the measured position information is stored in the measurement information storage unit. Here, when the MS receives a GPS signal including its location information from the GPS and transmits the GPS signal to the serving AP, the controller stores the GPS signal received by the serving AP. The location information of the MS includes current location information, movement direction information, and movement speed information of the MS.

Thereafter, in step 507, the distance from the current location of the MS to a proper handover point is calculated using the current location information and the moving direction information of the stored MS. In step 509, the MS calculates a start time for performing the handover by using the calculated distance and movement speed information. In operation 511, the position information of the MS stored in the measurement information storage unit and the threshold values stored in the fixed information storage unit are compared to determine the change of the moving direction of the MS and the change of the moving speed of the MS. That is, the moving direction information and the moving speed information of the MS stored in the measurement information storage unit are compared with the threshold values of the respective threshold values, the moving direction thresholds, and the moving speed stored in the fixed information storage unit. If the location information of the MS is greater than the respective threshold values, the reliability of the calculated start time point is low, and the flow proceeds to step 505 to store and store the location information of the MS again. On the other hand, if the location information is less than the respective threshold value, the process proceeds to step 513.

In step 513, the MS performs handover to the target AP according to the calculated start time point and the handover execution delay time. Here, the handover execution delay time is determined in advance by the information about the time required by the hardware stored in the fixed information storage unit to perform the handover. Corresponding to this control, the target AP causes the resource to be allocated for the MS, and a wireless connection is established between the target AP and the MS.

FIG. 6 is a diagram schematically illustrating a controller structure of a system for handover in a wireless communication system according to another embodiment of the present invention.

Referring to FIG. 6, the MS 620 includes a controller 610 and a GPS receiver 625 capable of receiving GPS signals, and the controller 610 includes a measurement information storage unit 611 and fixed information. A storage unit 613, an information calculator 615, a viewpoint predictor 615, and a handover trigger 617 are included.

The measurement information storage unit 611 measures location information of the MS 620, that is, current location information and movement direction information of the MS 620, and signal strength between the MS 620 and the serving AP 630. Save it. The current location information and the moving direction information of the MS 620 are included in the GPS signal when the MS 620 receives the GPS signal including its location information from the GPS through the GPS receiver 625. After measuring the current position information and the movement direction information of the MS 620, the measured information is stored in the measurement information storage unit 611. In addition, the signal strength between the MS 620 and the serving AP 630 is the channel quality information between the MS 620 and the serving AP 630, that is, the MS 620 from the serving AP 630. The controller 610 measures the signal quality of the received downlink channel and is stored in the measurement information storage unit 611. In addition, as the measurement information storage unit 611 receives the GPS signal from the GPS at a predetermined period, the position information of the MS 620 is measured and stored again every predetermined period, and the strength of the signal is also predetermined. It is measured again at a period of and stored in the measurement information storage unit 611.

The fixed information storage unit 613 may include thresholds for performing the handover of the MS 620, that is, the threshold of the signal strength and the threshold of the handover determination, the cell radius of the serving cell, and the serving cell. The handover radius, location information of the serving AP 630, location information of neighboring APs including the target AP 640, and time information hardware required for the MS 620 to perform handover are stored. Here, the thresholds and time information hardware-necessary for the MS 620 to perform the handover are preset values and stored by a user or an administrator of the system, and the cell radius of the serving cell and the serving cell of the serving cell. A handover radius, location information of the serving AP 630, and location information of neighboring APs including the target AP 640 are received and stored from the serving AP 630.

In addition, the threshold of the signal strength is a criterion for determining whether the MS 620 performs handover through the signal strength stored in the measurement information storage unit 611. That is, if the quality of a signal received by the MS 620 from the serving AP 630 is deteriorated so that the stored signal strength is smaller than the threshold of the signal strength, the controller 610 determines that the MS 620 is configured to receive the signal. It is determined that handover is performed to the target AP 640. In addition, since the MS 620 determines that the handover is to be performed, the handover decision threshold is a determination criterion for performing the handover from the serving AP 630 to the target AP 640. That is, when the controller 610 determines to perform a handover, the serving cell stored in the fixed information storage unit 613 and the location information of the MS 620 stored in the measurement information storage unit 611. The MS 620 and the serving AP 630 corresponding to a cell radius of the serving cell, a handover radius of the serving cell, location information of the serving AP 630, and location information of neighboring APs including the target AP 640. ) And distances between the target AP 640 and the calculated result is less than the handover decision threshold, the MS 620 determines to perform a handover to the target AP 640.

The information calculator 615 uses the MS 620 and the serving AP using the location information of the MS 620 stored in the measurement information storage 611 and the information stored in the fixed information storage 613. 630 and respective distances between the target AP 640 are calculated, and the distances to the MS 620 and the handover appropriate point are calculated according to the calculated values. In addition, as the position information of the MS 620 stored in the measurement information storage unit 611 is stored again at a predetermined cycle, the distances are calculated at a predetermined cycle, and the MS 620 is moved using the calculation result. Calculate the speed. The information calculator 615 that calculates the distance between the moving speed information of the MS 620 and the appropriate handover point by using the information stored in the measurement information storage unit 611 and the fixed information storage unit 613 as described above. The calculated information is transmitted to the viewpoint predictor 617.

The viewpoint predictor 617 uses the information received from the information calculator 615 to predict a start time for the MS 620 to perform a handover. In this case, when the MS 620 switches the moving direction or the moving speed is changed, the controller 610 again moves through the location information of the MS 620 and includes the current location information of the MS 620. Information is measured and stored in the measurement information storage unit 611, and the information calculator 615 calculates the above-mentioned values and delivers the values to the viewpoint predictor 617. Then, the time predictor 617 re-predicts the start time for the MS 620 to perform the handover by using the calculated and transferred information.

Then, the viewpoint predictor 617 uses the MS 620 based on the starting time and information about a hardware time required for the MS 620 stored in the fixed information storage unit 613 to perform a handover. Predicts when to perform a handover. Accordingly, the viewpoint predictor 617 predicts a reliable handover timing of the MS 620. The viewpoint predictor 617 predicting the handover timing of the MS 620 transmits a control command corresponding to the handover timing to the handover trigger 619. The handover trigger 619 causes the target AP 640 to allocate resources for the MS 620 at the handover time by a control command received from the viewpoint predictor 619, and the target AP 640. ) And establish a wireless connection between the MS 620.

7 is a diagram schematically illustrating a structure of a system for performing handover in a wireless communication system according to another embodiment of the present invention.

Referring to FIG. 7, when the MS 730 located in the serving cell 710 and receiving a service from the serving AP 712 moves from the serving cell 710 to the target cell 720, the MS 730 Needs to perform a handover from the serving AP 712 to the target AP 722 that manages the target cell 720. The controller 610 transmits the current position information and the moving direction information of the MS 730 through the position information of the MS 730 received from the GPS so that the MS 730 performs the handover at an appropriate point. The measurement information is stored in the measurement information storage unit 611. In addition, the controller 610 stores the signal strength of the channel that the MS 730 receives from the serving AP 712 in the measurement information storage unit 611.

Hereinafter, for convenience of explanation, a proper point of handover will be described on the assumption that it is an intermediate point between the serving AP 712 and the target AP 722, and the serving AP 712 at the target AP 722. If the distance to D is D, an appropriate point for handover is D / 2. In addition, as described above, the fixed information storage unit 611 of the controller 610 includes thresholds for performing the handover of the MS 730, that is, the signal strength threshold and the handover determination threshold. The cell radius R of the serving cell 710, the handover radius r of the serving cell 710, location information of the serving AP 712, and locations of neighboring APs including the target AP 722. Information, and time information hardware necessary for the MS 730 to perform the handover is stored. In addition, the measurement information storage unit 611 of the controller 610 includes position information of the MS 730, that is, current position information and movement direction information θ of the MS 730, and the MS 730 and the serving AP. The signal strength between 712 is stored.

When the strength of the signal stored in the measurement information storage unit 611 is smaller than the threshold value of the signal strength stored in the fixed information storage unit 613 of the controller 610, the controller 610 is determined by the MS 730; The serving AP 712 determines to perform a handover to the target AP 722. In addition, the MS 730 and the serving AP through the position information of the MS 730 stored in the measurement information storage unit 611 and the position information of the serving AP 712 stored in the fixed information storage unit 613. A distance d _s is calculated between 712 and the distance between the MS 730 and the neighboring APs based on the position information of the MS 730 and the position information of the neighboring APs stored in the fixed information storage unit 613. The distance d _t between the MS 730 and the target AP 722 is calculated by calculating. Then, the calculated distance d _s between the MS 730 and the serving AP 712 is compared with the handover cell radius r of the serving cell stored in the fixed information storage unit 613. As a result of the comparison, if the distance d _s is greater than the handover cell radius r, the controller 610 may perform the handover of the MS 730 from the serving AP 712 to the target AP 722. After determining that the controller 610 determines the target AP 722 through the position information of the MS 730 stored in the measurement information storage 611, in particular, the moving direction information θ.

As such, the target AP 722 is determined, the information calculator 615 of the controller 610, the position information of the MS 730 and the image serving AP 712 stored in the measurement information storage unit 611. The MS 730, the serving AP 712, and the target by using the location information of the serving AP 712 and the location information of the target AP 722 received from the fixed information storage unit 613. The distances d _s and d _t between the APs 722 are calculated. Then, the information calculator 615 calculates the distance x to the appropriate handover point of the MS 730 through the calculated distances d _s and d _t . In this case, if the difference d _ts between the two distances d _s and d _t is smaller than the handover decision threshold stored in the fixed information storage unit 613, the controller 610 may determine that the MS 730 is not present. The serving AP 712 determines to perform handover from the target AP 722.

On the other hand, when a predetermined period is reached, the measurement information storage unit 611 measures and stores the information again, and the information calculator 615 uses the information stored in the measurement information storage unit 611 again. To recalculate the calculated values. Through this recalculation, the information calculator 615 calculates the moving speed of the MS 730. That is, the information calculator 615 calculates the difference d _ts between the two distances d _s and d _t calculated at the present time and the two distances d _s ' calculated after the predetermined period of time elapses. , d _t ') of the difference (d _ts') of the current moving direction of the MS (730) by calculating a change amount (Δd) of the predetermined cycle while the distance difference _{(d ts, d ts')} , i.e. the MS via It is determined whether 730 is currently moving to the target AP 722. The moving speed of the MS 730 is calculated based on the information measured and calculated at predetermined intervals.

Here, for convenience of description, each distance between the MS calculated at the current time, the serving AP, and the target AP and the difference between the two distances is represented by d _s , d _t , d _ts , and the time passes by a predetermined period. the difference between the distances and the two distances between the MS and the serving AP and the target AP calculated after a d _s', d _t ', d _ts' to indicate, as a result, the distance difference for the predetermined period (d _ts, d _ts 'change (Δd) of a) is d _ts' - is defined as d _ts. Hereinafter, for convenience of explanation, each distance and values calculated by the distances are applied in the same manner as described above.

Accordingly, the viewpoint predictor 617 of the controller 610 may use the information calculated by the information calculator 615 to start the MS 730 to perform a handover to the target AP 722. T), i.e., the time at which the MS 730 will arrive at the handover appropriate point. In addition, the viewpoint predictor 617 uses the MS 730 through information about a time required for hardware for the MS 730 stored in the fixed information storage unit 613 of the controller 610 to perform a handover. Note the time delay t of the hardware handover execution. Accordingly, the time predictor 617 transmits a control command corresponding to the start time T and the delay time t, that is, the handover time T-t, to the handover trigger 619. The handover trigger 619 that receives the control command controls the target AP 722 to allocate resources for the MS 730 after the Tt time elapses, and after the Tt time elapses, the target AP 722. ) And the MS 730 is established.

Here, even if the MS 730 switches the moving direction or the moving speed is variable, the controller 610 again measures the position information of the MS 730 when the predetermined period is reached and the measurement information storage unit. By storing in 611, the information calculator 615 calculates the handover proper point and the moving speed of the MS 730, as described above, and sends it to the viewpoint predictor 617 and the handover trigger 619. Predicting a time to perform a handover by, the target AP 720 allocates resources for the MS 730, and a wireless connection is established between the target AP 720 and the MS 730 .

8 is a diagram illustrating an operation of a controller for performing handover in a wireless communication system according to another embodiment of the present invention.

Referring to FIG. 8, in step 801, the controller measures channel quality information between a serving AP and the MS, that is, the strength of a received signal received by the MS from the serving AP and stores the measured signal strength in the measurement information storage unit. In step 803, the MS determines whether to perform the handover by comparing the measured strength of the received signal with a threshold of the signal strength already stored in the fixed information storage unit of the controller. If the measured intensity of the received signal is greater than the threshold of the signal strength, the controller determines that the MS does not perform the handover and proceeds to step 801 again.

On the other hand, if the measured strength of the received signal is less than the threshold of the signal strength, the controller determines that the MS will perform a handover to proceed to step 804. In step 804, the controller receives and stores all information including the information of the neighboring AP from the serving AP. That is, as described above, the fixed information storage unit of the controller includes thresholds for performing the handover of the MS, that is, the signal strength threshold, the handover determination threshold, and the cell radius R of the serving cell. ), Handover radius (r) of the serving cell, location information of the serving AP, and time information hardware necessary for the MS to perform handover is stored. Also. The measurement information storage unit stores the position information of the MS, that is, the current position information of the MS and the moving direction information θ.

In operation 805, the controller calculates a distance d _s between the serving AP and the MS by using the current position information of the MS and the position information of the serving AP stored in the measurement information storage unit and the fixed information storage unit. In addition, by calculating the distance (d _c ) between the MS and the neighboring AP using the current position information of the MS and the position information of neighboring APs including the target AP, the distance between the AP to be determined as a target AP and the target AP, that is, the target AP Calculate the distance d _t between and MS. Then, in operation 807, the calculated distance between the serving AP and the MS d _s is compared with the handover radius r of the serving cell. In step 807, if the distance d _s between the serving AP and the MS is smaller than the handover radius r of the serving cell, the controller proceeds to step 801 again.

On the other hand, if the distance d _s between the serving AP and the MS is greater than the handover radius r of the serving cell in step 807, the controller determines that the MS performs the handover and proceeds to step 809. do. That is, the controller determines that the MS performs the handover in steps 803 and 807. Next, in step 809, the controller selects a target AP from among the neighboring APs according to the movement direction information θ of the MS stored in the measurement information storage unit and the calculated distance between the MS and the neighboring AP d _c . Select and decide. In operation 811, the controller re-measures the position information of the MS and stores the measurement information again in the measurement information storage unit, and then stores the distance d _s ' between the serving AP and the MS. The distance d _t ′ between the target AP and the MS is calculated.

In operation 813, the calculated distance d _t ′ between the target AP and the MS is compared with the cell radius R of the serving cell. In this case, if the distance d _t ′ is greater than the cell radius R, the process proceeds to step 825 and compares the distance d _s ' between the serving AP and the MS with the handover cell radius r. In this case, when the distance d _t ′ between the target AP and the MS is greater than the cell radius R of the serving cell, the MS does not move to the target AP in step 813. If the distance d _s ′ is greater than the handover cell radius r compared to the distance d _s ′ between the AP and the MS and the handover cell radius r, the MS performs handover as described above. Since it is determined to be performed, the flow proceeds to step 811 again. In contrast, when the distance d _s ′ between the serving AP and the MS is smaller than the handover cell radius r in step 825, the MS will not perform a handover to the target AP, that is, the serving cell. Since it is determined to exist within, the operation of the controller for performing the handover of the MS is terminated.

On the other hand, if the distance d _t ′ between the target AP and the MS is smaller than the cell radius R of the serving cell, the controller proceeds to step 815, and the controller proceeds to the predetermined period in step 815. The difference d _ts between the distance (d _s ) between the serving AP and the MS before the elapsed time and the distance d _t between the target AP and the MS is calculated. After calculating the difference (d _ts ') between the two distances (d _s ', d _t ') after the elapsed time, the amount of change (Δd) of the distance difference (d _{ts ,,} d _ts ') during the elapsed time is calculated. Then, if the change amount Δd is less than 0 in step 817, the MS is currently moving to the target AP, and the process proceeds to step 819 to determine the handover. primary storage (d _ts ') is the fixed information of the AP and the MS distance (d _s ") and the target AP and the MS distance (d between _t') between If it is less than the handover decision threshold stored in the unit, the process proceeds to step 821.

In step 821, information stored in the measurement information storage unit and the fixed information storage unit, that is, location information of the serving AP, the target AP, and the MS, and values calculated during the predetermined period, that is, the serving in the MS The distance (d _s , d _s ', d _t , d _t ') between the AP and the target AP, the difference between the two distances (d _ts , d _ts ') and the change amount of the distance difference (d _ts , d _ts ') ( After calculating the moving speed of the MS through Δd), a handover proper point and a handover start time point of the MS are calculated. Then, the MS performs handover to the target AP according to the time information hardware-necessary for the MS stored in the handover start time and the fixed information storage unit to perform the handover to the target AP in step 823. And the target AP allocates resources for the MS according to the control, and a wireless connection is established between the target AP and the MS.

On the other hand, if the change amount Δd of the distance difference d _ts and d _ts ′ is greater than 0 in step 817, the MS does not move to the target AP at present, and the process proceeds to step 811 again. The distance d _s ' between MSs and the distance d _t ′ between the target AP are calculated. Also, in step 819, if the difference d _ts 'between the two distances d _s ' and d _t ′ is greater than the handover decision threshold, the MS does not perform the handover.

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

As described above, when the mobile terminal moves between cells managed by different access points, the mobile terminal predicts a handover time using the location information of the mobile terminal, and performs a handover at the predicted time point. By doing so, it is possible to prevent time delay and waste of resources for handover.

Claims (20)

A method for supporting handover in a wireless communication system comprising a mobile terminal, a serving access point for providing a communication service to the mobile terminal, and a target access point different from the serving access point and to which the mobile terminal will handover. To If the mobile terminal detects that the mobile terminal should be handed over, receiving location information of the mobile terminal; Estimating a handover time of the mobile terminal according to the location information; Controlling the target access point so that the target access point allocates resources at the handover time point; Establishing a connection between the target access point and the mobile terminal; When the mobile terminal detects that the mobile terminal should be handed over, comparing the location information of the mobile terminal with a threshold of previously stored location information; And re-receiving location information of the mobile terminal when the location information of the mobile terminal exceeds a threshold value of previously stored location information as a result of the comparison. The method of claim 1, The location information includes current location information of the mobile terminal, movement direction information and movement speed information. The method of claim 1, The process of detecting that the handover should be, Measuring the strength of a signal received by the mobile terminal from the serving access point, and then comparing the measured intensity of the signal with a threshold of a pre-stored signal strength; If the measured signal strength is less than the threshold of the signal strength, the mobile terminal recognizes that the handover should be included. delete delete The method of claim 1, Receiving the location information of the mobile terminal, And receiving location information of the serving access point and location information of the target access point. delete The method of claim 6, The process of detecting that the handover should be, A first distance between the serving access point and the mobile terminal, and between the target access point and the mobile terminal, corresponding to the location information of the serving access point, the location information of the target access point, and the location information of the re-received mobile terminal; Calculating the second distance, Comparing the first distance with a radius of a serving cell that manages the serving access point; If the first distance is greater than or equal to the radius of the serving cell, the mobile terminal recognizes that the handover should be performed. The method of claim 8, As a result of the comparison, when the first distance is greater than or equal to the radius of the serving cell, the first distance and the second distance are recalculated using the location information of the re-received mobile terminal, and the recalculated second distance and the Comparing the radius of the serving cell, If the recalculated second distance is less than the radius of the serving cell, the first difference value between the first distance and the second distance, the second difference value between the recalculated first distance, and the second distance; Calculate a third difference value between the first difference value and the second difference value, wherein the first distance, the second distance, the recalculated first distance, the recalculated second distance, the first difference Calculating a moving speed of the mobile terminal using a value, the second difference value and the third difference value, and then calculating a handover start time point of the mobile terminal. The method of claim 1, Receiving the location information, And receiving location information of the mobile terminal included in a signal transmitted by a global positioning system (GPS). A system for supporting handover in a wireless communication system including a mobile terminal, a serving access point for providing a communication service to the mobile terminal, and a target access point different from the serving access point and to which the mobile terminal will handover. To When the mobile terminal detects that the mobile terminal should be handed over, the mobile station receives location information of the mobile terminal, predicts a handover time of the mobile terminal according to the location information, and then accesses the target at the predicted handover time. A controller for controlling the target access point to allocate resources and for establishing a connection between the target access point and the mobile terminal; When the controller detects that the mobile terminal should be handed over, the controller compares the position information of the mobile terminal with a threshold value of the previously stored position information, and as a result of the comparison, the threshold of the position information at which the position information of the mobile terminal is previously stored. If the value is exceeded, the handover support system, characterized in that for receiving the location information of the mobile terminal again. The method of claim 11, The location information includes the current location information of the mobile terminal, movement direction information and movement speed information. The method of claim 11, The controller comprising: Measure the strength of the signal received by the mobile terminal from the serving access point, compare the measured signal strength with a threshold of a pre-stored signal strength, and as a result of the comparison the strength of the measured signal And if less than a threshold, the mobile terminal recognizes that the handover should be handed over. delete delete The method of claim 11, The controller may further receive location information of the serving access point and location information of the target access point. delete The method of claim 16, The controller comprising: A first distance between the serving access point and the mobile terminal, and between the target access point and the mobile terminal, corresponding to the location information of the serving access point, the location information of the target access point, and the location information of the re-received mobile terminal; Calculate the second distance, Compare the first distance and the radius of the serving cell that manages the serving access point, and when the comparison results the first distance is greater than the radius of the serving cell, the mobile terminal recognizes that the handover should be handed over Handover support system. The method of claim 18, The controller comprising: As a result of the comparison, when the first distance is greater than or equal to the radius of the serving cell, the first distance and the second distance are recalculated using the location information of the re-received mobile terminal, and the recalculated second distance and the Compare the radius of the serving cell, If the recalculated second distance is less than the radius of the serving cell, the first difference value between the first distance and the second distance, the second difference value between the recalculated first distance, and the second distance; Calculate a third difference value between the first difference value and the second difference value, wherein the first distance, the second distance, the recalculated first distance, the recalculated second distance, the first difference And a handover start time point of the mobile terminal after calculating a moving speed of the mobile terminal using the value, the second difference value and the third difference value. The method of claim 11, The controller is a handover support system, characterized in that for receiving the position information of the mobile terminal included in the signal transmitted by the Global Positioning System (GPS).

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