JP3813812B2 - Wireless mobile - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a CDMA (Code Division Multiple Access) wireless device and a CDMA in-zone standby transition method.
[0002]
[Prior art]
In recent years, a plurality of base stations are distributed in a service area, a radio zone called a cell is formed by these base stations, and a cellular connection is established between the base station and a mobile radio for each cell. Mobile communication systems are widespread.
[0003]
As a multiple access method in this cellular mobile communication system, for example, an FDMA (Frequency Division Multiple Access) communication method using a different frequency for each user, or sharing the same frequency by dividing time for each user There are TDMA (Time Division Multiple Access) communication systems and CDMA communication systems that use different codes for each user at the same frequency.
[0004]
Among these, in the CDMA system, a spread modulation system is used in which a time-series random code sequence is superimposed on a transmission signal, and the spread-modulated signal is called a spread spectrum signal. On the other hand, the receiver of the spread spectrum signal can acquire information from the spread spectrum signal by executing a kind of demodulation processing called despreading processing using the same code sequence as the code sequence used by the transmitter.
For this reason, when each user uses different code sequences, the same frequency and time can be shared, and frequency resources can be used effectively. Furthermore, since it is necessary to use the same code sequence between the sender and the receiver, there is an advantage that information is difficult to leak to a third party who does not have the same code sequence, so that the secrecy is excellent.
[0005]
By the way, in the CDMA system, after the power is turned on or after moving, the mobile station establishes synchronization with the signal transmitted from the base station immediately in order to be able to communicate with the base station under the serving cell. There is a need to. In addition to the establishment of such synchronization, a comprehensive operation including identification of a service carrier used for communication with a base station is generally called a cell search.
[0006]
Here, the cell search is roughly executed as follows. That is, first, slot timing is detected by inputting a signal through a specific channel (P-SCH) from the received spread spectrum signal to the matched filter, and secondly, the detected slot timing and The specific channel (S-SCH) is used to specify the frame timing and the scramble code group is detected. Third, the scramble code is detected using the detected scramble code group and the specific channel (CPICH). Fourth, the signal via a specific channel (BCCH) is despread using the detected scramble code, and the cell area number and other information are commonly reported to all mobile devices in the cell. Information obtained.
[0007]
Then, when the mobile device acquires information, the mobile device shifts to the in-zone standby state. However, if the mobile station cannot acquire information, cannot detect slot timing in the first place, or cannot detect a scramble code, it returns the search procedure to slot timing detection again, and performs despreading processing. The same operation is intermittently repeated until the information is acquired. Here, when information cannot be acquired by the despreading process, the mobile device enters an out-of-service state.
[0008]
[Problems to be solved by the invention]
However, the power consumed in the despreading process executed by the CDMA method is relatively large. For this reason, when a despreading process is executed a considerable number of times in the mobile device, there is a problem that the power is consumed as much as a result and the continuous standby time of the mobile device is shortened.
[0009]
The present invention has been made in view of the above-described circumstances, and the object of the present invention is to reduce the despreading process when shifting to the in-standby standby state, reduce the consumed power, and set the standby time. It is an object of the present invention to provide a CDMA wireless device and a CDMA standby waiting method for extending the service period.
[0010]
[Means for Solving the Problems]
  In order to achieve the above object, the present invention relates to the first invention.In the mobile radio apparatus, storage means for storing frequency information indicating the lowest frequency among the frequencies at which a carrier wave used for radio communication with a base station can be located, an antenna for receiving a spread spectrum signal, and the storage After measuring the electric field strength of the spread spectrum signal received by the antenna at the lowest frequency indicated by the frequency information of the means, the frequency at which the electric field strength is measured is moved from the lowest frequency to the higher frequency side by a predetermined frequency width. Measurement means for sequentially measuring the electric field strength of the spread spectrum signal received by the antenna at each of the frequencies, and each time the electrolytic strength is measured by the measurement means, the measured electrolytic strength is a first threshold value. Is a means for counting whether or not the electric field intensity exceeds the first threshold value, When the threshold value is reached, the frequency band between the frequency of the spread spectrum signal that was the determination target when performing the first count of the continuous count and the frequency of the spread spectrum signal that was the determination target when performing the last count After specifying a second frequency band that is narrower than the first frequency band, including band specifying means for specifying the first frequency band, and a center frequency of the specified first frequency band, Cell search frequency specifying means for sequentially specifying a predetermined number of frequencies included in the second frequency band as frequencies to be subjected to cell search; and the frequency used by the cell search frequency specifying means for the frequency included in the second frequency band. When specified as the frequency to be subject to cell search, the signal of the first channel included in the spread spectrum signal received by the antenna at that frequency The frame timing and the scramble code group are detected using the detected slot timing and the signal of the second channel included in the spread spectrum signal, and then the third timing included in the scramble code group and the spread spectrum signal. The scramble code is detected using the channel signal, and the own channel is located by performing despreading processing on the fourth channel signal included in the spread spectrum signal using the detected scramble code. A cell search execution unit for acquiring broadcast information including information unique to the base stationIt is characterized by.
[0011]
  Similarly, in order to achieve the above object, the second invention is concerned.In the mobile radio, storage means storing frequency information indicating the lowest frequency and the highest frequency of a frequency band in which a carrier used for radio communication with a base station can be located, an antenna for receiving a spread spectrum signal, After measuring the electric field strength of the spread spectrum signal received by the antenna at the lowest frequency indicated by the frequency information of the storage means, move the frequency for measuring the electric field strength from the lowest frequency to the higher frequency side by a predetermined frequency width. Measuring means for sequentially measuring the electric field strength of the spread spectrum signal received by the antenna at each of the shifted frequencies, and the measured electrolytic strength is a predetermined threshold each time the electrolytic strength is measured by the measuring means. Determining means for determining whether or not the threshold value is greater than the threshold value, the electrolytic intensity of the spread spectrum signal received by the antenna at a certain frequency. When the determining means determines that the frequency exceeds the band, the band specifying means for specifying a first frequency band that is a frequency band between the frequency and the highest frequency indicated by the frequency information of the storage means, and the specified After specifying a second frequency band that is narrower than the first frequency band, including the center frequency of the first frequency band, a predetermined number of frequencies included in the second frequency band are subject to cell search. Cell search frequency specifying means for sequentially specifying as a frequency to be, and when the cell search frequency specifying means specifies a frequency included in the second frequency band as a frequency to be subjected to cell search, the antenna receives at that frequency Slot timing detected from the signal of the first channel included in the spread spectrum signal and the second channel included in the spread spectrum signal. Is used to detect the frame timing and the scramble code group, then the scramble code is detected using the scramble code group and the third channel signal included in the spread spectrum signal, and the detected scramble code is detected. Cell search execution unit for acquiring broadcast information including information unique to the base station where the mobile station is located by performing despreading processing on the signal of the fourth channel included in the spread spectrum signal using With.
[0018]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of the present invention will be described below with reference to the drawings.
[0019]
<First Embodiment>
First, a CDMA wireless mobile device (hereinafter simply referred to as “mobile device”) applied to the method according to the embodiment will be described. FIG. 1 is a block diagram showing the configuration of this mobile device.
As shown in the figure, in the mobile device 100, a control unit 10 including a CPU (Central Processing Unit) or the like is configured to control each unit.
[0020]
Next, the antenna 12 receives the spread spectrum signal 30 transferred via the service carrier. The storage device 14 mainly stores frequency information related to service carriers. Here, the frequency information regarding the service carrier is information indicating, for example, the center frequency of the service carrier and its bandwidth.
Subsequently, the electric field strength measuring device 16 measures the electric field strength at the frequency specified by the control unit 10 and returns the measured value to the control unit 10.
[0021]
On the other hand, the cell search execution unit 18 receives the spread spectrum signal carried by the service carrier designated by the control unit 10 and executes the above-described cell search.
In addition to the configuration shown in the figure, the mobile device 100 includes the same mechanism as that normally provided (for example, a receiver, a transmitter, an operation unit, a display unit, etc.). The description thereof will be omitted because it is not related to the purpose.
[0022]
<Operation>
Here, before describing the operation of the mobile device 100, a service carrier assumed in the present embodiment will be briefly described with reference to FIG.
As shown in the figure, in the present embodiment, it is assumed that there is one service carrier, and the service carrier has a frequency f._C1With a bandwidth centered around. In this case, the storage device 14 (see FIG. 1) stores information on the service carrier, for example, the frequency f._C1Information such as bandwidth and bandwidth is stored as frequency information.
[0023]
<Cell search operation>
Next, the cell search operation in this embodiment will be described. FIG. 3 is a flowchart showing a processing procedure up to the transition to the standby state including the cell search operation.
First, in step Sa1, the control unit 10 resets the variable k in the internal register to “0”. Here, the variable k indicates the number of continuous cell searches performed by the cell search execution unit 18.
[0024]
Next, in step Sa2, the control unit 10 first reads the frequency information stored in the storage device 14, and secondly, the frequency f is calculated from the read frequency information to the electric field strength measurement device 16._C1Instruct to measure the field strength at. As a result, the electric field strength measuring device 16 has the frequency f_C1The field strength E was measured by actually measuring the field strength E_C1Is returned to the control unit 10.
[0025]
Subsequently, in step Sa3, the control unit 10 returns the returned electric field strength E._C1Is greater than a preset threshold value Eth.
If the determination result is negative, the control unit 10 returns the processing procedure to step Sa2 after a predetermined time has elapsed, and again sends the frequency f to the electric field strength measuring device 16._C1Instruct to measure the field strength at. That is, in this embodiment, the measured electric field strength E_C1Is less than or equal to the threshold value, the processing procedure does not proceed after step Sa4.
On the other hand, the measured electric field strength E_C1When the threshold value exceeds the threshold value, in step Sa4, the control unit 10 sends the frequency f to the cell search execution unit 18._C1Is directed to perform a cell search for a service carrier (with a bandwidth defined by frequency information) centered on.
[0026]
Thereby, the cell search execution unit 18 first detects a slot timing by inputting a signal through a specific channel (S-SCH) among the received spread spectrum signals to the matched filter, 2 specifies the frame timing using the detected slot timing and a specific channel (P-SCH), detects a scramble code group, and thirdly detects the scramble code group and a specific channel (CPICH). Scramble code is detected using, and fourthly, a signal transmitted through a specific channel (BCCH) is subjected to despreading processing using the detected scramble code to try to acquire broadcast information (BCCH information).
[0027]
In step Sa5, the control unit 10 determines whether or not the cell search execution unit 18 has acquired the broadcast information. If the determination result is affirmative, the control unit 10 shifts to the in-zone standby state in step Sa6. .
On the other hand, when the cell search execution unit 18 cannot acquire the broadcast information, the control unit 10 increments the variable k by “1” in step Sa7 in accordance with the execution of the cell search, and further increments in step Sa8. It is determined whether or not the subsequent variable k is larger than a preset upper limit value kmax.
[0028]
When the variable k indicating the number of cell search executions by the cell search execution unit 18 exceeds the upper limit kmax, the control unit 10 returns the processing procedure to step Sa1, resets the variable k to “0”, Again, the frequency f_C1Instruct to measure the field strength at.
On the other hand, if the variable k does not exceed the upper limit value kmax, the control unit 10 causes the processing procedure to be skipped to step Sa4, causes the cell search execution unit 18 to execute the cell search again, and acquires broadcast information. Let me try.
[0029]
Thus, in the first embodiment, the frequency f_C1And the measured electric field strength E_C1The cell search is executed only when the threshold value Eth exceeds the threshold value Eth. Therefore, in the present embodiment, when the electric field strength in the service carrier is weak, the despreading process that consumes a large amount of power is not executed, so that the power consumption is reduced accordingly.
Furthermore, in the first embodiment, when the number of times that broadcast information cannot be acquired exceeds the upper limit value kmax even though the cell search is performed, the processing procedure is returned to the first step Sa1, so the cell search is repeated. Is prevented.
Therefore, in this embodiment, useless cell search operations are prevented double, and power consumption is reduced, so that the standby time can be prolonged.
[0030]
Second Embodiment
In the first embodiment described above, in order to simplify the explanation, it is assumed that there is one service carrier. However, in an actual CDMA system, as shown in FIG._C1, F_C2... f_CNThere may be N service carriers, each centered at.
Therefore, a second embodiment assuming a case where there are a plurality of N service carriers in this way will be described next. In the second embodiment, the storage device 14 (see FIG. 1) stores information on these service carriers, for example, the frequency f._C1, F_C2... f_CNSuch as information and bandwidth information are stored as frequency information.
[0031]
<Cell search operation>
Next, the operation in the second embodiment will be described. FIG. 5 is a flowchart showing the processing procedure of the second embodiment.
First, in step Sb1, the control unit 10 sets a variable n in the internal register to “1”. Here, the variable n is an ordinal number obtained by counting the service carriers that are cell search candidates from the low frequency side by the cell search execution unit 18. Here, the cell search candidates in the initial state are represented by the center frequency f_C1It means to be set in a service carrier.
[0032]
Next, in step Sb2, the control unit 10 resets the variable k in the internal register to “0”. Here, the variable k indicates the number of continuous cell search executions for a service that is a candidate for cell search.
Subsequently, in step Sb3, the control unit 10 first reads out the frequency information of the service carrier that is currently the cell search target from the storage device 14, and secondly, for the field strength measuring device 16, The frequency f from the read frequency information_CnInstruct to measure the field strength at.
As a result, the electric field strength measuring device 16 has the frequency f_CnThe field strength E was measured by actually measuring the field strength E_CnIs returned to the control unit 10.
[0033]
Next, in step Sb4, the control unit 10 returns the returned electric field strength E._CnIs greater than a preset threshold value Eth.
If the determination result is negative, the controller 10 increments the variable n by “1” in step Sb8 to change the current cell search candidate to the next service carrier, and further, in step Sb9. In FIG. 5, it is determined whether or not the variable n after increment is larger than N, that is, whether or not a service carrier that should not be installed is targeted for cell search.
If the determination result is negative, the control unit 10 returns the processing procedure to step Sb3 in order to measure the electric field strength again for the service carrier that is a candidate for the search after the increment. On the other hand, if the determination result is affirmative, the control unit 10 determines in step Sb10 that the service carrier having the lowest center frequency among the installed service carriers (the center frequency is f)._C1After the variable n is set to “1” in order to return to the search candidate, the processing procedure is returned to step Sb3 in order to measure the electric field strength again for the service carrier.
[0034]
That is, in step Sb4, the center frequency f of the nth service carrier counted from the low frequency side._CnField strength E_CnIs equal to or less than the threshold Eth, the service carrier that is a candidate for cell search is changed to the next (n + 1) th service carrier, and the electric field strength that is a precondition for performing the cell search is measured. . On the other hand, the center frequency f of the service carrier having the highest center frequency_CNField strength E_CNIs less than or equal to the threshold Eth, the candidate service carrier is in the initial state (ie, the center frequency is f_C1), The electric field strength which is a precondition for executing the cell search is measured.
[0035]
In step Sb4, the frequency f_CnField strength E_CnIs determined to be greater than the threshold value Eth, the control unit 10 determines to the cell search execution unit 18 in step Sb5 the service carrier that is currently a cell search candidate, that is, the frequency f._CnThe cell search is instructed for the service carrier having the bandwidth defined by the frequency information. As a result, the cell search execution unit 18 performs the despreading process as in the first embodiment described above to generate the frequency f._CnAs for service carriers centering on, it tries to acquire broadcast information (BCCH information).
[0036]
In step Sb6, the control unit 10 determines whether or not the cell search execution unit 18 has acquired the broadcast information. If the determination result is affirmative, the control unit 10 shifts to the in-zone standby state in step Sb7. .
On the other hand, when the cell search execution unit 18 cannot acquire the broadcast information, the control unit 10 increments the variable k by “1” in step Sb11 in correspondence with the execution of the cell search, and further increments in step Sb12. It is determined whether or not the subsequent variable k is larger than a preset upper limit value kmax.
If the variable k indicating the number of consecutive cell search executions for the service carrier that is currently a cell search candidate exceeds the upper limit value kmax, the control unit 10 selects a cell search candidate in step Sb13. In order to change to the next service carrier, the variable n is incremented by “1”. Further, in step Sb14, it is determined whether or not the service carrier indicated after the increment is not installed.
[0037]
If the determination result is negative, the control unit 10 immediately returns the processing procedure to step Sb2 in order to measure the electric field strength again for the service carrier that has become a cell search candidate after the increment. On the other hand, if this determination result is affirmative, in step Sb15, the control unit 10 selects a service carrier having the lowest center frequency among the installed service carriers (a carrier having a center frequency of fc1). In order to return to the candidate, after setting the variable n to “1”, the processing procedure is returned to step Sb2 in order to measure the electric field strength again for the service carrier.
[0038]
Thus, in the second embodiment, first, the frequency f_C1, F_C2... f_CN, Secondly, the field strength at the center frequency is measured, and thirdly, the measured field strength E is measured._CnIs equal to or less than the threshold value Eth, a service carrier that is a candidate for cell search is selected as the next one, and the electric field strength is measured again while the measured electric field strength E is measured._CnWhen the threshold value Eth exceeds the threshold value Eth, the cell search is executed for the first time.
For this reason, in the second embodiment, cell search for a service carrier having a low electric field strength is skipped without being executed, and accordingly, power consumption is reduced and the electric field strength at the center frequency is the threshold. Service carriers exceeding the value can be detected efficiently.
Furthermore, in the second embodiment, when the number of times broadcast information cannot be acquired despite the execution of cell search exceeds the upper limit value kmax, a service carrier serving as a search candidate is selected as the following, and the electric field Since the strength is re-measured, it is possible to prevent the cell search from being repeated unnecessarily.
Therefore, in the present embodiment, even when there are a plurality of service carriers, unnecessary cell search operations are prevented double, and power consumption is suppressed. As a result, standby time can be extended. Moreover, it becomes possible to efficiently detect one of a plurality of service carriers.
In the second embodiment, among the plurality of service carriers, cell search candidates are set in order from the one located on the low frequency side, but this order is not limited. For example, cell search candidates may be set in order from the one located on the high frequency side, or may be a random order.
[0039]
<Third Embodiment>
In the second embodiment described above, when there are a plurality of service carriers, the electric field strengths at the center frequency of these service carriers are measured, and the service carriers corresponding to those whose electric field strengths exceed the threshold Eth are searched for by cell search. However, it is also possible to estimate the service carrier from the CDMA standard and perform cell search.
Therefore, the third and fourth embodiments that perform the cell search by estimating the service carrier in this way will be described in order.
[0040]
First, a third embodiment will be described. In the standard proposed by a group called 3GPP (3rd Generation Partnership Project), the carrier raster is defined as 200 kHz, and therefore, from the low frequency side to the high frequency side (or high frequency) at a frequency interval of 200 kHz. When the electric field strength is measured (from the side toward the low frequency side), the measured frequency is always included in the frequency band of a certain service carrier.
[0041]
Therefore, in the third embodiment, as shown in FIG. 6, first, in the frequency band where the service carrier can be installed, the electric field strength is set at a frequency interval of 200 kHz from the low frequency side to the high frequency side. Second, if the measured electric field strength that exceeds the threshold Eth is over a considerable frequency bandwidth W (kHz), it is estimated that a service carrier exists in this band. Decided to do.
[0042]
Further, the estimated center frequency of the service carrier is ideally a frequency that first exceeds the threshold Eth when measuring the electric field strength (f in the figure)._L) And the frequency that finally exceeded the threshold Eth (f in the figure)_H). However, in practice, since it is subject to various effects due to reflection and the like, in this embodiment, a cell search is sequentially performed on a plurality of Q pieces positioned before and after this intermediate frequency to attempt to acquire broadcast information. did.
[0043]
Next, the cell search operation of such an algorithm will be described. FIG. 7 is a flowchart showing a processing procedure of the third embodiment.
First, in step Sc1, the control unit 10 sets a variable m in the internal register to “1”. Here, the variable m means an ordinal number when the frequency to be measured for electric field strength is counted from the low frequency side. Further, the frequency fm indicated by using this variable m is the mth counted from the low frequency side among the frequencies arranged at intervals of 200 kHz in the range from the lowest frequency to the highest frequency of the frequency band in which the service carrier can be installed. Means things. Therefore, setting the variable m to “1” in step Sc1 means that the frequency to be measured for the electric field strength is set to the lowest frequency at which the service carrier can be installed.
[0044]
Subsequently, in step Sc2, the control unit 10 resets the variable p in the internal register to “0” and sets the variable q to “1”. The meaning contents of the variables p and q will be described later.
Further, in step Sc3, the control unit 10 instructs the electric field strength measuring device 16 to measure the electric field strength at the current frequency fm. Thereby, the electric field strength measuring device 16 actually measures the electric field strength at the frequency fm, and returns the measured electric field strength Em to the control unit 10.
[0045]
Next, in step Sc4, the control unit 10 determines whether or not the returned electric field intensity Em is larger than a preset threshold value Eth.
If the determination result is negative, the control unit 10 increments the variable m by “1” in step Sc11 and returns the processing procedure to step Sc2. On the other hand, if the determination result is positive, the control unit 10 returns the variable m in step Sc5. p is incremented by “1”. Further, in step Sc6, it is determined whether or not the incremented variable p matches the threshold value pth. If the determination result is negative, the control unit 10 increments the variable m by “1” in step Sc12, and returns the processing procedure to step Sc3.
[0046]
Here, the threshold value pth is a value represented by (W / 200) when the bandwidth W (kHz) in FIG. 6 is used. That is, the threshold value pth indicates the number of measurement points of the electric field strength existing in the bandwidth W.
The variable p is reset to “0” in the initial state, and if the measured electric field intensity Em exceeds the threshold value Eth, it is incremented in step Sc5, while the measured electric field intensity Em is the threshold value. If it is less than the value, it is reset again to “0” in step Sc2. Furthermore, if the incremented variable p falls below the threshold value pth, the measurement frequency of the electric field strength is changed to the following by step Sc12.
For this reason, the variable p after being incremented in step Sc5 indicates that the measured electric field intensity Em exceeds the threshold value Eth when the electric field intensity is measured while shifting the measurement frequency to the high frequency side at intervals of 200 kHz. It shows the number of consecutive times.
Therefore, in step Sc6, it is determined whether or not the number of times coincides with the threshold value pth. Whether or not the electric field intensity Em exceeding the threshold value Eth continuously spreads over the considerable frequency bandwidth W is determined. It is equivalent to determining that.
[0047]
If the determination result is affirmative, in step Sc7, the control unit 10 firstly estimates that a service carrier exists in a frequency band in which the electric field strength Em continuously exceeds the threshold value Eth, Frequency f located before and after the center frequency of the band_C1, F_C2... f_CQAre set as the center frequencies of the service carriers, respectively (see FIG. 6).
[0048]
In subsequent Step Sc8, the control unit 10 instructs the cell search execution unit 18 to provide the service carrier corresponding to the variable q at the present time, that is, the frequency f._CQAnd a cell search is instructed for a service carrier having a bandwidth defined by frequency information. As a result, the cell search execution unit 18 performs the despreading process as in the first embodiment described above to generate the frequency f._CQAs for service carriers centering on, it tries to acquire broadcast information (BCCH information).
[0049]
In step Sc9, the control unit 10 determines whether or not the cell search execution unit 18 has acquired the broadcast information. If the determination result is affirmative, the control unit 10 shifts to the in-zone standby state in step Sc10. .
On the other hand, when the cell search execution unit 18 cannot acquire the broadcast information, the control unit 10 determines whether or not the current variable q exceeds the number Q in Step Sc13.
If the determination result is negative, in step Sc14, the control unit 10 increments the variable q by “1” in order to change the cell search candidate, and then returns the processing procedure to step Sc8. The cell search execution unit 18 is instructed to execute the cell search for the service carrier.
If the determination result is affirmative, the control unit 10 assumes that there is no service carrier in the band and should measure the electric field strength while shifting the measurement frequency to the high frequency side at intervals of 200 kHz. The processing procedure is returned to step Sc2.
[0050]
Thus, in the third embodiment, first, in the frequency band where the service carrier can be installed, the electric field strength is measured at a frequency interval of 200 kHz from the low frequency side toward the high frequency side, and secondly, If the measured electric field strength that exceeds the threshold Eth continuously spreads more than the extent corresponding to the considerable frequency bandwidth W, it is estimated that a service carrier exists in this band. Thus, the cell search is executed.
For this reason, in this embodiment, even when the mobile device 100 does not have information on service carriers, the service carriers to be subjected to cell search are narrowed down to Q, so that despreading with large power consumption is performed. It is possible to reduce the number of execution times of processing.
In the third embodiment, the electric field strength is measured and the service carriers are candidateed in the order from the one located on the low frequency side toward the high frequency side, but this order is not limited. For example, the order may be the order from the higher frequency side, or may be the random order.
[0051]
<Fourth embodiment>
Next, as in the third embodiment, a fourth embodiment that estimates a service carrier and performs a cell search will be described.
In the fourth embodiment, as shown in FIG. 8, first, in the frequency band where the service carrier can be installed, the electric field strength is continuously measured from the low frequency side to the high frequency side. Second, when the measured electric field intensity Em exceeds the threshold value Eth for the first time, a frequency closer to the high frequency by half the carrier frequency bandwidth ΔF is recognized as the center frequency of the service carrier. However, as described in the third embodiment, since it is actually affected by various factors such as reflection, a cell search is sequentially performed on a plurality of Q pieces located before and after the center frequency to obtain broadcast information. Decided to try.
[0052]
Next, the cell search operation of such an algorithm will be described. FIG. 9 is a flowchart illustrating a processing procedure according to the fourth embodiment.
First, in step Sd1, the control unit 10 sets the variables m and q in the internal register to “1”, respectively. Here, the variable m means an ordinal number when the frequency to be measured for electric field strength is counted from the low frequency side. Further, the frequency fm indicated by using this variable m means the mth frequency counted from the low frequency side among the frequencies arranged at regular intervals from the lowest frequency to the highest frequency of the frequency band in which the service carrier can be installed. To do.
[0053]
Therefore, in step Sd1, setting the variable m to “1” means that the frequency to be measured for the electric field strength is set to the lowest frequency at which the service carrier can be installed, as in the third embodiment. means.
Furthermore, the variable q means an ordinal number when the target Q frequencies are counted from the low frequency side, as in the third embodiment. In addition, about frequency arrangement | positioning, in this 4th Embodiment, it is good also as a 200 kHz space | interval similarly to 3rd Embodiment, and may be other than that.
[0054]
Subsequently, in step Sd2, the control unit 10 instructs the electric field strength measuring device 16 to measure the electric field strength at the current frequency fm. Thereby, the electric field strength measuring device 16 actually measures the electric field strength at the frequency fm, and returns the measured electric field strength Em to the control unit 10.
[0055]
Next, in step Sd3, the control unit 10 determines whether or not the returned electric field strength Em is larger than a preset threshold value Eth.
If the determination result is negative, the control unit 10 increments the variable m by “1” in step Sd8 to change the frequency to be measured for the electric field strength, and returns the processing procedure to step Sd2.
On the other hand, if this determination result is affirmative, in step Sd4, the control unit 10 firstly, from the frequency fm corresponding to the electric field intensity Em exceeding the threshold value Eth, only half of the carrier bandwidth ΔF. The frequency close to the high frequency is estimated as the center frequency of the service carrier, and secondly, the frequency f positioned before and after the estimated center frequency._C1, F_C2... f_CQAre set as the center frequency of the service carrier.
[0056]
In subsequent step Sd5, the control unit 10 tells the cell search execution unit 18 the carrier corresponding to the variable q at the present time, that is, the frequency f._CQAnd a cell search is instructed for a service carrier having a bandwidth defined by frequency information. As a result, the cell search execution unit 18 performs the despreading process as in the first embodiment described above to generate the frequency f._CQAs for service carriers centering on, it tries to acquire broadcast information (BCCH information).
[0057]
In step Sd6, the control unit 10 determines whether or not the cell search execution unit 18 has acquired the broadcast information. If the determination result is affirmative, the control unit 10 shifts to the in-zone standby state in step Sd7. .
On the other hand, when the cell search execution unit 18 cannot acquire the broadcast information, the control unit 10 determines whether or not the current variable q exceeds the candidate number Q in step Sd9.
If the determination result is negative, in step Sd10, the control unit 10 increments the variable q by “1” in order to change the cell search candidate, and then returns the processing procedure to step Sd5. The cell search execution unit 18 is instructed to execute the cell search for the service carrier.
If the determination result is affirmative, the control unit 10 sets a value obtained by adding the service carrier bandwidth ΔF to the current frequency fm as a new frequency fm in step Sd11, and then performs the processing procedure. Return to step Sd1. Thereby, the measurement frequency of the electric field strength is shifted at a stretch toward the high frequency by the bandwidth ΔF. This is because it is determined that the estimated service carrier does not exist, and it is meaningless to measure the electric field strength again in this band.
[0058]
As described above, in the fourth embodiment, first, in the frequency band in which the service carrier can be installed, the electric field strength is continuously measured from the low frequency side to the high frequency side, and secondly, the measured electric field is measured. A configuration in which, when the strength exceeds the threshold Eth, a frequency closer to a high frequency by half of the service carrier bandwidth ΔF is estimated as the center frequency of the service carrier from the measured frequency fm, and cell search is executed. It has become.
For this reason, in the fourth embodiment, even if the mobile device 100 does not have information on service carriers, the service carriers that are subject to cell search are narrowed down to Q, so that the power consumption is greatly reversed. It is possible to reduce the number of executions of the diffusion process.
In the fourth embodiment, the electric field strength is measured in the order from the low frequency side to the high frequency side, and the center frequency of the service carrier is candidateized. Absent. For example, it is good also as an order from the thing located in the high frequency side.
[0059]
<Fifth Embodiment>
In the third or fourth embodiment described above, even when the mobile device 100 does not have information on the service carrier, the service carrier exists in a band where the measured electric field strength Em exceeds the threshold value Eth. The estimation and the cell search are executed. However, if the estimated service carrier can be actually identified, other service carriers can be estimated from some frequency information.
For example, as shown in FIG. 10, the center frequency f is determined by cell search._c1When the service carrier to be 'is specified, the center frequency f of the service carrier other than the specified service carrier is determined from the information of the frequency pitch ΔFp where the service carrier stored in the storage device 14 is installed in advance._c2', F_c3', ..., f_cN'Can be estimated.
[0060]
Therefore, a fifth embodiment for estimating other service carriers in this way will be described. FIG. 11 is a flowchart showing this operation procedure.
First, when the storage device 14 does not store information related to the service carrier, the control unit 10 performs the process before step Sc7 in the third embodiment described above or the process before step Sd4 in the fourth embodiment described above. By the process, the frequency is shifted, the electric field strength is measured, and the frequency band in which the service carrier exists is estimated (step Se1).
[0061]
Next, in step Se2, the control unit 10 instructs the cell search execution unit 18 to execute the cell search for the estimated service carrier. Thereby, the cell search execution part 18 performs a de-spreading process, tries acquisition of broadcast information (BCCH information), ie, specifies a service carrier.
In step Se3, the control unit 10 determines whether or not the cell search execution unit 18 has acquired broadcast information. If the determination result is negative, the control unit 10 returns the processing procedure to step Se1 and performs service again. While the carrier is estimated, if this determination result is affirmative, in step Se4, a transition is made to the in-zone standby state.
[0062]
Furthermore, in step Se5, the control unit 10 determines the center frequency f of the identified service carrier._c1'And the frequency pitch ΔFp information, the center frequency f in the service carrier other than the specified service carrier_c2', F_c3', ..., f_cN'Is estimated and stored in the storage device 14.
[0063]
As described above, even if the information about the service carrier is not stored in the storage device in the mobile device 100, the center frequency of the service carrier that can be communicated is estimated and stored according to the fifth embodiment. Later, it becomes possible to select an efficient service carrier.
[0064]
<Sixth Embodiment>
Next, a sixth embodiment of the present invention will be described. As shown in FIG. 12, it is assumed that the mobile device 100 is not located in a cell under the control of the radio base station BS. In this state, the mobile device 100 needs to specify a service carrier with which communication is possible. However, simply repeating the cell search operation consumes power and shortens the standby time.
Therefore, in the sixth embodiment, the number of times that the service carrier could not be specified is counted, and when the number exceeds a certain value, the electric field strength is measured to select a cell search candidate.
[0065]
FIG. 13 is a flowchart showing an operation procedure in the sixth embodiment. First, in step Sf1, the control unit 10 resets a variable k indicating the number of continuous cell search executions to “0”.
Next, in step Sf2, the control unit 10 instructs the cell search execution unit 18 to execute a cell search for a certain service carrier. Thereby, the cell search execution part 18 performs a de-spreading process, and tries acquisition of alerting | reporting information (BCCH information).
[0066]
Then, in step Sf3, the control unit 10 determines whether or not the cell search execution unit 18 has acquired broadcast information (BCCH information). If the determination result is affirmative, in step Sf4, the in-zone standby mode is determined. Transition to the state.
On the other hand, when the cell search execution unit 18 cannot acquire the notification information, the control unit 10 determines whether or not the current variable k is larger than the preset upper limit value kmax in step Sf5. .
[0067]
If the determination result is negative, the control unit 10 increments the variable k by “1” in step Sf6 and then returns the processing procedure to step Sf2 to perform the cell search again. The cell search execution unit 18 is instructed to execute.
When the determination result in step Sf5 is affirmative, the control unit 10 instructs the field strength measuring device 16 to measure the field strength in step Sf7, and then measures the measured field strength in step Sf8. From this, it is determined whether or not a service carrier that is a candidate for cell search is selected. In addition, about the measurement of the electric field strength in step Sf7, and selection of the service carrier used as the candidate in step Sf8, any method can be used among the first to fifth embodiments described above.
[0068]
Here, if a service carrier that is a candidate for cell search cannot be selected, the control unit 10 returns the processing procedure to step Sf7 and continues to the electric field strength measuring device 16 until a service carrier that becomes a candidate for cell search is selected. The measurement of the electric field strength is repeatedly executed.
On the other hand, if a service carrier that is a candidate for cell search can be selected, the control unit 10 moves the processing procedure to step Sf1, resets the variable k to “0”, and then targets the service carrier selected as a candidate. The cell search execution unit 18 is instructed to perform the cell search.
[0069]
As described above, according to the sixth embodiment, when the number of consecutive cell search executions exceeds the threshold value kmax, the electric field strength is repeatedly executed until a service carrier that is a candidate for cell search is selected. . Here, the power consumed by the measurement of the electric field strength is smaller than the power consumed by the despreading process in the cell search. For this reason, it becomes possible to suppress the electric power consumed when the mobile device 100 is located outside the service area.
In addition, when the mobile device 100 moves from outside the service area to within the service area, the service carrier is immediately identified by the cell search in step Sf2, so that it does not take a long time to shift to the service area standby state.
[0070]
<Seventh embodiment>
Next, a seventh embodiment of the present invention will be described. Immediately after the power is turned on, when the information about the service carrier is not stored in the storage device 14, the mobile device 100 needs to specify a service carrier that can be communicated. Is consumed, so the standby time is shortened.
Therefore, in the seventh embodiment, when information on the service carrier is not stored immediately after the power is turned on, the electric field strength is measured and a cell search candidate is selected.
[0071]
FIG. 14 is a flowchart showing an operation procedure in the seventh embodiment. First, when power is turned on in the mobile device 100, the control unit 10 determines whether or not information on a service carrier is stored in the storage device 14 in step Sg1.
If the determination result is negative, the control unit 10 instructs the electric field strength measuring device 16 to measure the electric field strength in step Sg2, and then in step Sg3, the cell search is performed from the measured electric field strength. It is determined whether or not a service carrier that is a candidate for is selected.
It should be noted that any of the above-described first to fifth embodiments can be used for the measurement of the electric field strength at step Sg2 and the selection of candidate service carriers at step Sg3. .
[0072]
Here, if a service carrier that is a candidate for cell search cannot be selected, the control unit 10 returns the processing procedure to step Sg2 and measures electric field strength until a service carrier that becomes a candidate for cell search is selected. The apparatus 16 is caused to repeatedly execute electric field strength measurement.
On the other hand, if a service carrier that is a candidate for cell search can be selected, or if the determination result in step Sg1 is affirmative, the control unit 10 moves the processing procedure to step Sg4 and selects it as a candidate. The cell search execution unit 18 is instructed to perform a cell search for the service carrier indicated or the service carrier indicated by the stored information.
[0073]
Then, in step Sg5, the control unit 10 determines whether or not the cell search execution unit 18 has acquired broadcast information (BCCH information). Transition to the state. On the other hand, when the cell search execution unit 18 cannot acquire the notification information, the control unit 10 returns to step Sg1.
[0074]
As described above, according to the seventh embodiment, immediately after the power is turned on, if information on the service carrier is not stored, the electric field strength is repeatedly measured until a service carrier that is a candidate for cell search is selected. Become. As described above, the power consumed by the measurement of the electric field strength is smaller than the power consumed by the despreading process in the cell search, so that the power consumed immediately after the mobile device 100 is turned on can be suppressed. It becomes.
[0075]
【The invention's effect】
As described above, according to the present invention, in the CDMA system, it is possible to reduce the despreading process when shifting to the in-zone standby state, reduce the consumed power, and extend the standby time. It becomes.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration of a mobile device according to each embodiment of the present invention.
FIG. 2 is a diagram for explaining a service carrier assumed in the first embodiment of the present invention.
FIG. 3 is a flowchart showing an operation procedure of the first embodiment.
FIG. 4 is a diagram for explaining a service carrier assumed in the second embodiment of the present invention.
FIG. 5 is a flowchart showing an operation procedure of the second embodiment.
FIG. 6 is a diagram for explaining a service carrier estimation operation in the third embodiment of the present invention.
FIG. 7 is a flowchart showing an operation procedure of the third embodiment.
FIG. 8 is a diagram for explaining a service carrier estimation operation according to the fourth embodiment of the present invention.
FIG. 9 is a flowchart showing an operation procedure of the fourth embodiment.
FIG. 10 is a diagram for explaining another service carrier estimation operation in the fifth embodiment of the present invention;
FIG. 11 is a flowchart showing an operation procedure of the fifth embodiment.
FIG. 12 is a diagram for explaining the positional relationship of a mobile device in a sixth embodiment of the present invention.
FIG. 13 is a flowchart showing an operation procedure of the sixth embodiment.
FIG. 14 is a flowchart showing an operation procedure in the seventh embodiment of the present invention.
[Explanation of symbols]
10. Control unit
12 ... Antenna
14 ... Storage device
16 ... Electric field strength measuring device
18 ... Cell search execution part
100 ... mobile equipment

Claims (2)

Storage means for storing frequency information indicating the lowest frequency among the frequencies at which a carrier wave used for wireless communication with a base station can be located;
An antenna for receiving a spread spectrum signal;
After measuring the electric field strength of the spread spectrum signal received by the antenna at the lowest frequency indicated by the frequency information of the storage means, move the frequency for measuring the electric field strength from the lowest frequency to the higher frequency side by a predetermined frequency width. Measuring means for sequentially measuring the electric field strength of the spread spectrum signal received by the antenna at each of the shifted frequencies;
Each time the electrolytic strength is measured by the measuring means, it is determined whether or not the measured electrolytic strength exceeds a first threshold, and counts the number of consecutive times when the electric field strength exceeds the first threshold. When the counted number of consecutive times reaches the second threshold value, the frequency of the spread spectrum signal that was the determination target when performing the first count of the continuous number of times and the spread spectrum that was the determination target when performing the last count Band specifying means for specifying a first frequency band, which is a frequency band between signal frequencies;
After specifying a second frequency band that is narrower than the first frequency band including the center frequency of the specified first frequency band, a predetermined number of frequencies included in the second frequency band are stored in the cell. Cell search frequency specifying means for sequentially specifying the frequency to be searched;
When the cell search frequency specifying means specifies a frequency included in the second frequency band as a frequency to be subjected to cell search, from the signal of the first channel included in the spread spectrum signal received by the antenna at that frequency. After detecting the frame timing and the scramble code group using the detected slot timing and the signal of the second channel included in the spread spectrum signal, the third channel included in the scramble code group and the spread spectrum signal The base station in which it is located is detected by using the detected scramble code to detect the scramble code and applying the despreading process to the fourth channel signal included in the spread spectrum signal using the detected scramble code. Cell search execution to obtain broadcast information including information specific to the station And
Wireless mobile device equipped with. Storage means for storing frequency information indicating a minimum frequency and a maximum frequency of a frequency band in which a carrier wave used for wireless communication with a base station can be located;
An antenna for receiving a spread spectrum signal;
After measuring the electric field strength of the spread spectrum signal received by the antenna at the lowest frequency indicated by the frequency information of the storage means, move the frequency for measuring the electric field strength from the lowest frequency to the higher frequency side by a predetermined frequency width. Measuring means for sequentially measuring the electric field strength of the spread spectrum signal received by the antenna at each of the shifted frequencies;
Judgment means for judging whether or not the measured electrolytic strength exceeds a predetermined threshold each time the electrolytic strength is measured by the measuring means;
When the determination means determines that the electrolytic intensity of the spread spectrum signal received by the antenna at a certain frequency exceeds the threshold, the frequency band is between the frequency and the highest frequency indicated by the frequency information of the storage means. Band specifying means for specifying the first frequency band;
After specifying a second frequency band that is narrower than the first frequency band including the center frequency of the specified first frequency band, a predetermined number of frequencies included in the second frequency band are stored in the cell. Cell search frequency specifying means for sequentially specifying the frequency to be searched;
When the cell search frequency specifying means specifies a frequency included in the second frequency band as a frequency to be subjected to cell search, from the signal of the first channel included in the spread spectrum signal received by the antenna at that frequency. After detecting the frame timing and the scramble code group using the detected slot timing and the signal of the second channel included in the spread spectrum signal, the third channel included in the scramble code group and the spread spectrum signal The base station in which it is located is detected by using the detected scramble code to detect the scramble code and applying the despreading process to the fourth channel signal included in the spread spectrum signal using the detected scramble code. Broadcast including information specific to the station A cell search execution unit for acquiring information;
Wireless mobile device equipped with.

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