JP3663191B2 - Mobile communication terminal - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a mobile communication terminal used in a mobile communication system such as an automobile / mobile phone system or a wireless LAN.
[0002]
[Prior art]
In the W-CDMA system defined by 3GPP (3rd Generation Partnership Project), a handover is performed even in an incoming call waiting state. In other words, since the mobile station must maintain a state in which incoming information can be received correctly, there is a possibility that Paging information can be received more correctly compared to the current standby cell, that is, a serving cell. If a high cell exists, a handover is performed to change the destination to that cell. Handover in this incoming call waiting state is called reselection (see Non-Patent Document 1, for example).
[0003]
As shown in FIG. 11, the mobile station performs intermittent reception at intervals of 2.56 s in the incoming call waiting state. At the time of this intermittent reception, if the reception power S related to the serving cell is larger than the threshold value Sintra specified from the network side, the mobile station performs RF wakeup 101, Serving Cell Search 102, and PI (Paging Indicator) detection 103, If an incoming call to the self cannot be detected by the PI detection 103, the process returns to the sleep state. In this case, the operation period in one intermittent reception is, for example, about 30 ms.
[0004]
When the received power S is less than or equal to the threshold value Sintra, the mobile station performs PI detection Monitored Cell Search 104 and Reselection determination 105 subsequent to RF wakeup 101 and Serving Cell Search 102. If the result of the reselection determination 105 indicates that no reselection occurs, the mobile station performs sleep 106 and returns to the sleep state. In this case, the operation period in one intermittent reception is, for example, about 100 ms.
[0005]
If a reselection occurs as a result of the reselection determination 105, the mobile station further performs BCCH reception 107, PCH close / open parameter update 108, and sleep 109 to return to the sleep state. In BCCH Reception 107, broadcast information transmitted on BCCH is received. The broadcast information includes MIB (Master Information Block) and SIB (System Information Block). It takes several hundreds of milliseconds to receive the MIB. It takes 1000 to 2000 ms to receive SIB. For this reason, the operation period in one intermittent reception when Reselection occurs is extremely long, at least about 1500 ms. In addition, after the BCCH Reception 107 is completed, a CRC check on the received broadcast information is performed, and if CRC NG is detected even for one frame, the broadcast information must be received again from the beginning. For this reason, when CRC NG occurs, the operation time in intermittent reception is further increased.
[0006]
[Non-Patent Document 1]
3GPP TS 25.133
[0007]
[Problems to be solved by the invention]
For this reason, when reselection is performed, the period during which the mobile station is in the sleep state is shortened as shown in FIG. 11, which may increase power consumption.
[0008]
The present invention has been made in consideration of such circumstances, and its purpose is to shorten the operation period of intermittent reception when performing a handover in an incoming call waiting state, thereby reducing power consumption. It is an object of the present invention to provide a mobile communication terminal that can reduce the above.
[0009]
[Means for Solving the Problems]
In order to achieve the above-described object, the present invention includes first information and second information positioned after the first information, and further includes update information indicating an update state of the second information in the first information. In a mobile communication terminal used in a mobile communication system that broadcasts broadcast information for each cell, when it becomes necessary to perform handover in an incoming call waiting state, based on broadcast information related to the handover destination cell When it becomes necessary to perform handover, handover processing means for performing processing for handover, storage means for associating cell identification information, broadcast information, and energy information in association with each other and storing a predetermined number of sets, The first receiving means for receiving the first information of the broadcast information related to the handover destination cell and the hand when the handover needs to be performed Update information included in the broadcast information stored in the storage means in association with the identification information of the handover destination cell or the identification information of the destination cell is not stored in the storage means. If the update information included in the first information received by the first receiving means does not match, the second information of the broadcast information related to the handover destination cell is received for use by the handover processing means. When the second information is received by the second receiving means and the second receiving means, broadcast information including the second received information and the first information received by the first receiving means and the broadcast information are First writing means for writing identification information of related cells in association with each other in the storage means, detection means for detecting the energy amount of a signal sent from the cell, Energy amount information determined in consideration of the detected energy amount when the energy amount of the signal transmitted from the cell corresponding to the identification information stored in the storage means is detected by the detection means. A second writing means for writing energy information in association with the identification information in the storage means, and storing in the storage means in association with the identification information of the handover destination cell when the handover needs to be performed; If the update information included in the broadcast information being matched with the update information included in the first information received by the first receiving means, the storage means is associated with the identification information of the handover destination cell. Reading means for reading out the notification information stored in the hand-over processing means, and the first writing means further comprises: When the stage has already stored the predetermined number of sets of the identification information, the notification information, and the energy information, the set of the identification information, the notification information, and the energy selected based on the energy amount information The information is deleted from the storage means, and the new notification information and the identification information are written to the storage means.
[0010]
By taking such means, the broadcast information consisting of the first information received by the first receiving means and the second information received by the second receiving means is the identification information of the cell to which the broadcast information relates. Are associated with each other and stored in the storage means. When it is necessary to perform a handover, update information included in broadcast information stored in association with identification information of a handover destination cell, and update information included in the first information received by the first receiving unit, If they match, the broadcast information stored in association with the identification information of the handover destination cell is used by the handover processing means. However, if the above condition is not satisfied, the second information is received by the second receiving means, and the broadcast information composed of the second information and the first information received by the first receiving means is used by the handover processing means. Is done. Therefore, if the above condition is satisfied, the handover can be performed without receiving the second information.
[0011]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings. In the present embodiment, a mobile communication terminal conforming to the W-CDMA scheme formulated in 3GPP will be described.
[0012]
FIG. 1 is a block diagram of a mobile communication terminal according to this embodiment.
[0013]
As shown in FIG. 1, the mobile communication terminal of this embodiment includes an antenna 1, a radio unit 2, a CDMA processing unit 3, a compression / decompression unit 4, a PCM processing unit 5, a call unit 6, an input unit 7, a display unit 8, and a storage. Unit 9, cell energy detection unit 10, and CPU 11. The radio unit 2 includes a duplexer (DUP) 2a, a reception circuit (RX) 2b, a frequency synthesizer (SYN) 2c, and a transmission circuit (TX) 2d. The call unit 6 includes a receiver amplifier 6a, a receiver 6b, a microphone 6c, and a transmission amplifier 6d.
[0014]
A radio signal transmitted from a base station (not shown) is received by the antenna 1 and then input to the radio unit 2. In the radio unit 2, the radio signal is input to the receiving circuit 2b via the duplexer 2a. The radio signal is frequency-converted into an intermediate frequency signal by being mixed in the reception local oscillation signal output from the frequency synthesizer 2c with the reception circuit 2b. The frequency of the reception local oscillation signal generated from the frequency synthesizer 2c is set by a control signal output from the CPU 11.
[0015]
The intermediate frequency signal is input to the CDMA processing unit 3. The CDMA processing unit 3 despreads the intermediate frequency signal using a spreading code assigned to the receiving channel. Subsequently, the CDMA processing unit 3 performs quadrature demodulation corresponding to, for example, a QPSK (Quadrature Phase Shift Keying) modulation method, and thereby converts it into demodulated data of a predetermined format. Then, the CDMA processing unit 3 gives the demodulated data to the compression / decompression unit 4.
[0016]
The compression / decompression unit 4 separates data of various media multiplexed on the demodulated data output from the CDMA processing unit 3. The compression / decompression unit 4 performs a decoding process on the separated data by a method corresponding to each medium. For example, the compression / decompression unit 4 performs a voice decoding process on the audio data according to, for example, the QCELP method or the EVRC method. The audio data after the voice decoding process is given to the PCM processing unit 5. The compression / decompression unit 4 performs video decoding processing on the video data according to, for example, the MPEG4 system. Video data obtained by this video decoding process is given to the CPU 11. Various types of control data sent from the mail data and the mobile communication network are given from the compression / decompression unit 4 to the CPU 11.
[0017]
The PCM processing unit 5 performs PCM decoding on the audio data provided from the compression / decompression unit 4 to obtain an analog audio signal. The audio signal is amplified by the receiver amplifier 6a and then output as audio from the receiver 6b.
[0018]
The voice uttered by the speaker is converted into a voice signal by the microphone 6c. This audio signal is input to the transmission amplifier 6d. The audio signal is amplified to an appropriate level by the transmission amplifier 6d and then given to the PCM processing unit 5.
[0019]
The PCM processing unit 5 performs PCM encoding processing on the audio signal to obtain digital audio data. The PCM processing unit 5 gives this audio data to the compression / decompression unit 4.
[0020]
Note that mail data and control data created by the CPU 11 are also given to the compression / decompression unit 4.
[0021]
The compression / decompression unit 4 detects the energy amount of the input voice from the audio data, and determines the transmission data rate based on the detection result. The compression / decompression unit 4 encodes the audio data into a signal having a format corresponding to the transmission data rate. The compression / decompression unit 4 multiplexes various data such as the audio data, the mail data, or the control data after the encoding according to a predetermined transmission format to form transmission data. The compression / decompression unit 4 gives the transmission data to the CDMA processing unit 3.
[0022]
The CDMA processing unit 3 modulates the carrier wave signal with the transmission data given from the compression / decompression unit 4. For this modulation, for example, QPSK is used. The CDMA processing unit 3 performs spread spectrum processing on the modulated carrier signal using a PN code assigned to each transmission channel, thereby obtaining a transmission signal. Then, the CDMA processing unit 3 gives the transmission signal to the transmission circuit 2d of the radio unit 2.
[0023]
The transmission circuit 2d converts the transmission signal into a radio frequency signal by synthesizing it with a transmission local oscillation signal generated from the frequency synthesizer 2c. Then, based on the transmission data rate notified by the CPU 11, the transmission circuit 2d amplifies only the effective portion of the radio frequency signal and outputs it. The radio frequency signal output from the transmission circuit 2d is supplied to the antenna 1 via the duplexer 2a, and transmitted from the antenna 1 to the connected base station.
[0024]
The input unit 7 is provided with a key group including a dial key, a call key, a power key, an end key, a volume adjustment key, a mode designation key, and the like. The input unit 7 inputs user instructions by pressing these keys. The display unit 8 is provided with a liquid crystal display (LCD) and a light emitting diode (LED). The display unit 8 uses these LCDs and LEDs, including the telephone number of the communication partner's terminal and the operation status of the own terminal such as the incoming call status, download information from the WEB site, transmission / reception mail, moving image, illustration Displays the battery discharge status etc.
[0025]
The storage unit 9 uses, for example, ROM, DRAM (dynamic RAM), SRAM (static RAM), flash memory, or the like as appropriate. The storage unit 9 stores an operation program for the CPU 11. In addition, the storage unit 9 stores various data such as various setting information, various reception data, and various data created by the apparatus. A part of the storage area of the storage unit 9 is used as a cache for broadcast information.
[0026]
The cell energy detection unit 10 detects reception energy (hereinafter referred to as cell energy) for each cell based on a correlation value obtained when the intermediate frequency signal is despread by the CDMA processing unit 3. The cell energy detection unit 10 notifies the CPU 12 of the detected cell energy.
[0027]
The CPU 11 realizes operation as a mobile communication terminal by performing control processing of each unit by software processing based on an operation program stored in the storage unit 9. The CPU 11 operates as a physical layer control unit 111, an upper layer control unit 112, a time measuring unit 113, a cache organizing unit 114, and an energy writing unit 115 by software processing based on the operation program.
[0028]
The physical layer control unit 111 performs various controls related to the physical layer. The physical layer control unit 111 further includes an MIB receiving unit 111a, an SIB receiving unit 111b, a broadcast information writing unit 111c, and a broadcast information reading unit 111d. The MIB receiving unit 111a unconditionally receives the MIB when it is necessary to acquire broadcast information. The SIB receiving unit 111b receives the SIB only when notification information to be acquired is not cached in the storage unit 9 when it is necessary to acquire the notification information. When the SIB is received by the SIB reception unit 111b, the broadcast information writing unit 111c writes the broadcast information including the SIB and the MIB received by the MIB reception unit 111a into the storage unit 9 in order to cache it. When the notification information to be acquired is cached in the storage unit 9 when the notification information needs to be acquired, the notification information reading unit 111d reads out the cached notification information from the storage unit 9.
[0029]
The upper layer control unit 112 performs various controls related to the upper layer. The upper layer control unit 112 further includes a reselection control unit 112a. The reselection control unit 112a performs control for performing reselection.
[0030]
The timer 113 measures the elapsed time from the cache for each piece of notification information cached in the storage unit 9.
[0031]
The cache organizing unit 114 deletes the notification information whose elapsed time after being cached exceeds a predetermined time from the storage unit 9 and organizes the cache.
[0032]
When the cell energy relating to the cell corresponding to the notification information cached in the storage unit 9 is detected by the cell energy detection unit 10, the energy writing unit 115 associates the cell energy with the notification information and stores the cell energy. Write to.
[0033]
FIG. 2 is a diagram showing a cache table prepared in the storage unit 9 for caching notification information.
[0034]
As shown in FIG. 2, the cache table can store a plurality (eight in this case) of notification information. Furthermore, the cache table can store a scrambling code, cell energy, and VALUE_TAG in association with each broadcast information.
[0035]
Here, VALUE_TAG will be described.
[0036]
VALUE_TAG is included in broadcast information transmitted on BCCH. More specifically, VALUE_TAG is included in the MIB of the MIB and SIB constituting the broadcast information. VALUE_TAG indicates how the SIB is updated. That is, VALUE_TAG can take a value of “1” to “8”, and the value is updated every time the SIB is updated.
[0037]
By the way, the SIB includes 18 blocks “SIB1” to “SIB18”, and different information is indicated in each block.
[0038]
FIG. 3 is a diagram showing a specific example of the format of broadcast information.
[0039]
In the broadcast information shown in FIG. 3, 20 blocks obtained by adding two “Reserve” blocks to 18 SIB blocks are divided into 5 groups of 4 blocks, and a total of 5 MIBs are added, one at the head of each group. One period is arranged by arrangement. Thus, this notification information is composed of 25 blocks for one period. If each block has a length of about 40 ms, for example, one cycle of the broadcast information has a length of 1000 ms. In this case, the information of each SIB block is reported once every about 1000 ms and for about 40 ms. The MIB is broadcast once every about 200 ms and for about 40 ms.
In this way, the MIB period is shorter than the SIB block period if the same broadcast information needs to be acquired many times, even if all SIB blocks are not acquired, the VALUE_TAG of the MIB. This is because there is a possibility that the reacquisition of the SIB block can be omitted by determining whether or not is different from the previously acquired value.
[0040]
However, the VALUE_TAG of the MIB is not updated only when the SIB block “SIB7” is exceptionally updated. This is because the SIB block “SIB7” includes UL interference amount information. Since the UL interference amount information is determined by the instantaneous number of users existing in a certain cell and the transmission power of those users, it always varies. For this reason, if VALUE_TAG is also updated according to the update of the SIB block “SIB7”, the VALUE_TAG will always change, so the update of the SIB block “SIB7” is not reflected in VALUE_TAG. .
[0041]
Next, the operation of the mobile communication terminal configured as described above will be described. In the following, operations related to reselection will be described in detail.
[0042]
Reselection occurs when a search for neighboring cells is performed by the physical layer and, as a result, a cell that can obtain a reception level equal to or higher than a threshold value can be detected continuously over a certain period of time.
[0043]
Therefore, as shown in FIG. 4, the CPU 11 can detect whether or not cells capable of obtaining a reception level equal to or higher than the threshold value can be continuously detected over a certain period of time as shown in FIG. Confirm whether or not. If no cell that satisfies the above condition is found, the physical layer control unit 111 shifts to sleep without performing reselection.
[0044]
If a cell satisfying the above conditions is found, the physical layer control unit 111 reports all of the found cells to the upper layer as reselection target cells in step ST1-3.
[0045]
Upon receiving this report, upper layer control section 112 selects the optimum cell from the reported reselection target cells in step ST2-1 as shown in FIG. Subsequently, in step ST2-2, the upper layer control unit 112 requests the physical layer control unit 111 to acquire broadcast information regarding the selected optimum cell. In this request, the higher layer control unit 112 notifies the physical layer control unit 111 of the identification number of the scrambling code assigned to the optimum cell.
[0046]
In response to this request, in step ST1-4, the physical layer control unit 111 first receives only the MIB of the broadcast information. Further, in step ST1-5, the physical layer control unit 111 executes broadcast information acquisition processing.
[0047]
A flowchart of the notification information acquisition process by the physical layer control unit 111 is shown in FIG.
[0048]
As shown in FIG. 5, in the broadcast information acquisition process, the physical layer control unit 111 assigns “0” to the variable i in step ST3-1, and sets the broadcast information cached in the storage unit 9 to the variable m. The number obtained by subtracting “1” from the number is substituted. Thereafter, in step ST3-2, the physical layer control unit 111 matches the scrambling code notified from the higher layer control unit 112 as described above with the scrambling code cached in association with INDEX [i]. Check whether or not. If it is confirmed that the two scrambling codes do not match, the physical layer control unit 111 confirms whether or not the variable i is less than the variable m in step ST3-3. If it is confirmed that the variable i is less than the variable m, the physical layer control unit 111 increases the variable i by one in step ST3-4. Thereafter, the physical layer control unit 111 returns the process to step ST3-2. As a result, the notified scrambling code is compared with each of the cached scrambling codes.
[0049]
If it is confirmed in step ST3-2 that both scrambling codes match, physical layer control section 111 confirms in steps ST3-5 and ST3-6 whether or not the following conditions are satisfied.
[0050]
(1) The VALUE_TAG included in the MIB received in step ST1-4 matches the VALUE_TAG cached in association with INDEX [i].
[0051]
(2) The elapsed time indicated by the time counting unit 113 (hereinafter referred to as timer [i]) for the notification information cached in association with INDEX [i] is a predetermined time T _SIB7 Is not yet passed.
[0052]
When it is confirmed that the above condition is satisfied, the physical layer control unit 111 determines that the cached broadcast information is still valid information. Therefore, in step ST3-7, the physical layer control unit 111 reads the notification information cached in association with INDEX [i] from the storage unit 9, and reports the notification information to the higher layer control unit 112. When this report is finished, the physical layer control unit 111 ends the broadcast information acquisition process and returns to the process shown in FIG.
[0053]
On the other hand, when it is confirmed in step ST3-5 and step ST3-6 that the above condition is not satisfied, or in step ST3-3, it is confirmed that the variable i is not less than the variable m. The layer control unit 111 determines that there is no information to be acquired in the cached notification information. Therefore, in step ST3-8, the physical layer control unit 111 newly receives an SIB, and reports this SIB to the higher layer control unit 112 as broadcast information together with the MIB received in step ST1-4.
[0054]
Subsequently, in step ST3-9, the physical layer control unit 111 confirms whether or not the notification information of the cacheable number has already been cached. If it is confirmed that the number of cached broadcast information has not reached the cacheable number, the physical layer control unit 111 sets each information to be cached in association with INDEX [i + 1] in step ST3-10. Write to the storage unit 9. At this time, since the variable i matches the maximum value of the INDEX value associated with the cached broadcast information, new information is cached in association with the INDEX value one larger than that. Become. And in order to time-measure the elapsed time regarding the alert information newly cached here, the physical layer control part 111 starts timer [i + 1] in step ST3-11. After that, the physical layer control unit 111 ends the broadcast information acquisition process and returns to the process shown in FIG.
[0055]
On the other hand, when it is confirmed in Step ST3-9 that the notification information of the cacheable number has already been cached, the physical layer control unit 111 corresponds to the smallest cached cell energy in Step ST3-12. Determine INDEX number n. For example, if the cache table is in the state shown in FIG. 6A, the INDEX number n is determined to be “6”.
[0056]
If the cell energy detection unit 10 detects the cell energy related to the cell in which the scrambling code is cached when the cell search or the like is performed, the CPU 11 uses the energy writing unit 115 to cache the cached cell. The energy value is updated to an average value obtained by adding the newly detected value. Thus, the value of the cached cell energy is assumed to indicate the average magnitude of recent cell energy.
[0057]
Thereafter, in step ST3-13, the physical layer control unit 111 writes each information into the storage unit 9 to be cached in association with INDEX [n]. Thereby, for example, the cache table in the state shown in FIG. 6A is updated to the state shown in FIG. And in order to time-measure the elapsed time regarding the alert information newly cached here, the physical layer control part 111 starts timer [n] in step ST3-14. After that, the physical layer control unit 111 ends the broadcast information acquisition process and returns to the process shown in FIG.
[0058]
The scrambling code written in steps ST3-10 and ST3-13 is the current notification scrambling code. The cell energy to be written is the cell energy detected by the cell energy detector 10 for the cell corresponding to the current notification scrambling code when the reselection target cell is detected. The VALUE_TAG to be written is the VALUE_TAG included in the MIB received in step ST1-4. The broadcast information to be written consists of the MIB received in step ST1-4 and the SIB received in step ST3-8.
[0059]
As described above, in the broadcast information acquisition process, cached broadcast information or newly received broadcast information is reported to the higher layer control unit 112. In response to this report, upper layer control section 112 performs a CRC check on the reported broadcast information in step ST2-3, and confirms whether or not it has been normally acquired. If there is a CRC NG, the higher layer control unit 112 returns the process to step ST2-2, and requests the physical layer control unit 111 to acquire broadcast information again.
[0060]
If the physical layer control unit 111 completes the broadcast information acquisition process, in step ST1-6, it is determined whether the next report made from the higher layer control unit 112 is a broadcast information acquisition request or a PCH close instruction. Confirm. If acquisition of broadcast information is requested again as described above, the physical layer control unit 111 returns the process to step ST1-4.
[0061]
Thus, when there is CRC NG, acquisition of broadcast information regarding the same cell is performed again. If the broadcast information cannot be normally acquired even if the broadcast information is repeatedly acquired for a certain number of times, upper layer control section 112 gives up reselection and continues the incoming call waiting state in the original cell.
[0062]
Now, if it is confirmed in step ST2-3 that the broadcast information reported from the physical layer control unit 111 is normal, the higher layer control unit 112 determines in step ST2-4 the cell of the incoming call reception destination so far. To close the physical layer control unit 111. Upon receiving this instruction, the physical layer control unit 111 confirms that PCH close has been instructed in step ST1-6. In this case, in step ST1-7, the physical layer control unit 111 discards various kinds of information for waiting for an incoming call in the cell of the incoming call waiting destination.
[0063]
In step ST2-5, the upper layer control unit 112 instructs the physical layer control unit 111 to open the PCH related to the current reselection destination cell in step ST2-5. This instruction includes various types of information (new cell information) for waiting for an incoming call in the reselection destination cell, such as information on the reselection destination cell and information on neighboring cells of the cell. . When receiving this instruction, the physical layer control unit 111 acquires the new cell information in step ST1-8. In step ST1-9, the physical layer control unit 111 starts an intermittent reception operation for performing incoming call waiting based on the new cell information. In response, upper layer control section 112 starts an intermittent reception operation in step ST2-6.
[0064]
The CPU 11 causes the cache organizing unit 114 to execute a cache organizing process as shown in FIG. 7 at every predetermined timing such as every predetermined time interval.
[0065]
First, in step ST4-1, the cache organizing unit 114 substitutes “0” for the variable j, and substitutes the number obtained by subtracting “1” from the number of notification information cached in the storage unit 9 for the variable k. Thereafter, in step ST4-2, the cache organizing unit 114 determines the elapsed time indicated by the time measured by the time measuring unit 113 (hereinafter referred to as timer [j]) for the notification information cached in association with INDEX [j]. T _SIB7 To see if it has already exceeded. The predetermined time T _SIB7 Is a time corresponding to the period for reacquiring the SIB block “SIB7”. Predetermined time T _SIB7 Is set to 20 minutes, for example.
[0066]
Timer [j] is a predetermined time T _SIB7 In step ST4-3, the cache organizing unit 114 confirms whether or not the variable j is less than the variable k. If it is confirmed that the variable j is less than the variable k, the cache organizing unit 114 increases the variable j by one in step ST4-4. Thereafter, the cache organizing unit 114 returns the process to step ST4-2. As a result, each timer has a predetermined time T _SIB7 It is sequentially confirmed whether or not the above has already been exceeded.
[0067]
Timer [j] is a predetermined time T _SIB7 In step ST4-5, the cache organizing unit 114 stores each information cached in association with INDEX [j + 1] to INDEX [k] in step ST4-5. Move to correspond to INDEX [j] to INDEX [k-1]. Then, in step ST4-6, the cache organizing unit 114 deletes each information cached in association with INDEX [k].
[0068]
Specifically, for example, the cache table is in the state shown in FIG. 8A, and the timer [6] corresponding to INDEX [6] _SIB7 Is exceeded, the information cached in association with INDEX [7] is moved so as to be associated with INDEX [6] as shown in FIG. Then, the information cached in association with INDEX [7] is deleted, and as shown in FIG. 8B, these storage areas are all unused.
[0069]
Subsequently, in step ST4-7, the cache organizing unit 114 sets the timer times of timer [j + 1] to timer [k] to timer [j] to timer [k-1], respectively. As a result, the correspondence between the notification information moved in the cache table and the timer that measures the elapsed time after the notification information is cached are matched.
[0070]
Since one piece of notification information has been deleted as described above, the cache organizing unit 114 decreases the variable k by one in step ST4-8. On this basis, in step ST4-9, the cache organizing unit 114 checks whether or not the variable j is equal to or less than the variable k.
[0071]
Here, if the variable j is equal to or less than the variable k, there is information that has not been checked yet, so the cache organizing unit 114 repeatedly executes the process of step ST4-2.
[0072]
If it can be confirmed in step ST4-9 that the variable j is equal to or less than the variable k, or if it can be confirmed in step ST4-3 that the variable j is less than the variable k, all the cached items are stored. Since this information has been checked, the cache organizing unit 114 ends the cache organizing process.
[0073]
As described above, according to the present embodiment, the notification information that has been successfully received is cached in the storage unit 9. When a new reselection occurs and it is necessary to acquire broadcast information, only MIB is received first. If broadcast information related to the same cell is cached in the storage unit 9 and the VALUE_TAG related to the cached broadcast information matches the VALUE_TAG included in the newly received MIB, the SIB is not received. The cached notification information is read from the storage unit 9 and used. As a result, when using the cached broadcast information, as shown in FIG. 9B, the operation period is significantly shortened compared to the case of FIG. 9A in which all the broadcast information is newly received. can do.
[0074]
Further, since the cached broadcast information is normally received, CRC NG does not occur as long as the cached broadcast information is used. Therefore, the processing for reacquisition is not repeatedly performed, and the operation period can be reliably shortened from this point.
[0075]
Thus, the ratio of the sleep period can be increased, and the power consumption can be reduced efficiently.
[0076]
The normal timing at which reselection occurs is when the mobile station moves between cell boundaries, when it is affected by an unforeseeable building, and the like. However, exceptionally, for example, in a place such as a high-rise building where a large number of cells can be seen, the reception level of each cell may become unstable and reselection may occur frequently. In such a case, it is conceivable that the same cell is repeatedly subject to reselection within a short period of time, and the broadcast information may not be updated during that time. Therefore, in such a case, the cached notification information can be frequently used, and reselection can be performed efficiently.
[0077]
In addition, since the time required for reselection is shortened, it is possible to quickly resume the incoming call waiting. As a result, the incoming call rate is improved.
[0078]
That is, as shown in FIG. 10, since the base stations perform the incoming call notification asynchronously, the standby base station BS2 after the reselection performs the incoming call notification earlier than the original standby base station BS1. It can happen. At this time, if all of the notification information is received in the reselection, the reselection is not completed even when the incoming notification is made as shown by the arrow A1, and there is a possibility that the incoming notification may not be received. is there. On the other hand, if the reselection is completed within a short period by using the cached notification information as indicated by the arrow A2, the possibility of receiving the incoming notification increases. Therefore, the incoming call rate is NO.
[0079]
By the way, VALUE_TAG is used to determine the validity of the cached broadcast information, but VALUE_TAG can take only 8 values from “1” to “8”. For this reason, if the broadcast information remains cached for a long time, if the VALUE_TAG in the latest broadcast information is one or more rounds, the VALUE_TAG matches even though the broadcast information is updated. There is a risk that this situation will occur. However, in this embodiment, the predetermined time T _SIB7 Is set as the effective period, and broadcast information cached for more than this time is not used. For this reason, it is possible to prevent the situation as described above from occurring and prevent inappropriate notification information from being used.
[0080]
Furthermore, according to the present embodiment, the elapsed time from the cache is a predetermined time T. _SIB7 Whether or not there is information exceeding the limit is monitored, and processing for deleting the corresponding information from the cache is periodically performed. For this reason, in the broadcast information acquisition process, it is possible to suppress the necessity of performing the determination in step ST3-5 or step ST3-6 for outdated information, and to perform reselection more efficiently. Is possible.
[0081]
Moreover, according to this embodiment, the average value of the cell energy detected recently about the cell with which the alerting | reporting information currently cached is related is managed. And when the broadcast information is newly received and the cacheable number of broadcast information is already cached, the broadcast information on the cell having the smallest managed cell energy is deleted, and a new The broadcast information is cached. A small cell energy is equivalent to a low possibility of moving to a new cell, and is therefore a piece of information that is least likely to be used for broadcast information relating to that cell. Therefore, it is possible to cache more important information by erasing such low importance information and caching newly received broadcast information having high importance.
[0082]
The present invention is not limited to the above embodiment. For example, as a value to be cached as cell energy, it is possible to use various values as materials for evaluating the recent received energy, such as the most recently detected received energy value. is there.
[0083]
The selection condition of the notification information to be deleted from the storage unit 9 to cache new notification information can be arbitrarily changed so that the cached timing is the oldest.
[0084]
The present invention can also be applied to a mobile communication terminal conforming to a system other than the 3GPP W-CDMA system.
[0085]
In addition, various modifications can be made without departing from the scope of the present invention.
[0086]
【The invention's effect】
According to the present invention, the broadcast information composed of the first information received by the first receiving means and the second information received by the second receiving means is associated with the identification information of the cell to which the broadcast information relates. To be stored in the storage means. When it is necessary to perform a handover, update information included in broadcast information stored in association with identification information of a handover destination cell, and update information included in the first information received by the first receiving unit, If the two match, the broadcast information stored in association with the identification information of the handover destination cell is used by the handover processing means. However, if the above condition is not satisfied, the second information is received by the second receiving means, and the broadcast information composed of the second information and the first information received by the first receiving means is used for the handover processing means. I will let you. Therefore, if the above condition is satisfied, the handover can be performed without receiving the second information. As a result, the operation period of the intermittent reception when performing the handover in the incoming call waiting state can be shortened. As a result, the mobile communication terminal can reduce power consumption.
According to the present invention, the storage means can store the identification information and the notification information in a predetermined number of sets, and corresponds to each of the stored identification information and the notification information. In addition, energy information is stored, and detection means for detecting the energy amount of the signal transmitted from the cell and energy amount of the signal transmitted from the cell corresponding to the identification information stored in the storage means are Second writing means for writing predetermined energy amount information determined in consideration of the detected energy amount to the storage means in association with the identification information as the energy information in response to detection by the detecting means When the storage means has already stored the predetermined number of the identification information and the notification information, the first writing means And deleting a set of the identification information and the notification information selected based on the associated energy amount information from the storage means, and writing the new notification information and the identification information into the storage means. Yes. Therefore, broadcast information about an important cell that transmits a signal that can be received with a large amount of energy can be stored in the storage means, and the operation period of intermittent reception as described above can be efficiently reduced. Is possible.
[Brief description of the drawings]
FIG. 1 is a block diagram of a mobile communication terminal according to an embodiment of the present invention.
FIG. 2 is a diagram showing a cache table prepared in a storage unit 9 for caching notification information.
FIG. 3 is a diagram illustrating a specific example of a format of broadcast information.
FIG. 4 is a flowchart of the physical layer control unit 111 and the upper layer control unit 112 at the time of reselection.
FIG. 5 is a flowchart of broadcast information acquisition processing by a physical layer control unit 111;
FIG. 6 is a diagram showing a specific example of a state of writing new information to the cache table.
FIG. 7 is a flowchart of cache organizing processing by the cache organizing unit 114;
FIG. 8 is a diagram showing a specific example of how the cache is organized.
FIG. 9 is a diagram showing the processing content during one intermittent reception operation with reselection.
FIG. 10 is a diagram for explaining improvement of an incoming call rate.
FIG. 11 is a diagram showing processing contents during an intermittent reception operation in the 3GPP W-CDMA system.
[Explanation of symbols]
1 ... Antenna
2 ... Radio part
3 ... CDMA processor
4 ... Compression / decompression part
5 ... PCM processor
6 ... Calling part
7 ... Input section
8 ... Display section
9 ... Memory unit
10: Cell energy detector
11 ... CPU
111 ... physical layer control unit
111a ... MIB receiver
111b ... SIB receiver
111c ... Notification information writing unit
111d ... Notification information reading unit
112 ... upper layer control unit
112a ... Reselection control unit
113 ... Timekeeping section
114 ... Cash Organizing Department
115 ... Energy writing unit

Claims (3)

Broadcast information including first information and second information located after the first information and further including update information indicating the state of update of the second information is broadcast for each cell. In a mobile communication terminal used in a mobile communication system,
Handover processing means for performing processing for handover based on broadcast information regarding a handover destination cell when it is necessary to perform handover in an incoming standby state;
Storage means for associating cell identification information, the broadcast information, and energy information in association with each other,
First receiving means for receiving the first information of the broadcast information related to the handover destination cell when the handover needs to be performed;
When the handover needs to be performed, the identification information of the handover destination cell is not stored in the storage means, or is stored in the storage means in association with the identification information of the handover destination cell. If the update information included in the broadcast information does not match the update information included in the first information received by the first receiving means, the second information of the broadcast information related to the handover destination cell is Second receiving means for receiving for use in the handover processing means;
When the second information is received by the second receiving means, broadcast information comprising the second received information and the first information received by the first receiving means, and identification of a cell to which the broadcast information relates First writing means for writing information to the storage means in association with each other;
Detection means for detecting the energy amount of the signal sent from the cell;
Energy amount information determined in consideration of the detected energy amount when the energy amount of the signal transmitted from the cell corresponding to the identification information stored in the storage unit is detected by the detection unit. Second writing means for writing to the storage means in association with the identification information as the energy information;
When the handover needs to be performed, the update information included in the broadcast information stored in the storage unit in association with the identification information of the handover destination cell and the first reception unit received by the first reception unit If the update information included in the information matches, a reading means for reading out the broadcast information stored in the storage means in association with the identification information of the handover destination cell for use in the handover processing means; Equipped,
Further, the first writing means, when the storage means already stores the predetermined number of the identification information, the notification information, and the energy information, the one set selected based on the energy amount information. And deleting the identification information, the notification information, and the energy information from the storage means, and writing the new notification information and the identification information into the storage means.   2. The mobile communication terminal according to claim 1, wherein the first writing unit deletes the identification information and the notification information having the smallest energy amount indicated by the associated energy amount information from the storage unit. . Using the information of Master Information Block defined in the 3rd Generation Partnership Project (3GPP) W-CDMA system as the first information,
Using the information of System Information Block defined by the W-CDMA system as the second information,
Using the VARUE_TAG value defined in the W-CDMA system as the update information,
Using the transmission information on the BCCH defined by the W-CDMA system as the broadcast information,
The mobile communication terminal according to claim 1, wherein a scrambling code defined in the W-CDMA system is used as the identification information.

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