JP2004040591A - Wireless lan system and its communicating method - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a wireless LAN system that makes communications continue by a station STA and an access point AP2 if a communication error occurs. <P>SOLUTION: An access point AP1 is provided with an ID memory 13 that stores an ESS-ID 1 being a network ID. The access point AP2 is provided with an ID memory 13 that stores an ESS-ID 2. The stations STA1 and STA2 are provided with a detecting means for detecting a communication error between an ID memory 23 that stores the ESS-ID 1 and the ESS-ID 2 and the access point AP1, an ID switching means for making a switch from the ESS-ID 1 to the ESS-ID 2 when the communication error is detected, and a communicating means for communicating with the access point AP2 on the basis of the switched ESS-ID 2. <P>COPYRIGHT: (C)2004,JPO

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a simple wireless LAN system that improves communication reliability.
[0002]
[Prior art]
A wireless LAN system as a first related art will be described with reference to FIG. FIG. 12 is a diagram illustrating a method in which a station STA automatically sets a detour when an abnormality occurs in an access point AP in a wireless LAN system including a plurality of access points AP and a plurality of stations STA.
12A, the stations STA1, STA2, and STA4 exist in the communication range 35 of the access point AP1, the stations STA1 to STA3 exist in the communication range 36 of the access point AP2, and the communication of the access point AP3. In the range 37, stations STA1, STA4 to STA6 exist.
[0003]
Each of the access points AP1 to AP3 performs a self-test, and if the result of the self-test is good, transmits data including an ESS-ID (extended service set identifier), which is a network ID for identifying itself, to each station STA within the communication range. Sending to. Here, the ESS-IDs of the access points AP1, AP2, and AP3 are ESS-ID1, ESS-ID2, and ESS-ID3, respectively.
[0004]
Each station STA stores the ESS-ID received from each access point AP in the order in which the radio wave reception level is strong, and transmits its own identification ID to the first stored access point AP for communication. Set the route. Here, the identification IDs of the stations STA1 to ST6 are STA-ID1 to STA-ID6. That is, if the reception level of the station STA1 is strongly received in the order of the access points AP1, AP2, and AP3, it is stored in the ID memory 213 in the order of ESS-ID1, ESS-ID2, and ESS-ID3. STA-ID1 is transmitted to the access point AP1 to set a communication path.
[0005]
On the other hand, when the access point AP1 detects an abnormality as a result of the self test, the access point AP1 stops transmitting data including the ESS-ID1 as shown in FIG. Each station STA within the communication range of the access point AP1 cannot receive ESS-ID1, determines that some abnormality has occurred, and changes the order of the ID memory 213. The station STA1 transmits STA-ID1 to the access point AP2 changed to the highest order, sets a bypass communication path, and continues communication. Such a method for automatically setting a detour is disclosed, for example, in Japanese Patent Application Laid-Open No. 7-322341.
[0006]
Next, a wireless LAN system as a second related art will be described with reference to FIG. FIG. 13 illustrates roaming in a wireless LAN system. In roaming, when a station STA moves during communication, the station STA automatically switches to a destination access point AP to continue connection to the LAN. .
Referring to FIG. 13, in the wireless LAN system, access points AP1 to AP3 are arranged so as to cover a use range of the wireless LAN, and a station STA1 exists in a communication range. Here, the same ESS-ID1 is set for the access points AP1 to AP3 and the station STA1.
Now, while the station STA1 is communicating with the access point AP1, even if the station STA1 moves from the communication range 35 of the access point AP1 to the communication range 36 of the access point AP2 and the communication range 37 of the access point AP3, the access points AP2 and AP3 can be accessed. Automatically switches the connection and continues the communication.
Such a roaming function is standardized in IEEE 802.11 in a wireless LAN system.
[0007]
[Problems to be solved by the invention]
However, in Japanese Patent Application Laid-Open No. 7-322341, since the communication ranges of the plurality of access points AP and the station STA overlap to automatically set a detour communication path, for example, in FIG. When the station STA1, the access point AP2, and the station STA2 set a communication path and transmit radio waves at the same time, radio waves collide and a communication error occurs to lower the throughput. Therefore, normally, in order to prevent radio waves from colliding, transmission is performed after confirming that no other radio waves are transmitted. However, as the number of access points AP with overlapping communication ranges increases, the probability of radio wave collision increases. As a result, there is a problem that the waiting time until the transmission of a radio wave becomes longer and the throughput is significantly reduced.
[0008]
Further, in the roaming in the wireless LAN system, when a communication failure occurs due to a failure or fading of the access point AP, there is a problem that communication cannot be continuously performed because there is no detour communication path. Furthermore, in a range where the communication ranges of a plurality of access points AP overlap, there is a problem that radio waves collide and throughput is reduced.
[0009]
SUMMARY OF THE INVENTION The present invention has been made to solve the above-described problems, and has an access point AP1 that normally communicates with a station STA and a backup access point AP2, and when a communication error occurs, the station STA It is an object of the present invention to provide a wireless LAN system and a communication method thereof in which communication is continued by the access point AP2.
[0010]
[Means for Solving the Problems]
A wireless LAN system according to a first aspect of the present invention comprises an access point and a station in an infrastructure mode, a first access point for normal communication, and a second access point serving as a backup for the first access point. A wireless LAN system that forms a duplex communication path by providing: a first memory in which an ESS-ID1 that is a first network ID is stored; The access point has a second memory storing a second network ID ESS-ID2, and the station has a third memory storing a network ID ESS-ID1 and ESS-ID2. Detecting means for detecting a communication error with the first access point; ID switching means for switching from the ESS-ID1 to the ESS-ID2 when an error is detected, and communication means for communicating with the second access point based on the ESS-ID2 switched by the ID switching means. It is characterized by having.
According to the wireless LAN system, when the station detects a communication error, the station switches the network ID from ESS-ID1 to ESS-ID2 and communicates with the second access point.
Therefore, in a normal state, the station communicates with the first access point by using the network ID ESS-ID1, and when a communication error is detected, the station communicates with the second access point. There is an effect that the second access point and the station can continue communication.
[0011]
A communication method for a wireless LAN system according to a second aspect of the present invention has a wired LAN for communicating a first access point and a second access point, and includes ID exchange means for exchanging ESS-IDs of each other. When the station detects a communication error, the station switches from the ESS-ID1 to the ESS-ID2 by the ID switching unit, communicates with the second access point, and performs the second access. The point issues an ESS-ID exchange request to the first access point by the ID exchange means via the wired LAN, and the first and second access points exchange each other's ESS-ID, The station that has switched the ESS-ID2 changes the ESS-ID2 by the ID switching means. Switch to D1, it is characterized in.
According to this communication method, when a communication error is detected, the first access point and the second access point exchange their ESS-IDs, and the station and the second access point perform communication. Thereafter, since the station returns from ESS-ID2 to ESS-ID1, there is an effect that communication can be performed without interference when the station is communicating with the second access point.
[0012]
In the wireless LAN system according to a third aspect, the first and second access points have command transmission means for transmitting a command to a station within the communication range to change the ESS-ID, and the station comprises: When a communication error is detected by the detection means, the ID switching means switches from the ESS-ID1 to the ESS-ID2 to communicate with a second access point, and the second access point communicates with the command transmission means. Transmits the command to the station, and receives the command, and the station switches the ESS-ID to the ESS-ID2 by the command.
According to such a wireless LAN system, even if a communication error occurs, the station and the second access point can communicate without exchanging the network ID between the first access point and the second access point. Since there is no need to change the MAC address of the destination access point when exchanging the network ID, there is an effect that the control is simplified. In addition, there is an effect that communication can be performed without interference when the station is communicating with the second access point.
[0013]
A communication method for a wireless LAN system according to a fourth aspect of the present invention includes a wired LAN that allows a first access point to communicate with a second access point, wherein the second access point includes the first access point. The station has notification means for notifying the point that communication is performed by ESS-ID1, and the station switches from ESS-ID1 to ESS-ID2 by ID switching means when a communication error is detected by the detection means. The second access point communicates with the second access point, and the second access point notifies the first access point via the wired LAN that communication is to be performed by ESS-ID1 by the notifying unit. The first access point that has received the notification stops the wireless output, and switches the ESS-ID2 to the status. ® down, the switch the ESS-ID2 by the ID switching means ESS-ID1, it is characterized in.
According to such a wireless LAN system, even if a communication error occurs, the station and the second access point can communicate without exchanging the network ID between the first access point and the second access point. Since there is no need to change the MAC address of the destination access point when exchanging the network ID, there is an effect that the control is simplified.
[0014]
A wireless LAN system according to a fifth invention uses one of a wireless communication line and a dedicated communication line instead of a wired LAN.
According to such a wireless LAN system, even if the wired LAN serving as the communication transmission path of the access point is congested, communication between the access points can be performed by a wireless or dedicated communication line, so that a decrease in throughput is suppressed. There is.
[0015]
BEST MODE FOR CARRYING OUT THE INVENTION
Embodiment 1 FIG.
One embodiment of the present invention will be described with reference to FIGS. 1 is an overall view of a wireless LAN system, FIG. 2 is a block diagram showing the inside of access points AP1 and AP2, and FIG. 3 is a block diagram showing the inside of stations STA1, STA2 and STA3.
In FIG. 1, the wireless LAN system performs communication at a normal time as a wired / wireless bridge, and is connected to a first access point and AP1 connected by a wired LAN 41, and to the access point AP1 via the wired LAN 41. In addition, a second access point AP2 serving as a backup for performing detour communication only in an emergency, and STA1 serving as first, second, and third stations serving as wireless terminal stations communicating with the access points AP1 and AP2. The STA2 and the STA3 form an infrastructure mode, and the access points AP1 and AP2 are installed so that the communication range 35 of the access point AP1 and the communication range 36 of the access point AP2 cover substantially the same range. And stations STA1 to STA in communication ranges 35 and 36. 3 is installed.
Note that the channel (frequency band) of the wireless transmission wave is divided into 14 channels in IEEE 802.11, but in the present embodiment, all the access points AP1, AP2, and the stations STA1 to STA3 are set to the same channel. I have.
[0016]
In FIG. 2, access points AP1 and AP2 are a control unit 11 for controlling the whole, a data memory 12 for temporarily storing data to be transmitted, a first memory (access point AP1) for storing an ESS-ID, An ID memory 13 as a second memory (access point AP2), a wireless module 14 for wirelessly transmitting data, and a LAN controller 15 for controlling a wired LAN are provided. ESS-ID1, which is an ID, is stored, and ESS-ID2, which is a network ID, is stored in the ID memory 13 of the access point AP2.
Further, an ID exchange unit is provided for exchanging the ESS-ID between the access point AP1 and the access point AP2, that is, by exchanging the ESS-ID2, the access point AP1 becomes the ESS-ID2 and the access point AP1 becomes the ESS-ID1. .
[0017]
3, stations STA1 to STA3 are provided with a control unit 21 for controlling the whole, a data memory 22 for storing data to be transmitted, an ID memory 23 as a third memory for storing ESS-ID, ESS-ID1 is stored first, and ESS-ID2 is stored second in the ID memory 23 in the ID memory 23.
Further, the stations STA1 to STA3 detect a communication error with the access point AP1, and when the communication error is detected, store the ESS-ID1 of the ID memory 23 and the ESS-ID2 of the ID memory 23 first. ID switching means for performing the switching, and communication means for communicating with the access point AP2 based on the ESS-ID2 switched by the ID switching means.
[0018]
As described above, the wired LAN system normally sets the ESS-ID1 to the first in the ID memory 23 of the stations STA1 to STA3 when the access point AP1 serves as a gateway and communicates with each of the stations STA1 to STA3. The access point AP1 receives the transmission data from the STA1 via the wireless transmission path A, and the station STA2 receives the transmission data from the access point AP1 via the wireless transmission path C.
In the event of a communication error, the access point AP2 sets the first ESS-ID2 in the ID memory 23 of the stations STA1 to STA3 when communicating with the stations STA1 to STA3, and transmits the transmission data from the station STA1. Is received by the access point AP2 via the wireless transmission path B, and the station STA2 receives transmission data from the access point AP2 via the wireless transmission path D. That is, the communication path is duplicated by using the normal access point AP1 and the backup access point AP2 for bypass communication that operates in an emergency.
[0019]
The operation of the wireless LAN system configured as described above will be described with reference to FIGS. FIG. 4 is a flowchart showing the operation of the control unit of the station STA1, and FIGS. 5 and 6 are flowcharts showing the operation of the control unit of the access points AP1 and AP2.
Now, in normal times, the access point AP1 and each of the stations STA1 to STA3 are communicating with each other with the network ID being ESS-ID1. For example, when data is transmitted from the station STA1 to the station STA2, the control unit 21 of the station STA1 reads the transmission data stored in the data memory 22, and adds the MAC address of the station STA2 as the final destination information to the transmission data. The MAC address of the access point AP1 is added to the destination of the access point AP1, and the data to which the ESS-ID1 read from the ID memory 23 is added is transmitted to the access point AP1 through the wireless module 24 of the station STA1 and the wireless transmission path A. Is compared with its own ESS-ID stored in the ID memory 13 and stores the transmitted data in the data memory 12 if they are the same.
[0020]
The control unit 11 of the access point AP1 reads the transmission data from the data memory 12, adds the MAC address of the station STA2 as the final destination to the transmission data, and adds the ESS-ID1 read from the ID memory 13 to the transmission data. The packet is transmitted to the station STA2 through the wireless module 14. The station STA2 receives the transmission data via the wireless transmission path B and the wireless module 24. If the network ID is the same, that is, if the network ID is ESS-ID1, the station STA2 stores the transmitted data in the data memory 22 and transmits the data to the station STA1. Communication to the station STA2 via the access point AP1 is completed.
[0021]
Here, since the communication between the station STA1 and the station STA2 is performed via the access point AP1, a communication error a may occur in the wireless transmission path A or a communication error c may occur in the wireless transmission path C. There is.
<When a communication error a occurs in the wireless transmission path A>
When a communication error a occurs in the wireless transmission path A in the communication from the station SAT1 to the access point AP1, the control unit 21 of the station STA1 receives the "end signal" indicating the end of the communication from the access point AP1 by the detection means. If not, it is determined that the communication error is a (step S101), and retry communication is executed with the access point AP1 (step S103). The control unit 21 of the station STA1 determines again whether or not normal communication has been performed (step S105), and determines whether or not normal communication has been performed even after the specified number of retry transmissions (step S107).
[0022]
When it is determined that the communication error a has occurred even after the retry transmission has been performed the specified number of times, the control unit 21 of the station STA1 stores the data to be communicated with the access point AP2 from the ID memory 23 into the data of the access point AP2. The ESS-ID2 stored as the ESS-ID is read and added (step S109), and the destination MAC address of the packet is changed from the access point AP1 to the access point AP2, and the network ID is changed from the ESS-ID1 to the ESS-ID2 (setting). ) (Step S111). The control unit 21 of the station STA1 transmits a packet including the ESS-ID2 to the access point AP2 (communication means of claim 1, step S113). The control unit 21 of the station STA1 returns (sets) the network ID from the ESS-ID2 to the ESS-ID1 by receiving the “end signal” indicating the end of the communication from the access point AP2 (step S115). This is for fixing the communication for normal use to the access point AP1 and fixing the communication for abnormal use to the access point AP2.
[0023]
The access point AP2 determines whether or not the data transmitted from the station STA1 via the wireless transmission path C transmits the data addressed to itself by detecting and comparing the MAC address AP2 and the ESS-ID included in the data. This is determined while constantly monitoring (step S201). If the data is determined to be addressed to itself, the data is received (step S203), and the received data is stored in the data memory 12 (step S205). The control unit 11 of the access point AP2 requests the access point AP1 to which the ESS-ID1 is set to exchange with the ESS-ID2 set to the access point AP2 via the wired LAN 41. A request signal is transmitted (step S207). The access point AP1 receives the ESS-ID exchange request, stores the ESS-ID2 in the ID memory 13, reads the ESS-ID1 from the ID memory 13, and sends the ESS-ID1 and the "ESS-ID" to the access point AP2 via the wired LAN 41. "Exchange OK" is transmitted (step S209). The control unit 11 of the access point AP2 stores the ESS-ID1 transmitted from the access point AP1 in the ID memory 13, and the ESS-ID exchange is completed.
[0024]
The control unit 11 of the access point AP2 reads out the transmission data stored in the data memory 12, adds destination information to the MAC address of the station STA2, and adds ESS-ID1 as the network ID to the transmission data, and transmits the transmission information to the station STA2 by packet transmission. (Step S211). The station STA2 receives the packet transmitted by the wireless transmission path D, stores the transmission data in the data memory 22, and ends the data transmission from the station STA1 to the station STA2. In this state, since the access point AP1 and the access point AP2 exchange ESS-IDs, the access point AP becomes the access point AP2 that performs normal communication, and becomes the standby access point AP1 for the detour path when communication is abnormal.
Note that the access point AP2 issues an ESS-ID exchange renewal request, and if the ESS-ID exchange acknowledgment is not returned from the access point AP1, the network ID is changed to ESS-ID1 by simulating that the access point AP1 has failed. Communication can be continued. If the access point AP1 fails, no interference occurs.
[0025]
In the communication between the station STA1 and the station STA2 via the access point AP1 as in the above embodiment, when a communication error a occurs on the wireless transmission path A, the station STA1 detects the communication error a, and the station STA1 transmits the ESS. -Change (set) ID1 to ESS-ID2 and transmit data to the access point AP2 for detour communication, and the access point AP2 stores the data in the data memory 12. The access point AP2 transmits an ESS-ID exchange request to the access point AP1 via the wired LAN 41 to exchange the network ID of the access point AP1, that is, the access point AP2 is changed to the ESS-ID1, and the access point AP1 is changed to the access point AP1. Is exchanged for ESS-ID2, and data transmission is performed to the station STA2 of the final destination.
Therefore, by always making the backup access point AP2 stand by other than the access point AP1 that normally communicates, and operating the network IDs of the access points AP1 and AP2, even if a communication error occurs, the access point AP2 allows the detour communication path. Can be set and communication can be continued.
Moreover, even in an emergency, since the network IDs of the access points AP1 and AP2 are different, it is possible to prevent interference when the stations STA1 to STA3 communicate with the access points AP1 and AP2.
[0026]
<When a communication error c occurs in the wireless transmission path C>
Next, although the communication from the station STA1 to the access point AP1 is performed normally, but a communication error c occurs in the wireless transmission path C from the access point AP1 to the final destination station STA2, the control unit 11 of the access point AP1 By not receiving the “end signal” indicating the end of communication from the station STA1, it is determined that the communication error is c (step S301), and the control unit 11 of the access point AP1 sends the above-mentioned signal to the access point AP2 via the wired LAN 41. Thus, a signal of "ESS-ID exchange request" requesting to exchange the ESS-ID is transmitted (step S307).
[0027]
The access point AP2 receives the ESS-ID exchange request, executes the ESS-ID exchange, transmits “ESS-ID exchange acknowledgement” to the access point AP1 via the wired LAN 41 (step S309), and after the ESS-ID exchange, The access point AP1 transmits data obtained by adding the MAC address of the station STA2 as final destination information to the transmission data received from the station STA1 to the access point AP2 via the wired LAN 41 (step S311). The access point AP2 that has received the data transmits the transmission data to the station STA2, which is the final destination, by ESS-ID1, and the station STA2 receives the transmission data (step S313).
Note that the access point AP1 may be executed in place of steps S307, S309, and S311. That is, to the transmission data received from the station STA1, an ESS-ID exchange request, the ESS-ID1 of its own network ID, and the MAC address of the station STA2 as the final destination are added to the access point AP2 via the wired LAN. To send data. The access point AP2 receives the data, stores the ESS-ID1 in the ID memory 12, reads out the ESS-ID2 stored so far, and sends an ESS-ID exchange approval together with the ESS-ID2 to the access point AP1. You may reply.
[0028]
When a communication error c occurs in the wireless transmission path C from the access point AP1 to the station STA2 of the final destination as described above, the access point AP1 and the access point AP2 exchange their network IDs via the wired LAN 41, That is, the network ID of the access point AP1 is changed from ESS-ID1 to ESS-ID2, and the network ID of the access point AP2 is changed from ESS-ID2 to ESS-ID1. The access point AP1 adds the MAC address of the station STA2 as final destination information to the transmission data received from the station STA1, and transmits the transmission data to the access point AP2 via the wired LAN 41. The access point AP2 determines the final destination based on the ESS-ID. Data transfer is performed to the station STA2.
Therefore, even if a communication error occurs in the communication between the station STA1 and the access point AP1, the communication can be continuously performed by the access point AP2 and the stations STA1 and STA2. Furthermore, since one of the access points AP1 and AP2 becomes the standby access point AP, the radio waves of communication do not collide, and the throughput does not decrease, thereby improving the reliability of communication. Moreover, since the communication identification number is fixedly set, the station STA does not need a function for determining the priority of the access point AP. Therefore, a highly reliable dual communication system can be obtained.
[0029]
In the above embodiment, the access points AP1 and AP2 and the stations STA1 to STA3 are set to the same wireless channel. However, control is performed so that the communication group of the access point AP1 and the channel used by the communication group of the access point AP2 are separated. This can reduce the collision of wireless signals and improve the throughput.
[0030]
Embodiment 2 FIG.
In the first embodiment, since the network IDs of the access point AP1 for normal communication and the standby access point AP2 for bypass communication are exchanged due to communication errors a and c, the control is complicated.
Therefore, the second embodiment has the effects of the first embodiment and is made to solve the above-mentioned problem. This embodiment will be described with reference to FIG. FIG. 7 is an overall view of the wireless LAN system. In FIG. 7, the same reference numerals as those in FIG. 1 denote the same or corresponding parts, and a description thereof will be omitted.
[0031]
The configuration of the wireless LAN system in FIG. 7 is almost the same as that of the first embodiment. In the access point AP2, each station STA1 and STA2 is changed from ESS-ID1 to ESS-ID2 based on communication errors a and c. ESS-ID change command.
[0032]
The operation of the wireless LAN system configured as described above will be described with reference to FIGS.
<When a communication error a occurs in the wireless transmission path A>
When a communication error a occurs during data transmission from the station STA1 to the access point AP1, the station STA1 transmits data to the access point AP2 by ESS-ID2 as shown in the flowchart of FIG. 4, as in the first embodiment. (Steps S101 to S115). The access point AP2 constantly monitors whether data transmitted from the station STA1 via the wireless transmission path C is data addressed to itself by detecting data of the MAC address AP2 and ESS-ID2 included in the data. While determining (step S401), if the data is determined to be addressed to itself, the data is received (step S403), and the received data is stored in the data memory 12 (step S405). The control unit 11 of the access point AP2 transmits a “ESS-ID change command” for changing the network ID for constantly communicating from all stations STA1 to STA3 existing in the communicable range from ESS-ID1 to ESS-ID2. (Step S407). The stations STA1 to STA3 receive the command and store the normal communication in the ID memory 23 in the ESS-ID2 and store the bypass communication in the ESS-ID1. The access point AP2 executes data transmission to the station STA2, which is the final destination, using ESS-ID2 (step S409).
[0033]
When the communication error a occurs, the station STA1 changes the network ID from ESS-ID1 to ESS-ID2 and transmits data to the access point AP2, and the access point AP2 transmits an ESS-ID change command to the stations STA1 to STA1. The access point AP2 transmits the data to the STA3 and changes the network ID of the stations STA1 to STA3 to the same ESS-ID2 as that of the access point AP2.
[0034]
<When a communication error c occurs in the wireless transmission path C>
Next, although the communication from the station STA1 to the access point AP1 is performed normally, but a communication error c occurs in the wireless transmission path C from the access point AP1 to the final destination station STA2, the control unit 11 of the access point AP1 By not receiving the “end signal” indicating the end of communication from the station STA1, it is determined that the communication error is c (step S501), and the access point AP1 sends the transmission data received from the station STA1 via the wired LAN 41 to the station STA1 as final destination information. The access point AP2 receives the transmission data by adding the MAC address of the STA2 to the access point AP2 (step S507), and constantly communicates with all the stations STA1 to STA3 existing within the communicable range. Sending a Ttowaku ID from ESS-ID1 of the ESS-ID change command for changing the ESS-ID2 (step S509). The access point AP2 transmits data to the station STA2 (step S511).
[0035]
Even if the communication error c occurs in this way, the access point AP2 transmits the ESS-ID change command to change the network ID of each station STA that constantly communicates to the same ESS-ID2 as the access point AP2. The point AP2 can transmit data to the final destination station STA2 by ESS-ID2, and can continuously execute communication. Moreover, as described in the first embodiment, it is not necessary to exchange the network IDs of the access point AP1 and the standby access point AP2 for the detour communication, so that the control is simplified.
[0036]
Embodiment 3 FIG.
Another embodiment of the present invention will be described with reference to FIG. The difference between the present embodiment and the first and second embodiments is that the access point AP2 has a function of notifying the access point AP1 which normally communicates that the communication is performed by ESS-ID1. The point is that it communicates with the station STA.
In FIG. 10, the wireless LAN system transmits an ESS-ID use notification command to the access point AP1 to the access point AP2, and transmits an ESS-ID use permission response to the access point AP2 to the access point AP1. Has a function.
With such a command and response, the access point AP2 is configured to obtain the right to use the ESS-ID1 set in the access point AP1 and communicate with each station STA in which the ESS-ID1 is set. I have.
[0037]
As in the first embodiment, a communication error a occurs in the wireless transmission path A in the communication from the station STA1 to the access point AP1.
<When a communication error a occurs in the wireless transmission path A>
When the station STA1 detects a communication error a during data transmission to the access point AP1, the station STA1 changes the network ID to ESS-ID2 and transmits data to the access point AP2. Upon receiving this, the access point AP2 transmits an ESS-ID use notification command to the access point AP1 via the wired LAN 41. Upon receiving the command, the access point AP1 stops its wireless output only, and returns an ESS-ID use permission response and its own ESS-ID1 to the access point AP2 with the wired output activated. . Here, the reason why the access point AP1 stops its wireless output before returning the ESS-ID use permission response is to prevent interference with the access point AP2.
[0038]
Since the access point AP2 receives the ESS-ID use permission response and receives the ESS-ID1 use permission, the access point AP2 transmits data to the final destination station STA2 via the wireless transmission path D using the ESS-ID1. When the communication to the station STA2 ends normally, the access point AP2 notifies the access point AP1 of the end of the use of the ESS-ID1 via the wired LAN 41, thereby releasing the wireless output stop of the access point AP1 and returning to the normal operation. .
In addition, even if the ESS-ID use notification command is issued, if the ESS-ID use permission response is not returned from the access point AP of the other party, the access point AP of the transmission source considers that the access point AP of the other party has failed, and Communication can be continued by changing the ID.
[0039]
Next, a case will be described in which the communication from the station STA1 to the access point AP1 is normally performed, but the communication from the access point AP1 to the final destination station STA2, that is, a communication error c occurs in the wireless transmission path C.
<When a communication error c occurs in the wireless transmission path C>
When detecting the communication error c with the station STA2, the access point AP1 adds the MAC address of the station STA2, which is the final destination, the ESS-ID use permission response, and its own ESS to the transmission data received from the station STA1 toward the access point AP2. -Add ID1 and transmit it to the access point AP2 via the wired LAN 41, and simultaneously stop its own wireless output. The access point AP2 receives this, and obtains the transmission data for the station STA2 and the permission to use the ESS-ID1, so that the transmission data is transferred to the final destination station STA2 using the ESS-ID1. When the communication to the station STA2 ends normally, the access point AP2 notifies the access point AP1 of the end of the use of the ESS-ID1 via the wired LAN 41, thereby releasing the wireless output stop of the access point AP1 and returning to the normal operation. .
[0040]
Even when the communication errors a and c occur as described in the above embodiment, the access point AP1 stops the output of the normally operating access point AP1 by the ESS-ID use notification command, and the ESS capable of communicating with the station STA2. -Communication can be continuously performed using ID1, and a highly reliable duplex communication system can be obtained.
[0041]
Embodiment 4 FIG.
In the first to third embodiments, the ESS-ID change request, the ESS-ID change permission, the ESS-ID use notification command, the ESS-ID use permission response, and the transmission via the wireless or dedicated communication line instead of the wired LAN 41 The access point AP1 and the backup access point AP2 that transmit and receive data and perform normal communication are changed. Thereby, even if the wired LAN communication between the access point AP1 and the access point AP2 is congested, the above-mentioned ESS-ID change request and the like can be communicated through a wireless or dedicated communication line, so that the wireless LAN system in which the throughput is hardly reduced is realized. Obtainable.
[0042]
In the first to fourth embodiments, as shown in FIG. 11, the access point AP1 and the access point AP2 are arranged so as to sandwich each station STA. At this time, even if there is a communication failure 42 between the access point AP1 and each station STA, communication can be continuously performed through the access point AP2, and a highly reliable duplex communication system can be constructed. .
[Brief description of the drawings]
FIG. 1 is an overall configuration diagram of a wireless LAN system according to an embodiment of the present invention.
FIG. 2 is an internal configuration diagram of access points AP1 and AP2 shown in FIG.
FIG. 3 is an internal configuration diagram of stations STA1 to STA3 shown in FIG.
FIG. 4 is a flowchart showing an operation of the station STA1 shown in FIG.
FIG. 5 is a flowchart showing an operation of the access point AP2 shown in FIG.
FIG. 6 is a flowchart showing an operation of access points AP1 and AP2 shown in FIG.
FIG. 7 is an overall configuration diagram of a wireless LAN system showing another embodiment.
8 is a flowchart showing an operation of the access point AP2 shown in FIG.
FIG. 9 is a flowchart showing an operation of the access points AP1 and AP2 shown in FIG.
FIG. 10 is an overall configuration diagram of a wireless LAN system according to another embodiment.
FIG. 11 is an overall configuration diagram of a wireless LAN system according to another embodiment.
FIG. 12 is an overall configuration diagram of a wireless LAN system showing a first related art.
FIG. 13 is an overall configuration diagram of a wireless LAN system showing a second related art.
[Explanation of symbols]
AP1 First access point (wireless base station), AP2 Second access point (wireless base station), STA1, STA2, STA3 station, 13 ID memory (first and second memory), 23 ID memory (third) Memory).

Claims (5)

An access point and a station are configured in an infrastructure mode, and a dual communication path is formed by including a first access point that normally performs communication and a second access point that is a backup of the first access point. A wireless LAN system,
A first memory in which an ESS-ID1, which is a first network ID, is stored in the first access point;
The second access point includes a second memory storing an ESS-ID2 that is a second network ID;
A third memory in which the network IDs ESS-ID1 and ESS-ID2 are stored;
Detecting means for detecting a communication error with the first access point;
ID switching means for switching from the ESS-ID1 to the ESS-ID2 when the communication error is detected;
Communication means for communicating with the second access point based on the ESS-ID2 switched by the ID switching means.
A wireless LAN system characterized by the above. It has a wired LAN for communicating the first access point and the second access point, and comprises ID exchange means for exchanging the ESS-ID of each other,
When the communication unit detects the communication error, the station switches from the ESS-ID1 to the ESS-ID2 by the ID switching unit, and communicates with the second access point.
The second access point issues an ESS-ID exchange request to the first access point by the ID exchange means via the wired LAN, and the first and second access points exchange ESS-IDs with each other. Exchange ID,
The station which has switched the ESS-ID2 switches the ESS-ID2 to the ESS-ID1 by the ID switching means.
The communication method for a wireless LAN system according to claim 1, wherein: The first and second access points have command transmission means for transmitting a command to the stations within a communication range to change an ESS-ID,
When the communication unit detects the communication error, the station switches from the ESS-ID1 to the ESS-ID2 by the ID switching unit, and communicates with the second access point.
The second access point transmits the command to the station by the command transmission unit,
The communication method according to claim 1, wherein the station receiving the command switches the ESS-ID to the ESS-ID2 according to the command. A wired LAN for communicating between the first access point and the second access point,
The second access point has a notifying unit for notifying the first access point that communication is performed with the ESS-ID1,
When the communication unit detects a communication error, the station switches from ESS-ID1 to ESS-ID2 by the ID switching unit, and communicates with the second access point.
The second access point notifies the first access point via the wired LAN that communication is to be performed using ESS-ID1 by the notification unit,
The first access point that has received the notification stops radio output,
The station which has switched the ESS-ID2 switches the ESS-ID2 to the ESS-ID1 by the ID switching means.
The communication method for a wireless LAN system according to claim 1, wherein: Instead of the wired LAN, it is one of a wireless communication line and a dedicated communication line,
The wireless LAN system according to claim 2 or 4, wherein:

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