JPWO2007080627A1 - Mobile communication terminal device and communication system - Google Patents

Abstract

A mobile communication terminal device capable of smoothly communicating with each of a plurality of communication systems having different frequency bands and saving power. In this apparatus, in the mobile communication terminal device 100, the control unit 170 controls the 3G, S3G, and 4G data reception processing units 140, 150, and 160 based on the remaining battery level of the battery 195 and the reception status information of 3G, S3G, and 4G. One or two data reception processing units are set with a measurement cycle of the reception state, and the reception state is measured by controlling the one or two data reception processing units according to the set measurement cycle. The reception state information comparison unit 174 compares the received power in the 3G, S3G, and 4G communication systems using the reception state information indicating the measured reception state. Based on the comparison result of the reception state information comparison unit 174, the optimum method selection control unit 176 selects a communication method for measuring the reception state from among the 3G, S3G, and 4G communication methods, and selects the 3G, S3G, and 4G communication methods. A measurement cycle is set for the data reception processing unit corresponding to the selected communication method among the data reception processing units. The control unit 170 controls the data reception processing unit corresponding to the communication method selected by the optimum method selection unit 174 and measures the reception state.

Description

  The present invention relates to a mobile communication terminal apparatus and a communication system capable of performing communication by a plurality of communication methods.

  In a region where multiple services with different communication methods have been mixed, a mobile terminal that is already connected to one network becomes different when it becomes difficult to connect to that network as it moves. It is considered to switch to another type of network so that the connection can continue.

  As a communication method of a mobile terminal capable of communicating with a plurality of communication systems having different communication methods, for example, there is one disclosed in Patent Document 1. This Patent Document 1 describes a mobile that can communicate with both wireless LAN (Local Area Network) and W-CDMA (Wideband Code Division Multiple Access), which is a third generation mobile communication system (hereinafter referred to as “3G”). A wireless communication system comprising a terminal is disclosed. The mobile terminal in Patent Document 1 determines a communication system that accommodates a radio access station that is a destination, based on the received quality of a received downlink signal. In Patent Document 1, a database in a network is referred to based on type information of a wireless system notified from a mobile terminal, and a handover method that satisfies the request of the mobile terminal is selected on the server side.

Further, in Patent Document 2, when base stations of different generations using a CDMA (Code Division Multiple Access) communication method are arranged separately for each area and the mobile station moves from one area to an area of a different generation, A method for switching between stations and realizing handover between base stations without disconnection is described.
JP 2004-260444 A JP 2000-201369 A

  By the way, in the mobile communication system, a service-in of a fourth generation mobile communication system (hereinafter referred to as “4G”) is scheduled. In the process leading to 4G, Super 3G (hereinafter referred to as “3G”), which is an intermediate position between 3G and 4G, aims to smoothly transition from the existing third generation mobile communication system (hereinafter referred to as “3G”). S3G ") has been proposed.

  3G is a communication method represented by W-CDMA and CDMA2000, the frequency band is 2 GHz, and the trunk network is an ATM network. Further, S3G is a communication method that has been studied using a 1.7 or 2.5 GHz band as a use frequency band. In S3G, “VSF-OFDM (Variable Spreading Factor, Orthogonal Frequency and Code Division Multiplexing)” is used for downlink, and “DS-CDMA (Direct Spread Code Division Multiple Access)” is used for uplink, and the data transfer rate is 100 Mbps at rest, The moving time is 30 Mbps, and the delay time is 2.0 ms or less with respect to the current about 10 ms. The S3G trunk network is an IP network. Furthermore, 4G uses the same technology as S3G with a usage frequency band of 5 GHz, and has a frequency band for 100 MHz centered on 4.635 GHz for downstream and 30 MHz centered on 4.9 GHz for upstream. It is used. This 4G is introduced by adding MIMO (Multiple Input, Multiple Output) using multiple antennas to the existing wireless system, and the data transfer rate is 1 Gbps when stationary and 100 Mbps when moving, Is an IP network.

  In an area where a plurality of communication scheme areas having different frequency bands and transmission speeds (bit rates) such as 3G, S3G, and 4G are mixed, a mobile terminal communication system that can communicate with each communication scheme is provided. There is a desire to realize it.

  In order to realize this, in an area where a plurality of services having different communication methods such as 3G area, S3G area, and 4G area are mixed, the mobile terminal receives a receiving device and a transmission for different frequencies such as 3G, S3G, and 4G. Device. In particular, when the base stations of communication systems having different frequencies do not mutually exchange cell information in the respective areas, it is necessary to first perform a cell search for the base stations of all communication systems on the mobile terminal side. . In addition, after that, since it becomes necessary to always receive and decode the signals of the respective systems, the power consumption increases.

  Also, in order to realize a communication system in which a mobile terminal can use a plurality of services with different communication methods, the mobile terminal selects a bit rate with priority over a network with a plurality of communication methods with different frequency bands. A case where a communication method is determined can be considered. In this case, first of all, in all communication methods (3G, S3G, 4G), cell search is performed to measure each communication state, and the communication method is always switched to a speedy communication method. Since it is necessary to receive and demodulate (3G, S3G, 4G) signals, the power consumption increases.

  Furthermore, in the case where base stations having different communication methods such as 3G, S3G, and 4G exchange cell information with each other, after connecting to the cell having the maximum reception level of the downlink pilot channel, The neighboring cell information is obtained by receiving and decoding the broadcast information. Then, after connecting to the base station with the maximum reception level among the base stations of the three communication systems having different frequency bands, it is conceivable that the neighboring cell information is obtained and handed over to an appropriate cell at any time.

  However, even if it is known that there is a cell in the vicinity, it is necessary to perform a cell search in order to determine whether the condition is optimal for the terminal. For this reason, it is necessary for the mobile terminal to periodically check all reception levels of signals transmitted from the base stations of the respective communication schemes, and power consumption increases accordingly.

  As described above, in a region where a plurality of services having different communication methods such as 3G area, S3G area, and 4G area are mixed, the mobile terminal uses reception devices and transmission devices for different frequencies such as 3G, S3G, and 4G. Because radio waves in different frequency bands are always monitored, power is consumed in each of the transmission / reception receivers and transmitters of different frequency bands, resulting in very large power consumption. A problem occurs.

  Further, in an area where a plurality of services such as 3G area, S3G area, and 4G area are mixed, it is difficult to perform processing such as which communication system movement should be selected for cell search and handover.

  In Patent Literature 1, since the server side selects a handover method that satisfies the request of the mobile terminal based on the type information of the wireless system notified from the mobile terminal, it is not necessary to select the handover method on the mobile terminal side. However, it is not specifically disclosed how to determine and determine the reception quality for the various types of information of the wireless system to be determined.

  Further, Patent Document 2 discloses a method for selecting a plurality of generations (2G, 3G) of base stations with different communication methods performed by a mobile terminal. However, a description for saving power when selecting a base station is disclosed. It is not disclosed at all.

  An object of the present invention is to provide a mobile communication terminal apparatus and a communication system that can smoothly communicate with each of a plurality of communication systems having different frequency bands and achieve power saving.

  The mobile communication terminal device of the present invention receives a battery and signals of the first, second, and third communication methods that are driven by the battery and have different use frequency bands and communication areas, respectively, via an antenna, First, second and third receiving means for measuring reception states for each of the first, second and third communication schemes from received signals and outputting as reception state information each including a received power value; Based on the remaining battery level of the battery and the reception status information for each of the first, second and third receiving means, one or two receiving means among the first, second and third receiving means Using the control unit that sets the measurement cycle of the reception state, controls the one or two reception units according to the set measurement cycle, and measures the reception state, and the reception state information indicating the measured reception state Said first, second and second A communication unit for comparing the received power in the communication method and a communication method for measuring the reception state is selected from the first, second and third communication methods based on the comparison result of the comparison unit. And a method selecting unit that sets the measurement period for a receiving unit corresponding to the selected communication method among the first, second, and third receiving units, and the control unit includes the method selecting unit. Adopts a configuration in which the reception unit corresponding to the communication method selected by the user is controlled to measure the reception state.

  As described above, according to the present invention, communication is possible with each of a plurality of communication systems having different frequency bands, and power saving can be achieved.

The figure which shows an example of the communication system which has a mobile communication terminal which concerns on one embodiment of this invention The figure which shows an example of the relationship between the received signal strength and receiving position of each system which the mobile communication terminal shown to FIG. 1A receives The figure which shows an example of the relationship between the received signal strength and frequency of each system which the mobile communication terminal shown to FIG. 1A receives The block diagram which shows schematic structure of the mobile terminal as a mobile communication terminal device which concerns on one embodiment of this invention The block diagram which shows the principal part structure of the control part in the mobile communication terminal shown in FIG. The figure which shows the relationship between the electric power remaining amount of the battery stored in memory, and the time period at the time of measuring a communication state Flowchart explaining basic processing of mobile terminal according to the present embodiment The figure which shows the modification of the data reception process part for 3G The figure which shows another modification of the data reception process part for 3G Flowchart for explaining an example of a communication method selection method as processing of a mobile terminal according to the present invention A flowchart for explaining an example of processing for checking a signal level of a 4G communication method when a mobile terminal moves in the A direction in a communication system. The figure which shows another example of the selection method of the communication system in a mobile terminal Flowchart explaining processing when power level difference of received signal measured first is small The block diagram which shows schematic structure of the mobile terminal which is another example of the mobile communication terminal device which belongs to the communication system which concerns on embodiment of this invention. The block diagram which shows the principal part structure of the control part in the mobile terminal shown in FIG. The figure which shows an example of the received signal of the communication system which is the same power value and has a different power peak when measuring the received signal of a different communication system

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The mobile communication terminal apparatus (hereinafter referred to as “mobile terminal”) in the present embodiment is compatible with a plurality of communication systems having different usage frequency bands and communication areas, and the areas of these communication systems (service network). ) Are overlapping.

  Here, areas of a plurality of communication schemes having different utilization frequency bands and different sizes of utilization frequencies and communication areas are defined as areas of the first to third communication schemes. The bit rate is assumed to be higher in the order up to 3. Furthermore, the communication areas of the first to third communication methods are narrower in the order of the first to third.

  Specifically, an area of the second communication method that has a different frequency band from the first communication method and a higher bit rate than the first communication method exists within the area of the first communication method. In addition, within the area of the second communication method, there is an area of the third communication method that has a different frequency band from the second communication method and a higher bit rate than the second communication method.

  FIG. 1 is a diagram for explaining a communication state in a communication system 200 of a mobile communication terminal 100 according to an embodiment of the present invention, and FIG. 1A is a communication system having a mobile communication terminal according to an embodiment of the present invention. It is a figure which shows an example. FIG. 1B is a diagram showing an example of the relationship between the received signal strength of each method received by the mobile communication terminal shown in FIG. 1A and the reception position, and FIG. 1C is the received signal of each method received by the mobile communication terminal shown in FIG. 1A. It is a figure which shows an example of the relationship between an intensity | strength and a frequency.

  Mobile terminal 100 of the present embodiment shown in FIG. 1A can communicate with each of a plurality of communication methods. Here, a plurality of communication methods having different frequency bands and bit rates used for communication are referred to as first to third communication methods, and the communication areas are overlapped and the bit rates are increased in order, 3G, S3G, 4G. And

  First, a communication system to which the mobile terminal 100 belongs will be described.

  In the communication system 200 to which the mobile terminal 100 shown in FIG. 1A belongs, the S3G base station 220 and the S3G communication area (S3G service area 221) are included in the 3G communication area (3G service area 211) by the 3G base station 210. Is arranged. In addition, a 4G base station 230 is arranged in the S3G communication area (S3G service area 221), and a communication area (4G service area 231) by the 4G base station 230 is arranged. 1B and 1C correspond to the case where the mobile terminal 100 moves in the arrow direction (arrow A direction) in the communication system 200 shown in FIG. 1A.

  That is, FIG. 1B shows the signal strength when the mobile terminal 100 receives signals transmitted from the base stations 210 to 230 of each communication method when the mobile terminal 100 moves in the A direction in the communication system 200 of FIG. 1A. Yes. Specifically, in FIG. 1B, a graph 212 shows an example of signal strength in the mobile terminal 100 when a radio signal is received from the 3G base station 210 that is a signal in the frequency band of 2 GHz. A graph 222 shows an example of signal strength in the mobile terminal 100 when a radio signal is received from the S3G base station 220 that is a signal having a frequency of 1.7 or 2.5 GHz. Further, the graph 232 shows an example of the reception intensity in the mobile terminal 100 when a radio signal is received from the 4G base station 230 that is a signal in the frequency band of 5 GHz.

  FIG. 1C shows the relationship between the signal strength and the frequency when the spread signal transmitted from each base station 210 to 230 is received by the mobile terminal 100, and the graph 213 is output from the 3G base station. A graph 223 shows an example of a modulation signal output from an S3G base station, and a graph 233 shows an example of a modulation signal output from a 4G base station.

  FIG. 2 is a block diagram showing a schematic configuration of a mobile terminal as a mobile communication terminal apparatus according to an embodiment of the present invention.

  The mobile terminal 100 shown in FIG. 2 has a function of transmitting and receiving data corresponding to each of a plurality of communication methods in the communication system 200. In the mobile terminal 100, the communication method used when transmitting and receiving data is measured by changing the time interval for measuring signals from the base stations 210, 220, and 230 for each communication method, and determined based on the measured value. Is done.

  The mobile terminal 100 shown in FIG. 2 corresponds to a data transmission method selection unit 102, data transmission processing units 110, 120, and 130 that transmit data corresponding to each of a plurality of communication methods, and each of a plurality of communication methods. Data reception processing units 140, 150, and 160 that receive data, filters 105 and 106, multiplexer / demultiplexer 107, antenna 108, control unit 170, memory 190, and battery (shown as battery 195 in the figure) 195 are provided.

  The data transmission processing units 110, 120, and 130 and the data reception processing units 140, 150, and 160 correspond to 3G, S3G, and 4G, respectively. Each processing unit that performs transmission / reception processing with the 3G base station 210 is a 3G data transmission processing unit 110, 3G data reception processing unit 140, and each processing unit that performs transmission / reception processing with the S3G base station 220 is S3G data transmission processing unit. 120, the 3G data reception processing unit 150, and each processing unit that performs transmission / reception processing with the 4G base station 230 will be described as a 4G data transmission processing unit 130 and a 4G data reception processing unit 160.

  Based on the control information input from the control unit 170, the data transmission method selection unit 102 selects which communication method information is to be transmitted from among a plurality of communication methods. Then, the data transmission method selection unit 102 outputs information to be transmitted to the data transmission processing unit corresponding to the selected communication method. Specifically, when the communication method for transmitting information is one of 3G, S3G, and 4G communication methods, the input signal input to the data transmission method selection unit 102 is the 3G data transmission processing unit 110, The data is output to one of the S3G data transmission processing unit 120 and the 4G data transmission processing unit 130.

  The 3G data transmission processing unit 110, the S3G data transmission processing unit 120, and the 4G data transmission processing unit 130 each transmit an input signal input via the data transmission method selection unit 102 as information of a corresponding communication method. Processing is performed as possible, and the result is output to the filter 105. The signal input to the filter 105 is transmitted as a radio signal from the antenna 108 via the multiplexer / demultiplexer 107.

  Here, the 3G data transmission processing unit 110, the S3G data transmission processing unit 120, and the 4G data transmission processing unit 130 process the input signals according to the respective communication schemes, and can transmit information according to the respective communication schemes. To. As a specific configuration, each of the data transmission processing units 110, 120, and 130 processes the input signal input from the data transmission method selection unit 102 with the encoding processing units 112, 122, 132, modulation processing units 113, 123, and 133, transmission processing units 114, 124, and 134, and amplifiers 115, 125, and 135. The amplifiers 115, 125, and 135 are shown as a 3G amplifier 115, an S3G amplifier 125, and a 4G amplifier 135 in FIG. 2 in accordance with the communication method used for each process.

  The encoding processing units 112, 122, and 132 encode input signals using the respective communication methods, and output the encoded signals to the modulation processing units 113, 123, and 133.

  Modulation processing sections 113, 123, and 133 perform modulation processing on the signals input from encoding processing sections 112, 122, and 132 using the respective communication methods, and output the result to transmission processing sections 114, 124, and 134.

  The transmission processing units 114, 124, and 134 up-convert the signals input from the modulation processing units 113, 123, and 133, convert the signals into signals of frequencies used in the respective communication systems, and each communication system amplifier. 115, 125 and 135.

  The 3G amplifier 115, the S3G amplifier 125, and the 4G amplifier 135 cause the signals input from the transmission processing units 114, 124, and 134 to have signal levels suitable for the transmission frequency used in each communication method. Amplified and output to the filter 105.

  Here, the data reception processing units 140, 150, and 160 corresponding to each communication method correspond to 3G, S3G, and 4G, respectively, and signals (3G, S3G, and 4G) correspond to each communication method (3G, S3G, and 4G). Data). Here, the data reception processing units 140, 150, and 160 corresponding to each communication method are illustrated as a 3G data reception processing unit 140, an S3G data reception processing unit 150, and a 4G data reception processing unit 160, respectively. .

  Each of the data reception processing units 140, 150, and 160 passes through the antenna 108 and the multiplexer / demultiplexer 107, and then receives a radio signal (data) distributed for each usage frequency of 3G, S3G, and 4G via the filter 106. Entered. Each data reception processing unit 140, 150, 160 measures and controls reception state information of a radio signal that serves as an index for selecting a communication method to be used in the control unit 170 based on the input radio signal. In addition to outputting to unit 170, the received signal is output to the outside as data. In FIG. 2, each data reception processing unit 140, 150, 160 measures the total received power in each communication method at a predetermined time period set by the control unit 170 as reception state information.

  Each data reception processing unit 140, 150, 160 will be described in detail.

  The 3G, S3G, and 4G data reception processing units 140, 150, and 160 are 3G, S3G, and 4G low noise amplifiers 142, 152, 162, 3G, and S3G that perform processing in their respective communication methods. 4G power intensity measurement units 143, 153, 163, reception processing units 144, 154, 164, demodulation processing units 145, 155, 165, and decoding processing units 146, 156, 166 are provided.

  The 3G, S3G, and 4G low noise amplifiers 142, 152, and 162 amplify the input signal while keeping the additional noise small, and the 3G, S3G, and 4G power intensity measuring units 143, 153, 163 and the reception processing units 144, 154, and 164.

  The reception processing units 144, 154, and 164 perform down-conversion and automatic gain control (AGC) processing on input signals from the 3G, S3G, and 4G low noise amplifiers 142, 152, and 162. . Then, the reception processing units 144, 154, and 164 output the processed input signals to the demodulation processing units 145, 155, and 165.

  The demodulation processing units 145, 155, and 165 demodulate the input signals by performing processing such as despreading processing, and the demodulated signals are output to the decoding processing units 146, 156, and 166 for decoding. Decoding is performed in the processing units 146, 156, and 166.

  The signals decoded by the decoding processing units 146, 156, and 166 are output to the outside as data via the external output device 104 provided in the mobile terminal 100. Examples of the external output device 104 include an LED (Light-Emitting Diode), a display device such as a liquid crystal display, a sound output device that outputs sound such as a speaker, and a storage device.

  The 3G, S3G, and 4G power strength measuring units 143, 153, and 163 respectively receive the power strength of the input signals, specifically, the total received power P_ALL_3G_last, P_ALL_S3G_last, Measure P_ALL_4G_last. These measurement results are output to the control unit 170. Note that “_last” means the latest data of the measurement result in this embodiment.

  In response to these measurement results, the control unit 170 selects a communication method to be used and performs data reception processing units 140, 150, 160 for 3G, S3G, and 4G in order to perform reception processing in the selected communication method. The corresponding data reception processing unit is controlled to perform reception processing, and the data subjected to the reception processing is output to the external output device 104.

  FIG. 3 is a block diagram showing a main configuration of the control unit 170 in the mobile communication terminal shown in FIG.

  The control unit 170 performs communication based on signals input from the 3G, S3G, and 4G data reception processing units 140, 150, and 160, information from the memory 190, and information on the battery 195 (in this case, 3G, S3G, 4G), and by using the selection result, the data transmission method selection unit 102 uses which transmission method to transmit the input signal input to the data transmission method selection unit 102 as information To decide.

  As illustrated in FIG. 3, the control unit 170 includes a remaining battery level detection unit 172, a reception state information comparison unit 174, and an optimum method selection control unit 176.

  The battery remaining amount detection unit 172 detects the remaining amount of power of the battery 195 connected to the control unit 170, and is controlled by the optimum method selection control unit 176 to output to the optimum method selection control unit 176.

  The reception status information comparison unit 174 uses the reception status information, which is a signal input from the 3G data reception processing unit 140, the S3G data reception processing unit 150, and the 4G data reception processing unit 160, to determine the base of each communication method. The reception states of the signals from the stations 210, 220, and 230 are compared, and the comparison result is output to the optimum method selection control unit 176.

  The reception state information comparison unit 174 may use the signals input from the data reception processing units 140, 150, and 160 as comparison targets as they are, or extract other reference information from the input signals. Then, the extracted information may be compared. Furthermore, the input signal may be compared with a preset threshold value, or information extracted from the input signal may be compared with a preset threshold value. The reception state information comparison unit 174 is controlled by the optimum method selection control unit 176.

  Here, the reception state information includes the power intensity (reception power) of signals input from the 3G power intensity measurement unit 143, the S3G power intensity measurement unit 153, and the 4G power intensity measurement unit 163, that is, each communication method ( 3G, S3G, 4G) is a received power level of a signal received.

  Therefore, in the present embodiment, reception state information comparison section 174 compares the signal power strengths in 3G, S3G, and 4G.

  Based on information such as a control table stored in the remaining battery level detection unit 172, the reception status information comparison unit 174, and the memory 190, the optimum method selection control unit 176 is the communication most suitable for communication in the actual radio wave propagation environment state. Select a method.

  Specifically, the optimum method selection control unit 176 measures the received signals in descending order when the power values of the received signals from the respective communication methods output as the comparison results output by the reception state information comparing unit 174 are different. A time period setting unit 177 is provided for setting periods T1, T2, and T3 (where T1 ≦ T2 ≦ T3). At this time, the time cycle setting unit 177 sets T3 = ∞ so that the actual measurement is performed only in the communication method with the time cycles of T1 and T2. That is, by setting T3 = ∞, the time period for the communication method with the smallest received signal power value among the three communication methods, in other words, the communication method with the smallest received power intensity among the three communication methods. Do not set. As described above, when the time period for measuring the reception signal of the predetermined signal system is not set, T = 0 may be used instead of the time period T = ∞.

  Further, when the power values of the received signals in the plurality of communication methods are the same, the optimum method selection control unit 176 selects the communication method set as the default value.

  Then, the optimal method selection control unit 176 sends a time period to the 3G data reception processing unit 140, the S3G data reception processing unit 150, and the 4G data reception processing unit 160 in order to transmit and receive data according to the selected communication method. The setting unit 177 outputs and controls a control signal that causes the reception state to be measured at each set time period.

  That is, in the optimum method selection control unit 176, the time period setting unit 177 receives signals from the corresponding base stations 210, 220, and 230 for the 3G, S3G, and 4G data reception processing units 140, 150, and 160, respectively. Set the time period (T1, T2, T3) for measuring.

  By assigning these set time periods to the data reception processing units 140, 150, and 160, the optimum method selection control unit 176 selects the communication method in which the reception state (in this case, the received signal strength) is actually measured. is doing.

  In the optimum method selection control unit 176, the setting of the time period in the time period setting unit 177 is associated with the remaining power level of the battery 195, and the remaining power level of the battery 195 stored in the memory 190 (remaining battery level). And the base station check time T. Specifically, the setting of the time period is synonymous with the setting of which received signal is measured for the received signal among the received signals from the 3G, S3G, and 4G base stations 210, 220, and 230. .

  FIG. 4 is a diagram illustrating an example of the relationship between the remaining power of the battery 195 stored in the memory 190 (battery remaining amount) and the time period when the communication state is measured. This figure shows the association between the remaining battery level and the time period (T_3G, T_S3G, T_4G) at which the mobile terminal 100 checks the base station of each communication method.

  As shown in FIG. 4, when the remaining power of the battery 195 of the mobile terminal 100 is large, the reception state (signal strength) measurement time period T for each communication method is short, and base stations for all communication methods Measure signals from 210, 220, 230. Further, as shown in FIG. 4, as the remaining battery level decreases, the number of communication methods to be measured in the reception state decreases.

  The memory 190 stores information used in communication in addition to a control table such as a table (see FIG. 4) showing a relationship between the remaining amount of power of the battery 195 (remaining battery amount) and the time period when the communication state is measured. The data can be stored and read / written under the control of the optimum method selection control unit 176. In the control table stored in the memory 190, the average of the circuits constituting the data transmission / reception unit of each communication method, the received power level or propagation loss, the SIR value (Signal to Interference power Ratio), in the remaining battery level and time period of the battery 195 The power consumption value is associated. Instead of the SIR value, a BER (Bit Error Rate) value and a FER (Flame Error Rate) value may be associated. Needless to say, the elements associated in these control tables may be associated with only elements as necessary. Information used in communication stored in the memory 190 includes transmission information from the power intensity measuring units 143, 153, and 163, and base stations 210, 220, and 230 (see FIG. 1) having different communication methods. is there.

  Next, the operation of mobile terminal 100 having the above configuration will be described with reference to FIG. FIG. 5 is a flowchart for explaining basic processing of mobile terminal 100 according to the present embodiment.

  First, in step S101, the mobile terminal 100 is turned on. In step S102, the 3G data reception processing unit 140 measures the total received power P_ALL_3G_last in the frequency band used in the 3G system, and the process proceeds to step S103. To do. “_Last” means the latest data of the measurement result.

  In step S103, the S3G data reception processing unit 150 measures the total received power P_ALL_S3G_last in the frequency band used in S3G, and proceeds to step S104.

  In step S104, the 4G data reception processing unit 160 measures the total received power P_ALL_4G_last in the frequency band used in 4G, and proceeds to step S105.

  In step S105, the remaining battery level detection unit 172 measures the remaining power level of the battery 195, and the reception status information comparison unit 174 uses the total received power P_ALL_3G_last in the frequency band used in 3G and the frequency used in S3G. The reception state of each communication method (3G, S3G, 4G) is compared using the total reception power P_ALL_4G_last in the frequency band used in the total reception power P_ALL_S3G_last, 4G in the band, and the process proceeds to step S106. The comparison of the reception status of each communication method in step S106 is, for example, the total received power P_ALL_3G_last in the frequency band used in 3G, the total received power P_ALL_S3G_last in the frequency band used in S3G, and the total in the frequency band used in 4G. This is a comparison of the received power P_ALL_4G_last.

  In step S106, the optimum method selection control unit 176 uses the time period setting unit 177 based on the comparison result by the reception state information comparison unit 174 and the information from the memory 190, and the frequency band used in 3G, S3G, and 4G. T1, T2, T3 (however, T1 ≤ T2 ≤ T3) in the time period (T_3G, T_S3G, T_4G) for measuring (checking) the received signal in descending order of the power value among all received power P_ALL_3G_last, P_ALL_S3G_last, P_ALL_4G_last ) Is set.

  In this step S106, when all the received powers P_ALL_3G_last, P_ALL_S3G_last, P_ALL_4G_last in each communication method (3G, S3G, 4G) are equal and the remaining battery level is low, the optimum method selection control unit 176 The time periods T1, T2, and T3 are set in ascending order of the average power consumption value of the transmission / reception circuit.

  This is because the power consumption of electronic circuits constituting an amplifier (amplifier), a modulation unit, a demodulation unit, and the like in a used frequency band is different in each communication method. That is, the time period is set so that a communication method with low average power consumption in the electronic circuit constituting the processing unit is selected from the data transmission / reception processing units 110, 120, 130, 140, 150, and 160 of each communication method. To do. After step S106, the process proceeds to step S107.

  In step S107, the optimum method selection control unit 176 outputs the time periods T1 to T3 set in step S106 to each data reception processing unit 140, 150, 160, and in each data reception processing unit 140, 150, 160, Based on the input time period, the reception state (reception power value here) of the reception signal for each base station of each communication method is checked. In order to set the time period for checking the reception state of signals transmitted from these base stations for each base station of each communication system, the transmission signal of the communication system to be measured is determined by changing the time period. For example, when T3 = infinity is set, only the reception state of the reception signal of the communication method in which the time periods T1 and T2 are set is checked.

  The optimum method selection control unit 176 uses the time period setting unit 177 to set the time period for checking the received signal of each communication method, thereby communicating which communication method from a plurality of communication methods (3G, S3G, 4G). The information on the determined communication method is output to the data transmission method selection unit 102. Further, the determined information is output to the corresponding transmission processing units 110, 120, and 130.

  As described above, the transmission / reception processing units 110, 120, 130, 140, 150, and 160 change the signal measurement time period for each communication method as the time periods T1, T2, and T3 for measuring the signal from the base station. I am letting. Here, since the time period is set to T1 ≦ T2 ≦ T3 and T3 = infinity, the communication method in which the time period is T3 does not actually set the time period to be measured. In the mobile terminal 100, the time period is T1. Only the T2 communication method is actually measured.

  Therefore, it is possible to achieve both low power consumption, reduced processing amount, and high bit rate in order to measure a received signal of a communication method with a large received power without always measuring signals from base stations of all communication methods. It becomes possible.

  In each data reception processing unit 140, 150, 160 of the present embodiment, the power intensity measurement units 143, 153, 163 are after the low noise amplifiers 142, 152, 162 in the processing units 140, 150, 160, respectively. Although arranged, it is not limited to this.

  For example, in the same configuration as each data reception processing unit 140, 150, 160, it may be arranged after the demodulation processing units 145, 155, 165 instead of after the low noise amplifiers 142, 152, 162.

  An example of this is shown in FIG. FIG. 6 is a diagram illustrating a first modification of the data reception processing unit.

  FIG. 6 is a diagram showing a 3G data reception processing unit 140a which is a modification 1 of the 3G data reception processing unit 140. In this data reception processing unit 140a, the 3G power intensity measurement unit 143 is a demodulation processing unit 145. Is placed after.

  According to this configuration, the received signal which is the target when the 3G power intensity measurement unit 143 measures the power intensity is subjected to demodulation processing such as despreading processing in the demodulation processing unit 145 before measuring the power intensity. Will be given. Therefore, more accurate power intensity can be measured when the power intensity is measured in the 3G data reception processing unit 140 shown in FIG.

  In the mobile terminal 100, when the 3G data reception processing unit 140 is changed to the 3G data reception processing unit 140a, S3G and 4G data reception processing units 150 and 160 (see FIG. 2), which are other communication methods, are also used. The configuration is the same as that of the 3G data reception processing unit 140a. That is, in each of the S3G and 4G data reception processing units 150 and 160 (see FIG. 2), the S3G and 4G power intensity measurement units are not after the low noise amplifiers 152 and 162, but the demodulation processing unit 155, It is arranged after 165 and performs processing on the input signal. With this configuration, the same power and effect as those obtained when the 3G data reception processing unit 140a is changed to the 3G data reception processing unit 140, that is, accurate power intensity is also measured in S3G and 4G.

  Furthermore, in each of the data reception processing units 140, 150, and 160 of the present embodiment, the reception status information output to the control unit is the total reception power in the frequency band used in each communication method, but is not limited thereto. It may be a propagation loss in each communication method. In this case, each data reception processing unit 140, 150, 160 includes a propagation loss measurement unit for each communication method instead of the power intensity measurement unit for each communication method.

  FIG. 7 is a diagram illustrating a 3G data reception processing unit 140b as a modification 2 of the 3G data reception processing unit. The reception processing unit as the modification 2 is the same as the 3G data reception processing unit 140a of FIG. The 3G power intensity measurement unit 143 is replaced with a 3G propagation loss measurement unit 147. That is, in the data reception processing unit 140b, the 3G propagation loss measurement unit is arranged after the demodulation processing unit 145.

  As described above, the mobile terminal provided with the configuration of the data reception processing unit 140b as the modification 2 as a data reception processing unit corresponding to each different communication method is used in the control unit (corresponding to the control unit 170 shown in FIG. 2). A communication method for actual communication is determined based on information output from the propagation loss measurement unit provided in each of the data reception processing units having different communication methods.

  That is, the mobile terminal having the configuration of the data reception processing unit 140b of the second modification is controlled based on the propagation loss instead of the power intensity. Note that the propagation loss is generally calculated from the base station output power transmitted from the base station and the received power at the mobile terminal 100. In this case, the processing in the control unit is performed by replacing “P_ALL_last” shown in FIG. 5 with the reciprocal of the propagation loss.

  That is, the reception state information input from the data reception processing unit of the predetermined communication method to the reception state information comparison unit 174 includes a propagation loss, and the reception state information comparison unit 174 includes the first, second and third A propagation loss comparison unit that compares the propagation loss of the reception state information in the communication method with a preset specified value of the propagation loss is provided. The control unit configured as described above selects the communication method having the highest received power by the optimum method selection unit, measures the reception state of the selected communication method, and then selects the reception method by the reception state information comparison unit 174. When the propagation loss of the communication method is compared with the specified value of the propagation loss, and the propagation loss of the reception state information of the selected communication method is smaller than the specified value of the propagation loss, the communication previously selected by the optimum method selection control unit 176 A communication method other than the communication method is selected, and the reception state corresponding to the selected other communication method is measured.

  In the present embodiment, the time periods T1, T2, and T3 for measuring signals from the base station are set in the reception processing units 140, 150, and 160 as T1 ≦ T2 ≦ T3, T3 = infinity, and the time period Is actually measuring only the T1 and T2 communication methods, but this is not the only case, and it always reduces the power consumption and processing amount without measuring signals from base stations of all communication methods. As long as both a high bit rate and a high bit rate can be achieved, any configuration may be used.

  Specifically, first, the total reception powers P_ALL_3G_last, P_ALL_S3G_last, and P_ALL_4G_last of each communication method are measured using the data reception processing units 140, 150, and 160 of all communication methods. Thereafter, the optimum method selection control unit 176 checks only the signal with the highest signal level and the signal with the second highest signal level.

  Then, when the difference between No. 1 and No. 2 becomes smaller than a preset constant value (including reverse rotation), the signal level in the communication system which is the third signal level is measured. Then, the optimum method selection control unit 176 performs re-ranking using the received power of all the methods, and measures only the received power in the communication method in which the first and second highest signal levels are measured.

  This process will be described in detail.

  FIG. 8 is a flowchart for explaining an example of a communication method selection method as processing of the mobile terminal 100 according to the present invention.

  Prior to the process shown in FIG. 8, as in the process shown in FIG. 5, first, the mobile terminal 100 is turned on, and then the 3G data reception processing unit 140 is configured to operate in all frequency bands used in the 3G system. The reception power P_ALL_3G_last is measured, the S3G data reception processing unit 150 measures the total reception power P_ALL_S3G_last in the frequency band used in S3G, and the 4G data reception processing unit 160 performs the total reception in the frequency band used in 4G. The received power P_ALL_4G_last is being measured. Then, the remaining battery level detection unit 174 measures the remaining power level of the battery 195 and performs a communication method selection process.

  In this communication method selection method, in step S201, the reception state information comparison unit 174 first uses the frequency at which the total received power in the frequency band used in 3G (hereinafter referred to as “P_ALL_3G_last”) is used in S3G. If it is determined whether or not the received power is greater than the total received power in the band (hereinafter, described as “P_ALL_S3G_last”), the process proceeds to step S202. If not, the process proceeds to step S203.

  In step S202, it is determined whether or not P_ALL_S3G_last is greater than the total received power in the frequency band used in 4G (hereinafter described as “P_ALL_4G_last”). If larger, the process proceeds to step S204; The process proceeds to step S205.

  In step S204, the reception state information comparison unit 174 outputs a comparison determination result of P_ALL_3G_last> P_ALL_S3G_last> P_ALL_4G_last to the optimum method selection control unit 176, and proceeds to step S206.

  In step S206, the optimum method selection control unit 176 causes the time period setting unit 177 to set the time period for checking the signal from the base station in the order of the received power in the order of T1, T2, T3 (T1 ≦ T2 ≦ T3). And T3 = infinity) is set, and the process proceeds to step S207. Specifically, in step S206, T_3G = T1, T_S3G = T2, and T_4G = T3 = ∞ are set.

  In step S207, the reception state information comparison unit 174 is used to determine whether P_ALL_3G_last-P_ALL_S3G_last <specified value P1. If P_ALL_3G_last-P_ALL_S3G_last is smaller than the specified value P1, the process proceeds to step S208, and P_ALL_3G_last- If P_ALL_S3G_last is greater than or equal to the specified value P1, the process ends.

  In step S208, the 4G data reception processing unit 160 measures the total received power P_ALL_4G_last in the frequency band used in 4G, and proceeds to step S201.

  On the other hand, in step S205, P_ALL_3G_last> P_ALL_4G_last is determined. If P_ALL_3G_last> P_ALL_4G_last, the process proceeds to step S209, and if not satisfied, the process proceeds to step S210.

  In step S209, the reception state information comparison unit 174 outputs a comparison determination result of P_ALL_3G_last> P_ALL_4G_last> P_ALL_S3G_last to the optimum method selection control unit 176, and proceeds to step S211.

  In step S211, the optimum method selection control unit 176 causes the time period setting unit 177 to set the time period for checking the signal from the base station in the order of the received power in the order of T1, T2, T3 (T1 ≦ T2 ≦ T3). And T3 = infinity) is set, and the process proceeds to step S212. Specifically, in step S211, T_3G = T1, T_4G = T2, and T_S3G = T3 = ∞ are set.

  In step S212, the reception state information comparison unit 174 is used to determine whether P_ALL_3G_last-P_ALL_4G_last <specified value P2 or not. If P_ALL_3G_last-P_ALL_4G_last is smaller than the specified value P2, the process proceeds to step S213, and P_ALL_3G_last- If P_ALL_4G_last is greater than or equal to the specified value P2, the process ends.

  In step S213, the S3G data reception processing unit 150 measures the total received power P_ALL_S3G_last in the frequency band used in S3G, and proceeds to step S201.

  In step S210, the reception state information comparison unit 174 outputs a comparison result of P_ALL_4G_last> P_ALL_3G_last> P_ALL_S3G_last to the optimum method selection control unit 176, and proceeds to step S214.

  In step S214, the optimum method selection control unit 176 uses the time period setting unit 177 to set the time period for checking the signal from the base station in the order of the received power in the order of T1, T2, T3 (T1 ≦ T2 ≦ T3). And T3 = infinity) is set, and the process proceeds to step S215. Specifically, in step S214, T_4G = T1, T_3G = T2, and T_S3G = T3 = ∞ are set.

  In step S215, the reception state information comparison unit 174 is used to determine whether P_ALL_4G_last-P_ALL_3G_last <specified value P3. If P_ALL_4G_last-P_ALL_3G_last is smaller than the specified value P3, the process proceeds to step S213, and P_ALL_3G_last- If P_ALL_4G_last is greater than or equal to the specified value P3, the process ends.

  In step S203, the reception state information comparison unit 174 determines whether or not P_ALL_S3G_last> P_ALL_4G_last. If P_ALL_S3G_last> P_ALL_4G_last, the process proceeds to step S216, and if not, the process proceeds to step S217.

  In step S216, the reception state information comparison unit 174 determines whether or not P_ALL_3G_last> P_ALL_4G_last. If P_ALL_3G_last> P_ALL_4G_last, the process proceeds to step S218, and if not, the process proceeds to step S219.

  In step S218, the reception state information comparison unit 174 outputs a comparison result of P_ALL_S3G_last> P_ALL_3G_last> P_ALL_4G_last to the optimum method selection control unit 176, and proceeds to step S220.

  In step S220, the optimum method selection control unit 176 causes the time period setting unit 177 to check the time period for checking the signal from the base station in order from the method with the highest reception power, T1, T2, T3 (T1 ≦ T2 ≦ T3). And T3 = infinity) is set, and the process proceeds to step S221. Specifically, in step S220, T_S3G = T1, T_3G = T2, and T_4G = T3 = ∞ are set.

  In step S221, the reception state information comparison unit 174 is used to determine whether P_ALL_S3G_last-P_ALL_3G_last <specified value P4. If P_ALL_S3G_last-P_ALL_3G_last is smaller than the specified value P4, the process proceeds to step S208 and P_ALL_S3G_last- If P_ALL_3G_last is greater than or equal to the specified value P4, the process ends.

  In step S219, the reception state information comparison unit 174 outputs a comparison result of P_ALL_S3G_last> P_ALL_4G_last> P_ALL_3G_last to the optimum method selection control unit 176, and proceeds to step S222.

  In step S222, the optimum method selection control unit 176 causes the time period setting unit 177 to set the time period for checking the signal from the base station in order from the method with the highest reception power, T1, T2, T3 (T1 ≦ T2 ≦ T3). And T3 = infinity) is set, and the process proceeds to step S223. Specifically, in step S222, T_S3G = T1, T_4G = T2, and T_3G = T3 = ∞ are set.

  In step S223, the reception state information comparison unit 174 is used to determine whether P_ALL_S3G_last-P_ALL_4G_last <specified value P5. If P_ALL_S3G_last-P_ALL_4G_last is smaller than the specified value P5, the process proceeds to step S224 and P_ALL_S3G_last- If P_ALL_4G_last is equal to or greater than the specified value P5, the process ends.

  In step S224, the 3G data reception processing unit 140 measures the total received power P_ALL_3G_last in the frequency band used in 3G, and proceeds to step S201.

  In step S217, the reception state information comparison unit 174 outputs a comparison result of P_ALL_4G_last> P_ALL_S3G_last> P_ALL_3G_last to the optimum method selection control unit 176, and proceeds to step S225.

  In step S225, the optimum method selection control unit 176 causes the time period setting unit 177 to check the time period for checking the signal from the base station in the order of the received power in the order of T1, T2, T3 (T1 ≦ T2 ≦ T3). And T3 = infinity) is set, and the process proceeds to step S226. Specifically, in step S225, T4 = T1, T_S3G = T2, and T_3G = T3 = ∞ are set.

  In step S226, the reception state information comparison unit 174 is used to determine whether P_ALL_4G_last-P_ALL_S3G_last <specified value P6. If P_ALL_4G_last-P_ALL_S3G_last is smaller than the specified value P6, the process proceeds to step S224, and P_ALL_4G_last- If P_ALL_S3G_last is greater than or equal to the specified value P6, the process ends.

  In step S224, the 3G data reception processing unit 140 measures the total received power P_ALL_3G_last in the frequency band used in 3G, and proceeds to step S201.

  That is, the above-described communication method selection method classifies the cases of steps S204, S209, S210, and S217 to S219 for each large and small pattern of the total received power in the frequency bands used in 3G, S3G, and 4G. Thereafter, in steps S206, S211, S214, S220, S222, and S225, the time period for checking the signal from the base station is set to T1, T2, T3 (however, T1 ≦ T2 ≦ T3) in order from the system having the highest received power. , T3 = infinity), and change the time period to be checked for each method.

  Next, in steps S207, S212, S215, S221, S223, and S226, the received power difference of the method in which T1 and T2 are selected as the signal check period in steps S206, S211, S214, S220, S222, and S225, that is, received power ( It is determined whether the (true number) ratio is smaller than a prescribed value Pn (n = 1, 2, 3...). As a result of this determination, if the received power difference of the method in which T1 and T2 are selected is smaller than Pn, the frequency used in the method in which T3 is selected as the signal check period in steps S206, S211, S214, S220, S222, and S225. After measuring the total received power in the band, the process returns to step S201, and the received signals of each method are ranked again. If larger, the process is terminated. As described above, in this embodiment, it is possible to achieve both low power consumption, reduction in processing amount, and high bit rate.

  Further, in the communication system 200, the mobile terminal 100 assumes that the area 231 of the 4G base station 230 exists in the area 221 of the S3G base station 220. Therefore, for the 4G communication scheme, the S3G signal level is 3G. The signal level may be checked when it becomes higher.

  FIG. 9 is a flowchart for explaining an example of processing for checking the signal level of the 4G communication method when the mobile terminal 100 moves in the direction A in the communication system 200.

  As shown in FIG. 9, in step S301, the 3G reception data processing unit 140 measures the total received power P_ALL_3G_last in the frequency band used in 3G. Next, in step S302, the 3G reception data processing unit 150 measures the total received power P_ALL_S3G_last in the frequency band used in S3G, and proceeds to step S303.

  In step S303, the reception state information comparison unit 174 determines whether the difference between the total received power P_ALL_3G_last in the frequency band used in 3G and the total received power P_ALL_S3G_last in the frequency band used in S3G is larger than the specified value P7. Compare if small. If this difference is small, the process proceeds to step S304. If the difference is large, the process proceeds to step S305, and the time periods for checking signals from the 3G, S3G, and 4G base stations 210, 220, and 230 are set to T1, After setting T2 and T3 (= ∞), the process is terminated.

  In step S304, the 4G reception data processing unit 160 measures the total received power P_ALL_4G_last in the frequency band used in 4G, and proceeds to step S306.

  In step S306, the reception state information comparison unit 174 compares the difference between the total received power P_ALL_S3G_last in the frequency band used in S3G and the total received power P_ALL_4G_last in the frequency band used in 4G with the specified value P8, If the difference is small, the process proceeds to step S307, and if the difference is large, the process proceeds to step S308.

  In step S307, which is processing when (P_ALL_S3G_last)-(P_ALL_4G_last) <P8, the optimum scheme selection control unit 176 uses the time period setting unit 177 to start from the 4G, S3G, and 3G base stations 210, 220, and 230. The time periods for checking the signals are set to T1, T2, and T3 (= ∞), respectively, and then the process ends.

  In step S308, which is processing when (P_ALL_S3G_last) − (P_ALL_4G_last) ≧ P8, time periods for checking signals from the S3G, 4G, and 3G base stations 210, 220, and 230 are set to T1, T2, and T3 (= ∞, respectively). After that, the process ends.

  As described above, for the 4G communication method in the mobile terminal 100, the signal level is checked when the S3G signal level becomes higher than 3G. Therefore, the reception signal levels of the three communication methods are always set. In the mobile terminal 100 in the communication system 200, it is possible to achieve both low power consumption, reduced processing amount, and high bit rate.

  In addition, the mobile terminal 100 may first measure the reception states of all communication methods, and check only the first one thereafter. That is, another communication method may be checked only when the communication method being used is about to be cut off (when the communication method is smaller than another specified value).

  FIG. 10 is a diagram illustrating another example of a communication method selection method in the mobile terminal 100.

  First, the 3G, S3G, and 4G data reception processing units 140, 150, and 160 measure all received powers P_ALL_3G_last, P_ALL_S3G_last, and P_ALL_4G_last in frequency bands used in 3G, S3G, and 4G, respectively. Further, the remaining battery level detection unit 172 measures the remaining power level of the battery 195. After these processes, the mobile terminal 100 performs a communication method selection process as shown in FIG.

  That is, as illustrated in FIG. 10, in steps S401 to S403, the reception state information comparison unit 174 performs the total received power P_ALL_3G_last in the frequency band used in 3G, the total received power P_ALL_S3G_last in the frequency band used in S3G, The total received power P_ALL_4G_last in the frequency band used in 4G is compared and determined.

  Thereafter, in steps S404, S411, and S417, based on the determination result of the reception state information comparison unit 174, the optimum method selection control unit 176 has the maximum received power in the frequency bands used in 3G, S3G, and 4G. Let T1 be the signal check time period for one method and infinity for the other methods.

  After that, in steps S405, S412, and S418, the reception state information comparison unit 174 determines whether or not the received signal power of the method in which the signal check time period is T1 is smaller than the specified value. In each of these steps S405, S412, and S418, if the determination result is large, the process returns to steps S405, S412, and S418, respectively, and the signal check time period is set to the check time T1 without changing to another communication method. Check the signal from the base station of T1.

  On the other hand, in these steps S405, S412, and S418, if the determination result is small, the process proceeds to steps S406, S413, and S419, respectively.

  In steps S406, S407, S413, S414, S419, and S420, the total received power in the frequency band used in the method in which the check time is set to ∞ in the previous steps S404, S411, and S417 is measured.

  In steps S408, S415, and S421, the reception state information comparison unit 174 uses a method in which the check time is set to ∞ in each of the previous steps S404, S411, and S417, for example, frequency bands used in S3G and 4G in step S417. Compare the total received power at.

  As a result, based on the comparison result from the reception state information comparison unit 174, the optimum method selection control unit 176 sets T1 as the base station signal check time period of the method with higher received power in steps S409, S410, and S416. After making the check time of other methods infinite, the process is terminated. For example, in step S409, the base station signal check time period of the S3G system is set to T1, and the check time of other systems is set to infinity.

  Note that, as a variation of the communication method selection method in the mobile terminal 100 shown in FIG. When the received power value of the reception status information of the communication method with the first highest received power is smaller than the specified value of the received power value by comparing with the specified value, the first, second and third communication methods Among them, a method of selecting a communication method having the largest quotient when the received power is divided by the communication rate as a communication method for measuring the reception state is also conceivable.

  That is, even if the received power value in the frequency band of the measured communication method is smaller than the specified value of the received power value, the error rate can be lowered if the communication rate of the measured communication method is small. The communication method having the largest ratio of the power / communication rate to the received power is measured (checked). Therefore, the mobile terminal 100 first measures the reception state of all communication methods, checks only the first one at that time, and checks only the first after that, and the communication method used is likely to be cut off. Check the other communication method only when (when it becomes smaller than the specified value).

  Since the communication method is selected in this way, it is not necessary to check the reception state of signals of all receivable communication methods, so that the power consumption in the mobile terminal 100 can be reduced.

  Also, in the mobile terminal 100 having the above-described configuration, when the signal reception power level difference of the three (3G, S3G, 4G) methods measured first is the same, only the default value, that is, the method having the default measurement frequency is measured. However, even when the signal reception power level difference of the three methods (3G, S3G, 4G) measured first is small (MAX (a, b, c) -MIN (a, b, c) <specified value) Alternatively, it may be configured to measure only the method of the default measurement frequency (the mainstream at that time).

  For example, when the communication method of the signal set as the default measurement frequency is 3G, only the signal from the 3G base station is measured. The default base station is supported by rewriting the farm.

  FIG. 11 is a flowchart for explaining processing when the power level difference of the received signal measured first is small.

  In step S601, the reception state information comparison unit 174 compares the difference between the value of the method that takes the maximum value and the value of the method that takes the minimum value of all the measured received powers with the preset specified value P12 (MAX). (P_ALL_3G_last, P_ALL_S3G_last, P_ALL_4G_last) −MIN (P_ALL_3G_last, P_ALL_S3G_last, P_ALL_4G_last) <P12).

  In step S601, when the difference between the value of the method that takes the maximum value and the value of the method that takes the minimum value of the measured total received power is larger than the specified value P12, the process proceeds to step S602. The processing from step S602 to step S622 is the same as the processing from step S401 to step S421 described in FIG.

  In step S601, when the difference between the value of the method that takes the maximum value and the value of the method that takes the minimum value among the measured total received power is smaller than the specified value P12, the process proceeds to step S623.

  In step S623, the optimum scheme selection control unit 176 sets the time period setting unit 177 to check only the signal of the base station that should be checked by default in the specified time period, and is specified by default. The measured data reception processing unit is made to measure. In FIG. 11, the default checking method is the 3G method, but the present invention is not limited to this, and an S3G method or a 4G method may be used.

  Next, in step S624, the reception state information comparison unit 174 compares the total reception power (here, 3G total reception power P_ALL_3G_last) in the frequency band used as a default with the specified value P13, and is greater than or equal to the specified value P13. If so, the process returns to step S623, and the total received power (here, 3G total received power P_ALL_3G_last) in the frequency band used in the default method is checked again.

  On the other hand, if it is determined in step S624 that the total received power in the frequency band used by default (here, 3G total received power P_ALL_3G_last) is smaller than the specified value P13, the process proceeds to steps S625 and S626 in order. The total received power (P_ALL_S3G_last, P_ALL_4G_last in FIG. 11) of each communication method in the frequency band used in the non-method (S3G, 4G method in FIG. 11) is measured.

  In step S627, the total received power (P_ALL_S3G_last, P_ALL_4G_last in FIG. 11) in the frequency band used in the measured non-default method (S3G, 4G method in FIG. 11) is compared. Specifically, in step S627, it is determined whether or not the total received power P_ALL_S3G_last of S3G is greater than the total received power P_ALL_4G_last of 4G, and if so, the process proceeds to step S610, The process proceeds to step S611.

  In steps S610 and S611, the base station signal check time period of the communication method with the larger received power is set to T1 among all the received powers compared, and the check time of the other methods is set to infinity, and then the process ends. To do. For example, in step S610, the base station signal check time period of the S3G system is set to T1, and the check time of other systems is set to infinity.

  That is, in steps S610, S611, and S617, the signal check time period of the method with large received power among the non-default communication methods is set to T1, and the processing is terminated with ∞ as the other.

  Here, the method to be measured by default can be dealt with by rewriting the firmware based on the control signal from the base station. As a result, when the service is not started yet or the service is terminated, the control method in the terminal is changed without the operator of the mobile terminal 100 performing consciousness and complicated operation, thereby suppressing wasteful power consumption. I can do it.

  FIG. 12 is a block diagram illustrating a schematic configuration of a mobile terminal 500 that is another example of the mobile terminal apparatus belonging to the communication system 200 according to the embodiment of this invention.

  A mobile terminal 500 illustrated in FIG. 12 has a function of transmitting and receiving data corresponding to each of a plurality of communication methods in the communication system 200.

  The mobile terminal 500 performs measurement by changing the time interval for measuring signals from the base stations 210, 220, and 230 for each communication method, and determines a communication method to be used when transmitting / receiving data based on the measured value. .

  The determination method in the mobile terminal 500 uses SIR (Signal to Interference power Ratio), and first measures the reception state (SIR) of the communication method in which communication is possible. Only the first reception state (SIR in this case) at that time is checked thereafter. When the SIR becomes smaller than the specified value, control is performed to measure the SIR of another communication method.

  A mobile terminal 500 shown in FIG. 12 has a basic configuration similar to that of the mobile terminal 100 corresponding to the embodiment shown in FIG. 2, a measurement unit that measures reception state information of each communication method, and these measurement units Only the configuration of the control unit that selects the optimum communication method based on the reception state information measured by the above is different. Therefore, below, the same code | symbol is attached | subjected to the same component and the description is abbreviate | omitted.

  That is, in the mobile terminal 500, the data reception processing units 140, 150, and 160 for each communication method are replaced with the 3G, S3G, and 4G power intensity measuring units 143, 153, and 163, for 3G, for S3G, and 4G. SIR measuring units 148, 158, and 168 are provided.

  The 3G, S3G, and 4G data reception processing units 140c, 150a, and 160a are 3G, S3G, and 4G low noise amplifiers 142, 152, and 162, and a reception processing unit 144 that perform processing in the respective communication methods. 154, 164, demodulation processing units 145, 155, 165, decoding processing units 146, 156, 166, 3G, S3G, 4G SIR measurement units 148, 158, 168.

  The 3G, S3G, and 4G SIR measurement units 148, 158, and 168 measure the SIR of the input signals after demodulation using the input signals, respectively. These measurement results are output to the controller 170a.

  In addition, the mobile terminal 500 includes a control unit 170a that performs communication method selection processing based on the measurement information from each of the SIR measurement units 148, 158, and 168.

  The mobile terminal 500 measures the SIR value in each communication method at a predetermined time period set by the control unit 170a in the data reception processing units 140c, 150a, 160a of a plurality of communication methods. The measured total received power and SIR value are output to the controller 170a as reception state information.

  FIG. 13 is a block diagram showing a main configuration of the control unit 170a in the mobile terminal 500 shown in FIG.

  As shown in FIG. 13, the control unit 170a determines which communication is performed based on signals input from the 3G, S3G, and 4G data reception processing units 140c, 150a, and 160a, information from the memory 190, and information on the battery 195. The communication method (here, 3G, S3G, 4G) is selected, and using the selection result, in the data transmission method selection unit 102, which transmission method the input signal input to the data transmission method selection unit 102 is selected. To determine whether to transmit as information.

  The control unit 170a includes a remaining battery level detection unit 172, a reception state information comparison unit 174a, and an optimum method selection control unit 176a. The reception state comparison unit 174a includes a SIR comparison unit 1742.

  The SIR comparison unit 1742 calculates the SIR in the use frequency band of the communication method among the reception state information which is a signal input from the 3G data reception processing unit 140c, the S3G data reception processing unit 150a, and the 4G data reception processing unit 160a. In comparison, the result is output to the optimum method selection control unit 176a as a comparison result of the reception status of the signals from the base stations 210, 220, and 230 of each communication method.

  Based on information from the control table stored in the battery remaining amount detection unit 172, the SIR comparison unit 1742 of the reception state information comparison unit 174a, the memory 190, etc., the optimum method selection control unit 176a in the actual radio wave propagation environment state Select the most suitable communication method.

  Specifically, the optimum method selection control unit 176a measures SIRs based on the received signals in descending order when the SIR values of the received signals from the respective communication methods output as the comparison results by the reception state information comparing unit 174a are different. A time period setting unit 177 is provided for setting time periods T1, T2, and T3 (where T1 ≦ T2 ≦ T3). At this time, the time period setting unit 177 sets T2 = T3 = ∞ so that the actual measurement is performed only in the communication method with the time period T1. When the SIR values of the received signals in the plurality of communication methods are the same, the optimum method selection control unit 176a selects the communication method set as the default value.

  Then, the optimum method selection control unit 176a sends a time period to the 3G data reception processing unit 140c, the S3G data reception processing unit 150a, and the 4G data reception processing unit 160a in order to transmit and receive data according to the selected communication method. The setting unit 177 outputs and controls a control signal for measuring the reception state, here, the SIR in a set time period.

  That is, in the optimum method selection control unit 176a, the time period setting unit 177 sets the SIR of the corresponding base stations 210, 220, and 230 for each of the 3G, S3G, and 4G data reception processing units 140c, 150a, and 160a. Set the measurement time period (T1, T2, T3). Note that T1, T2, and T3 in this embodiment are arbitrary periods that satisfy 0 <T1, T2, T3 ≦ ∞, and T1 ≦ T2 ≦ T3.

  The time period setting unit 177 assigns these set time periods to the data reception processing units 140c, 150a, and 160a, so that the optimum method selection control unit 176a actually measures the reception state (here, SIR). The communication method is selected.

  In the optimum method selection control unit 176a, the setting of the time period in the time period setting unit 177 is associated with the remaining power of the battery 195 and the SIR value, and the remaining power of the battery 195 stored in the memory 190 (battery Remaining amount), SIR value, base station check time T and SIR. Specifically, the setting of the time period is for selecting a communication method. Among the received signals from the 3G, S3G, and 4G base stations 210, 220, and 230, which received signal is received and received. This is synonymous with the setting of whether to measure the state (SIR).

  In this manner, the control unit 170a of the mobile terminal 500 first causes the data reception processing units 140c, 150a, and 160a to measure the total received power for each communication method. Then, the measured received power for each communication method is compared by the SIR comparison unit 1742 of the reception state information comparison unit 174a, and the optimum method selection control unit 176a determines the communication method with the highest SIR value from the comparison result. Select the communication method that uses the signal. Then, the SIR of the selected signal thereafter is measured using the data reception processing unit of the communication method having the highest SIR value. The SIR comparison unit 1742 monitors the SIR of the received signal in the communication method with the highest received signal, and controls to measure the SIR of the other communication method when it is smaller than a preset specified value.

  Since the communication method is selected in this way, it is not necessary to check the reception status of all receivable communication methods, so that the mobile terminal 500 can reduce power consumption and improve QoS (Quality of Service). Can do.

  The mobile terminal 500 is configured to measure the SIR of each communication method. However, the present invention is not limited to this, and the SIR value is measured at a base station that is a communication partner (for example, base stations indicated by 210, 220, and 230 in FIG. 1). Only the mobile terminal 500 may be notified. In this case, instead of the SIR measuring units 148, 458 and 168, a SIR value acquiring unit for acquiring the SIR value from the received signal is arranged.

  In the mobile terminal 500, the data reception processing units 140c, 150a, and 160a for each communication method are configured to include SIR measurement units 148, 158, and 168 as means for detecting the reception information state. The configuration is not limited, and a bit rate measuring unit that measures the bit rate of the received signal may be provided in place of the SIR measuring units 148, 158, and 168. In this case, in the control unit 170a, the reception state information comparison unit 174a has a configuration in which a bit rate comparison unit is provided instead of the SIR comparison unit 1742. In this case, since the SIR in each communication method is the same as the comparison target in place of the bit rate in each communication method, the other comparison methods and the like are the same. Further, in the mobile terminal 500, the data reception processing units 140c, 150a, and 160a of each communication method may detect the received information state as BER or FER instead of SIR. In this case, instead of the SIR measuring units 148, 158, and 168, a measuring unit for measuring the BER or FER of the received signal is provided, and the control unit side also replaces the SIR comparing unit with the BER. The comparison unit or the FER comparison unit is arranged.

  Further, the mobile terminal 500 may be configured to compare the received power value together with the SIR value in each communication method and select a communication method to be used based on the comparison result. For example, in the mobile terminal 500, the data reception processing units 140c, 150a, and 160a of a plurality of communication schemes have the power intensity together with the SIR value, specifically, the total received power P_ALL_3G_last and P_ALL_S3G_last in the corresponding frequency band of the corresponding communication scheme. , P_ALL_4G_last is measured and output to the controller 170a. On the other hand, the control unit 170a configures the reception state information comparison unit 174a to compare the magnitudes of all received powers P_ALL_3G_last, P_ALL_S3G_last, and P_ALL_4G_last.

  In detail, in the control unit 170a, the SIR comparison unit 1742 includes the reception status information that is a signal input from the 3G data reception processing unit 140c, the S3G data reception processing unit 150a, and the 4G data reception processing unit 160a. In addition to comparing SIRs in the communication system use frequency band, and having a preset value set in advance for comparison with these input SIR values, the SIR of each communication method is compared with a preset specified value. Thus, the result is compared with the reception status of the signals from the base stations 210, 220, and 230 of each communication method, and is output to the optimum method selection control unit 176a.

  Then, the optimum method selection control unit 176a determines the actual radio wave propagation environment based on information from the battery remaining amount detection unit 172, the SIR comparison unit 1742 of the reception state information comparison unit 174a, the control table stored in the memory 190, and the like. Select the communication method most suitable for communication in the state. Specifically, the optimum method selection control unit 176a measures the SIRs based on the received signals in descending order when the power values of the received signals from the respective communication methods output as the comparison results by the reception state information comparing unit 174a are different. A time period setting unit 177 is provided for setting time periods T1, T2, and T3 (where T1 ≦ T2 ≦ T3). At this time, the time period setting unit 177 sets T2 = T3 = ∞ so that the actual measurement is performed only in the communication method with the time period T1.

  When the power values of the received signals in the plurality of communication methods are the same, the optimum method selection control unit 176a selects the communication method set as the default value. Next, the optimum method selection control unit 176a sends a time period to the 3G data reception processing unit 140c, the S3G data reception processing unit 150a, and the 4G data reception processing unit 160a in order to transmit and receive data according to the selected communication method. The setting unit 177 outputs and controls a control signal for measuring the reception state, here, the SIR in a set time period.

  That is, in the optimum method selection control unit 176a, the time period setting unit 177 sets the SIR of the corresponding base stations 210, 220, and 230 for each of the 3G, S3G, and 4G data reception processing units 140c, 150a, and 160a. Set the measurement time period (T1, T2, T3). Note that T1, T2, and T3 in this embodiment are arbitrary periods that satisfy 0 <T1, T2, T3 ≦ ∞, and T1 ≦ T2 ≦ T3.

  By assigning these set time periods to the data reception processing units 140c, 150a, and 160a, the optimum method selection control unit 176a selects a communication method for actually measuring the reception state (here, SIR).

  In this manner, the control unit 170a of the mobile terminal 500 first causes the data reception processing units 140c, 150a, and 160a to measure the total received power for each communication method. Then, the received power of each measured communication method is compared, and based on the comparison result, the optimum method selection control unit 176a selects the communication method that uses the signal of the communication method having the highest received power level.

  Then, the SIR of the selected signal thereafter is measured using the data reception processing unit of the communication method having the highest received power level. The SIR comparison unit 1742 monitors the SIR of the received signal in the communication method with the highest received signal, and controls to measure the SIR of the other communication method when it is smaller than a preset specified value. Since the communication method is selected in this way, it is not necessary to check all the reception states of signals of the receivable communication method, and the mobile terminal 500 can reduce power consumption and improve QoS (Quality of Service). Can do.

  Further, in the mobile terminals 100 and 500, the 3G data reception processing units 140 and 140c, the S3G data reception processing units 150 and 150a, and the 4G data reception processing units 160 and 160a are one system (finger or the like) in RAKE reception. It may be constituted by.

  In addition, although it is about the received signal in the utilization frequency band each measured in the data reception process part 140,140a-140c, 150,150a, 160,160a of each communication system, the power value of the received signal of each communication system measured is In the case where they are the same, the optimum method selection control units 176 and 176a select the communication method set as the default value, but not limited to this, select the communication method with the higher power peak of the received signal. It is good also as composition to do.

  For example, in mobile terminals 100 and 500 according to the present embodiment, the peak power measurement function is added to power intensity measurement units 143, 153, and 163 or SIR measurement units 148, 158, and 168, but the band of the received signal is narrow. Prioritize the strong signal method.

  FIG. 14 shows the same power value when measuring received signals of different communication methods by adding a peak power measurement function to the power intensity measurement units 143, 153, 163 or SIR measurement units 148, 158, 168. It is a figure which shows an example of the received signal of the communication system from which an electric power peak differs.

  FIG. 14 shows the power value 801 of the total received power P_ALL_3G_last in the frequency band used in 3G and the power value 802 of the total received power P_ALL_S3G_last in the frequency band used in S3G, and the area of the power value 801 is shown. = Area of power value 802.

  As shown in FIG. 14, when the S3G method is higher, the reception state is determined using information output from the power intensity measurement units 143, 153, 163 or the SIR measurement units 148, 158, 168 to the control units 170, 170a. The information comparison units 174 and 174a perform comparison including the power peak, and the optimum method selection control units 176 and 176a select the S3G communication method having a high power peak. As described above, since a method with high peak power is prioritized, communication speed and quality can be improved, and power saving and a high bit rate in a used communication method can be achieved.

  In addition, the control unit 170 compares the received power value in the reception state information of the communication method with the first largest reception power with the specified value of the received power value in the reception state information comparison unit 174, and receives the first. When the received power value of the reception state information of the communication method with the higher power is smaller than the preset value of the received power value, the optimum method selection control unit 176 receives the received power among the 3G, S3G, and 4G communication methods. The communication method having the largest quotient when the value is divided by the communication rate may be selected as the communication method for measuring the reception state, and the reception state may be measured.

  In this embodiment, the cellular system is mainly described as a communication system having a different communication method. However, a system combined with another wireless communication system such as a wireless LAN or a fixed wireless system may be used.

  The mobile communication terminal device and the communication system according to the present invention can communicate with each of a plurality of communication systems having different frequency bands, have an effect of saving power, and have different frequency bands mixed together. It is useful as something used in the region.

  The present invention relates to a mobile communication terminal apparatus and a communication system capable of performing communication by a plurality of communication methods.

  In a region where multiple services with different communication methods have been mixed, a mobile terminal that is already connected to one network becomes different when it becomes difficult to connect to that network as it moves. It is considered to switch to another type of network so that the connection can continue.

  As a communication method of a mobile terminal capable of communicating with a plurality of communication systems having different communication methods, for example, there is one disclosed in Patent Document 1. This Patent Document 1 describes a mobile that can communicate with both wireless LAN (Local Area Network) and W-CDMA (Wideband Code Division Multiple Access), which is a third generation mobile communication system (hereinafter referred to as “3G”). A wireless communication system comprising a terminal is disclosed. The mobile terminal in Patent Document 1 determines a communication system that accommodates a radio access station that is a destination, based on the received quality of a received downlink signal. In Patent Document 1, a database in a network is referred to based on type information of a wireless system notified from a mobile terminal, and a handover method that satisfies the request of the mobile terminal is selected on the server side.

Further, in Patent Document 2, when base stations of different generations using a CDMA (Code Division Multiple Access) communication method are arranged separately for each area and the mobile station moves from one area to an area of a different generation, A method for switching between stations and realizing handover between base stations without disconnection is described.
JP 2004-260444 A JP 2000-201369 A

  By the way, in the mobile communication system, a service-in of a fourth generation mobile communication system (hereinafter referred to as “4G”) is scheduled. In the process leading to 4G, Super 3G (hereinafter referred to as “3G”), which is an intermediate position between 3G and 4G, aims to smoothly transition from the existing third generation mobile communication system (hereinafter referred to as “3G”). S3G ") has been proposed.

3G is a communication method represented by W-CDMA and CDMA2000, the frequency band is 2 GHz, and the trunk network is an ATM network. Further, S3G is a communication method that has been studied using a 1.7 or 2.5 GHz band as a use frequency band. In S3G, “VSF-OFDM (Variable Spreading Factor, Orthogonal Frequency and Code Division Multiplexing)” is used for downlink, and “DS-CDMA (Direct Spread Code Division Multiple Access)” is used for uplink, and the data transfer rate is 100 Mbps when stationary, The moving time is 30 Mbps, and the delay time is 2.0 ms or less with respect to the current about 10 ms. The S3G trunk network is an IP network. Furthermore, 4G uses the same technology as S3G with a usage frequency band of 5 GHz, and has a frequency band for 100 MHz centered on 4.635 GHz for downstream and 30 MHz centered on 4.9 GHz for upstream. It is used. This 4G uses MIMO (Multiple Input, Multiple
Output) is added to an existing wireless system, the data transfer rate is 1 Gbps when stationary, and 100 Mbps when moving, and the trunk network is an IP network.

  In an area where a plurality of communication scheme areas having different frequency bands and transmission speeds (bit rates) such as 3G, S3G, and 4G are mixed, a mobile terminal communication system that can communicate with each communication scheme is provided. There is a desire to realize it.

  In order to realize this, in an area where a plurality of services having different communication methods such as 3G area, S3G area, and 4G area are mixed, the mobile terminal receives a receiving device and a transmission for different frequencies such as 3G, S3G, and 4G. Device. In particular, when the base stations of communication systems having different frequencies do not mutually exchange cell information in the respective areas, it is necessary to first perform a cell search for the base stations of all communication systems on the mobile terminal side. . In addition, after that, since it becomes necessary to always receive and decode the signals of the respective systems, the power consumption increases.

  Also, in order to realize a communication system in which a mobile terminal can use a plurality of services with different communication methods, the mobile terminal selects a bit rate with priority over a network with a plurality of communication methods with different frequency bands. A case where a communication method is determined can be considered. In this case, first of all, in all communication methods (3G, S3G, 4G), cell search is performed to measure each communication state, and the communication method is always switched to a speedy communication method. Since it is necessary to receive and demodulate (3G, S3G, 4G) signals, the power consumption increases.

  Furthermore, in the case where base stations having different communication methods such as 3G, S3G, and 4G exchange cell information with each other, after connecting to the cell having the maximum reception level of the downlink pilot channel, The neighboring cell information is obtained by receiving and decoding the broadcast information. Then, after connecting to the base station with the maximum reception level among the base stations of the three communication systems having different frequency bands, it is conceivable that the neighboring cell information is obtained and handed over to an appropriate cell at any time.

  However, even if it is known that there is a cell in the vicinity, it is necessary to perform a cell search in order to determine whether the condition is optimal for the terminal. For this reason, it is necessary for the mobile terminal to periodically check all reception levels of signals transmitted from the base stations of the respective communication schemes, and power consumption increases accordingly.

  As described above, in a region where a plurality of services having different communication methods such as 3G area, S3G area, and 4G area are mixed, the mobile terminal uses reception devices and transmission devices for different frequencies such as 3G, S3G, and 4G. Because radio waves in different frequency bands are always monitored, power is consumed in each of the transmission / reception receivers and transmitters of different frequency bands, resulting in very large power consumption. A problem occurs.

  Further, in an area where a plurality of services such as 3G area, S3G area, and 4G area are mixed, it is difficult to perform processing such as which communication system movement should be selected for cell search and handover.

  In Patent Literature 1, since the server side selects a handover method that satisfies the request of the mobile terminal based on the type information of the wireless system notified from the mobile terminal, it is not necessary to select the handover method on the mobile terminal side. However, it is not specifically disclosed how to determine and determine the reception quality for the various types of information of the wireless system to be determined.

  Further, Patent Document 2 discloses a method for selecting a plurality of generations (2G, 3G) of base stations with different communication methods performed by a mobile terminal. However, a description for saving power when selecting a base station is disclosed. It is not disclosed at all.

  An object of the present invention is to provide a mobile communication terminal apparatus and a communication system that can smoothly communicate with each of a plurality of communication systems having different frequency bands and achieve power saving.

  The mobile communication terminal device of the present invention receives a battery and signals of the first, second, and third communication methods that are driven by the battery and have different use frequency bands and communication areas, respectively, via an antenna, First, second and third receiving means for measuring reception states for each of the first, second and third communication schemes from received signals and outputting as reception state information each including a received power value; Based on the remaining battery level of the battery and the reception status information for each of the first, second and third receiving means, one or two receiving means among the first, second and third receiving means Using the control unit that sets the measurement cycle of the reception state, controls the one or two reception units according to the set measurement cycle, and measures the reception state, and the reception state information indicating the measured reception state Said first, second and second A communication unit for comparing the received power in the communication method and a communication method for measuring the reception state is selected from the first, second and third communication methods based on the comparison result of the comparison unit. And a method selecting unit that sets the measurement period for a receiving unit corresponding to the selected communication method among the first, second, and third receiving units, and the control unit includes the method selecting unit. Adopts a configuration in which the reception unit corresponding to the communication method selected by the user is controlled to measure the reception state.

  As described above, according to the present invention, communication is possible with each of a plurality of communication systems having different frequency bands, and power saving can be achieved.

  Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings. The mobile communication terminal apparatus (hereinafter referred to as “mobile terminal”) in the present embodiment is compatible with a plurality of communication systems having different usage frequency bands and communication areas, and the areas of these communication systems (service network). ) Are overlapping.

  Here, areas of a plurality of communication schemes having different utilization frequency bands and different sizes of utilization frequencies and communication areas are defined as areas of the first to third communication schemes. The bit rate is assumed to be higher in the order up to 3. Furthermore, the communication areas of the first to third communication methods are narrower in the order of the first to third.

  Specifically, an area of the second communication method that has a different frequency band from the first communication method and a higher bit rate than the first communication method exists within the area of the first communication method. In addition, within the area of the second communication method, there is an area of the third communication method that has a different frequency band from the second communication method and a higher bit rate than the second communication method.

  FIG. 1 is a diagram for explaining a communication state in a communication system 200 of a mobile communication terminal 100 according to an embodiment of the present invention, and FIG. 1A is a communication system having a mobile communication terminal according to an embodiment of the present invention. It is a figure which shows an example. FIG. 1B is a diagram showing an example of the relationship between the received signal strength of each method received by the mobile communication terminal shown in FIG. 1A and the reception position, and FIG. 1C is the received signal of each method received by the mobile communication terminal shown in FIG. 1A. It is a figure which shows an example of the relationship between an intensity | strength and a frequency.

  Mobile terminal 100 of the present embodiment shown in FIG. 1A can communicate with each of a plurality of communication methods. Here, a plurality of communication methods having different frequency bands and bit rates used for communication are referred to as first to third communication methods, and the communication areas are overlapped and the bit rates are increased in order, 3G, S3G, 4G. And

  First, a communication system to which the mobile terminal 100 belongs will be described.

  In the communication system 200 to which the mobile terminal 100 shown in FIG. 1A belongs, the S3G base station 220 and the S3G communication area (S3G service area 221) are included in the 3G communication area (3G service area 211) by the 3G base station 210. Is arranged. In addition, a 4G base station 230 is arranged in the S3G communication area (S3G service area 221), and a communication area (4G service area 231) by the 4G base station 230 is arranged. 1B and 1C correspond to the case where the mobile terminal 100 moves in the arrow direction (arrow A direction) in the communication system 200 shown in FIG. 1A.

That is, FIG. 1B shows the signal strength when the mobile terminal 100 receives signals transmitted from the base stations 210 to 230 of each communication method when the mobile terminal 100 moves in the A direction in the communication system 200 of FIG. 1A. Yes. Specifically, in FIG. 1B, a graph 212 shows an example of signal strength in the mobile terminal 100 when a radio signal is received from the 3G base station 210 that is a signal in the frequency band of 2 GHz. A graph 222 shows an example of signal strength in the mobile terminal 100 when a radio signal is received from the S3G base station 220 that is a signal having a frequency of 1.7 or 2.5 GHz. Further, the graph 232 shows an example of the reception intensity in the mobile terminal 100 when a radio signal is received from the 4G base station 230 that is a signal in the frequency band of 5 GHz.

  FIG. 1C shows the relationship between the signal strength and the frequency when the spread signal transmitted from each base station 210 to 230 is received by the mobile terminal 100, and the graph 213 is output from the 3G base station. A graph 223 shows an example of a modulation signal output from an S3G base station, and a graph 233 shows an example of a modulation signal output from a 4G base station.

  FIG. 2 is a block diagram showing a schematic configuration of a mobile terminal as a mobile communication terminal apparatus according to an embodiment of the present invention.

  The mobile terminal 100 shown in FIG. 2 has a function of transmitting and receiving data corresponding to each of a plurality of communication methods in the communication system 200. In the mobile terminal 100, the communication method used when transmitting and receiving data is measured by changing the time interval for measuring signals from the base stations 210, 220, and 230 for each communication method, and determined based on the measured value. Is done.

  The mobile terminal 100 shown in FIG. 2 corresponds to a data transmission method selection unit 102, data transmission processing units 110, 120, and 130 that transmit data corresponding to each of a plurality of communication methods, and each of a plurality of communication methods. Data reception processing units 140, 150, and 160 that receive data, filters 105 and 106, multiplexer / demultiplexer 107, antenna 108, control unit 170, memory 190, and battery (shown as battery 195 in the figure) 195 are provided.

  The data transmission processing units 110, 120, and 130 and the data reception processing units 140, 150, and 160 correspond to 3G, S3G, and 4G, respectively. Each processing unit that performs transmission / reception processing with the 3G base station 210 is a 3G data transmission processing unit 110, 3G data reception processing unit 140, and each processing unit that performs transmission / reception processing with the S3G base station 220 is S3G data transmission processing unit. 120, the 3G data reception processing unit 150, and each processing unit that performs transmission / reception processing with the 4G base station 230 will be described as a 4G data transmission processing unit 130 and a 4G data reception processing unit 160.

  Based on the control information input from the control unit 170, the data transmission method selection unit 102 selects which communication method information is to be transmitted from among a plurality of communication methods. Then, the data transmission method selection unit 102 outputs information to be transmitted to the data transmission processing unit corresponding to the selected communication method. Specifically, when the communication method for transmitting information is one of 3G, S3G, and 4G communication methods, the input signal input to the data transmission method selection unit 102 is the 3G data transmission processing unit 110, The data is output to one of the S3G data transmission processing unit 120 and the 4G data transmission processing unit 130.

  The 3G data transmission processing unit 110, the S3G data transmission processing unit 120, and the 4G data transmission processing unit 130 each transmit an input signal input via the data transmission method selection unit 102 as information of a corresponding communication method. Processing is performed as possible, and the result is output to the filter 105. The signal input to the filter 105 is transmitted as a radio signal from the antenna 108 via the multiplexer / demultiplexer 107.

Here, the 3G data transmission processing unit 110, the S3G data transmission processing unit 120, and the 4G data transmission processing unit 130 process the input signals according to the respective communication schemes, and can transmit information according to the respective communication schemes. To. As a specific configuration, each of the data transmission processing units 110, 120, and 130 processes the input signal input from the data transmission method selection unit 102 with the encoding processing units 112, 122, 132, modulation processing units 113, 123, and 133, transmission processing units 114, 124, and 134, and amplifiers 115, 125, and 135. The amplifiers 115, 125, and 135 are shown as a 3G amplifier 115, an S3G amplifier 125, and a 4G amplifier 135 in FIG. 2 in accordance with the communication method used for each process.

  The encoding processing units 112, 122, and 132 encode input signals using the respective communication methods, and output the encoded signals to the modulation processing units 113, 123, and 133.

  Modulation processing sections 113, 123, and 133 perform modulation processing on the signals input from encoding processing sections 112, 122, and 132 using the respective communication methods, and output the result to transmission processing sections 114, 124, and 134.

  The transmission processing units 114, 124, and 134 up-convert the signals input from the modulation processing units 113, 123, and 133, convert the signals into signals of frequencies used in the respective communication systems, and each communication system amplifier. 115, 125 and 135.

  The 3G amplifier 115, the S3G amplifier 125, and the 4G amplifier 135 cause the signals input from the transmission processing units 114, 124, and 134 to have signal levels suitable for the transmission frequency used in each communication method. Amplified and output to the filter 105.

  Here, the data reception processing units 140, 150, and 160 corresponding to each communication method correspond to 3G, S3G, and 4G, respectively, and signals (3G, S3G, and 4G) correspond to each communication method (3G, S3G, and 4G). Data). Here, the data reception processing units 140, 150, and 160 corresponding to each communication method are illustrated as a 3G data reception processing unit 140, an S3G data reception processing unit 150, and a 4G data reception processing unit 160, respectively. .

  Each of the data reception processing units 140, 150, and 160 passes through the antenna 108 and the multiplexer / demultiplexer 107, and then receives a radio signal (data) distributed for each usage frequency of 3G, S3G, and 4G via the filter 106. Entered. Each data reception processing unit 140, 150, 160 measures and controls reception state information of a radio signal that serves as an index for selecting a communication method to be used in the control unit 170 based on the input radio signal. In addition to outputting to unit 170, the received signal is output to the outside as data. In FIG. 2, each data reception processing unit 140, 150, 160 measures the total received power in each communication method at a predetermined time period set by the control unit 170 as reception state information.

  Each data reception processing unit 140, 150, 160 will be described in detail.

  The 3G, S3G, and 4G data reception processing units 140, 150, and 160 are 3G, S3G, and 4G low noise amplifiers 142, 152, 162, 3G, and S3G that perform processing in their respective communication methods. 4G power intensity measurement units 143, 153, 163, reception processing units 144, 154, 164, demodulation processing units 145, 155, 165, and decoding processing units 146, 156, 166 are provided.

  The 3G, S3G, and 4G low noise amplifiers 142, 152, and 162 amplify the input signal while keeping the additional noise small, and the 3G, S3G, and 4G power intensity measuring units 143, 153, 163 and the reception processing units 144, 154, and 164.

  The reception processing units 144, 154, and 164 perform down-conversion and automatic gain control (AGC) processing on input signals from the 3G, S3G, and 4G low noise amplifiers 142, 152, and 162. . Then, the reception processing units 144, 154, and 164 output the processed input signals to the demodulation processing units 145, 155, and 165.

  The demodulation processing units 145, 155, and 165 demodulate the input signals by performing processing such as despreading processing, and the demodulated signals are output to the decoding processing units 146, 156, and 166 for decoding. Decoding is performed in the processing units 146, 156, and 166.

  The signals decoded by the decoding processing units 146, 156, and 166 are output to the outside as data via the external output device 104 provided in the mobile terminal 100. Examples of the external output device 104 include an LED (Light-Emitting Diode), a display device such as a liquid crystal display, a sound output device that outputs sound such as a speaker, and a storage device.

  The 3G, S3G, and 4G power strength measuring units 143, 153, and 163 respectively receive the power strength of the input signals, specifically, the total received power P_ALL_3G_last, P_ALL_S3G_last, Measure P_ALL_4G_last. These measurement results are output to the control unit 170. Note that “_last” means the latest data of the measurement result in this embodiment.

  In response to these measurement results, the control unit 170 selects a communication method to be used and performs data reception processing units 140, 150, 160 for 3G, S3G, and 4G in order to perform reception processing in the selected communication method. The corresponding data reception processing unit is controlled to perform reception processing, and the data subjected to the reception processing is output to the external output device 104.

  FIG. 3 is a block diagram showing a main configuration of the control unit 170 in the mobile communication terminal shown in FIG.

  The control unit 170 performs communication based on signals input from the 3G, S3G, and 4G data reception processing units 140, 150, and 160, information from the memory 190, and information on the battery 195 (in this case, 3G, S3G, 4G), and by using the selection result, the data transmission method selection unit 102 uses which transmission method to transmit the input signal input to the data transmission method selection unit 102 as information To decide.

  As illustrated in FIG. 3, the control unit 170 includes a remaining battery level detection unit 172, a reception state information comparison unit 174, and an optimum method selection control unit 176.

  The battery remaining amount detection unit 172 detects the remaining amount of power of the battery 195 connected to the control unit 170, and is controlled by the optimum method selection control unit 176 to output to the optimum method selection control unit 176.

  The reception status information comparison unit 174 uses the reception status information, which is a signal input from the 3G data reception processing unit 140, the S3G data reception processing unit 150, and the 4G data reception processing unit 160, to determine the base of each communication method. The reception states of the signals from the stations 210, 220, and 230 are compared, and the comparison result is output to the optimum method selection control unit 176.

  The reception state information comparison unit 174 may use the signals input from the data reception processing units 140, 150, and 160 as comparison targets as they are, or extract other reference information from the input signals. Then, the extracted information may be compared. Furthermore, the input signal may be compared with a preset threshold value, or information extracted from the input signal may be compared with a preset threshold value. The reception state information comparison unit 174 is controlled by the optimum method selection control unit 176.

Here, the reception state information is the power intensity (reception power) of signals input from the 3G power intensity measurement unit 143, the S3G power intensity measurement unit 153, and the 4G power intensity measurement unit 163, respectively.
That is, the received power level of the signal received by each communication method (3G, S3G, 4G).

  Therefore, in the present embodiment, reception state information comparison section 174 compares the signal power strengths in 3G, S3G, and 4G.

  Based on information such as a control table stored in the remaining battery level detection unit 172, the reception status information comparison unit 174, and the memory 190, the optimum method selection control unit 176 is the communication most suitable for communication in the actual radio wave propagation environment state. Select a method.

  Specifically, the optimum method selection control unit 176 measures the received signals in descending order when the power values of the received signals from the respective communication methods output as the comparison results output by the reception state information comparing unit 174 are different. A time period setting unit 177 is provided for setting periods T1, T2, and T3 (where T1 ≦ T2 ≦ T3). At this time, the time cycle setting unit 177 sets T3 = ∞ so that the actual measurement is performed only in the communication method with the time cycles of T1 and T2. That is, by setting T3 = ∞, the time period for the communication method with the smallest received signal power value among the three communication methods, in other words, the communication method with the smallest received power intensity among the three communication methods. Do not set. As described above, when the time period for measuring the reception signal of the predetermined signal system is not set, T = 0 may be used instead of the time period T = ∞.

  Further, when the power values of the received signals in the plurality of communication methods are the same, the optimum method selection control unit 176 selects the communication method set as the default value.

  Then, the optimal method selection control unit 176 sends a time period to the 3G data reception processing unit 140, the S3G data reception processing unit 150, and the 4G data reception processing unit 160 in order to transmit and receive data according to the selected communication method. The setting unit 177 outputs and controls a control signal that causes the reception state to be measured at each set time period.

  That is, in the optimum method selection control unit 176, the time period setting unit 177 receives signals from the corresponding base stations 210, 220, and 230 for the 3G, S3G, and 4G data reception processing units 140, 150, and 160, respectively. Set the time period (T1, T2, T3) for measuring.

  By assigning these set time periods to the data reception processing units 140, 150, and 160, the optimum method selection control unit 176 selects the communication method in which the reception state (in this case, the received signal strength) is actually measured. is doing.

  In the optimum method selection control unit 176, the setting of the time period in the time period setting unit 177 is associated with the remaining power level of the battery 195, and the remaining power level of the battery 195 stored in the memory 190 (remaining battery level). And the base station check time T. Specifically, the setting of the time period is synonymous with the setting of which received signal is measured for the received signal among the received signals from the 3G, S3G, and 4G base stations 210, 220, and 230. .

  FIG. 4 is a diagram illustrating an example of the relationship between the remaining power of the battery 195 stored in the memory 190 (battery remaining amount) and the time period when the communication state is measured. This figure shows the association between the remaining battery level and the time period (T_3G, T_S3G, T_4G) at which the mobile terminal 100 checks the base station of each communication method.

As shown in FIG. 4, when the remaining power of the battery 195 of the mobile terminal 100 is large, the reception state (signal strength) measurement time period T for each communication method is short, and base stations for all communication methods Measure signals from 210, 220, 230. Further, as shown in FIG. 4, as the remaining battery level decreases, the number of communication methods to be measured in the reception state decreases.

  The memory 190 stores information used in communication in addition to a control table such as a table (see FIG. 4) showing a relationship between the remaining amount of power of the battery 195 (remaining battery amount) and the time period when the communication state is measured. The data can be stored and read / written under the control of the optimum method selection control unit 176. In the control table stored in the memory 190, the average of the circuits constituting the data transmission / reception unit of each communication method, the received power level or propagation loss, the SIR value (Signal to Interference power Ratio), in the remaining battery level and time period of the battery 195 The power consumption value is associated. Instead of the SIR value, a BER (Bit Error Rate) value and a FER (Flame Error Rate) value may be associated. Needless to say, the elements associated in these control tables may be associated with only elements as necessary. Information used in communication stored in the memory 190 includes transmission information from the power intensity measuring units 143, 153, and 163, and base stations 210, 220, and 230 (see FIG. 1) having different communication methods. is there.

  Next, the operation of mobile terminal 100 having the above configuration will be described with reference to FIG. FIG. 5 is a flowchart for explaining basic processing of mobile terminal 100 according to the present embodiment.

  First, in step S101, the mobile terminal 100 is turned on. In step S102, the 3G data reception processing unit 140 measures the total received power P_ALL_3G_last in the frequency band used in the 3G system, and the process proceeds to step S103. To do. “_Last” means the latest data of the measurement result.

  In step S103, the S3G data reception processing unit 150 measures the total received power P_ALL_S3G_last in the frequency band used in S3G, and proceeds to step S104.

  In step S104, the 4G data reception processing unit 160 measures the total received power P_ALL_4G_last in the frequency band used in 4G, and proceeds to step S105.

  In step S105, the remaining battery level detection unit 172 measures the remaining power level of the battery 195, and the reception status information comparison unit 174 uses the total received power P_ALL_3G_last in the frequency band used in 3G and the frequency used in S3G. The reception state of each communication method (3G, S3G, 4G) is compared using the total reception power P_ALL_4G_last in the frequency band used in the total reception power P_ALL_S3G_last, 4G in the band, and the process proceeds to step S106. The comparison of the reception status of each communication method in step S106 is, for example, the total received power P_ALL_3G_last in the frequency band used in 3G, the total received power P_ALL_S3G_last in the frequency band used in S3G, and the total in the frequency band used in 4G. This is a comparison of the received power P_ALL_4G_last.

  In step S106, the optimum method selection control unit 176 uses the time period setting unit 177 based on the comparison result by the reception state information comparison unit 174 and the information from the memory 190, and the frequency band used in 3G, S3G, and 4G. T1, T2, T3 (however, T1 ≤ T2 ≤ T3) in the time period (T_3G, T_S3G, T_4G) for measuring (checking) the received signal in descending order of the power value among all received power P_ALL_3G_last, P_ALL_S3G_last, P_ALL_4G_last ) Is set.

  In this step S106, when all the received powers P_ALL_3G_last, P_ALL_S3G_last, P_ALL_4G_last in each communication method (3G, S3G, 4G) are equal and the remaining battery level is low, the optimum method selection control unit 176 The time periods T1, T2, and T3 are set in ascending order of the average power consumption value of the transmission / reception circuit.

  This is because the power consumption of electronic circuits constituting an amplifier (amplifier), a modulation unit, a demodulation unit, and the like in a used frequency band is different in each communication method. That is, the time period is set so that a communication method with low average power consumption in the electronic circuit constituting the processing unit is selected from the data transmission / reception processing units 110, 120, 130, 140, 150, and 160 of each communication method. To do. After step S106, the process proceeds to step S107.

  In step S107, the optimum method selection control unit 176 outputs the time periods T1 to T3 set in step S106 to each data reception processing unit 140, 150, 160, and in each data reception processing unit 140, 150, 160, Based on the input time period, the reception state (reception power value here) of the reception signal for each base station of each communication method is checked. In order to set the time period for checking the reception state of signals transmitted from these base stations for each base station of each communication system, the transmission signal of the communication system to be measured is determined by changing the time period. For example, when T3 = infinity is set, only the reception state of the reception signal of the communication method in which the time periods T1 and T2 are set is checked.

  The optimum method selection control unit 176 uses the time period setting unit 177 to set the time period for checking the received signal of each communication method, thereby communicating which communication method from a plurality of communication methods (3G, S3G, 4G). The information on the determined communication method is output to the data transmission method selection unit 102. Further, the determined information is output to the corresponding transmission processing units 110, 120, and 130.

  As described above, the transmission / reception processing units 110, 120, 130, 140, 150, and 160 change the signal measurement time period for each communication method as the time periods T1, T2, and T3 for measuring the signal from the base station. I am letting. Here, since the time period is set to T1 ≦ T2 ≦ T3 and T3 = infinity, the communication method in which the time period is T3 does not actually set the time period to be measured. In the mobile terminal 100, the time period is T1. Only the T2 communication method is actually measured.

  Therefore, it is possible to achieve both low power consumption, reduced processing amount, and high bit rate in order to measure a received signal of a communication method with a large received power without always measuring signals from base stations of all communication methods. It becomes possible.

  In each data reception processing unit 140, 150, 160 of the present embodiment, the power intensity measurement units 143, 153, 163 are after the low noise amplifiers 142, 152, 162 in the processing units 140, 150, 160, respectively. Although arranged, it is not limited to this.

  For example, in the same configuration as each data reception processing unit 140, 150, 160, it may be arranged after the demodulation processing units 145, 155, 165 instead of after the low noise amplifiers 142, 152, 162.

  An example of this is shown in FIG. FIG. 6 is a diagram illustrating a first modification of the data reception processing unit.

  FIG. 6 is a diagram showing a 3G data reception processing unit 140a which is a modification 1 of the 3G data reception processing unit 140. In this data reception processing unit 140a, the 3G power intensity measurement unit 143 is a demodulation processing unit 145. Is placed after.

  According to this configuration, the received signal which is the target when the 3G power intensity measurement unit 143 measures the power intensity is subjected to demodulation processing such as despreading processing in the demodulation processing unit 145 before measuring the power intensity. Will be given. Therefore, more accurate power intensity can be measured when the power intensity is measured in the 3G data reception processing unit 140 shown in FIG.

  In the mobile terminal 100, when the 3G data reception processing unit 140 is changed to the 3G data reception processing unit 140a, S3G and 4G data reception processing units 150 and 160 (see FIG. 2), which are other communication methods, are also used. The configuration is the same as that of the 3G data reception processing unit 140a. That is, in each of the S3G and 4G data reception processing units 150 and 160 (see FIG. 2), the S3G and 4G power intensity measurement units are not after the low noise amplifiers 152 and 162, but the demodulation processing unit 155, It is arranged after 165 and performs processing on the input signal. With this configuration, the same power and effect as those obtained when the 3G data reception processing unit 140a is changed to the 3G data reception processing unit 140, that is, accurate power intensity is also measured in S3G and 4G.

  Furthermore, in each of the data reception processing units 140, 150, and 160 of the present embodiment, the reception status information output to the control unit is the total reception power in the frequency band used in each communication method, but is not limited thereto. It may be a propagation loss in each communication method. In this case, each data reception processing unit 140, 150, 160 includes a propagation loss measurement unit for each communication method instead of the power intensity measurement unit for each communication method.

  FIG. 7 is a diagram illustrating a 3G data reception processing unit 140b as a modification 2 of the 3G data reception processing unit. The reception processing unit as the modification 2 is the same as the 3G data reception processing unit 140a of FIG. The 3G power intensity measurement unit 143 is replaced with a 3G propagation loss measurement unit 147. That is, in the data reception processing unit 140b, the 3G propagation loss measurement unit is arranged after the demodulation processing unit 145.

  As described above, the mobile terminal provided with the configuration of the data reception processing unit 140b as the modification 2 as a data reception processing unit corresponding to each different communication method is used in the control unit (corresponding to the control unit 170 shown in FIG. 2). A communication method for actual communication is determined based on information output from the propagation loss measurement unit provided in each of the data reception processing units having different communication methods.

  That is, the mobile terminal having the configuration of the data reception processing unit 140b of the second modification is controlled based on the propagation loss instead of the power intensity. Note that the propagation loss is generally calculated from the base station output power transmitted from the base station and the received power at the mobile terminal 100. In this case, the processing in the control unit is performed by replacing “P_ALL_last” shown in FIG. 5 with the reciprocal of the propagation loss.

  That is, the reception state information input from the data reception processing unit of the predetermined communication method to the reception state information comparison unit 174 includes a propagation loss, and the reception state information comparison unit 174 includes the first, second and third A propagation loss comparison unit that compares the propagation loss of the reception state information in the communication method with a preset specified value of the propagation loss is provided. The control unit configured as described above selects the communication method having the highest received power by the optimum method selection unit, measures the reception state of the selected communication method, and then selects the reception method by the reception state information comparison unit 174. When the propagation loss of the communication method is compared with the specified value of the propagation loss, and the propagation loss of the reception state information of the selected communication method is smaller than the specified value of the propagation loss, the communication previously selected by the optimum method selection control unit 176 A communication method other than the communication method is selected, and the reception state corresponding to the selected other communication method is measured.

  In the present embodiment, the time periods T1, T2, and T3 for measuring signals from the base station are set in the reception processing units 140, 150, and 160 as T1 ≦ T2 ≦ T3, T3 = infinity, and the time period Is actually measuring only the T1 and T2 communication methods, but this is not the only case, and it always reduces the power consumption and processing amount without measuring signals from base stations of all communication methods. As long as both a high bit rate and a high bit rate can be achieved, any configuration may be used.

Specifically, first, the total reception power P_ALL_3G_last, P_ALL_S3G_last, and P_ALL_4G_last of each communication method is measured using the data reception processing units 140, 150, and 160 of all communication methods. Thereafter, the optimum method selection control unit 176 checks only the signal with the highest signal level and the signal with the second highest signal level.

  Then, when the difference between No. 1 and No. 2 becomes smaller than a preset constant value (including reverse rotation), the signal level in the communication system which is the third signal level is measured. Then, the optimum method selection control unit 176 performs re-ranking using the received power of all the methods, and measures only the received power in the communication method in which the first and second highest signal levels are measured.

  This process will be described in detail.

  FIG. 8 is a flowchart for explaining an example of a communication method selection method as processing of the mobile terminal 100 according to the present invention.

  Prior to the process shown in FIG. 8, as in the process shown in FIG. 5, first, the mobile terminal 100 is turned on, and then the 3G data reception processing unit 140 is configured to operate in all frequency bands used in the 3G system. The reception power P_ALL_3G_last is measured, the S3G data reception processing unit 150 measures the total reception power P_ALL_S3G_last in the frequency band used in S3G, and the 4G data reception processing unit 160 performs the total reception in the frequency band used in 4G. The received power P_ALL_4G_last is being measured. Then, the remaining battery level detection unit 174 measures the remaining power level of the battery 195 and performs a communication method selection process.

  In this communication method selection method, in step S201, the reception state information comparison unit 174 first uses the frequency at which the total received power in the frequency band used in 3G (hereinafter referred to as “P_ALL_3G_last”) is used in S3G. If it is determined whether or not the received power is greater than the total received power in the band (hereinafter, described as “P_ALL_S3G_last”), the process proceeds to step S202. If not, the process proceeds to step S203.

  In step S202, it is determined whether or not P_ALL_S3G_last is greater than the total received power in the frequency band used in 4G (hereinafter described as “P_ALL_4G_last”). If larger, the process proceeds to step S204; The process proceeds to step S205.

  In step S204, the reception state information comparison unit 174 outputs a comparison determination result of P_ALL_3G_last> P_ALL_S3G_last> P_ALL_4G_last to the optimum method selection control unit 176, and proceeds to step S206.

  In step S206, the optimum method selection control unit 176 causes the time period setting unit 177 to set the time period for checking the signal from the base station in the order of the received power in the order of T1, T2, T3 (T1 ≦ T2 ≦ T3). And T3 = infinity) is set, and the process proceeds to step S207. Specifically, in step S206, T_3G = T1, T_S3G = T2, and T_4G = T3 = ∞ are set.

  In step S207, the reception state information comparison unit 174 is used to determine whether P_ALL_3G_last-P_ALL_S3G_last <specified value P1. If P_ALL_3G_last-P_ALL_S3G_last is smaller than the specified value P1, the process proceeds to step S208, and P_ALL_3G_last- If P_ALL_S3G_last is greater than or equal to the specified value P1, the process ends.

  In step S208, the 4G data reception processing unit 160 measures the total received power P_ALL_4G_last in the frequency band used in 4G, and proceeds to step S201.

On the other hand, in step S205, P_ALL_3G_last> P_ALL_4G_last is determined, and P_ALL_3G_las
If t> P_ALL_4G_last, the process proceeds to step S209, and if not satisfied, the process proceeds to step S210.

  In step S209, the reception state information comparison unit 174 outputs a comparison determination result of P_ALL_3G_last> P_ALL_4G_last> P_ALL_S3G_last to the optimum method selection control unit 176, and proceeds to step S211.

  In step S211, the optimum method selection control unit 176 causes the time period setting unit 177 to set the time period for checking the signal from the base station in the order of the received power in the order of T1, T2, T3 (T1 ≦ T2 ≦ T3). And T3 = infinity) is set, and the process proceeds to step S212. Specifically, in step S211, T_3G = T1, T_4G = T2, and T_S3G = T3 = ∞ are set.

  In step S212, the reception state information comparison unit 174 is used to determine whether P_ALL_3G_last-P_ALL_4G_last <specified value P2 or not. If P_ALL_3G_last-P_ALL_4G_last is smaller than the specified value P2, the process proceeds to step S213, and P_ALL_3G_last- If P_ALL_4G_last is greater than or equal to the specified value P2, the process ends.

  In step S213, the S3G data reception processing unit 150 measures the total received power P_ALL_S3G_last in the frequency band used in S3G, and proceeds to step S201.

  In step S210, the reception state information comparison unit 174 outputs a comparison result of P_ALL_4G_last> P_ALL_3G_last> P_ALL_S3G_last to the optimum method selection control unit 176, and proceeds to step S214.

  In step S214, the optimum method selection control unit 176 uses the time period setting unit 177 to set the time period for checking the signal from the base station in the order of the received power in the order of T1, T2, T3 (T1 ≦ T2 ≦ T3). And T3 = infinity) is set, and the process proceeds to step S215. Specifically, in step S214, T_4G = T1, T_3G = T2, and T_S3G = T3 = ∞ are set.

  In step S215, the reception state information comparison unit 174 is used to determine whether P_ALL_4G_last-P_ALL_3G_last <specified value P3. If P_ALL_4G_last-P_ALL_3G_last is smaller than the specified value P3, the process proceeds to step S213, and P_ALL_3G_last- If P_ALL_4G_last is greater than or equal to the specified value P3, the process ends.

  In step S203, the reception state information comparison unit 174 determines whether or not P_ALL_S3G_last> P_ALL_4G_last. If P_ALL_S3G_last> P_ALL_4G_last, the process proceeds to step S216, and if not, the process proceeds to step S217.

  In step S216, the reception state information comparison unit 174 determines whether or not P_ALL_3G_last> P_ALL_4G_last. If P_ALL_3G_last> P_ALL_4G_last, the process proceeds to step S218, and if not, the process proceeds to step S219.

  In step S218, the reception state information comparison unit 174 outputs a comparison result of P_ALL_S3G_last> P_ALL_3G_last> P_ALL_4G_last to the optimum method selection control unit 176, and proceeds to step S220.

  In step S220, the optimum method selection control unit 176 causes the time period setting unit 177 to check the time period for checking the signal from the base station in order from the method with the highest reception power, T1, T2, T3 (T1 ≦ T2 ≦ T3). And T3 = infinity) is set, and the process proceeds to step S221. Specifically, in step S220, T_S3G = T1, T_3G = T2, and T_4G = T3 = ∞ are set.

  In step S221, the reception state information comparison unit 174 is used to determine whether P_ALL_S3G_last-P_ALL_3G_last <specified value P4. If P_ALL_S3G_last-P_ALL_3G_last is smaller than the specified value P4, the process proceeds to step S208 and P_ALL_S3G_last- If P_ALL_3G_last is greater than or equal to the specified value P4, the process ends.

  In step S219, the reception state information comparison unit 174 outputs a comparison result of P_ALL_S3G_last> P_ALL_4G_last> P_ALL_3G_last to the optimum method selection control unit 176, and proceeds to step S222.

  In step S222, the optimum method selection control unit 176 causes the time period setting unit 177 to set the time period for checking the signal from the base station in order from the method with the highest reception power, T1, T2, T3 (T1 ≦ T2 ≦ T3). And T3 = infinity) is set, and the process proceeds to step S223. Specifically, in step S222, T_S3G = T1, T_4G = T2, and T_3G = T3 = ∞ are set.

  In step S223, the reception state information comparison unit 174 is used to determine whether P_ALL_S3G_last-P_ALL_4G_last <specified value P5. If P_ALL_S3G_last-P_ALL_4G_last is smaller than the specified value P5, the process proceeds to step S224 and P_ALL_S3G_last- If P_ALL_4G_last is equal to or greater than the specified value P5, the process ends.

  In step S224, the 3G data reception processing unit 140 measures the total received power P_ALL_3G_last in the frequency band used in 3G, and proceeds to step S201.

  In step S217, the reception state information comparison unit 174 outputs a comparison result of P_ALL_4G_last> P_ALL_S3G_last> P_ALL_3G_last to the optimum method selection control unit 176, and proceeds to step S225.

  In step S225, the optimum method selection control unit 176 causes the time period setting unit 177 to check the time period for checking the signal from the base station in the order of the received power in the order of T1, T2, T3 (T1 ≦ T2 ≦ T3). And T3 = infinity) is set, and the process proceeds to step S226. Specifically, in step S225, T4 = T1, T_S3G = T2, and T_3G = T3 = ∞ are set.

  In step S226, the reception state information comparison unit 174 is used to determine whether P_ALL_4G_last-P_ALL_S3G_last <specified value P6. If P_ALL_4G_last-P_ALL_S3G_last is smaller than the specified value P6, the process proceeds to step S224, and P_ALL_4G_last- If P_ALL_S3G_last is greater than or equal to the specified value P6, the process ends.

  In step S224, the 3G data reception processing unit 140 measures the total received power P_ALL_3G_last in the frequency band used in 3G, and proceeds to step S201.

  That is, the above-described communication method selection method classifies the cases of steps S204, S209, S210, and S217 to S219 for each large and small pattern of the total received power in the frequency bands used in 3G, S3G, and 4G. Thereafter, in steps S206, S211, S214, S220, S222, and S225, the time period for checking the signal from the base station is set to T1, T2, T3 (however, T1 ≦ T2 ≦ T3) in order from the system having the highest received power. , T3 = infinity), and change the time period to be checked for each method.

Next, in steps S207, S212, S215, S221, S223, and S226, the received power difference of the method in which T1 and T2 are selected as the signal check period in steps S206, S211, S214, S220, S222, and S225, that is, received power ( It is determined whether the (true number) ratio is smaller than a prescribed value Pn (n = 1, 2, 3...). As a result of this determination, if the received power difference of the method in which T1 and T2 are selected is smaller than Pn, the frequency used in the method in which T3 is selected as the signal check period in steps S206, S211, S214, S220, S222, and S225. After measuring the total received power in the band, the process returns to step S201, and the received signals of each method are ranked again. If larger, the process is terminated. As described above, in this embodiment, it is possible to achieve both low power consumption, reduction in processing amount, and high bit rate.

  Further, in the communication system 200, the mobile terminal 100 assumes that the area 231 of the 4G base station 230 exists in the area 221 of the S3G base station 220. Therefore, for the 4G communication scheme, the S3G signal level is 3G. The signal level may be checked when it becomes higher.

  FIG. 9 is a flowchart for explaining an example of processing for checking the signal level of the 4G communication method when the mobile terminal 100 moves in the direction A in the communication system 200.

  As shown in FIG. 9, in step S301, the 3G reception data processing unit 140 measures the total received power P_ALL_3G_last in the frequency band used in 3G. Next, in step S302, the 3G reception data processing unit 150 measures the total received power P_ALL_S3G_last in the frequency band used in S3G, and proceeds to step S303.

  In step S303, the reception state information comparison unit 174 determines whether the difference between the total received power P_ALL_3G_last in the frequency band used in 3G and the total received power P_ALL_S3G_last in the frequency band used in S3G is larger than the specified value P7. Compare if small. If this difference is small, the process proceeds to step S304. If the difference is large, the process proceeds to step S305, and the time periods for checking signals from the 3G, S3G, and 4G base stations 210, 220, and 230 are set to T1, After setting T2 and T3 (= ∞), the process is terminated.

  In step S304, the 4G reception data processing unit 160 measures the total received power P_ALL_4G_last in the frequency band used in 4G, and proceeds to step S306.

  In step S306, the reception state information comparison unit 174 compares the difference between the total received power P_ALL_S3G_last in the frequency band used in S3G and the total received power P_ALL_4G_last in the frequency band used in 4G with the specified value P8, If the difference is small, the process proceeds to step S307, and if the difference is large, the process proceeds to step S308.

  In step S307, which is processing when (P_ALL_S3G_last)-(P_ALL_4G_last) <P8, the optimum scheme selection control unit 176 uses the time period setting unit 177 to start from the 4G, S3G, and 3G base stations 210, 220, and 230. The time periods for checking the signals are set to T1, T2, and T3 (= ∞), respectively, and then the process ends.

  In step S308, which is processing when (P_ALL_S3G_last) − (P_ALL_4G_last) ≧ P8, time periods for checking signals from the S3G, 4G, and 3G base stations 210, 220, and 230 are set to T1, T2, and T3 (= ∞, respectively). After that, the process ends.

  As described above, for the 4G communication method in the mobile terminal 100, the signal level is checked when the S3G signal level becomes higher than 3G. Therefore, the reception signal levels of the three communication methods are always set. In the mobile terminal 100 in the communication system 200, it is possible to achieve both low power consumption, reduced processing amount, and high bit rate.

  In addition, the mobile terminal 100 may first measure the reception states of all communication methods, and check only the first one thereafter. That is, another communication method may be checked only when the communication method being used is about to be cut off (when the communication method is smaller than another specified value).

  FIG. 10 is a diagram illustrating another example of a communication method selection method in the mobile terminal 100.

  First, the 3G, S3G, and 4G data reception processing units 140, 150, and 160 measure all received powers P_ALL_3G_last, P_ALL_S3G_last, and P_ALL_4G_last in frequency bands used in 3G, S3G, and 4G, respectively. Further, the remaining battery level detection unit 172 measures the remaining power level of the battery 195. After these processes, the mobile terminal 100 performs a communication method selection process as shown in FIG.

  That is, as illustrated in FIG. 10, in steps S401 to S403, the reception state information comparison unit 174 performs the total received power P_ALL_3G_last in the frequency band used in 3G, the total received power P_ALL_S3G_last in the frequency band used in S3G, The total received power P_ALL_4G_last in the frequency band used in 4G is compared and determined.

  Thereafter, in steps S404, S411, and S417, based on the determination result of the reception state information comparison unit 174, the optimum method selection control unit 176 has the maximum received power in the frequency bands used in 3G, S3G, and 4G. Let T1 be the signal check time period for one method and infinity for the other methods.

  After that, in steps S405, S412, and S418, the reception state information comparison unit 174 determines whether or not the received signal power of the method in which the signal check time period is T1 is smaller than the specified value. In each of these steps S405, S412, and S418, if the determination result is large, the process returns to steps S405, S412, and S418, respectively, and the signal check time period is set to the check time T1 without changing to another communication method. Check the signal from the base station of T1.

  On the other hand, in these steps S405, S412, and S418, if the determination result is small, the process proceeds to steps S406, S413, and S419, respectively.

  In steps S406, S407, S413, S414, S419, and S420, the total received power in the frequency band used in the method in which the check time is set to ∞ in the previous steps S404, S411, and S417 is measured.

  In steps S408, S415, and S421, the reception state information comparison unit 174 uses a method in which the check time is set to ∞ in each of the previous steps S404, S411, and S417, for example, frequency bands used in S3G and 4G in step S417. Compare the total received power at.

  As a result, based on the comparison result from the reception state information comparison unit 174, the optimum method selection control unit 176 sets T1 as the base station signal check time period of the method with higher received power in steps S409, S410, and S416. After making the check time of other methods infinite, the process is terminated. For example, in step S409, the base station signal check time period of the S3G system is set to T1, and the check time of other systems is set to infinity.

Note that, as a variation of the communication method selection method in the mobile terminal 100 shown in FIG. 10, the optimum method selection control unit 176 determines the received power value and the received power value in the reception status information of the communication method having the first highest received power. When the received power value of the reception status information of the communication method with the first largest received power is smaller than the specified value of the received power value by comparing with the specified value, the first, second and third communication methods Among them, a method of selecting a communication method having the largest quotient when the received power is divided by the communication rate as a communication method for measuring the reception state is also conceivable.

  That is, even if the received power value in the frequency band of the measured communication method is smaller than the specified value of the received power value, the error rate can be lowered if the communication rate of the measured communication method is small. The communication method having the largest ratio of the power / communication rate to the received power is measured (checked). Therefore, the mobile terminal 100 first measures the reception state of all communication methods, checks only the first one at that time, and checks only the first after that, and the communication method used is likely to be cut off. Check the other communication method only when (when it becomes smaller than the specified value).

  Since the communication method is selected in this way, it is not necessary to check the reception state of signals of all receivable communication methods, so that the power consumption in the mobile terminal 100 can be reduced.

  Also, in the mobile terminal 100 having the above-described configuration, when the signal reception power level difference of the three (3G, S3G, 4G) methods measured first is the same, only the default value, that is, the method having the default measurement frequency is measured. However, even when the signal reception power level difference of the three methods (3G, S3G, 4G) measured first is small (MAX (a, b, c) -MIN (a, b, c) <specified value) Alternatively, it may be configured to measure only the method of the default measurement frequency (the mainstream at that time).

  For example, when the communication method of the signal set as the default measurement frequency is 3G, only the signal from the 3G base station is measured. The default base station is supported by rewriting the farm.

  FIG. 11 is a flowchart for explaining processing when the power level difference of the received signal measured first is small.

  In step S601, the reception state information comparison unit 174 compares the difference between the value of the method that takes the maximum value and the value of the method that takes the minimum value of all the measured received powers with the preset specified value P12 (MAX). (P_ALL_3G_last, P_ALL_S3G_last, P_ALL_4G_last) −MIN (P_ALL_3G_last, P_ALL_S3G_last, P_ALL_4G_last) <P12).

  In step S601, when the difference between the value of the method that takes the maximum value and the value of the method that takes the minimum value of the measured total received power is larger than the specified value P12, the process proceeds to step S602. The processing from step S602 to step S622 is the same as the processing from step S401 to step S421 described in FIG.

  In step S601, when the difference between the value of the method that takes the maximum value and the value of the method that takes the minimum value among the measured total received power is smaller than the specified value P12, the process proceeds to step S623.

  In step S623, the optimum scheme selection control unit 176 sets the time period setting unit 177 to check only the signal of the base station that should be checked by default in the specified time period, and is specified by default. The measured data reception processing unit is made to measure. In FIG. 11, the default checking method is the 3G method, but the present invention is not limited to this, and an S3G method or a 4G method may be used.

Next, in step S624, the reception state information comparison unit 174 compares the total reception power (here, 3G total reception power P_ALL_3G_last) in the frequency band used by default with the specified value P13, and is equal to or greater than the specified value P13. If so, the process returns to step S623, and the total received power (here, 3G total received power P_ALL_3G_last) in the frequency band used in the default method is checked again.

  On the other hand, if it is determined in step S624 that the total received power in the frequency band used by default (here, 3G total received power P_ALL_3G_last) is smaller than the specified value P13, the process proceeds to steps S625 and S626 in order. The total received power (P_ALL_S3G_last, P_ALL_4G_last in FIG. 11) of each communication method in the frequency band used in the non-method (S3G, 4G method in FIG. 11) is measured.

  In step S627, the total received power (P_ALL_S3G_last, P_ALL_4G_last in FIG. 11) in the frequency band used in the measured non-default method (S3G, 4G method in FIG. 11) is compared. Specifically, in step S627, it is determined whether or not the total received power P_ALL_S3G_last of S3G is greater than the total received power P_ALL_4G_last of 4G, and if so, the process proceeds to step S610, The process proceeds to step S611.

  In steps S610 and S611, the base station signal check time period of the communication method with the larger received power is set to T1 among all the received powers compared, and the check time of the other methods is set to infinity, and then the process ends. To do. For example, in step S610, the base station signal check time period of the S3G system is set to T1, and the check time of other systems is set to infinity.

  That is, in steps S610, S611, and S617, the signal check time period of the method with large received power among the non-default communication methods is set to T1, and the processing is terminated with ∞ as the other.

  Here, the method to be measured by default can be dealt with by rewriting the firmware based on the control signal from the base station. As a result, when the service is not started yet or the service is terminated, the control method in the terminal is changed without the operator of the mobile terminal 100 performing consciousness and complicated operation, thereby suppressing wasteful power consumption. I can do it.

  FIG. 12 is a block diagram illustrating a schematic configuration of a mobile terminal 500 that is another example of the mobile terminal apparatus belonging to the communication system 200 according to the embodiment of this invention.

  A mobile terminal 500 illustrated in FIG. 12 has a function of transmitting and receiving data corresponding to each of a plurality of communication methods in the communication system 200.

  The mobile terminal 500 performs measurement by changing the time interval for measuring signals from the base stations 210, 220, and 230 for each communication method, and determines a communication method to be used when transmitting / receiving data based on the measured value. .

The determination method in mobile terminal 500 is SIR (desired wave signal power to interference power ratio, Signal
to Interference power Ratio), and first measure the reception status (SIR) of the communication system that can communicate, and check only the first reception status (SIR in this case) at that point. To do. When the SIR becomes smaller than the specified value, control is performed to measure the SIR of another communication method.

A mobile terminal 500 shown in FIG. 12 has a basic configuration similar to that of the mobile terminal 100 corresponding to the embodiment shown in FIG. 2, a measurement unit that measures reception state information of each communication method, and these measurement units Only the configuration of the control unit that selects the optimum communication method based on the reception state information measured by the above is different. Therefore, below, the same code | symbol is attached | subjected to the same component and the description is abbreviate | omitted.

  That is, in the mobile terminal 500, the data reception processing units 140, 150, and 160 for each communication method are replaced with the 3G, S3G, and 4G power intensity measuring units 143, 153, and 163, for 3G, for S3G, and 4G. SIR measuring units 148, 158, and 168 are provided.

  The 3G, S3G, and 4G data reception processing units 140c, 150a, and 160a are 3G, S3G, and 4G low noise amplifiers 142, 152, and 162, and a reception processing unit 144 that perform processing in the respective communication methods. 154, 164, demodulation processing units 145, 155, 165, decoding processing units 146, 156, 166, 3G, S3G, 4G SIR measurement units 148, 158, 168.

  The 3G, S3G, and 4G SIR measurement units 148, 158, and 168 measure the SIR of the input signals after demodulation using the input signals, respectively. These measurement results are output to the controller 170a.

  In addition, the mobile terminal 500 includes a control unit 170a that performs communication method selection processing based on the measurement information from each of the SIR measurement units 148, 158, and 168.

  The mobile terminal 500 measures the SIR value in each communication method at a predetermined time period set by the control unit 170a in the data reception processing units 140c, 150a, 160a of a plurality of communication methods. The measured total received power and SIR value are output to the controller 170a as reception state information.

  FIG. 13 is a block diagram showing a main configuration of the control unit 170a in the mobile terminal 500 shown in FIG.

  As shown in FIG. 13, the control unit 170a determines which communication is performed based on signals input from the 3G, S3G, and 4G data reception processing units 140c, 150a, and 160a, information from the memory 190, and information on the battery 195. The communication method (here, 3G, S3G, 4G) is selected, and using the selection result, in the data transmission method selection unit 102, which transmission method the input signal input to the data transmission method selection unit 102 is selected. To determine whether to transmit as information.

  The control unit 170a includes a remaining battery level detection unit 172, a reception state information comparison unit 174a, and an optimum method selection control unit 176a. The reception state comparison unit 174a includes a SIR comparison unit 1742.

  The SIR comparison unit 1742 calculates the SIR in the use frequency band of the communication method among the reception state information which is a signal input from the 3G data reception processing unit 140c, the S3G data reception processing unit 150a, and the 4G data reception processing unit 160a. In comparison, the result is output to the optimum method selection control unit 176a as a comparison result of the reception status of the signals from the base stations 210, 220, and 230 of each communication method.

  Based on information from the control table stored in the battery remaining amount detection unit 172, the SIR comparison unit 1742 of the reception state information comparison unit 174a, the memory 190, etc., the optimum method selection control unit 176a in the actual radio wave propagation environment state Select the most suitable communication method.

Specifically, the optimum method selection control unit 176a measures SIRs based on the received signals in descending order when the SIR values of the received signals from the respective communication methods output as the comparison results by the reception state information comparing unit 174a are different. A time period setting unit 177 is provided for setting time periods T1, T2, and T3 (where T1 ≦ T2 ≦ T3). At this time, the time period setting unit 177 sets T2 = T3 = ∞ so that the actual measurement is performed only in the communication method with the time period T1. When the SIR values of the received signals in the plurality of communication methods are the same, the optimum method selection control unit 176a selects the communication method set as the default value.

  Then, the optimum method selection control unit 176a sends a time period to the 3G data reception processing unit 140c, the S3G data reception processing unit 150a, and the 4G data reception processing unit 160a in order to transmit and receive data according to the selected communication method. The setting unit 177 outputs and controls a control signal for measuring the reception state, here, the SIR in a set time period.

  That is, in the optimum method selection control unit 176a, the time period setting unit 177 sets the SIR of the corresponding base stations 210, 220, and 230 for each of the 3G, S3G, and 4G data reception processing units 140c, 150a, and 160a. Set the measurement time period (T1, T2, T3). Note that T1, T2, and T3 in this embodiment are arbitrary periods that satisfy 0 <T1, T2, T3 ≦ ∞, and T1 ≦ T2 ≦ T3.

  The time period setting unit 177 assigns these set time periods to the data reception processing units 140c, 150a, and 160a, so that the optimum method selection control unit 176a actually measures the reception state (here, SIR). The communication method is selected.

  In the optimum method selection control unit 176a, the setting of the time period in the time period setting unit 177 is associated with the remaining power of the battery 195 and the SIR value, and the remaining power of the battery 195 stored in the memory 190 (battery Remaining amount), SIR value, base station check time T and SIR. Specifically, the setting of the time period is for selecting a communication method. Among the received signals from the 3G, S3G, and 4G base stations 210, 220, and 230, which received signal is received and received. This is synonymous with the setting of whether to measure the state (SIR).

  In this manner, the control unit 170a of the mobile terminal 500 first causes the data reception processing units 140c, 150a, and 160a to measure the total received power for each communication method. Then, the measured received power for each communication method is compared by the SIR comparison unit 1742 of the reception state information comparison unit 174a, and the optimum method selection control unit 176a determines the communication method with the highest SIR value from the comparison result. Select the communication method that uses the signal. Then, the SIR of the selected signal thereafter is measured using the data reception processing unit of the communication method having the highest SIR value. The SIR comparison unit 1742 monitors the SIR of the received signal in the communication method with the highest received signal, and controls to measure the SIR of the other communication method when it is smaller than a preset specified value.

  Since the communication method is selected in this way, it is not necessary to check the reception status of all receivable communication methods, so that the mobile terminal 500 can reduce power consumption and improve QoS (Quality of Service). Can do.

  The mobile terminal 500 is configured to measure the SIR of each communication method. However, the present invention is not limited to this, and the SIR value is measured at a base station that is a communication partner (for example, base stations indicated by 210, 220, and 230 in FIG. 1). Only the mobile terminal 500 may be notified. In this case, instead of the SIR measuring units 148, 458 and 168, a SIR value acquiring unit for acquiring the SIR value from the received signal is arranged.

  In the mobile terminal 500, the data reception processing units 140c, 150a, and 160a for each communication method are configured to include SIR measurement units 148, 158, and 168 as means for detecting the reception information state. The configuration is not limited, and a bit rate measuring unit that measures the bit rate of the received signal may be provided in place of the SIR measuring units 148, 158, and 168. In this case, in the control unit 170a, the reception state information comparison unit 174a has a configuration in which a bit rate comparison unit is provided instead of the SIR comparison unit 1742. In this case, since the SIR in each communication method is the same as the comparison target in place of the bit rate in each communication method, the other comparison methods and the like are the same. Further, in the mobile terminal 500, the data reception processing units 140c, 150a, and 160a of each communication method may detect the received information state as BER or FER instead of SIR. In this case, instead of the SIR measuring units 148, 158, and 168, a measuring unit for measuring the BER or FER of the received signal is provided, and the control unit side also replaces the SIR comparing unit with the BER. The comparison unit or the FER comparison unit is arranged.

  Further, the mobile terminal 500 may be configured to compare the received power value together with the SIR value in each communication method and select a communication method to be used based on the comparison result. For example, in the mobile terminal 500, the data reception processing units 140c, 150a, and 160a of a plurality of communication schemes have the power intensity together with the SIR value, specifically, the total received power P_ALL_3G_last and P_ALL_S3G_last in the corresponding frequency band of the corresponding communication scheme. , P_ALL_4G_last is measured and output to the controller 170a. On the other hand, the control unit 170a configures the reception state information comparison unit 174a to compare the magnitudes of all received powers P_ALL_3G_last, P_ALL_S3G_last, and P_ALL_4G_last.

  In detail, in the control unit 170a, the SIR comparison unit 1742 includes the reception status information that is a signal input from the 3G data reception processing unit 140c, the S3G data reception processing unit 150a, and the 4G data reception processing unit 160a. In addition to comparing SIRs in the communication system use frequency band, and having a preset value set in advance for comparison with these input SIR values, the SIR of each communication method is compared with a preset specified value. Thus, the result is compared with the reception status of the signals from the base stations 210, 220, and 230 of each communication method, and is output to the optimum method selection control unit 176a.

  Then, the optimum method selection control unit 176a determines the actual radio wave propagation environment based on information from the battery remaining amount detection unit 172, the SIR comparison unit 1742 of the reception state information comparison unit 174a, the control table stored in the memory 190, and the like. Select the communication method most suitable for communication in the state. Specifically, the optimum method selection control unit 176a measures the SIRs based on the received signals in descending order when the power values of the received signals from the respective communication methods output as the comparison results by the reception state information comparing unit 174a are different. A time period setting unit 177 is provided for setting time periods T1, T2, and T3 (where T1 ≦ T2 ≦ T3). At this time, the time period setting unit 177 sets T2 = T3 = ∞ so that the actual measurement is performed only in the communication method with the time period T1.

  When the power values of the received signals in the plurality of communication methods are the same, the optimum method selection control unit 176a selects the communication method set as the default value. Next, the optimum method selection control unit 176a sends a time period to the 3G data reception processing unit 140c, the S3G data reception processing unit 150a, and the 4G data reception processing unit 160a in order to transmit and receive data according to the selected communication method. The setting unit 177 outputs and controls a control signal for measuring the reception state, here, the SIR in a set time period.

That is, in the optimum method selection control unit 176a, the time period setting unit 177 sets the SIR of the corresponding base stations 210, 220, and 230 for each of the 3G, S3G, and 4G data reception processing units 140c, 150a, and 160a. Set the measurement time period (T1, T2, T3). Note that T1, T2, and T3 in this embodiment are arbitrary periods that satisfy 0 <T1, T2, T3 ≦ ∞, and T1 ≦ T2 ≦ T3.

  By assigning these set time periods to the data reception processing units 140c, 150a, and 160a, the optimum method selection control unit 176a selects a communication method for actually measuring the reception state (here, SIR).

  In this manner, the control unit 170a of the mobile terminal 500 first causes the data reception processing units 140c, 150a, and 160a to measure the total received power for each communication method. Then, the received power of each measured communication method is compared, and based on the comparison result, the optimum method selection control unit 176a selects the communication method that uses the signal of the communication method having the highest received power level.

  Then, the SIR of the selected signal thereafter is measured using the data reception processing unit of the communication method having the highest received power level. The SIR comparison unit 1742 monitors the SIR of the received signal in the communication method with the highest received signal, and controls to measure the SIR of the other communication method when it is smaller than a preset specified value. Since the communication method is selected in this way, it is not necessary to check all the reception states of signals of the receivable communication method, and the mobile terminal 500 can reduce power consumption and improve QoS (Quality of Service). Can do.

  Further, in the mobile terminals 100 and 500, the 3G data reception processing units 140 and 140c, the S3G data reception processing units 150 and 150a, and the 4G data reception processing units 160 and 160a are one system (finger or the like) in RAKE reception. It may be constituted by.

  In addition, although it is about the received signal in the utilization frequency band each measured in the data reception process part 140,140a-140c, 150,150a, 160,160a of each communication system, the power value of the received signal of each communication system measured is In the case where they are the same, the optimum method selection control units 176 and 176a select the communication method set as the default value, but not limited to this, select the communication method with the higher power peak of the received signal. It is good also as composition to do.

  For example, in mobile terminals 100 and 500 according to the present embodiment, the peak power measurement function is added to power intensity measurement units 143, 153, and 163 or SIR measurement units 148, 158, and 168, but the band of the received signal is narrow. Prioritize the strong signal method.

  FIG. 14 shows the same power value when measuring received signals of different communication methods by adding a peak power measurement function to the power intensity measurement units 143, 153, 163 or SIR measurement units 148, 158, 168. It is a figure which shows an example of the received signal of the communication system from which an electric power peak differs.

  FIG. 14 shows the power value 801 of the total received power P_ALL_3G_last in the frequency band used in 3G and the power value 802 of the total received power P_ALL_S3G_last in the frequency band used in S3G, and the area of the power value 801 is shown. = Area of power value 802.

As shown in FIG. 14, when the S3G method is higher, the reception state is determined using information output from the power intensity measurement units 143, 153, 163 or the SIR measurement units 148, 158, 168 to the control units 170, 170a. The information comparison units 174 and 174a perform comparison including the power peak, and the optimum method selection control units 176 and 176a select the S3G communication method having a high power peak. As described above, priority is given to a method having a high peak power, so that communication speed and quality can be improved, and power saving and a high bit rate can be achieved in a communication method used.

  In addition, the control unit 170 compares the received power value in the reception state information of the communication method with the first largest reception power with the specified value of the received power value in the reception state information comparison unit 174, and receives the first. When the received power value of the reception state information of the communication method with the higher power is smaller than the preset value of the received power value, the optimum method selection control unit 176 receives the received power among the 3G, S3G, and 4G communication methods. The communication method having the largest quotient when the value is divided by the communication rate may be selected as the communication method for measuring the reception state, and the reception state may be measured.

  In this embodiment, the cellular system is mainly described as a communication system having a different communication method. However, a system combined with another wireless communication system such as a wireless LAN or a fixed wireless system may be used.

  The mobile communication terminal device and the communication system according to the present invention can communicate with each of a plurality of communication systems having different frequency bands, have an effect of saving power, and have different frequency bands mixed together. It is useful as something used in the region.

The figure which shows an example of the communication system which has a mobile communication terminal which concerns on one embodiment of this invention The figure which shows an example of the relationship between the received signal strength and receiving position of each system which the mobile communication terminal shown to FIG. 1A receives The figure which shows an example of the relationship between the received signal strength and frequency of each system which the mobile communication terminal shown to FIG. 1A receives The block diagram which shows schematic structure of the mobile terminal as a mobile communication terminal device which concerns on one embodiment of this invention The block diagram which shows the principal part structure of the control part in the mobile communication terminal shown in FIG. The figure which shows the relationship between the electric power remaining amount of the battery stored in memory, and the time period at the time of measuring a communication state Flowchart explaining basic processing of mobile terminal according to the present embodiment The figure which shows the modification of the data reception process part for 3G The figure which shows another modification of the data reception process part for 3G Flowchart for explaining an example of a communication method selection method as processing of a mobile terminal according to the present invention A flowchart for explaining an example of processing for checking a signal level of a 4G communication method when a mobile terminal moves in the A direction in a communication system. The figure which shows another example of the selection method of the communication system in a mobile terminal Flowchart explaining processing when power level difference of received signal measured first is small The block diagram which shows schematic structure of the mobile terminal which is another example of the mobile communication terminal device which belongs to the communication system which concerns on embodiment of this invention. The block diagram which shows the principal part structure of the control part in the mobile terminal shown in FIG. The figure which shows an example of the received signal of the communication system which is the same power value and has a different power peak when measuring the received signal of a different communication system

Claims (7)

Battery,
The signals received by the first, second, and third communication systems that are driven by the battery and that have different usage frequency bands and communication areas and that the communication areas become narrower in the overlapping order are received via the antenna, respectively. From the first, second and third receiving means for measuring the reception state for each of the first, second and third communication methods, respectively, and outputting as reception state information including a reception power value, respectively
Based on the remaining battery level of the battery and the reception status information for each of the first, second and third receiving means, one or two receiving means among the first, second and third receiving means A control unit that sets a measurement cycle of the reception state, controls the one or two reception units according to the set measurement cycle, and measures the reception state;
A comparison unit that compares the received power in the first, second, and third communication schemes using the reception state information indicating the measured reception state;
Based on the comparison result of the comparison unit, a communication method for measuring a reception state is selected from the first, second, and third communication methods, and the first, second, and third receiving units are selected. A method selection unit that sets the measurement period for a receiving unit corresponding to the selected communication method;
The mobile communication terminal apparatus, wherein the control means controls the reception means corresponding to the communication method selected by the method selection unit to measure the reception state.   The method selection unit compares the reception power value in the reception state information of the communication method with the first largest reception power with the specified value of the reception power value, and receives the reception state information of the communication method with the first largest reception power. When the received power value is smaller than the specified value of the received power value, the communication method having the largest quotient when the received power is divided by the communication rate is received from the first, second and third communication methods. The mobile communication terminal apparatus according to claim 1, wherein the mobile communication terminal apparatus is selected as a communication method for measuring a state.   The method selection unit compares the ratio of the reception power value of the reception state information of the two communication methods with the first and second largest reception power with the specified value of the reception power ratio, and the ratio of the reception power value is The mobile communication terminal apparatus according to claim 1, wherein when the received power ratio is smaller than a specified value, a communication method other than the communication method having the first highest received power is selected. The reception status information includes a SIR value,
The comparison unit includes an SIR comparison unit that compares an SIR value of the reception state information in the first, second, and third communication methods with a predetermined value of a preset SIR,
The method selection unit compares the SIR value of the communication method having the first highest received power with the specified value of the SIR, and the SIR value of the reception state information of the communication method having the first highest received power is the SIR. 2. The mobile communication terminal apparatus according to claim 1, wherein a communication method other than the communication method having the first largest reception power is selected when the communication value is smaller than the prescribed value. The reception status information includes a propagation loss,
The comparison unit includes a propagation loss comparison unit that compares the propagation loss of the reception state information in the first, second, and third communication methods with a preset value of the propagation loss,
The method selection unit compares the propagation loss of the first communication method with the largest received power with the specified value of the propagation loss, and the propagation loss of the reception state information of the communication method with the first received power is the The mobile communication terminal apparatus according to claim 1, wherein when the transmission loss is smaller than a specified value, a communication method other than the communication method with the first largest reception power is selected.   The control means sets the measurement period of the reception state in the first and second reception means to measure the reception state of the signals of the first communication method and the second communication method, and the received power value of the second communication method The mobile communication terminal apparatus according to claim 1, wherein, when the received power value of the first communication method is higher than the first receiving means, the measurement period is set in the third receiving means instead of the first receiving means. The mobile communication terminal device according to claim 1,
A first base station device that communicates with the mobile communication terminal device using a signal of a first communication method;
A second base station device that communicates with the mobile communication terminal device using a signal of a second communication method that is different in frequency band from the first communication method and has a smaller communication area than the communication area of the first communication method;
A third base station apparatus that communicates with the mobile communication terminal apparatus using a signal of a third communication system that is different in frequency band from the first and second communication systems and has a communication area that is narrower than the communication area of the second communication system; ,
Comprising
The second base station apparatus is arranged in the area of the first communication scheme, and the third base station apparatus is a communication system arranged in the communication area of the second communication scheme.

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