KR100594112B1 - Effective handover method of terminal using gps and the system therefor - Google Patents

Abstract

The present invention implements a handover function through efficient neighbor cell search in a mobile communication terminal. To this end, a mobile communication terminal in call service periodically uses GPS information to determine its speed and current location, calculates and stores an estimated moving location, and responds to the network based on the location information. Efficiently search for and select potent cells.

Handover, GPS, cell, mobile communication terminal

Description

Efficient HANDOVER METHOD OF TERMINAL USING GPS AND THE SYSTEM THEREFOR}

1 is a block diagram of a conventional mobile communication system used to explain the operation of the present invention;

2 is a block diagram illustrating an internal configuration of a mobile communication terminal according to an embodiment of the present invention;

3 is a diagram illustrating a method for providing location information to a network according to an embodiment of the present invention;

4 is a diagram illustrating a cell selection process according to movement of a mobile communication terminal according to an embodiment of the present invention;

5 is a diagram illustrating a handover operation process between a mobile communication terminal and a network according to an embodiment of the present invention.

The present invention relates to a handover method and a system thereof in a mobile communication terminal, and more particularly, to an efficient handover method and a system therefor in a mobile communication terminal using GPS.

In general, when a mobile communication terminal is powered on, the mobile communication terminal searches for and finds a cell of a selected Public Land Mobile Network (PLMN), selects it, and adjusts a channel to access the communication network. do. As long as the mobile communication terminal is powered on as described above, cell selection and reselection are performed in a continuous process. In particular, when the mobile communication terminal moves from cell to cell, the mobile communication terminal must disconnect from the faraway cell and reselect with a new suitable cell capable of receiving better signals. The cell reselection process of the mobile communication terminal includes selecting a more suitable cell and associated Radio Access Technology (RAT) based on the radio wave measurement and cell reselection criteria of the connected state. As described above, the conventional cell reselection method is such that the mobile communication terminal reselects a neighbor cell that satisfies a cell reselection criterion among cells suitable for the mobile communication terminal.

This cell reselection process will be described with reference to FIG. 1. 1 is a schematic configuration diagram of a conventional mobile communication system used for explaining the operation of the present invention. As shown in FIG. 1, as an example of a typical mobile communication system, a mobile communication system of Global System for Mobile Communication (GSM) / General Packet Radio Service (GPRS) is established by a fixed site base station located in each cell. A plurality of cells 102-112 each defining a wireless coverage area. For example, as shown in FIG. 1, cell 102 defines a wireless coverage area established by base station 114 located in cell 102, and similarly, each of the remaining cells 104-112. Defines an associated radio coverage area established by a corresponding base station (not shown) located within each of cells 104-112.

On the other hand, since the mobile station (MS) (hereinafter referred to as mobile communication terminal) 100 moves with the user from the position X to the position Y of the mobile communication system, the mobile communication terminal 100 receives signals from the base stations of the cells 102-112. Properties are continuously monitored and based on any selection criteria, the corresponding cell is selected via the associated base station. For example, if the signal characteristic from cell 110 is that cell 110 is selected as the optimal coverage area based on cell reselection criteria, then cell 110 is serving cell or mobile communication terminal 100. Is considered to be a cell that transmits and receives packet data.

As mentioned above, the mobile communication terminal continues to monitor signal characteristics from cells 102-112. For example, as shown in FIG. 1, as mobile communication terminal 100 moves along a location indicated from location X to location Y, the mobile communication terminal 100 is moved from the coverage area associated with cell 110. For example, it moves to a coverage area associated with other cells, such as cells 112 and 106. The mobile communication terminal 100 reselects the cell 112 as a serving cell if the cell 112 is considered to be an optimal cell based on signal characteristics from another cell, for example, the cell 112. In addition, the mobile communication terminal 100 reselects the cell 106 as a serving cell if the cell 106 is considered an optimal cell from the signal characteristics of another cell, for example, the cell 106.

Here, the above-described process will be described in more detail as described below. If it is assumed that the mobile communication terminal 100 moves from the cell 110 at the position X to the cell 106 at the position Y, the mobile communication terminal 100 has a path loss reference parameter for each cell. The criterion parameter C1 value, the reselection criterion parameter C2 value, the signal level threshold criterion parameter C31 value and the cell ranking criterion parameter C32 value are calculated. As a result of the calculation, it is assumed that the reception strength of the cell is good in the order of the cell 112, the cell 106, and the cell 102 and the cell 112 are inappropriate cells. When the mobile communication terminal 100 moves from the cell 110 serving cell to the cell 106 side, the cell 112 serving as an unsuitable cell has a priority of cell reselection due to the reception strength of the cell. Therefore, the mobile communication terminal 100 first receives the corresponding cell information including the suitability of the cell 112 and determines whether the cell becomes a suitable cell. As a result of determination, when the cell 112 determines that the cell 112 is an unsuitable cell, the mobile communication terminal 100 receives the cell information indicating whether the cell 112 has a good reception strength and then determines whether the cell is a suitable cell. Accordingly, when the mobile communication terminal 100 determines that the cell 106 is a suitable cell, the mobile communication terminal 100 camps on the cell 106.

As described above, the mobile communication terminal camped on the serving cell in the mobile communication system performs cell reselection based on cell reselection criteria. Here, the cell reselection criteria for causing the mobile communication terminal to attempt cell reselection will be described later. First, the first cell reselection criterion is a case where the position loss reference parameter C1 is higher than a predetermined threshold in the mobile communication terminal camped in the serving cell. In this case, the cell reselection is performed. The second cell reselection criterion is a downlink signaling fail, and the third is a better cell based on the C2, C31 and C32 values in the same location area. This is the case when a significantly better cell is found in another location area.

As described above, in the conventional cell reselection process, when neighbor cells satisfying the aforementioned cell reselection criteria are generated, cell information including suitability is received from the network. Thereafter, the mobile communication terminal determines whether the neighboring cell is a cell suitable for the mobile communication terminal from the received cell information, and if it is determined that the cell is suitable, performs a reselection to the cell. If the mobile terminal determines that the cell is an unsuitable cell, the mobile station performs the same process again with respect to a cell having a good reception strength, and as a result, camps into the cell.

Specifically, when a mobile communication terminal providing a conventional GSM / GPRS function in a call service state, that is, a dedicated state does not receive a corresponding service in a current cell, cell reselection by a network is required. In order to find the most suitable cell for this purpose, the mobile communication terminal periodically measures the power value and quality value of the neighboring cell and reports it to the network. The network selects the most suitable cell based on the reported value and informs the mobile terminal to move to the cell, which is called a handover. Meanwhile, the mobile communication terminal receiving a handover command from the network moves to the indicated designated cell and sends a handover complete from the moved cell to the network. This handover process is performed manually by the network, unlike the cell reselection process.

As described above, when a measurement is performed on a neighboring cell periodically and an event such as a measurement value of a neighboring cell becomes higher than a currently serving cell or exceeds a predetermined threshold, it is difficult to provide a service in the cell anymore. When occurring, the mobile terminal performs handover to a cell having a better measurement value, for example, a power value and a quality value, than the current cell. However, if the power value and the quality value of the neighboring cells of the current mobile communication terminal are similar, there is a problem that frequent handover may occur to find out which cell is the optimal cell.

Accordingly, the present invention provides a method and system for enabling the network to enable efficient cell management for mobile communication terminals in a call service so that unnecessary handovers do not occur frequently.

The present invention also provides a method and system for predicting a mobile location of a mobile communication terminal in a call service to enable efficient cell search and handover on the predicted location.

According to an aspect of the present invention, there is provided an efficient handover method in a mobile communication terminal using GPS, wherein the GPS location information is periodically measured according to a moving path of the mobile communication terminal to obtain location information data from the GPS location information. Acquiring a result of measuring a signal characteristic of a neighboring cell with respect to a current cell during the movement to a network; and receiving a GPS location information request message from the network in response to the transmission. Generating and transmitting a response message including a message; and receiving a cell selection result determined based on the location information data from the network, and performing a handover operation.

In addition, according to the present invention, a system for performing an efficient handover using GPS, obtains and stores the location information data from the GPS location information measured according to the movement path, the signal characteristics of the neighboring cell for the current cell during the movement The mobile communication terminal periodically transmitting the result of the measurement and the difference between the candidate cell measurement result value and the remaining neighbor cell measurement result value among the neighbor cells based on the measurement result compared with a predetermined threshold value, the predetermined threshold value or less And requesting GPS location information from the mobile communication terminal and obtaining location information corresponding to the request, wherein the network determines a serving cell based on the location information data.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that the same elements in the figures are represented by the same reference numerals wherever possible. In addition, in describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted.

The present invention implements a handover function through efficient neighbor cell search in a mobile communication terminal. To this end, a mobile communication terminal in call service periodically uses GPS information to determine its speed and current location, calculates and stores an estimated moving location, and responds to the network based on the location information. Efficiently search for and select potent cells.

In the embodiment of the present invention, if the power value and the quality value of the serving cell or nearby cells are similar, the cell reselection process for the mobile communication terminal to find a suitable cell having both good power and quality values is possible. Do not repeat it more than necessary. This is because the number of cell reselection is increased to maintain the call quality in the region composed of neighboring cells having similar power and quality values. Accordingly, the present invention considers the position of the user seeking the reliability of call quality and focuses on the more efficient cell management by preventing frequent handover between the mobile communication terminal and the network.

Components and operations of the mobile communication terminal in which the above functions are implemented will be described with reference to FIG. 2. 2 is an internal block diagram of a mobile communication terminal according to an embodiment of the present invention.

First, the control unit 200 generally controls the overall operation of the mobile communication terminal 100 such as call and data transmission and reception. The control unit 200 always continuously monitors signal characteristics from the base station and applies the cell reselection criteria. On the basis of this, a cell is transmitted and received through the associated base station and camped. However, due to its mobility, the control unit 200 changes the received measured values, for example, power and quality values, in the cell as the movement even in the call service state, or changes in the measured values even in adjacent cells. For this reason, cell reselection for handover is necessary.

In more detail, the control unit 200 according to an embodiment of the present invention performs a measurement on a neighbor cell when moving from the current cell and transmits the measurement result value to a network. Furthermore, according to the present invention, the position of the mobile communication terminal 100 is calculated by using the GPS information received through the GPS receiver 240 so that a more efficient cell search can be performed, and the position of the mobile communication terminal 100 is calculated. Prediction generates location information data and provides it to the network. Accordingly, the network determines a new cell based on the expected movement position at the time when handover of the mobile communication terminal 100 is required and provides it to the mobile communication terminal 100. Therefore, the controller 200 selects a new cell determined by the network as the serving cell.

The display unit 210 receives and displays display data of key input data input by a user under the control of the controller 200, or displays an operation state and a plurality of information of the mobile communication terminal 100 using icons and text. do. In addition, the display unit 210 allows the user to visually know the state in setting or driving a required function under the control of the controller 200.

In addition, the memory unit 220 connected to the controller 200 may include a read only memory (ROM) and a random access memory (RAM) for storing a plurality of programs and information necessary for controlling the operation of the mobile communication terminal 100. ), Voice memory and the like. In addition, according to an embodiment of the present invention, the memory unit 220 stores position information data including a moving speed, a current position, an expected moving position, and the like calculated using the GPS information under the control of the controller 200. Subsequently, the transceiver 230 transmits / receives an RF signal with a base station through an antenna ANT under the control of the controller 200, and transmits a GPS information request message from a network according to the present invention, and a response message thereto. Send / receive communication signals with the network, such as by sending it back to the network.

The GPS receiver 240 mounted on the mobile communication terminal 100 receives a GPS signal from a GPS satellite through an antenna so that the position of the mobile communication terminal 100 can be immediately determined. In other words, the mobile communication terminal 100 receives GPS information transmitted from a GPS satellite through the built-in GPS receiver 240.

On the other hand, the location information data including the speed and location information of the mobile communication terminal can be delivered to the network in various ways. As an example, there may be a case as shown in FIG. 3. 3 is a diagram illustrating a method of providing location information to a network according to an exemplary embodiment of the present invention.

Referring to FIG. 3, the network 300 periodically receives measurement values of cells measured by the mobile communication terminal 100, and if it is determined that it is time to replace the current cell with a new cell, the GPS is detected at step S300. A GPS location information request message is transmitted to the mobile communication terminal 100. Then, the mobile communication terminal 100 transmits the GPS location information response message generated in response to the request message to the network 300. At this time, the mobile communication terminal 100 periodically finds and updates the current location using the received GPS information, and calculates its own moving speed by calculating the previous location and the current location.

Then, since the mobile communication terminal 100 may also predict the location to be moved in the future based on the current position and the moving speed obtained through the above-described process, the mobile communication terminal 100 can calculate the expected moving position. Accordingly, the mobile communication terminal 100 generates location information data including the current location, the moving speed, and the expected moving location, and periodically updates and stores the location information data. In this state, if there is a request for GPS location information from the network 300, the mobile communication terminal 100 generates a GPS location information response message by using previously stored location information data.

Subsequently, when the network 300 receives the GPS location information response message from the mobile communication terminal 100, the network 300 uses this to determine a new cell. In this case, it is assumed that the network 300 knows the GPS location information of the base station in the cell under its control.

Meanwhile, in the above description, the mobile communication terminal 100 determines its own moving speed and current location by using GPS information, and then calculates an expected moving location directly using the GPS information and provides it to the network 300 as an example. However, differently, when only the moving speed and the location information of the mobile communication terminal 100 are provided, the network 300 may directly calculate the expected moving position by learning the position change. In other words, when the network 300 needs to select a new cell, the network 300 learns a change in position based on the speed and the past position of the mobile communication terminal 100 and then again from the mobile communication terminal 100. The location information can be provided and used to determine a new cell.

In addition, in FIG. 3, the mobile communication terminal 100 provides location information data only when there is a request for GPS location information from the network 300. Alternatively, the mobile communication terminal 100 periodically transmits the location information data to the network ( Of course, it can be delivered to (300).

Next, reference is made to FIG. 4 to describe in detail a specific example to which the present invention is applied. 4 is a diagram illustrating a cell selection process according to movement of a mobile communication terminal according to an embodiment of the present invention.

Referring to FIG. 4, as the mobile communication terminal 100 which is in a call service moves from the position a of the mobile communication system to the position c past the position b, the mobile communication terminal 100 gradually moves away from the area covered by the base station A. Continually monitors signal characteristics from each base station of cells 400-420 and selects that cell through the associated base station based on any selection criteria. At this time, according to an embodiment of the present invention, the mobile communication terminal 100 uses the GPS information periodically received by the GPS receiver 240 as the position c moves from the position a past the position b to the position c. After the location is identified, the next location is calculated based on the estimated location. For example, the mobile communication terminal 100 in call service may be located far from the cell of base station A and adjacent to the cell 400 of base station B, the cell 410 of base station C, and the cell 420 of base station D. The signal characteristics from each cell 400-420, for example, the power value and the quality value, are continuously monitored. Then, the mobile communication terminal 100 transmits the signal characteristic result obtained through such monitoring to the network 300 through a measurement report message.

Meanwhile, the network 300 searches for the optimal cell from the signal characteristics of the cells 400 ˜ 420 using the measurement report message transmitted from the mobile communication terminal 100, and selects a cell which is considered as the optimal cell as the serving cell. However, if it is determined that the next serving cell is difficult because the power and quality values measured from the cells 400 to 420 are almost similar, the network 300 transmits a GPS location information request message to the mobile communication terminal 100. do.

Upon receiving this, the mobile communication terminal 100 generates a GPS location information response message including location information data using its own moving speed, location, and estimated moving location, and transmits the GPS location information response message to the network 300.

In addition, as another embodiment of the present invention, the network may periodically transmit and receive GPS location information related messages with the mobile communication terminal 100 to obtain the speed and location information of the mobile communication terminal 100. Based on this, the network 300 calculates an expected movement position of the mobile communication terminal 100 and uses it in a new cell selection process.

Specifically, when the network 300 knows the estimated moving position to which the mobile communication terminal 100 to move through the GPS location information response message in the state of knowing the location information of the base stations under its control in advance, the handover is performed. Even though the location may occur frequently, one cell may be determined based on the location information and the estimated moving location of the base station, thereby selecting the next serving cell.

For example, when the mobile communication terminal 100 moves from the a position to the c position and moves to the c position, if the GPS information is used, the mobile communication terminal 100 moves to a certain position while grasping the moving speed and position. You will know. Therefore, based on this, the network 300 may know the expected moving position of the mobile communication terminal 100. Through this process, when the mobile communication terminal 100 is in a position where handover occurs frequently because the power value and the quality value of each base station B, base station C, and base station D are similar to each other, the network 300 detects such a situation. In order not to occur frequently, the mobile communication terminal 100 may determine that the base station C is getting closer to the base station C by comparing the location of each base station with the expected moving position. Then, the network 300 determines that the most probable cell is the cell 410 controlled by the base station C using this determination result and selects it as the serving cell. Accordingly, the mobile communication terminal 100 performs a handover process to the serving cell selected by the network 300. As such, the network 300 selects the most influential cell using the expected movement position of the mobile communication terminal 100, thereby preventing unnecessary handover process between the mobile communication terminal 100 and the network 300.

Hereinafter, a process of performing handover between a mobile communication terminal and a network using GPS information according to an embodiment of the present invention will be described. Reference will be made to FIG. 5 to describe this specific example in detail. 5 is a diagram illustrating a handover operation process between a mobile communication terminal and a network according to an exemplary embodiment of the present invention.

Referring to FIG. 5, the mobile communication terminal 100 determines whether the GPS information is periodically received in step 600, and when the GPS information is received, the mobile communication terminal 100 proceeds to step 605 to determine the moving speed and the current location and then uses the estimated movement. Calculate the location. In FIG. 5, a case in which the mobile communication terminal 100 directly calculates an estimated moving position is described. However, the network 300 calculates an expected moving position by itself by receiving only the moving speed and current location information from the mobile communication terminal 100. Of course, it is possible to calculate the expected moving position through a variety of methods, such as.

The mobile communication terminal 100 proceeds to step 610 to measure signal characteristics for the current serving cell and neighboring cells. Through this, the mobile communication terminal 100 selects a candidate cell that can be a new serving cell for handover. At this time, the power value and the quality value of the neighboring cell periodically measured at the position of the mobile communication terminal 100 are used. In step 615, the mobile communication terminal 100 transmits the measurement result values for the candidate cell and the neighbor cell to the network 300.

Accordingly, the network 300 proceeds to step 620 and determines whether the difference between the measurement result values is within the threshold range. In detail, the network 300 determines whether the difference obtained by subtracting the neighbor cell measurement result from the candidate cell measurement result is greater than or equal to a predetermined threshold. That is, it is determined whether the newly selected candidate cell has a superior measurement value than other cells. If the difference is greater than or equal to the threshold, the optimum cell determination is possible. In step 625, the mobile communication terminal 100 performs a process according to the corresponding handover, such as selecting a current candidate cell as a new serving cell. . In contrast, the GPS function is used when the difference is less than a threshold value, that is, when a measurement of the cells is similar and it is difficult to determine one cell.

Accordingly, the network 300 transmits a GPS location information request message to the mobile communication terminal 100 in step 630. In response to this, the mobile communication terminal 100 generates a GPS location information response message including location information data obtained through a periodic GPS measurement operation in step 635 and transmits it to the network 300 in step 640. Then, the network 300 determines a new cell corresponding to the base station on the expected mobile location of the mobile communication terminal 100 by using the GPS location information and the GPS location information response message of each base station already known in step 645. Select that cell as the serving cell. Then, the network 300 transmits a new cell selection result through a handover command in step 650, and correspondingly, the mobile communication terminal 100 hands over to a cell selected by the network 300 in step 655. Follow the process according to.

According to the present invention on the basis of the above-described, the network 300 obtains the data that the mobile communication terminal 100 already has, or at this point in time through the GPS location information interrogation process periodically or in real time You can also get the data directly. Therefore, the timing of acquiring data on the movement speed and the current position of the mobile communication terminal 100 may be any time.

As described above, according to the present invention, the network can avoid the frequent handover process with the mobile communication terminal using GPS information, thereby performing efficient cell management.

Claims (18)

In an efficient handover method in a mobile communication terminal using GPS, Periodically measuring GPS location information according to a moving path of the mobile communication terminal to obtain location information data from the GPS location information; Transmitting a result of measuring signal characteristics of a neighboring cell with respect to a current cell to the network during the movement; Generating and transmitting a response message including the location information data when a GPS location information request message is received from the network in response to the transmission; Receiving a cell selection result determined based on the location information data from the network, and performing a handover operation. The method of claim 1, wherein the obtaining of the location information data comprises: Calculating, by the mobile communication terminal, a moving speed and a current location using the GPS location information; Calculating an expected moving position using the moving speed and the current position; And generating and storing location information data including the calculated moving speed, the current location, and the expected moving location. The method of claim 1, And by the mobile communication terminal, periodically updating and storing the location information data by using the received GPS location information. The method of claim 1, wherein the location information data is And information about a moving speed and a current location of the mobile communication terminal. The method of claim 1, wherein the location information data is And information about a movement speed, a current position, and an expected movement position of the mobile communication terminal. The method of claim 1, wherein the transmitting of a result of measuring signal characteristics of a neighboring cell to the current cell to a network is performed. And periodically transmitting a result of measuring a power value and a quality value of the cells to the network. The method of claim 1, wherein the generating and transmitting of the response message including the location information data comprises: Receiving the GPS location information request message from the network only when the difference between the candidate cell measurement result value and the remaining neighbor cell measurement result value of the neighboring cells is less than or equal to a predetermined threshold when the measurement result is transmitted; And generating and transmitting a GPS location information response message including location information data previously acquired in response to the reception. The method of claim 7, wherein When the GPS location information response message is received, a process of determining a new cell by the network based on an estimated movement location of the mobile communication terminal calculated by learning a change in location based on the location information data included in the message. Method further comprising a. The method of claim 8, wherein the new cell is determined And determining the cell of the base station corresponding to the estimated moving position by comparing the GPS position information of the plurality of base stations under the network with the estimated moving position. The method of claim 1, wherein the mobile communication terminal And periodically measuring GPS location information according to a moving path thereof, obtaining location information data from the GPS location information, and periodically transmitting the location information data to the network. The system for performing an efficient handover using GPS, A mobile communication terminal acquiring and storing location information data from GPS location information measured according to a moving path, and periodically transmitting a result of measuring signal characteristics of a neighboring cell with respect to a current cell during the movement; Based on the measured result, the difference between the candidate cell measurement result value among the neighbor cells and the remaining neighbor cell measurement result value is compared with a predetermined threshold value, and when the predetermined threshold value is less than or equal to, requesting GPS location information from the mobile communication terminal, and requesting the request. And a network for determining a serving cell based on the position information data when obtaining position information corresponding to the position information. The method of claim 11, wherein the mobile communication terminal And calculating a moving speed and a current position by using the GPS position information, and calculating an estimated moving position from the calculated moving speed and the current position. The method of claim 12, wherein the mobile communication terminal And generating location information data from the movement speed and the current location, and periodically updating and storing the location information data. The method of claim 12, wherein the mobile communication terminal Generating location information data from the movement speed, the current position and the expected movement position, and periodically updating and storing the position information data. 15. The method of claim 13, wherein the mobile communication terminal is And when the GPS location information request is received from the network, providing the previously stored location information data. The method of claim 11, wherein the measured result is And a result of measuring a power value and a quality value, which are signal characteristics of a neighboring cell, with respect to the current cell. 12. The system of claim 11, wherein said network is And performing a handover operation by determining a serving cell using location information on the GPS and location information data of a plurality of base stations under its control. 15. The method of claim 13, wherein the network is And determining the cell of the base station corresponding to the estimated moving position as a serving cell by comparing the GPS position information of the plurality of base stations under its control with the estimated moving position.

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