JP2014003473A - Radio repeater and its control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To suppress increase in a time necessary for data transmission between a radio master unit and a radio slave unit due to data relay.SOLUTION: A radio repeater according to the invention includes: a first radio unit for performing radio communication with a radio master unit via a first channel; a second radio unit for performing radio communication with a radio slave unit via a second channel; and a control unit for having the first and second radio units perform radio communication in parallel and perform transmission and reception of data between the radio master unit and the radio slave unit.

Description

  The present invention relates to a wireless relay device that relays data between a wireless master device and a wireless slave device, and a control method thereof.

  In a communication system such as a wireless local area network (LAN) in which a wireless master device and a wireless slave device perform wireless communication, depending on the communication environment, radio waves are blocked between the wireless master device and the wireless slave device. And wireless slave units may not be able to perform wireless communication.

  Therefore, Patent Literature 1 (Japanese Patent Application Laid-Open No. 2011-135594) discloses a wireless relay device that performs wireless communication with a wireless master device and a wireless slave device and relays data between the wireless master device and the wireless slave device. Has been. According to this wireless relay device, data can be transmitted and received between the wireless master device and the wireless slave device via the wireless relay device even when the wireless master device and the wireless slave device cannot directly perform wireless communication. It becomes possible.

JP 2011-135594 A

  Since the wireless relay device as described above generally uses the same channel for wireless communication with a wireless parent device and wireless communication with a wireless child device, wireless communication can be performed simultaneously with the wireless parent device and the wireless child device. Can not. Therefore, for example, when data is transmitted from the wireless master device to the wireless slave device via the wireless relay device, data is transmitted from the wireless master device to the wireless relay device, and after the data transmission by the wireless master device is completed, the wireless relay is performed. There is a problem that the apparatus needs to transmit data to the wireless slave unit, and the time required for data transmission is increased compared to the case where data is directly transmitted between the wireless master unit and the wireless slave unit.

In order to achieve the above object, the wireless relay device of the present invention provides:
A first wireless unit that performs wireless communication with the wireless parent device via the first channel;
A second wireless unit that performs wireless communication with the wireless slave device via the second channel;
A control unit configured to cause the first and second wireless units to perform wireless communication in parallel and to transmit and receive data between the wireless master device and the wireless slave device;

In order to achieve the above object, a method for controlling a wireless relay device of the present invention includes:
A wireless relay device having a first wireless unit that performs wireless communication with a wireless master device via a first channel, and a second wireless unit that performs wireless communication with a wireless slave device via a second channel A control method,
The first wireless unit and the second wireless unit perform wireless communication in parallel, and transmit and receive data between the wireless master device and the wireless slave device.

  According to the present invention, it is possible to suppress an increase in time required for data transmission between a wireless master device and a wireless slave device due to data relay.

It is a figure which shows the structure of the communication system with which the radio relay apparatus of one Embodiment of this invention is applied. It is a block diagram which shows the structure of the radio relay apparatus shown in FIG. It is a figure which shows an example of the MAC address memorize | stored in Flash ROM shown in FIG. It is a figure which shows the connection state of a radio | wireless main | base station and a radio | wireless subunit | mobile_unit. It is a figure which shows the operation | movement of a radio | wireless main | base station and a radio | wireless sub_unit when direct data transmission is performed between a radio | wireless main | base station and a radio | wireless slave | mobile_unit. It is a figure which shows operation | movement of a radio | wireless main | base station, a radio | wireless relay apparatus, and a radio | wireless subunit | mobile_unit in case data transmission is performed between a radio | wireless main | base station and a radio | wireless slave | mobile_unit via a related radio | wireless relay apparatus. It is a figure which shows operation | movement of a radio | wireless main | base station, a radio | wireless relay apparatus, and a radio | wireless subunit | mobile_unit in case data transmission is performed between a radio | wireless main | base station and a radio | wireless slave | mobile_unit via the radio | wireless relay apparatus which concerns on this invention. It is a figure which shows operation | movement of a radio | wireless main | base station and a radio | wireless slave | mobile_unit in case data transmission is performed directly between a radio | wireless main | base station and a radio | wireless slave | mobile_unit. It is a figure which shows operation | movement of a radio | wireless main | base station, a radio | wireless relay apparatus, and a radio | wireless subunit | mobile_unit in case data transmission is performed between a radio | wireless main | base station and a radio | wireless slave | mobile_unit via a related radio | wireless relay apparatus. It is a figure which shows operation | movement of a radio | wireless main | base station, a radio | wireless relay apparatus, and a radio | wireless subunit | mobile_unit in case data transmission is performed between a radio | wireless main | base station and a radio | wireless slave | mobile_unit via the radio | wireless relay apparatus which concerns on this invention.

  EMBODIMENT OF THE INVENTION Below, the form for implementing this invention is demonstrated with reference to drawings.

  FIG. 1 is a diagram illustrating a configuration of a communication system 10 to which a wireless relay device 100 according to an embodiment of the present invention is applied.

  The communication system 10 includes a wireless relay device 100, a wireless master device 101, and a wireless slave device 102.

  Each of the wireless relay device 100, the wireless master device 101, and the wireless slave device 102 is a wireless LAN communication device that performs wireless LAN communication conforming to the IEEE 802.11 standard.

  The wireless relay device 100 performs wireless communication with the wireless master device 101 and the wireless slave device 102 and performs data relay between the wireless master device 101 and the wireless slave device 102.

  The wireless master device 101 is an access point device, and the wireless slave device 102 is a client terminal used by a user.

  Next, the configuration of the wireless relay device 100 will be described. Note that the configurations of the wireless master device 101 and the wireless slave device 102 are well known to those skilled in the art and are not directly related to the present invention, and thus the description thereof is omitted.

  FIG. 2 is a block diagram illustrating a configuration of the wireless relay device 100.

  The wireless relay device 100 includes a base unit radio unit 210, a slave unit radio unit 220, a flash ROM (Read Only Memory) 230, a memory 240, and a control unit 250. The base unit radio unit 210 includes a base unit side interface unit 211 and a base unit media access control (MAC) unit 212. The slave unit wireless unit 220 includes a slave unit side interface unit 221 and a slave unit MAC unit 222. The base unit radio unit 210 is an example of a first radio unit, and the slave unit radio unit 220 is an example of a second radio unit.

  The base unit radio unit 210 performs radio communication with the radio base unit 101.

  The base unit side interface unit 211 transmits / receives data to / from the wireless base unit 101 via, for example, a 5 GHz band wireless LAN channel.

  The base unit MAC unit 212 controls wireless communication with the wireless base unit 101 via the base unit side interface unit 211 in accordance with a MAC protocol defined in the IEEE 802.11 standard.

  The slave unit side interface unit 221 transmits / receives data to / from the wireless slave unit 102 via, for example, a 2.4 GHz band wireless LAN channel.

  The slave unit MAC unit 222 controls wireless communication with the wireless slave unit 102 via the slave unit side interface unit 221 according to the MAC protocol defined in the IEEE 802.11 standard.

  Note that the base unit side interface unit 211 and the slave unit side interface unit 221 include an antenna for wireless communication, a circuit that converts an analog signal received from the antenna into a digital signal, and a digital signal that is converted into an analog signal from the antenna. A circuit for transmitting is provided.

  As shown in FIG. 3, the flash ROM 230 stores a MAC address 1 used for wireless communication with the wireless master device 101 and a MAC address 2 used for wireless communication with the wireless slave device 102.

  The memory 240 stores various data. The memory 240 is provided with a data buffer unit 241. The data buffer unit 241 temporarily stores data received from the wireless master device 101 and the wireless slave device 102.

  The control unit 250 controls the base unit radio unit 210 and the slave unit radio unit 220. The base unit radio unit 210 and the slave unit radio unit 220 are connected between the radio base unit 101 and the radio slave unit 102. Data relay.

  Next, operation | movement of the communication system 10 of this embodiment is demonstrated.

  In the following, it is assumed that the wireless master device 101 is a dual band device capable of wireless communication using a wireless LAN in the 5 GHz band and the 2.4 GHz band. The wireless master device 101 is also used for SSID (Service Set Identifier) -1, which is setting information used for wireless communication by a wireless LAN in the 5 GHz band, and for wireless communication by a wireless LAN in the 2.4 GHz band. It is assumed that the setting information SSID-2 is held. The wireless relay device 100 and the wireless slave device 102 can perform wireless communication with the wireless master device 101 by setting the same SSID as the wireless master device 101.

  First, the control unit 250 instructs the base unit MAC unit 212 to output a connection request to the wireless base unit 101 in order to perform wireless communication with the wireless base unit 101 in the 5 GHz band. Here, the control unit 250 reads the MAC address 1 stored in the flash ROM 230 and used for wireless communication with the wireless master device 101, and instructs the read MAC address 1 to output a connection request to the wireless master device 101. In addition, the data is output to the base unit MAC unit 212.

  When an instruction to output a connection request to the wireless master unit 101 is input, the base unit MAC unit 212 sends a connection request including the MAC address 1 input together with the instruction to the base unit side interface unit 211. To the wireless master device 101.

  When receiving the connection request from the wireless relay device 100, the wireless master device 101 establishes wireless communication with the wireless relay device 100.

  The base unit MAC unit 212 acquires the SSID-1 and SSID-2 held by the wireless base unit 101 via the base unit side interface unit 211, and outputs them to the control unit 250.

  Control unit 250 causes memory 240 to store SSID-1 and SSID-2 output from base unit MAC unit 212. In addition, the control unit 250 sets SSID-1 as the SSID used for wireless communication by the wireless LAN in the 5 GHz band, and sets SSID-2 as SSID used for wireless communication by the wireless LAN in the 2.4 GHz band. Set.

  Here, wireless communication between the wireless master device 101 and the wireless relay device 100 is performed via an arbitrary channel in the 5 GHz band.

  On the other hand, the wireless slave device 102 transmits a connection request to the wireless relay device 100 in order to perform wireless communication with the wireless relay device 100 in the 2.4 GHz band.

  The connection request transmitted from the wireless slave unit 102 is received by the slave unit interface unit 201 and input to the control unit 250 via the slave unit MAC unit 222.

  When a connection request from the wireless slave unit 102 is input, the control unit 250 instructs the slave unit MAC unit 222 to perform connection setting processing with the wireless slave unit 102. Here, the control unit 250 reads the MAC address 2 stored in the flash ROM 230 and used for wireless communication with the wireless slave device 102, and uses the read MAC address 2 together with the connection setting processing instruction for the slave device. The data is output to the MAC unit 222.

  When an instruction for connection setting processing with the wireless slave device 102 is input, the slave unit MAC unit 222 uses the MAC address 2 input together with the instruction to perform connection setting processing with the wireless slave device 102. To establish wireless communication with the wireless slave device 102. The control unit 250 also causes the slave unit MAC unit 222 to notify the wireless slave unit 102 of the SSID-2 acquired from the wireless master unit 101 via the slave unit side interface unit 221. The wireless slave device 102 sets the notified SSID-2 as the SSID used for wireless communication by the wireless LAN in the 2.4 GHz band.

  Here, wireless communication between the wireless slave device 102 and the wireless relay device 100 is performed via an arbitrary channel in the 2.4 GHz band.

  Through the processing described above, the wireless master device 101 and the wireless slave device 102 can perform wireless communication via different channels. By performing wireless communication through different channels between the wireless master device 101 and the wireless slave device 102, interference between channels does not occur. Therefore, the wireless relay device 100 is configured simultaneously with the wireless master device 101 and the wireless slave device 102. Wireless communication can be performed.

  Here, as shown in FIG. 4, the wireless slave device 102 that has been transmitting / receiving data to / from the wireless master device 101 via the wireless relay device 100 is in a position where it can directly communicate with the wireless master device 101. May move.

  As described above, the wireless master device 101 holds the SSID-2 used for wireless communication by the wireless LAN in the 2.4 GHz band. In addition, SSID-2 is set in the wireless slave device 102 as the SSID used for wireless communication by the wireless LAN in the 2.4 GHz band. Since SSID-2 common to the wireless master device 101 and the wireless slave device 102 is set, the wireless master device 101 and the wireless slave device 102 automatically perform wireless communication by a wireless LAN in the 2.4 GHz band. Can be done.

  Conversely, the wireless slave device 102 that has been performing wireless communication with the wireless master device 101 by the wireless LAN in the 2.4 GHz band may move to a position where data relay by the wireless relay device 100 is necessary. Also in this case, as described above, since SSID-2 is set in the wireless relay device 100 as the SSID used for wireless communication by the wireless LAN in the 2.4 GHz band, It is possible to automatically perform wireless communication with a wireless LAN using a wireless LAN in the 2.4 GHz band.

  Hereinafter, operations of the wireless master device 101, the wireless relay device 100, and the wireless slave device 102 will be described more specifically.

  First, operations of the wireless master device 101 and the wireless slave device 102 when the wireless master device 101 directly transmits data A to the wireless slave device 102 will be described with reference to FIG.

  At time t51, the wireless master device 101 starts transmission of data A to the wireless slave device 102, and the wireless slave device 102 receives the data A transmitted from the wireless master device 101. In general, there is a time lag between when the transmission side starts transmitting data and when the reception side receives the data. However, in general, this time lag is sufficiently small as compared with the time required for transmission / reception of the entire data, and thus description thereof is omitted. In the following, it is assumed that time T is required for transmission of the entire data A.

  At time t52 after time T has elapsed from time t51, the wireless master device 101 ends the transmission of data A, and the wireless slave device 102 ends the reception of data A. Therefore, as shown in FIG. 5, when the wireless master device 101 directly transmits data A to the wireless slave device 102, time T is required.

  Next, an operation when the wireless master device 101 transmits data A to the wireless slave device 102 via the wireless relay device will be described.

  First, for comparison, a wireless master device is connected via a general wireless relay device (hereinafter referred to as wireless relay device 103) that performs wireless communication using the same channel between the wireless master device 101 and the wireless slave device 102. The operations of the wireless master device 101, the wireless relay device 103, and the wireless slave device 102 when 101 transmits data A to the wireless slave device 102 will be described with reference to FIG.

  At time t61, the wireless master device 101 starts transmitting data A to the wireless relay device 103, and the wireless relay device 103 receives the data A transmitted from the wireless parent device 101, and receives the received data A. Buffer.

  At time t62 after the elapse of time T from time t61, the wireless master device 101 ends the transmission of data A, and the wireless relay device 103 ends the reception of data A.

  When the reception of the data A is completed, the wireless relay device 103 starts transmission of the buffered data A to the wireless slave device 102, and the wireless slave device 102 receives the data transmitted from the wireless relay device 103. .

  At time t63 after the elapse of time T from time t62, the wireless relay device 103 ends the transmission of data A, and the wireless slave device 102 ends the reception of data A. Accordingly, as shown in FIG. 6, when the wireless master device 101 transmits data A to the wireless slave device 102 via the wireless relay device 103, the wireless master device 101 directly transmits data A to the wireless slave device 102. In this case, 2 times of time 2T is required.

  Next, the operations of the wireless master device 101, the wireless relay device 100, and the wireless slave device 102 when the wireless master device 101 transmits data A to the wireless slave device 102 via the wireless relay device 100 of the present embodiment. This will be described with reference to FIG.

  At time t71, the wireless master device 101 starts transmitting data A to the wireless relay device 100.

  In the wireless relay device 100, the data A transmitted from the wireless master device 101 is received by the parent device-side interface unit 211 and input to the control unit 250 via the parent device MAC unit 212. The control unit 250 buffers the input data A in the data buffer unit 241.

  Next, the control unit 250 determines whether or not the slave unit radio unit 220 is in an idle state in which no wireless communication is performed. Since the slave unit wireless unit 220 is not performing wireless communication and is in an idle state, the control unit 250 instructs the slave unit MAC unit 222 to transmit the buffered data A to the wireless slave unit 102. . In response to the instruction from the control unit 250, the slave unit MAC unit 222 starts transmission of the buffered data A to the wireless slave unit 102 via the slave unit side interface unit 221. Normally, when the data buffering amount reaches a threshold value, the data is transmitted. Therefore, there is a time lag after the data is received until the buffering amount reaches a predetermined threshold and transmission of the data is started. However, this time lag can be sufficiently reduced as compared with the time required for transmission / reception of the entire data A by appropriately setting the above-described threshold value, and thus the description is omitted.

  The wireless slave device 102 receives the data A transmitted from the wireless relay device 100.

  At time t72 after the elapse of time T from time t71, the wireless master device 101 ends transmission of data A.

  In radio relay apparatus 100, base unit side interface unit 211 ends the reception of data A. Further, the slave unit MAC unit 222 ends the transmission of the buffered data A to the wireless slave unit 102 via the slave unit side interface unit 221.

  The wireless slave device 102 ends the reception of data A. Accordingly, as shown in FIG. 7, when the wireless master device 101 transmits data A to the wireless slave device 102 via the wireless relay device 100 of the present embodiment, the wireless master device 101 transmits data to the wireless slave device 102. The time T is the same as when A is directly transmitted, and an increase in time required for data transmission between the wireless master device 101 and the wireless slave device 102 due to data relay is suppressed.

  In FIGS. 5 to 7, an example in which data is transmitted from the wireless master device 101 side has been described. However, according to the wireless relay device 100 of the present embodiment, data is transmitted from the wireless slave device 102 side. In this case as well, an increase in time required for data transmission between the wireless master device 101 and the wireless slave device 102 due to data relay can be suppressed.

  Further, according to the wireless relay device 100 of the present embodiment, an increase in time required for data transmission can be suppressed even when the wireless master device 101 and the wireless slave device 102 each transmit data to the counterpart side. . Hereinafter, operations when the wireless master device 101 and the wireless slave device 102 each transmit data to the other party will be described.

  First, when the wireless master device 101 directly transmits data A to the wireless slave device 102 and the wireless slave device 102 directly transmits data B to the wireless master device 101, the wireless master device 101 and the wireless slave device 101 are transmitted. The operation of the machine 102 will be described with reference to FIG.

  At time t81, the wireless master device 101 starts transmission of data A to the wireless slave device 102, and the wireless slave device 102 receives the data A transmitted from the wireless master device 101.

  At time t82 after the elapse of time T from time t81, the wireless master device 101 ends transmission of data A, and the wireless slave device 102 ends reception of data A. When the reception of the data A is completed, the wireless slave device 102 starts transmitting data B to the wireless master device 101, and the wireless master device 101 receives the data B transmitted from the wireless slave device 102. Here, it is assumed that transmission of data B requires time T.

  At time t83 after the elapse of time T from time t82, the wireless slave device 102 ends transmission of data B, and the wireless parent device 101 ends reception of data B. Therefore, as shown in FIG. 8, when the wireless master device 101 directly transmits data A to the wireless slave device 102 and the wireless slave device 102 directly transmits data B to the wireless slave device 101, time 2T is required. It becomes.

  Next, an operation when the wireless master device 101 transmits data A to the wireless slave device 102 and the wireless slave device 102 transmits data B to the wireless master device 101 via the wireless relay device will be described.

  First, for comparison, a case where the wireless master device 101 transmits data A to the wireless slave device 102 and the wireless slave device 102 transmits data B to the wireless master device 101 via the wireless relay device 103 described above. Operations of the wireless master device 101, the wireless relay device 103, and the wireless slave device 102 will be described with reference to FIG.

  At time t91, the wireless master device 101 starts transmission of data A to the wireless relay device 103. The wireless relay device 103 receives the data A transmitted from the wireless master device 101, and receives the received data A. Buffer.

  At time t92 after the elapse of time T from time t91, the wireless master device 101 ends the transmission of data A, and the wireless relay device 103 ends the reception of data A.

  When the reception of data A is completed, the wireless relay device 103 starts transmission of the buffered data A to the wireless slave device 102, and the wireless slave device 102 receives the data A transmitted from the wireless relay device 103. To do.

  At time t93 after the elapse of time T from time t92, the wireless relay device 103 ends transmission of data A, and the wireless slave device 102 ends reception of data A. When the reception of data A is completed, the wireless slave device 102 starts transmitting data B to the wireless relay device 103, and the wireless relay device 103 receives the data B transmitted from the wireless slave device 102, and receives the data B. Buffered data B.

  At time t94 after the elapse of time T from time t93, the wireless slave device 102 ends the transmission of data B, and the wireless relay device 103 ends the reception of data B. When the reception of data B is completed, the wireless relay device 103 starts transmission of the buffered data B to the wireless master device 101, and the wireless master device 101 receives the data B transmitted from the wireless relay device 103. To do.

  At time t95 after the elapse of time T from time t94, the wireless relay device 103 ends transmission of data B, and the wireless master device 101 ends reception of data B. Therefore, as shown in FIG. 9, when the wireless master device 101 transmits data A to the wireless slave device 102 and the wireless slave device 102 transmits data B to the wireless master device 101 via the wireless relay device 103. Requires a time 4T that is twice as long as when the wireless master device 101 directly transmits data A to the wireless slave device 102 and the wireless slave device 102 directly transmits data B to the wireless slave device 101.

  Next, the wireless master device 101 transmits data A to the wireless slave device 102 and the wireless slave device 102 transmits data B to the wireless master device 101 via the wireless relay device 100 of the present embodiment. Operations of base unit 101, wireless relay device 100, and wireless slave unit 102 will be described with reference to FIG.

  As described above, the wireless relay device 100 performs wireless communication with each of the wireless master device 101 and the wireless slave device 102 using different channels. Therefore, the wireless relay device 100 can perform wireless communication with the wireless master device 101 and the wireless slave device 102 simultaneously. Therefore, as shown in FIG. 10, at time t101, the wireless master device 101 starts transmitting data A to the wireless relay device 100, and the wireless slave device 102 transmits data B to the wireless relay device 100. Start.

  In the wireless relay device 100, the data A transmitted from the wireless master device 101 is received by the parent device-side interface unit 211 and input to the control unit 250 via the parent device MAC unit 212. The control unit 250 buffers the input data A in the data buffer unit 241. The data B transmitted from the wireless slave device 102 is received by the slave device side interface unit 221 and input to the control unit 250 via the slave device MAC unit 222. The control unit 250 buffers the input data B in the data buffer unit 241.

  Next, the control unit 250 determines whether or not the slave unit radio unit 220 is idle. Since the data B transmitted from the wireless slave unit 102 is received, the slave unit wireless unit 220 is not in an idle state. Therefore, the control unit 250 waits for transmission of the buffered data A to the wireless slave device 102. Further, the control unit 250 determines whether or not the base unit radio unit 210 is empty. Since the data A transmitted from the wireless master device 101 is received, the wireless device for master device 210 is not in an empty state. Therefore, the control unit 250 waits for transmission of the buffered data B to the wireless master device 101.

  At time t102 after the elapse of time T from time t101, the wireless master device 101 ends transmission of data A, and the parent device side interface unit 211 ends reception of data A. The wireless slave device 102 ends the transmission of the data B, and the slave device side interface unit 221 ends the reception of the data B.

  When the reception of data A is completed, control unit 250 determines whether or not slave unit radio unit 220 is idle. Since reception of the data B has been completed, the slave radio unit 220 is in an empty state. When reception of data B is completed, control unit 250 determines whether or not base unit radio unit 210 is idle. Since reception of data A has been completed, base unit radio section 210 is idle.

  Since the slave unit wireless unit 220 is empty, the control unit 250 instructs the slave unit MAC unit 222 to transmit the buffered data A to the wireless slave unit 102. Further, since the base unit radio unit 210 is empty, the control unit 250 instructs the base unit MAC unit 212 to transmit the buffered data B to the radio base unit 101.

  In response to the instruction from the control unit 250, the slave unit MAC unit 222 starts transmission of the buffered data A to the wireless slave unit 102 via the slave unit side interface unit 221. Receives the data A transmitted from the wireless relay device 100. In response to the instruction from the control unit 250, the base unit MAC unit 212 starts transmission of the buffered data B to the wireless base unit 101 via the base unit side interface unit 211, and The device 101 receives the data B transmitted from the wireless relay device 100.

  At time t103 after time T has elapsed from time t102, slave unit MAC unit 222 ends transmission of data A, and wireless slave unit 102 ends reception of data A. Further, base unit MAC section 212 ends transmission of data B, and wireless base unit 101 ends reception of data B. Therefore, as shown in FIG. 10, when the wireless master device 101 transmits data A to the wireless slave device 102 and the wireless slave device 102 transmits data B to the wireless master device 101 via the wireless relay device 100. Is equivalent to the time 2T when the wireless master device 101 directly transmits data A to the wireless slave device 102 and the wireless slave device 102 directly transmits data B to the wireless slave device 101. An increase in time required for data transmission between the master unit 101 and the wireless slave unit 102 is suppressed.

  As described above, according to the present embodiment, the wireless relay device 100 uses the wireless base unit 210 that performs wireless communication with the wireless base unit 101 and the wireless slave unit 102 using a channel different from the base unit wireless unit 210. A wireless unit 220 for a slave unit that performs wireless communication with the wireless unit 210. When one of the wireless unit 210 for the base unit and the wireless unit 210 for the base unit receives data, the other wireless unit is in an empty state. For example, data received by one radio unit is transmitted to the other radio unit.

  Therefore, since data can be transmitted and received simultaneously with the wireless master device 101 and the wireless slave device 102, the time required for data transmission between the wireless master device 101 and the wireless slave device 102 due to data relay is increased. Can be suppressed.

  In the present embodiment, the example of performing wireless communication using a wireless LAN in the 5 GHz band and the 2.4 GHz band has been described, but the present invention is not limited to these frequency bands.

  In the present embodiment, the wireless relay device 100 performs wireless communication with the wireless master device 101 via a wireless LAN in the 5 GHz band, and performs wireless communication with the wireless slave device 102 via the wireless LAN in the 2.4 GHz band. However, the present invention is not limited to this. The wireless relay device 100 may perform wireless communication with the wireless master device 101 through a wireless LAN in the 2.4 GHz band and wireless communication with the wireless slave device 102 through a wireless LAN in the 5 GHz band.

  In the present embodiment, the wireless relay device 100 has been described using an example in which wireless communication is performed with the wireless master device 101 and the wireless slave device 102 using wireless LANs of different frequency bands. However, the wireless relay device 100 is not limited thereto. is not. The wireless relay device 100 may perform wireless communication with the wireless master device 101 and the wireless slave device 102 using different channels of wireless LAN in the same frequency band. In this case, the same effect can be obtained by configuring the base unit side interface unit 211 and the slave unit side interface unit 221 to correspond to the frequency bands of the channels used for wireless communication.

  A part or all of the above-described embodiment can be described as in the following supplementary notes, but is not limited thereto.

(Appendix 1)
A first wireless unit that performs wireless communication with the wireless parent device via the first channel;
A second wireless unit that performs wireless communication with the wireless slave device via the second channel;
A control unit that causes the first and second wireless units to perform wireless communication in parallel, and to transmit and receive data between the wireless master device and the wireless slave device; A wireless relay device.

(Appendix 2)
In the wireless relay device according to attachment 1,
The control unit causes the first radio unit to acquire setting information necessary for radio communication with the radio base unit from the radio base unit, and causes the second radio unit to transmit information to the first radio unit. A wireless relay device that transmits the acquired setting information to the wireless slave device.

(Appendix 3)
A wireless relay device having a first wireless unit that performs wireless communication with a wireless master device via a first channel, and a second wireless unit that performs wireless communication with a wireless slave device via a second channel A control method,
Control of a radio relay apparatus characterized in that the first and second radio units perform radio communication in parallel and send and receive data between the radio master unit and the radio slave unit Method.

(Appendix 4)
In the method for controlling the wireless relay device according to attachment 3,
The first wireless unit causes the wireless base unit to acquire setting information necessary for wireless communication with the wireless base unit, and the second wireless unit acquires the setting information acquired by the first wireless unit. Is transmitted to the wireless slave unit. A method for controlling a wireless relay device, comprising:

DESCRIPTION OF SYMBOLS 10 Communication system 100 Wireless relay apparatus 101 Radio | wireless parent machine 102 Radio | wireless child machine 210 Master unit radio | wireless part 211 Parent | base station side interface part 212 Master unit MAC part 220 Slave unit radio | wireless part 221 Slave unit side interface part 222 Slave unit MAC Part 230 Flash ROM
240 memory 241 data buffer unit 250 control unit

In order to achieve the above object, the wireless relay device of the present invention provides:
A first wireless unit that includes a MAC unit for a parent device that controls wireless communication with the wireless parent device, and performs wireless communication with the wireless parent device via a first channel;
A slave unit MAC unit that controls wireless communication with the wireless slave unit , a second wireless unit that performs wireless communication with the wireless slave unit via a second channel;
A control unit configured to cause the first and second wireless units to perform wireless communication in parallel and to transmit and receive data between the wireless master device and the wireless slave device;

In order to achieve the above object, a method for controlling a wireless relay device of the present invention includes:
A master unit MAC unit for controlling radio communication with a radio base unit is provided, and radio communication between a radio unit and a first radio unit that performs radio communication with the radio base unit via a first channel is controlled. A wireless relay device control method , comprising: a slave MAC unit, and a second wireless unit that performs wireless communication with the wireless slave device via a second channel,
The first wireless unit and the second wireless unit perform wireless communication in parallel, and transmit and receive data between the wireless master device and the wireless slave device.

Claims (4)

A first wireless unit that performs wireless communication with the wireless parent device via the first channel;
A second wireless unit that performs wireless communication with the wireless slave device via the second channel;
A control unit that causes the first and second wireless units to perform wireless communication in parallel, and to transmit and receive data between the wireless master device and the wireless slave device; A wireless relay device. The wireless relay device according to claim 1,
The control unit causes the first radio unit to acquire setting information necessary for radio communication with the radio base unit from the radio base unit, and causes the second radio unit to transmit information to the first radio unit. A wireless relay device that transmits the acquired setting information to the wireless slave device. A wireless relay device having a first wireless unit that performs wireless communication with a wireless master device via a first channel, and a second wireless unit that performs wireless communication with a wireless slave device via a second channel A control method,
Control of a radio relay apparatus characterized in that the first and second radio units perform radio communication in parallel and send and receive data between the radio master unit and the radio slave unit Method. In the control method of the radio relay device according to claim 3,
The first wireless unit causes the wireless base unit to acquire setting information necessary for wireless communication with the wireless base unit, and the second wireless unit acquires the setting information acquired by the first wireless unit. Is transmitted to the wireless slave unit. A method for controlling a wireless relay device, comprising:

Images