KR20050071646A - Dual mode system and dual mode radio terminal - Google Patents

Abstract

A base station in a first mobile communication mode communicates in a terminal with the first mobile communication mode and transmits a radio signal in a second mobile communication mode. A base station in the second mobile communication mode communicates with a terminal in the second mobile communication mode and transmits a radio signal in the first mobile communication mode. A first device of a dual mode portable terminal communicates, in the first mobile communication mode, with a base station in the first mobile communication mode and receives a radio signal of the first mobile communication mode transmitted from the base station in the second mobile communication mode and judges from the radio signal whether or not the second mobile communication mode base station is present. A second device of the dual mode portable terminal judge from the radio signal whether or not the first mobile communication mode base station is present.

Description

Dual mode system and dual mode wireless terminal {DUAL MODE SYSTEM AND DUAL MODE RADIO TERMINAL}

The present invention relates to a dual mode system and a dual mode wireless terminal in mobile communication, and in particular, a dual mode wireless terminal capable of communicating in both mobile communication modes under a dual mode environment of a first mobile communication mode and a second mobile communication mode. And a dual mode system for communicating using the terminal.

The present invention is used in a dual mode environment in which a W-CDMA radio system coexists with respect to an existing radio system Global System for Mobile Communication (GSM) or Personal Digital Cellular Telecommunication System (PDC) in Europe and Japan.

In the dual mode environment, the portable terminal uses any wireless system (communication mode) of W-CDMA or GSM (or PDC). In this case, the terminal needs to know whether the base stations of both communication modes exist in the vicinity in preparation for handover between base stations of different communication modes, and thus the information of neighboring base stations also exists for communication modes that are not regularly used. You have to collect it. At that time, the terminal deliberately activates the communication unit according to the unused communication mode, and collects information on whether or not the base station of the unused communication mode exists in the vicinity. On the other hand, the presence information of the presence of the neighboring base station in the communication mode in use is made regularly.

24 is a diagram for explaining a conventional operation example. In the normal state of Fig. 24A, the dual mode terminal MS communicates with the base station BTS1 of W-CDMA using the communication unit 1 of W-CDMA. At this time, the power supply of the other GSM communication unit 2 is turned off. However, the GSM radio wave 4 from the GSM base station BTS2 is arriving. Here, the CPU (or DSP) 3 periodically outputs an instruction PON of power ON to the GSM communication unit 2 of the terminal MS, as shown in FIG. Require measurement to be collected (ambient information collection). In this manner, when collecting the surrounding information, it is necessary to start the communication unit in an unused communication mode and collect the surrounding information as in the level measurement of radio waves.

In the wireless portable terminal MS, at the same time miniaturization, how to increase continuous calls and continuous standby time with a small battery has become an important problem. In the above conventional method, the power supply of the communication unit in the unused communication mode is periodically turned on, and information of the neighboring base stations in the unused communication mode is periodically collected. That is, in the conventional method, since a communication unit in a communication mode other than the communication mode in use must be periodically started, power consumption is consumed accordingly, which leads to a problem that the battery consumption of the terminal is fast and continuous calls and standby time are reduced.

In the prior art, there is a mobile telephone system for quickly registering a position with respect to another mobile telephone system GSM when the mobile telephone system PHS in use is outside the service area (Patent Document 1). In this case, immediately after the terminal is powered on, all the control channels used in the GSM are searched for and stored, and the position registration is processed using the stored control channels when the PHS is out of the area. In addition, when normal communication cannot be performed through all stored control channels, the entire control channel used in GSM is searched and stored. However, Patent Document 1 does not relate to soft handover in which a wireless system switches from one base station to another base station during communication in an instantaneous disconnection and continues communication. Further, Patent Document 1 does not search for neighboring cells during movement in a dual mode system for handover between base stations of different radio systems. Therefore, patent document 1 cannot solve the said problem.

[Patent Document 1: Japanese Patent Application Laid-Open No. 11-298964]

In view of the above, an object of the present invention is to prepare a handover between base stations of different mobile communication modes in a dual mode environment so that the base station of each mobile communication mode can be recognized with low power consumption. It is.

Another object of the present invention is that, in a terminal, only a base station in each mobile communication mode is turned on while a device in a mobile communication mode in operation is turned on and a power source in a mobile communication mode is turned off. It is to be able to recognize whether or not.

FIG. 1 is a diagram illustrating a principle for recognizing the existence of a neighboring GSM base station while the terminal MS communicates with a W-CDMA base station.

FIG. 2 is a diagram illustrating a principle for recognizing the existence of a neighboring W-CDMA base station while the terminal MS communicates with the GSM base station.

3 is a diagram illustrating a downlink signal frame format from a W-CDMA base station to a mobile station and a downlink channel related to the present invention.

4 is a diagram for explaining P-SCH and S-SCH.

FIG. 5 is a diagram showing a correspondence table between the patterns Cs ^{i, 0} , Cs ^{i, 1} , Cs ^{i, 2} ,..., Cs ^{i, 14} of 15 secondary scramble codes SSC and a group number.

6 is a diagram illustrating a W-CDMA transmitter of a GSM base station BTS2.

7 is a diagram illustrating a processing flow for identifying whether a neighboring GSM base station exists by always transmitting a P-SCH from the GSM base station.

8 is a diagram illustrating a first processing flow for identifying whether a neighboring GSM base station exists by always transmitting P-SCH and S-SCH from the GSM base station.

9 is a diagram illustrating a second processing flow for identifying whether a neighboring GSM base station exists by always transmitting P-SCH and S-SCH from the GSM base station.

Fig. 10 is a correspondence table of group numbers and network types of scramble codes.

11 is a diagram illustrating an example of a neighbor cell detection table.

12 is a diagram illustrating a processing flow for identifying whether a neighboring GSM base station exists by always transmitting P-SCH, S-SCH, and CPICH from the GSM base station.

13 is a correspondence table of scramble codes and network types.

14 is a diagram illustrating an example of a neighbor cell detection table.

FIG. 15 is a diagram illustrating a process flow for identifying whether a neighboring GSM base station exists by always transmitting P-SCH, S-SCH, CPICH, and BCH from the GSM base station.

16 is a diagram illustrating a downlink signal format of a GSM signal of a predetermined frequency.

FIG. 17 shows a processing flow for identifying the presence of a neighboring GSM base station by always transmitting the SCH of the predetermined synchronization burst SB and the FCCH of the predetermined frequency correction burst FB from the W-CDMA base station at the predetermined frequency F1. Drawing.

 FIG. 18 is a diagram illustrating a processing flow of transmitting a SCH, FCCH, BCCH from a W-CDMA base station to identify the presence of a neighboring GSM base station.

FIG. 19 is a diagram illustrating a case where the dual mode portable terminal MS performs handover by movement while communicating with the W-CDMA base station BTS1, and the dual mode portable terminal MS is a GSM base station (FIG. It is a figure (b) explaining the case where handover is carried out by movement while communicating with BTS2).

20 is a diagram for explaining the case where the GSM base station starts to transmit the W-CDMA radio signal when receiving the W-CDMA radio signal from the dual mode portable terminal (MS).

FIG. 21 is a view for explaining the case where the W-CDMA base station starts transmitting the GSM radio signal when receiving the GSM radio signal from the dual mode portable terminal (MS).

Fig. 22 is a diagram for explaining the procedure when the dual mode portable terminal MS searches for neighboring cells while communicating with the W-CDMA base station BTS1.

23 is a flowchart for explaining the operation of the dual-mode portable terminal.

24 is a diagram for explaining a conventional operation example.

The present invention provides a first communication method capable of communicating in first and second mobile communication modes, respectively, in a dual mode environment of a first mobile communication mode (for example, W-CDMA) and a second mobile communication mode (for example, GSM or PDC). And a dual mode system for communicating using a terminal having a second device. The base station of the first mobile communication mode communicates with the terminal in the first mobile communication mode and simultaneously transmits a radio signal in the second mobile communication mode, and the base station of the second mobile communication mode communicates with the terminal in the second mobile communication mode By transmitting a radio signal in the first mobile communication mode, the first device of the terminal communicates with the base station of the first mobile communication mode in the first mobile communication mode, and at the same time, the first mobile transmitted from the base station of the second mobile communication mode. Receiving a radio signal in a communication mode, it is determined whether the base station of the second mobile communication mode is present based on the radio signal, the second device of the terminal in the second mobile communication mode and the base station of the second mobile communication mode And at the same time as receiving a radio signal of the second mobile communication mode transmitted from the base station of the first mobile communication mode, and based on the radio signal, the first mobile communication. The existence of the base station in the new mode is determined.

That is, when the terminal operates in the first mobile communication mode (W-CDMA), the base station of the second mobile communication mode (GSM / PDC) transmits a radio signal recognizable in the first mobile communication mode. Receiving a radio signal to determine the presence of the base station in the second mobile communication mode. In addition, when the terminal operates in the second mobile communication mode (GSM / PDC), the base station (W-CDMA) of the first mobile communication mode transmits a radio signal recognizable in the second mobile communication mode. Receiving a radio signal to determine the presence of the base station in the second mobile communication mode.

A second aspect of the present invention is a dual mode wireless terminal capable of communicating in first and second mobile communication modes, respectively, in a dual mode environment of a first mobile communication mode and a second mobile communication mode. The dual mode wireless terminal has first and second devices for communicating in first and second mobile communication modes, respectively, and the first device communicates with a base station in a first mobile communication mode in a first mobile communication mode, Receiving a radio signal of the first mobile communication mode transmitted from the base station of the second mobile communication mode, and determines the presence of the base station of the second mobile communication mode based on the radio signal, the second device is a second mobile Communicate with the base station of the second mobile communication mode in the communication mode, and receive a wireless signal of the second mobile communication mode transmitted from the base station of the first mobile communication mode, and based on the wireless signal, Determine whether the base station exists.

According to the dual mode system and the dual mode wireless terminal, the presence of neighboring base stations in each mobile communication mode can be recognized with low power consumption in preparation for handover between base stations in other mobile communication modes.

Further, according to the present invention, only the device according to the mobile communication mode in operation is turned on and the device according to the other mobile communication mode is turned off while recognizing whether each mobile communication mode base station is present in the vicinity. As a result, power consumption can be reduced, and battery life can be extended.

(A) Outline of the present invention

The present invention provides a dual mode system using a terminal capable of using both systems of W-CDMA and GSM / PDC in a dual mode environment of W-CDMA and GSM / PDC, wherein each base station recognizes each other's system. It is an object to transmit a radio signal and to collect information of neighboring cells without starting up one system even if either system is used by the terminal. Accordingly, according to the present invention, the terminal can recognize each other's cell information (base station presence information) without activating both systems. Therefore, in order to collect cell information, another system can be started and handover to the required system can be performed when necessary without excessive consumption of current.

FIG. 1 is a diagram illustrating a principle for recognizing the presence or absence of a neighboring GSM base station while the W-CDMA device 11 in the dual mode portable terminal MS communicates with the W-CDMA base station BTS1. In FIG. 1, the base station BTS1 of W-CDMA serves W-CDMA using radio signal 1. FIG. The base station (BTS2) of GSM serves the GSM using radio signal 2, but transmits radio signal 3 for W-CDMA in addition to this signal. That is, the GSM transceiver 21 of the GSM base station BTS2 serves the GSM service using the radio signal 2 under the control of the control unit (CPU) 23, and the W-CDMA transmitter 22 is the W-CDMA. The dragon radio signal 3 is transmitted. Wireless signal 3 is a broadcast signal for W-CDMA that is always transmitted.

Under this environment, the dual mode portable terminal MS communicates with the base station BTS1 of W-CDMA using a first device (W-CDMA device) 11 capable of communicating with W-CDMA. On the other hand, the second device (GSM device) 12 capable of communicating with GSM is in a power off state. At this time, the W-CDMA apparatus 11 also performs processing (cell search) for periodically searching for another base station (BTS) in accordance with an instruction from the control unit (CPU or DSP) 13. If the W-CDMA radio wave (wireless signal 3) is being transmitted from the GSM base station BTS2, the W-CDMA device 11 of the terminal MS determines that the base station BTS exists, and the base station (BTS) is determined from the received signal. Specific processing of the BTS). Since the radio signal for W-CDMA originally includes a code for identifying a base station (BTS), the W-CDMA device 11 recognizes the existence of the GSM BTS by comparing it with a code of a previously registered GSM BTS. can do. That is, the presence of the BTS for GSM can be recognized while the power supply of the GSM device 12 is turned off.

FIG. 2 is a diagram illustrating a principle for recognizing the presence or absence of a neighboring W-CDMA base station while the GSM device 12 in a dual mode portable terminal MS communicates with the GSM base station BTS2. In FIG. 2, the GSM base station BTS2 serves as GSM using radio signal 1. Although the base station BTS1 of W-CDMA serves W-CDMA using radio signal 2, it transmits radio signal 3 for GSM in addition to this signal. That is, the W-CDMA transceiver 31 of the W-CDMA base station BTS1 serves W-CDMA using the radio signal 2 under the control of the control unit (CPU) 33, and the GSM transmitter 32 Transmits a radio signal 3 for GSM. Radio signal 3 is a broadcast signal for always transmitting GSM.

In this environment, the dual mode portable terminal MS is using the GSM device 12 to communicate with the base station BTS2 of GSM. On the other hand, the W-CDMA device 11 is in a power off state. At this time, the GSM apparatus 12 also performs a process of periodically searching for another base station (BTS) in accordance with an instruction from the control unit (CPU or DSP) 13. If the radio wave (wireless signal 3) of GSM is being transmitted from the W-CDMA base station BTS1, the GSM device 12 of the terminal MS determines that the base station BTS exists, and the base station BTS is determined from the received signal. Do a specific treatment of. Since the radio signal for W-CDMA originally includes a synchronization pattern for identifying a base station (BTS), the GSM device 12 uses the synchronization pattern of the W-CDMA BTS registered in advance, so that the base station for W-CDMA is used. (BTS) can recognize the presence. That is, the presence of the W-CDMA base station (BTS) can be recognized with the power supply of the W-CDMA device 11 turned off.

(B) W-CDMA signal format

3 is a diagram illustrating a downlink signal format from a W-CDMA base station to a mobile station and a downlink channel related to the present invention. One frame is 10 msec and is composed of 15 slots (S0 to S14).

The primary synchronization channel (P-SCH) is used for slot synchronization with a cell search channel. In each base station, this P-SCH is spread with a preset primary scramble code (PSC) of 256 chips in length, and is arranged at the head 66.7 µsec of each slot. The PSC is the same at all base stations.

Secondary synchronization channel (S-SCH) is a channel for establishing the frame synchronization for the base station and the mobile station to identify to which scramble code group the base station (cell) belongs. The S-SCH is spread with a 256 chip length secondary scramble code (SSC) and is placed at the leading 66.7 μsec in every slot. As the base station code, 512 scrambled codes SC are prepared, and these are divided into 64 groups of 8 units each. After identifying which group the base station code belongs to, the base station code can be identified by correlating the received signal with the eight scramble codes belonging to the group.

As shown in Fig. 4, the pattern of 15 SSCs (Cs ^{i, 0} , Cs ^{i, 1} , Cs ^{i, 2} , ... Cs ^{i, 14} ) inserted at the beginning of one frame of 15 slots Correspondence is previously supported as shown in FIG. Accordingly, the terminal may identify a group of base station codes according to which code pattern the base station is transmitting.

 In FIG. 2, one primary common control channel (PCCPCH) exists in each base station as a downlink common channel and is used to transmit a BCH (notification information). The BCH includes all the information about the base station, and also includes type information such as whether the base station is a base station for W-CDMA or a base station for GSM.

The common pilot channel (CPICH) is a downlink common channel and there is one in each cell. The CPICH is spread to the base station code, and the terminal MS can identify the base station code by calculating a correlation between each of the eight scramble codes of the identified group and the common pilot channel CPICH.

The W-CDMA transceiver 31 (FIG. 2) of the W-CDMA base station BTS1 has all the equipment for executing W-CDMA communication. On the other hand, the W-CDMA transmitter 22 (FIG. 1) of the GSM base station BTS2 spreads the respective channels with a predetermined code by using the multipliers 41 to 44 as shown in FIG. Synthesis | combined by 45 has a structure which transmits a synthesized signal via the wireless transmission part which is not shown in figure.

(C) process of identifying presence of neighboring GSM base station

(a) In case of transmitting P-SCH from GSM base station

7 is a diagram illustrating a process flow for identifying whether a neighboring GSM base station exists by always transmitting a P-SCH of W-CDMA from a GSM base station. However, the primary scramble code (PSC) in which the W-CDMA base station spreads the P-SCH is different from the secondary scramble code (PSC) in which the GSM base station spreads the P-SCH. The PSC of the GSM base station is called Gp.

The mobile station (dual mode portable terminal) MS is in communication with the W-CDMA base station BTS1 in the W-CDMA mode (see FIG. 1), the W-CDMA device 11 is powered on, and the GSM device 12 is powered. It is turned off (step 101).

The W-CDMA device 11 periodically searches for neighbor base stations, calculates a correlation between the code Gp and the received signal, and checks whether correlation has been made (slot synchronization has been established) (step 102). If correlation is found, it is determined that there is no GSM base station (step 103), and if correlation is determined, it is determined that there is a GSM base station (step 104), and the process returns to the beginning.

On the other hand, in step 104, the reception level may be measured to determine that there is a GSM base station only when the reception level is greater than or equal to the set value.

(b) In case of transmitting P-SCH and S-SCH from GSM base station

8 to 9 are diagrams showing a processing flow for identifying the presence or absence of a neighboring GSM base station by always transmitting P-SCH and S-SCH of W-CDMA from the GSM base station. On the other hand, the spreading code (PSC) of the P-SCH transmitted by the GSM base station is the same as the spreading code (PSC) of the P-SCH transmitted by the W-CDMA base station. Further, the group number of the scramble code used by the W-CDMA base station and the group number of the scramble code used by the GSM base station are divided as shown in FIG. 10, and the W-CDMA apparatus 11 maintains this table. have. That is, the group numbers 1 to 32 are called scramble code groups used by the W-CDMA base station, and the number loops 33 to 64 are called scramble code groups used by the GSM base station.

The dual mode portable terminal (mobile station) MS is in communication with the W-CDMA base station BTS1 in the W-CDMA mode (see FIG. 1), the W-CDMA device 11 is powered on, and the GSM device 12 is powered. It is turned off. In this state, the W-CDMA device 11 periodically searches for neighboring base stations according to the instruction from the control unit 13 (step 201), and correlates the known primary scramble code (PSC) with the received signal. The operation checks to see if correlation has been taken (slot synchronization has been established) (step 202). If no correlation is taken, cell search continues.

If correlation is taken, it is assumed that there is a cell, and the neighbor cell detection table is updated (step 203). That is, as shown in FIG. 9, the scramble code group of the neighbor base station is identified using the S-SCH (step 203a). Subsequently, a reception level is detected for each identified scramble code group, and it is determined whether the reception level is greater or smaller than a set level (step 203b), and if it is small, it is regarded as being deleted (step 203c). It is assumed that group number / receive level / network type and the like are registered (step 203d). When the above processing is terminated for the entire scramble code group identified in step 203a, the neighbor cell detection table is updated based on the determination result of steps 203c and 203d (step 203e). 11 shows an example of a neighbor cell detection table, where three base stations exist at present, and each group number, detection level (receive level), and network type (indicating whether the base station is a W-CDMA base station or a GSM base station) are shown. Is recorded.

In the above, the case where the terminal is in communication has been described, but when the power is turned on, it is as follows. In other words, immediately after the power is turned on, the terminal MS searches for a cell, creates a neighboring cell detection table, registers a position, and shifts to an idle state (standby state).

The terminal MS measures the reception level of the neighbor base station during the idle state and communication, and updates the neighbor cell detection table described above (step 204) to reduce the reception level from the base station during the communication and the reception level from the neighbor base station. It is checked whether there has been an increase (the occurrence of an event) (step 205). Upon detecting the occurrence of the event, the event is notified to the communicating base station (BTS) (step 206). The event is generated when the level detected by the terminal MS exceeds the threshold value from the threshold information of the level provided from the base station BTS notified by the BCCH during communication and notified by the DCCH during communication.

If there is a change request of the standby cell or communication cell from the base station BTS (step 207), the terminal MS shifts to the cell designated by the base station BTS under the control of the control unit 13. At the time of transition, the control unit 13 determines whether the transition destination cell is a W-CDMA network or a GSM network (step 208), and if it is a W-CDMA network, updates or handovers an existing cell (step 209). On the other hand, if the transition destination cell is a GSM network, the control unit 13 activates the GSM device 12 (step 210), and then checks whether the terminal MS is in communication (step 211), and if so, to the GSM base station. A handover for handover is processed (step 212), and a cell change is processed if not in communication (step 213).

(c) In case of transmitting P-SCH, S-SCH, CPICH from GSM base station

12 is a diagram illustrating a processing flow for identifying the presence or absence of a neighboring GSM base station by always transmitting P-SCH, S-SCH, and CPICH of W-CDMA from the GSM base station.

On the other hand, the spreading code (PSC) of the P-SCH transmitted by the GSM base station is the same as the spreading code (PSC) of the P-SCH transmitted by the W-CDMA base station. In addition, the scramble code used by the W-CDMA base station and the scramble code used by the GSM base station are divided as shown in FIG. 13, and the W-CDMA device 11 maintains this table. That is, scramble codes 0 to n are scramble codes used by the W-CDMA base station, and scramble codes (n + 1) to 511 are called scramble codes used by the GSM base station.

The dual mode portable terminal MS is in the W-CDMA mode in communication with the W-CDMA base station BTS1 or in an idle state (step 301). The W-CDMA device 11 is powered on and the GSM device 12 is powered. It is turned off. In this state, the W-CDMA device 11 periodically searches for neighboring base stations by using the known primary scramble code (PSC) according to the instruction from the control unit 13 (establishment of slot synchronization detection) ( Step 302). Upon detecting establishment of slot synchronization, the S-SCH is used to identify the scramble code group of the neighbor base station (step 303). Next, the scramble code (base station code) of the neighbor base station is detected using the CPICH (step 304).

Then, the received level is measured for each detected scramble code, and it is determined whether the received level is larger or smaller than the set level, and if it is small, it is considered to be deleted, and if it is large, the scramble code / receive level / network type, etc. Is assumed to be registered, and the neighboring cell detection table is updated based on these determination results (step 306). Fig. 14 is an example of the neighbor cell detection table, where a plurality of base stations exist at present, and each scramble code, detection level (reception level), and network type are recorded.

Thereafter, the same processing as in step 204 of FIG. 8 is performed. That is, each step after step 204 performs update, handover, and cell change processing of the neighbor cell detection table.

(d) In case of transmitting P-SCH, S-SCH, CPICH, BCH from GSM base station

FIG. 15 is a diagram illustrating a process flow for identifying the presence or absence of a neighboring GSM base station by always transmitting P-SCH, S-SCH, CPICH, and BCH of W-CDMA from the GSM base station. However, the spreading code (PSC) of the P-SCH transmitted by the GSM base station is the same as the spreading code (PSC) of the P-SCH transmitted by the W-CDMA base station. In addition, one base station code is assigned to the GSM base station.

As shown in FIG. 1, the dual mode portable terminal MS is in communication with the W-CDMA base station BTS1 in the W-CDMA mode or is in an idle state (step 401), and the W-CDMA device 11 is powered up. On, GSM device 12 is powered off. In this state, the W-CDMA device 11 periodically searches for neighbor base stations using the known primary scramble code (PSC) according to the instruction from the control unit 13 (step 402). Upon detecting establishment of slot synchronization, the S-SCH is used to identify the scramble code group of the neighbor base station (step 403). Next, the scramble code (base station code) of the neighbor base station is detected using the CPICH (step 404).

When the base station code is obtained, the P-CCPCH is despread to demodulate BCH information (step 405), and the network type of the base station is identified based on the BCH information (step 406). In addition, the reception level is measured with respect to each of the identified scramble codes (step 407), and it is determined whether the reception level is larger or smaller than a set level, and if it is small, it is considered to be deleted, and if it is large, the scramble code / reception level is large. It is assumed that / network type and the like are registered, and the neighboring cell detection table is updated based on these determination results (step 408).

Thereafter, the same processing as in step 204 of FIG. 8 is performed. That is, the steps after step 204 are performed to update, handover, and change cell of the neighbor cell detection table.

(e) When transmitting SCH and FCCH of GSM from W-CDMA base station

FIG. 16 is a downlink signal format of a GSM signal of a predetermined frequency, a hyper frame (HF) is composed of 2048 super frames (SF), one super frame (SF) is composed of, for example, 26 multi-frames (MF) , One multi-frame (MF) is composed of 8 slot TDMA frames, one TDMA frame is composed of 148 bits, the tail bit (TB) and the guard interval (GP) is provided before and after. In GSM, a 148-bit synchronous burst (SB) is inserted every 10 frames. The set of synchronous bursts (SBs) is called an SCH (synchronization channel). By establishing synchronization of the SCH, the timing of each frame can be accurately determined. do. Similarly, a frequency corrected burst (FB) of 148 bits is inserted every 10 frames, and the set of frequency corrected bursts (FBs) is referred to as an FCCH (frequency corrected frequency correction channel). Can be generated. The notification channel BCCH, the common control channel CCCH, and the like are moved by the multi-frame MF.

The W-CDMA base station BTS1 (Fig. 2) is assigned a predetermined frequency F1, a predetermined SB pattern, and an FB pattern. The W-CDMA base station BTS1 always transmits the GSM signal of the frequency F1 obtained by inserting the SB pattern and the FB pattern every 10 frames. The dual mode portable terminal MS corrects the frequency to F1 using the FB pattern, and determines whether or not the W-CDMA base station exists according to whether synchronization can be established by the SB pattern.

FIG. 17 is a diagram showing a processing flow for identifying the presence or absence of a neighboring GSM base station by always transmitting SCH and FCCH from a W-CDMA base station at a predetermined frequency F1. The dual mode portable terminal MS is said to know the frequency F1, the pattern of the synchronous burst SB, and the pattern of the frequency correction burst FB.

The dual mode portable terminal MS (see Fig. 2) is in communication with the GSM base station BTS2 in GSM mode, the GSM device 12 is powered on and the W-CDMA device 11 is powered off (step 501). ).

In accordance with an instruction from the control unit 13, the GSM device 12 periodically searches for neighboring base stations using the known frequency F1, synchronous burst pattern, and frequency corrected burst pattern, and sets the frequency of the clock signal with the FCCH. The frequency correction is performed at F1 and the SCH is monitored for synchronization establishment (step 502).

If no synchronization is established in the SCH, it is determined that there is no W-CDMA base station (step 503). If it is established in synchronization with the SCH, it is determined that a W-CDMA base station exists (step 504). Thereafter, the process returns to the beginning and the subsequent processing is repeated.

On the other hand, in step 504, the reception level may be measured to determine that the W-CDMA base station exists only when the reception level is equal to or greater than a set value. It is also possible to configure the W-CDMA base station to be identified by changing the combination of the SB pattern and the frequency given to the W-CDMA base station.

(f) In case of transmitting SCH, FCCH, BCCH from W-CDMA base station

FIG. 18 is a diagram illustrating a processing flow of transmitting a SCH, FCCH, BCCH from a W-CDMA base station to identify the presence of a neighboring GSM base station. On the other hand, the predetermined frequency F1, the synchronous burst pattern, and the frequency correction burst pattern are assigned to the W-CDMA base station BTS1 (Fig. 2). The W-CDMA base station BTS1 always inserts the SB pattern and the FB pattern every 10 frames, and transmits the GSM signal of the frequency F1 including the type information of the W-CDMA base station to the BCCH.

The dual mode portable terminal MS (Fig. 2) is in communication with the GSM base station BTS2 in GSM mode, the GSM device 12 is powered on and the W-CDMA device 11 is powered off (step 601). .

In accordance with an instruction from the control unit 13, the GSM device 12 periodically searches for a neighbor base station using a known frequency F1, a synchronization burst pattern, and a frequency correction burst pattern, and uses a FCCH to set a clock signal frequency. Frequency correction is performed at F1, and at the same time, the synchronization burst pattern of the SCH is synchronized (step 602). After synchronization establishment, the BCCH is demodulated (step 603), and the W-CDMA base station is identified based on the network type information included in the BCCH information (step 604).

Next, the reception level from the W-CDMA base station is measured (step 605), and it is determined whether the reception level is larger or smaller than the set level, and if it is small, it is determined that there is no W-CDMA base station, and if it is large, the W-CDMA base station is determined. It is determined to exist (step 606). Meanwhile, detailed information for specifying the W-CDMA base station may be included in the BCCH information.

Subsequently, the above operation is repeated to create a neighbor cell detection table, and handover and cell change are performed by the processing as shown in FIG.

(D) The area where the second radio signal transmitted by the base station in the first radio mode reaches

FIG. 19A is a diagram illustrating a case where the dual mode portable terminal MS performs handover by movement while communicating with the W-CDMA base station BTS1. In this case, it is necessary to make the area AR _W to which the W-CDMA radio signal transmitted by the neighboring GSM base station BTS2 is smaller than or equal to the area AR _G to which the GSM radio wave reaches. When the area is set in this way, the dual mode portable terminal MS moves while communicating with the W-CDMA base station BTS1, and the point where the communication destination is switched from the W-CDMA base station BTS1 to the GSM base station BTS2 is the area ( AR _W ), in other words, is surely within the reach of the GSM radio wave, so that communication is not lost. However, if the area AR _W to which the W-CDMA radio signal reaches is larger than the area AR _G to the GSM radio wave, the point where the radio wave is switched from the W-CDMA base station BTS1 to the GSM base station BTS2 is used. There is a situation where communication is lost because it is out of reach.

FIG. 19B is a diagram illustrating a case where the dual mode portable terminal MS performs handover by movement while communicating with the GSM base station BTS2. In this case, it is necessary to make the area AR _G to which the GSM radio signal transmitted by the neighboring W-CDMA base station BTS1 reaches or smaller than or equal to the area AR _W to which the W-CDMA radio waves reach. When the area is set in this way, the dual mode portable terminal MS moves while communicating with the GSM base station BTS2, and the point where the communication destination is switched from the GSM base station BTS2 to the W-CDMA base station BTS1 is the area AR _G. ), That is, within the range where the W-CDMA radio waves reliably reach, so that communication is not interrupted. However, if the area AR _G to which the GSM radio signal is touched is larger than the area AR _W to which the W-CDMA radio wave is touched, the point where the GSM radio wave is switched from the GSM base station BTS2 to the W-CDMA base station BTS1 is reached. It becomes the range which does not reach, and the situation which loses communication occurs.

(E) Timing at which the base station in the first wireless mode starts to transmit the second wireless signal

In the above embodiment, the base station in the first wireless mode is always transmitting the second wireless signal. That is, the GSM base station BTS2 always transmits a W-CDMA radio signal, and the W-CDMA base station BTS1 always transmits a GSM radio signal. However, since there is always a transmission, there is a problem that the power consumption at the base station becomes large.

Thus, as shown in Fig. 20, the GSM base station (BTS2) includes a receiver (W-CDMA transceiver) 24 in addition to the W-CDMA transmitter, so that the W-CDMA radio from the dual mode portable terminal (MS) can be found. When the signal 3 is received, transmission of the W-CDMA radio signal is started, and when the W-CDMA radio signal 3 is not received, transmission of the W-CDMA radio signal is stopped. 20 corresponds to FIG. 1, and like reference numerals designate like parts.

21, the base station (BTS1) of the W-CDMA includes a receiver (GSM transceiver) 34 in addition to the transmitter of the GSM to receive the GSM radio signal 3 from the dual mode mobile terminal (MS). In this case, transmission of the GSM radio signal is started, and when the GSM radio signal 3 is not received, the transmission of the GSM radio signal is stopped. 21 corresponds to FIG. 2, and the same reference numerals are assigned to the same parts.

Fig. 22 is a diagram for explaining the procedure when the dual mode portable terminal MS searches for neighboring cells while communicating with the W-CDMA base station BTS1.

The dual mode terminal MS communicates with the base station BTS1 of the W-CDMA, and when the terminal MS moves and enters the area of the GSM base station BTS2 (the range of radio waves from the terminal MS). The GSM base station BTS2 detects the W-CDMA radio signal 3 from the terminal MS (steps 701 and 702), whereby a wireless terminal operating in W-CDMA can be found nearby. Upon detecting the presence of a wireless terminal operating with W-CDMA, the control unit 23 of the GSM base station (BTS2) activates the transmission unit of the W-CDMA transmission and reception unit 24 to start transmission of the radio signal 2 for W-CDMA. (Step 703). Accordingly, the dual mode portable terminal MS can identify the presence of the GSM base station BTS2 at the time of collecting the surrounding information.

(F) operation of the dual mode mobile terminal

23 is a flowchart illustrating the operation of the dual mode portable terminal.

The controller 13 of the dual-mode portable terminal (MS) collects peripheral information at the W-CDMA device 11 periodically (step 801) when moving while talking in the W-CDMA mode, and then the neighbor base stations of the W-CDMA. If neighboring base stations of GSM are found, they are registered (steps 802 and 803). Thereafter, the radio signal used for communication is monitored for deterioration (step 804), and when deterioration occurs, another base station (BTS) having a good radio wave condition is selected. In the BTS selection, however, if a base station (BTS) for W-CDMA is registered (YES in step 805), switching to the W-CDMA base station, i.e., handover, between the same communication modes is performed (step 806). .

On the other hand, in step 805, if there is no base station (BTS) (W-CDMA base station (BTS)) in the same communication mode in the vicinity, it is checked whether or not there is registration of GSM base station (BTS). (Step 807) If present, the GSM device 12 in the terminal is activated (step 808), the necessary steps are taken, and then handover is made to the GSM (step 809). Thereafter, the W-CDMA system not in use is powered off (step 810). On the other hand, in step 807, if there is no registration of the base station for GSM (BTS), the out-of-field indication (step 811) is performed to end the process.

As described above, according to the present invention, battery consumption of the terminal can be suppressed. For example, if the terminal is operating in the W-CDMA mode, the current consumption of the W-CDMA device 11 in the terminal is 200 mA, the current consumption of the control unit CPU 100 mA, and the GSM device 12. If the current consumption is 120 mA, the interval (period) of collecting the surrounding information of the GSM base station is 1 sec, and the collection period (from the power on to the end of the measurement) is 500 ms.

200 + 100 + (120 × 500/1000) = 360 mA

Becomes On the other hand, since the current consumption according to the present invention does not have the power ON of GSM,

200 + 100 = 300mA

Becomes Therefore, when using a battery of 700 mAh,

Battery life in the prior art,

700 mAh / 360 mA = 117 minutes

However, the battery life in the present invention,

700 mAh / 300 mA = 140 minutes

This can reduce battery consumption for about 23 minutes compared to the prior art.

In addition, when the dual mode mobile terminal (MS) is operating in the GSM mode,

Current consumption by the prior art,

120 + 100 + (200 × 500/1000) = 320 mA

Becomes On the other hand, since the power consumption of the present invention does not have W-CDMA Power ON,

120 + 100 = 220 mA

Becomes Therefore, when using a battery of 700 mAh,

Battery life in the prior art,

700 mAh / 320 mA = 131 minutes

However, the battery life of the present invention,

700 mAh / 220 mA = 191 minutes

As a result, the battery consumption can be reduced for about 60 minutes compared to the prior art.

In the above description, the first wireless communication mode has been described as W-CDMA and the second wireless communication mode is GSM. However, the present invention is not limited thereto, and the first wireless communication mode is W-CDMA and the second wireless communication mode. It may be a PDC, and in general, it can be applied to any combination of communication modes.

According to the present invention, whether or not a base station of each mobile communication mode is present in the vicinity with only the device according to the mobile communication mode in operation being turned on and the power of the device according to the other mobile communication mode being turned off. Since it can be recognized, a power consumption can be made small and battery life can be extended.

Claims (16)

A dual mode system for communicating using a terminal having a function capable of communicating in both mobile communication modes under a dual mode environment of a first mobile communication mode and a second mobile communication mode, And the base station in the second mobile communication mode transmits a radio signal recognizable in the first mobile communication mode. The dual mode system of claim 1, wherein the base station of the first mobile communication mode transmits a radio signal recognizable in a second mobile communication mode. 2. The method of claim 1, wherein when the first mobile communication mode is called W-CDMA and the second mobile communication mode is called GSM or PDC, a GSM / PDC base station transmits a P-SCH as the radio signal, and the terminal transmits the P-SCH. Dual mode system, characterized in identifying presence of GSM / PDC base station, with or without SCH. 2. The method of claim 1, wherein when the first mobile communication mode is W-CDMA and the second mobile communication mode is GSM or PDC, a GSM / PDC base station transmits a P-SCH and an S-SCH as the radio signals. The terminal includes a code group number and a network type correspondence table, and identifies a code group number of a neighboring base station from the S-SCH, and determines whether a GSM / PDC base station exists from the identified base station code group number and the correspondence table. Dual mode system, characterized in that identifying. 2. The method of claim 1, wherein when the first mobile communication mode is called W-CDMA and the second mobile communication mode is called GSM or PDC, a GSM / PDC base station transmits P-SCH, S-SCH and CPICH as the radio signals. The terminal may include a scramble code and a correspondence table of a network type, identify a scramble code of a neighbor base station from the CPICH, and identify the presence or absence of a GSM / PDC base station from the identified scramble code and the correspondence table. Dual mode system. 2. The method of claim 1, wherein when the first mobile communication mode is called W-CDMA and the second mobile communication mode is called GSM or PDC, the GSM / PDC base station uses the P-SCH, S-SCH, CPICH and PCCPCH as the radio signals. And the terminal identifies the presence or absence of a GSM / PDC base station from the BCH information in the PCCPCH. The dual mode system of claim 1, wherein an area where the radio signal of the first mobile communication mode transmitted by the base station of the second mobile communication mode reaches is smaller than or equal to that of the second wireless communication mode. The mobile station of claim 1, wherein the base station of the second mobile communication mode includes a receiver of the first mobile communication mode in addition to the transmitter of the first mobile communication mode, and thus the terminal of the first mobile communication mode is connected to the first mobile communication mode. And when receiving a wireless signal, transmitting a wireless signal in a first mobile communication mode with the transmitter. The mobile station according to claim 2, wherein when the first mobile communication mode is called W-CDMA and the second mobile communication mode is called GSM or PDC, the W-CDMA base station transmits an FCCH / SCH, which is a synchronization channel, as the radio signal. And identify the presence of the W-CDMA base station based on whether synchronization is established with the SCH. 3. The method of claim 2, wherein when the first mobile communication mode is called W-CDMA and the second mobile communication mode is called GSM or PDC, the W-CDMA base station transmits a BCCH in addition to the FCCH / SCH which is a synchronization channel as the radio signal. And the terminal identifies the presence of the W-CDMA base station using the information in the BCCH. The mobile station of claim 2, wherein the base station of the first mobile communication mode includes a receiver of the second mobile communication mode in addition to the transmitter of the second mobile communication mode, and thus the terminal of the second mobile communication mode from the terminal communicating in the second mobile communication mode. And when receiving a wireless signal, transmitting a wireless signal in a second mobile communication mode with the transmitter. The dual mode system of claim 2, wherein the area where the radio signal of the second mobile communication mode transmitted by the base station of the first mobile communication mode reaches is smaller than or equal to the area of the first wireless communication mode. In the dual mode system of the first mobile communication mode and the second mobile communication mode, a dual mode system for communicating using a terminal having a first and a second device capable of communicating in the first and second mobile communication mode, respectively, The base station of the first mobile communication mode communicates with the terminal in the first mobile communication mode and simultaneously transmits a radio signal in the second mobile communication mode, The base station of the second mobile communication mode communicates with the terminal in the second mobile communication mode and simultaneously transmits a radio signal in the first mobile communication mode, The first device of the terminal communicates with the base station of the first mobile communication mode in the first mobile communication mode, receives a radio signal of the first mobile communication mode transmitted from the base station of the second mobile communication mode, The base station of the second mobile communication mode is determined based on the signal, and the second device of the terminal communicates with the base station of the second mobile communication mode in the second mobile communication mode, and at the same time, the base station of the first mobile communication mode. And receiving the radio signal of the second mobile communication mode transmitted from the mobile station, and determining whether the base station is in the first mobile communication mode based on the radio signal. A dual mode wireless terminal capable of communicating in first and second mobile communication modes, respectively, in a dual mode environment of a first mobile communication mode and a second mobile communication mode, First and second devices communicating in said first and second mobile communication modes, respectively, The first apparatus communicates with the base station of the first mobile communication mode in the first mobile communication mode, receives a wireless signal of the first mobile communication mode transmitted from the base station of the second mobile communication mode, and based on the wireless signal. Determine whether there is a base station in the second mobile communication mode, The second device communicates with the base station of the second mobile communication mode in the second mobile communication mode, receives a wireless signal of the second mobile communication mode transmitted from the base station of the first mobile communication mode, and based on the wireless signal. And determining whether there is a base station in the first mobile communication mode. And receiving means for receiving information about the first and second mobile communication systems having different transmission formats of radio signals as a radio signal corresponding to the first mobile communication system. And transmitting means for transmitting information about the first and second mobile communication systems having different transmission formats of radio signals as a radio signal corresponding to the first mobile communication system.