JP2022159672A - Wireless lan device, channel control method, and program - Google Patents

Abstract

To provide a wireless LAN device capable of shortening a time required for switching from a communication channel belonging to W52 to a communication channel belonging to W53 or W56.SOLUTION: A wireless LAN device 10 comprises: a communication unit 11 that communicates with a wireless terminal by radio; a monitoring unit 12 that monitors a radar wave using a second channel; and a controller 13 that, in a case where a predetermined time period has not elapsed in monitoring the radar wave using the second channel at a timing when a radar wave using a first channel is detected, switches a channel to be used by the communication unit 11 to a third channel not requested to monitor the radar wave and causes the monitoring of the radar wave using the second channel to continue. When the monitoring unit 12 does not detect the radar wave using the second channel for the predetermined time period, the controller 13, switches the channel to be used by the communication unit 11 from the third channel to the second channel.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to a wireless LAN device, channel control method, and program.

In recent years, wireless LAN access points that enable communication using frequencies in the 5 GHz band have become widespread. The frequency of the 5 GHz band is, for example, frequencies used in communication channels of the W52, W53, and W56 bands. In general, when using communication channels in the W53 and W56 bands, it is legally required to use the DFS function to change to another communication channel when radar waves are detected.

Japanese Unexamined Patent Application Publication No. 2002-200001 discloses a configuration of an image transmission device having a plurality of wireless communication circuits. The image transmitting device performs wireless communication with the image receiving device through the first wireless circuit, monitors communication channels belonging to W53 or W56 through the second wireless circuit, and performs communication belonging to W52 through the third wireless circuit. Monitor channels. In the image transmission device of Patent Document 1, when a radar wave is detected in the first radio circuit, the communication channel with the better quality is selected from the communication channels belonging to W52 and the communication channels belonging to W53 or W56. Perform wireless communication with the image receiving device. In Patent Document 1, when the image transmission device selects a communication channel belonging to W52 in the second wireless circuit, a new communication channel belonging to W53 or W56 is selected in the first wireless circuit and the second wireless circuit. Start monitoring. Here, it is assumed that the image transmission device detects no radar wave in the communication channel belonging to W53 or W56 for 60 seconds in the first radio circuit and the second radio circuit. In this case, the image transmitting apparatus performs wireless communication by switching from the third wireless circuit using the communication channel belonging to W52 to the first or second wireless circuit.

WO2016/163009

The image transmission device disclosed in Patent Document 1 takes at least 60 seconds to switch from a communication channel belonging to W52 to a communication channel belonging to W53 or W56. However, when using communication channels belonging to W52, there is no need to use the DFS function, so many wireless communication devices use communication channels belonging to W52. Therefore, if a communication channel belonging to W52 is continued to be used, there is a problem that interference with other wireless communication devices may occur and communication quality may deteriorate. Therefore, it is required to shorten the time required to switch from a communication channel belonging to W52 to a communication channel belonging to W53 or W56.

An object of the present disclosure is to provide a wireless LAN device, a channel control method, and a program capable of shortening the time required to switch from a communication channel belonging to W52 to a communication channel belonging to W53 or W56.

A wireless LAN device according to a first aspect of the present disclosure includes a communication unit that performs wireless communication with a wireless terminal, and a radar wave that uses a second channel different from the first channel used in the communication unit. a monitoring unit that performs monitoring, and when the monitoring of the radar wave using the second channel has not elapsed for a predetermined period at the timing when the radar wave using the first channel is detected by the communication unit, a control unit that switches the channel used by the communication unit to a third channel that is not required to monitor radar waves, and that causes the monitoring unit to continue monitoring radar waves using the second channel; wherein, if the monitoring unit does not detect a radar wave using the second channel for the predetermined period of time, the control unit changes the channel used by the communication unit from the third channel to the second channel. switch to

A channel control method according to a second aspect of the present disclosure includes a communication unit that performs wireless communication with a wireless terminal, and a radar wave that uses a second channel different from the first channel used in the communication unit. A channel control method executed in a wireless LAN device having a monitoring unit for monitoring, wherein the second channel is used at the timing when the radar wave using the first channel is detected in the communication unit. when the monitoring of the radar wave has not elapsed for a predetermined period of time, the channel used by the communication unit is switched to a third channel that is not required to monitor the radar wave, and the second channel in the monitoring unit is switched. and if the monitoring unit does not detect the radar wave using the second channel for the predetermined period of time, the channel used by the communication unit is changed from the third channel to the Switch to the second channel.

A program according to a third aspect of the present disclosure includes: a communication unit that performs wireless communication with a wireless terminal; and monitoring of radar waves using a second channel different from the first channel used in the communication unit. a program to be executed by a computer that is a wireless LAN device having a monitoring unit that performs radar using the second channel at the timing when the radar wave using the first channel is detected in the communication unit When the monitoring of waves has not elapsed for a predetermined period of time, the channel used by the communication unit is switched to a third channel that is not required to monitor radar waves, and the second channel in the monitoring unit is used. If the monitoring unit does not detect the radar wave using the second channel for the predetermined period of time, the channel used by the communication unit is changed from the third channel to the second channel. causes the computer to switch to the channel of

According to the present disclosure, it is possible to provide a wireless LAN device, a channel control method, and a program capable of shortening the time required to switch from a communication channel belonging to W52 to a communication channel belonging to W53 or W56.

1 is a configuration diagram of a wireless LAN device according to a first embodiment; FIG. 1 is a configuration diagram of a communication system according to a second embodiment; FIG. 1 is a configuration diagram of a wireless LAN device according to a second embodiment; FIG. FIG. 10 is a diagram for explaining a channel configuration of 5 GHz band according to the second embodiment; FIG. 10 is a diagram for explaining communication channel switching control according to the second embodiment; FIG. 10 is a diagram showing the flow of communication channel switching processing in the transmission/reception circuit according to the second embodiment; FIG. 10 is a diagram showing the flow of communication channel switching processing in the transmission/reception circuit according to the second embodiment; FIG. 10 is a diagram showing the flow of communication channel switching processing in the receiving circuit according to the second embodiment; FIG. 10 is a diagram showing the flow of communication channel switching processing in the receiving circuit according to the second embodiment; 1 is a configuration diagram of a wireless LAN device according to each first embodiment; FIG.

(Embodiment 1)
BEST MODE FOR CARRYING OUT THE INVENTION Hereinafter, embodiments of the present invention will be described with reference to the drawings. A configuration example of a wireless LAN (Local Area Network) device 10 according to the first embodiment will be described with reference to FIG. The wireless LAN device 10 may be a computer device operated by a processor executing a program stored in memory. The wireless LAN device 10 may be, for example, an access point or a wireless LAN base station.

The wireless LAN device 10 has a communication section 11 , a monitoring section 12 and a control section 13 . The communication unit 11, the monitoring unit 12, and the control unit 13 may be software or modules whose processing is performed by a processor executing a program stored in memory. Alternatively, the communication unit 11, the monitoring unit 12, and the control unit 13 may be hardware such as circuits or chips.

The communication unit 11 performs wireless communication with a wireless terminal. A wireless terminal may be, for example, a wireless LAN terminal. A wireless LAN terminal may be referred to as a wireless LAN slave device. The communication unit 11 performs wireless communication with a wireless terminal using, for example, a communication standard defined in IEEE (Institute of Electrical and Electronics Engineers) 802.11. Specifically, the communication unit 11 performs wireless communication with a wireless terminal using a frequency in the 5 GHz band. The frequency of the 5 GHz band is, for example, frequencies used in communication channels of the W52, W53, and W56 bands.

The communication unit 11 transmits or receives text data, audio data, image data, moving image data, or the like to or from the wireless terminal. Further, the communication unit 11 transmits or receives control data for performing wireless LAN communication with the wireless terminal.

The monitoring unit 12 monitors radar waves using a second channel different from the first channel used in the communication unit 11 . The radar wave may be, for example, a radar wave output from a weather radar or an air radar. A channel indicates a frequency band used when transmitting or receiving data. The number of usable channels is determined according to the wireless LAN communication standard. The monitoring unit 12 can receive data transmitted using the second channel. Monitoring radar waves may be determining whether or not radar waves using the second channel have been received. The second channel is, for example, a communication channel in either W53 or W56 band required to monitor radar waves.

The control unit 13 may detect the radar wave using the first channel at the timing when the monitoring unit 12 has not monitored the radar wave using the second channel for a predetermined period. In this case, at the timing when the radar wave using the first channel is detected in the communication unit 11, the control unit 13 changes the channel used by the communication unit 11 to the third channel for which monitoring of the radar wave is not requested. switch to Furthermore, the control unit 13 causes the monitoring unit 12 to continue monitoring the radar wave using the second channel.

Since the communication unit 11 performs wireless communication with the wireless terminal using the first channel, it may detect radar waves using the first channel. Here, it is assumed that the first channel is a communication channel in either W53 or W56 band required to monitor radar waves. When the communication unit 11 detects a radar wave using the first channel, the control unit 13 needs to change the first channel to another communication channel. At this time, if a W53 or W56 band communication channel is used as another communication channel, the other communication channel must be a communication channel in which no radar wave is detected for one minute. Here, the predetermined period is one minute during which no radar wave is detected. Therefore, the control unit 13 cannot switch the first channel to the second channel for which the predetermined period of time has not been monitored. Therefore, the control unit 13 switches the first channel to the third channel, which is not required to monitor radar waves. Assume that the third channel is, for example, a W52 band communication channel.

Furthermore, even when the communication channel used by the communication unit 11 is switched from the first channel to the third channel, the control unit 13 keeps the communication channel monitored by the monitoring unit 12 as the second channel. do.

The control unit 13 switches the communication channel used by the communication unit 11 from the third channel to the second channel when the monitoring unit 12 does not detect the radar wave using the second channel for a predetermined period of time. That is, when the monitoring unit 12 does not detect a radar wave using the second channel for one minute, the control unit 13 switches the communication channel used by the communication unit 11 from the third channel to the second channel. switch.

As described above, when the communication unit 11 detects a radar wave, the wireless LAN device 10 detects that the communication channel monitored by the monitoring unit 12 has not passed the predetermined period of one minute. The communication channel used by the unit 11 is switched to the W52 band communication channel. At this time, even if the communication channel used by the communication unit 11 is switched, the control unit 13 causes the monitoring unit 12 to continue monitoring the communication channel. Therefore, when the control unit 13 switches the communication channel used in the communication unit 11 to the communication channel of the W52 band, the monitoring time of the communication channel of the W53 or W56 band in the monitoring unit 12 is several seconds to several tens of seconds. is doing. That is, when the communication channel used in the communication unit 11 is switched to the W52 band communication channel, the remaining time until one minute of radar wave monitoring by the monitoring unit 12 elapses is shorter than 60 seconds. Therefore, the time required for the communication unit 11 to switch from the communication channel of the W52 band to the communication channel of the W53 or W56 band, which has been monitored by the monitoring unit 12 for one minute, is shorter than 60 seconds.

Therefore, by using the wireless LAN device 10, the possibility of causing interference while the communication unit 11 is using the communication channel of the W52 band is reduced compared to the case where the communication channel of the W52 band is used for 60 seconds. be able to. Furthermore, if the communication channel of the communication unit 11 cannot be changed to the communication channel monitored by the monitoring unit 12 when the communication unit 11 detects a radar wave, the wireless LAN device 10 changes to the communication channel of the W52 band. . Therefore, by using the wireless LAN device 10, it is possible to avoid interruption of communication when a 5 GHz band radar wave is detected.

(Embodiment 2)
Next, a configuration example of the communication system according to the second embodiment will be described with reference to FIG. The communication system of FIG. 2 has a wireless LAN device 20, a wireless LAN terminal 30, a management terminal 40, a radar 50 and the Internet 60.

A wireless LAN device 20 corresponds to the wireless LAN device 10 . The wireless LAN device 20, the wireless LAN terminal 30, and the management terminal 40 may be computer devices operated by a processor executing a program stored in memory.

The wireless LAN terminal 30, which may be called a wireless LAN slave device, performs wireless communication with the wireless LAN device 10, which is a wireless LAN parent device. FIG. 2 shows an example in which one wireless LAN terminal 30 wirelessly communicates with the wireless LAN device 20 , but a plurality of wireless LAN terminals 30 may wirelessly communicate with the wireless LAN device 20 .

The management terminal 40 is a terminal that manages the wireless LAN device 20 and may input or change parameter values set in the wireless LAN device 20 . Furthermore, the management terminal 40 may upgrade the software or middleware installed in the wireless LAN device 20 . The management terminal 40 may communicate with the wireless LAN device 20 via a LAN (Local Area Network), for example.

The radar 50 is a device that emits radar waves, and may be, for example, a weather radar, an aviation radar, or the like. Radar 50 emits radar having a frequency in the 5 GHz band. Specifically, the radar 50 transmits radar waves using communication channels in the W53 or W56 band.

The wireless LAN device 20 communicates with a server device or the like via the Internet 60 and relays communication between the wireless LAN terminal 30 and the Internet 60 .

Next, a configuration example of the wireless LAN device 20 according to the second embodiment will be described with reference to FIG. The wireless LAN device 20 has transmitting/receiving circuits 21_1 to 21_4, a receiving circuit 21_5, antennas 22_1 to 22_5, a control section 23, a memory 24, a WAN interface 25, and a LAN interface . The transmitting/receiving circuits 21_1 to 21_4 and the antennas 22_1 to 22_4 correspond to the communication section 11 in the wireless LAN device 10 of FIG. The receiving circuit 21_5 and the antenna 22_5 correspond to the monitoring unit 12 in the wireless LAN device 10 of FIG. The controller 23 corresponds to the controller 13 in the wireless LAN device 10 of FIG.

WAN interface 25 connects to Internet 60 and transmits and receives data over Internet 60 . The LAN interface 26 connects to a LAN and transmits and receives data to and from the management terminal 40 via the LAN.

Transmitting/receiving circuits 21_1 to 21_4 and antennas 22_1 to 22_4 perform wireless communication with the wireless LAN terminal 30. FIG. The transmission/reception circuit 21_1, for example, modulates data and transmits the modulated data to the wireless LAN terminal 30 via the antenna 22_1. Further, the transmission/reception circuit 21_1 demodulates data received via the antenna 22_1. The transmission/reception circuits 21_2 to 21_4 also perform data modulation and demodulation in the same manner as the transmission/reception circuit 21_1, and the antennas 22_2 to 22_4 also perform data transmission/reception in the same manner as the antenna 22_1.

Further, the transmitting/receiving circuits 21_1 to 21_4 and the antennas 22_1 to 22_4 receive the radar waves transmitted from the radar 50 when the communication channel set in the transmitting/receiving circuits 21_1 to 21_4 and the communication channel used for the radar waves are the same. do. Receiving radar waves may be translated into detecting radar waves.

The receiving circuit 21_5 and the antenna 22_5 receive radar waves transmitted from the radar 50 when the communication channel set in the receiving circuit 21_5 and the communication channel used for the radar waves are the same. The receiving circuit 21_5 and the antenna 22_5 use communication channels different from those used by the transmitting/receiving circuits 21_1 to 21_4 and the antennas 22_1 to 22_4.

The control unit 23 determines communication channels to be set in the transmission/reception circuits 21_1 to 21_5. Furthermore, the control unit 23 changes the communication channels set in the transmission/reception circuits 21_1 to 21_5. For example, when the control unit 23 determines to communicate with the wireless LAN terminal 30 using a communication channel of the W53 or W56 band, it sets communication channel information of the W53 or W56 band to the transmission/reception circuits 21_1 to 21_4. The channels set in the transmission/reception circuits 21_1 to 21_4 are hereinafter referred to as user data communication channels.

After setting user data communication channels in the transmission/reception circuits 21_1 to 21_4, the control unit 23 executes CAC (Channel Availability Check) for 60 seconds to detect radar waves transmitted from the radar 50 . In other words, the transmission/reception circuits 21_1 to 21_4 monitor for 60 seconds whether or not radar waves using the same communication channel as the user data communication channel have been received. The transmitting/receiving circuits 21_1 to 21_4 output the reception result to the control unit 23 when receiving the radar wave. The control unit 23 changes the user data communication channel set in the transmission/reception circuits 21_1 to 21_4 so as not to use the same communication channel as the received radar wave. When the transmitting/receiving circuits 21_1 to 21_4 do not receive a radar wave for 60 seconds, the control unit 23 performs wireless communication with the wireless LAN terminal 30 using the user data communication channel. When performing wireless communication with the wireless LAN terminal 30 using the user data communication channel, the control unit 23 executes ISM (In-Service Monitoring) to detect radar waves in the user data communication channel. For example, the control unit 23 sets 100ch (ch indicates a channel) of the W56 band as the user data communication channel.

Here, the channel configuration of the 5 GHz band will be explained using FIG. FIG. 4 shows communication channels in the W52, W53, and W56 bands included in the 5 GHz band. FIG. 4 shows that the W52 band includes 36ch, 40ch, 44ch and 48ch, and the W53 band includes 52ch, 56ch, 60ch and 64ch. Furthermore, the W56 band includes 100ch, 104ch, 108ch, 112ch, 116ch, 120ch, 124ch, 128ch, 132ch, 136ch, 140ch, and 144ch. FIG. 4 also shows that each communication channel has a bandwidth of 20 MHz. Therefore, when setting a bandwidth of 40 MHz for each transmission/reception circuit or reception circuit, the control unit 23 needs to set two communication channels. Similarly, the control unit 23 sets four communication channels when setting a bandwidth of 80 MHz, and sets eight communication channels when setting a bandwidth of 160 MHz.

Returning to FIG. 3, the control unit 23 further sets a communication channel different from the user data communication channel in the receiving circuit 21_5 in preparation for newly detecting a radar wave during communication on the user data communication channel. A communication channel set in the receiving circuit 21_5 is called a monitoring communication channel. The control unit 23 sets communication channel information for the W53 or W56 band in the receiving circuit 21_5. For example, when 100ch of the W56 band is set as the communication channel for user data, the control unit 23 may set 116ch of the W56 band as the communication channel for monitoring. The distance between the communication channel used for the user data communication channel and the communication channel used for the monitoring communication channel may be determined in advance. For example, the monitoring communication channel may be set to a communication channel separated from the communication channel used for the user data communication channel by at least the frequency band used for wireless communication with the wireless LAN terminal 30 .

After setting the monitoring communication channel to the receiving circuit 21_5, the control unit 23 executes CAC (Channel Availability Check) for 60 seconds to detect radar waves transmitted from the radar 50 . The control unit 23 starts CAC of the receiving circuit 21_5 at substantially the same timing as the timing of starting CAC in the transmitting/receiving circuits 21_1 to 21_4. Furthermore, the control unit 23 continues the CAC of the receiving circuit 21_5 even after 60 seconds have passed. In other words, when no radar wave is detected for 60 seconds, the control unit 23 continues CAC and continues to detect the radar wave.

As a result, when the transmitting/receiving circuits 21_1 to 21_4 detect the radar wave, the control unit 23 has already passed 60 seconds of CAC using the monitoring communication channel. Therefore, when a radar wave is detected in the transmission/reception circuits 21_1 to 21_4, the control unit 23 uses the communication channel of the user data communication channel as the monitoring communication channel without substantial interruption. can be switched to In this case, the control unit 23 sets a new communication channel in the receiving circuit 21_5 as a monitoring communication channel, and starts CAC. Immediately after switching the communication channel of the user data communication channel, the control unit 23 starts CAC of the monitoring communication channel in the receiving circuit 21_5.

The control unit 23 may detect radar waves again within 60 seconds immediately after switching the user data communication channel of the transmission/reception circuits 21_1 to 21_4. In this case, the CAC of the supervisory communication channel has not passed for 60 seconds. Therefore, the control unit 23 cannot switch the communication channel of the user data communication channel set in the transmitting/receiving circuits 21_1 to 21_4 to the communication channel of the monitoring communication channel before 60 seconds of CAC have passed. In this case, the control unit 23 sets the W52 band communication channel as the user data communication channel in the transmission/reception circuits 21_1 to 21_4. That is, the control unit 23 switches the user data communication channel of the transmission/reception circuits 21_1 to 21_4 to the W52 band communication channel. Here, the control unit 23 continues CAC without changing the monitoring communication channel of the receiving circuit 21_5.

It is assumed that the CAC in the receiving circuit 21_5 has passed 60 seconds after switching the user data communication channels of the transmitting/receiving circuits 21_1 to 21_4 to the W52 band communication channel. In this case, the control unit 23 again switches the user data communication channel of the transmission/reception circuits 21_1 to 21_4 to the communication channel used as the monitoring communication channel. That is, the control unit 23 switches the communication channel set in the transmission/reception circuits 21_1 to 21_4 from the W52 band communication channel to the W53 or W56 band communication channel.

The memory 24 stores a register A for designating the communication channel used by the transmission/reception circuits 21_1 to 21_4 and a register B for designating the communication channel used by the reception circuit 21_5. In addition, memory 24 stores a flag indicating whether the communication channel specified in register B has completed 60 seconds of CAC. The usage of the registers and flags will be detailed later.

Here, communication channel switching control in the control unit 23 will be described with reference to FIG. FIG. 5 shows switching of communication channels set in the transmitting/receiving circuits 21_1 to 21_4 and the receiving circuit 21_5 in chronological order. When the switch of the wireless LAN device 20 is switched to ON to start wireless operation, the control unit 23 selects, for example, 100ch of the W56 band selected by the administrator of the wireless LAN device 20 to the transmission/reception circuits 21_1 to 21_4. Configure and start CAC. The control unit 23 controls the transmission/reception circuits 21_1 to 21_4 so that only reception is possible while CAC is being executed in the transmission/reception circuits 21_1 to 21_4.

The control unit 23 starts CAC of the transmitting/receiving circuits 21_1 to 21_4, and at the same time, sets the receiving circuit 21_5 to 116ch of the W56 band, for example, and starts CAC. The control unit 23 controls the receiving circuit 21_5 so that only reception is possible while CAC is being performed in the receiving circuit 21_5.

The control unit 23 starts transmission and reception in the transmission/reception circuits 21_1 to 21_4 when no radar wave is detected within 60 seconds from when the transmission/reception circuits 21_1 to 21_4 start CAC to time t1. At this time, the control unit 23 causes the receiving circuit 21_5 to continuously perform CAC without stopping it.

Thereafter, when a radar wave with a frequency of 100ch is transmitted from the radar 50 or another radar, the transmitting/receiving circuits 21_1 to 21_4 detect the radar wave at time t2. In this case, the control unit 23 stops communication in the transmission/reception circuits 21_1 to 21_4, and immediately switches the user data communication channel used in the transmission/reception circuits 21_1 to 21_4 to 116ch. For 116ch, CAC continues to be executed after time t1, and 60 seconds or more have passed since the start of CAC. Therefore, the control unit 23 can immediately switch the user data communication channel used in the transmission/reception circuits 21_1 to 21_4 to 116ch.

At time t2, the control unit 23 switches the monitoring communication channel used in the receiving circuit 21_5 to, for example, 52ch in the W53 band and starts CAC. The control unit 23 controls the receiving circuit 21_5 so that only reception is possible while CAC is being performed in the receiving circuit 21_5.

After that, when radar waves with a frequency of 116ch are transmitted from the radar 50 or another radar, the transmitting/receiving circuits 21_1 to 21_4 detect the radar waves at time t3. Here, it is assumed that the radar that sent out the radar wave at time t2 and the radar that sent out the radar wave at time t3 are different radars. Although the communication system in FIG. 2 shows an image in which radar is transmitted from a building fixed on the ground, in reality, radar is also transmitted from mobile objects. For example, radar types include "maritime radionavigation", "mobile (excluding aeronautical mobile)", "earth exploration satellite (active)", "space research (active)", and "radiolocation". Therefore, it is difficult for the wireless LAN device 20 to determine in advance when and from where to receive the radar wave. In other words, the wireless LAN device 20 may receive radar waves at any time.

The time t3 is the time before 60 seconds have passed since the time t2, for example, the time 30 seconds have passed since the time t2. In this case, the control unit 23 stops using 116ch in the transmitting/receiving circuits 21_1 to 21_4, and immediately switches the user data communication channel used in the transmitting/receiving circuits 21_1 to 21_4 to, for example, 36ch of the W52 band, which does not require DFS. . At time t3, 60 seconds have not yet passed for 52ch for which CAC is being performed in the receiving circuit 21_5. Therefore, the control unit 23 cannot switch the user data communication channel of the transmission/reception circuits 21_1 to 21_4 to 52ch at time t3.

After time t3, the control unit 23 continues the CAC of 52ch in the receiving circuit 21_5.

Thereafter, at time t4, 30 seconds after time t3, 60 seconds have passed since the CAC of 52ch was started in the receiving circuit 21_5. At time t4, the CAC of 52ch in the receiving circuit 21_5 has passed for 60 seconds. At time t4, the control unit 23 switches the user data communication channel used in the transmitting/receiving circuits 21_1 to 21_4 to 52ch used in the receiving circuit 21_5. The control unit 23 switches the monitoring communication channel in the receiving circuit 21_5 to any communication channel in the W53 or W56 band other than 100ch, 116ch, and 52ch, and starts CAC.

Next, the flow of communication channel switching processing in the transmission/reception circuits 21_1 to 21_4 will be described with reference to FIGS. 6 and 7. FIG. First, the control unit 23 sets, for example, 100ch in the register A stored in the memory 24, permits the transmission/reception circuits 21_1 to 21_4 to receive data, and starts CAC (S11). For example, when the wireless LAN device 20 is powered on, the control unit 23 executes the process of step S11.

Next, the control unit 23 determines whether 60 seconds have elapsed for the CAC in the transmission/reception circuits 21_1 to 21_4 (S12). If the control unit 23 determines that the CAC has not passed 60 seconds, it repeats the process of step S12.

When the control unit 23 determines that the CAC has passed 60 seconds, it allows the transmission/reception circuits 21_1 to 21_4 to transmit/receive data using 100ch of the register A (S13). Next, the control unit 23 determines whether or not a radar wave using the communication channel 100ch set in the register A is detected in the transmitting/receiving circuits 21_1 to 21_4 (S14). When determining that the radar wave using 100ch is not detected, the control unit 23 repeats the process of step S14.

When determining that a radar wave using 100ch is detected, the control unit 23 sets 116ch set in the register B to the register A, and transmits/receives data using the 116ch in the transmitting/receiving circuits 21_1 to 21_4. is permitted (S15).

Next, the control unit 23 determines whether or not a radar wave using 116ch, which is the communication channel set in the register A, has been detected in the transmitting/receiving circuits 21_1 to 21_4 (S16). When the control unit 23 determines that the radar wave using 116ch is not detected in the transmitting/receiving circuits 21_1 to 21_4, it repeats the process of step S16.

When the control unit 23 determines that the radar wave using 116ch is detected in the transmitting/receiving circuits 21_1 to 21_4, it determines whether or not the flag stored in the memory 24 is set to 1 (S17). Setting the flag to 1 indicates that the communication channel specified in register B has completed 60 seconds of CAC. If the flag is set to a value other than 1, eg, 0, it indicates that the communication channel specified in register B has not completed the 60 second CAC.

If the control unit 23 determines that the flag is not set to 1, it sets the W52 band communication channel, for example, 36ch, in the register A, and transmits and receives data using the 36ch in the transmitting/receiving circuits 21_1 to 21_4. is permitted (S18). Next, the control unit 23 determines whether or not the flag stored in the memory 24 is set to 1 (S19). When determining that the flag is not set to 1, the control unit 23 repeats the process of step S19.

The control unit 23 sets the communication channel set in the register B to the register A when determining that the flag is set to 1 in step S17 or S19. Furthermore, the control unit 23 permits data transmission/reception in the transmission/reception circuits 21_1 to 21_4 using the set communication channel (S20). After executing the processing of step S20, the control unit 23 repeats the processing of step S16 and subsequent steps.

Next, the flow of communication channel switching processing in the receiving circuit 21_5 will be described with reference to FIGS. 8 and 9. FIG. First, the control unit 23 resets the flag to 0 when the wireless LAN device 20 is powered on (S31). Next, the control unit 23 sets, for example, 116ch in the register B, permits data reception in the receiving circuit 21_5, and starts CAC (S32).

Next, the control unit 23 determines whether 60 seconds have elapsed for the CAC in the receiving circuit 21_5 (S33). If the control unit 23 determines that the CAC has not passed 60 seconds, it repeats the process of step S33.

If the control unit 23 determines that 60 seconds have passed since the CAC, it sets or changes the value of the flag to 1 (S34).

Next, the control unit 23 continues the CAC of 116ch in the receiving circuit 21_5 (S35).

Next, the control unit 23 determines whether or not 116ch set in the register B is set in the register A (S36). In other words, the control unit 23 determines whether the communication channel of the register A has been rewritten to the communication channel of the register B or not. If the control unit 23 determines that the communication channel of the register A has not been rewritten to the communication channel of the register B, it repeats the process of step S35. If the control unit 23 determines that the communication channel of the register A has been rewritten to the communication channel of the register B, it resets the value of the flag to 0 (S37).

Next, the control unit 23 sets, for example, 52ch of the W53 band in the register B, and permits data reception using 52ch in the receiving circuit 21_5 (S38).

Next, the control unit 23 determines whether 60 seconds have elapsed for the CAC in the receiving circuit 21_5 (S39). If the control unit 23 determines that the CAC has not passed 60 seconds, it repeats the process of step S39.

If the control unit 23 determines that 60 seconds have passed since the CAC, it sets or changes the value of the flag to 1 (S40).

Next, the control unit 23 continues CAC of 52ch in the receiving circuit 21_5 (S41).

Next, the control unit 23 determines whether or not the 52ch set in the register B is set in the register A (S42). In other words, the control unit 23 determines whether the communication channel of the register A has been rewritten to the communication channel of the register B or not. If the control unit 23 determines that the communication channel of the register A has not been rewritten to the communication channel of the register B, it repeats the process of step S41. If the control unit 23 determines that the communication channel of the register A has been rewritten to the communication channel of the register B, it resets the value of the flag to 0 (S43). Next, the control unit 23 sets a new communication channel in the register B and permits the receiving circuit 21_5 to receive data using the new communication channel (S44). Henceforth, the process after step S39 is repeated.

As described above, the wireless LAN device 20 according to the second embodiment changes the values of the registers and flags stored in the memory 24 to select communication channels to be set in the transmission/reception circuits 21_1 to 21_4 and the reception circuit 21_5. can be controlled. Furthermore, the wireless LAN device 20 continues CAC in the receiving circuit 21_5 even after switching the communication channel set in the transmitting/receiving circuits 21_1 to 21_4 to the W52 band communication channel. Further, when the CAC in the receiving circuit 21_5 has passed for 60 seconds, the wireless LAN device 20 changes the communication channel set in the transmitting/receiving circuits 21_1 to 21_4 from the W52 band communication channel to the communication channel in which the CAC has passed for 60 seconds. do. In this case, the wireless LAN device 20 can shorten the use of the W52 band communication channel in the transmission/reception circuits 21_1 to 21_4 to less than 60 seconds. As a result, the wireless LAN device 20 can reduce interference that may occur when another device uses the communication channel of the W52 band in the transmission/reception circuits 21_1 to 21_4.

FIG. 10 is a block diagram showing a configuration example of the wireless LAN device 10 and the wireless LAN device 20 (hereinafter referred to as the wireless LAN device 10 and the like). Referring to FIG. 10, the wireless LAN device 10 etc. includes a network interface 1201 , a processor 1202 and a memory 1203 . Network interface 1201 may be used to communicate with other network nodes. Network interface 1201 may include, for example, a network interface card (NIC) conforming to the IEEE 802.3 series.

The processor 1202 reads software (computer program) from the memory 1203 and executes it, thereby performing the processing of the wireless LAN device 10 and the like described using the flowcharts in the above embodiments. Processor 1202 may be, for example, a microprocessor, MPU, or CPU. Processor 1202 may include multiple processors.

The memory 1203 is composed of a combination of volatile memory and non-volatile memory. Memory 1203 may include storage remotely located from processor 1202 . In this case, the processor 1202 may access the memory 1203 via an I/O (Input/Output) interface (not shown).

In the example of FIG. 10, memory 1203 is used to store software modules. The processor 1202 reads and executes these software modules from the memory 1203, thereby performing the processing of the wireless LAN device 10 and the like described in the above embodiments.

As described with reference to FIG. 10, each of the processors included in the wireless LAN device 10 and the like in the above-described embodiments includes one or more processors including instruction groups for causing a computer to execute the algorithm described with reference to the drawings. Run the program.

In the above examples, the programs can be stored and delivered to computers using various types of non-transitory computer readable media. Non-transitory computer-readable media include various types of tangible storage media. Examples of non-transitory computer-readable media include magnetic recording media (eg, flexible discs, magnetic tapes, hard disk drives), magneto-optical recording media (eg, magneto-optical discs), CD-ROMs (Read Only Memory), CD-Rs, CD-R/W, semiconductor memory (eg, mask ROM, PROM (Programmable ROM), EPROM (Erasable PROM), flash ROM, RAM (Random Access Memory)). The program may also be delivered to the computer on various types of transitory computer readable medium. Examples of transitory computer-readable media include electrical signals, optical signals, and electromagnetic waves. Transitory computer-readable media can deliver the program to the computer via wired channels, such as wires and optical fibers, or wireless channels.

It should be noted that the present disclosure is not limited to the above embodiments, and can be modified as appropriate without departing from the scope of the present disclosure.

10 wireless LAN device 11 communication unit 12 monitoring unit 13 control unit 20 wireless LAN device 21_1 transmission/reception circuit 21_2 transmission/reception circuit 21_3 transmission/reception circuit 21_4 transmission/reception circuit 21_5 reception circuit 22_1 antenna 22_2 antenna 22_3 antenna 22_4 antenna 22_5 antenna 23 control unit 24 memory 25 WAN interface 26 LAN interface 30 Wireless LAN terminal 40 Management terminal 50 Radar 60 Internet

Claims (8)

a communication unit that performs wireless communication with a wireless terminal;
a monitoring unit that monitors radar waves using a second channel different from the first channel used in the communication unit;
The channel used by the communication unit when the monitoring of the radar wave using the second channel has not elapsed for a predetermined period at the timing when the radar wave using the first channel is detected by the communication unit. to a third channel for which monitoring of radar waves is not requested, and a control unit for continuing monitoring of radar waves using the second channel in the monitoring unit,
The control unit
A wireless LAN device, wherein the channel used by the communication unit is switched from the third channel to the second channel when the monitoring unit does not detect the radar wave using the second channel for the predetermined period of time. The control unit
monitoring the radar wave using the second channel at the timing when the channel used by the communication unit is switched to the first channel in which no radar wave has been detected in the monitoring unit for the predetermined period of time; Item 1. The wireless LAN device according to item 1. The control unit
Monitoring of radar waves using a fourth channel for which monitoring of radar waves is requested to the monitoring unit at the timing when the channel used by the communication unit is switched from the third channel to the second channel 3. The wireless LAN device according to claim 1 or 2, which initiates the The control unit
A flag value associated with a channel for which no radar wave has been detected for the predetermined period of time is set to a first value, and a flag value associated with a channel for which monitoring has not elapsed for the predetermined period of time is set to a second value. 4. The wireless LAN device according to claim 1, which manages channels. 5. The channel according to claim 1, wherein the channels required to monitor radar waves are channels in the W53 band and W56 band of the 5 GHz band, and the channels not required to monitor the radar waves are the W52 band in the 5 GHz band. The wireless LAN device according to any one of claims 1 to 3. The monitoring unit
6. Radar waves are monitored using the first channel used in the communication unit and the second channel separated by a frequency band used by the communication unit or more. The wireless LAN device according to . Executed in a wireless LAN device having a communication unit that performs wireless communication with a wireless terminal and a monitoring unit that monitors radar waves using a second channel different from the first channel used in the communication unit a channel control method comprising:
The channel used by the communication unit when the monitoring of the radar wave using the second channel has not elapsed for a predetermined period at the timing when the radar wave using the first channel is detected by the communication unit. to a third channel that is not required to monitor radar waves, and continue monitoring radar waves using the second channel in the monitoring unit,
A channel control method, wherein when the monitoring unit does not detect a radar wave using the second channel for the predetermined period of time, the channel used by the communication unit is switched from the third channel to the second channel. A computer, which is a wireless LAN device, having a communication unit that performs wireless communication with a wireless terminal, and a monitoring unit that monitors radar waves using a second channel different from the first channel used in the communication unit. A program to be executed by
The channel used by the communication unit when the monitoring of the radar wave using the second channel has not elapsed for a predetermined period at the timing when the radar wave using the first channel is detected by the communication unit. to a third channel that is not required to monitor radar waves, and continue monitoring radar waves using the second channel in the monitoring unit,
When the monitoring unit does not detect a radar wave using the second channel for the predetermined period of time, the computer executes switching of the channel used by the communication unit from the third channel to the second channel. program to make

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