JP2010258596A - Radio communication equipment, radio repeater, and radio communication system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide radio communication equipment connecting seamlessly to a radio communication network of a different radio communication standard. <P>SOLUTION: The radio communication equipment has: a physical layer portion (203); a first RF portion (202); a second RF portion (205); a first antenna (201); and a second antenna (204). The physical layer portion (203) generates a transmission signal based on a transmission packet. The first RF portion (202) converts the transmission signal generated by the physical layer portion (203) from base band frequencies into RF frequencies, in conformity with a first radio communication standard. The second RF portion (205) converts the transmission signal generated by the physical layer portion (203) from base band frequencies into RF frequencies, in conformity with a second radio communication standard having a communication range different from the first radio communication standard. The first antenna (201) transmits wirelessly the transmission signal converted by the first RF portion (202). The second antenna (204) transmits wirelessly the transmission signal converted by the second RF portion (205). <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a wireless communication device, a wireless relay device, and a wireless communication system.

  Japanese Patent Laid-Open No. 2008-271140 discloses a communication system that allows a terminal to select the same GGSN when executing a handover in order to implement a handover that takes over a session between a mobile communication network and a wireless LAN. It is disclosed.

  Japanese Patent Laid-Open No. 2004-56515 discloses information on communication terminal devices used in a certain network system among other network systems, while communicating with a plurality of different network systems. A communication terminal device relaying to a network system is disclosed.

JP 2008-271140 A JP 2004-56515 A

  An object of the present invention is to provide a wireless communication device, a wireless relay device, and a wireless communication system that can seamlessly connect wireless communication networks of different wireless communication standards.

  The wireless communication device includes: a physical layer unit that generates a transmission signal based on a transmission packet; and a transmission unit that converts the transmission signal generated by the physical layer unit according to a first wireless communication standard from a baseband frequency to an RF frequency. A second RF unit that converts a transmission signal generated by the physical layer unit from a baseband frequency to an RF frequency in accordance with a second wireless communication standard having a communication range different from that of the first RF communication standard and the first wireless communication standard RF unit, a first antenna that wirelessly transmits the transmission signal converted by the first RF unit, and a second antenna that wirelessly transmits the transmission signal converted by the second RF unit. The first antenna receives a radio signal having a frequency of the first radio communication standard, the second antenna receives a radio signal having a frequency of the second radio communication standard, and the second antenna 1 RF part is the front A signal received via the first antenna in accordance with a first wireless communication standard is converted from an RF frequency to a baseband frequency, and the second RF unit is in accordance with the second wireless communication standard. A signal received via the second antenna is converted from an RF frequency to a baseband frequency, and the physical layer unit receives the signal based on the received signal converted by the first RF unit or the second RF unit. It is characterized by generating a packet.

  The wireless relay device receives from the RF frequency a first antenna that receives a wireless signal having a frequency of the first wireless communication standard, and a signal received through the first antenna in accordance with the first wireless communication standard. The first RF unit that converts to a baseband frequency, the physical layer unit that performs synchronization processing on the received signal converted by the first RF unit, and the first wireless communication standard have different communication ranges. A second RF unit for converting a signal based on the received signal converted by the first RF unit in accordance with a second wireless communication standard from a baseband frequency to an RF frequency, and a signal converted by the second RF unit. A second antenna for wirelessly transmitting the received signal, wherein the second antenna receives a radio signal having a frequency of the second wireless communication standard, and the second RF unit includes the second antenna. In accordance with the wireless communication standards of A signal received via the second antenna is converted from an RF frequency to a baseband frequency, and the first RF unit receives the received signal converted by the second RF unit in accordance with the first wireless communication standard. Is converted from a baseband frequency to an RF frequency, and the first antenna wirelessly transmits the reception signal converted by the first RF unit.

  The wireless communication networks of the first wireless communication standard and the second wireless communication standard can be seamlessly connected.

1 is a block diagram illustrating a configuration example of a wireless communication system according to a first embodiment of the present invention. It is a block diagram which shows the structural example of the portable terminal of FIG. It is a block diagram which shows the structural example of the radio | wireless communications system by the 2nd Embodiment of this invention. It is a block diagram which shows the structural example of the portable terminal of FIG. It is a block diagram which shows the structural example of the portable terminal by the 3rd Embodiment of this invention. It is a block diagram which shows the structural example of the portable terminal by the 4th Embodiment of this invention. It is a block diagram which shows the structural example of the RF part of WiMAX and the RF part of WLAN in the portable terminal by the 5th Embodiment of this invention.

(First embodiment)
FIG. 1 is a block diagram showing a configuration example of a radio communication system according to the first embodiment of the present invention. The wireless communication system includes a mobile terminal 101, a wireless relay device 102, and a base station 103. The wireless relay device 102 is placed in the building 104. The base station 103 is a base station of a wireless communication standard of WiMAX (Worldwide Interoperability for Microwave Access). WiMAX is a first wireless communication standard created mainly for outdoor use. WLAN (Wireless Local Area Network) is a second wireless communication standard made mainly for indoor use. WiMAX and WLAN have different communication ranges, WiMAX has a wide communication range, and WLAN has a narrow communication range. The portable terminal 101 is a movable wireless communication device. When outdoors, the mobile terminal 101 can communicate with the base station 103 via a WiMAX wireless communication network. However, since WiMAX is a wireless communication standard for outdoor use, the portable terminal 101 cannot directly perform wireless communication with the base station 103 through the WiMAX wireless communication network indoors in the building 104. Therefore, the wireless relay device 102 is provided in the building 104. The portable terminal 101 performs wireless communication with the base station 103 via the wireless relay device 102 indoors in the building 104.

  The mobile terminal 101 is a movable wireless communication apparatus that can perform both WiMAX and WLAN wireless communication. As described above, the mobile terminal 101 performs wireless communication with the base station 103 via the WiMAX wireless communication network outdoors. On the other hand, the portable terminal 101 performs wireless communication with the base station 103 via the wireless relay device 102 indoors in the building 104. Specifically, the mobile terminal 101 performs wireless communication with the wireless relay apparatus 102 through a WLAN wireless communication network. The base station 103 performs wireless communication with the wireless relay apparatus 102 through a WiMAX wireless communication network.

  The wireless relay device 102 includes a first antenna 110, a WiMAX RF (Radio Frequency) unit 111, a WiMAX physical layer unit 112, a WLAN physical layer unit 114, a WLAN RF unit 115, and a second antenna 116. Have.

  First, a case where the mobile terminal 101 receives a signal from the base station 103 via the wireless relay device 102 will be described. The first antenna 110 receives a wireless signal S 1 having a WiMAX frequency (for example, 2.5 GHz) from the base station 103. The WiMAX RF unit 111 converts the signal S1 received via the first antenna 110 from the RF frequency to the baseband frequency in accordance with the WIMAX wireless communication standard, and outputs the signal S2. The WiMAX physical layer unit 112 generates an IP (Internet Protocol) packet 113 based on the signal S2 converted by the WiMAX RF unit 111 in accordance with the WiMAX wireless communication standard. Also, the WiMAX physical layer unit 112 performs a synchronization process on the reception signal converted by the WiMAX RF unit 111. The IP packet S3 is an IP packet output from the WiMAX physical layer unit 112. The IP packet S4 is an IP packet input by the physical layer unit 114 of the WLAN. The IP packets S3 and S4 are the same as the IP packet 113. The WLAN physical layer unit 114 generates the transmission signal S5 based on the IP packet 113 generated by the WiMAX physical layer unit 112. The WLAN RF unit 115 converts the transmission signal S5 generated by the WLAN physical layer unit 114 from a baseband frequency to an RF frequency in accordance with the WLAN wireless communication standard, and outputs a signal S6. The second antenna 116 wirelessly transmits to the mobile terminal 101 a signal S6 having a WLAN frequency (for example, 2.4 GHz) converted by the RF unit 115 of the WLAN.

  Next, a case where the mobile terminal 101 transmits a signal to the base station 103 via the wireless relay device 102 will be described. The second antenna 116 receives a wireless signal S6 having a WLAN frequency from the portable terminal 101. The WLAN RF unit 115 converts the signal S6 received via the second antenna 116 from the RF frequency to the baseband frequency in accordance with the WLAN wireless communication standard, and outputs the signal S5. The WLAN physical layer unit 114 generates an IP packet 113 based on the signal S5 converted by the WLAN RF unit 115 in accordance with the WLAN wireless communication standard. The WiMAX physical layer unit 112 generates a transmission signal S2 based on the IP packet 113 generated by the WLAN physical layer unit 114 in accordance with the WiMAX wireless communication standard. The WiMAX RF unit 111 converts the transmission signal S2 generated by the WiMAX physical layer unit 112 from a baseband frequency to an RF frequency, and outputs a signal S1. The first antenna 110 wirelessly transmits the signal S <b> 1 converted by the WiMAX RF unit 111 to the base station 103.

  FIG. 2 is a block diagram illustrating a configuration example of the mobile terminal 101 in FIG. The mobile terminal 101 includes a first antenna 201, a WiMAX RF unit 202, a WiMAX physical layer unit 203, a second antenna 204, a WLAN RF unit 205, a WLAN physical layer unit 206, and a switch 207.

  First, a case where the portable terminal 101 wirelessly transmits a signal will be described. The IP packet 208 is output to the WiMAX physical layer unit 203 or the WLAN physical layer unit 206 via the switch 207. The switch 207 is connected to the WiMAX physical layer unit 203 when the mobile terminal 101 communicates outdoors, and is connected to the WLAN physical layer unit 206 when the mobile terminal 101 communicates indoors. A specific method for controlling the switch 207 will be described later. The WiMAX physical layer unit 203 generates a transmission signal based on the transmission packet 208 in accordance with the WiMAX wireless communication standard. The WLAN physical layer unit 206 generates a transmission signal based on the transmission packet 208 in accordance with the WLAN wireless communication standard. The WiMAX RF unit 202 converts the transmission signal generated by the WiMAX physical layer unit 203 from a baseband frequency to an RF frequency in accordance with the WiMAX wireless communication standard. The WLAN RF unit 205 converts the transmission signal generated by the WLAN physical layer unit 206 from a baseband frequency to an RF frequency in accordance with the WLAN wireless communication standard. The first antenna 201 wirelessly transmits to the base station 103 a transmission signal having a WiMAX frequency converted by the WiMAX RF unit 202. The second antenna 204 wirelessly transmits the transmission signal of the WLAN frequency converted by the WLAN RF unit 205 to the wireless relay apparatus 102.

  Next, a case where the mobile terminal 101 wirelessly receives a signal will be described. The first antenna 201 receives from the base station 103 a radio signal having a frequency of the WiMAX radio communication standard. The second antenna 204 receives a radio signal having a frequency of the WLAN radio communication standard from the radio relay apparatus 102. The WiMAX RF unit 202 converts a signal received via the first antenna 201 from an RF frequency to a baseband frequency in accordance with the WiMAX wireless communication standard. The WLAN RF unit 205 converts a signal received via the second antenna 204 from an RF frequency to a baseband frequency in accordance with the WLAN wireless communication standard. The WiMAX physical layer unit 203 generates a received IP packet based on the received signal converted by the WiMAX RF unit 202 in accordance with the WiMAX wireless communication standard, and outputs the IP packet 208 via the switch 207. The WLAN physical layer unit 206 generates a received IP packet based on the received signal converted by the WLAN RF unit 205 in accordance with the WLAN wireless communication standard, and outputs the IP packet 208 via the switch 207. Similarly to the above, the switch 207 is connected to the WiMAX physical layer unit 203 when the mobile terminal 101 communicates outdoors, and is connected to the WLAN physical layer unit 206 when the mobile terminal 101 communicates indoors.

  A control example of the switch 207 will be described. One frame has a reception subframe and a transmission subframe, and the periods of the reception subframe and the transmission subframe are defined. In accordance with the regulations, the mobile terminal 101 and the wireless relay device 102 in FIG. 1 perform reception processing and transmission processing.

  The WiMAX physical layer unit 203 generates an IP packet based on a signal received from the first antenna 201 via the WiMAX RF unit 202, and calculates an error rate of the IP packet. At the same time, the WLAN physical layer unit 206 generates an IP packet based on a signal received from the second antenna 204 via the WLAN RF unit 205 and calculates an error rate of the IP packet.

  When the mobile terminal 101 is located outdoors, the mobile terminal 101 can normally receive the WiMAX signal from the base station 103 and cannot normally receive the WLAN signal from the wireless relay apparatus 102. As a result, the error rate calculated by the WiMAX physical layer unit 203 is small, and the error rate calculated by the WLAN physical layer unit 206 is large. Therefore, when the error rate calculated by the WiMAX physical layer unit 203 is smaller than the error rate calculated by the WLAN physical layer unit 206, the switch 207 is connected to the WiMAX physical layer unit 203. Even when the mobile terminal 101 transmits, the state of the switch 207 does not change.

  Further, when the mobile terminal 101 is located indoors, the mobile terminal 101 cannot normally receive the WiMAX signal from the base station 103 and can normally receive the WLAN signal from the wireless relay apparatus 102. As a result, the error rate calculated by the WiMAX physical layer unit 203 is large, and the error rate calculated by the WLAN physical layer unit 206 is small. Therefore, when the error rate calculated by the physical layer unit 206 of the WLAN is smaller than the error rate calculated by the physical layer unit 203 of the WiMAX, the switch 207 is connected to the physical layer unit 206 of the WLAN. Even when the mobile terminal 101 transmits, the state of the switch 207 does not change.

  As described above, the portable terminal 101 can automatically switch between WiMAX wireless communication and WLAN wireless communication by the switch 207. Even if the portable terminal 101 moves between the outdoors and indoors, this wireless communication system can seamlessly connect the wireless communication networks of WiMAX and WLAN.

  As shown in FIG. 1, an input signal S1 of the WiMAX RF unit 111 is a signal of one frame of about 1 ms. The output signal S2 of the WiMAX RF unit 111 is delayed by about 3 μs from the input signal S1 of the WiMAX RF unit 111 by the processing of the WiMAX RF unit 111. Further, the output packet S3 of the WiMAX physical layer unit 112 is delayed by about 50 μs from the input signal S2 of the WiMAX physical layer unit 112 by the processing of the WiMAX physical layer unit 112. The output signal S5 of the WLAN physical layer unit 114 is delayed by about 1 ms from the input packet S4 of the WLAN physical layer unit 114 due to the processing of the WLAN physical layer unit 114. Further, the output signal S6 of the WLAN RF unit 115 is delayed by about 50 μs from the input signal S5 of the WLAN RF unit 115 by the processing of the WLAN RF unit 115.

  Thus, by converting the WiMAX format signal S1 into the IP packet 113 and converting the IP packet 113 into the WLAN format signal S6, a delay of 1 ms or more generated from the timing of the WiMAX frame and the WLAN frame A problem that a circuit delay or the like gives to a wireless communication system or a problem of current consumption occurs. Hereinafter, a second embodiment for solving the problem will be described.

(Second Embodiment)
FIG. 3 is a block diagram showing a configuration example of a radio communication system according to the second embodiment of the present invention. The wireless communication system includes a mobile terminal 101, a wireless relay device 102, and a base station 103. The wireless relay device 102 is placed in the building 104. Hereinafter, the points of the present embodiment different from the first embodiment will be described. The wireless relay apparatus 102 includes a first antenna 110, a WiMAX RF unit 111, a WiMAX physical layer unit 112, a WLAN RF unit 115, and a second antenna 116.

  First, a case where the mobile terminal 101 receives a signal from the base station 103 via the wireless relay device 102 will be described. The first antenna 110 receives a wireless signal S 11 having a WiMAX frequency from the base station 103. The WiMAX RF unit 111 converts the signal S11 received via the first antenna 110 from the RF frequency to the baseband frequency in accordance with the WiMAX wireless communication standard, and outputs the signal S12. The WiMAX physical layer unit 112 performs a synchronization process on the received signal S12 converted by the WiMAX RF unit 111. The WLAN RF unit 115 converts the received signal S12 converted by the WiMAX RF unit 111 from a baseband frequency to an RF frequency in accordance with the WLAN wireless communication standard, and outputs a signal S13. The second antenna 116 wirelessly transmits the received signal S13 converted by the WLAN RF unit 115 to the mobile terminal 101.

  The transmission signal of the base station 103 has a WiMAX-compliant physical layer level and a WiMAX-compliant RF frequency. The signal S11 has a WiMAX compliant physical layer level and a WiMAX compliant RF frequency. The signal S13 has a WiMAX-compliant physical layer level and a WLAN-compliant RF frequency. The received signal of the portable terminal 101 has a WiMAX-compliant physical layer level and a WLAN-compliant RF frequency.

  Next, a case where the mobile terminal 101 transmits a signal to the base station 103 via the wireless relay device 102 will be described. The transmission of the portable terminal 101 has a WiMAX-compliant physical layer level and a WLAN-compliant RF frequency. The second antenna 116 receives from the portable terminal 101 a wireless signal S13 having a frequency of the WLAN wireless communication standard. The WLAN RF unit 115 converts the signal S13 received via the second antenna 116 from the RF frequency to the baseband frequency in accordance with the WLAN wireless communication standard, and outputs the signal S12. The WiMAX RF unit 111 converts the received signal S12 converted by the WLAN RF unit 115 from the baseband frequency to the RF frequency in accordance with the WiMAX wireless communication standard, and outputs a signal S11. The first antenna 110 wirelessly transmits the reception signal S11 converted by the WiMAX RF unit 111 to the base station 103.

  The transmission signal of the portable terminal 101 has a WiMAX-compliant physical layer level and a WLAN-compliant RF frequency. The signal S13 has a WiMAX-compliant physical layer level and a WLAN-compliant RF frequency. The signal S11 has a WiMAX compliant physical layer level and a WiMAX compliant RF frequency. The received signal of the base station 103 has a WiMAX-compliant physical layer level and a WiMAX-compliant RF frequency.

  As described above, the wireless relay apparatus 102 only needs to perform conversion between the WiMAX RF frequency and the WLAN RF frequency, and thus there is no need to return the IP packet.

  FIG. 4 is a block diagram illustrating a configuration example of the mobile terminal 101 in FIG. The mobile terminal 101 includes a first antenna 201, a WiMAX RF unit 202, a second antenna 204, a WLAN RF unit 205, a switch 207, and a WiMAX physical layer unit 203.

  First, a case where the portable terminal 101 wirelessly transmits a signal will be described. The IP packet 208 is output to the physical layer unit 203 of WiMAX. The WiMAX physical layer unit 203 generates a transmission signal based on the transmission packet 208 in accordance with the WiMAX wireless communication standard. The switch 207 outputs the transmission signal generated by the WiMAX physical layer unit 203 to the WiMAX RF unit 202 or the WLAN RF unit 205. Specifically, as in the first embodiment, the switch 207 is connected to the WiMAX RF unit 202 when the portable terminal 101 communicates outdoors, and the WLAN RF when the portable terminal 101 communicates indoors. Connected to the unit 205. The WiMAX RF unit 202 converts the transmission signal generated by the WiMAX physical layer unit 203 from a baseband frequency to an RF frequency in accordance with the WiMAX wireless communication standard. The WLAN RF unit 205 converts the transmission signal generated by the WiMAX physical layer unit 203 from a baseband frequency to an RF frequency in accordance with the WLAN wireless communication standard. The first antenna 201 wirelessly transmits to the base station 103 a transmission signal having a WiMAX frequency converted by the WiMAX RF unit 202. The second antenna 204 wirelessly transmits the transmission signal of the WLAN frequency converted by the WLAN RF unit 205 to the wireless relay apparatus 102.

  The transmission signal of the first antenna 201 has a WiMAX-compliant physical layer level and a WiMAX-compliant RF frequency. The transmission signal of the second antenna 204 has a WiMAX-compliant physical layer level and a WLAN-compliant RF frequency.

  Next, a case where the mobile terminal 101 wirelessly receives a signal will be described. The first antenna 201 receives from the base station 103 a radio signal having a frequency of the WiMAX radio communication standard. The received signal has a WiMAX compliant physical layer level and a WiMAX compliant RF frequency. The second antenna 204 receives a radio signal having a frequency of the WLAN radio communication standard from the radio relay apparatus 102. The received signal has a WiMAX compliant physical layer level and a WLAN compliant RF frequency. The WiMAX RF unit 202 converts a signal received via the first antenna 201 from an RF frequency to a baseband frequency in accordance with the WiMAX wireless communication standard. The WLAN RF unit 205 converts a signal received via the second antenna 204 from an RF frequency to a baseband frequency in accordance with the WLAN wireless communication standard. The switch 207 outputs the signal converted by the WiMAX RF unit 202 or the WLAN RF unit 205 to the WiMAX physical layer unit 203. Specifically, as in the first embodiment, the switch 207 is connected to the WiMAX RF unit 202 when the mobile terminal 101 communicates outdoors, and the WLAN RF when the mobile terminal 101 communicates indoors. Connected to the unit 205. The WiMAX physical layer unit 203 generates and outputs a received IP packet 208 based on the received signal converted by the WiMAX RF unit 202 or the WLAN RF unit 205 in accordance with the WiMAX wireless communication standard.

  As described above, the portable terminal 101 can automatically switch between WiMAX wireless communication and WLAN wireless communication by the switch 207. When the mobile terminal 101 is located outdoors, the mobile terminal 101 communicates directly with the base station 103 via the first antenna 201. Also, when the mobile terminal 101 is located indoors, the mobile terminal 101 communicates with the base station 103 via the second antenna 204 and the wireless relay device 102. Even if the portable terminal 101 moves between the outdoors and indoors, this wireless communication system can seamlessly connect the wireless communication networks of WiMAX and WLAN.

  As shown in FIG. 3, the input signal S11 of the WiMAX RF unit 111 is a signal of one frame of about 1 ms. The output signal S12 of the WiMAX RF unit 111 is delayed by about 3 μs from the input signal S11 of the WiMAX RF unit 111 by the processing of the WiMAX RF unit 111. Further, the output signal S13 of the WLAN RF unit 115 is delayed by about 3 μs from the input signal S12 of the WLAN RF unit 115 by the processing of the WLAN RF unit 115.

  In the first embodiment, as illustrated in FIG. 1, the wireless relay device 102 receives a WiMAX signal from the outdoor base station 103 and transmits a WLAN signal to the indoor portable terminal 101. At this time, the radio relay apparatus 102 has to receive all one frame of the WiMAX signal, convert it to IP data 113, and then convert it to a WLAN signal and transmit it. Since one frame is about 1 ms, the delay amount is 1 ms or more.

  On the other hand, in the present embodiment, basically, only the delay time of the analog circuit needs to be considered, and the delay time is within 10 μs. Therefore, this embodiment can reduce the delay time to 1/100 compared to the first embodiment. In addition, the wireless relay device 102 and the mobile terminal 101 of this embodiment can reduce the physical layer portion (baseband circuit) of the WLAN and the like, and can reduce current consumption and cost.

(Third embodiment)
FIG. 5 is a block diagram showing a configuration example of the mobile terminal 101 according to the third embodiment of the present invention. In the first embodiment, when the wireless relay device 102 of FIG. 1 is used, it is necessary to use the mobile terminal 101 of FIG. In the second embodiment, when the wireless relay device 102 of FIG. 3 is used, it is necessary to use the mobile terminal 101 of FIG. In the present embodiment, the wireless relay device 102 of FIG. 1 may be placed in the building 104, or the wireless relay device 102 of FIG. 3 may be placed. That is, the wireless relay device 102 of FIG. 1 is placed in a certain building 104, and the wireless relay device 102 of FIG. 3 is placed in another building 104. The mobile terminal 101 of the present embodiment can communicate with the base station 103 via the wireless relay device 102 of FIG. 1 and can also communicate with the base station 103 via the wireless relay device 102 of FIG. . Hereinafter, the points of the present embodiment different from the first embodiment will be described. The mobile terminal 101 includes a first antenna 201, a WiMAX RF unit 202, a second antenna 204, a WLAN RF unit 205, a switch 207a, a WiMAX physical layer unit 203, a WLAN physical layer unit 206, and a switch 207b. .

  First, a case where the portable terminal 101 wirelessly transmits a signal will be described. The IP packet 208 is output to the WiMAX physical layer unit 203 or the WLAN physical layer unit 206 via the switch 207b. The WiMAX physical layer unit 203 generates a transmission signal based on the transmission packet 208 in accordance with the WiMAX wireless communication standard. The WLAN physical layer unit 206 generates a transmission signal based on the transmission packet 208 in accordance with the WLAN wireless communication standard. The switch 207 a outputs a signal generated by the WiMAX physical layer unit 203 or the WLAN physical layer unit 206 to the WiMAX RF unit 202 or the WLAN RF unit 205. The WiMAX RF unit 202 converts the transmission signal generated by the WiMAX physical layer unit 203 or the WLAN physical layer unit 206 from a baseband frequency to an RF frequency in accordance with the WiMAX wireless communication standard. The WLAN RF unit 205 converts the transmission signal generated by the WiMAX physical layer unit 203 or the WLAN physical layer unit 206 from a baseband frequency to an RF frequency in accordance with the WLAN wireless communication standard. The first antenna 201 wirelessly transmits to the base station 103 a transmission signal having a WiMAX frequency converted by the WiMAX RF unit 202. The second antenna 204 wirelessly transmits the transmission signal of the WLAN frequency converted by the WLAN RF unit 205 to the wireless relay apparatus 102.

  Next, a case where the mobile terminal 101 wirelessly receives a signal will be described. The first antenna 201 receives from the base station 103 a radio signal having a frequency of the WiMAX radio communication standard. The second antenna 204 receives a radio signal having a frequency of the WLAN radio communication standard from the radio relay apparatus 102. The WiMAX RF unit 202 converts a signal received via the first antenna 201 from an RF frequency to a baseband frequency in accordance with the WiMAX wireless communication standard. The WLAN RF unit 205 converts a signal received via the second antenna 204 from an RF frequency to a baseband frequency in accordance with the WLAN wireless communication standard. The switch 207a outputs the signal converted by the WiMAX RF unit 202 or the WLAN RF unit 205 to the WiMAX physical layer unit 203 or the WLAN physical layer unit 206. The WiMAX physical layer unit 203 generates a received IP packet based on the received signal converted by the WiMAX RF unit 202 or the WLAN RF unit 205 in accordance with the WiMAX wireless communication standard, and transmits the IP packet via the switch 207b. The packet 208 is output. The WLAN physical layer unit 206 generates a received IP packet based on the received signal converted by the WiMAX RF unit 202 or the WLAN RF unit 205 in accordance with the WLAN wireless communication standard, and transmits the IP packet via the switch 207b. The packet 208 is output.

  When the wireless relay device 102 of FIG. 1 is used, when the mobile terminal 101 is located outdoors, the switch 207b is connected to the WiMAX physical layer unit 203, and the switch 207a is connected to the WiMAX RF unit 202 and the WiMAX physical layer. When the unit 203 is connected and the portable terminal 101 is located indoors, the switch 207b is connected to the WLAN physical layer unit 206, and the switch 207a connects the WLAN RF unit 205 and the WLAN physical layer unit 206.

  When the wireless relay device 102 of FIG. 3 is used, when the mobile terminal 101 is located outdoors, the switch 207b is connected to the WiMAX physical layer unit 203, and the switch 207a is connected to the WiMAX RF unit 202 and the WiMAX physical layer. When the unit 203 is connected and the portable terminal 101 is located indoors, the switch 207b is connected to the WiMAX physical layer unit 203, and the switch 207a connects the WLAN RF unit 205 and the WiMAX physical layer unit 203. Similarly to the first embodiment, the switches 207a and 207b can perform control based on the error rate calculated by the physical layer unit 203 of WiMAX and the physical layer unit 206 of WLAN.

  As described above, the mobile terminal 101 according to the present embodiment can communicate with the base station 103 via the wireless relay apparatus 102 of FIG. 1 and further communicate with the base station 103 via the wireless relay apparatus 102 of FIG. You can also communicate.

(Fourth embodiment)
FIG. 6 is a block diagram illustrating a configuration example of the mobile terminal 101 according to the fourth embodiment of the present invention. Hereinafter, differences of the present embodiment from the third embodiment will be described. The WiMAX physical layer unit 203 includes an analog-digital converter and digital-analog converter 601, a switch 602, and a WiMAX signal processing unit 603. The WLAN physical layer unit 206 includes an analog-to-digital converter / digital-analog converter 601, a switch 602, and a WLAN signal processing unit 604. The physical layer unit 203 of WiMAX and the physical layer unit 206 of WLAN commonly use the analog-digital converter, the digital-analog converter 601, and the switch 602.

  First, a case where the portable terminal 101 wirelessly transmits a signal will be described. The switch 207 b outputs the IP packet 208 to the WiMAX signal processing unit 603 or the WLAN signal processing unit 604. The WiMAX signal processing unit 603 generates a transmission signal based on the IP packet 208 in accordance with the OFDMA (Orthogonal Frequency Division Multiple Access) method in accordance with the WiMAX wireless communication standard. The WLAN signal processing unit 604 generates a transmission signal based on the IP packet 208 by an OFDM (Orthogonal Frequency Division Multiplexing) method in accordance with the WLAN wireless communication standard. The switch 602 outputs the transmission signal generated by the WiMAX signal processing unit 603 or the WLAN signal processing unit 604 to the digital-analog converter 601. The digital / analog converter 601 converts the transmission signal generated by the WiMAX signal processing unit 603 or the WLAN signal processing unit 604 from digital to analog, and outputs the analog signal to the switch 207a.

  Next, a case where the mobile terminal 101 wirelessly receives a signal will be described. The analog-to-digital converter 601 converts the received signal input from the WiMAX RF unit 202 or the WLAN RF unit 205 via the switch 207a from analog to digital. The switch 602 outputs the signal converted by the analog-digital converter 601 to the WiMAX signal processing unit 603 or the WLAN signal processing unit 604. The WiMAX signal processing unit 603 generates an IP packet based on the signal converted by the analog-to-digital converter 601 by the OFDMA method in accordance with the WiMAX wireless communication standard, and outputs the IP packet 208 via the switch 207b. To do. The WLAN signal processing unit 604 generates an IP packet based on the signal converted by the analog-to-digital converter 601 by OFDM based on the WLAN wireless communication standard, and outputs the IP packet 208 via the switch 207b. To do.

  The switch 602 is connected to the WiMAX signal processing unit 603 or the WLAN signal processing unit 604 by the same operation as the switch 207b.

  As described above, the WiMAX physical layer unit 203 and the WLAN physical layer unit 206 can use the analog-digital converter and the digital-analog converter 601 in common. Thereby, the portable terminal 101 can be reduced in size. This embodiment can also be applied to the first embodiment.

(Fifth embodiment)
FIG. 7 is a block diagram illustrating a configuration example of the WiMAX RF unit 202 and the WLAN RF unit 205 in the mobile terminal 101 according to the fifth embodiment of the present invention. Hereinafter, the points of the present embodiment different from the second embodiment will be described.

  The WiMAX RF unit 202 includes a low noise amplifier 701, a mixer 702, a switch 705, a first mixer 706, a first filter 707, a second mixer 708, and a second filter 709. The WLAN RF unit 205 includes a low noise amplifier 703, a mixer 704, a switch 705, a first mixer 706, a first filter 707, a second mixer 708, and a second filter 709. The WiMAX RF unit 202 and the WLAN RF unit 205 commonly use the switch 705, the first mixer 706, the first filter 707, the second mixer 708, and the second filter 709.

  The low noise amplifier 701 amplifies the WiMAX signal received via the first antenna 201. The low noise amplifier 703 amplifies the WLAN signal received via the second antenna 204. The mixer 702 converts the signal amplified by the low noise amplifier 701 from an RF frequency to an intermediate frequency in accordance with the WiMAX wireless communication standard. The mixer 704 converts the signal amplified by the low noise amplifier 703 from an RF frequency to an intermediate frequency in accordance with WLAN wireless communication standards. The switch 705 outputs the output signal of the mixer 702 or 704 to the first mixers 706 and 708 by the same operation as the switch 207 of FIG. The first mixer 706 converts the output signal of the mixer 702 or 704 into an I signal. The second mixer 708 converts the output signal of the mixer 702 or 704 into a Q signal. The first filter 707 performs filtering on the output signal of the first mixer 706 and outputs the result to the switch 207 in FIG. The second filter 709 performs filtering on the output signal of the second mixer 708 and outputs the result to the switch 207 in FIG.

  As described above, the WiMAX RF unit 202 and the WLAN RF unit 205 can use the first mixer 706, the first filter 707, the second mixer 708, and the second filter 709 in common. Thereby, the portable terminal 101 can be reduced in size.

  In the first to fifth embodiments, each of the wireless relay device 102 and the mobile terminal 101 can be configured by one semiconductor chip.

  In the first to fifth embodiments, WiMAX is described as an example of the first wireless communication standard and WLAN is described as an example of the second wireless communication standard. However, the present invention is not limited to this. For example, as a wireless communication standard for outdoor use, LTE (Long Term Evolution) or the like can be used in addition to WiMAX. In addition to WLAN, Bluetooth (Bluetooth), Wi-Fi (Wireless Fidelity), or the like can be used as an indoor wireless communication standard. Also, the first wireless communication standard and the second wireless communication standard can be used with different communication ranges. For example, the first wireless communication standard is a wireless communication standard in a wide communication range, and the second wireless communication standard is a wireless communication standard in a narrower communication range.

  As described above, in the portable terminal (wireless communication apparatus) 101 according to the first to fifth embodiments, at the time of transmission, the physical layer unit 203 and / or 206 generates a transmission signal based on the transmission packet. The first RF unit 202 converts the transmission signal generated by the physical layer unit 203 and / or 206 from the baseband frequency to the RF frequency in accordance with the first wireless communication standard (WiMAX or the like). The second RF unit 205 is based on a transmission signal generated by the physical layer unit 203 and / or 206 in accordance with a second wireless communication standard (such as WLAN) that has a communication range different from that of the first wireless communication standard. Convert from band frequency to RF frequency. The first antenna 201 wirelessly transmits the transmission signal converted by the first RF unit 202. The second antenna 204 wirelessly transmits the transmission signal converted by the second RF unit 205.

  In the mobile terminal (wireless communication apparatus) 101 of the first to fifth embodiments, the first antenna 201 receives a wireless signal having a frequency of the first wireless communication standard at the time of reception. The second antenna 204 receives a radio signal having a frequency of the second radio communication standard. The first RF unit 202 converts a signal received via the first antenna 201 from an RF frequency to a baseband frequency in accordance with the first wireless communication standard. The second RF unit 205 converts the signal received via the second antenna 204 from the RF frequency to the baseband frequency in accordance with the second wireless communication standard. The physical layer unit 203 and / or 206 generates a reception packet based on the reception signal converted by the first RF unit 202 or the second RF unit 205.

  In the wireless relay device 102 of the first to fifth embodiments, when the mobile terminal 101 receives from the base station 103, the first antenna 110 receives a wireless signal having a frequency of the first wireless communication standard. . The first RF unit 111 converts a signal received via the first antenna 110 from an RF frequency to a baseband frequency in accordance with the first wireless communication standard. The physical layer unit 112 performs a synchronization process on the reception signal converted by the first RF unit 111. The second RF unit 115 generates a signal based on the received signal converted by the first RF unit 111 from the baseband frequency in accordance with the second wireless communication standard having a communication range different from that of the first wireless communication standard. Convert to RF frequency. The second antenna 116 wirelessly transmits the reception signal converted by the second RF unit 115.

  In the wireless relay device 102 of the first to fifth embodiments, when the mobile terminal 101 transmits to the base station 103, the second antenna 116 receives a wireless signal having a frequency of the second wireless communication standard. . The second RF unit 115 converts the signal received via the second antenna 116 from the RF frequency to the baseband frequency in accordance with the second wireless communication standard. The first RF unit 111 converts a signal based on the reception signal converted by the second RF unit 115 from a baseband frequency to an RF frequency in accordance with the first wireless communication standard. The first antenna 110 wirelessly transmits the reception signal converted by the first RF unit 111.

  According to the first to fifth embodiments, it is possible to seamlessly connect wireless communication networks of the first wireless communication standard and the second wireless communication standard.

  The above-described embodiments are merely examples of implementation in carrying out the present invention, and the technical scope of the present invention should not be construed in a limited manner. That is, the present invention can be implemented in various forms without departing from the technical idea or the main features thereof.

  Regarding the above embodiment, the following additional notes are disclosed.

(Appendix 1)
A physical layer unit that generates a transmission signal based on the transmission packet;
A first RF unit that converts a transmission signal generated by the physical layer unit in accordance with a first wireless communication standard from a baseband frequency to an RF frequency;
A second RF unit that converts a transmission signal generated by the physical layer unit from a baseband frequency to an RF frequency in accordance with a second wireless communication standard having a communication range different from that of the first wireless communication standard;
A first antenna that wirelessly transmits a transmission signal converted by the first RF unit;
A second antenna that wirelessly transmits the transmission signal converted by the second RF unit,
The first antenna receives a radio signal having a frequency of the first wireless communication standard;
The second antenna receives a radio signal having a frequency of the second radio communication standard;
The first RF unit converts a signal received via the first antenna according to the first wireless communication standard from an RF frequency to a baseband frequency,
The second RF unit converts a signal received via the second antenna in accordance with the second wireless communication standard from an RF frequency to a baseband frequency,
The wireless communication apparatus, wherein the physical layer unit generates a reception packet based on a reception signal converted by the first RF unit or the second RF unit.
(Appendix 2)
The physical layer part is
A first physical layer unit that generates a transmission signal based on a transmission packet in accordance with the first wireless communication standard;
A second physical layer unit that generates a transmission signal based on a transmission packet in accordance with the second wireless communication standard,
The first physical layer unit generates a reception packet based on a reception signal converted by the first RF unit or the second RF unit in accordance with the first wireless communication standard,
The second physical layer unit generates a reception packet based on a reception signal converted by the first RF unit or the second RF unit in accordance with the second wireless communication standard. The wireless communication apparatus according to appendix 1.
(Appendix 3)
The first physical layer unit and the second physical layer unit include an analog-to-digital converter that converts a reception signal input from the first RF unit or the second RF unit from analog to digital, and a transmission signal. The wireless communication apparatus according to appendix 2, wherein a digital-analog converter that converts digital to analog is commonly used.
(Appendix 4)
The first RF unit and the second RF unit commonly use a first mixer that converts a received signal into an I signal and a second mixer that converts a received signal into a Q signal. The wireless communication device according to any one of appendices 1 to 3.
(Appendix 5)
A first antenna for receiving a radio signal having a frequency of a first radio communication standard;
A first RF unit that converts a signal received via the first antenna in accordance with the first wireless communication standard from an RF frequency to a baseband frequency;
A physical layer unit that performs synchronization processing on the reception signal converted by the first RF unit;
A second signal for converting a signal based on the received signal converted by the first RF unit from a baseband frequency to an RF frequency in accordance with a second wireless communication standard having a communication range different from that of the first wireless communication standard. RF section;
A second antenna that wirelessly transmits the reception signal converted by the second RF unit,
The second antenna receives a radio signal having a frequency of the second radio communication standard;
The second RF unit converts a signal received via the second antenna in accordance with the second wireless communication standard from an RF frequency to a baseband frequency,
The first RF unit converts a signal based on the received signal converted by the second RF unit in accordance with the first wireless communication standard from a baseband frequency to an RF frequency,
The wireless relay device, wherein the first antenna wirelessly transmits a reception signal converted by the first RF unit.
(Appendix 6)
The physical layer part is
In accordance with the first wireless communication standard, a first physical layer unit that generates a packet based on a signal received from the first antenna via the first RF unit;
A second physical layer unit that generates a transmission signal based on the packet generated by the first physical layer unit,
The second RF unit converts a transmission signal generated by the second physical layer unit from a baseband frequency to an RF frequency, and transmits the RF signal via the second antenna.
The second physical layer unit generates a packet based on a signal received from the second antenna via the second RF unit in accordance with the second wireless communication standard,
The first physical layer unit generates a transmission signal based on the packet generated by the second physical layer unit in accordance with the first wireless communication standard,
The supplementary note 5, wherein the first RF unit converts a transmission signal generated by the first physical layer unit from a baseband frequency to an RF frequency, and transmits the converted signal through the first antenna. Wireless relay device.
(Appendix 7)
The second RF unit converts a signal received from the first antenna via the first RF unit from a baseband frequency to an RF frequency in accordance with the second wireless communication standard, and Transmit through two antennas,
The first RF unit converts a signal received from the second antenna via the second RF unit from a baseband frequency to an RF frequency in accordance with the first wireless communication standard, and 6. The wireless relay device according to appendix 5, wherein transmission is performed via one antenna.
(Appendix 8)
A wireless communication device;
A wireless relay device,
The wireless communication device
A physical layer unit that generates a transmission signal based on the transmission packet;
A first RF unit that converts a transmission signal generated by the physical layer unit in accordance with a first wireless communication standard from a baseband frequency to an RF frequency;
A second RF unit that converts a transmission signal generated by the physical layer unit from a baseband frequency to an RF frequency in accordance with a second wireless communication standard having a communication range different from that of the first wireless communication standard;
A first antenna that wirelessly transmits a transmission signal converted by the first RF unit to a base station;
A second antenna that wirelessly transmits the transmission signal converted by the second RF unit to the wireless relay device;
The first antenna receives a radio signal having a frequency of the first radio communication standard from the base station,
The second antenna receives a radio signal having a frequency of the second radio communication standard from the radio relay device;
The first RF unit converts a signal received via the first antenna according to the first wireless communication standard from an RF frequency to a baseband frequency,
The second RF unit converts a signal received via the second antenna in accordance with the second wireless communication standard from an RF frequency to a baseband frequency,
The physical layer unit generates a reception packet based on the reception signal converted by the first RF unit or the second RF unit,
The wireless relay device is
A third antenna for receiving a radio signal of the frequency of the first radio communication standard from the base station;
A third RF unit for converting a signal received via the third antenna in accordance with the first wireless communication standard from an RF frequency to a baseband frequency;
A physical layer unit that performs synchronization processing on the received signal converted by the third RF unit;
A fourth RF unit that converts a signal based on the received signal converted by the third RF unit in accordance with the second wireless communication standard from a baseband frequency to an RF frequency;
A fourth antenna that wirelessly transmits the reception signal converted by the fourth RF unit to the wireless communication device;
The fourth antenna receives a radio signal having a frequency of the second radio communication standard from the radio communication device;
The fourth RF unit converts a signal received via the fourth antenna according to the second wireless communication standard from an RF frequency to a baseband frequency,
The third RF unit converts a signal based on the reception signal converted by the fourth RF unit in accordance with the first wireless communication standard from a baseband frequency to an RF frequency,
The wireless communication system, wherein the third antenna wirelessly transmits the reception signal converted by the third RF unit to the base station.

201 First antenna 202 WiMAX RF unit 203 WiMAX physical layer unit 204 Second antenna 205 WLAN RF unit 207 Switch 208 IP packet

Claims (5)

A physical layer unit that generates a transmission signal based on the transmission packet;
A first RF unit that converts a transmission signal generated by the physical layer unit in accordance with a first wireless communication standard from a baseband frequency to an RF frequency;
A second RF unit that converts a transmission signal generated by the physical layer unit from a baseband frequency to an RF frequency in accordance with a second wireless communication standard having a communication range different from that of the first wireless communication standard;
A first antenna that wirelessly transmits a transmission signal converted by the first RF unit;
A second antenna that wirelessly transmits the transmission signal converted by the second RF unit,
The first antenna receives a radio signal having a frequency of the first wireless communication standard;
The second antenna receives a radio signal having a frequency of the second radio communication standard;
The first RF unit converts a signal received via the first antenna according to the first wireless communication standard from an RF frequency to a baseband frequency,
The second RF unit converts a signal received via the second antenna in accordance with the second wireless communication standard from an RF frequency to a baseband frequency,
The wireless communication apparatus, wherein the physical layer unit generates a reception packet based on a reception signal converted by the first RF unit or the second RF unit. The physical layer part is
A first physical layer unit that generates a transmission signal based on a transmission packet in accordance with the first wireless communication standard;
A second physical layer unit that generates a transmission signal based on a transmission packet in accordance with the second wireless communication standard,
The first physical layer unit generates a reception packet based on a reception signal converted by the first RF unit or the second RF unit in accordance with the first wireless communication standard,
The second physical layer unit generates a reception packet based on a reception signal converted by the first RF unit or the second RF unit in accordance with the second wireless communication standard. The wireless communication apparatus according to claim 1. A first antenna for receiving a radio signal having a frequency of a first radio communication standard;
A first RF unit that converts a signal received via the first antenna in accordance with the first wireless communication standard from an RF frequency to a baseband frequency;
A physical layer unit that performs synchronization processing on the reception signal converted by the first RF unit;
A second signal for converting a signal based on the received signal converted by the first RF unit from a baseband frequency to an RF frequency in accordance with a second wireless communication standard having a communication range different from that of the first wireless communication standard. RF section;
A second antenna that wirelessly transmits the reception signal converted by the second RF unit,
The second antenna receives a radio signal having a frequency of the second radio communication standard;
The second RF unit converts a signal received via the second antenna in accordance with the second wireless communication standard from an RF frequency to a baseband frequency,
The first RF unit converts a signal based on the received signal converted by the second RF unit in accordance with the first wireless communication standard from a baseband frequency to an RF frequency,
The wireless relay device, wherein the first antenna wirelessly transmits a reception signal converted by the first RF unit. The physical layer part is
In accordance with the first wireless communication standard, a first physical layer unit that generates a packet based on a signal received from the first antenna via the first RF unit;
A second physical layer unit that generates a transmission signal based on the packet generated by the first physical layer unit,
The second RF unit converts a transmission signal generated by the second physical layer unit from a baseband frequency to an RF frequency, and transmits the RF signal via the second antenna.
The second physical layer unit generates a packet based on a signal received from the second antenna via the second RF unit in accordance with the second wireless communication standard,
The first physical layer unit generates a transmission signal based on the packet generated by the second physical layer unit in accordance with the first wireless communication standard,
4. The first RF unit converts a transmission signal generated by the first physical layer unit from a baseband frequency to an RF frequency, and transmits the converted signal via the first antenna. The wireless relay device described. A wireless communication device;
A wireless relay device,
The wireless communication device
A physical layer unit that generates a transmission signal based on the transmission packet;
A first RF unit that converts a transmission signal generated by the physical layer unit in accordance with a first wireless communication standard from a baseband frequency to an RF frequency;
A second RF unit that converts a transmission signal generated by the physical layer unit from a baseband frequency to an RF frequency in accordance with a second wireless communication standard having a communication range different from that of the first wireless communication standard;
A first antenna that wirelessly transmits a transmission signal converted by the first RF unit to a base station;
A second antenna that wirelessly transmits the transmission signal converted by the second RF unit to the wireless relay device;
The first antenna receives a radio signal having a frequency of the first radio communication standard from the base station,
The second antenna receives a radio signal having a frequency of the second radio communication standard from the radio relay device;
The first RF unit converts a signal received via the first antenna according to the first wireless communication standard from an RF frequency to a baseband frequency,
The second RF unit converts a signal received via the second antenna in accordance with the second wireless communication standard from an RF frequency to a baseband frequency,
The physical layer unit generates a reception packet based on the reception signal converted by the first RF unit or the second RF unit,
The wireless relay device is
A third antenna for receiving a radio signal of the frequency of the first radio communication standard from the base station;
A third RF unit for converting a signal received via the third antenna in accordance with the first wireless communication standard from an RF frequency to a baseband frequency;
A physical layer unit that performs synchronization processing on the received signal converted by the third RF unit;
A fourth RF unit that converts a signal based on the received signal converted by the third RF unit in accordance with the second wireless communication standard from a baseband frequency to an RF frequency;
A fourth antenna that wirelessly transmits the reception signal converted by the fourth RF unit to the wireless communication device;
The fourth antenna receives a radio signal having a frequency of the second radio communication standard from the radio communication device;
The fourth RF unit converts a signal received via the fourth antenna according to the second wireless communication standard from an RF frequency to a baseband frequency,
The third RF unit converts a signal based on the reception signal converted by the fourth RF unit in accordance with the first wireless communication standard from a baseband frequency to an RF frequency,
The wireless communication system, wherein the third antenna wirelessly transmits the reception signal converted by the third RF unit to the base station.

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