JP2010035062A - Communication terminal and communication method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a communication terminal and communication method, capable of performing communications in accordance with a plurality of communication schemes, in which a communication with a base station can be surely performed in a wireless communication system including the base station that has time information which is not accurate. <P>SOLUTION: When a communication terminal first establishes a communication of CDMA 2000_1x scheme and is brought into a waiting state and the communication terminal then establishes a communication of a 1xEVDO scheme and is brought into a waiting state, if a difference between SysTime_1x and SysTime_EVDO is greater than a prescribed threshold THcorrect, even when the SysTime_EVDO is acquired from a base station 2_EVDO in establishing and trying the communication of the 1xEVDO scheme, the SysTime_1x being applied to a clock unit 16 in establishing the communication of the CDMA 2000_1x scheme is maintained as it is and the newly acquired SysTime_EVDO is not applied to the clock unit 16. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a communication terminal and a communication method for performing a wireless communication terminal.

In a wireless communication system including communication using a plurality of communication schemes (communication protocols), there is a communication terminal that communicates with a base station using a plurality of communication schemes.
For example, as different communication methods, for example, there are a CDMA2000_1x method and a 1xEVDO method. The 1xEVDO system is a data communication standard included in the CDMA2000 standard.
As described above, there is a communication terminal capable of performing communication by a plurality of communication methods with one unit. Such a communication terminal is called a hybrid terminal, for example. In such a communication terminal, for example, communication using the CDMA2000_1x method can be performed during a voice call, and communication using the 1xEVDO method can be performed during data communication (email / data transmission / reception).

  Now, in the wireless communication system, the communication terminal communicates via the base station and exchanges data by the communication method as described above. Here, in order for the communication terminal to communicate with the base station, it is necessary to synchronize with the base station. Synchronization between the communication terminal and the base station is performed using accurate time based on, for example, a GPS signal.

  A GPS signal having accurate time information is transmitted from the GPS satellite, and the base station receives the GPS signal to obtain accurate time information. However, in recent years, a situation has arisen in which a base station is arranged at a position where it cannot communicate with a GPS satellite, for example, underground or indoor. In such a case, for example, the base station can obtain time information by receiving a pseudo GPS signal generated and transmitted by a GPS signal generator that generates a GPS signal in a pseudo manner. A positioning signal generator that generates a GPS signal in a pseudo manner is disclosed in, for example, Patent Document 1.

JP 2006-20151 A

  In Patent Document 1, a GPS signal generation unit included in a GPS signal generation device includes an input unit that receives an input of a signal transmitted from a CPU, and data or a GPS signal necessary for controlling the operation of the GPS signal generation unit. A pseudo signal generator that generates a pseudo GPS signal based on a memory that stores data necessary for generation, data that is input in response to a command input via the input unit, and data that is read from the memory And a positioning signal generator including an output unit for sending a GPS signal to a distributor.

  As described above, since the received GPS signal is a pseudo GPS signal in the base station that receives the pseudo GPS signal, there is a possibility that the time information including the pseudo GPS signal is slightly shifted. There is. Therefore, in a wireless communication system including a base station having inaccurate time information in this way, a communication terminal that can perform communication by a plurality of communication methods alone cannot communicate with the base station successfully. May occur.

  An object of the present invention is to provide a communication terminal and a communication method capable of reliably performing communication with a base station using a plurality of communication methods in order to prevent the above-described situation.

  In order to eliminate the disadvantages described above, the communication device of the first invention is a communication terminal that performs radio communication with a base station of a plurality of communication protocols and stands by in each communication protocol, A communication unit that performs communication, and a control unit that updates clock information. The control unit receives a first system time from a base station of a first protocol via the communication unit, and When the second system time is received from the base station of the second protocol after updating the clock information with the system time of 1, the difference between the first system time and the second system time is calculated, When the difference is equal to or smaller than a predetermined threshold, the clock information is newly updated for the second system time, and the base station of the first protocol and the second time are updated using the updated clock information. If communication with a protocol base station is established and the difference is larger than a predetermined threshold value, the clock information is not updated by the second system time, and the clock is updated at the first system time. According to the corrected timing information generated by applying the difference to the timing information calculated based on the clock information based on the first system time while maintaining communication with the base station of the first protocol. Establish communication with the base station of the protocol.

  Preferably, the communication unit is capable of hybrid standby using different frequency bands for the first protocol and the second protocol.

  Preferably, the first protocol is CDMA2000_1x and the second protocol is 1xEVDO.

  Preferably, the first system time and the second system time are based on time information generated by the base station acquiring a GPS signal from a GPS satellite or a pseudo-generated GPS signal. Time information.

  A communication method according to a second aspect of the present invention is a communication method for a communication terminal having a communication unit for performing communication control based on clock information, performing wireless communication with a base station of a plurality of communication protocols, and waiting in each communication protocol. Then, after receiving the first system time from the base station of the first protocol via the communication unit and updating the clock information with the first system time, from the base station of the second protocol When the second system time is received, a difference between the first system time and the second system time is calculated, and when the difference is not more than a predetermined threshold value, the second system time is set to the second system time. The clock information is newly updated, communication with the base station of the first protocol and the base station of the second protocol is established based on the updated clock information, and the difference is If it is larger than a certain threshold value, the clock information is not updated by the second system time, and the base station of the first protocol is updated by the clock information updated by the first system time. The communication establishment with the base station of the second protocol is performed according to the correction timing information generated by applying the difference to the timing information calculated based on the first system time.

  ADVANTAGE OF THE INVENTION According to this invention, the communication terminal and communication method which can perform communication with a base station reliably by a some communication system can be provided.

Hereinafter, a communication terminal 1 will be described as an example of an embodiment of a communication terminal of the present invention.
FIG. 1 is a diagram for explaining a communication system 100 including the communication terminal 1 of the present embodiment.
As illustrated in FIG. 1, the communication system 100 includes a communication terminal 1 and a base station 2. The base station 2 is connected to an exchange (not shown) or the like and connected to a public communication network.
For simplicity of explanation, in FIG. 1, as the communication system 100, only one communication terminal 1 and two base stations 2 (base stations 2_1x and 2_EVDO) are shown. And a base station.
In addition, the communication system 100 according to the present embodiment supports two types of communication methods, CDMA2000_1x and 1xEVDO. Base station 2_1x represents a base station that performs CDMA2000_1x communication, and base station 2_EVDO represents a base station that performs 1xEVDO communication. The communication terminal 1 is a communication terminal (hybrid terminal) capable of performing communication using either of two types of communication methods, CDMA2000_1x and 1xEVDO.

Next, the operation of the communication terminal 1 will be described.
There is a very large correlation between the two communication systems, CDMA2000_1x and 1xEVDO.
First, when waiting, the communication terminal 1 monitors the occurrence of an incoming call, that is, performs signal monitoring from the base station by paging in the CDMA2000_1x system, while the 1xEVDO signal is used to maintain a session in the 1xEVDO system. Monitor.
And in each communication system, the base station used for standby is not necessarily common. In the mutual communication system, of course, the network side is commonly managed for location registration, outgoing / incoming calls, and monitoring of the communication state, but communication between the base station and the communication terminal 1 is wireless, and the protocol is Different.
In addition, although many base stations are laid, each base station is compatible with only the CDMA2000_1x system, one supporting only the 1xEVDO system, and one supporting both the CDMA2000_1x system and the 1xEVDO system. .
Furthermore, the frequency band that can be handled by each base station may be different.
The communication terminal 1 is configured not to be restricted to using the same base station in the CDMA2000_1x method and the 1xEVDO method at the time of standby, thereby maintaining a state in which both devices are waiting as much as possible. It is configured to be able to.

Incidentally, as described above, in the communication system 100 of the present embodiment, the main processing purpose is to monitor outgoing / incoming calls in CDMA2000_1x and to maintain an EVDO session in 1xEVDO. In both CDMA2000_1x and 1xEVDO, it is necessary to periodically monitor a signal from a standby base station for communication.
For this monitoring timing, time synchronization needs to be established between the base station and the communication terminal 1, and each base station is provided with a GPS receiver or a GPS signal generator that generates a pseudo-GPS signal. Therefore, accurate time information or pseudo time information from a GPS signal is supplied to each base station.
The communication terminal 1 receives the time information from these base stations as needed, updates the internal clock information, and monitors the broadcast information addressed to the terminal from the base station in both CDMA2000_1x and 1xEVDO.

Hereinafter, in such a communication system 100, the communication terminal 1 waits for each of, for example, a base station that obtains time information by a pseudo GPS signal in the CDMA2000_1x system and a base station that obtains time information by a true GPS signal in the 1xEVDO system. Assumes that
If the clock information from the GPS signal generator is slightly different from the clock information obtained from the true GPS signal, the communication terminal cannot synchronize with either base station. This is because, in general, only one piece of clock information is held on the communication terminal side, and the clock information on the communication terminal side is overwritten with the latest acquired time information.
In general, the communication terminal 1 first adjusts its own clock information to the time information of the base station of the CDMA2000_1x system in the initial acquisition (synchronous communication with the base station) of the CDMA2000_1x system. Thereafter, the session establishment operation is also performed for the 1xEVDO system. And in this initial acquisition to 1xEVDO, it is updated to the time information of the base station of 1xEVDO system.

There are two reasons why the communication terminal 1 is configured to overwrite and update the time information acquired later.
First, as a general rule, both CDMA2000_1x and 1xEVDO networks have time information normally synchronized, and since any time information is used in common, there is only one clock information on the communication terminal side. It is enough, and it is possible to cope with it enough by updating this.
The second reason is that the area where the 1xEVDO base station is laid is smaller than the area where the CDMA2000_1x base station is laid. That is, at the time of initial acquisition to the base station of the CDMA2000_1x system, there is no base station of 1xEVDO system in the vicinity, and at this time, the initial acquisition to the base station of the 1xEVDO system cannot be performed, and after that, the base station of the 1xEVDO system It often happens that initial capture occurs. That is, since a large amount of time has elapsed since the clock information was updated in the CDMA2000_1x system, it is preferable to update the clock information to the latest time information.

However, as described above, hybrid standby may occur between the base station to which the GPS signal generator is connected and the base station having a true GPS receiver. When the time information obtained by the mutual base stations is slightly shifted, the time information obtained from the CDMA2000_1x base station is overwritten by the time information obtained from the 1xEVDO base station to be initially acquired later. Become. In such a case, the time information possessed by the communication terminal is the time information obtained from the base station of the 1xEVDO system, and therefore is different from the time information possessed by the base station of the CDMA2000_1x system. Communication with the station cannot be performed successfully.
A configuration for avoiding such a situation will be described below.

FIG. 2 shows an example of the configuration of the communication terminal 1.
FIG. 2 is a block diagram illustrating an example of the configuration of the communication terminal 1.
As illustrated in FIG. 2, the communication terminal 1 includes a communication unit 11, an operation unit 12, an audio processing unit 13, a storage unit 14, a display unit 15, a clock unit 16, and a control unit 17.

Hereinafter, the detail of each structure of the communication terminal 1 is demonstrated.
The communication unit 11 performs wireless communication with the base station 2 via an antenna or the like (not shown in FIG. 2) under the control of the control unit 17 described later. Data transmitted and received in wireless communication is, for example, voice data for voice calls, mail data, time information, and the like.
The communication unit 11 further includes a CDMA2000 — 1x communication unit 111 and a 1xEVDO communication unit 112 corresponding to each of the two types of communication methods. The communication unit 11 communicates with the base station corresponding to each communication method by each communication unit in a method according to the definition of each communication method. The communication terminal 1 can communicate with the CDMA2000_1x communication unit 111 and the 1xEVDO communication unit 112 by either of the two types of communication methods. That is, it is possible to communicate with the base station 2_1x that performs CDMA2000_1x communication and the base station 2_EVDO that performs 1xEVDO communication.
The operation unit 12 is an input device such as a numeric keypad or a cross key, and receives user input during various operations of the communication terminal 1 and transmits an operation signal indicating the input content to the control unit 17.

The audio processing unit 13 converts an audio signal input from a microphone or the like not shown in FIG. 1 into audio data, or decodes audio data acquired from the base station by the communication unit 11 into an audio signal, and a speaker (not shown). Process to output the sound from. With the processing of the voice processing unit 13, it is possible to make a voice call in the communication terminal 1.
The storage unit 14 may be a volatile memory such as a RAM (Random Access Memory) in addition to a non-volatile memory such as a storage device including a flash memory or an HDD (Hard Disk Drive). The storage unit 14 stores, for example, image data of a standby screen displayed on the display unit 15 (to be described later), a ring tone / incoming melody, an application program that operates on the communication terminal 1, and the like.

The display unit 15 is a display device such as an LCD (Liquid Crystal Display) or an organic EL (electroluminescence) display, and displays a screen related to the operation according to various operations of the communication terminal 1. For example, information on the call destination is displayed when a voice call is made, and information on the call source is displayed when a call is received.
The display unit 15 displays a clock under the control of the clock unit 16 described later. That is, for example, a clock is displayed on a standby screen or a screen for clock display.
The timepiece unit 16 is a timepiece device having a crystal resonator or the like. The clock unit 16 controls the display unit 15 to display a clock on the basis of time information obtained through communication with the base station 2 in cooperation with the control unit 17.
The control unit 17 is a central processing unit that controls the communication terminal 1 in an integrated manner. That is, the various configurations of the communication terminal 1 described above are controlled during various operations of the communication terminal 1.

Next, an example of the configuration of the base station 2 will be described.
FIG. 3 is a diagram illustrating an example of the configuration of the base station 2.
As illustrated in FIG. 3, the base station 2 includes a GPS communication unit 21, a wireless communication unit 22, a time information holding unit 23, a network connection unit 24, and a control unit 25.
The GPS communication unit 21 communicates with a GPS satellite (not shown in FIG. 1) or a pseudo GPS signal generation device that artificially generates a GPS signal, and acquires a GPS signal (pseudo GPS signal) including time information. Part.
The wireless communication unit 22 performs wireless communication with the communication terminal 1 in the communication system 100 shown in FIG. The wireless communication unit 22 uses a different communication method for wireless communication with the communication terminal 1 for each base station. That is, the base station 2_1x that performs wireless communication with the communication terminal 1 using the CDMA2000_1x scheme is the wireless communication unit 22 that supports CDMA2000_1x, and the base station 2_EVDO that performs wireless communication with the communication terminal 1 using the 1xEVDO scheme is the wireless communication that supports 1xEVDO. Each has a portion 22.

  The time information holding unit 23 is a block that holds time information included in the GPS signal (or pseudo GPS signal) acquired by the GPS communication unit 21. For each base station 2, depending on the position where the base station 2 is installed, it communicates with a GPS satellite and acquires a GPS signal, or communicates with a pseudo GPS signal generator and acquires a pseudo GPS signal, Is decided. The base station 2 obtains time information by any method and holds it in the time information holding unit 23.

The network connection unit 24 is an interface that is connected to a network-side management device such as an exchange or a location server by an optical fiber cable or the like.
The control unit 25 performs control to operate each functional unit of the base station 2.

Hereinafter, first, an operation example during communication in the communication terminal 1 capable of performing communication in a plurality of communication methods will be described.
FIG. 4 is a flowchart for explaining an operation example during communication in the communication terminal 1 capable of performing communication in a plurality of communication methods.
Step ST1:
First, the control unit 17 of the communication terminal 1 sequentially scans frequency channels in which carriers may exist, in accordance with a predetermined scan list, in order to start communication using the CDMA2000_1x method. As a result of scanning, some frequency channels (pilot channel candidates) having good reception field strength are picked up.
Next, despreading is performed on these pilot channel candidates in order from the best, and the signal wave to interference wave ratio is calculated from the obtained pilot signal, and trial is performed until sufficient strength is obtained. Here, when a sufficient signal wave-to-interference wave ratio is obtained, the process proceeds to position registration processing for the base station that transmits the pilot channel.
By the way, the processing up to this point is basically the same in both the CDMA2000_1x system and the 1xEVDO system. Therefore, the processing up to this point will be described in a simplified manner in the 1xEVDO system.
Using the CDMA2000_1x communication unit 111 of the communication unit 11, the description returns to the process related to location registration with the base station (base station 2_1x) that has transmitted the pilot channel specified by the scan process.
Step ST2:
The CDMA2000_1x communication unit 111 further performs code synchronization from the pilot channel based on the acquired pilot signal, and acquires Sync Channel Message: (1x Sync Msg) that is a synchronization signal from the base station 2_1x.

Step ST3:
The time information from the base station 2_1x is obtained from the Sync Channel Message: (1x Sync Msg) of the base station 2_1x via the CDMA2000_1x communication unit 111, and the clock information managed by the clock unit 16 and the control unit 17 is obtained at this time. To match. The time pointed to by the time information obtained from the base station 2_1x is hereinafter referred to as system time SysTime_1x.
Step ST4:
The communication unit 11 establishes synchronization in step ST3 and updates the clock information described above, and then makes a location registration request to the base station and starts waiting for communication with the base station 2_1x. Specifically, PCH (paging channel) monitoring for confirming whether or not there is an incoming call from the base station 2_1x is started. At this time, the communication unit 11 (CDMA2000_1x communication unit 111) notifies the base station 2_1x of the intermittent reception timing of the paging channel calculated based on the system time SysTime_1x. The method for calculating the intermittent reception timing of the paging channel is not particularly limited in the present embodiment. Existing technology can be used.

Step ST5:
Next, the control unit 17 starts communication using the 1xEVDO method. That is, communication with the base station 2_EVDO is attempted using the 1xEVDO communication unit 112 of the communication unit 11. Note that the process in step ST4 and the process in step ST5 are not necessarily continuous in time.
Step ST6:
After performing a scan process similar to the selection of the CDMA2000_1x acquisition candidate base station in step ST1, the 1xEVDO communication unit 112 performs Sync Channel Message: (EVDO Sync Msg) that is a synchronization signal from the identified base station 2_EVDO. To get.

Step ST7:
The time information from the base station 2_EVDO is acquired from the Sync Channel Message: (EVDO Sync Msg) of the base station 2_EVDO via the 1xEVDO communication unit 112. The time indicated by the time information obtained from the base station 2_EVDO is hereinafter referred to as a system time SysTime_EVDO.
Step ST8:
The control unit 17 calculates a difference between the system time SysTime_1x obtained in step ST3 and the system time SysTime_EVDO obtained in step ST7, and determines whether or not the difference is greater than a predetermined threshold value THcorrect. That is, the control unit 17 determines that the time information obtained from the base station 2_1x of the CDMA2000_1x method and the time information obtained from the base station 2_EVDO of the 1xEVDO method are larger than errors assumed in advance due to a difference in communication path or noise. Determine whether it is larger. Therefore, the predetermined threshold value THcorrect is an arbitrary value determined empirically so as to be larger than the error.
In this step, if the difference between the system time SysTime_1x and the system time SysTime_EVDO is larger than THcorrect, the process proceeds to step ST9, and if not, the process proceeds to step ST11.

Step ST9:
When the difference between the system time SysTime_1x and the system time SysTime_EVDO is larger than THcorrect, the control unit 17 does not update the clock information with the SysTime_EVDO acquired in step ST7.
On the other hand, it is necessary to intermittently receive broadcast information from the base station 2_EVDO for reasons such as maintaining session establishment even when there is no communication.
In step ST3, based on the system time SysTime_1x applied to the clock information managed by the control unit 17, the timing for intermittent reception of EVDO broadcast information is calculated.
Step ST10:
The control unit 17 adds <(SysTime_1x)-(SysTime_EVDO)>, which is a difference in system time, to the EVDO intermittent reception timing calculated in step ST9.
That is, assuming that the EVDO intermittent reception timing calculated in step ST9 is T_EVDO_interval, the intermittent reception timing is calculated based on the system time SysTime_1x notified from the base station 2_1x of the CDMA2000_1x system. However, since it is known in Step ST8 that there is a difference larger than THcorrect between SysTime_1x and SysTime_EVDO, T_EVDO_interval is different from the original intermittent reception timing of the 1xEVDO system.
The control unit 17 corrects this deviation with the calculated system time difference, and calculates the corrected intermittent reception timing T_EVDO_intervalTemp.
As described above, T_EVDO_intervalTemp = ((T_EVDO_interval) + (SysTime_1x-SysTime_EVDO))).
As a result, communication with the base station 2_EVDO of the 1xEVDO system is established, and corrected intermittent reception timing T_EVDO_intervalTemp for waiting for the paging channel is obtained.

Step ST11:
When the difference between the system time SysTime_1x and the system time SysTime_EVDO is equal to or less than THcorrect, that is, when the system times in the base station 2_1x and the base station 2_EVDO are equal, the system time SysTime_EVDO newly obtained in step ST7 is applied to the clock unit 16. .
Step ST12:
Based on the system time SysTime_EVDO applied to the clock information managed by the clock unit 16 and the control unit 17 in step ST11 in order to establish communication by notifying the base station 2_EVDO, the control unit 17 Intermittent reception timing of broadcast information is calculated. The method for calculating the intermittent reception timing of the broadcast information is not particularly limited in the present invention.

Step ST13:
The control unit 17 notifies the base station 2_EVDO of the intermittent reception timing of the broadcast information calculated in step ST10 or step ST12 via the communication unit 11, makes a session establishment request in the EVDO scheme, and establishes communication.
Step ST14:
Thereafter, a session by the EVDO method is established.

As described above, in the communication terminal 1 according to the present embodiment, when the difference between the system time SysTime_1x and the system time SysTime_EVDO is larger than the predetermined threshold value THcorrect, the system time SysTime_1x previously applied to the clock unit 16 is used. And the newly acquired system time SysTime_EVDO is not applied to the clock unit 16.
Here, for example, after establishing communication with the base station 2_EVDO and entering the EVDO standby state, the communication terminal 1 again captures the CDMA2000_1x base station 2_1x and enters the CDMA2000_1x standby state. Think. If the system time SysTime_1x is not left as it is and the SysTime_EVDO is applied to the system time of the communication terminal 1 as in the operation example illustrated in FIG. 4 described above, the intermittent reception timing for establishing communication with the base station 2_1x Is calculated based on SysTime_EVDO. Here, since SysTime_EVDO is greatly deviated from SysTime_1x by a predetermined threshold value THcorrect, the CDMA2000_1x intermittent reception timing is deviated, and communication of the CDMA2000_1x method cannot be established successfully.
Therefore, in the operation example shown in FIG. 4 described above, when the difference between the system time SysTime_1x and the system time SysTime_EVDO is larger than the predetermined threshold value THcorrect, even if the system time SysTime_EVDO is notified from the base station 2_EVDO, Is not applied to the timepiece unit 16, so that the situation described above can be avoided.

  In the operation example shown in FIG. 4 described above, since the system time used when calculating the intermittent reception timing notified to the base station 2_EVDO is SysTime_1x, it is necessary to correct this. Therefore, the control unit 17 calculates the corrected intermittent reception timing T_EVDO_intervalTm by T_EVDO_interval + (SysTime_1x-SysTime_EVDO) based on the 1xEVDO intermittent reception timing T_EVDO_interval calculated using SysTime_1x. As a result, the intermittent reception timing used when establishing communication with the base station 2_EVDO is also corrected in accordance with the system time SysTime_EVDO, thereby avoiding a situation where the intermittent reception timing is shifted and communication cannot be performed well when establishing 1xEVDO communication. it can.

Hereinafter, the effect in the operation example at the time of communication in the communication terminal 1 capable of performing communication in a plurality of communication methods as described in FIG. 4 will be described.
FIG. 5 is a diagram illustrating a specific example of a communication system 101 having a communication terminal 1 capable of performing communication in a plurality of communication schemes and a plurality of base stations having different communication schemes.
In the specific example shown in FIG. 5, the communication system 101 includes one communication terminal 1, base stations 2_1x and 2_EVDO of BandClass6, and base stations 2_1x and 2_EVDO of BandClass3. BandClass refers to a frequency band for communication, BandClass6 means a frequency band of 2 GHz, and BandClass3 means a new 800 MHz frequency band.

In the specific example of the communication system 101 shown in FIG. 5, it is assumed that the base stations 2_1x and 2_EVDO of the BandClass 3 are disposed in a closed space, that is, for example, underground or indoor. Therefore, since the base stations 2_1x and 2_EVDO of the BandClass 3 cannot directly communicate with the GPS satellite, the pseudo GPS signal is acquired from the pseudo GPS signal generation device and time information is obtained.
On the other hand, the base stations 2_1x and 2_EVDO of BandClass 6 are assumed to be arranged in an open space. Therefore, the base stations 2_1x and 2_EVDO of the BandClass 6 can obtain accurate time information by acquiring GPS signals from GPS satellites.
Here, the time information included in the pseudo GPS signal generated by the pseudo GPS signal generation device is not necessarily accurate, and is assumed to have a deviation of, for example, about ± 100 ms at the maximum from the accurate time information included in the GPS signal.

In the specific example of the communication system 101 as shown in FIG. 5, consider a case where the communication terminal 1 starts waiting.
As in FIG. 4, the communication terminal 1 first acquires the BandClass6 system and receives 1x Sync Msg from the base station 2_1x of the BandClass6 in the CDMA2000_1x system. At this time, the time information notified from the base class 2_1x of the BandClass 6 is accurate time information obtained from the GPS satellite as described above. Here, the accurate time information obtained from the GPS satellite is hereinafter referred to as SysTimeReal. That is, the time information obtained by the communication terminal 1 here is SysTimeReal_1x.
Now, it is assumed that the communication terminal 1 performs processing at the start of communication such as initial acquisition with the base station 2_1x of the BandClass 6 based on SysTimeReal_1x and starts standby in the CDMA2000_1x system.

Next, the communication terminal 1 tries communication using the 1xEVDO method.
Here, it is assumed that the communication terminal 1 cannot capture the BandClass6 system in the 1xEVDO system. In this case, the communication terminal 1 tries to acquire the BandClass3 system in the 1xEVDO system. As a result, it is assumed that the communication terminal 1 has received EVDO Sync Msg from the base station 2_EVDO of BandClass 3. At this time, the time information notified from the base class 2_EVDO of the BandClass 3 is based on the pseudo GPS information obtained from the pseudo GPS generation device as described above. Here, the time information based on the pseudo GPS information obtained from the pseudo GPS generation device is hereinafter referred to as SysTimeSim. That is, the time information obtained by the communication terminal 1 here is SysTimeSim_EVDO.

  Here, in the communication terminal 1, as shown in the operation example in FIG. 4, the control unit 17 calculates the difference between the SysTimeReal_1x and the SisTimeSim_EVDO, and determines whether the difference is larger than a predetermined threshold value. Become. Here, the predetermined threshold value THcorrect is set to 1 ms (difference in error level), for example. As described above, since the SysTimeReal_1x and the SysTimeSim_EVDO have a maximum difference of ± 100 ms, the control unit 17 determines that the difference between the SysTimeReal_1x and the SysTimeSim_EVDO is larger than the predetermined threshold value THcorrect. Then, the control unit 17 does not apply the system time SysTimeSim_EVDO notified from the base station 2_EVDO of BandClass 3 to the clock unit 16. That is, the system time currently applied to the communication terminal 1 remains SysTimeReal_1x.

  Here, the control part 17 calculates the intermittent reception timing for establishing communication with base station 2_EVDO of BandClass3. At this time, EVDO intermittent reception timing T_EVDO_interval is calculated using the current system time SysTimeReal_1x, and is corrected based on the difference between SysTimeReal_1x and SysTimeSim_EVDO. Specifically, as in the operation example shown in FIG. 4, the corrected intermittent reception timing T_EVDO_intervalTemp equivalent to the intermittent reception timing calculated using the 1xEVDO system time SysTimeSim_EVDO is calculated by T_EVDO_interval + (SysTime_1x-SysTime_EVDO).

  If, in the communication terminal 1, the control unit 17 has applied the system time SysTimeSim_EVDO notified from the base station 2_EVDO of the BandClass3 to the clock unit 16, then communication with the base station 2_1x of the BandClass6 is reestablished. In this case, the intermittent reception timing notified to the base station 2_1x is calculated on the basis of SysTimeSim_EVDO. However, as described above, there is a deviation of 100 ms at maximum between SysTimeReal_1x and SysTimeSim_EVDO necessary for generating the correct intermittent reception timing to be notified to the base station 2_1x. Therefore, the calculated intermittent reception timing is a correct value. It will not be. As a result, the establishment of communication between the communication terminal 1 and the base class 2_1x of the BandClass 6 is not successfully established, and a situation in which communication cannot be performed occurs. However, according to the communication terminal 1 of the present embodiment, such a situation can be avoided as described above.

As described above, according to the communication terminal 1 of the embodiment of the present invention, when the communication of the CDMA2000_1x system is first established and enters the standby state, and then the communication of the 1xEVDO system is established and enters the standby state, the SysTime_1x And SysTime_EVDO are larger than a predetermined threshold value THcorrect, even if the SysTime_EVDO is acquired from the base station 2_EVDO when trying to establish communication in the 1xEVDO method, it is applied to the clock unit 16 when establishing communication in the CDMA2000_1x method. The previously acquired SysTime — 1x is left as it is, and the newly acquired SysTime — EVDO is not applied to the clock unit 16.
For this reason, for example, when communication with the base station 2_EVDO is established, and after entering the EVDO standby state, the communication terminal 1 captures the CDMA2000_1x base station 2_1x again and enters the CDMA2000_1x standby state. Therefore, it is possible to avoid a situation in which the CDMA2000_1x intermittent reception timing is shifted and the communication of the CDMA2000_1x method cannot be established successfully.

  Further, according to the communication terminal 1 of the embodiment of the present invention, since the system time used when calculating the intermittent reception timing notified to the base station 2_EVDO is SysTime_1x, the 1xEVDO intermittent reception timing calculated using SysTime_1x. Based on T_EVDO_interval, the corrected intermittent reception timing T_EVDO_intervalTemp is calculated by T_EVDO_interval + (SysTime_1x-SysTime_EVDO). As a result, the intermittent reception timing used when establishing communication with the base station 2_EVDO is also corrected in accordance with the system time SysTime_EVDO, thereby avoiding a situation where the intermittent reception timing is shifted and communication cannot be performed well when establishing 1xEVDO communication. it can.

The present invention is not limited to the embodiment described above.
That is, when implementing the present invention, various modifications and alternatives may be made to the components of the above-described embodiments within the technical scope of the present invention or an equivalent scope thereof.
In the embodiment described above, the communication terminal 1 is assumed to be a mobile phone, but the present invention is not limited to this. For example, another communication device such as a PDA (Personal Digital Assistant) may be used.
In the above-described embodiment, each base station is described as an example of the wireless communication unit 22 that supports only CDMA2000_1x and one that supports only 1xEVDO. However, the present invention is not limited to this. It is not limited. The base station may support both communication methods. Even if the base station waiting for CDMA2000_1x is a base station that also supports the 1xEVDO system, if there is another base station with a better communication environment in the 1xEVDO system, the base station It is also conceivable to perform 1xEVDO system standby. Even in such a case, the same effect can be obtained by performing the same processing as in the above-described embodiment.

FIG. 1 is a diagram for explaining a communication system including a communication terminal according to the present embodiment. FIG. 2 is a block diagram illustrating an example of the configuration of the communication terminal. FIG. 3 is a block diagram showing an example of the configuration of the base station. FIG. 4 is a flowchart for explaining an operation example during communication in a communication terminal capable of performing communication in a plurality of communication methods. FIG. 5 is a diagram illustrating a specific example of a communication system having a communication terminal capable of performing communication in a plurality of communication schemes and a plurality of base stations having different communication schemes.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 100,101 ... Communication system, 1 ... Communication terminal, 11 ... Communication part, 111 ... CDMA2000_1x communication part, 112 ... 1xEVDO communication part, 12 ... Operation part, 13 ... Voice processing part, 14 ... Memory | storage part, 15 ... Display part, DESCRIPTION OF SYMBOLS 16 ... Clock part, 17 ... Control part, 2 ... Base station, 21 ... Communication part, 22 ... Wireless communication part, 23 ... Time information holding part

Claims (5)

A communication terminal that performs wireless communication with a base station of a plurality of communication protocols and stands by in each communication protocol,
A communication unit for communicating with the base station;
A control unit for updating the clock information;
Have
The control unit receives the first system time from the base station of the first protocol via the communication unit, updates the clock information with the first system time, and then the base station of the second protocol When the second system time is received from, the difference between the first system time and the second system time is calculated,
If the difference is equal to or smaller than a predetermined threshold, the clock information is newly updated for the second system time, and the base station of the first protocol and the second are updated using the updated clock information. Establish communication with the base station of the protocol
If the difference is larger than a predetermined threshold value, the clock information is not updated by the second system time, and communication with the base station of the first protocol is performed at the first system time. Maintaining communication with the base station of the second protocol according to the correction timing information generated by applying the difference to the timing information calculated based on the clock information based on the first system time A communication terminal characterized by that. The communication terminal according to claim 1, wherein the communication unit is capable of hybrid standby using different frequency bands for the first protocol and the second protocol. The first protocol is CDMA2000_1x,
The communication terminal according to claim 1 or 2, wherein the second protocol is 1xEVDO. The first system time and the second system time are time information generated when the base station acquires a GPS signal from a GPS satellite, or time information based on a pseudo-generated GPS signal. It is either. The communication terminal as described in any one of Claim 1 to 3 characterized by the above-mentioned. A communication method for a communication terminal having a communication unit that performs communication control based on clock information, performs wireless communication with a base station of a plurality of communication protocols, and waits in each communication protocol,
After receiving the first system time from the base station of the first protocol via the communication unit and updating the clock information with the first system time, the second system from the base station of the second protocol When the time is received, the difference between the first system time and the second system time is calculated,
If the difference is less than or equal to a predetermined threshold, the clock information is newly updated for the second system time, and the base station and the second of the first protocol are updated based on the updated clock information. Establish communication with the base station of the protocol
When the difference is larger than a predetermined threshold, the clock information is not updated by the second system time, and the first protocol is updated by the clock information updated at the first system time. Establishing communication with the base station of the second protocol according to the corrected timing information generated by applying the difference to the timing information calculated based on the first system time while maintaining communication with the base station The communication method characterized by performing.

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