JP2010074390A - Wireless terminal and handover control method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a wireless terminal that suppresses the ping-pong effects and the data loss, and to provide a handover control method. <P>SOLUTION: The wireless terminal, which constitutes a part of a wireless system of a cell method, includes: a measuring part for measuring reception quality of each cell in the wireless system when reception quality of a communication cell is excellent; a cell list update part that updates a cell list by rearranging the cell list on the basis of a change amount of the present measurement result from the last-time measurement result if the measuring part measures the reception quality of all cells in the wireless system; a search part that measures the reception quality according to the cell list when the reception quality of the communication cell is not excellent and searches for a cell in which the reception quality becomes an appropriate level; and a switching part for switching the communication cell to the cell searched by the search part. <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 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 to receive data between data on the same channel, the power of the receiving unit of the wireless terminal is turned off to suppress the power consumption of the wireless terminal. In addition, when a wireless terminal moves between cells, radio waves from the current base station become weak and communication failure occurs as it is, so that 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 radio terminal, the reception quality is measured for each cell other than the current cell during the period between data on the same channel, and the handover is performed to switch to the cell with the best reception quality. Sometimes it switched. This is called a ping-pong effect, and the ping-pong effect causes a reception interruption or the like, and is desirably suppressed as much as possible. In addition, reception quality of all cells cannot be measured within a period between data on the same channel, and there is a problem that radio waves are received without switching cells and data is lost.

  In view of the above problems, an object of the present invention is to provide a radio terminal and a handover control method that can suppress a ping-pong effect and data loss.

In order to achieve the above object, a wireless terminal of the present invention is a wireless terminal that forms part of a cellular wireless system.
When the reception quality of the communication cell is good, a measurement unit that measures the reception quality of each cell in the wireless system;
When the measurement unit measures the reception quality of all cells in the wireless system, a cell list update unit that rearranges the cell list based on the amount of change from the previous measurement result of the current measurement result, and updates the cell list;
When the reception quality of the communication cell is not good, a search unit for measuring the reception quality according to the cell list and searching for a cell with the reception quality at an appropriate level;
And a switching unit that switches the communication cell to the cell searched by the search unit.

  According to such a configuration, the cell list is rearranged based on the amount of change in reception quality, that is, the cell list is rearranged and updated in the order of the cells of the radio signal transmitting unit considered that the radio terminal is closer, When the reception quality of the communication cell deteriorates, the communication cell is switched to the cell of the wireless signal transmitter that is considered to be closest to the wireless terminal, so that the reception quality is good for the time being, and the communication cell is more than necessary. Can be suppressed and the ping-pong effect can be suppressed. Even if the reception quality is not good, the communication cell is switched immediately, so that data loss can be suppressed.

Further, in the above configuration, the wireless terminal of the present invention starts the measurement after the measurement start time after the measurement unit,
When the measurement unit measures the reception quality of all the cells in the wireless system, the measurement interval time is determined based on the amount of change from the previous measurement result of the current measurement result, and the current measurement is performed for the determined measurement interval time. A measurement start time determination unit is provided in which the time elapsed from the start time is a new measurement start time.

  According to such a configuration, according to the moving speed of the wireless terminal, the measurement interval is shortened to update the cell list earlier, and even when the reception quality deteriorates, the communication cell is immediately switched, and the data Power loss can be suppressed, or the measurement interval can be lengthened to prioritize power reduction.

Further, in the above configuration, the wireless terminal of the present invention starts the measurement after the measurement start time after the measurement unit,
When the measurement unit measures the reception quality of all the cells in the wireless system, the distance of the wireless terminal from the wireless signal transmission position is estimated based on the measurement result, and the current measurement is performed for the measurement interval time corresponding to the estimated distance. A measurement start time determination unit is provided in which the time elapsed from the start time is a new measurement start time.

  According to such a configuration, according to the position of the wireless terminal, the measurement interval is shortened and the cell list is updated early, and even when the reception quality deteriorates, the communication cell is immediately switched, and the data Loss can be suppressed, or power saving can be prioritized by increasing the measurement interval.

  Further, in the above configuration, the wireless terminal of the present invention includes a demodulator that demodulates a signal based on a radio signal, and when the demodulator cannot demodulate when measuring the measurement unit, the measurement unit The cell was not demodulated, and the next measurement was not performed.

  Further, the radio terminal of the present invention includes a demodulator that demodulates a signal based on a radio signal in the above configuration, and when the demodulator cannot demodulate at the time of measurement by the measurement unit, the cell list update unit Is configured to update the cell list by placing the cells that could not be demodulated at the end of the cell list.

In order to achieve the above object, a handover control method of the present invention is a handover control method for a radio terminal that forms part of a cellular radio system.
When the reception quality of the communication cell is good, a measurement step of measuring the reception quality of each cell in the wireless system;
When the reception quality of all the cells in the wireless system is measured by the measurement step, the cell list update step of rearranging the cell list based on the amount of change from the previous measurement result of the current measurement result to update the cell list When,
When the reception quality of the communication cell is not good, a search step of measuring the reception quality according to the cell list and searching for a cell with the reception quality at an appropriate level;
And a switching step of switching the communication cell to the cell searched by the searching step.

  According to such a configuration, the cell list is rearranged based on the amount of change in reception quality, that is, the cell list is rearranged and updated in the order of the cells of the radio signal transmitting unit considered that the radio terminal is closer, When the reception quality of the communication cell deteriorates, the communication cell is switched to the cell of the wireless signal transmitter that is considered to be closest to the wireless terminal, so that the reception quality is good for the time being, and the communication cell is more than necessary. Can be suppressed and the ping-pong effect can be suppressed. Even if the reception quality is not good, the communication cell is switched immediately, so that data loss can be suppressed.

In the handover control method of the present invention, in the above configuration, the measurement step is started after the measurement start time,
When the reception quality of all the cells in the wireless system is measured by the measurement step, the measurement interval time is determined based on the amount of change from the previous measurement result of the current measurement result, and the current measurement time is determined by the determined measurement interval time. The measurement start time determination step is used in which the time elapsed from the measurement start time is a new measurement start time.

  According to such a configuration, according to the moving speed of the wireless terminal, the measurement interval is shortened to update the cell list earlier, and even when the reception quality deteriorates, the communication cell is immediately switched, and the data Power loss can be suppressed, or the measurement interval can be lengthened to prioritize power reduction.

In the handover control method of the present invention, in the above configuration, the measurement step is started after the measurement start time,
When the reception quality of all cells in the wireless system is measured by the measurement step, the distance of the wireless terminal from the wireless signal transmission position is estimated based on the measurement result, and the current state is measured for the measurement interval time corresponding to the estimated distance. The measurement start time determination step is used in which the time elapsed from the measurement start time is a new measurement start time.

  According to such a configuration, according to the position of the wireless terminal, the measurement interval is shortened and the cell list is updated early, and even when the reception quality deteriorates, the communication cell is immediately switched, and the data Loss can be suppressed, or power saving can be prioritized by increasing the measurement interval.

  In the handover control method of the present invention, in the above configuration, the wireless terminal includes a demodulation unit that demodulates a signal based on a wireless signal, and the demodulation unit cannot demodulate at the time of measurement in the measurement step In the next measurement step, the cell that could not be demodulated is not measured.

  In the handover control method of the present invention, in the above configuration, the wireless terminal includes a demodulation unit that demodulates a signal based on a wireless signal, and the demodulation unit cannot demodulate at the time of measurement in the measurement step In the cell list update step, the cell list is updated by arranging the cell that could not be demodulated at the end of the cell list.

  According to the wireless terminal and the handover control method of the present invention, it is possible to suppress the ping-pong effect and data loss.

  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 obtained by arranging data of a plurality of channels in time series is repeatedly transmitted. Data 301, 302, and 303 that are data of the same channel are transmitted at regular intervals (in fact, 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 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.

  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 configuration shown in FIG. , 502a2, 503a1, 503a2, 503a3) and includes the cell ID and frequency of each cell.

  The handover control unit 203 creates a cell list from the acquired cell information. In addition, the handover control unit 203 creates a reception quality history table representing the reception quality history for each cell from the acquired cell information. The reception quality history in the reception quality history table includes the current reception quality and the previous reception quality. For example, when the cell information is as shown in FIG. 5, a cell list as shown in FIG. 6A is created, and a reception quality history table as shown in FIG. 6B is created.

  In addition, the handover control unit 203 acquires a cell ID from TPS (Transmission Parameter Signaling) in the transport stream, and sets the cell represented by this cell ID as the current cell.

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

  In step S103, the handover control unit 203 determines whether or not the calculated reception quality is equal to or higher than the set value. If the calculated reception quality is equal to or higher than the set value, the reception quality is good (Y in step S103). The adjacent cell reception quality measurement process of S109 is performed. Then, the handover control unit 203 causes the power control unit 204 to turn off the power supply to the reception unit 202, and does not change the current cell (step S110). Then, after the off period (FIG. 3) has elapsed, 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 at the reception frequency of the current cell, and calculates the reception quality. (Step S102).

  If the calculated reception quality is lower than the set value in step S103, it is determined that the reception quality is not good (N in step S103), and 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. The reception quality of the target cell is measured.

  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. Hysteresis is used to suppress frequent cell switching due to fluctuations in radio field intensity. If the received quality is lower than the value obtained by adding hysteresis to the received quality of the current cell (N in Step S106), the process proceeds to Step S107, and 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.

  If 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, the reception quality is assumed to be an appropriate level (Y in step S106), and the process proceeds to step S108. The handover control unit 203 changes the current cell to the target cell and executes handover. Then, the handover control unit 203 turns off the power supply to the reception unit 202 by the power control unit 204, and the handover control unit 203 turns on the power supply to the reception unit 202 after the off period has elapsed. Then, the data of the designated channel is received at the reception frequency of the current cell, and the reception quality is calculated (step S102). In addition, after execution of the handover in step S108, in the first step S105, the reception quality of the first cell in the cell list (or the next cell if the cell is the current cell) is measured.

  When 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), the handover control unit 203 supplies the power control unit 204 with power supply to the reception unit 202. Is turned off, the current cell is not changed (step S110), and after the off period has elapsed, the power control unit 204 turns on the power supply to the receiving unit 202, and receives data of the specified channel at the reception frequency of the current cell. The reception quality is calculated (step S102). After this, if N is determined in step S103, in the first subsequent step S105, the reception quality of the target cell after the change is measured in step S107. On the other hand, if Y is determined in step S103, the first subsequent time is measured. In step S105, the reception quality of the first cell in the cell list (or the next cell if the cell is the current cell) is measured.

  Here, the neighbor cell reception quality measurement processing in step S109 will be described with reference to FIG.

  When the neighbor cell reception quality measurement process starts, first, in step S201, the handover control unit 203 is the first measurement, or the current time is after the measurement start time determined later, or the measurement It is determined whether the middle flag is set. If none of these are applicable (N in step S201), the process ends (return).

  On the other hand, if either of them is satisfied (Y in step S201), the process proceeds to step S202, and the handover control unit 203 sets a measurement flag.

  In step S203, 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 S203), and proceeds to step S204. Here, the handover control unit 203 uses the first cell in the cell list as a target cell, receives data at the reception frequency of the target cell, calculates reception quality, and measures the reception quality of the target cell. Then, the handover control unit 203 stores the measurement result as the current reception quality corresponding to the target cell in the reception quality history table. If the current reception quality is already stored, the current reception quality that has already been stored is stored as the previous reception quality, and the measurement result is stored in the current reception quality. Note that the target cell in the first step S204 after measuring the reception quality of all the cells in the cell list is the first cell in the cell list.

  Next, in step S205, the handover control unit 203 determines whether there is a cell next to the target cell in the cell list. If there is (Y in step S205), the handover control unit 203 sets the cell as a new target cell. Is changed (step S206), and the process returns to step S203.

  If the time for measuring the reception quality does not fall within the remaining off period in step S203 (N in step S203), the process ends (return).

  In step S205, if there is no next cell in the cell list (N in step S205), the process proceeds to step S207, and the handover control unit 203 resets the measuring flag. Then, after the reception quality history process of step S208 is performed, the process ends (return).

  Here, the reception quality history processing in step S208 will be described with reference to FIG.

  When the reception quality history process starts, first, in step S301, the handover control unit 203 determines whether it is the first measurement of the reception quality of all the cells in the cell list. If it is the first measurement (Y in step S301), the process proceeds to step S304, and the handover control unit 203 determines the measurement start time. Here, for example, a time after a predetermined elapsed time from the current time may be determined as the measurement start time. Then, the process ends (return).

  If it is not the first measurement in step S301 (N in step S301), the process proceeds to step S302. Here, the handover control unit 203 obtains a reception quality change amount obtained by subtracting the previous reception quality from the current reception quality for every cell of the reception quality history table, and each absolute value of each obtained reception quality change amount. Find the average value of. This average value can be considered to represent the moving speed of the wireless terminal. If the calculated average value is equal to or greater than a predetermined threshold, the moving speed is fast and the handover control unit 203 sets the current measurement start time. A time obtained by adding a predetermined first measurement interval time is set as a new measurement start time. If the obtained average value is smaller than a predetermined threshold value, the handover control unit 203 determines that the moving speed is slow and sets a predetermined second measurement interval time longer than the first measurement interval time at the current measurement start time. The added time is set as a new measurement start time. The maximum value may be used instead of the average value.

  In step S302, the measurement start time may be determined by the following method. First, the handover control unit 203 obtains the average value. Then, if the obtained average value is larger than the previous average value, the time obtained by adding the new measurement interval time to the current measurement start time is set as a new measurement interval time that is shorter than the current measurement interval time. A new measurement start time is assumed. If the calculated average value is smaller than the previous average value, the time obtained by adding the new measurement interval time to the current measurement start time is set as a new measurement interval time, which is longer than the current measurement interval time. A new measurement start time is assumed. If the obtained average value is the same as the previous average value, a time obtained by adding the current measurement interval time to the current measurement start time is set as a new measurement start time. In the first step S302, the average value is obtained, a predetermined initial value is set as the measurement interval time, and the initial value is added to the current measurement start time to obtain a new measurement start time. Also in this method, the maximum value may be used instead of the average value.

  Further, in step S302, the measurement start time may be determined by the following method. There is a radio wave transmission tower at the center of the cell, the reception quality on the same circle centering on the center of the cell is the same, and the reception quality decreases as the distance from the center of the cell increases. Therefore, the handover control unit 203 has a correspondence table between the reception quality and the distance from the cell center in advance, and in step S302, the handover control unit 203 determines the current reception quality of the current cell in the reception quality history table. And the distance from the cell center is obtained from the correspondence table. If the position of the obtained distance is near the center of the cell, the handover control unit 203 sets a time obtained by adding a predetermined first measurement interval time to the current measurement start time as a new measurement start time. Further, if the position of the obtained distance is near the edge of the cell, the handover control unit 203 adds a time obtained by adding a predetermined second measurement interval time shorter than the first measurement interval time to the current measurement start time. A new measurement start time is assumed. Further, if the position of the obtained distance is not near the center of the cell or the edge of the cell, the handover control unit 203 sets the interval between the first measurement interval time and the second measurement interval time at the current measurement start time. The time obtained by adding the predetermined third measurement interval time is defined as a new measurement start time.

  After step S302, the process proceeds to step S303, and the handover control unit 203 updates the cell list. Here, in the reception quality history table, the cell list is updated by rearranging the cells in descending order of the reception quality change amount obtained by subtracting the previous reception quality from the current reception quality. That is, the cell list is rearranged in the order of the cells of the transmission tower considered to be approaching. After updating the cell list in step S303, the process ends (return).

  If the handover control unit 203 cannot digitally demodulate the reception quality at step S204, the reception quality measurement at the next step S204 of the same cell may not be performed to reduce power. If the handover control unit 203 cannot digitally demodulate the reception quality at step S204, the cell list update at step S303 places the cells that could not be digitally demodulated at the end of the list, and the remaining cells. May be arranged in descending order on the plus side of the received quality change amount.

  Next, the effect of the present invention will be described with reference to FIG.

  Consider a case where a wireless terminal moves along a movement route 901 as shown in the upper part of FIG. When the above-described conventional wireless terminal reaches the point X, the reception quality deteriorates at the reception frequency of the current cell A, and the reception quality is measured for all cells other than the current cell A during the off period. Since the reception quality is distributed as shown in the lower part of FIG. 10, the reception quality of cell B is the highest, and the current cell is switched to cell B. When the wireless terminal reaches the point Y, the reception quality deteriorates at the reception frequency of the current cell B, and the reception quality is measured for all cells other than the current cell B during the off period. Since the reception quality is distributed as shown in the lower part of FIG. 10, the reception quality of cell C is the highest, and the current cell is switched to cell C.

  On the other hand, in the wireless terminal of the present invention, before reaching the point X, the cell list is updated so that the largest cell C on the plus side becomes the top by comparing the reception quality change amount of each cell, , The reception quality deteriorates at the reception frequency of the current cell A, and it is confirmed that the reception quality of the cell C at the head of the cell list is at an appropriate level, and the current cell is switched to the cell C. Thereafter, even if the point Y is reached, the current cell C is not switched. As described above, with the wireless terminal of the present invention, it is possible to suppress the excessive cell switching, that is, the occurrence of the ping-pong effect as in the conventional wireless terminal.

  In addition, in the conventional wireless terminal, even when reaching the X point and the Y point, the reception quality of all the cells cannot be measured in one off period, and after the off period elapses without switching the current cell. However, if the wireless terminal of the present invention arrives at the point X, the cell C is at the head of the cell list. The reception quality of the cell C can be measured within the off period to confirm that the reception quality is at an appropriate level, and the current cell can be switched to the cell C, so that radio waves can be received well after the off period has elapsed and data is lost. I can prevent that.

  Further, in the wireless terminal of the present invention, if it is estimated that the moving speed is fast, the measurement interval is shortened, the cell list is updated earlier, cell switching can be performed within one off period, The loss is suppressed. Further, if it is estimated that the moving speed is slow, it is possible to lengthen the measurement interval and give priority to power reduction.

  In the case of the embodiment in which the distance from the cell center is estimated as described above, if the wireless terminal is estimated to be located near the edge of the cell, the measurement interval is shortened and the cell list is updated earlier, Cell switching can be performed within one off period, and data loss is suppressed. Further, if it is estimated that the wireless terminal is located near the center of the cell, it is possible to lengthen the measurement interval and give priority to power reduction.

  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. FIG. 10 is a diagram illustrating an example of creating a cell list. These are figures which show the example of preparation of a reception quality log | history table. These are the flowcharts of the reception process which concerns on this invention. These are the flowcharts of the adjacent cell reception quality measurement processing according to the present invention. These are the flowcharts of reception quality history processing according to the present invention. These are the figures which show the example of cell arrangement | positioning for demonstrating the effect of this invention, the example of a movement path | route, and the example of reception quality distribution.

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 (10)

In a wireless terminal that forms part of a cellular wireless system,
When the reception quality of the communication cell is good, a measurement unit that measures the reception quality of each cell in the wireless system;
When the measurement unit measures the reception quality of all cells in the wireless system, a cell list update unit that rearranges the cell list based on the amount of change from the previous measurement result of the current measurement result, and updates the cell list;
When the reception quality of the communication cell is not good, a search unit for measuring the reception quality according to the cell list and searching for a cell with the reception quality at an appropriate level;
A wireless terminal comprising: a switching unit that switches a communication cell to a cell searched by the search unit. The measurement unit starts measurement when it is after the measurement start time,
When the measurement unit measures the reception quality of all the cells in the wireless system, the measurement interval time is determined based on the amount of change from the previous measurement result of the current measurement result, and the current measurement is performed for the determined measurement interval time. The wireless terminal according to claim 1, further comprising a measurement start time determination unit that sets a time elapsed from the start time as a new measurement start time. The measurement unit starts measurement when it is after the measurement start time,
When the measurement unit measures the reception quality of all the cells in the wireless system, the distance of the wireless terminal from the wireless signal transmission position is estimated based on the measurement result, and the current measurement is performed for the measurement interval time corresponding to the estimated distance. The wireless terminal according to claim 1, further comprising a measurement start time determination unit that sets a time elapsed from the start time as a new measurement start time.   A demodulator that demodulates a signal based on a radio signal, and when the demodulator cannot demodulate at the time of measurement by the measurement unit, the measurement unit does not perform the next measurement on a cell that could not be demodulated The wireless terminal according to claim 1, wherein the wireless terminal is a wireless terminal.   A demodulator that demodulates a signal based on a radio signal, and when the demodulator cannot demodulate at the time of measurement by the measurement unit, the cell list update unit sets the cell that could not be demodulated to the end of the cell list The wireless terminal according to claim 1, wherein the wireless terminal is arranged to update a cell list. In a handover control method for a radio terminal constituting a part of a cellular radio system,
When the reception quality of the communication cell is good, a measurement step of measuring the reception quality of each cell in the wireless system;
When the reception quality of all the cells in the wireless system is measured by the measurement step, the cell list update step of rearranging the cell list based on the amount of change from the previous measurement result of the current measurement result to update the cell list When,
When the reception quality of the communication cell is not good, a search step of measuring the reception quality according to the cell list and searching for a cell with the reception quality at an appropriate level;
And a switching step of switching the communication cell to the cell searched by the searching step. The measurement step is started after the measurement start time,
When the reception quality of all the cells in the wireless system is measured by the measurement step, the measurement interval time is determined based on the amount of change from the previous measurement result of the current measurement result, and the current measurement time is determined by the determined measurement interval time. The handover control method according to claim 6, further comprising a measurement start time determination step in which a time elapsed from the measurement start time is a new measurement start time. The measurement step is started after the measurement start time,
When the reception quality of all cells in the wireless system is measured by the measurement step, the distance of the wireless terminal from the wireless signal transmission position is estimated based on the measurement result, and the current state is measured for the measurement interval time corresponding to the estimated distance. The handover control method according to claim 6, further comprising a measurement start time determination step in which a time elapsed from the measurement start time is a new measurement start time. The wireless terminal includes a demodulation unit that demodulates a signal based on a wireless signal,
9. The measurement of a cell that could not be demodulated in the next measurement step when the demodulator could not demodulate at the time of measurement in the measurement step. The handover control method according to any one of the above. The wireless terminal includes a demodulation unit that demodulates a signal based on a wireless signal,
When the demodulator cannot demodulate at the time of measurement in the measurement step, the cell list update step arranges the cell that could not be demodulated at the end of the cell list and updates the cell list. The handover control method according to any one of claims 6 to 9.

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