JP5028653B2 - Radio communication system and mobile radio terminal apparatus - Google Patents

Description

  The present invention relates to a wireless communication system that provides a plurality of wireless connection schemes.

  For example, CDMA2000 1x system (for example, see Non-Patent Document 1), EV-DO system (for example, Non-Patent Document 2) and LTE (Long Term Evolution) system (for example, Non-Patent Document 3) wireless connection systems Development of a mobile radio terminal apparatus corresponding to the mobile radio terminal apparatus and a radio communication system corresponding to the mobile radio terminal apparatus is underway. In the case of this example, for CDMA2000 1x and EV-DO, the population coverage rate of the service area has reached about 95%. On the other hand, for newly developed LTE, it is expected that the service will be deployed in order from the urban area with the highest population density at the beginning of operation.

However, in the mobile radio terminal apparatus corresponding to the multimode as described above, the area of the new service is small, and thus power is wasted in order to search for the service area (base station). This can cause problems.
Agilent Technologies 2001 3G Workshop Part 2, January 16, 2001, p2-35. Agilent Technologies 2001 3G Workshop Part2, January 16, 2001, p36-50. Erik Dahlman Academic Press, 2007, p. 277-369.

  In a multi-mode mobile radio terminal device that supports a plurality of radio connection schemes, the area of a new service is small, and there is a risk that power is wasted in order to search for the service area (base station). There was a problem that there was.

  The present invention was made to solve the above problem, and even when a service is provided by a plurality of communication methods and a communication method with a narrow service area is included, the service area (base station) is efficiently searched, It is another object of the present invention to provide a radio communication system and a mobile radio terminal device that can save power consumed for searching.

In order to achieve the above object, the present invention provides a plurality of first wireless base stations that wirelessly communicate with a first communication method to form a first service area and wirelessly communicate with a second communication method. A wireless communication system in which a plurality of second wireless base stations for communication are arranged to form a second service area narrower than the first service area, and a mobile wireless terminal device is wirelessly connected to a network, For each radio base station, storage means for storing information indicating the presence of a second radio base station located in the vicinity, and arrangement information of the second radio base station based on information stored in the storage means, Transmitting means for transmitting to the mobile radio terminal device through the first radio base station ,
The arrangement information indicates the density at which the second radio base station exists .

As described above, in the present invention, information about the presence of the second radio base station located in the vicinity is provided to the mobile radio terminal device through the first radio base station.
Therefore, according to the present invention, even if the second service area formed by the second radio base station is narrower than the first service area formed by the first radio base station, It is possible to provide a wireless communication system and a mobile wireless terminal device that can efficiently search based on information and save power consumed for searching.

Hereinafter, an embodiment of the present invention will be described with reference to the drawings.
A radio communication system according to an embodiment of the present invention will be described by taking as an example a case corresponding to three radio access schemes of CDMA2000 1x scheme (hereinafter referred to as 1x scheme), EV-DO scheme, and LTE scheme.

  The 1x system can provide voice communication service and low-speed packet communication service of 100kbps or less by circuit switching connection. The EV-DO system can provide a high-speed packet service of up to about 2.4 Mbps at 100 kbps or higher by packet switching connection. The LTE system provides a high-speed packet service of about 2 Mbps to 20 Mbps by packet switching connection, and can also provide a voice call service by VoIP (Voice over Internet Protocol).

  Each method has different use frequencies. Here, it is defined as follows. That is, in the 1x scheme, the frequency f1d is assigned as the downlink from the base station to the mobile radio terminal apparatus, and conversely, f1u is assigned as the uplink frequency. In the EV-DO scheme, the frequency f2d is assigned as a downlink from the base station to the mobile radio terminal apparatus, and conversely, f2u is assigned as the uplink frequency. In the LTE scheme, the frequency f3d is assigned as a downlink from the base station to the mobile radio terminal apparatus, and conversely, f3u is assigned as the uplink frequency.

  As shown in FIG. 1, this radio communication system forms a service area E1 that provides 1x and EV-DO services, and a service area E2 that provides LTE services. In the service area E1, a base station 1x BS that uses the 1x scheme as an access scheme and a base station EV-DO BS that uses the EV-DO scheme as an access scheme each form a radio zone called a cell. A service area E1 is formed by arranging a large number of wireless zones. Similarly, in the service area E2, the base station LTE BS using the LTE scheme as an access scheme forms a radio zone called a cell. A service area E2 is formed by arranging a large number of wireless zones. As shown in this figure, the service area E1 includes a service area E2 therein. In this figure, the service area E1 and the service area E2 are shown separately, but even at the position where the service area E2 is illustrated, the base station 1x BS for providing each service of the 1x method and the EV-DO method, EV-DO BS exists.

  As shown in FIG. 2, the base station 1x BS, EV-DO BS, and LTE BS are collectively controlled by the base station control unit 200. The database 300 stores location management information indicating where the base stations 1x BS, EV-DO BS, and LTE BS are respectively arranged in the service area.

  The location management information includes information indicating whether the cell to be formed overlaps the cell formed by the base station LTE BS or the cell formed by the base station LTE BS for the base station 1x BS and the base station EV-DO BS. The overlapping base station has information indicating whether the base station LTE BS is located near the boundary (outer edge) in the service area E2 or near the center. That is, the location management information indicates whether or not there is a base station LTE BS in the vicinity of the base station 1x BS and the base station EV-DO BS, the existing density, and the position of the base station LTE BS in the service area E2. ing.

  The base station control unit 200 refers to the location management information and controls the base station 1x BS to transmit LTE_DENSITY_MESSAGE with a 1x paging signal. The 1x paging signal here is, for example, compliant with TIA / EIA STANDARD IS-2000.5 and conforms to the format of 3.7.2.3.2 Message Body Contents. Here, LTE_DENSITY_MESSAGE is defined as shown in FIG.

  Each value of the LTE_DENSITY_MESSAGE field value has the meaning shown in FIG. 4, and this value is determined by the base station control unit 200 based on the location management information. That is, the Field value is set according to the degree of overlap of the cell formed by the base station 1x BS with the cell formed by the base station LTE BS and the position of the cell, and this is transmitted by the 1x paging signal.

  Specifically, for the base station 1x BS that forms a cell that does not overlap the cell formed by the base station LTE BS (D in Fig. 1), the field value is set to "00" and a 1x paging signal is transmitted. Let In addition, for the base station 1x BS that mainly forms a cell overlapping with the cell (C in FIG. 1) formed by the base station LTE BS that forms a cell near the boundary of the service area E2, the field value is set to “01”. Set to send 1x paging signal.

  In addition, the base station 1x BS that mainly forms an overlapping cell is formed not in the vicinity of the boundary of the service area E2 but in a cell (B in FIG. 1) formed by the base station LTE BS that forms a cell inside the service area E2. Sets the Field value to “10” and sends a 1x paging signal. Also, for the base station 1x BS that forms a cell (A in FIG. 1) that overlaps with a cell formed by a plurality of base stations LTE BS that form a cell within the service area E2, not near the boundary of the service area E2 Sets the Field value to “11” and transmits a 1x paging signal.

  In the example shown in FIG. 3 and FIG. 4, the data length is 2 bits so that the cell formed by the base station 1x BS overlaps the cell formed by the base station LTE BS. As shown in FIG. 1, it may be 1 bit. In this case, as shown in FIG. 6, it is shown whether or not the cell formed by the base station 1x BS overlaps the cell formed by the base station LTE BS.

  Next, the configuration of the mobile radio terminal apparatus will be described with reference to FIG. As shown in this figure, the mobile radio terminal apparatus includes a transmission / reception antenna 101, a reception antenna 102, a terminal control unit 100, a reception unit 110, a reception signal processing unit 120, a transmission signal processing unit 130, A transmission unit 140. In addition, a display unit 150 that displays characters and video, an input unit 160 that accepts user requests and number input, a battery and power supply unit that supply driving power, a microphone for inputting transmitted voice, and received voice A loudspeaker is provided.

  Radio signals (frequency f1d, f2d, f3d) transmitted from the base station 1x BS, EV-DO BS, and LTE BS are received by the transmission / reception antenna 101 and the reception antenna 102. The received radio signal is down-converted into a baseband received signal by the receiving unit 110. The local signal used for the down-conversion is oscillated at a frequency corresponding to the communication method instructed from the reception signal processing unit 120, and thereby a radio signal (frequency f1d, f2d, or f3d) to be received is received. Selected.

  The received signal processing unit 120 processes a signal received from the base station EV-DO BS corresponding to the EV-DO method, and a 1x received signal processing unit 120a that processes the signal received from the base station 1x BS corresponding to the 1x method. EV-DO reception signal processing section 120b that performs the LTE system, and LTE reception signal processing section 120c that processes signals received from the base station LTE BS corresponding to the LTE scheme.

  The reception signal processing unit 120 notifies the reception unit 110 of the communication method instructed by the terminal control unit 100, and also includes a 1x reception signal processing unit 120a, an EV-DO reception signal processing unit 120b, and an LTE reception signal processing unit 120c. The processing unit corresponding to the communication method is activated.

  The 1x received signal processing unit 120a, the EV-DO received signal processing unit 120b, and the LTE received signal processing unit 120c perform signal processing according to the corresponding communication method, respectively. Then, the baseband received signal is demodulated and decoded to obtain received data.

  The transmission signal processing unit 130 generates a signal to be transmitted to the base station 1x BS corresponding to the 1x scheme, and a signal to be transmitted to the base station EV-DO BS corresponding to the EV-DO scheme. An EV-DO transmission signal processing unit 130b that performs the LTE scheme, and an LTE transmission signal processing unit 130c that generates a signal to be transmitted to the base station LTE BS corresponding to the LTE scheme.

  The transmission signal processing unit 130 notifies the transmission unit 140 of the communication method instructed by the terminal control unit 100, and also includes a 1x transmission signal processing unit 130a, an EV-DO transmission signal processing unit 130b, and an LTE transmission signal processing unit 130c. The processing unit corresponding to the communication method is activated.

  The 1x transmission signal processing unit 130a, the EV-DO transmission signal processing unit 130b, and the LTE transmission signal processing unit 130c perform signal processing according to the corresponding communication method, respectively. The transmission data is encoded and then modulated to generate a baseband transmission signal.

  The transmission unit 140 oscillates a local signal having a frequency corresponding to the communication method notified from the transmission signal processing unit 130, and up-converts the baseband transmission signal to a radio frequency using the local signal. Thereby, the radio signal (any one of the frequencies f1u, f2u, and f3u) to be transmitted is selected. The radio signal is radiated to the space through the transmission / reception antenna 101.

  The terminal control unit 100 controls each unit of the mobile radio terminal device in an integrated manner, and controls each unit to perform communication using a communication method according to a request from the user through the input unit 160, Alternatively, a communication method is selected according to a communication method selection process described later, and location registration or waiting for an incoming call is performed.

  Next, the operation of the mobile radio terminal apparatus having the above configuration will be described. In the following description, communication method selection processing will be described in particular. The flowcharts shown in FIGS. 8 to 11 are for explaining the above-described communication method selection processing, and are realized by the terminal control unit 100 operating according to control programs and control data stored therein.

  When the power is turned on, in step 8a, the terminal control unit 100 instructs the reception signal processing unit 120 and the transmission signal processing unit 130 to select the 1x method as the communication method. Thereby, the reception signal processing unit 120 activates the 1x reception signal processing unit 120a and notifies the reception unit 110 of the 1x method as a communication method.

  On the other hand, the receiving unit 110 oscillates a local signal for receiving a 1x radio signal, and down-converts the signal having the frequency f1u to baseband. Similarly, the transmission signal processing unit 130 activates the 1x transmission signal processing unit 130a and notifies the transmission unit 140 of the 1x method as a communication method.

  After that, the terminal control unit 100 monitors the reception data output from the reception signal processing unit 120 (1x reception signal processing unit 120a), receives the pilot signal transmitted from the base station 1x BS, and completes the initial acquisition. It is determined whether it has been completed. Here, when the initial acquisition of the 1x method can be completed, the process proceeds to step 8c. On the other hand, when the initial acquisition of the 1x method cannot be completed, the process proceeds to step 8b to perform out-of-service processing. In this out-of-service processing, a video indicating that the user is out of the 1x service area (outside the service area E1) is displayed on the display unit 150 to the user.

  In step 8c, the terminal control unit 100 controls the 1x transmission signal processing unit 130a activated in step 8a to transmit a signal requesting location registration through the base station 1x BS. Then, after performing location registration in this way, processing for waiting for an incoming signal sent from the base station 1x BS is started, and the process proceeds to step 8d.

  In step 8d, the terminal control unit 100 extracts LTE_DENSITY_MESSAGE from the received data of the 1x paging signal received by the 1x received signal processing unit 120a from the base station 1x BS, and proceeds to step 8e.

  In Step 8e, the terminal control unit 100 detects a Field value from the LTE_DENSITY_MESSAGE extracted in Step 8d, and determines which value the value indicates. Here, when the Field value is “00”, the process A shown in FIG. 9 is executed. If the Field value is “01”, process B shown in FIG. 10 is executed. If the Field value is “10” or “11”, the process C shown in FIG. 11 is executed.

  Next, the process A will be described with reference to FIG. This process is performed when the LTE_DENSITY_MESSAGE of the field value “00” is received from the base station 1x BS waiting for the incoming signal through the 1x paging signal, that is, when the mobile radio terminal apparatus is located in the cell D shown in FIG. Executed.

  In step 9a, the terminal control unit 100 instructs the reception signal processing unit 120 and the transmission signal processing unit 130 to select the EV-DO method as the communication method. As a result, the reception signal processing unit 120 activates the EV-DO reception signal processing unit 120b in addition to the state in which the 1x reception signal processing unit 120a has already been activated, and also transmits the EV as a communication method to the reception unit 110. -Notify the DO method.

  On the other hand, since the receiving unit 110 has already been notified that the 1x method is used as the communication method, the reception unit 110 receives the local signal for receiving the 1x method radio signal and the EV-DO method radio signal. A local signal to be received is alternately oscillated in accordance with the reception cycle of the paging signal of each method, and the signal of frequency f1u and the signal of frequency f2u are down-converted to baseband in a time division manner. Similarly, the transmission signal processing unit 130 activates the EV-DO transmission signal processing unit 130b in addition to the state where the 1x transmission signal processing unit 130a has already been activated, and sets the EV-DO method as a communication method to the transmission unit 140. Notice.

  After that, the terminal control unit 100 monitors the reception data output from the reception signal processing unit 120 (EV-DO reception signal processing unit 120b) and receives a pilot signal transmitted from the base station EV-DO BS. It is determined whether the initial acquisition has been completed. Here, when the initial acquisition of the EV-DO method is completed, the process proceeds to step 9c. On the other hand, when the initial acquisition of the EV-DO method cannot be completed, the process proceeds to step 9b to perform out-of-service processing. . In the out-of-service processing, the display unit 150 displays a video indicating that the user is out of the EV-DO service area (outside the service area E1) to the user.

  In step 9c, the terminal control unit 100 controls the EV-DO transmission signal processing unit 130b activated in step 9a to transmit a signal requesting location registration through the base station EV-DO BS. And after performing location registration in this way, the process which waits for the incoming signal sent from base station EV-DO BS is started, and it transfers to step 9d.

  As a result, the mobile radio terminal apparatus waits for an incoming call in both the 1x system and the EV-DO system. Here, the LTE reception signal processing unit 120c and the LTE transmission signal processing unit 130c are not activated, and neither the reception unit 110 nor the transmission unit 140 performs transmission / reception for the LTE scheme.

  In step 9d, the terminal control unit 100 extracts LTE_DENSITY_MESSAGE from the reception data of the 1x paging signal received by the 1x reception signal processing unit 120a from the base station 1x BS, and proceeds to step 9e.

  In step 9e, the terminal control unit 100 detects a field value from the LTE_DENSITY_MESSAGE extracted in step 9d, and determines which one the value indicates. Here, when the Field value is “00”, the process proceeds to Step 9d, and the waiting for the occurrence of an incoming call is continued in both the 1x system and the EV-DO system. If the Field value is “01”, process B shown in FIG. 10 is executed. If the Field value is “10” or “11”, the process C shown in FIG. 11 is executed.

  Next, processing B will be described with reference to FIG. This process is performed when the LTE_DENSITY_MESSAGE of the field value “01” is received from the base station 1x BS that is waiting for an incoming call through the 1x paging signal, that is, the base station 1x BS mainly overlaps the cell C shown in FIG. It is executed when forming.

  In step 10a, the terminal control unit 100 instructs the reception signal processing unit 120 and the transmission signal processing unit 130 to select the LTE method as the communication method. As a result, the received signal processing unit 120 activates the LTE received signal processing unit 120c in addition to the state where the 1x received signal processing unit 120a has already been activated, and also sets the LTE method as the communication method for the receiving unit 110. Notice.

  On the other hand, since the receiving unit 110 has already been notified that the 1x method is used as the communication method, the receiving unit 110 receives the local signal for receiving the 1x wireless signal and the LTE wireless signal. The local signal for oscillation is alternately oscillated in accordance with the reception period of the paging signal of each method, and the signal of the frequency f1u and the signal of the frequency f3u are down-converted to baseband in a time division manner. Similarly, the transmission signal processing unit 130 activates the LTE transmission signal processing unit 130c in addition to the state where the 1x transmission signal processing unit 130a has already been activated, and notifies the transmission unit 140 of the LTE scheme as a communication scheme.

  After that, the terminal control unit 100 monitors the reception data output from the reception signal processing unit 120 (LTE reception signal processing unit 120c), receives the pilot signal transmitted from the base station LTE BS, and completes the initial acquisition. It is determined whether it has been completed. Here, when the LTE system initial acquisition is completed, the process proceeds to step 10c. On the other hand, when the LTE system initial acquisition cannot be completed, the process proceeds to step 10b and out-of-service processing is performed. In this out-of-service processing, a video indicating that the user is out of the LTE service area (outside the service area E2) is displayed on the display unit 150 to the user.

  In step 10c, the terminal control unit 100 controls the LTE transmission signal processing unit 130c activated in step 10a to transmit a signal requesting location registration through the base station LTE BS. And after performing location registration in this way, the process which waits for the incoming signal sent from base station LTE BS is started, and it transfers to step 10d. As a result, the mobile radio terminal apparatus waits for an incoming call in both the 1x system and the LTE system.

  In step 10d, the terminal control unit 100 determines whether or not waiting for an incoming call using the EV-DO method. If the terminal control unit 100 is waiting for an incoming call using the EV-DO method, the terminal control unit 100 instructs the received signal processing unit 120 to The instruction to end reception of the -DO method is instructed, and the transmission signal processing unit 130 is instructed to end transmission of the EV-DO method, and the process proceeds to Step 10e. In cases other than the above, the process proceeds to step 10e as it is.

  Thereby, the reception signal processing unit 120 stops the EV-DO reception signal processing unit 120b and notifies the reception unit 110 to end the reception of the EV-DO method. Similarly, the transmission signal processing unit 130 stops the EV-DO transmission signal processing unit 130b and notifies the transmission unit 140 to end the EV-DO transmission. The reception unit 110 and the transmission unit 140 end transmission / reception for the EV-DO scheme.

  In step 10e, the terminal control unit 100 extracts LTE_DENSITY_MESSAGE from the reception data of the 1x paging signal received by the 1x reception signal processing unit 120a from the base station 1x BS, and proceeds to step 10f.

  In step 10f, the terminal control unit 100 detects a Field value from the LTE_DENSITY_MESSAGE extracted in Step 10e, and determines which value the value indicates. Here, when the Field value is “00”, the process A shown in FIG. 9 is executed. On the other hand, if the Field value is “01”, the process proceeds to Step 10e, and the waiting for the occurrence of an incoming call is continued in both the 1x system and the LTE system. If the Field value is “10” or “11”, the process C shown in FIG. 11 is executed.

  Next, processing C will be described with reference to FIG. This process is performed when the LTE_DENSITY_MESSAGE of the field value “11” or “10” is received from the base station 1x BS waiting for an incoming call through the 1x paging signal, that is, the base station 1x BS has the cell A shown in FIG. This is executed when a cell mainly overlapping with B is formed.

  In step 11a, the terminal control unit 100 instructs the reception signal processing unit 120 and the transmission signal processing unit 130 to select the LTE method as the communication method. As a result, the received signal processing unit 120 activates the LTE received signal processing unit 120c in addition to the state where the 1x received signal processing unit 120a has already been activated, and also sets the LTE method as the communication method for the receiving unit 110. Notice.

  On the other hand, since the receiving unit 110 has already been notified that the 1x method is used as the communication method, the receiving unit 110 receives the local signal for receiving the 1x wireless signal and the LTE wireless signal. The local signal for oscillation is alternately oscillated in accordance with the reception period of the paging signal of each method, and the signal of the frequency f1u and the signal of the frequency f3u are down-converted to baseband in a time division manner. Similarly, the transmission signal processing unit 130 activates the LTE transmission signal processing unit 130c in addition to the state where the 1x transmission signal processing unit 130a has already been activated, and notifies the transmission unit 140 of the LTE scheme as a communication scheme.

  After that, the terminal control unit 100 monitors the reception data output from the reception signal processing unit 120 (LTE reception signal processing unit 120c), receives the pilot signal transmitted from the base station LTE BS, and completes the initial acquisition. It is determined whether it has been completed. Here, when the LTE system initial acquisition is completed, the process proceeds to step 11c. On the other hand, when the LTE system initial acquisition cannot be completed, the process proceeds to step 11b to perform out-of-service processing. In this out-of-service processing, a video indicating that the user is out of the LTE service area (outside the service area E2) is displayed on the display unit 150 to the user.

  In step 11c, the terminal control unit 100 controls the LTE transmission signal processing unit 130c activated in step 11a to transmit a signal requesting location registration through the base station LTE BS. And after performing location registration in this way, the process which waits for the incoming signal sent from base station LTE BS is started, and it transfers to step 11d. As a result, the mobile radio terminal apparatus waits for an incoming call in both the 1x system and the LTE system.

  In step 11d, the terminal control unit 100 determines whether it is waiting for an incoming call using the EV-DO method. If the terminal control unit 100 is waiting for an incoming call using the EV-DO method, the terminal control unit 100 instructs the received signal processing unit 120 to Instructs the transmission signal processing unit 130 to end the transmission of the EV-DO method while instructing to end the reception of the -DO method, and proceeds to step 11e. In cases other than the above, the process proceeds to step 11e as it is.

  Thereby, the reception signal processing unit 120 stops the EV-DO reception signal processing unit 120b and notifies the reception unit 110 to end the reception of the EV-DO method. Similarly, the transmission signal processing unit 130 stops the EV-DO transmission signal processing unit 130b and notifies the transmission unit 140 to end the EV-DO transmission. The reception unit 110 and the transmission unit 140 end transmission / reception for the EV-DO scheme.

  In step 11e, the terminal control unit 100 instructs the reception signal processing unit 120 to end the reception of the 1x method and also instructs the transmission signal processing unit 130 to end the transmission of the 1x method. Then, the process ends. In cases other than the above, the process is terminated as it is.

  Thereby, the reception signal processing unit 120 stops the 1x reception signal processing unit 120a and notifies the reception unit 110 to end the reception of the 1x system. Similarly, the transmission signal processing unit 130 stops the 1x transmission signal processing unit 130a and notifies the transmission unit 140 to end the 1x transmission. The reception unit 110 and the transmission unit 140 end transmission / reception for the 1x scheme.

  As described above, in the radio communication system configured as described above, the base station 1x BS has a field value depending on the degree to which the cell formed by the base station 1x BS overlaps the cell formed by the base station LTE BS and the position of the overlapping cell. And send this with a 1x paging signal. On the other hand, the mobile radio terminal apparatus receives the 1x paging signal from the base station 1x BS, and determines whether the base station LTE BS exists at the current location based on the Field value. If the base station LTE BS is present, it is determined whether the base station is located at the boundary of the service area E2 or the base station located in the center, and the base station LTE BS is searched according to these judgment results. Like to do.

  Therefore, according to the radio communication system having the above configuration, it is possible to determine whether or not the LTE system service is provided through the 1x system having a wide service area and to search for an LTE base station wastefully. Thus, the service area E2 can be searched efficiently and the power consumption can be reduced.

  Note that the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying the constituent elements without departing from the scope of the invention in the implementation stage. In addition, various inventions can be formed by appropriately combining a plurality of constituent elements disclosed in the embodiment. Further, for example, a configuration in which some components are deleted from all the components shown in the embodiment is also conceivable. Furthermore, you may combine suitably the component described in different embodiment.

  As an example, for example, in the above embodiment, the base station 1x BS sets four field values according to the degree to which the cell to be formed overlaps the cell formed by the base station LTE BS and the position of the overlapping cell. However, as shown in FIG. 5 and FIG. 6, the degree can be set in two ways. In this case, the processing shown in FIG. 12 may be executed instead of the communication method selection processing shown in FIG. That is, the terminal control unit 100 executes Step 12e instead of Step 8e.

  In step 12e, the terminal control unit 100 detects a Field value from the LTE_DENSITY_MESSAGE extracted in Step 8d, and determines which one the value indicates. Here, when the Field value is “0”, the process A shown in FIG. 9 is executed. If the Field value is “1”, process C shown in FIG. 11 is executed. Even with such simplified processing, the same effect can be obtained although accuracy and efficiency are lowered.

  In the above embodiment, the information indicating the arrangement of the LTE base station LTE BS is transmitted from the base station 1x BS through the 1x paging signal. However, the LTE signal is transmitted through the traffic signal transmitted by the base station 1x BS. Information indicating the arrangement of the system base station LTE BS may be transmitted. The traffic signal here is compliant with TIA / EIA STANDARD IS-2000.5 and follows the format of 3.7.2.3.3 Message Body Contents.

Further, instead of the 1x scheme, the base station EV-DO BS may be applied to the EV-DO scheme and transmit the above information through a paging signal or a traffic signal. In this case, the information may be transmitted as a part of parameters of these messages.
Furthermore, in the above embodiment, when the field value is “10” and “11”, the process C is executed. However, the base station LTE BS is arranged so as to distinguish between them. You may make it process according to the density.
In addition, it goes without saying that the present invention can be similarly implemented even if various modifications are made without departing from the gist of the present invention.

The figure for demonstrating the relationship between the service area and cell of the radio | wireless communications system concerning this invention. The figure for demonstrating the structure which controls the base station of the radio | wireless communications system shown in FIG. The figure for demonstrating LTE_DENSITY_MESSAGE which base station 1x BS of the radio | wireless communications system shown in FIG. 1 transmits. The figure for demonstrating LTE_DENSITY_MESSAGE which base station 1x BS of the radio | wireless communications system shown in FIG. 1 transmits. The figure for demonstrating LTE_DENSITY_MESSAGE which base station 1x BS of the radio | wireless communications system shown in FIG. 1 transmits. The figure for demonstrating LTE_DENSITY_MESSAGE which base station 1x BS of the radio | wireless communications system shown in FIG. 1 transmits. FIG. 2 is a circuit block diagram showing a configuration of a mobile radio terminal device of the radio communication system shown in FIG. 1. The flowchart for demonstrating the communication system selection process of the mobile radio | wireless terminal apparatus shown in FIG. The flowchart for demonstrating the communication system selection process of the mobile radio | wireless terminal apparatus shown in FIG. The flowchart for demonstrating the communication system selection process of the mobile radio | wireless terminal apparatus shown in FIG. The flowchart for demonstrating the communication system selection process of the mobile radio | wireless terminal apparatus shown in FIG. The flowchart for demonstrating the communication system selection process of the mobile radio | wireless terminal apparatus shown in FIG.

Explanation of symbols

  DESCRIPTION OF SYMBOLS 100 ... Terminal control part, 101 ... Transmission / reception antenna, 102 ... Reception antenna, 110 ... Reception part, 120 ... Reception signal processing part, 120a ... 1x reception signal processing part, 120b ... EV-DO reception signal processing part, 120c ... LTE reception signal processing unit, 130 ... transmission signal processing unit, 130a ... 1x transmission signal processing unit, 130b ... EV-DO transmission signal processing unit, 130c ... LTE transmission signal processing unit, 140 ... transmission unit, 150 ... display unit, 160 ... input unit, 200 ... base station control unit, 300 ... database, E1 ... service area, E2 ... service area.

Claims (14)

A plurality of first radio base stations that perform radio communication using the first communication method are provided to form a first service area, and a plurality of second radio base stations that perform radio communication using the second communication method are provided. A wireless communication system that forms a second service area narrower than the first service area and wirelessly connects a mobile wireless terminal device to a network,
Storage means for storing information indicating the presence of a second radio base station located in the vicinity of each first radio base station;
Transmission means for transmitting the arrangement information of the second radio base station based on the information stored in the storage means to the mobile radio terminal device through the first radio base station , and
The wireless communication system , wherein the arrangement information indicates a density at which the second wireless base station exists . The first communication method is a CDMA2000 1x method, the second communication method is an LTE method,
The wireless communication system according to claim 1, wherein the transmission unit transmits the arrangement information by a 1x paging signal. The first communication method is a CDMA2000 1x method, the second communication method is an LTE method,
The wireless communication system according to claim 1, wherein the transmission unit transmits the arrangement information by a 1x traffic signal. The first communication method is an EV-DO method, the second communication method is an LTE method,
The wireless communication system according to claim 1, wherein the transmission unit transmits the arrangement information by an EV-DO paging signal. The first communication method is an EV-DO method, the second communication method is an LTE method,
The wireless communication system according to claim 1, wherein the transmission unit transmits the arrangement information using an EV-DO traffic signal.   The wireless communication system according to claim 1, wherein the arrangement information indicates presence / absence of the second wireless base station. The storage means stores, for each first radio base station, information indicating the presence of a second radio base station located nearby and position information of the second radio base station in the second service area. ,
The wireless communication system according to claim 1, wherein the arrangement information indicates a location where the second wireless base station is located in the second service area. The radio communication system according to claim 7 , wherein the arrangement information indicates whether or not the second radio base station is located at a boundary in the second service area. A plurality of first radio base stations that perform radio communication using the first communication method are provided to form a first service area, and a plurality of second radio base stations that perform radio communication using the second communication method are provided. A mobile radio terminal used in a radio communication system that forms a second service area that is narrower than the first service area,
Receiving means for receiving information indicating the presence of a second radio base station located in the vicinity from the first radio base station;
Second base station searching means for searching for the second radio base station based on the information received by the receiving means;
Stop control means for stopping the operation of the means for communicating with the first radio base station when the information received by the receiving means indicates that the second radio base station is in the vicinity. A mobile radio terminal device. The second base station search means does not search for the second radio base station when the information received by the reception means indicates that there is no second radio base station in the vicinity. The mobile radio terminal apparatus according to claim 9 . The stop control means, when the information received by the receiving means indicates that the second radio base station is in the vicinity, after synchronizing with the second radio base station, The mobile radio terminal apparatus according to claim 9 , wherein the operation of the means for communicating is stopped. Further, when the information received by the receiving means indicates that the second radio base station existing in the vicinity is located at the boundary of the second service area, the first radio base station and the first radio base station The mobile radio terminal apparatus according to claim 9, further comprising standby control means for waiting for an incoming signal for both of the two radio base stations. And a first base station searching means for searching for the first radio base station immediately after the power is turned on.
The reception means receives information indicating the presence of a second radio base station located in the vicinity from the first radio base station detected by the first base station search means,
The mobile radio terminal according to claim 9 , wherein the second base station search means searches for the second radio base station based on the information when the receiving means receives the information. apparatus. The wireless communication system includes a plurality of third wireless base stations that wirelessly communicate with a third communication method to form a third service area wider than the second service area,
Furthermore, when the information received by the receiving means indicates that there is no second radio base station in the vicinity, the information processing apparatus further comprises third base station search means for searching for the third radio base station. The mobile radio terminal apparatus according to claim 9 .

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