JP2003348001A - Mobile radio terminal - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To suppress power consumption of a battery provided in a mobile radio terminal by properly controlling a cell search cycle of the mobile radio terminal. <P>SOLUTION: The mobile radio terminal 100 is provided with a function for periodically detecting base stations to be candidates for a hand over destination by receiving signals to be transmitted from the base stations and further provided with decision means and cycle change means. The decision means (30, 32) decide whether or not the mobile radio terminal stays in a communication area of the same base station. When the mobile radio terminal is decided to stay in the communication area of the same base station by the decision means (30, 32), the cycle change means (30, 31, 33) prolong a detection cycle of the base stations to be the candidates for the hand over destination. <P>COPYRIGHT: (C)2004,JPO

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a mobile radio terminal mounted on a mobile radio terminal for receiving a signal transmitted from a base station and searching for a base station transmitting and receiving an information signal.
In particular, the present invention relates to a mobile radio terminal that changes a cell search depending on whether or not the mobile radio terminal is staying.

[0002]

2. Description of the Related Art For example, CDMA (Code Division Mu)
In the ltiple Access) communication method, a mobile radio terminal specifies a phase and a spreading code of a pilot channel transmitted from a base station by performing a cell search in order to receive an information signal. In addition, the cell search is used to enable a handover to another base station when the mobile radio terminal moves between service areas provided by each base station. Is also used.

On the other hand, since a mobile radio terminal operates on power supplied by a battery, a low power consumption mode is provided in order to suppress power consumption in a standby state. In this mode, incoming call confirmation is executed by periodically returning from the sleep state. Then, the above-described cell search is also periodically executed as a cell search cycle at a timing when the device returns from the sleep state.

[0004]

However, there still remains a problem to be solved in the process of executing the cell search at the timing of returning from the sleep state as described above.

[0005] When the mobile radio terminal is in the low power consumption mode, it periodically returns from the sleep state. Since this cycle is fixedly set, if the cell search cycle is too long, the mobile radio terminal cannot acquire the next base station required with the movement of the mobile radio terminal and cannot communicate. Sometimes it becomes.

[0006] On the other hand, if the cell search cycle of the mobile radio terminal is too short, the cell search is performed frequently even though the reception level from the base station is sufficient in a state where the mobile radio terminal hardly moves. Will be wasted.

SUMMARY OF THE INVENTION The present invention has been made in view of the above-mentioned problem, and is directed to a mobile radio terminal that appropriately controls a cell search cycle of the mobile radio terminal and suppresses power consumption of a battery included in the mobile radio terminal. The purpose is to provide.

[0008]

A mobile radio terminal according to the present invention has a function of receiving a signal transmitted from a base station and periodically detecting a base station which is a candidate for a handover destination. In, a determining means for determining whether the mobile radio terminal is staying in the communication area of the same base station, and if it is determined that the mobile radio terminal is staying in the communication area of the same base station by the determining means, Cycle changing means for lengthening the detection cycle of the base station which is a candidate for the handover destination.

According to the above arrangement, the switching time of the base station, that is, the waiting time at one base station, is always measured as the dwell time, and the cell search activation time interval is determined in accordance with the switching time of the base station. The switching candidate base station is predicted by the next switching time so that it can be detected by that time.

[0010] Thereby, the cell search activation interval is set to be short when the mobile radio terminal moves at a high speed, and to be long when the mobile radio terminal is stopped when it becomes unnecessary to newly detect the base station. However, if the cell search activation interval becomes infinitely long when the mobile radio terminal is stopped, an upper limit is set for the activation interval to prevent the base station to be switched when the mobile radio terminal starts to be undetected. A lower limit is set for the start interval in consideration of the battery life when moving.

[0011] In addition, if the base stations are switched alternately even when the base station is stopped, there is a high possibility that the switching destination is the same base station as the base station connected in the past. Therefore, if the base station is stored several times in the past and switched to the same base station, it is determined that the base station is in a staying state, the counting of the staying time is continued, and the start cycle of the cell search is extended, so that an unnecessary cell can be obtained. Do not search.

The residence time is a time during which the mobile radio terminal waits in a state where it can be considered that the mobile radio terminal is not moving.
In a state where the mobile radio terminal can be regarded as not moving, the reception level of the signal received by the mobile radio terminal from the standby base station is high and stable.

[0013]

DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a mobile radio terminal according to an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a functional block diagram of a mobile wireless terminal 100 according to one embodiment of the present invention. The mobile wireless terminal 100 according to the present embodiment includes a wireless unit 10, a baseband processing unit 20, a control unit 30, and an interface unit 40. In addition, the baseband processing unit 20 includes a cell search circuit 21. Further, the control unit 30 includes a timer 31 and a memory 3
2 and a counter 33 are connected. The mobile radio terminal 100 is connected to a base station 5 connected to a mobile communication network.
Communication is performed with 0. The cell search is automatically executed by the cell search circuit 21.

The signal from base station 50 received by the antenna is input to radio section 10. A desired channel is selected from the received signal, and a desired signal is received.
This signal is demodulated and output to baseband processing section 20.

In the baseband processing section 20, the demodulated signal is converted into a digital signal, and this digital signal is digitally demodulated. That is, this digital signal becomes data necessary for communication, voice data, user service data, and the like.

These data are output to the interface unit 40 and the memory 32 under the control of the control unit 30. In the interface unit 40, the audio data is output as real audio. Further, the memory 32 stores the input data.

On the other hand, when a signal such as voice is transmitted,
Data such as actual voice is input to the interface unit 40, the input signal is converted into a digital signal, and the control unit 30
Is output to the baseband processing unit 20 according to the control of.

In the baseband processing section 20, the input digital signal is digitally modulated. The digitally modulated signal is converted to an analog signal and output to the radio unit 10.

In the radio unit 10, the converted analog signal is modulated. The modulated analog signal is transmitted from the antenna to the base station 50 after removing unnecessary signal components other than the desired channel.

FIG. 2 is a flowchart for calling a cell search cycle update process of mobile radio terminal 100 according to one embodiment of the present invention.

When the mobile radio terminal 100 enters the standby state and the intermittent activation process is started (ST-A1), the reception level of the signal received from the base station to be communicated and the detection of the incoming call are executed (ST-A1). -A2).

In addition to the processing of step ST-A2, it is confirmed whether the current time is a cell search timing (cell search cycle) for detecting a switching candidate base station (ST-A3). If the cycle for executing the cell search has not been reached, the process proceeds to step ST-A4.
Go to -A5.

The control unit 30 determines whether or not it is the execution cycle of the cell search based on the time measured by the timer 31.

If it is determined in step ST-A3 that the cell search cycle has arrived, a search for a base station effective as a switching candidate is executed (ST-A4). When this process ends, mobile radio terminal 100 shifts to the sleep state again.

On the other hand, if it is determined in step ST-A3 that the cell search cycle has not arrived, the cell search cycle is updated (ST-A5).

This updating process is executed based on an instruction from the control unit 30, and updates the base station identification information on the base station stored in the memory 32 and the mobile radio terminal 1.
00 reads from the counter 33 and stores the staying time in the cell covered by the same base station (ST-
A5).

FIG. 3 is a flowchart of a cell search cycle update process of mobile radio terminal 100 according to one embodiment of the present invention. The following update processing is executed based on an instruction from the control unit 30.

When the process for updating the cell search cycle is executed (ST-B1), it is determined whether or not to change the base station on which mobile radio terminal 100 is on standby (ST-B2). . When the mobile radio terminal 100 changes the base station on which the mobile radio terminal 100 is on standby, the process proceeds to step ST-B3. On the other hand, when the mobile radio terminal 100 does not change the base station on which the mobile radio terminal 100 is on standby, the process proceeds to step ST-B6. move on.

It should be noted that whether or not the mobile radio terminal 100 changes the base station on which the mobile station 100 is on standby is determined by whether or not a signal from a base station having a higher reception level than the current standby base station is received. It is done based on. That is, when a signal from a base station having a higher reception level than that of the current standby base station is being received, the base station that stands by to the base station having the higher reception level is changed. On the other hand, when a signal from a base station having a higher reception level than the current standby base station is not received, the mobile radio terminal 100 continuously performs standby with the current standby base station.

Alternatively, the determination may be made based on whether or not the reception level of the base station that is currently waiting is lower than a preset threshold. If the reception level is lower than this threshold, a base station that can communicate at a reception level higher than this threshold is selected. This threshold is set based on the reception performance of the mobile radio terminal 100, the nature of radio waves transmitted to and received from the base station, and the like.

If it is determined in step ST-B2 that the standby base station is to be changed, a search is made to determine whether the identification information of the destination base station is present in the identification information of the base station stored in the memory 32. (ST-B3). The memory 32 usually stores identification information of a plurality of base stations, and the base station and the identification information correspond one-to-one.

Step ST stored in memory 32
The identification information of the base station searched for in B3 is the identification information of the base station that has been on standby in the past, and the identification information of the base station that has been changed within the number of change times m and has been awaited since the present time. It is. That is, the history of the identification information of the base station changed within the number of change times m from the present to the past is stored in the memory 32. This numerical value m
Is empirically set to a value such that the cell search is optimally performed. The optimum value of the numerical value m changes depending on the arrangement distribution of the surrounding cells where the mobile radio terminal 100 is located.

This numerical value m may be set beforehand when the mobile radio terminal is manufactured, or may be set so that the user can freely set the numerical value m. If the setting is made at the time of manufacturing the mobile radio terminal, the setting may be made according to the region where the mobile radio terminal is sold.

Further, the identification information of the destination base station is added to the history stored in the memory 32 as the latest identification information (ST-B4). Further, the identification information is added to the history stored in the memory 32 and the oldest stored identification information is deleted from the memory 32 (ST-B4).

However, if the oldest stored identification information of the base station exists as a history within m times, the identification information is set so as not to be discarded from the history. That is, the identification information of the base station changed within m times is always set in the memory 32.

After step ST-B3, step ST-
Proceeding to B4, the result searched in step ST-B3 is determined in step ST-B5.

In step ST-B3, it is searched whether the identification information of the base station to be changed exists in the identification information of the base station stored as a history in the memory 32, and the identification information of the base station to be changed is stored in the memory 32. Is determined as a history (ST-B5). If the change-destination base station is stored in the memory 32 as a history, the step ST-
The process proceeds to B6, and if the base station to be changed is not stored in the memory 32 as a history, the process proceeds to step ST-B7.

In this step ST-B5, when the identification information of the base station to be changed is stored as a history in the memory 32, it is determined that the mobile radio terminal 100 has hardly moved its position and stayed there. I reckon. Similarly, in step ST-B2, when it is determined that the mobile radio terminal 100 continuously performs standby with the current standby base station, the mobile radio terminal hardly moves its position and stays there. Assume that there is.

If the changed base station is stored as a history in the memory 32, or if it is determined in step ST-B2 that the mobile radio terminal 100 does not change the standby base station, the mobile station stays Counter 33 indicating time
And the waiting time is updated by adding a standby wake-up cycle (DRX) to the terminal (ST-B6). DRX is a mobile radio terminal 100
Indicates the time interval at which the standby operation starts. Here, the added residence time is set to the wake-up cycle DRX, but is not limited to this. If a more effective numerical value can be obtained experimentally, the additional residence time may be set to that numerical value.

When the base station of the change destination is stored in the memory 32 as a history, the cell search cycle is not changed.

As a matter of course, if there is no change in the base station, DRX is added to the residence time counter T if the change-destination base station exists in the history even if there is a change. Even if there is a change in the base station, the DRX is added to the residence time counter T when the change destination base station is in the history, because unnecessary cell search is performed in a place such as an urban area where base stations are densely arranged. This is because they do not.

In a place such as an urban area, there are a plurality of receivable base stations, and the base station is changed even if the mobile radio terminal 100 hardly moves. Therefore, even when the standby base station moves back and forth between the same base stations, even if there is a change in the base station, if the destination base station is in the history, it is determined that the base station is in the history, and the count-up is continued without clearing the residence time counter. Is set to As a result, the battery can be used effectively without performing the cell search unnecessarily.

On the other hand, if the base station to be changed is not stored as a history in the memory 32 in step ST-B5, the cell search cycle is updated to shorten the cell search cycle (ST-B7). In the present embodiment, a value obtained by dividing the time of the residence time counter by a certain natural number is used as a cell search cycle (ST-B7). That is, t = T / n. Here, t is a cell search cycle, T is the time indicated by the residence time counter, and n is a natural number. Usually, n = 4, but the present invention is not limited to this.

It is also possible to set so that a certain time is subtracted from the time indicated by the residence time counter. An essential matter here is to shorten the cell search cycle.

Thereafter, the updated cell search cycle t becomes
The preset upper limit value of the cell search cycle (tma
It is determined whether it is larger than x) (ST-B9).
When the updated cell search cycle t is not larger than the upper limit value tmax, the process proceeds to step ST-B10, and when the updated cell search period t is larger than the upper limit value tmax, the process proceeds to step ST-B11.

If it is determined in step ST-B9 that the updated cell search cycle t is not larger than the upper limit value tmax, the updated cell search cycle t is set to be smaller than the preset lower limit value (tmin). It is determined whether or not it is smaller (ST-B10). If the updated cell search cycle t is not smaller than the lower limit value tmin, step ST-
Proceeding to B8, the updated cell search cycle t becomes the lower limit value tm
If it is smaller than in, the process proceeds to step ST-B12.

If it is determined in step ST-B9 that the updated cell search cycle t is larger than the upper limit value tmax, the cell search cycle t is updated again to tmax (ST
-B11).

If it is determined in step ST-B10 that the updated cell search cycle t is smaller than the lower limit value tmin, the cell search cycle t is updated to tmin again (ST-B12).

The upper limit value tmax and the lower limit value tmi
n is set to a numerical value in a range in which the effect of updating the cell search cycle is recognized. For example, tmax is set in a range shorter than the default cell search cycle. The time tmin is set based on the maximum practically possible frequency of the cell search in consideration of the battery capacity of the mobile radio terminal 100 and the power consumption by the cell search.

The cell search period t is set to an upper limit (tmax) so that even when the cell search period is stagnant, the cell search is performed in order to secure candidates for switching base stations in preparation for the start of movement. Further, by setting a lower limit (tmin), a cell search cycle can be opened to some extent so as not to use up a finite battery even during high-speed movement.
The frequency of cell search, which increases the processing time, is suppressed.

If it is determined in step ST-B10 that the updated cell search cycle t is not smaller than the lower limit value tmin, the cell search cycle is set to t in step ST-B11.
max or re-updated, or step ST-B
When the cell search cycle is updated again to tmin at 12, the residence time counter T is cleared (ST-B8).
That is, T is set to 0. When reaching this step, the standby base station is changed, and the identification information of the standby base station to be changed is not stored in the memory 32 of the mobile radio terminal 100 as a history.
The mobile wireless terminal 100 can be regarded as not staying. Therefore, the residence time counter is cleared.

After the stay time counter is updated in step ST-B6, or after the stay time counter is cleared to 0 in step ST-B8, the process for updating the cell search cycle is completed (ST-B6). B1
3).

FIG. 4 is an explanatory diagram showing how the base station of the mobile radio terminal 100 according to the embodiment of the present invention is changed.

As shown in FIG. 4, the mobile radio terminal 10
It is assumed that 0 (that is, the mobile station) moves in the radio wave range provided by the base station A, the base station B, and the base station C as in the moving direction 7.

At first, from the state of waiting at the base station A, the received power 4 by the base station A decreases as the mobile radio terminal 100 moves, and the received power 5 by the base station B increases instead.

At position 8, the standby base station switches from base station A to base station B. In order to enable switching from the base station A to the base station B, the mobile radio terminal 100 enters the radio range 2 of the base station B before the radio range 1 of the base station A.
It is necessary to detect the base station B before exiting from. When the mobile radio terminal 100 further moves, the received power 5 of the base station B decreases, and instead, the received power 6 of the base station C increases.

Then, at position 9, the standby base station switches from base station B to base station C. In this case, the mobile radio terminal 100 waits at the base station B between the position 8 and the position 9. In order to enable switching from the base station B to the base station C, it is necessary to detect the base station C before entering the radio wave range 2 of the base station B after entering the radio range 3 of the base station C.

FIG. 5 is an explanatory diagram of a cell search cycle of the mobile radio terminal 100 according to one embodiment of the present invention. FIG. 5 shows a temporal representation of the operation described above with reference to FIG.

The base station C can be detected by the increase of the received power 12 by the base station C before the received power 11 by the base station B falls to a level that cannot be received, that is, within a time during which the base station B can wait. , It is necessary to detect the base station C.

In the present embodiment, the cell search period t is obtained in proportion to the standby time with the base station that has been waiting. Also, the higher the moving speed of the mobile radio terminal 100, the shorter the standby time. Therefore, the cell search period t becomes shorter as the moving speed of the mobile radio terminal 100 becomes faster. As a result, it is possible to reliably detect the next standby base station.

In the example shown in FIG. 5, the base station C can be reliably detected in the (n-1) th cell search 14.
At time 13, the standby base station can be switched to base station C.

As described above, according to the present embodiment, in order to obtain the cell search cycle, the time required for switching from the current base station to the next base station by movement is measured. A value obtained by dividing this time by an arbitrary natural number n (normally, n = 4) is set as a cell search cycle in which the next base station is waiting. Also,
This time includes the traffic between base stations that approach each other in an urban area or the like, so that when there is no possibility that a new base station can be detected, the cell search cycle is lengthened.

Since the cell search process takes a long time, it is necessary to reduce the number of times per unit time as much as possible in order not to waste power. It is necessary to increase the number of times per unit time in order for the mobile radio terminal 100 to detect the base station to which the mobile radio terminal 100 is to be switched when moving and prepare for the switching.

The mobile radio terminal 10 according to the embodiment of the present invention
0 determines the cell search cycle in accordance with the arrangement intervals of the base stations and the moving speed of the mobile radio terminal 100. Therefore,
Switching destination base station candidates can always be maintained with a minimum number of cell searches. In addition, the mobile radio terminal 10 that is performing standby operation of switching base stations in a stable manner and
0 low power consumption can be realized.

The present invention is not limited to the above-described embodiment, but can be implemented with various modifications within the technical scope.

[0066]

According to the mobile radio terminal of the present invention, the power consumption of the battery provided in the mobile radio terminal is suppressed by changing the cell search cycle according to the arrangement interval of the base stations and the moving speed of the mobile radio terminal. It becomes possible to do.

[Brief description of the drawings]

FIG. 1 is a functional block diagram of a mobile wireless terminal according to an embodiment of the present invention.

FIG. 2 is a flowchart for calling a cell search cycle update process of the mobile wireless terminal according to one embodiment of the present invention.

FIG. 3 is a flowchart of a cell search cycle update process of the mobile wireless terminal according to one embodiment of the present invention.

FIG. 4 is an explanatory diagram showing how a mobile radio terminal changes a standby base station according to an embodiment of the present invention.

FIG. 5 is an explanatory diagram of a cell search cycle of the mobile wireless terminal according to one embodiment of the present invention.

[Explanation of symbols]

10 Radio section 20 Baseband processing unit 21 Cell Search Circuit 30 control unit 31 timer 32 memories 33 counter 40 Interface section 50 base stations

Claims (3)

[Claims] 1. A mobile radio terminal having a function of receiving a signal transmitted from a base station and periodically detecting a base station which is a candidate for a handover destination, wherein the mobile radio terminal is located within a communication area of the same base station. Determining means for determining whether or not the wireless terminal is staying; detecting, when the determining means determines that the wireless terminal is staying within the communication area of the same base station, detection of the base station as a candidate for the handover destination; A mobile radio terminal, comprising: a period changing unit for increasing a period. 2. The mobile radio terminal according to claim 1, further comprising a counter for counting a staying time of the mobile radio terminal when the mobile radio terminal stays in the communication area of the same base station. The mobile radio terminal according to claim 1. 3. An identification information indicating a base station connected in the past and storage means for storing the number of times of connection to the base station, wherein the identification information indicating the base station detected as a handover destination candidate is stored in the storage unit. 3. The mobile radio terminal according to claim 1, wherein the mobile radio terminal is regarded as staying in an area covered by the detected base station when the mobile radio terminal is stored in the storage unit. .