JP2009253357A - Wireless terminal and handover control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a wireless terminal and the handover control method capable of reducing power consumption. <P>SOLUTION: A handover control portion 203 measures the received quality, and searches for a cell having the received quality of a proper level according to a cell list showing a total dwell time for each cell. After the search, the total dwell time of a changed cell is updated, and the cell list is updated. Then, the current cell is switched to the searched cell. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a radio terminal and a handover control method.

DVB-H (Digital Video Broadcasting-Handhelds) is defined as one of the technical standards related to broadcasting services for portable wireless terminals. In DVB-H, a cell system is adopted for installing a base station, and data of each channel is transmitted from the base station to the wireless terminal by time division multiplexing. Since there is no need for reception between data on the same channel, the power of the receiving unit of the wireless terminal is turned off to suppress power consumption of the wireless terminal. In addition, when a wireless terminal moves between cells, radio waves from the current base station weaken and communication failure occurs as it is, so a so-called handover is performed to switch base stations for communication (for example, Patent Document 1 and Non-Patent Document 1). See).
Special Table 2007-529939 Xiaodong Yang, 2 others, "A SURVEY OF HANDOVER ALGORITHMS IN DVB-H", IEEE Communications Surveys & Tutorials, 4th Quarter 2006, Volume 8, No. 4, p.16-p.29

  However, in the conventional wireless terminal, since the reception quality is confirmed in the order of the adjacent cell list during the period between the data of the same channel and the handover is performed, there is a problem that power consumption increases.

  In view of the above problems, an object of the present invention is to provide a wireless terminal and a handover control method that can reduce power consumption.

  In order to achieve the above object, a wireless terminal of the present invention measures reception quality according to a cell list representing a switching history of each cell in a wireless terminal that performs handover from a cell to another cell in a wireless system. A search unit for searching for a cell at an appropriate level, a cell list update unit for updating a cell list by updating a switching history of the switched cell when searched by the search unit, and a cell searched for by the search unit And a switching unit for switching the communication cell.

  According to such a configuration, by considering the switching history, the frequency of reception quality measurement can be reduced and the power consumption can be reduced.

  Further, in the wireless terminal having the above configuration, the cell list represents a total stay time of each cell, and the cell list update unit adds the stay time of the switched cell to the total stay time of the switched cell. Then, the cell list may be updated by rearranging the cells in descending order of the total stay time.

  Furthermore, in this configuration, the cell list updating unit may update the cell list by listing the switched cells last among the cells whose total stay time is not zero.

  In the wireless terminal having the above-described configuration, the cell list represents the number of times of switching of each cell, and the cell list update unit adds 1 to the number of times of switching of the switched cells, The cell list may be updated by rearranging.

  Further, in this configuration, the cell list update unit may update the cell list by listing the switched cells last among the cells whose switching frequency is not zero.

  The wireless terminal having the above configuration further includes a storage unit that stores a cell switching history to the cell searched by the searching unit, and the cell list update unit includes the search in the cell switching history stored by the storage unit. When there is a cell that has been switched from the cell searched by the unit, the cell list may be updated by preferentially listing the cell. According to such a configuration, it is possible to further reduce the frequency of reception quality measurement and further reduce power consumption.

  In order to achieve the above object, a handover control method of the present invention provides a cell list representing a switching history of each cell in a handover control method for a radio terminal that performs handover from a cell to another cell in a radio system. A search step for measuring reception quality according to the above and searching for a cell having a reception level at an appropriate level; and a cell list update step for updating a cell list by updating a switching history of the switched cells when searched by the search step; And a switching step of switching the communication cell to the cell searched by the searching step.

  According to such a configuration, by considering the switching history, the frequency of reception quality measurement can be reduced and the power consumption can be reduced.

  Further, in the handover control method having the above configuration, the cell list represents a total stay time of each cell, and the cell list update step includes the stay time of the switched cell in the total stay time of the switched cell. The cell list may be updated by adding and rearranging the cells in descending order of the total stay time.

  Further, in this configuration, the cell list update step may update the cell list by listing the switched cells last among the cells whose total stay time is not zero.

  In the handover control method having the above configuration, the cell list represents the number of times of switching of each cell, and the cell list update step adds 1 to the number of times of switching of the switched cells, The cell list may be updated by rearranging.

  Furthermore, in this configuration, the cell list update step may update the cell list by listing the switched cells last among the cells whose switching frequency is not zero.

  Further, in the handover control method configured as described above, the method includes a storing step of storing a cell switching history to the cell searched by the searching step, wherein the cell list updating step includes the cell switching history stored by the storing step. When there is a cell that has been switched from the cell searched in the search step, the cell list may be updated by preferentially listing the cell. According to such a configuration, it is possible to further reduce the frequency of reception quality measurement and further reduce power consumption.

  According to the radio terminal and the handover control method of the present invention, power consumption can be reduced.

  Embodiments of the present invention will be described below with reference to the drawings.

  FIG. 1 is a schematic diagram showing a radio system in DVB-H. The server 101 supplies broadcast data to the master station 103a of each cell 103 via the network 102, and the master station 103a performs wireless output. A subcell 104 is provided in the weak electric field region of the cell 103 inside the cell 103. The repeater 104a of the subcell 104 converts the frequency of the radio wave output from the master station 103a and outputs it by radio. The portable wireless terminal 105 receives and demodulates the radio wave of the cell 103 or the subcell 104 and acquires broadcast data.

  FIG. 2 is a schematic configuration diagram of a radio terminal according to the present invention. The wireless terminal according to the present invention includes an antenna 201, a receiving unit 202, a handover control unit 203, and a power control unit 204. Note that other components of the wireless terminal are not directly related to the present invention and are omitted in FIG.

  The antenna 201 receives radio waves and outputs a high frequency signal to the receiving unit 202. The receiving unit 202 extracts a channel frequency signal from the high frequency signal from the antenna 201 by channel selection control of the handover control unit 203, converts the extracted signal into a baseband signal, and converts the baseband signal into the handover control unit 203. Output to. In addition, the reception unit 202 detects a received signal strength index (RSSI) value and outputs it to the handover control unit 203. The handover control unit 203 digitally demodulates the baseband signal and acquires a transport stream. Further, the handover control unit 203 calculates reception quality from error information obtained by digital demodulation and an RSSI value obtained from the reception unit 202.

  The power control unit 204 controls power supply to the reception unit 202 according to an instruction from the handover control unit 203 in order to reduce power consumption.

  FIG. 3 is a diagram illustrating data transmission in DVB-H. In DVB-H, broadcast data is transmitted by time division multiplexing, and data in which a plurality of channels are arranged in time series is repeatedly transmitted. Data 301, 302, and 303, which are data of the same channel, are transmitted at regular intervals (actually data of other channels are arranged between data 301 and data 302 and between data 302 and data 303). In the off period 304, which is the period between the data 301 and the data 302, and the off period 305, which is the period between the data 302 and the data 303, the wireless terminal does not need to receive data, so the power of the receiving unit is turned off and power consumption is reduced. It is possible to suppress. Also, during this off period, the wireless terminal can confirm the reception quality of the cell adjacent to the current cell by tuning the frequency different from that of the current cell, and can execute the handover.

  FIG. 4 is a diagram illustrating an example of cell arrangement. Cell A, cell B, cell C, cell D, and cell E are generally arranged in a lattice shape so that the frequencies do not overlap with the adjacent cells, and the frequency of each cell is different from the frequency of the adjacent cell. The cells A and D that are not adjacent to each other may have the same frequency. The subcells a1, a2, and a3 are provided in the cell A, the subcells b1 and b2 are provided in the cell B, the subcells c1, c2, and c3 are provided in the cell C, and the subcells d1, d2 are The cell D is provided inside the cell D, and the subcells e1 and e2 are provided inside the cell E. The subcell and its parent cell (eg, subcells a1, a2, a3 and cell A) also have different frequencies.

(First embodiment of reception processing)
Next, reception processing in the wireless terminal according to the present invention will be described using the flowchart of FIG.

  When a reception processing start operation is performed in the wireless terminal, in step S101, the handover control unit 203 causes the power control unit 204 to turn on the power supply to the reception unit 202, scans the broadcast frequency band, and sets the reception quality. Get the reception frequency that is greater than or equal to the value. Then, the handover control unit 203 acquires cell information from service information (SI: Service Information) in the transport stream based on the received signal of the acquired reception frequency. The cell information is provided as a network information table (NIT: Network Information Table) in the service information. For example, the cell information is configured as shown in FIG. 5 (parent cell information 501, 502, 503 and subcell information 501a1, 501a2, 501a3, 502a1). , 502a2, 503a1, 503a2, 503a3) and includes the cell ID and frequency of each cell. The handover control unit 203 creates a cell list representing the total stay time of each cell from the acquired cell information. Here, the total stay time of each cell is assumed to be zero. In addition, the handover control unit 203 acquires a cell ID from TPS (Transmission Parameter Signaling) in the transport stream, and sets this as the current cell.

  In step S102, the handover control unit 203 receives data of the designated channel at the current reception frequency and calculates reception quality.

  In step S103, the handover control unit 203 determines whether the calculated reception quality is equal to or higher than the set value. If the received quality is equal to or higher than the set value (Y in step S103), the power control unit 204 receives the reception unit 202. The power supply to is turned off, and the reception frequency and the current cell are not changed (step S109). Then, after the lapse of the off period (FIG. 3), the handover control unit 203 causes the power control unit 204 to turn on the power supply to the reception unit 202, receives the data of the designated channel in step S102, and calculates the reception quality.

  If the calculated reception quality is lower than the set value in step S103 (N in step S103), the process proceeds to step S104. In step S104, the handover control unit 203 determines whether or not the time for measuring the reception quality falls within the remaining off period (Y in step S104), and proceeds to step S105.

  In step S105, the handover control unit 203 sets the first cell in the cell list (or the next cell if the cell is the current cell) as a target cell, receives data at the reception frequency of the target cell, and calculates reception quality. .

  In step S106, the handover control unit 203 determines whether the calculated reception quality is equal to or greater than the value obtained by adding hysteresis to the reception quality of the current cell calculated in step S102. If it is smaller than the value obtained by adding hysteresis to the reception quality of the current cell (N in step S106), it is determined that the reception quality is not an appropriate level, and the process proceeds to step S107. The handover control unit 203 sets the target cell as the next cell in the cell list. (If the cell is the current cell, change to the next cell), and return to step S104. Note that the cell list reference returns to the top when the end is reached.

  If it is determined in step S104 that the time for measuring the reception quality does not fall within the remaining off period (N in step S104), in step S109, the handover control unit 203 changes the current cell and the reception frequency. First, after the off period has elapsed, in step S102, the data of the designated channel is received to calculate the reception quality.

  When it is determined in step S106 that the calculated reception quality is equal to or higher than the value obtained by adding hysteresis to the reception quality of the current cell (Y in step S106), the handover control unit 203 sends a reception unit to the power control unit 204. The power supply to 202 is turned off, the process proceeds to step S108, and the handover process is started. By using hysteresis, frequent cell switching can be prevented and the power saving effect can be enhanced.

  FIG. 7 shows a flowchart of the handover process. First, in step S201, the handover processing unit 203 adds the stay time of the current cell to the total time of the current cell in the cell list.

  In step S202, the handover control unit 203 rearranges the cell list in descending order of the total time. However, the current cell is listed last among those whose total time is not zero.

  In step S203, the handover control unit 203 switches the current cell to the target cell and changes the reception frequency to the frequency of the target cell.

  Thereafter, when the off period elapses, the handover control unit 203 causes the power control unit 204 to turn on the power supply to the reception unit 202, and in step S102 (FIG. 6), the handover control unit 203 sets the specified channel with the changed reception frequency. Receive data and calculate reception quality. After step S108, the target cell whose reception quality is measured in step S105 is the first cell in the cell list (or the next cell if the cell is the current cell).

  In addition, when the reception process is resumed after the completion of such a reception process, the cell list is already created, and thus the cell list is not created in step S101.

  Note that a count value may be used instead of the total time in the cell list. In this case, the count value of each cell when creating the cell list in step S101 is set to zero. In step S201, 1 is added to the count value of the current cell in the cell list. In step S202, the cell list is rearranged in descending order of the count value. However, the current cell is listed last among the count values that are not zero.

  According to such reception processing, by considering the cell switching history, it is possible to reduce the frequency of reception quality measurement for handover, and to reduce power consumption.

(Second embodiment of reception processing)
Further, the handover process in step S108 of FIG. 6 may be a process as shown in FIG.

  First, in step S301, the handover processing unit 203 adds the stay time of the current cell to the total time of the current cell in the cell list.

  In step S302, the handover processing unit 203 stores a switching history from the current cell to the target cell. If the same switching history is already saved, it is not saved.

  In step S303, the handover control unit 203 prioritizes the cells that have been switched from the target cell in the saved switching history in descending order of the total time, and then places the remaining cells in descending order of the total time. Line up. However, if there is a current cell among the remaining cells, the remaining cells are listed last among those whose total time is not zero. If there is no cell that has been switched from the target cell in the saved switching history, the cells are arranged in descending order of the total time, and the current cell is listed last among those whose total time is not zero.

  In step S304, the handover control unit 203 switches the current cell to the target cell and changes the reception frequency to the frequency of the target cell.

  Thereafter, when the off period elapses, the handover control unit 203 causes the power control unit 204 to turn on the power supply to the reception unit 202, and in step S102 (FIG. 6), the handover control unit 203 sets the specified channel with the changed reception frequency. Receive data and calculate reception quality. After step S108, the target cell whose reception quality is measured in step S105 is the first cell in the cell list (or the next cell if the cell is the current cell).

  When a count value is used instead of the total time in the cell list, 1 is added to the count value of the current cell in the cell list in step S301. In step S303, the cells that have been switched from the target cell in the stored switching history are arranged in descending order of the count value, and the remaining cells are arranged in descending order of the count value. However, if there is a current cell among the remaining cells, the remaining cells are listed last among those whose count values are not zero. If there is no cell that has been switched from the target cell in the stored switching history, the cells are arranged in descending order of the count value, and the current cell is listed last among those that do not have a count value of 0.

  By storing and using the switching history in this way, it is possible to further reduce the frequency of reception quality measurement for handover and further reduce power consumption.

  Hereinafter, examples of effects of the present invention will be described.

  Here, as shown in FIG. 9, the wireless terminal repeats a movement route 901 (for example, commuting route) that follows cell A → cell B → cell C → subcell c1 → cell C → subcell c2 → cell C twice. Assume the case of moving. FIG. 10 shows the transition of the cell list when the first embodiment of the reception process (however, when the count value is used) is performed in such a case.

  At the first point 1, a cell list is created based on the cell information acquired from the server (a cell list corresponding to the first point 1 in FIG. 10), and the current cell is set to cell A.

  Then, the reception quality is measured as subcell a1 → subcell a2 → subcell a3 → cell B based on the cell list, and cell B is found fourth as a cell having an appropriate reception quality at point 2, and the cell list is updated (see FIG. 10), the current cell is switched from cell A to cell B.

  Then, based on the cell list, the reception quality is measured as cell A → subcell a1 → subcell a2 → subcell a3 → subcell b1 → subcell b2 → subcell b3 → cell C. Found eighth, the cell list is updated (cell list corresponding to the first point 3 in FIG. 10), and the current cell is switched from cell B to cell C.

  Thereafter, the same applies to the point 7, and after the current cell is switched to the cell C at the point 7, the reception process is terminated. When the reception process is resumed at point 1, a new cell list is not created (a cell list corresponding to the second point 1 in FIG. 10), and the current cell is set to cell A.

  Then, the reception quality is measured as cell C → cell B based on the cell list, and cell B is found second as a cell having a reception quality of an appropriate level at point 2, and the cell list is updated (second time point 2 in FIG. 10). , The current cell is switched from cell A to cell B.

  Then, the reception quality of the cell C is measured based on the cell list, and the cell C is first found as a cell having an appropriate reception quality at the point 3, and the cell list is updated (corresponding to the second point 3 in FIG. 10). Cell list), the current cell is switched from cell B to cell C. Thereafter, the same applies to point 7.

  As can be seen from FIG. 10, the cell B is found fourth at the first point 2 but second at the second point 2. In addition, the cell C is found at the eighth point at the first point 3, the third at the first point 5, the fourth at the first point 7, the first at the second point 3, the fourth at the second point 5, and the second. The fourth spot is found at the seventh point. Further, the subcell c1 is found ninth at the first point 4 but secondly at the second point 4. The subcell c2 is found tenth at the first point 6 but third at the second point 6. According to the first embodiment of the reception process, since the cell list is updated so that frequently switched cells are arranged on the top side of the cell list, the cell to be switched can be found early, and the reception quality measurement can be performed. It becomes possible to reduce power consumption by reducing the frequency.

  FIG. 11 shows the transition of the cell list when the second embodiment of the reception process (when the count value is used) is performed when the wireless terminal moves by repeating the movement route 901 as shown in FIG. 9 twice. Indicates.

  Here, the switching history is stored at the first point 2 to point 7, and the cell list is updated based on the switching history stored at the second point 2 to point 7. Thereby, the cell switched earlier can be found in the point 4-7 of the 2nd time compared with FIG. According to the second embodiment of the reception process, since the cell list is updated so that the cell that has been switched from the current cell is preferentially placed on the top side of the cell list, the cell to be switched can be found earlier. Therefore, it is possible to further reduce the frequency of reception quality measurement and further reduce power consumption.

  The embodiment described above is merely an example for carrying out the present invention, and can be modified in various ways without departing from the gist of the present invention. For example, the present invention may be applied to other broadcasting technology standards without being limited to DVB-H.

These are the schematic diagrams which show the radio system in DVB-H. These are the schematic block diagrams of the radio | wireless terminal which concerns on this invention. These are figures which show the data transmission in DVB-H. These are figures which show the example of arrangement | positioning of a cell. These are figures which show the structural example of cell information. These are the flowcharts regarding 1st Embodiment and 2nd Embodiment of a reception process. These are flowcharts of the handover process in the first embodiment of the reception process. These are the flowcharts of the handover process in 2nd Embodiment of a reception process. These are figures which show the assumption path | route for demonstrating the effect of this invention. These are figures which show the transition of a cell list when 1st Embodiment of a reception process is performed. These are figures which show the transition of a cell list when 2nd Embodiment of a reception process is performed.

Explanation of symbols

101 Server 102 Network 103 Cell 103a Master station 104 Subcell 104a Repeater 105 Wireless terminal 201 Antenna 202 Receiver 203 Handover controller 204 Power controller 301, 302, 303 Data 304, 305 Off period 501, 502, 503 Parent cell information 501a1, 501a2, 501a3 Subcell information 502a1, 502a2 Subcell information 503a1, 503a2, 503a3 Subcell information 901 Movement path

Claims (12)

In a wireless terminal that performs handover from a cell to another cell in a wireless system,
A search unit for measuring reception quality according to a cell list representing a switching history of each cell and searching for a cell having a proper reception quality level;
When searched by the search unit, a cell list update unit that updates a cell list by updating a switching history of the switched cells;
A wireless terminal comprising: a switching unit that switches a communication cell to a cell searched by the search unit. The cell list represents the total stay time of each cell,
The cell list update unit adds the stay time of the switched cell to the total stay time of the switched cell and rearranges the cells in descending order of the total stay time to update the cell list. The wireless terminal according to claim 1.   The radio terminal according to claim 2, wherein the cell list updating unit updates the cell list by listing the switched cells last among the cells whose total stay time is not zero. The cell list represents the number of times each cell is switched,
The wireless terminal according to claim 1, wherein the cell list update unit adds 1 to the number of times of switching of the switched cells, and rearranges the cells in descending order of the number of times of switching to update the cell list.   The radio terminal according to claim 4, wherein the cell list update unit updates the cell list by listing the switched cells last among the cells whose switching frequency is not zero. A storage unit for storing a cell switching history to a cell searched by the search unit;
When there is a cell that has been switched from the cell searched by the search unit in the cell switching history stored by the storage unit, the cell list update unit preferentially lists the cell The wireless terminal according to claim 1, wherein the wireless terminal is updated. In a handover control method for a radio terminal that performs handover from a cell to another cell in a radio system,
A search step for measuring a reception quality according to a cell list representing a switching history of each cell and searching for a cell whose reception quality is an appropriate level;
When searched by the search step, a cell list update step of updating a cell list by updating a switching history of the switched cells;
And a switching step of switching the communication cell to the cell searched by the searching step. The cell list represents the total stay time of each cell,
The cell list update step adds the stay time of the switched cell to the total stay time of the switched cell and rearranges the cells in descending order of the total stay time to update the cell list. The handover control method according to claim 7.   9. The handover control method according to claim 8, wherein the cell list update step updates the cell list by listing the switched cells last among the cells whose total stay time is not zero. The cell list represents the number of times each cell is switched,
8. The handover control method according to claim 7, wherein the cell list update step adds 1 to the number of times of switching of the switched cells and updates the cell list by rearranging the cells in descending order of the number of times of switching. .   The handover control method according to claim 10, wherein the cell list updating step updates the cell list by listing the switched cells last among the cells whose switching frequency is not zero. A storage step of storing a cell switching history to the cell searched by the searching step;
In the cell list update step, if there is a cell that has been switched from the cell searched by the search step in the cell switching history stored by the storage step, the cell list is preferentially listed. The handover control method according to claim 7, wherein the method is updated.

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