JP5455581B2 - Wireless terminal - Google Patents

Description

  The present invention relates to a radio communication system, a radio base station, a radio terminal, and a radio communication method using both a CDMA scheme and an OFDM scheme.

  Currently, third generation (or 3.5 generation) mobile phone systems using a CDMA (Code Division Multiple Access) system are widely used.

  In recent years, an OFDM (Orthogonal Frequency Division Multiplexing) scheme that transmits data in parallel using a plurality of subcarriers orthogonal to each other has attracted attention as a new communication scheme. The OFDM method can be used in fourth generation (or 3.9 generation) mobile phone systems and the like because it can exhibit higher communication performance than the CDMA method.

  In wireless communication systems such as mobile phone systems, wireless base stations corresponding to new communication methods are gradually installed. Therefore, in the transition period from the third generation to the fourth generation, both the CDMA method and the OFDM method are used. Wireless terminals that are compatible with the system are expected to become widespread.

  Conventionally, a wireless terminal (so-called dual terminal) that supports two communication methods uses a communication method used for wireless communication with a wireless base station (hereinafter, used communication method) using the following method. Switching. For example, the dual terminal compares the reception levels measured in the respective communication methods, and switches the communication method used from the communication method with the lower reception level to the communication method with the higher reception level (see Patent Document 1).

JP 2009-50056 A

  By the way, the receiving side in the wireless communication system receives a combined wave of a plurality of radio waves (multipath waves) having different paths from the transmitting side. For this reason, in the OFDM system, the transmission side adds a guard interval for absorbing the time difference between the preceding wave and the delayed wave for each OFDM symbol.

  However, when a delayed wave exceeding the guard interval time length occurs, interference (so-called intersymbol interference) occurs between temporally preceding and succeeding OFDM symbols in the received signal on the receiving side, and communication performance deteriorates.

  Here, since the conventional dual terminal simply selects the communication method with the higher reception level, the OFDM method is used if the reception level of the OFDM method is higher than the CDMA method. However, when intersymbol interference occurs in the OFDM system, not only the original communication performance of the OFDM system cannot be exhibited, but the communication performance may be lower than that of the CDMA system. Considering intersymbol interference, when a dual terminal is switched to a CDMA radio base station by intersymbol interference and switched to the OFDM system at the same position as the switched position, the influence of intersymbol interference is again affected. There is a problem of receiving.

  Accordingly, an object of the present invention is to provide a wireless terminal that avoids deterioration in communication performance due to intersymbol interference.

  The radio terminal of the present invention is a radio terminal that can communicate with an OFDM radio base station compatible with the OFDM scheme, and that can communicate with a CDMA radio base station compatible with the CDMA scheme, and which has generated intersymbol interference. After switching from the station connection to the CDMA radio base station connection, if it is determined that the own radio terminal has moved, the control unit is configured to control to switch to the OFDM radio base station connection.

  ADVANTAGE OF THE INVENTION According to this invention, the radio | wireless terminal which avoids the fall of the communication performance by intersymbol interference can be provided.

1 is an overall schematic diagram of a wireless communication system according to an embodiment of the present invention. It is a figure for demonstrating the OFDM signal which the radio | wireless terminal which concerns on embodiment of this invention receives. It is a figure for demonstrating the guard interval in an OFDM system. It is a block diagram which shows the structure of the radio | wireless terminal which concerns on embodiment of this invention. It is a block diagram which shows the structure of the wireless base station which concerns on embodiment of this invention. It is a figure for demonstrating the EVM and EVM threshold value which concern on embodiment of this invention. It is a sequence diagram which shows the operation pattern 1 of the radio | wireless communications system which concerns on embodiment of this invention. It is a sequence diagram which shows the operation | movement pattern 2 of the radio | wireless communications system which concerns on embodiment of this invention. It is a figure for demonstrating the waveform measurement process which concerns on other embodiment. It is a sequence diagram which shows the operation pattern 3 of the radio | wireless communications system which concerns on embodiment of this invention.

  Next, an embodiment of the present invention will be described with reference to the drawings. Specifically, (1) Overview of wireless communication system, (2) Configuration of wireless terminal, (3) Configuration of wireless base station, (4) Operation of wireless communication system, (5) Effects of embodiment, (6 ) Other embodiments will be described. In the description of the drawings in the following embodiments, the same or similar parts are denoted by the same or similar reference numerals.

(1) Overview of Radio Communication System FIG. 1 is an overall schematic diagram of a radio communication system 10 according to the present embodiment.

  As shown in FIG. 1, the radio communication system 10 includes a radio terminal 100, a radio base station 200 (first radio base station), and a radio base station 300 (second radio base station).

  The radio terminal 100 is a dual terminal that supports both the CDMA scheme and the OFDM scheme. The radio base station 200 corresponds to the OFDM scheme, and the radio base station 300 corresponds to the CDMA scheme. In this specification, the OFDM scheme includes an OFDMA (Orthogonal Frequency Division Multiplexing Access) scheme.

  In this embodiment, the OFDM communication standard is LTE (Long Term Evolution) standardized in 3GPP (3rd Generation Partnership Project). In LTE, the OFDM scheme is used for the downlink. In the following, the downlink will be mainly described. In this embodiment, the CDMA communication standard is cdma2000 standardized in 3GPP2. In cdma2000, the CDMA system is used for both the uplink (reverse link) and the downlink (forward link).

  Radio base station 200 forms part of LTE network (referred to as “E-UTRAN”) 20. The radio base station 300 forms part of the cdma2000 network 30. The LTE network 20 includes an MME (Mobility Management Entity) 25 that is a management device that manages the mobility of the wireless terminal 100.

  The wireless terminal 100 is connected to the wireless base station 200 (hereinafter “active mode”). Specifically, the radio terminal 100 is connected to the radio base station 200 and communicates with a communication destination device (for example, a server or a communication terminal) via the radio base station 200. The radio terminal 100 is located within the communicable area of the radio base station 200 and is located within the communicable area of the radio base station 300.

The OFDM system is a system in which data is distributed to a plurality of subcarriers orthogonal to each other and each subcarrier is modulated. On the transmission side, each subcarrier is subjected to multiphase PSK modulation or multilevel QAM modulation, and then each subcarrier is subjected to inverse fast Fourier transform (IFFT) to generate an OFDM signal. The receiving side performs demodulation by performing a fast Fourier transform (FFT) on the OFDM signal.

  When wireless communication is performed in an environment where the wireless terminal 100 and the wireless base station 200 cannot be directly seen, the antenna 101 (see FIG. 4) of the wireless terminal 100 has a plurality of different paths as shown in FIG. Receive radio waves (multipath waves). In the example of FIG. 2A, a path P1 directly reaching the antenna 101 of the wireless terminal 100 between the antenna 201 (see FIG. 5) of the wireless base station 200 and the antenna 101 of the wireless terminal 100, and a building or ground Routes P2 and P3 reaching the antenna 101 of the wireless terminal 100 after reflection by the above are formed.

  The radio wave received by the antenna 101 of the wireless terminal 100 via the path P1 is a preceding wave (direct wave). The radio wave received by the antenna 101 of the wireless terminal 100 via the paths P2 and P3 is a delayed wave delayed from the preceding wave.

  As shown in FIG. 2B, the radio waves of each path have different delay times. In the example of FIG. 2B, the antenna 101 of the wireless terminal 100 receives the radio wave (direct wave) of the path P1 with the delay time τ1, receives the radio wave (reflected wave) of the path P2 with the delay time τ2, and The radio wave (reflected wave) of P3 is received with a delay time τ3. The antenna 101 of the wireless terminal 100 receives these radio waves as a synthesized wave.

  In the OFDM scheme, in order to absorb such a delay time difference caused by multipath, the transmission side adds a redundant signal section called a guard interval to each symbol.

  FIG. 3A is a diagram illustrating a symbol configuration in the OFDM scheme. As shown in FIG. 3 (a), symbols in the OFDM scheme (hereinafter referred to as OFDM symbols) are a guard symbol obtained by copying a finite time effective symbol section generated by IFFT and a part of the effective symbol section. It consists of an interval.

  By using the guard interval, as shown in FIG. 3B, the time difference (hereinafter referred to as “delay time difference”) Tdmax between the time when the preceding wave is received and the time when the latest delayed wave is received is When it falls within the guard interval Tg, the FFT on the receiving side functions normally, and the occurrence of intersymbol interference can be avoided.

  On the other hand, when a delayed wave exceeding the guard interval length Tg occurs, intersymbol interference occurs, the FFT on the receiving side does not function normally, and a large distortion occurs, resulting in a decrease in communication performance. Therefore, when it is estimated that the inter-code interference occurs in the radio terminal 100, the radio base station 200 according to the present embodiment performs a handover from the radio base station 200 to the radio base station 300 to the radio terminal 100. Let it run.

(2) Configuration of Radio Terminal FIG. 4 is a block diagram showing the configuration of the radio terminal 100.

  As illustrated in FIG. 4, the wireless terminal 100 includes an antenna 101, a modulation unit 121, a transmission unit 122 (terminal side transmission unit), a duplexer 123, a reception unit 124 (terminal side reception unit), a demodulation unit 125, and an OFDM measurement unit 141. (First measurement unit), CDMA measurement unit 142 (second measurement unit), control unit 160, and storage unit 180. The transmission unit 122 includes a switch SW1, a CDMA transmission unit 122A, and an OFDM transmission unit 122B. The receiving unit 124 includes a switch SW2, a CDMA receiving unit 124A, and an OFDM receiving unit 124B.

  The modulation unit 121 modulates and encodes transmission data from the control unit 160. The modulation unit 121 has a configuration corresponding to adaptive modulation. In adaptive modulation, a plurality of modulation schemes are determined in advance depending on the combination of the modulation level and the coding rate. The modulation scheme is also referred to as a modulation class or MCS (Modulation and Coding Scheme) level. The modulation unit 121 modulates and encodes transmission data using any one of a plurality of modulation schemes.

  The switch SW1 inputs the transmission data output from the modulation unit 121 to either the CDMA transmission unit 122A or the OFDM transmission unit 122B according to control by the control unit 160. The switch SW1 inputs transmission data to the CDMA transmission unit 122A when the communication method used is the CDMA method, and inputs transmission data to the OFDM transmission unit 122B when the communication method used is the OFDM method.

  The CDMA transmitter 122A spreads the input transmission data in accordance with the CDMA system and generates a CDMA signal in the radio frequency band by performing conversion to the radio frequency band and amplification processing. The generated CDMA signal is transmitted via the duplexer 123 and the antenna 101.

  The OFDM transmitter 122B multi-carrier-modulates the input transmission data according to the OFDM scheme, and generates a radio frequency band OFDM signal by performing conversion to the radio frequency band and amplification processing. The generated OFDM signal is transmitted via the duplexer 123 and the antenna 101.

  The duplexer 123 inputs a radio signal (CDMA signal or OFDM signal) to the antenna 101. On the other hand, at the time of reception, the duplexer 123 inputs the radio signal (CDMA signal or OFDM signal) received by the antenna 101 to the switch SW2.

  The switch SW2 inputs the radio signal from the duplexer 123 to either the CDMA receiving unit 124A or the OFDM receiving unit 124B under the control of the control unit 160. The switch SW2 inputs the radio signal from the duplexer 123 to the CDMA receiving unit 124A when the communication system used is the CDMA system, and the radio signal from the duplexer 123 when the communication system used is the OFDM system. Input to the OFDM receiver 124B.

  The CDMA receiving unit 124A performs conversion to the baseband and amplification processing on the input radio signal (CDMA signal) and despreading according to the CDMA method. The CDMA receiving unit 124A performs RAKE reception, which is a process for combining the preceding wave and the delayed wave included in the received CDMA signal. In RAKE reception, reception quality is improved by combining the preceding wave and the delayed wave with the same phase. The reception data obtained in this way is input to the demodulation unit 125.

  The OFDM receiving unit 124B performs conversion to baseband and amplification processing on the input radio signal (OFDM signal) and multicarrier demodulation according to the OFDM scheme. In addition, the OFDM receiver 124B removes the guard interval included in the received OFDM signal. Received data obtained as a result is input to demodulation section 125.

  The demodulator 125 demodulates and decodes the input received data. The demodulator 125 demodulates and decodes the received data by a method corresponding to any one of a plurality of modulation schemes. Further, the demodulation unit 125 performs symbol determination on the input received data.

  The OFDM measurement unit 141 measures a reception parameter indicating a time difference between the preceding wave and the delayed wave of the received OFDM signal. In this embodiment, as shown in FIG. 6A, the reception parameter refers to an amplitude error (amplitude error) and a phase error (amplitude error) between the OFDM symbol S included in the received OFDM signal and the reference point Sref of the OFDM symbol. Phase error). The greater the degree that the delay time difference Tdmax exceeds the guard interval Tg, the greater the value of the reception parameter (amplitude error and phase error). The reception parameter measured by the OFDM measurement unit 141 is input to the control unit 160.

  The CDMA measurement unit 142 measures the reception quality of the CDMA signal. In the present embodiment, reception field strength (RSSI) is used as the reception quality of the CDMA signal, but is not limited to RSSI, and may be reception SNR (Signal to Noise ratio) or the like. The RSSI measured by the CDMA measurement unit 142 is input to the control unit 160.

  The control unit 160 is configured using a CPU, for example, and controls various functions provided in the wireless terminal 100. The storage unit 180 is configured using, for example, a memory, and stores various types of information used for control in the control unit 160.

  The control unit 160 controls the switches SW1 and SW2. The controller 160 switches the switches SW1 and SW2 when switching the used communication method between the OFDM method and the CDMA method, and temporarily switches the switches SW1 and SW2 when measuring the RSSI of the CDMA signal during OFDM communication. It may be switched.

  The control unit 160 inputs the reception parameter measured by the OFDM measurement unit 141 and the RSSI measured by the OFDM measurement unit 141 to the modulation unit 121. The OFDM transmission unit 122B transmits the reception parameter and RSSI after modulation to the radio base station 200. Such a report of measurement results is called “Measurement Report”.

  The control unit 160 operates the OFDM measurement unit 141 and the CDMA measurement unit 142 according to an instruction from the radio base station 200, or executes a handover for switching the connection destination from the radio base station 200 to the radio base station 300. . In addition, the control unit 160 performs control so that the connection destination is switched from the radio base station 300 (CDMA base station) to the radio base station 400 (illustrated in FIG. 10) which is an OFDM base station. Here, the radio base station 200 indicates a first OFDM base station that has caused intersymbol interference. Radio base station 400 indicates a second OFDM base station in which no intersymbol interference occurs.

(3) Configuration of Radio Base Station FIG. 5 is a block diagram showing the configuration of the radio base station 200.

  As shown in FIG. 5, the radio base station 200 includes an antenna 201, a modulation unit 221, a transmission unit 222 (base station side transmission unit), a duplexer 223, a reception unit 224 (base station side reception unit), a demodulation unit 225, a control unit. Unit 240, storage unit 260, and wired communication unit 280.

  The modulation unit 221 modulates and encodes transmission data from the control unit 240. The modulation unit 221 modulates and encodes transmission data using any one of a plurality of modulation schemes according to adaptive modulation.

  The transmitter 222 multi-carrier-modulates the input transmission data according to the OFDM scheme, and generates a radio frequency band OFDM signal by performing conversion to a radio frequency band and amplification processing. The generated OFDM signal is transmitted via the duplexer 223 and the antenna 201.

  The duplexer 223 inputs the OFDM signal to the antenna 201. On the other hand, at the time of reception, the duplexer 223 inputs the OFDM signal received by the antenna 201 to the reception unit 224.

  The receiving unit 224 performs conversion to baseband and amplification processing on the input OFDM signal, and multicarrier demodulation according to the OFDM scheme. In addition, the reception unit 224 removes the guard interval included in the OFDM signal. The reception data obtained in this way is input to the demodulation unit 225.

  The demodulator 225 demodulates and decodes the input received data. The demodulator 225 demodulates and decodes the received data by a method corresponding to any one of a plurality of modulation schemes. The demodulator 225 performs symbol determination on the input received data.

  The control unit 240 is configured using, for example, a CPU, and controls various functions provided in the radio base station 200. The storage unit 260 is configured using a memory, for example, and stores various types of information used for control in the control unit 240. The wired communication unit 280 performs communication with the LTE network 20 side.

  The control unit 240 transmits an RSSI measurement instruction of the CDMA signal to the wireless terminal 100 using the transmission unit 222. In the present embodiment, the transmission unit 222 transmits the measurement instruction periodically or when a predetermined trigger occurs.

  The storage unit 260 stores in advance a neighbor list that is information on radio base stations (hereinafter referred to as “peripheral base stations”) located around the radio base station 200. In the present embodiment, the neighbor list includes the ID of a radio base station (radio base station 300 or the like) compatible with the CDMA system, used channel information, and the like. The control unit 240 includes the neighbor list in the measurement instruction and causes the transmission unit 222 to transmit the neighbor list.

  The control unit 240 acquires the reception parameters and RSSI transmitted by the wireless terminal 100 in response to the measurement instruction via the reception unit 224 and the demodulation unit 225. The control unit 240 determines whether to cause the radio terminal 100 to perform a handover based on the reception parameter and RSSI.

  Specifically, the control unit 240 calculates an EVM (Error Vector Magnitude) from the reception parameter, and compares the calculated EVM with an EVM threshold. The EVM threshold is determined based on a guard interval used in the OFDM method and is stored in advance in the storage unit 260.

  The EVM threshold is set in advance to a value of EVM when the delay time difference Tdmax exceeds the guard interval length Tg. The value of EVM when the delay time difference Tdmax exceeds the guard interval length Tg can be obtained experimentally or empirically.

  In the present embodiment, the EVM threshold value is provided for each modulation method used in adaptive modulation. EVM is also called modulation accuracy. As shown in FIG. 6 (a), an error vector based on the amount of phase / amplitude deviation (reception parameter) of the observed symbol point S from the symbol reference point Sref that should be the original. , Which is expressed as a percentage of the square root of the average power of the ideal signal. FIG. 6C shows an EVM calculation formula.

  As shown in FIG. 6B, the storage unit 260 stores a table in which modulation schemes are associated with EVM threshold values. As the modulation method is capable of high-speed communication (the modulation method having a larger number of bits per symbol), the restrictions on the phase / amplitude error become more severe. For this reason, the EVM threshold is set lower as the modulation method enables higher-speed communication.

  The control unit 240 acquires the EVM threshold value from the storage unit 260 based on the modulation scheme applied in the downlink, and compares it with the calculated EVM.

  Further, the control unit 240 compares the RSSI of the CDMA signal with a predetermined value. When the RSSI is higher than a predetermined value, it can be considered that the reception quality is good. The predetermined value is set in advance to an RSSI value at which the wireless terminal 100 can execute communication.

  When the calculated EVM exceeds the EVM threshold value and the RSSI is higher than the predetermined value, the control unit 240 of the radio base station 200 can control the radio base station (radio base station 300, etc.) that supports the CDMA system. It is determined to cause the radio terminal 100 to execute a handover to. When causing the radio terminal 100 to perform handover, the control unit 240 transmits a handover instruction to the radio terminal 100 using the transmission unit 222 after confirming whether the handover is successful.

(4) Operation of Radio Communication System Next, the operation of the radio communication system 10 will be described using (4.1) operation pattern 1 and (4.2) operation pattern 2 as examples. In the present embodiment, the operation of the wireless communication system 10 is based on a standard such as 3GPPTS36.300. The operation pattern 1 is an operation pattern that causes the wireless terminal 100 to periodically measure the RSSI of the CDMA signal. The operation pattern 2 is an operation pattern in which the radio terminal 100 measures the RSSI of the CDMA signal using a predetermined event as a trigger.

(4.1) Operation pattern 1
FIG. 7 is a sequence diagram showing an operation pattern 1 of the wireless communication system 10. This sequence is executed when the wireless terminal 100 is in the active mode.

  In step S <b> 101, the transmission unit 222 of the radio base station 200 transmits a measurement instruction to the radio terminal 100. The measurement instruction includes the above-described neighbor list. The OFDM receiving unit 124B of the wireless terminal 100 receives the measurement instruction.

  In step S102, the control unit 160 of the wireless terminal 100 causes the CDMA measurement unit 142 to measure the RSSI of the CDMA signal for each CDMA compatible base station corresponding to the ID included in the neighbor list.

  In step S103, the control unit 160 of the radio terminal 100 causes the OFDM measurement unit 141 to measure the reception parameter of the OFDM signal received from the radio base station 200.

  In step S104, the OFDM transmitter 122B of the radio terminal 100 transmits a measurement result report including the reception parameter measured by the OFDM measurement unit 141 and the RSSI measured by the CDMA measurement unit 142 to the radio base station 200. The receiving unit 224 of the radio base station 200 receives the measurement result report (reception parameters and RSSI).

  In step S105, the control unit 240 of the radio base station 200 calculates an EVM from the reception parameters received by the receiving unit 224 and demodulated by the demodulating unit 225.

  In step S106, the control unit 240 of the radio base station 200 compares the calculated EVM with the EVM threshold corresponding to the modulation scheme. Also, the control unit 240 of the radio base station 200 compares the RSSI received by the receiving unit 224 and demodulated by the demodulating unit 225 with a predetermined value.

  When the calculated EVM exceeds the EVM threshold and the RSSI is higher than a predetermined value, the control unit 240 of the radio base station 200 determines to cause the radio terminal 100 to execute a handover to the CDMA-compatible radio base station. (Step S107). On the other hand, when the calculated EVM is less than the EVM threshold or when the RSSI is equal to or less than a predetermined value, the control unit 240 of the radio base station 200 performs a handover to the radio base station compatible with CDMA to the radio terminal 100. Decide not to execute.

  When the calculated EVM exceeds the EVM threshold and there are a plurality of CDMA-compatible wireless base stations whose RSSI is higher than a predetermined value, the control unit 240 of the wireless base station 200 supports the CDMA with the highest RSSI. It is preferable to determine the wireless base station as a handover destination. Hereinafter, a case where the radio terminal 100 is caused to perform a handover to the radio base station 300 will be described.

  In step S108, the transmission unit 222 of the radio base station 200 transmits a handover preparation instruction to the radio terminal 100. The OFDM receiver 124B of the wireless terminal 100 receives the handover preparation instruction.

  In step S109, the OFDM transmitter 122B of the wireless terminal 100 transmits a connection request to the wireless base station 300 to the wireless base station 200. The connection request is transferred to the radio base station 300 by tunneling under the management of the MME 25 (step S110). If the connection request is successful, the MME 25 notifies the radio base station 200 to that effect (step S111).

  In step S112, the radio base station 200 transmits a handover instruction to the radio base station 300 to the radio terminal 100 in response to the notification from the MME 25. When receiving the instruction for handover to the radio base station 300, the radio terminal 100 executes handover to the radio base station 300.

(4.2) Operation pattern 2
FIG. 8 is a sequence diagram showing an operation pattern 2 of the wireless communication system 10. This sequence is executed when the wireless terminal 100 is in the active mode.

  In step S <b> 201, the control unit 160 of the radio terminal 100 causes the OFDM measurement unit 141 to measure the reception parameter of the OFDM signal received from the radio base station 200.

  In step S202, the OFDM transmission unit 122B of the wireless terminal 100 transmits the reception parameter measured by the OFDM measurement unit 141 to the wireless base station 200. The receiving unit 224 of the radio base station 200 receives reception parameters.

  In step S203, the control unit 240 of the radio base station 200 calculates an EVM from the reception parameters received by the receiving unit 224 and demodulated by the demodulating unit 225.

  In step S204, the control unit 240 of the radio base station 200 compares the calculated EVM with an EVM threshold corresponding to the modulation scheme.

  If the calculated EVM exceeds the EVM threshold, the transmitter 222 of the radio base station 200 transmits an RSSI measurement instruction to the radio terminal 100 in step S205. The measurement instruction includes the above-described neighbor list. The OFDM receiving unit 124B of the wireless terminal 100 receives the measurement instruction.

  In step S206, the control unit 160 of the wireless terminal 100 causes the CDMA measurement unit 142 to measure the RSSI of the CDMA signal for each CDMA compatible base station corresponding to the ID included in the neighbor list.

  In step S207, the OFDM transmitter 122B of the radio terminal 100 transmits a measurement result report including the RSSI measured by the CDMA measurement unit 142 to the radio base station 200. The receiving unit 224 of the radio base station 200 receives a measurement result report (RSSI).

  In step S208, the control unit 240 of the radio base station 200 compares the RSSI received by the receiving unit 224 and demodulated by the demodulating unit 225 with a predetermined value.

  When the RSSI is higher than the predetermined value, the control unit 240 of the radio base station 200 determines to cause the radio terminal 100 to execute a handover to the CDMA compatible radio base station (step S209). On the other hand, when the RSSI is equal to or less than the predetermined value, the control unit 240 of the radio base station 200 determines that the radio terminal 100 does not execute a handover to the CDMA compatible radio base station. Note that when there are a plurality of CDMA-compatible radio base stations whose RSSI is higher than a predetermined value, the control unit 240 of the radio base station 200 preferably determines the CDMA-compatible radio base station having the highest RSSI as a handover destination. .

  Each process of steps S210 to S214 is performed in the same manner as operation pattern 1.

(4.3) Operation pattern 3
In this pattern, after the control unit 160 of the radio terminal 100 switches from the connection of the radio base station 200 (OFDM radio base station) to the connection of the radio base station 300 (CDMA radio base station) based on the data transmission capability, When it is determined that the radio terminal 100 has moved to an area (desired area) where data transmission capability is predicted to be higher when communicating with an OFDM base station than when communicating with a CDMA radio base station, the radio base station 400 (FIG. 10). (OFDM radio base station) is switched to the connection.

  FIG. 10 is a sequence diagram showing an operation pattern 3 of the wireless communication system 10. This sequence is executed when the wireless terminal 100 is in the active mode.

  In step S301, the radio base station 300 transmits a measurement instruction to the radio terminal 100. The measurement instruction includes the above-described neighbor list. The CDMA receiver 124A of the wireless terminal 100 receives the measurement instruction.

  In step S302, the control unit 160 of the wireless terminal 100 causes the CDMA measurement unit 142 to measure the RSSI of the CDMA signal for each CDMA compatible base station corresponding to the ID included in the neighbor list.

  In step S303, the control unit 160 of the wireless terminal 100 causes the OFDM measurement unit 141 to measure the RSSI of the OFDM signal received from the wireless base station 200.

  In step S304, the control unit 160 determines the current reception strength (the radio wave in the RSSI of the CDMA signal measured by the CDMA measurement unit 142) rather than the reception strength when switching to the connection of the radio base station 300 (CDMA radio base station). When the RSSI of the base station 300 becomes small, it is determined that the wireless terminal 100 has moved. The fact that the current reception strength is reduced means that the wireless terminal 100 can be estimated to have moved away from the wireless base station 300, and the data transmission capability is higher when communicating with an OFDM base station than when communicating with a CDMA wireless base station. It is predicted that the wireless terminal 100 has moved.

  In step S305, the control unit 160 transmits a measurement result report including the RSSI of the OFDM signal measured by the OFDM measurement unit 141 and the RSSI of the CDMA signal measured by the CDMA measurement unit 142 to the radio base station 300. When it is determined that the wireless terminal 100 has moved, the control unit 160 sets that the wireless terminal 100 has moved in the measurement result report.

  In step S306, the radio base station 300 receives the measurement result report, and compares the RSSI of the OFDM signal with the RSSI of the CDMA signal.

  In step S307, when the highest RSSI of the OFDM signal is larger than the highest RSSI of the CDMA signal, and the radio base station 300 is set to have moved to the measurement result report, the radio base station 300 The station 300 determines to cause the radio terminal 100 to execute handover to the radio base station 400 that supports OFDM.

  In step S308, the radio base station 300 transmits a handover preparation instruction to the radio terminal 100. The CDMA receiver 124A of the wireless terminal 100 receives the handover preparation instruction.

  In step S <b> 309, the CDMA receiving unit 124 </ b> A of the wireless terminal 100 transmits a connection request to the wireless base station 400 to the wireless base station 300. The connection request is transferred to the radio base station 400 by tunneling via the SGSN / MME 25 (step S310). If the connection request is successful, the fact is notified to the radio base station 300 via the SGSN / MME 25 (step S311).

  In step S312, the radio base station 300 transmits a handover instruction to the radio base station 400 to the radio terminal 100 in response to the notification from the MME 25. When receiving the instruction for handover to the radio base station 400, the radio terminal 100 executes the handover to the radio base station 400.

  In the operation pattern 3, when the current reception strength is lower than the reception strength when the control unit 160 of the wireless terminal 100 switches to the connection of the wireless base station 300 (CDMA wireless base station), the wireless terminal 100 moves. However, instead of this, the control unit 160 acquires the current communication area from the radio base station 300 (CDMA radio base station), and identifies the communication area when switching to the radio base station 300. And the acquired identification information of the current communication area may not match, it may be determined that the wireless terminal 100 has moved. The communication area identification information may identify the location registration area. When GPS is implemented in the wireless terminal 100, the identification information of the communication area may be the position information of the own wireless terminal acquired by GPS.

  In the operation pattern 3, the handover to the radio base station 400 is executed. However, depending on the signal strength of the OFDM signal, the handover to the radio base station 200 may be performed again. .

  In operation pattern 3, when the radio terminal 100 switches from the OFDM scheme to the CDMA scheme due to intersymbol interference, the radio terminal 100 determines that the radio terminal has moved. Since no scheme is used, when switching from the CDMA scheme to the OFDM scheme again, a decrease in communication performance due to intersymbol interference is avoided.

(5) Effects of Embodiment According to the present embodiment, the control unit 240 of the radio base station 200 performs handover to the radio base station 300 when the EVM exceeds the EVM threshold and the RSSI is higher than a predetermined value. Is determined to be executed by the wireless terminal 100. Here, EVM reflects the delay time difference Tdmax between the preceding wave and the delayed wave of the OFDM signal, the EVM threshold is set to the value of EVM when the delay time difference Tdmax exceeds the guard interval length Tg, and EVM is EVM. Exceeding the threshold means that the delay time difference Tdmax has exceeded the guard interval length Tg.

  Therefore, in a situation where the delay time difference Tdmax is estimated to exceed the guard interval length Tg, after confirming that the reception level of the CDMA signal is good, the handover to the radio base station 300 corresponding to the CDMA scheme is performed by the radio terminal By causing the control unit 100 to execute the operation, intersymbol interference can be avoided, and deterioration in communication performance can be avoided. Further, until it is estimated that the delay time difference Tdmax exceeds the guard interval length Tg, the excellent communication performance of the OFDM method can be utilized.

  Therefore, the radio terminal 100 that supports both the CDMA scheme and the OFDM scheme avoids a decrease in communication performance due to intersymbol interference while utilizing the OFDM scheme in the active mode.

  Furthermore, since the CDMA receiving unit 124A of the wireless terminal 100 can perform RAKE reception that combines the preceding wave and the delayed wave included in the CDMA signal, it is highly resistant to a multipath environment and has a path diversity effect due to RAKE reception. Is obtained. Therefore, by switching the communication system used from the OFDM system to the CDMA system, it is possible to effectively suppress the degradation of communication performance by utilizing the characteristics of the CDMA system.

  Also, EVM (and reception parameters) can be measured with a small amount of calculation compared to other reception quality indicators such as SNR (Signal to Noise ratio), BER (Bit Error Rate), or channel estimation value, and It has a feature that the time required for measurement is short. For this reason, by using the EVM, it is possible to easily and immediately estimate whether or not the delay time difference Tdmax exceeds the guard interval length Tg. Therefore, the processing load and power consumption of the radio terminal 100 can be reduced and the period during which the communication performance is deteriorated due to intersymbol interference can be reduced as compared with the case where other reception quality indicators are used.

  In the present embodiment, the control unit 240 sets the EVM threshold corresponding to the modulation scheme applied to the downlink wireless communication, and thus can appropriately set the EVM threshold even when adaptive modulation is used. Become.

  When the radio base station and the radio terminal constituting the radio communication system according to the present embodiment switch from the OFDM scheme to the CDMA scheme due to intersymbol interference, the radio base station and the radio terminal determine that the radio terminal has moved, thereby switching to the CDMA scheme. Since the OFDM scheme is not performed in the same location as the location of, when switching from the CDMA scheme to the OFDM scheme again, a decrease in communication performance due to intersymbol interference is avoided.

(6) Other Embodiments As described above, the present invention has been described according to the embodiment. However, it should not be understood that the description and drawings constituting a part of this disclosure limit the present invention. From this disclosure, various alternative embodiments, examples and operational techniques will be apparent to those skilled in the art.

  For example, the reception parameter of the OFDM signal may be measured only when the voltage waveform state of the received OFDM signal satisfies a specific condition. FIG. 9 shows a waveform measurement process by the OFDM measurement unit 141. In the example of FIG. 9, the delay time difference is τ as shown in FIG. 9A, and the preceding wave shown in FIG. 9B and the delayed wave shown in FIG. The OFDM signal shown in d) is received. For example, the OFDM measurement unit 141 specifies the guard interval period of the preceding wave according to the symbol synchronization result, and measures the voltage waveform state (voltage value) of the OFDM signal at the measurement timing corresponding to the guard interval period. . The measurement is performed at each measurement timing corresponding to each guard interval period. The OFDM measurement unit 141 measures the voltage waveform state measured at the current measurement timing T (n) at a measurement timing T (n−1) before the current measurement timing (hereinafter referred to as “previous measurement timing”). It is determined whether or not the voltage waveform is equal. When the voltage waveform state measured at the current measurement timing T (n) is equal to the voltage waveform state measured at the previous measurement timing T (n−1), the OFDM measurement unit 141 omits the measurement of the reception parameter. When the state of the voltage waveform measured at the current measurement timing T (n) is different from the state of the voltage waveform measured at the previous measurement timing T (n−1), the reception parameter is measured. In the case where the determination is performed using only the EVM, an erroneous determination may be made if the EVM changes due to a factor (for example, a circuit factor) other than the change in the multipath state. Therefore, the current measurement timing T (n The measurement accuracy can be improved by measuring the EVM only when the state of the voltage waveform measured in (1) is different from the state of the voltage waveform measured at the previous measurement timing T (n-1).

In the above-described embodiment, an example in which the CDMA communication unit (CDMA transmission unit 122A and CDMA reception unit 124A) and the OFDM communication unit (OFDM transmission unit 122B and OFDM reception unit 124B) are individually provided has been described. However, the CDMA communication unit and the OFDM communication unit may be configured as one communication unit. For example, in a wireless terminal called a cognitive terminal, the communication method can be switched in software by downloading software (SDR BB, Tunable RF) corresponding to the communication method to be used.

  In the embodiment described above, the reception parameters measured by the radio terminal 100 are the amplitude error and the phase error, and the EVM is calculated in the radio base station 200. However, the radio terminal 100 may calculate an EVM from the amplitude error and the phase error and transmit the EVM to the radio base station 200 as a reception parameter. In this case, the “value corresponding to the reception parameter” is an EVM value. In addition, not only when EVM is used, another reception quality index (for example, SNR, BER, or channel estimation value) may be used.

  In the above-described embodiment, a mobile phone terminal is exemplified as the wireless terminal 100. However, the wireless terminal 100 is not limited to a mobile phone terminal, and may be a terminal mounted with a communication device of a CDMA system and an OFDM system.

  In the embodiment described above, the case where the guard interval length is a fixed length has been described as an example, but the guard interval length may be a variable length. For example, when two types of guard intervals, a short guard interval and a long guard interval longer than the short guard interval, are selectively used, the reception parameter (or EVM) is set at the long guard interval from the viewpoint of securing the measurement time. It is preferable to measure.

  In the embodiment described above, LTE has been described as an example of a wireless communication system using the OFDM method. However, not only LTE but also WiMAX standardized in IEEE 802.16 or next generation PHS (XGP) is used. Good.

  Thus, it should be understood that the present invention includes various embodiments and the like not described herein. Therefore, the present invention is limited only by the invention specifying matters in the scope of claims reasonable from this disclosure.

DESCRIPTION OF SYMBOLS 20 ... LTE network, 25 ... MME, 30 ... cdma2000 network, 10 ... Wireless communication system, 100 ... Wireless terminal, 101 ... Antenna, 121 ... Modulator, 122 ... Transmitter, 122A ... CDMA transmitter, 122B ... OFDM transmitter , 123... Duplexer, 124... Receiving unit, 124 A... CDMA receiving unit, 124 B... OFDM receiving unit, 125... Demodulating unit, 141... OFDM measuring unit, 142. DESCRIPTION OF SYMBOLS ... Wireless base station, 201 ... Antenna, 221 ... Modulation part, 222 ... Transmission part, 223 ... Duplexer, 224 ... Reception part, 225 ... Demodulation part, 240 ... Control part, 260 ... Memory | storage part, 280 ... Wired communication part, 300 ... Radio base station, SW1, SW2 ... Switch

Claims (3)

A wireless terminal capable of communicating with an OFDM radio base station compatible with the OFDM scheme and capable of communicating with a CDMA radio base station compatible with the CDMA scheme,
After switching from the connection of the OFDM radio base station causing intersymbol interference to the connection of the CDMA radio base station, if it is determined that the own radio terminal has moved, control is performed to switch to the connection of the OFDM radio base station A control unit ;
A CDMA measurement unit that measures reception intensity when receiving a signal transmitted from the CDMA radio base station ,
Wherein, the CDMA if the reception intensity of the current than the reception intensity when switching the connection of the radio base station is smaller, no-line terminal it determined that the own wireless terminal has moved.   The control unit acquires the current communication area from the CDMA radio base station, and when the identification information of the communication area when the connection to the CDMA radio base station is switched does not match the identification information of the current communication area The wireless terminal according to claim 1, wherein the wireless terminal determines that the wireless terminal has moved. The wireless terminal according to claim 2 , wherein the identification information of the communication area is a position of the wireless terminal of the communication area.

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