JP7445735B2 - Wireless LAN repeater and wireless LAN system - Google Patents

Description

The present invention relates to a wireless LAN repeater, a wireless LAN router, and a wireless LAN system equipped with a wireless LAN frequency band switching method.
Note that the wireless LAN router in the present invention refers to a wireless LAN base device, and also includes a wireless LAN access point that does not have a router function.

Regarding a wireless communication device equipped with a wireless LAN frequency band switching method, the following invention is disclosed.

For example, Patent Document 1 (Japanese Unexamined Patent Publication No. 2003-333640) discloses that in a wireless communication device compatible with multiple frequency bands such as a 5.2 GHz band and a 2.4 GHz band, a control unit of the wireless communication device As a method to determine whether the device is indoors or outdoors and to legally select a communication frequency band, the display terminal that forms the wireless communication system with the base device has directional sensitivity in one direction. A high detection antenna is installed so that its direction of high directional sensitivity faces in the opposite direction to the direction of gravity, the detection antenna emits a detection transmission signal, and the reflected waves from the reflected object are used for detection. It is received by an antenna and processed by a processing circuit. A method is disclosed in which the control unit (CPU) determines whether the display terminal is indoors or not based on the processing result and selects a communication frequency band.

In addition, Patent Document 2 (Japanese Unexamined Patent Application Publication No. 2015-192315) describes a wireless communication device with a relay function that uses a frequency band prohibited by law based on a small and simple configuration and reliable determination means. As a wireless communication device that performs communication at an appropriate frequency without using the a communication method determining unit that determines possible communication conditions and outputs the determination results; A wireless communication device is disclosed that includes a restriction section that instructs permission or disapproval of use of a band.

Furthermore, Patent Document 3 (Japanese Unexamined Patent Publication No. 2004-336351) describes a warning method when using a wireless LAN device that can transmit and receive even in a frequency band that is prohibited under certain conditions. Detects whether a wireless LAN device is trying to start communication using a frequency band whose use is prohibited, and if it is trying to start communication using a frequency band, under certain conditions, A method of warning when using a wireless LAN device is disclosed, which is characterized by issuing a warning indicating that the use of a frequency band is prohibited.

Furthermore, Patent Document 4 (International Publication No. 2012/137908) provides a function for forming a wireless service area by selecting a wireless communication method that adopts a frequency band based on location information from among different frequency bands. A wireless communication device equipped with a first wireless communication unit that connects to an external network, and that is connectable to an external network using either a first frequency band or a second frequency band that are different from each other. a second wireless communication unit that forms a service area; a location information acquisition unit that acquires location information of its own device; A wireless communication device is disclosed that includes a selection unit for making a selection.

Japanese Patent Application Publication No. 2003-333640 Japanese Patent Application Publication No. 2015-192315 Japanese Patent Application Publication No. 2004-336351 International Publication No. 2012/137908

In recent years, 2.4 GHz and 5 GHz bands have become available for wireless LAN, and in the 5 GHz band, W52 in the 5.2 GHz band, W53 in the 5.3 GHz band, and W56 in the 5.6 GHz band have become available. There is. Along with this, 2.4G, W52, W53, W56 is also available for routers, repeaters (communication devices with a relay function that connects routers and hosts), and hosts such as computers that are equipped with wireless LAN communication functions. A wide range of devices are available that are capable of communicating on all frequencies.
However, the frequency of the 5.2 GHz band overlaps with the feeder link of the satellite communication system, and the frequency of the 5.3 GHz band and 5.6 GHz band overlaps or is adjacent to that of the weather radar, so it is difficult to use home wireless In a LAN, usage restrictions are imposed on each frequency band.

Recently, efforts to use the 6 GHz band frequency for wireless LAN have begun worldwide. In the United States, U-NII 5 (5.925-6.425 GHz) and U-NII 7 (6.525-6.875 GHz) are already equipped with Standard Power AP (standard power access point, capable of communicating outdoors) and Use as a Low Power AP (low power access point, limited to indoor communication) is permitted. Furthermore, in U-NII 6 (6.425-6.525 GHz) and U-NII 8 (6.875-7.125 GHz), use is permitted only for Low Power APs. In addition, studies are also underway on Very Low Power, which has even lower output.
In Japan, a new ministerial ordinance regarding the introduction of 6GHz band wireless LAN was promulgated and enforced on September 2, 2022, and a new frequency band (5925MHz to 6425MHz) in the 6GHz band was defined as a low-power data communication system. According to the new ministerial ordinance, wireless stations that can only be used indoors must be LPI (Low Power Indoor) with an equivalent isotropic radiated power (EIRP) of up to 200 mW, and wireless stations that can be used indoors or outdoors must be VLP (Very) with an EIRP of up to 25 mW. Low Power) is specified as the target.
Table 1 below shows the restrictions for each frequency band as of September 2022.

As described in Table 1, the 2.4 GHz band and W56 band can be used indoors and outdoors, but the W52 band and W53 band can only be used indoors.
In addition, DFS (Dynamic Frequency Selection) is a system that allows wireless LAN equipment to detect radar radio waves, stop transmitting when detected (and switch to other channels) in order to avoid adverse effects on C-band radar, which is mainly used for weather observation. (movement). It is mandatory to install the DFS function in the W53 band and W56 band.
For the 6GHz band, VLP can be used indoors and outdoors, while LPI can only be used indoors.

Recently, as shown in Figure 16, a method of using wireless LAN is to place a router in the main house, a repeater in the outhouse, and communicate via wireless LAN between the wireless LAN router and the wireless LAN repeater. Furthermore, the use of wireless LAN communication between a wireless LAN repeater and a host located indoors in an outhouse has begun.
In this case, since the connection between the wireless LAN router and the wireless LAN repeater corresponds to an outdoor communication path, communication must be performed using a 2.4 GHz band, 5 GHz W56 band, or 6 GHz band VLP. However, since conventional wireless LAN routers and wireless LAN repeaters are technically capable of communicating with 5GHz W52 band, W53 band, and 6GHz band LPI, outdoor communication paths between wireless LAN routers and wireless LAN repeaters are not possible. It is thought that there may be cases in which connections are made via the 5GHz W52 band, W53 band, or 6GHz band LPI, resulting in violation of laws and regulations and having an adverse effect on radar, etc.
In addition, when starting up, if outdoor use is permitted by law and W56, which has a large communication capacity, is communicating between the router and repeater, if radar radio waves are detected by the wireless LAN router, the wireless Depending on the control algorithm of the LAN router, the radio frequency band may be switched to W52 or W53, which is prohibited for outdoor use.
In addition, even in wireless LAN repeaters that have the function of switching communication with the host from W56 to the 2.4 GHz band when radar radio waves are detected, information that radar radio waves have been detected is transmitted to the wireless LAN router. Therefore, if the wireless LAN router cannot detect radar radio waves, there is a possibility that communication between the wireless LAN router and the wireless LAN repeater may remain in the W56 band.

In the invention described in Patent Document 1, a display terminal that forms a wireless communication system with a base device is equipped with a detector for determining whether the device is indoors or outdoors. However, the detector described in Patent Document 1 detects whether the device is indoors or outdoors, and the wireless LAN repeater as depicted in FIG. If the space between the LAN router and wireless LAN repeater is outdoors, it will be determined that the space is indoors.

Further, in the wireless communication device (wireless LAN repeater) of the invention described in Patent Document 2, when the first communication unit connected to the router is using the W52 band or W53 band, that is, when the router and the repeater The second communication unit connected to the host is permitted to use the W52 band and W53 band only when it is determined that the communication route between the host and the host is an indoor communication route. However, as shown in Figure 6, if the wireless LAN repeater and host are indoors and the communication path between the wireless LAN router and the wireless LAN repeater is outdoor, then the wireless LAN router and the wireless Even if the 2.4 GHz or W56 band is being used between the LAN repeaters, the W52 band or W53 band can be used between the wireless LAN repeater and the host. Therefore, the control algorithm of the invention described in Patent Document 2 is not appropriate for the usage as depicted in FIG.

Further, the invention described in Patent Document 3 is an invention of an information communication device equipped with a wireless LAN, and there is no description regarding communication with a host, which is an essential function in a wireless LAN repeater. Since there is no description of the case where this is detected, this does not provide a solution to the problem that the present invention aims to solve.

In addition, in the invention described in Patent Document 4, position information of the own device is acquired, and when the location of the own device is a position where there is a high possibility that it is being used outdoors, the first frequency band and the second frequency Select a wireless communication method that uses a frequency band that is approved for outdoor use. However, in the case of the invention described in Patent Document 4, only the own device detects location information. Therefore, as shown in FIG. 6, the wireless LAN repeater and host are indoors, and the wireless LAN If the connection between the wireless LAN router and the wireless LAN repeater is outdoors, there is a possibility that the user will make a mistake in determining the wireless communication method that can be used.
Further, Patent Document 4 also does not describe the case where radar radio waves are detected.

The main object of the present invention is to provide a wireless LAN repeater that is installed in an outbuilding and connected via an outdoor communication path to a wireless LAN router placed in the main building, etc., and is used outdoors as required by law. A wireless LAN repeater, a wireless LAN router, and a wireless LAN system equipped with a wireless LAN channel switching method that uses available radio wave bands and preferentially uses frequency bands with higher communication capacity. It is about providing.
A further object of the present invention is to detect radar radio waves in the W56 band in a wireless LAN router connected to a wireless LAN repeater via an outdoor communication path, and to connect the wireless LAN router to the wireless LAN repeater. If connection on a channel becomes impossible, reconnect with a frequency band with a higher communication capacity as possible, and if it becomes possible to connect with a wireless LAN router on a frequency band with a higher communication capacity, An object of the present invention is to provide a wireless LAN repeater, a wireless LAN router, and a wireless LAN system that are equipped with a wireless LAN channel switching method that can return to the frequency band as quickly as possible.

(1)
A wireless LAN repeater according to one aspect is connected to a wireless LAN router via an outdoor communication path, and has an outhouse mode used when connected to a first host via an indoor communication path. It is a repeater and includes a wireless communication circuit that can communicate in the 2.4 GHz band, a wireless communication circuit that can communicate in the 5 GHz band, and a wireless communication circuit that can communicate in the 6 GHz band, and when starting the outhouse mode, Select the optimal communication environment from the connectable frequency bands of 6 GHz band VLP (Very Low Power), 5 GHz W56 band, and 2.4 GHz band, connect to the wireless LAN router, and connect to the first host. According to the request of the first host, connection is made to the host using a 2.4 GHz band, a 5 GHz band, and/or a 6 GHz band.
Note that when the connection between the wireless LAN repeater and the first host is in the 6 GHz band, the connection may be made using a 6 GHz band LPI (Low Power Indoor).
Further, when connecting to a wireless LAN router and a host at the same time in the same frequency band in the 6 GHz band, 5 GHz band, or 2.4 GHz band, the connection is made using the same channel in each frequency band. Furthermore, connecting in the 2.4 GHz band, 5 GHz W56 band, and/or 6 GHz band means connecting in a frequency band selected from the group consisting of the 2.4 GHz band, 5 GHz W56 band, and 6 GHz band, and Including combinations.

If a wireless LAN router is placed in the main house and a wireless LAN repeater is placed in an outhouse separate from the main house, the wireless LAN repeater will be connected to the wireless LAN router via an outdoor communication path, so the 5GHz W52 band, Using W53 band or 6GHz band LPI is a violation of laws and regulations. However, the wireless LAN repeater according to one aspect uses only the 6 GHz band VLP, 5 GHz W56 band, or 2.4 GHz band that is permitted for outdoor communication for communication between the wireless LAN router and the wireless LAN repeater. Therefore, there is no possibility of affecting satellite communication systems, weather radar, telecommunications services (fixed satellites, etc.), and there is no violation of laws and regulations.

Further, in a wireless LAN repeater according to one aspect, an optimal communication environment is selected from among the 6 GHz band VLP, 5 GHz W56 band, and 2.4 GHz band to connect. Therefore, for example, when the distance between a wireless LAN router and a wireless LAN repeater is long, 6GHz band VLP has a wide frequency band but has a small EIRP of up to 25 mW. If the 5 GHz W56 band has a larger communication capacity than the 5 GHz W56 band, it is possible to select a communication environment with a larger communication capacity by selecting the 5 GHz W56 band.
In addition, if the wireless LAN repeater is equipped with two or more wireless communication circuits that can communicate in the 5 GHz band, the connection with the wireless LAN router will be in the W56 band in the 5 GHz band, and the connection with the first host will be made in the 5 GHz band. can also be set to W52 or W53.

(2)
A wireless LAN repeater according to a second aspect of the present invention is a wireless LAN repeater according to one aspect, which includes a wireless communication circuit capable of communicating in a 2.4 GHz band, a wireless communication circuit capable of communicating in a 5 GHz band, and a wireless communication circuit capable of communicating in a 6 GHz band. Each of the wireless communication circuits may be composed of one circuit.

In this case, the circuit scale of the wireless communication circuit can be suppressed.
In addition, when using multi-link operation (MLO) that can use multiple frequency bands at the same time when connecting with Wi-Fi 7, etc., which is expected to be put into practical use in the future, in order to start MLO smoothly, it is necessary to use a wireless LAN repeater and It is desirable to limit connection with the host in the 5 GHz band to W56.

(3)
A wireless LAN repeater according to a third aspect of the present invention is a wireless LAN repeater according to one aspect, which connects to the wireless LAN router using 6 GHz band VLP when connection with the wireless LAN router using 6 GHz band VLP is impossible. If you request that it be possible and it becomes possible to connect in the 6GHz band VLP, the most suitable communication will be established again from among the connectable frequency bands of the 6GHz band VLP, 5GHz W56 band, and 2.4GHz band. You may select an environment and connect to a wireless LAN router.

The wireless LAN repeater of the present invention connects to a host located indoors using a 6 GHz band LPI with a large communication capacity if the 6 GHz band can be used. However, if the wireless LAN repeater has a function that allows LPI/VLP settings for each connected terminal, the wireless LAN repeater can also be connected to the wireless LAN router using the 6 GHz band VLP.
In a wireless LAN repeater that has such a function, if the wireless LAN router does not allow connection in the 6GHz band VLP and connects in the 5GHzW56 band or 2.4GHz band, the wireless LAN repeater Send a connection request in 6GHz band VLP to the wireless LAN router, and if connection in 6GHz band VLP becomes possible, connectable frequency bands of 6GHz band VLP, 5GHz W56 band, and 2.4GHz band will be sent again. By selecting the optimal communication environment from among them and connecting to the wireless LAN router, if the communication environment of 6GHz band VLP is optimal, switch to 6GHz band VLP and connect the wireless LAN router and wireless LAN repeater. Communication capacity can be increased.

Note that even for wireless LAN repeaters that do not have a function that allows LPI/VLP settings for each connected terminal, if the host of the wireless LAN repeater does not have a host that can communicate in the 6GHz band, it may be necessary to use the 6GHz band for connection with the host. If you do not need to use LPI, or if you want to increase the communication capacity between the wireless LAN repeater and the wireless LAN router by giving priority to the communication capacity between the wireless LAN repeater and the host, the wireless LAN repeater can be used wirelessly. A connection request using 6 GHz band VLP may be sent to the LAN router.
However, the fact that the wireless LAN router accepts a connection request using the 6 GHz band VLP is not a standard function of the wireless LAN router, but is a unique function. Therefore, in order for the wireless LAN router to accept a connection request using the 6 GHz band VLP and permit the connection using the 6 GHz band VLP, it is necessary to use a wireless LAN router equipped with an outhouse mode.

(4)
A wireless LAN repeater according to a fourth aspect of the present invention is a wireless LAN repeater according to one aspect, in which when a wireless LAN router is connected to a 5GHz W56 band and the connection in the 5GHz W56 band becomes impossible, the wireless LAN repeater If you try to connect on another channel and are unable to connect on another channel in the 5GHz W56 band, the most suitable communication environment will be selected from the connectable frequency bands of 6GHz band VLP and 2.4GHz band. You may also select one and connect it to a wireless LAN router.

When a wireless LAN repeater is connected to a wireless LAN router using a 5GHz W56 band channel, the wireless LAN router monitors radar radio waves, and if radar radio waves are detected, it connects to the connected 5GHz W56 band channel. , and informs the wireless LAN repeater that communication is possible in any one of the 6 GHz band VLP, another channel in the 5 GHz W56 band, and/or the 2.4 GHz band.
In this case, the wireless LAN repeater first attempts a connection using another channel in the 5 GHz W56 band, and if connection is possible, continues the connection using another channel.
On the other hand, if connection on another channel of the 5GHzW56 band is not possible, select the optimal communication environment from the connectable frequency bands of the 6GHz band VLP and 2.4GHz band and connect the wireless LAN router. Connect to.
The reason for prioritizing connection on another channel in the 5GHz W56 band is that the processing amount of the wireless LAN repeater increases by returning to startup every time a radar radio wave is detected, and the connection with the first host increases. This is to avoid any effect on communication between the wireless LAN repeater and the first host due to connection changes or the like.

(5)
A wireless LAN repeater according to a fifth aspect of the present invention is a wireless LAN repeater according to one aspect, in which the wireless LAN repeater is connected to a wireless LAN router in the 5GHz W56 band, and connection in the 5GHz W56 band is no longer possible. In this case, in addition to connecting to the wireless LAN router using the 6GHz band VLP or the 2.4GHz band, we investigated the possibility of connection using another channel of the 5GHzW56 band, and it became possible to connect using another channel of the 5GHzW56 band. In this case, the most suitable communication environment may be selected again from among the connectable frequency bands of the 6 GHz VLP band, the 5 GHz W56 band, and the 2.4 GHz band to connect to the wireless LAN router.

In the wireless LAN repeater according to the fourth invention, the throughput of the wireless LAN repeater is increased by first trying to connect using another channel in the 5GHzW56 band, and if connection is possible, connecting using another channel. and the influence on communication between the wireless LAN repeater and the first host.
However, in this case, in order to connect on another channel, it is necessary to confirm that there is no radar signal for at least one minute. Therefore, the connection between the wireless LAN router and the wireless LAN repeater is stopped for at least one minute.
In order to avoid this one-minute communication stoppage, the wireless LAN repeater according to the fifth invention first connects to a wireless LAN router in the 6 GHz band VLP or 2.4 GHz band, and in parallel connects to another wireless LAN router in the 5 GHz W56 band. We investigate the possibility of connection on the channel, and if it becomes possible to connect on another channel in the 5GHzW56 band, we will try again to connect to a connectable frequency among the 6GHz band VLP, 5GHzW56 band, and 2.4GHz band. The most suitable communication environment is selected from among the bands and connected to the wireless LAN router.
Note that when connection via another channel in the 5 GHz W56 band becomes possible, the connection with the wireless LAN router may be switched to another channel in the 5 GHz W56 band.

(6)
A wireless LAN repeater according to a sixth aspect of the present invention is a wireless LAN repeater according to one aspect, which checks at predetermined time intervals whether connection with a wireless LAN router in a 6 GHz band VLP and a 5 GHz W56 band is possible; If any of the 6GHz band VLP and 5GHz W56 band becomes connectable from unreachable, the connection will be made again from among the connectable frequency bands of the 6GHz band VLP, 5GHz W56 band, and 2.4GHz band. Alternatively, the most suitable communication environment may be selected to connect to the wireless LAN router.

Even if the most suitable communication environment is selected and connected from the connectable frequency bands among the 6GHz band VLP, 5GHz W56 band, and 2.4GHz band at the time of startup, the 6GHz band VLP, and 5GHzW56 band may be changed from unconnectable to connectable.
For example, this may occur when a mobile device such as a smartphone that is connected to a wireless LAN router via 6 GHz band LPI goes out with the user, or when radar radio waves are interrupted depending on the time of day.
Therefore, check whether connection with the wireless LAN router is possible in the 6GHz band VLP and 5GHz W56 band, and if any of the 6GHz band VLP and 5GHz W56 band changes from unconnectable to connectable. , it is desirable to go back to the start of the outhouse mode, select the optimal communication environment, and reconnect.
Note that the predetermined time in this case is, for example, 30 minutes.

(7)
A wireless LAN repeater according to a seventh aspect of the present invention is a wireless LAN repeater that includes a plurality of SSIDs, the SSID for connection with the wireless LAN router corresponds to 6GHz band VLP, and the wireless LAN repeater according to one aspect is The SSID may correspond to 6 GHz band LPI.

In this case, the wireless LAN router connected via the outdoor communication path belongs to the SSID compatible with 6GHz band VLP, and the first host connected via the indoor communication path belongs to the SSID compatible with 6GHz band LPI. By doing so, it is possible to reliably avoid legal violations and maximize the communication capacity to the first host.

(8)
A wireless LAN router according to an eighth aspect of the present invention is connected to a wireless LAN repeater via an outdoor communication path, and has an outhouse mode used when connected to a second host via an indoor communication path. A wireless LAN router that includes one wireless communication circuit that can communicate in the 2.4 GHz band, one wireless communication circuit that can communicate in the 5 GHz band, one wireless communication circuit that can communicate in the 6 GHz band, and a wired WAN. and a network circuit connectable to a LAN, and one wireless communication circuit capable of communicating in the 6GHz band is selected from a 6GHz band VLP and a 6GHz band LPI for each connected terminal of the wireless LAN repeater and the second host. and is configured to enable communication.
However, if the wireless LAN router is a wireless LAN access point, the network circuit may not be provided.

In this case, if the wireless LAN router is set to the outhouse mode, for example, the wireless LAN repeater connected via the outdoor communication route will be connected via 6GHz band VLP, and the wireless LAN repeater connected via the indoor communication route will be connected to the wireless LAN repeater connected via the outdoor communication route. Since the wireless LAN repeater and the second host can be connected via 6 GHz band LPI, the maximum communication capacity can be provided to the wireless LAN repeater and the second host without violating laws and regulations.
Note that if the wireless LAN repeater also has an outhouse mode, you can receive a notification from the wireless LAN repeater that it is connected via an outdoor communication route, but generally the wireless LAN repeater It is unknown whether the connection is via an outdoor communication route. In this case, when starting up the wireless LAN router, the MAC address of the connected terminal via the outdoor communication route may be input.
Further, since it is possible to communicate in both the 6 GHz band VLP and the 6 GHz band LPI using one wireless communication circuit capable of communicating in the 6 GHz band, the circuit scale of the wireless LAN router can be suppressed.
Note that wireless LAN routers are also equipped with two or more wireless communication circuits that can communicate in the 5GHz band, so that in 5GHz communication, W56 can connect to a wireless LAN repeater, and W52 can connect to a second host. Or it can be W53.

(9)
A wireless LAN router according to a ninth invention is the wireless LAN router according to the eighth invention, which includes a plurality of SSIDs, the SSID for connection with the wireless LAN repeater corresponds to 6GHz band VLP, and the second The SSID for connection with the host may correspond to 6 GHz band LPI.

In this case, the wireless LAN repeater connected via the outdoor communication path belongs to the SSID compatible with 6GHz band VLP, and the second host connected via the indoor communication path belongs to the SSID compatible with 6GHz band LPI. By doing so, it is possible to reliably avoid legal violations and maximize the communication capacity to the second host.

(10)
A wireless LAN router according to a tenth invention identifies the second host and the wireless LAN repeater by receiving identification information from the wireless LAN repeater in the wireless LAN router according to the eighth invention. It's okay.

Both a second host and a wireless LAN repeater can be connected as connection terminals to a wireless LAN router, but from the perspective of the wireless LAN router, which connection terminal is the second host and which connection terminal is the second host? In some cases, it may not be possible to identify whether it is a wireless LAN repeater.
According to the tenth invention, the wireless LAN repeater transmits identification information indicating that it is a wireless LAN repeater compatible with outhouse mode, and the wireless LAN router receives this identification information to determine which connection It is possible to identify whether the terminal is a wireless LAN repeater.
Therefore, even if the user does not make settings to identify the wireless LAN repeater in advance (settings to register the MAC address, IP address, SSID, etc. of the wireless LAN repeater), which connected terminals can communicate with each other in accordance with the indoor communication route. It is possible to identify whether the connected terminal is a second host that can communicate with the outdoor communication route, or which connected terminal is a wireless LAN repeater that needs to communicate with the outdoor communication route, so it is possible to identify the appropriate communication method. can be selected automatically.
Note that the wireless LAN repeater according to any one of the aspects to the seventh invention may be capable of transmitting this identification information, and the wireless LAN router according to any of the eighth to eleventh inventions may be capable of transmitting this identification information. The second host and the wireless LAN repeater may be able to be identified by receiving the information.

(11)
A wireless LAN router according to an eleventh invention is connected to a wireless LAN repeater via an outdoor communication path, and has an outhouse mode used when connected to a second host via an indoor communication path. A wireless LAN router that connects to a wired WAN and LAN with a wireless communication circuit that can communicate in the 2.4 GHz band, a wireless communication circuit that can communicate in the 5 GHz band, and a wireless communication circuit that can communicate in the 6 GHz band. A wireless communication circuit capable of communicating in the 6GHz band is equipped with a network circuit capable of communicating in the 6GHz band, and is capable of communicating in the 6GHz band with respect to all connected terminals of the wireless LAN repeater and the second host. If the wireless LAN repeater requests that the wireless LAN router connect to the second host using the 6GHz band LPI, and the wireless LAN router connects to the second host using the 6GHz band LPI. If not, switch the 6GHz band communication from LPI to VLP.

A wireless LAN router normally communicates with a second host using a 6 GHz band LPI. In this case, a wireless LAN router that is configured to be able to communicate with only one of the 6GHz band VLP and 6GHz band LPI for all connected terminals of the wireless LAN repeater and the second host is It is not possible to connect to a wireless LAN repeater connected via the communication path at 6 GHz.
However, if the wireless LAN router is not connected to the second host using 6GHz LPI, for example because the second host does not have a wireless communication circuit that can communicate in the 6GHz band, the wireless LAN router's By switching communication in the 6 GHz band from LPI to VLP, the communication capacity with the wireless LAN repeater can be increased.
Furthermore, in a wireless LAN router configured to be able to communicate with only one of the 6GHz band VLP and 6GHz band LPI for all connected terminals of the wireless LAN repeater and the second host, the wireless LAN If you want to give priority to increasing the communication capacity between the wireless LAN router and the wireless LAN repeater, all 6 GHz band communication, including communication with the second host, may be set to VLP.
Note that if the wireless LAN repeater also has an outhouse mode, you can receive a notification from the wireless LAN repeater that it is connected via an outdoor communication route, but generally the wireless LAN repeater It is unknown whether the connection is via an outdoor communication route. In this case, when starting up the wireless LAN router, the MAC address of the terminal via the outdoor communication route may be input.

(12)
A wireless LAN system according to a twelfth invention includes a wireless LAN router and a second host according to any one of the eighth to eleventh inventions, which are arranged in a main house, and a second host, which is arranged in an outhouse. a wireless LAN repeater according to any one of the inventions in item 7 and a first host, and the wireless LAN router and the wireless LAN repeater are both set to an outhouse mode and connected via an outdoor communication path. At the same time, the wireless LAN router is connected to the second host through an indoor communication path, and the wireless LAN repeater is connected to the first host through an indoor communication path.

If the wireless LAN router or wireless LAN repeater has an outhouse mode, setting the wireless LAN router or wireless LAN repeater to the outhouse mode will eliminate the possibility of affecting the satellite communication system and weather radar, and comply with laws and regulations. A communication system with no violations and maximum communication capacity can be configured.
In addition, as depicted in Figure 16, the main house and outhouse are generally used when a single residence consists of two or more independent buildings, the main building of which corresponds to the main house. Smaller buildings correspond to outbuildings. However, in this specification, among two or more independent buildings, the building where the wireless LAN router is located is the main building, regardless of the scale of the building.

However, if both the wireless LAN router and the wireless LAN repeater have an outhouse mode, the following effects can be obtained by setting both the wireless LAN router and the wireless LAN repeater to the outhouse mode. Obtainable.
1) When the wireless LAN router and wireless LAN repeater are communicating in the 5GHzW56 band or the 2.4GHz band, the wireless LAN repeater sends a connection request in the 6GHz band VLP to the wireless LAN router, and the wireless LAN Upon receiving this connection request, the wireless LAN router enables connection using 6GHz band VLP in cases where the wireless LAN router is capable of LPI/VLP connection for each terminal, or when there are no other terminals to connect using 6GHz LPI. can do.
2) Identification information indicating that the wireless LAN repeater is connected via an outdoor communication path can be sent from the wireless LAN repeater to the wireless LAN router, and the wireless LAN router is connected to the wireless LAN repeater. On the other hand, since communication is not permitted in the 6 GHz band LPI, 5 GHz W52 band, and W53 band where communication via outdoor communication paths is not permitted, legal violations can be more reliably eliminated.
Note that 1) and 2) above are not standard functions of wireless LAN systems, but are unique functions.

(13)
The wireless LAN system according to a thirteenth invention is the wireless LAN system according to the twelfth invention, wherein the wireless LAN router and the wireless LAN repeater each have a plurality of SSIDs, and the wireless LAN router and the second host each have a plurality of SSIDs. The SSID for the connection between the wireless LAN repeater and the first host is the same SSID, and the SSID for the connection between the wireless LAN router and the wireless LAN repeater is different from the same SSID above. It's okay.

In this case, the same SSID is set for the first host and the second host, so even if the host (for example, a smartphone) used in the main house moves to the detached house, the wireless LAN connection can be maintained as is. Can be continued. Also, since the SSID for the connection between a wireless LAN router and a wireless LAN repeater and the connection between a wireless LAN router or wireless LAN repeater and a host are different, the connection between a wireless LAN router and a wireless LAN repeater can be made outdoors. The connection between the wireless LAN router or the wireless LAN repeater and the host can be made compatible with the optimal communication (for example, VLP) for indoor communication (for example, LPI).

(14)
A wireless LAN system according to a fourteenth invention is a wireless LAN system according to the twelfth invention, wherein the 5 GHz band wireless communication circuit of the wireless LAN repeater has a radar radio wave detection circuit, and the wireless LAN repeater has a 5 GHz W56 band wireless communication circuit. When a radar radio wave is detected, the wireless LAN repeater may transmit the radar radio wave detection information to the wireless LAN router, and the wireless LAN router may determine that the radar radio wave has been detected.

In the wireless LAN system according to the twelfth invention, the wireless LAN router may be placed in a location away from the outer wall, such as in the center of the main house, and the wireless LAN repeater may be placed near the outer wall of the outbuilding. In such a case, the radar radio wave detection circuit of the wireless LAN router does not detect radar radio waves, but the radar radio wave detection circuit of the wireless LAN repeater may detect radar radio waves.
In the wireless LAN system according to the fourteenth invention, when the wireless LAN repeater detects radar radio waves in the 5GHzW56 band, the wireless LAN repeater transmits the radar radio wave detection information to the wireless LAN router. When a radar radio wave arrives, a wireless LAN router can reliably stop using that channel.
Note that this radar radio wave detection information transmission function is also not a standard function of the wireless LAN system, but is a unique function.

(15)
A wireless LAN system according to a fifteenth invention includes a wireless LAN router and a second wireless LAN repeater arranged in a main house, and a first wireless LAN system according to any one of the seventh inventions arranged in an outhouse. a wireless LAN repeater and a first host, the second wireless LAN repeater and the wireless LAN router are connected by an indoor communication path, and the first wireless LAN repeater is set to an outhouse mode. , is connected to the second wireless LAN repeater via an outdoor communication path, and is connected to the first host via an indoor communication path.

In this case, by providing the wireless LAN router and the second wireless LAN repeater in the main building, it becomes possible to communicate over a wider range and with a larger number of hosts located within the same main building.

(16)
A wireless LAN system according to a sixteenth invention includes a wireless LAN router according to any one of the eighth to eleventh inventions arranged in a main house, and a wireless LAN system according to one of the seventh inventions arranged in an outhouse. a first wireless LAN repeater, a third wireless LAN repeater, and a first host, and the wireless LAN router and the first wireless LAN repeater are set to an outhouse mode and The third wireless LAN repeater is connected to the first wireless LAN repeater via an indoor communication path, and is connected to the first host via an indoor communication path.

In this case, by providing the first wireless LAN repeater and the third wireless LAN repeater in the outhouse, it becomes possible to communicate over a wider range and with a larger number of hosts located within the same outhouse.

(17)
A wireless LAN system according to a seventeenth invention includes a wireless LAN router according to any one of the eighth to eleventh inventions arranged in a main house, and one of the wireless LAN routers according to one of the seventh inventions arranged in a first outhouse. A fourth wireless LAN repeater according to the invention, and a first wireless LAN repeater and a first host according to any one of the aspects to the seventh invention, which are arranged in the second outhouse. The wireless LAN router and the fourth wireless LAN repeater are set to the outhouse mode and are connected via the outdoor communication path, the first wireless LAN repeater is set to the outhouse mode, and the fourth wireless LAN repeater is set to the outhouse mode. It is connected to the LAN repeater via an outdoor communication path, and is connected to the first host via an indoor communication path.

In this case, the wireless LAN router according to any one of the eighth to eleventh inventions is placed in the main house, and from one aspect the first wireless LAN repeater according to any one of the seventh inventions is placed in the first outhouse. and further, from one aspect, by arranging the fourth wireless LAN repeater according to any one of the seventh inventions in the second outbuilding, hosts in three mutually independent buildings are connected to one router. be able to.

1 is a schematic configuration diagram of a wireless LAN system including a wireless LAN router, a wireless LAN repeater, and a host. FIG. 2 is a schematic block diagram of a wireless LAN repeater according to the first embodiment. 1 is an example of a schematic flowchart showing an operation when starting up a wireless LAN repeater according to the first embodiment. It is the 1st modification of the typical flowchart which shows the operation|movement at the time of starting up the repeater for wireless LAN of 1st Embodiment. This is a second modified example of the schematic flowchart showing the operation when starting up the wireless LAN repeater in the first embodiment. 2 is an example of a schematic flowchart showing an operation when checking wireless LAN repeater reconnection in the first embodiment; FIG. FIG. 2 is a schematic block diagram of a wireless LAN router according to a second embodiment. 12 is an example of a schematic flowchart showing operations when starting up a wireless LAN router according to the second embodiment. It is a modification of the typical flowchart which shows the operation|movement at the time of starting up the wireless LAN router of 2nd Embodiment. 2 is a schematic flowchart showing the operation of the wireless LAN system when switching from 6 GHz band LPI to 6 GHz band VLP. 1 is an example of a schematic flowchart showing the operation of a wireless LAN system when radar radio waves are detected. This is another example of a schematic flowchart showing the operation of the wireless LAN system when radar radio waves are detected. FIG. 3 is a schematic configuration diagram of a wireless LAN system according to a third embodiment. FIG. 3 is a schematic configuration diagram of a wireless LAN system according to a fourth embodiment. FIG. 3 is a schematic configuration diagram of a wireless LAN system according to a fifth embodiment. FIG. 2 is a schematic explanatory diagram of how to use a wireless LAN in which a wireless LAN router is placed in the main house and a wireless LAN repeater is placed in an outhouse.

Embodiments of the present invention will be described below with reference to the drawings. In the following description, the same parts are given the same reference numerals. In addition, when the symbols are the same, their names and functions are also the same. Therefore, detailed description thereof will not be repeated.

[Wireless LAN system 1000]
FIG. 1 is a schematic diagram of a wireless LAN system 1000 including a wireless LAN router 200, a wireless LAN repeater 100, and hosts 300 and 300a. In FIG. 1, the wireless LAN router 200 is located in a first building (hereinafter referred to as the main building 400), and the wireless LAN repeater 100 is located in a second building (hereinafter referred to as the outhouse 500). In this embodiment, the main house 400 is equipped with an optical line ONU and the like and has an environment in which wired Internet connection is possible, and the outhouse 500 does not have a wired Internet environment. The first host 300 in the outhouse 500 cannot directly communicate with the wireless LAN router 200 in the main house 400, or even if it can connect, the radio waves are weak and the connection is unstable, making it difficult to obtain sufficient communication speed. . Note that the hosts 300 and 300a are, for example, personal computers equipped with a wireless LAN, printers, smartphones, and the like.
Since the wireless LAN router 200 and the wireless LAN repeater 100 are located in different buildings, communication is performed via the outdoor communication path 600, and the wireless LAN router 200 and the second host 330a, Since the wireless LAN repeater 100 and the first host 300 are located inside the same building, communication is performed via the indoor communication path 700.

When using the 6 GHz band frequency for wireless LAN, indoors an LPI with an equivalent isotropic radiated power (EIRP) of up to 200 mW and a VLP with an EIRP of up to 25 mW can be used, but outdoors a VLP with an EIRP of up to 25 mW can be used. can only be used.
On the other hand, in the 5 GHz band, only the W56 band can be used outdoors, and there is a regulation that requires the user to move to another channel if radar waves are detected.
The wireless LAN repeater 100 and wireless LAN router 200 that constitute this wireless LAN system 1000 ensure compliance with the regulations based on the above laws and regulations, and the wireless LAN router 100 and the wireless LAN repeater 100, as well as the This aims to maximize the communication capacity (speed) between the repeater 100 and the first host 300.

[Wireless LAN repeater 100 of the first embodiment]
FIG. 2 is a schematic block diagram of the wireless LAN repeater 100 according to the first embodiment.
As shown in FIG. 2, the wireless LAN repeater 100 includes a 2.4 GHz band wireless communication circuit 10, a 5 GHz band wireless communication circuit 20, a 6 GHz band wireless communication circuit 30, a control circuit 40, and a data buffer 50. Further, the 2.4 GHz band wireless communication circuit 10, the 5 GHz band wireless communication circuit 20, and the 6 GHz band wireless communication circuit 30 each include antennas 11, 21, and 31. It is also possible to share an antenna between the 2.4 GHz band and the 5 GHz band by inserting an antenna switch (not shown) between the antenna and the wireless communication circuit. The 5 GHz band wireless communication circuit 20 includes a radar radio wave detection circuit 22.

The radar radio wave detection circuit 22 monitors radar radio waves in the 5 GHz W53 and W56 bands when the wireless LAN repeater 100 communicates with the first host 300, and when it detects radar radio waves, it monitors radar radio waves in the 5 GHz W53 and W56 bands. This is for the DFS function to move to other frequency bands.
Since the wireless LAN repeater 100 is connected to the wireless LAN router 200 via the outdoor communication path 600, it is considered that the radio waves transmitted by the wireless LAN repeater 100 are leaking outdoors. Therefore, for example, if the wireless LAN repeater 100 is connected to the wireless LAN router 200 via a 6 GHz band VLP and a radar radio wave in the 5 GHz W56 band arrives, the wireless LAN repeater 100 connects the first host 300 and the 5 GHz W56 band. Connecting via broadband may be a violation of laws and regulations. When the radar radio wave detection circuit 22 of the 5 GHz band wireless communication circuit 20 of the present invention detects radar radio waves, the wireless LAN repeater 100 performs communication with the host 300 during an unoccupied period on the channel where the radar radio waves were detected. By not communicating, the possibility of legal violations is prevented. Note that the non-occupancy period (NOP) is a period during which a channel becomes unusable when radar waves are detected, and is, for example, 30 minutes.

If there is one wireless communication circuit, only one channel can communicate in each of the 2.4 GHz band, 5 GHz band, and 6 GHz band. Therefore, for example, if communication (hereinafter also referred to as backhaul) between the wireless LAN router 200 and the wireless LAN repeater 100 is performed on one channel in the 2.4 GHz band, the wireless LAN router 200 and the host Communication with 300 can be done using the same channel as the backhaul in the 2.4GHz band, any channel in the 5GHz band, or any channel in the 6GHz band, but the communication in the 2.4GHz band is different from the backhaul. It is not possible to communicate on a channel. This is to limit the number of communication channels in each frequency band of the wireless LAN repeater 100 to one, and to simplify the circuit of the wireless LAN repeater 100. However, in the 5 GHz band, by providing two wireless communication circuits, it is also possible to use W56 for the backhaul and W52 or W53 for connection with the host.
The control circuit 40 controls each wireless communication circuit based on a flowchart described later, and also temporarily stores the information of the received packet in the data buffer 50, reconfigures it, and retransmits it to a predetermined destination.

(Flowchart of first embodiment)
3, FIG. 4, and FIG. 5 are schematic flowcharts showing the operation when starting up the wireless LAN repeater 100 according to the first embodiment. Among these, FIG. 3 is a flowchart when the wireless LAN repeater 100 can select LPI and VLP for each terminal (wireless LAN router 200 and first host 300) and communicate in 6 GHz band communication. . Furthermore, FIGS. 4 and 5 are flowcharts when the wireless LAN repeater 100 cannot communicate by selecting LPI and VLP for each terminal in 6 GHz band communication. When priority is given to connection to the first host 300 (when connected to the wireless LAN router 200 by VLP, connection is not made to the first host 300 by LPI), FIG. 300 via LPI, the wireless LAN router 200 is not connected via 6 GHz).
In addition, FIG. 6 shows a case where the wireless LAN repeater 100 is connected to the wireless LAN router 200 using a 6 GHz band VLP and a connection using a 5 GHz W56 band is possible, or when the wireless LAN repeater 100 is connected using a 5 GHz W56 band and a connection using a 6 GHz band VLP is possible. 12 is a flowchart for reselecting the optimal communication environment when connection becomes possible.
Note that as a method for selecting LPI and VLP for each terminal for communication, it is also possible to select LPI and VLP each time communication with the terminal is started, but for example, if the wireless LAN repeater 100 A plurality of SSIDs (Service Set Identifiers) may be provided, and a terminal that communicates using LPI and a terminal that connects using VLP may belong to different SSIDs.
The operation at startup of the wireless LAN repeater 100 will be described below based on each figure.

(Explanation of the flowchart in Figure 3)
FIG. 3 is a flowchart when the wireless LAN repeater 100 can select LPI and VLP for each terminal (wireless LAN router 200 and first host 300) and communicate in 6 GHz band communication.
At startup, the wireless LAN repeater 100 of the first embodiment first checks whether it can detect the 6 GHz band SSID from the wireless LAN router 200 (step S1).
If a 6 GHz band SSID is detected, it is checked whether it is possible to connect to the wireless LAN router 200 using the 6 GHz band VLP (step S2).
If it is possible to connect using the 6 GHz band VLP, it is further checked whether it is possible to connect using the 5 GHz W56 band (step S3).
If it is possible to connect to the wireless LAN router 200 using either the 6 GHz band VLP or the 5 GHz W56 band, select the optimal communication environment from the 6 GHz band VLP or the 5 GHz W56 band and connect to the wireless LAN router 200 (step S5). Note that the selection of the optimal communication environment is determined based on, for example, the size of communication capacity, error rate, etc.
In step S3, if the connection cannot be made in the 5GHzW56 band, it is confirmed whether or not to disconnect the wireless LAN router 200 in the 2.4GHz band (step S4).
If it is possible to connect to the wireless LAN router 200 using either the 6GHz band VLP or the 2.4GHz band, select the optimal communication environment between the 6GHz band VLP and the 2.4GHz band and connect to the wireless LAN router 200 (step S6).
In step S4, if connection is not possible in the 2.4 GHz band, connection is made with the wireless LAN router 200 in the 6 GHz band VLP (step S7).

When the connection with the wireless LAN router 200 is completed, the 6GHz band LPI, 5GHz band, and 2.4GHz band SSID are sent to the first host 300, and the first connection to the host 300 of Note that in the frequency band connected to the wireless LAN router 200, the connection with the wireless LAN router 200 and the connection with the first host 300 must be on the same channel.
In addition, when comparing the communication environment between 6GHz band VLP and 5GHz W56 band or 2.4GHz band, 6GHz band VLP with a wide frequency band should have the best communication environment, but 6GHz band VLP is EIRP. This is because the communication environment may be better in the 5GHzW56 band or the 2.4GHz band, depending on the distance between the wireless LAN router 200 and the wireless LAN repeater 100, the presence or absence of obstacles along the way, etc.

In step S2, if connection is not possible using the 6 GHz band VLP, the wireless LAN repeater 100 checks whether it is possible to connect to the wireless LAN router 200 using the 5 GHz W56 band (step S9).
If it is possible to connect using the 5 GHz W 56 band, it connects to the wireless LAN router 200 using the 5 GHz W 56 band (step S11).
In step S9, if connection is not possible in the 5GHzW56 band, it is checked whether connection is possible in the 2.4GHz band (step S10).
If it is possible to connect in the 2.4 GHz band, it connects to the wireless LAN router 200 in the 2.4 GHz band (step S12).
In step S10, if connection is not possible even in the 2.4 GHz band, the process returns to step S1 again. In this case, you may set a delay time until starting up again, a maximum number of repetitions when repeating starting up, or the like.

When the connection with the wireless LAN router 200 is completed, the 6GHz band LPI, 5GHz band, and 2.4GHz band SSID are sent to the first host 300, and the first connection to the host 300 of
After connecting with the first host 300, the wireless LAN repeater 100 may request the wireless LAN router 200 to change from 6 GHz band LPI to 6 GHz band VLP (or add 6 GHz band VLP) (step S14). .
If connection via 6GHz band VLP becomes possible, the process returns to step S3, selects the optimal communication environment among 6GHz band VLP, 5GHzW56 band, and 2.4GHz band, and reconnects to wireless LAN router 200. (Step S15).
This function is effective when the wireless LAN router 200 does not transmit the SSID of the 6 GHz band VLP even though it is possible to connect using the 6 GHz band VLP. However, since this function is not a standardized function of wireless LAN, the wireless LAN router 200 also needs to have an outhouse mode (unique function). This function will be explained again based on FIG. 10.

In step S1, if the 6GHz band SSID from the wireless LAN router 200 cannot be detected, check the connection in the 5GHzW56 band (step S16), and if the connection is possible in the 5GHzW56 band, connect in the 5GHzW56 band (step S18). . If the connection cannot be made in the 5GHzW56 band, the connection in the 2.4GHz band is confirmed (step S17), and if the connection can be made in the 2.4GHz band, the connection is made in the 2.4GHz band (step S19).
In step S17, if connection is not possible even in the 2.4 GHz band, the process returns to step S1 again. In this case, you may set a delay time until starting up again, a maximum number of repetitions when repeating starting up, or the like.
When the connection with the wireless LAN router 200 is completed, the 6GHz band LPI, 5GHz band, and 2.4GHz band SSID are sent to the first host 300, and the first connection to the host 300 of

(Explanation of the flowchart in Figure 4)
FIG. 4 shows a case where the wireless LAN repeater 100 cannot communicate by selecting LPI and VLP for each terminal (wireless LAN router 200 and first host 300) in 6 GHz band communication, and the wireless LAN router 200 (when connected to the wireless LAN router 200 by VLP, connection to the first host 300 is not made by LPI). Note that in FIG. 4, steps with the same numbers as in FIG. 3 indicate the same operations as in FIG.
In the flowchart of FIG. 4, after determining the connection method with the wireless LAN router 200 in S3 to S7, it is confirmed whether or not the wireless LAN router 200 is connected by 6GHz VLP (step S8a). If the wireless LAN router 200 is not connected to the wireless LAN router 200 by 6GHz VLP, the first host 300 is not connected to the first host 300 by 6GHz LPI (step S8c). The difference is in the connection (step S8b).
In step S8a, the fact that the wireless LAN repeater 100 is connected to the wireless LAN router 200 using 6GHz VLP means that the connection environment between the wireless LAN repeater 100 and the wireless LAN router 200 is optimal. Therefore, when downloading a large amount of data from the Internet, even if the connection between the wireless LAN repeater 100 and the first host 300 is set to 6GHz band VLP, the connection between the wireless LAN repeater 100 and the first host 300 may be changed. Even if the communication capacity decreases, it is considered to be more preferable overall.

(Explanation of the flowchart in Figure 5)
FIG. 5 shows a case where the wireless LAN repeater 100 cannot communicate by selecting LPI and VLP for each terminal (wireless LAN router 200 and first host 300) in 6 GHz band communication, and the first host 300 (when connected to the first host 300 by LPI, connection to the wireless LAN router 200 is not made at 6 GHz). Note that in FIG. 5 as well, steps with the same numbers as in FIG. 3 indicate the same operations as in FIG. 3.
If the first hosts 300 are exchanging a large amount of data with each other via the wireless LAN repeater 100, the flowchart in FIG. 5 gives priority to connection with the first host 300 rather than the flowchart in FIG. is more desirable.
In the flowchart of FIG. 5, after determining the connection method with the wireless LAN router 200 in S3 to S7, it is checked whether there is a connection request using the 6 GHz band LPI from the first host 300 (step S7a).
If there is a connection request using the 6 GHz band LPI, it is checked whether the wireless LAN router 200 is connected using the 6 GHz band VLP (step S7b).
If the wireless LAN router 200 is connected to the 6GHz band VLP, the connection is confirmed in the 5GHzW56 band (step S7c), and if the connection is possible in the 5GHzW56 band, the connection is switched to the 5GHzW56 band (step S7d), and the 5GHzW56 band is connected. If the connection cannot be made in the 2.4 GHz band, the connection is switched to the 2.4 GHz band (step S7e).
Then, in response to a request from the first host 300, it is connected to the first host 300 using one of the 6 GHz band LPI, 5 GHz W56 band, and 2.4 GHz band (step S8d).
On the other hand, in step S7a, if there is no connection request from the first host 300 in the 6GHz band LPI, the first host connects in either the 5GHzW56 band or the 2.4GHz band in response to the request from the first host 300. 300 (step S8e).

(Explanation of the flowchart in Figure 6)
FIG. 6 shows a case where the wireless LAN repeater 100 is connected to the wireless LAN router 200 using a 6 GHz band VLP and a connection using a 5 GHz W56 band is possible, or when the wireless LAN repeater 100 is connected using a 5 GHz W56 band and a connection using a 6 GHz band VLP is possible. 12 is a flowchart for reselecting the optimal communication environment when the communication environment becomes possible.
In FIG. 6, if the wireless LAN repeater 100 is not connected to the wireless LAN router 200 using the 6 GHz band VLP (step S31), it is checked whether the connection is possible using the 6 GHz band VLP (step S32), and the connection is possible. If so, the wireless LAN repeater 100 is restarted from step S1 according to the flowcharts of FIGS. 3 to 5 (step S35).
In step S32, if connection is not possible with the 6GHz band VLP and there is no connection with the 5GHzW56 band (for example, if connection is made with 2.4GHz) (step S33), check whether connection is possible with the 5GHzW56 band. Confirm (step S34), and if connection is possible, restart the wireless LAN repeater 100 (step S35)
In other cases, the wireless LAN repeater 100 continues in its current state.
Note that if this operation of reselecting the optimal communication environment is performed frequently, it may disrupt the connection between the wireless LAN repeater 100 and the wireless LAN router 200, and the connection between the wireless LAN repeater 100 and the first host 300. Therefore, it is desirable to limit the number of times to a predetermined time interval, for example, once every 30 minutes.

[Wireless LAN router 200 of second embodiment]
FIG. 7 is a schematic block diagram of a wireless LAN router 200 according to the second embodiment.
As shown in FIG. 7, the wireless LAN router 200 includes a 2.4GHz band wireless communication circuit 10a, a 5GHz band wireless communication circuit 20a, a 6GHz band wireless communication circuit 30a, a control circuit 40a, a data buffer 50a, and a network circuit 60. We are prepared. Furthermore, the 2.4 GHz band wireless communication circuit 10a, the 5 GHz band wireless communication circuit 20a, and the 6 GHz band wireless communication circuit 30a are each provided with antennas 11a, 21a, and 31a. It is also possible to share an antenna between the 2.4 GHz band and the 5 GHz band by inserting an antenna switch (not shown) between the antenna and the wireless communication circuit. The 5 GHz band wireless communication circuit 20a includes a radar radio wave detection circuit 22a.
Note that the wireless LAN router 200 in the second embodiment refers to a wireless LAN base device, and also includes wireless LAN access points that do not have a router function. However, if the wireless LAN router 200 is a wireless LAN access point, the network circuit 60 may be omitted.
The radar radio wave detection circuit 22a monitors radar radio waves when the wireless LAN router 200 communicates with the wireless LAN repeater 100 and the second host 300a in the 5 GHz W53 and W56 bands, and detects radar radio waves when the radar radio waves are detected. is for DFS functions that move to other channels or other frequency bands.
Furthermore, the wireless LAN router 200 includes a WAN side connection terminal 61 and a LAN side connection terminal 62, and the WAN side connection terminal 61 is connected to the Internet via an optical line ONU or the like.

(Flowchart of second embodiment)
8 and 9 are both flowcharts when starting up the wireless LAN router 200 in the outhouse mode, and FIG. 8 shows the flowchart when the wireless LAN router 200 has a function that allows LPI/VLP settings for each connected terminal. Flowchart FIG. 9 is a flowchart when the wireless LAN router 200 is unable to set LPI/VLP for each connected terminal.
Hereinafter, the operation at startup of the wireless LAN router 200 will be explained based on each figure.

(Explanation of the flowchart in Figure 8)
To start up the wireless LAN router 200 in the outhouse mode, first, the MAC address and the like of the wireless LAN repeater 100 located in the outhouse 500 and connected via the outdoor communication path 600 are specified (step S41). However, if the wireless LAN repeater 100 is also set to the outhouse mode, the identification information may be received from the wireless LAN repeater 100.
Next, the wireless LAN router 200 outputs the SSIDs of the 6 GHz band LPI, 6 GHz band VLP, 5 GHz W56 band, and 2.4 GHz band (step S42).
Next, there is a connection request in the 6 GHz band LPI from one of the connection terminals of the wireless LAN repeater 100 and the second host 300a, and the terminal that made the connection request connects via the outdoor connection path. If it is not the wireless LAN repeater 100 of the attached outhouse 500, connection using the 6 GHz band LPI is permitted (steps S43 to S45).
Next, if there is a connection request using the 6 GHz band VLP from any of the connected terminals (step S46), the connection using the 6 GHz band LPI is permitted (step S47).
Furthermore, if there is a connection request in the 5GHz W56 band from any connected terminal (step S48), the connection in the 5GHz W56 band is permitted (step S49), and a connection request in the 2.4 GHz band is made from any connected terminal. If so (step S50), connection in the 2.4 GHz band is permitted (step S51).

Note that the reason why the wireless LAN router 200 connects to the second host 300a using the W56 band at 5 GHz is due to the wireless LAN router 200 connecting to the second host 300a using the W56 band at 5 GHz. This is to enable simultaneous use of the 5 GHz band and the 6 GHz band for connection between the wireless LAN router 200 and the wireless LAN repeater 100 when link operation (MLO) becomes available. Therefore, when MLO is not used, when the 5 GHz W56 band is not used for the connection between the wireless LAN router 200 and the wireless LAN repeater 100, or when the wireless LAN repeater 100 is equipped with two wireless communication circuits of the 5 GHz band, If communication is possible using both W56, W52, and W53, communication in the 5 GHz band does not need to be limited to the W56 band.
In addition, if the wireless LAN router 200 does not have a connection terminal connected via an outdoor connection path such as the wireless LAN repeater 100, by starting the wireless LAN router 200 in normal mode, all frequency bands can be connected. can be connected to the second host 300a.

(Explanation of the flowchart in Figure 9)
FIG. 9 is a flowchart when the wireless LAN router 200 is unable to set LPI/VLP for each connected terminal. Therefore, only when the wireless LAN router 200 is not connected to the second host 300a using the 6 GHz band LPI, it can connect to the wireless LAN repeater 100 using the 6 GHz band VLP. Note that in FIG. 9 as well, steps with the same numbers as in FIG. 8 indicate the same operations as in FIG. 8.
In this case, the first SSID to be transmitted does not include the SSID of the 6GHz band VLP (step S42a), so if it is found that the 6GHz band VLP will not be used (No in step S43 or Yes in step S44), the 6GHz band VLP will be transmitted again. The SSID of the band VLP is transmitted (step S42b), and if there is a connection request in the 6 GHz band VLP from any connected terminal (step S46), the connection in the 6 GHz band VLP is permitted (step S47).
Steps S48 to S51 are the same as in FIG. 8.

[Wireless LAN system 1000]
The configuration of the wireless LAN system 1000 is as shown in FIG.
Since the wireless LAN router 200 and the wireless LAN repeater 100 are located in different buildings, communication is performed via the outdoor communication path 600, and the wireless LAN router 200 and the second host 300a, Since the wireless LAN repeater 100 and the first host 300 are located inside the same building, communication is performed via the indoor communication path 700.
Even if only the wireless LAN repeater 100 or only the wireless LAN router 200 is set to the outhouse mode, the purpose of the present invention, which is to configure a communication system with maximum communication capacity without violating laws and regulations, can be achieved. However, if both the wireless LAN router 200 and the wireless LAN repeater 100 are set to the outhouse mode, the effect can be further enhanced.
Here, as an operation when both the wireless LAN router 200 and the wireless LAN repeater 100 are set to the outhouse mode, the wireless LAN repeater 100 causes the wireless LAN router 200 to switch from 6GHz band LPI to 6GHz band VLP. The case of issuing a request will be explained based on FIG. 10. Further, a case where the wireless LAN repeater 100 and the wireless LAN router 200 operate in conjunction with each other at the time of radar radio wave detection will be described based on FIGS. 11 and 12.

(Switching request and response from 6GHz band LPI to 6GHz band VLP)
FIG. 10 shows a flowchart illustrating the operation when the wireless LAN repeater 100 requests the wireless LAN router 200 to switch from 6 GHz band LPI to 6 GHz band VLP.
When the wireless LAN router 200 is connected to the wireless LAN repeater 100 in the 5GHzW56 band or the 2.4GHz band (step S51), the wireless LAN router 200 requests a change from the wireless LAN repeater 100 to the 6GHz band VLP. Upon receiving (step S52), the wireless LAN router 200 examines whether it is possible to change the 6 GHz band to VLP (step S53). Normally, if the wireless LAN router 200 is not connected to the second host 300a by 6 GHz band LPI, it can be changed to VLP.
If the 6 GHz band can be changed to VLP, change the 6 GHz band to VLP (step S54), and send OK to the wireless LAN repeater 100 (step S55); if the change is not possible, send NG to the wireless LAN repeater 100. A reply is sent (step S56).
Note that this flowchart is a flowchart when the wireless LAN router 200 is unable to set the 6GHz band VLP/LPI for each terminal, and when the wireless LAN router 200 is able to set the 6GHz band VLP/LPI for each terminal. , step S53 is always Yes, and the wireless LAN router 200 only needs to add the 6 GHz band VLP (send the SSID including the 6 GHz band VLP) and return OK to the wireless LAN repeater 100.
By providing the wireless LAN system 1000 with this function, the wireless LAN router 200 and the wireless LAN repeater 100 can be connected using the 6 GHz band VLP, such as when there is no second host 300a that communicates using the 6 GHz band LPI. If possible, the communication capacity between the wireless LAN router 200 and the wireless LAN repeater 100 can be increased by surely connecting using the 6 GHz band VLP.

(Cooperative operation when detecting radar radio waves)
Regarding communication between the wireless LAN router 200 and the wireless LAN repeater 100, when the radar radio wave detection circuit 22a included in the wireless LAN router 200 detects radar radio waves, the wireless LAN router 200 switches to the wireless LAN repeater. 100 and the second host 300a, the possibility of violation of laws and regulations is prevented by not communicating on the channel where radar radio waves are detected during the non-occupied period. However, the wireless LAN router 200 may be placed away from the outer wall of the main building 400, and the wireless LAN repeater 100 may be placed near the outer wall of the outhouse 500. In such a case, the radar radio wave detection circuit 22a of the wireless LAN router 200 may not be able to detect radar radio waves, while the radar radio wave detection circuit 22 of the wireless LAN repeater 100 may detect radio waves.
In the wireless LAN system 1000 of the present invention, when both the wireless LAN router 200 and the wireless LAN repeater 100 are set to the outhouse mode, the DFS function is activated to avoid violating laws and regulations even in such a case. Therefore, the operation shown in FIG. 11 or 12 is performed.

In FIG. 11, when the radar radio wave detection circuit 22 of the wireless LAN repeater 100 detects radar radio waves (step S61), the wireless LAN repeater 100 transmits radar radio wave detection information to the wireless LAN router 200 (step S62). ).
When the wireless LAN router 200 receives radar radio wave detection information from the wireless LAN repeater 100, or when its own radar radio wave detection circuit 22a detects radio waves (step S63), the wireless LAN router 200 detects the currently used 5 GHz W56 band channel. (Step S64), and confirm connection with another channel in the 5GHz W56 band (Step S65). Specifically, a channel is searched for where no radar radio waves are detected for one minute or more and where the radio waves of another SSID's wireless LAN are weak.
If connection on another channel in the 5GHzW56 band is possible (step S66), connect to the wireless LAN repeater 100 on that channel (step S67); if not, connect the wireless LAN router 200 and the wireless LAN repeater 100, the wireless LAN repeater 100 and the wireless LAN router 200 are restarted from step S1 and steps S42 to S42a, respectively (step S68).
However, when restarting the wireless LAN repeater 100, "Is it OK to connect in the 5 GHz W56 band?" in steps S3 and S9 is "No". Furthermore, when restarting the wireless LAN router 200, the SSID of the 5 GHz W56 band is not output in steps S42, S42a, and S42b.

In FIG. 12, after stopping communication in the channel of the 5 GHz W56 band in use in step S64 due to detection of radar, etc., the wireless LAN router 200 first connects the wireless LAN repeater 100 at 6 GHz (VLP) or 2.4 GHz. (Step S71). Thereafter, the wireless LAN router 200 investigates the possibility of connection using another channel in the 5 GHz W56 band while maintaining the communication at step S71 (step S72). Specifically, a search is made for another channel where no radar radio waves are detected for more than one minute and where the radio waves of another SSID's wireless LAN are weak.
If connection via another channel in the 5GHzW56 band is possible (step S73), the wireless LAN router 200 switches the connection with the wireless LAN repeater 100 to another channel in the 5GHzW56 band (step S74), and if it is not possible. In that case, the connection with the wireless LAN repeater 100 at 6 GHz or 2.4 GHz is continued.
Note that in step S74, although FIG. 12 shows an example of switching to another channel in the W56 band, the present invention is not limited to this, and in order to find the optimal communication environment between the wireless LAN router 200 and the wireless LAN repeater 100 The wireless LAN repeater 100 and the wireless LAN router 200 may be restarted from step S1 and steps S42 to S42a, respectively.
In the method of FIG. 11, after stopping communication in the 5GHz W56 band in use, it is necessary to confirm that there is no radar radio wave on another channel for at least one minute, so communication is stopped for at least one minute. On the other hand, in the method of FIG. 12, although it is necessary to once connect to the wireless LAN repeater 100 at 6 GHz or 2.4 GHz, it is advantageous in that communication outages for at least one minute can be avoided.

(Advantages of wireless frequency band switching method in outhouse mode)
A wireless LAN router 200 placed inside the main house 400 and a wireless LAN repeater 100 placed in an outhouse 500 are connected via an outdoor communication path 600, and the wireless LAN repeater 100 is placed in the same outhouse 500. When connected to one or more first hosts 300 via the indoor communication path 700, the wireless LAN system 1000 of the present invention has the following advantages.
1) Since the 5GHz W52 band, W53 band, and 6GHz band LPI, which are prohibited for outdoor use, are not used for connection between the wireless LAN router 200 and the wireless LAN repeater 100, there is no violation of laws and regulations.
2) In order to select the optimal communication environment for connection to the wireless LAN router 200 from the 6 GHz band VLP and 5 GHz W56 band, which are permitted for outdoor communication, the connection with the wireless LAN router 200 is Communication capacity can be increased.
3) When radar radio waves are detected by the wireless LAN router 200 or the wireless LAN repeater 100 in the 5 GHz W56 band, one of the following two methods is adopted.
In the first method, a connection is first attempted using another channel in the 5 GHz W56 band, and if connection is not possible, the wireless LAN router 200 and the wireless LAN repeater 100 are restarted. Therefore, it is possible to ensure compliance with laws and regulations by improving radar detection accuracy during radar detection, and to suppress the processing amount of the wireless LAN repeater 100.
In the second method, first, a connection is made to the wireless LAN repeater 100 using 6 GHz or 2.4 GHz, and then a connection using another channel of the 5 GHz W56 band is attempted. Therefore, at the time of radar detection, it is possible to ensure compliance with laws and regulations by improving radar detection accuracy, and to avoid communication outage for at least one minute required for radar detection.
4) By periodically attempting to return to the 6 GHz band VLP or 5 GHz W56 band, which has a larger communication capacity, the cumulative communication capacity can be increased.

Note that the arrangement of the wireless LAN router 200 and the wireless LAN repeater 100 may be changed from the initial arrangement position. Therefore, the wireless LAN router 200 and the wireless LAN repeater 100 have a 2.4 GHz band not only in the outhouse mode, but also in the connection between the wireless LAN router 200 and the wireless LAN repeater 100, and the connection with the hosts 300 and 300a. It is desirable to also have a normal mode that uses all the frequency bands of , 5 GHz band, and 6 GHz band.
In addition, the switching between the two types of modes is such that it is easy to understand in which mode the wireless LAN router 200 and the wireless LAN repeater 100 are used, and the two types of modes can be switched using a switch or the like. is desirable. In this case, it is more preferable that the mode changeover switch be a slide switch provided on the side surface of the housing of the wireless LAN router 200 and the wireless LAN repeater 100 from the viewpoint of preventing erroneous operation and ensuring clarity. Furthermore, an LED provided on the housing may indicate in which mode communication is being performed, and which frequency band is used to indicate whether wireless LAN router 200 and wireless LAN repeater 100 are communicating. may also be shown. Furthermore, by displaying the communication status (radio field strength, etc.) between the wireless LAN router 200 and the wireless LAN repeater 100 using an LED or the like, it may be possible to easily find the optimal installation location for high-capacity, high-speed communication.

Furthermore, in the wireless LAN system 1000 configured as shown in FIG. , the SSID of the connection between the wireless LAN repeater 100 and the first host 300 is the same SSID, and the SSID of the connection between the wireless LAN router 200 and the wireless LAN repeater 100 is different from the above-mentioned same SSID. It may be configured as follows.

In this case, since the same SSID is set for the first host 300 and the second host 300a, even if the second host 300a (for example, a smartphone) used in the main house 400 moves to the outhouse 500, , the wireless LAN connection can be continued as is.
Further, since the SSID is different between the connection between the wireless LAN router 200 and the wireless LAN repeater 100 and the connection between the wireless LAN router 200 or the wireless LAN repeater 100 and the hosts 300 and 300a, for example, the wireless LAN router 200 and the wireless LAN repeater 100 have different SSIDs. The connection between the wireless LAN router 200 or the wireless LAN repeater 100 and the host 300 or 300a can be made compatible with the LPI.

[Wireless LAN system 1000a of third embodiment]
FIG. 13 shows the wireless LAN router 200 and the second wireless LAN repeater 120 placed in the main house 400, and the first wireless LAN repeater 100 and the first wireless LAN repeater of the first embodiment placed in the outhouse 500. 10 is a schematic configuration diagram of a wireless LAN system 1000a according to a third embodiment, which is configured with a host 300. FIG.
In the configuration of FIG. 13, an indoor communication path 720 exists between the wireless LAN router 200 and the second wireless LAN repeater 120, and an outdoor communication path 720 exists between the second wireless LAN repeater 120 and the wireless LAN repeater 100. Since it is the communication path 600, the second wireless LAN repeater 120 is set to the outdoor communication path specification for connection with the first wireless LAN repeater 100, and the wireless LAN repeater 100 is set to the outhouse mode. It is desirable to do so.
In this case, it is possible to connect the wireless LAN router 200 and the first host 300 with maximum communication capacity without violating any laws and regulations.

[Wireless LAN system 1000b of fourth embodiment]
FIG. 14 shows the wireless LAN router 200 of the second embodiment placed in the main house 400, the first wireless LAN repeater 100 of the first embodiment placed in the outhouse 500, and the third wireless LAN router 200 of the second embodiment placed in the main house 400. 10 is a schematic configuration diagram of a wireless LAN system 1000b according to a fourth embodiment, which is configured with a repeater 130 and a first host 300. FIG.
In the configuration of FIG. 14, an outdoor communication path 600 is between the wireless LAN router 200 and the first wireless LAN repeater 100, and an outdoor communication path 600 is between the first wireless LAN repeater 100 and the third wireless LAN repeater 130. Since the communication path 730 is an indoor communication path, it is desirable to set the wireless LAN router 200 and the first wireless LAN repeater 100 to the outhouse mode, and set the third wireless LAN repeater 130 to the normal mode. .
In this case, it is possible to connect the wireless LAN router 200 and the first host 300 with maximum communication capacity without violating any laws and regulations.

[Wireless LAN system 1000c of fifth embodiment]
FIG. 15 shows the wireless LAN router 200 of the second embodiment placed in the main house 400, the fourth wireless LAN repeater 140 of the first embodiment placed in the first outhouse 510, and the second A schematic configuration diagram of a wireless LAN system 1000c according to a fifth embodiment, which is configured with a first wireless LAN repeater 100 according to the first embodiment and a first host 300 arranged in an outhouse 520 of be.
In the configuration of FIG. 15, an outdoor communication path 640 is between the wireless LAN router 200 and the fourth wireless LAN repeater 140, and an outdoor communication path 640 is between the fourth wireless LAN repeater 140 and the first wireless LAN repeater 100. Since the communication path 600 is also an outdoor communication path, the wireless LAN router 200, the fourth wireless LAN repeater 140, and the first wireless LAN repeater 100 are set to the outhouse mode, and the fourth wireless LAN repeater 140 needs to be set to outdoor communication path specifications for connection with the wireless LAN repeater 100.
In this case, it is possible to establish a connection between the wireless LAN router 200 and the host 300 with maximum communication capacity without violating any laws and regulations.

In the present invention, the wireless LAN router 200 corresponds to a "wireless LAN router", the wireless LAN repeater 100 corresponds to a "wireless LAN repeater", the hosts 300 and 300a correspond to "hosts", and outdoor communication Routes 600, 640 correspond to "outdoor communication routes", indoor communication routes 700, 720, 730 correspond to "indoor communication routes", main house 400 corresponds to "main house", and outhouse 500 corresponds to "outhouse". However, the first outhouse 510 corresponds to a "first outhouse," the second outhouse 520 corresponds to a "second outhouse," and the second wireless LAN repeater 120 corresponds to a "second outhouse." the third wireless LAN repeater 130 corresponds to the “third wireless LAN repeater”, the fourth wireless LAN repeater 140 corresponds to the “fourth wireless LAN repeater”, The 2.4 GHz band wireless communication circuits 10, 10a correspond to "wireless communication circuits capable of communicating in the 2.4 GHz band", the 5 GHz band wireless communication circuits 20, 20a correspond to "wireless communication circuits capable of communicating in the 5 GHz band", and The 6 GHz band wireless communication circuits 30 and 30a correspond to a "wireless communication circuit capable of communicating in the 6 GHz band", the radar radio wave detection circuits 22 and 22a correspond to a "radar radio wave detection circuit", and the network circuit 60 corresponds to a "network circuit". The wireless LAN systems 1000, 1000a, 1000b, and 1000c correspond to the "wireless LAN system."

Although a preferred embodiment of the present invention is as described above, the present invention is not limited thereto. It will be appreciated that various other embodiments may be made without departing from the spirit and scope of the invention. Further, in this embodiment, the functions and effects of the configuration of the present invention are described, but these functions and effects are merely examples and do not limit the present invention.

10, 10a 2.4 GHz band wireless communication circuit 20, 20a 5 GHz band wireless communication circuit 22, 22a Radar radio wave detection circuit 30, 30a 6 GHz band wireless communication circuit 60 Network circuit 100 Wireless LAN repeater, first wireless LAN repeater 120 Second wireless LAN repeater 130 Third wireless LAN repeater 140 Fourth wireless LAN repeater 200 Wireless LAN router 300, 300a Host 400 Main house 500 Outhouse 510 First outhouse 520 Second outhouse 600,640 Outdoors Communication path 700, 720, 730 Indoor communication path 1000, 1000a, 1000b, 1000c Wireless LAN system

Claims (13)

A wireless LAN repeater that is connected to a wireless LAN router via an outdoor communication path and has an outhouse mode used when connected to a first host through an indoor communication path,
Equipped with a wireless communication circuit capable of communicating in the 2.4 GHz band, a wireless communication circuit capable of communicating in the 5 GHz band, and a wireless communication circuit capable of communicating in the 6 GHz band,
At the time of starting up the outhouse mode, the wireless LAN router selects the optimal communication environment from the connectable frequency bands of the 6 GHz band VLP (Very Low Power), 5 GHz W56 band, and 2.4 GHz band. In addition to connecting to
A wireless LAN repeater that connects to the first host using a 2.4 GHz band, a 5 GHz band, and/or a 6 GHz band according to a request of the first host. The wireless communication circuit capable of communicating in the 2.4 GHz band, the wireless communication circuit capable of communicating in the 5 GHz band, and the wireless communication circuit capable of communicating in the 6 GHz band are each configured as one circuit. Wireless LAN repeater. requesting the wireless LAN router to enable connection via 6GHz band VLP when connection with the wireless LAN router via 6GHz band VLP is impossible;
When connection via 6GHz band VLP becomes possible, select the optimal communication environment again from the connectable frequency bands of 6GHz band VLP, 5GHz W56 band, and 2.4GHz band and connect the wireless The wireless LAN repeater according to claim 1, which is connected to a LAN router. If you are connected to the wireless LAN router on the 5GHz W56 band and the connection on the 5GHz W56 band becomes impossible, try to connect on another channel on the 5GHz W56 band,
If connection with another channel in the 5GHz W56 band is not possible, select the most suitable communication environment from the connectable frequency bands of the 6GHz band VLP and the 2.4GHz band, and connect the wireless LAN router to the wireless LAN router. The wireless LAN repeater according to claim 1. If you are connected to the wireless LAN router on the 5GHz W56 band and the connection on the 5GHz W56 band becomes impossible, connect to the wireless LAN router on the 6GHz band VLP or the 2.4GHz band, and also connect to the 5GHz W56 band. investigate the possibility of connecting in the channels of
If it becomes possible to connect on another channel in the 5GHz W56 band, select the optimal communication environment again from among the connectable frequency bands of the 6GHz band VLP, 5GHz W56 band, and 2.4GHz band. The wireless LAN repeater according to claim 1, wherein the wireless LAN repeater is connected to the wireless LAN router. It is checked at predetermined time intervals whether connection is possible in the 6 GHz band VLP and 5 GHz W56 band with the wireless LAN router, and the connection is changed from unavailable to one of the 6 GHz band VLP and 5 GHz W56 band. If the wireless LAN router is connected to the wireless LAN router, the wireless LAN router selects the optimal communication environment again from among the connectable frequency bands of the 6 GHz band VLP, 5 GHz W56 band, and 2.4 GHz band, and connects to the wireless LAN router. The wireless LAN repeater described in . The wireless LAN repeater according to claim 1, comprising a plurality of SSIDs, wherein the SSID for connection with the wireless LAN router corresponds to 6GHz band VLP, and the SSID for connection with the first host corresponds to 6GHz band LPI. . A wireless LAN router and a second host located in the main building,
The wireless LAN repeater according to any one of claims 1 to 7 and the first host are arranged in an outhouse,
The wireless LAN repeater is set to the outhouse mode and is connected to the wireless LAN router via an outdoor communication path, and the wireless LAN router is connected to the second host via an indoor communication path. a wireless LAN system, wherein the wireless LAN repeater is connected to the first host via an indoor communication path. The wireless LAN router and the wireless LAN repeater each include a plurality of SSIDs,
The SSID of the connection between the wireless LAN router and the second host and the SSID of the connection between the wireless LAN repeater and the first host are the same SSID,
9. The wireless LAN system according to claim 8 , wherein the SSID of the connection between the wireless LAN router and the wireless LAN repeater is different from the same SSID. The 5 GHz band wireless communication circuit of the wireless LAN repeater has a radar radio wave detection circuit,
When the wireless LAN repeater detects radar radio waves in the 5GHzW56 band, the wireless LAN repeater transmits radar radio wave detection information to the wireless LAN router, and the wireless LAN router detects the radar radio waves. The wireless LAN system according to claim 8 , wherein the wireless LAN system determines that it has been detected. A wireless LAN router and a second wireless LAN repeater located in the main building;
The first wireless LAN repeater according to any one of claims 1 to 7 and the first host are arranged in an outhouse,
The second wireless LAN repeater and the wireless LAN router are connected via an indoor communication path,
The first wireless LAN repeater is set to the outhouse mode, and is connected to the second wireless LAN repeater via an outdoor communication path, and is also connected to the first host via an indoor communication path. , wireless LAN system. A wireless LAN router located in the main building,
The first wireless LAN repeater according to any one of claims 1 to 7, the third wireless LAN repeater, and the first host, which are arranged in an outhouse,
The first wireless LAN repeater is set to the outhouse mode and connected to the wireless LAN router via an outdoor communication path,
In the wireless LAN system, the third wireless LAN repeater is connected to the first wireless LAN repeater through an indoor communication path, and is connected to the first host through an indoor communication path. A wireless LAN router located in the main building,
The fourth wireless LAN repeater according to any one of claims 1 to 7, which is disposed in the first outhouse;
The first wireless LAN repeater according to any one of claims 1 to 7 and the first host, which are arranged in a second outhouse,
The fourth wireless LAN repeater is set to the outhouse mode and connected to the first wireless LAN router via an outdoor communication path,
The first wireless LAN repeater is set to the outhouse mode, and is connected to the fourth wireless LAN repeater via an outdoor communication path and to the first host via an indoor communication path. , wireless LAN system.