JP2018064289A - Transmission device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wireless LAN system and a radio communication device that can shorten a search time to search for another base station different from a base station during connection.SOLUTION: A radio terminal 10a switches a frequency from a first frequency to a second frequency used by a yet-to-be connected base station 20c, and transmits a probe request message M1 0r to the yet-to-be connected base station 20c. The yet-to-be connected base station 20c transmits a probe response message M11r to the radio terminal 10a using a second frequency by radio. The yet-to-be connected base station 20c transmits a probe redundant response message M12 to a connected base station 20a by cable via a wired LAN. The connected base station 20a transmits the probe redundant response message M12 to the radio terminal 10a using a first frequency by radio.SELECTED DRAWING: Figure 12

Description

  The present invention relates to a transmission apparatus that performs wireless communication.

In a wireless LAN system standardized by IEEE802.11, roaming is performed in which a base station to which a wireless communication device (wireless terminal) is connected is switched from a connected base station to another base station. For example, when the reception level of radio waves from a connected base station is lowered and communication quality cannot be ensured, the base station can be switched to a base station that can ensure better communication quality.

When roaming is performed, before switching from a connected base station to another base station, another base station that is a candidate for switching is searched, and information on the other base station is acquired in advance. As a result, the switching time for switching from the connected base station to another base station can be shortened.

As a method for a wireless terminal to search for a base station, there are an active scan in which the wireless terminal transmits a probe request message and a passive scan in which the wireless terminal waits until it receives a beacon transmitted from the base station.

In the active scan, when the wireless terminal receives a probe response message from the base station within a time period referred to as MinChannelTime, the search must be continued until the time period referred to as MaxChannelTime has elapsed. Therefore, when no other base station is found, the time difference between MaxChannelTime and MinChannelTime becomes a useless waiting time.

In a passive scan, the search must continue throughout MaxChannelTime. Therefore, when no other base station is found, MaxChannelTime becomes a useless waiting time.

JP 2006-93945 A JP 2009-141981

The wireless terminal searches for a base station at a frequency different from the frequency used for transmission / reception with the connected base station. Therefore, data communication is delayed while searching for a base station. Therefore, it is required to shorten the search time for the base station as much as possible. In particular, when a voice call with a high real-time property is performed using a wireless LAN system, a long search time adversely affects the call quality, and thus it is necessary to shorten the search time as much as possible.

In order to meet such a demand, an object of the present invention is to provide a wireless LAN system and a wireless communication apparatus capable of shortening a search time for searching for another base station different from the currently connected base station. .

In order to solve the above-described problems of the related art, the present invention transmits a first probe response message to the wireless terminal in response to reception of a probe request message from the wireless terminal, and other transmissions. Provided is a transmission device that transmits a second probe response message to the wireless terminal via the device.

According to the wireless LAN system and the wireless communication apparatus of the present invention, it is possible to shorten the search time for searching for another base station different from the connected base station.

1 is a diagram illustrating an overall schematic configuration of a wireless LAN system according to an embodiment. 1 is a block diagram illustrating a specific internal configuration of a wireless terminal that is a wireless communication apparatus according to an embodiment and constitutes a wireless LAN system. FIG. 1 is a block diagram illustrating a specific internal configuration of a base station that is a wireless communication apparatus according to an embodiment and constitutes a wireless LAN system. FIG. It is a sequence diagram which shows the message flow which acquires the information of a base station, before a wireless terminal searches a base station. It is a figure which shows the structural example of the other base station information request message which a radio | wireless terminal transmits to the connected base station. It is a flowchart which shows the process which the base station which received the other base station information request message performs. It is a figure which shows the structural example of the base station information request message which the base station which received the other base station information request message transmits to another base station. It is a figure which shows the structural example of the base station information response message which the other base station which received the base station information request message transmits to the base station which transmitted the base station information request message. It is a figure which shows the structural example of the base station information which the base station which received the base station information response message produces | generates. It is a flowchart which shows the process which the base station which received the base station information request message performs. It is a flowchart which shows the whole process in which a wireless terminal searches for a base station. It is a sequence diagram which shows the message flow for the base station search when the base station search method is set to the active scan. It is a figure which shows the structural example of the probe request message transmitted when a radio | wireless terminal searches a base station. It is a flowchart which shows the process which the base station which received the probe request message performs. It is a figure which shows the structural example of the probe redundant response message which the base station which received the probe request message transmits to the wireless terminal which transmitted the probe request message. It is a figure which shows the structural example of the base station information which a radio | wireless terminal produces | generates and preserve | saves in a base station database. It is a sequence diagram which shows the message flow for the base station search in case the base station search method is set to the passive scan. It is a figure which shows the structural example of the beacon transmission timing request message which a wireless terminal transmits to another base station. It is a flowchart which shows the process which a radio | wireless terminal selects the beacon transmission timing which another base station transmits. It is a figure which shows the structural example of the beacon transmission response message which the other base station which received the beacon transmission timing request message transmits to a wireless terminal. It is a figure which shows the structural example of the selection beacon transmission timing notification message which a wireless terminal transmits to another base station. It is a flowchart which shows the process which judges whether another base station transmits the message which shows transmission permission with respect to a radio | wireless terminal. It is a figure which shows the structural example of the neighbor base station information notification message which a radio | wireless terminal transmits to a base station. It is a flowchart which shows a process when a base station receives a neighboring base station information notification message. It is a figure which shows the structural example of the neighbor base station information response message which a base station transmits to a radio | wireless terminal. It is a figure which shows the structural example of the signal level request message which a radio | wireless terminal transmits to a base station. It is a figure which shows the structural example of the signal level response message which a base station transmits to a radio | wireless terminal.

Hereinafter, a wireless LAN system and a wireless communication apparatus according to an embodiment will be described with reference to the accompanying drawings. In the wireless communication apparatus according to the embodiment, it is assumed that either active scan or passive scan is set as a base station search method.

The wireless communication apparatus according to one embodiment can select between active scan and passive scan, but may employ only active scan or only passive scan.

First, an overall schematic configuration of a wireless LAN system according to an embodiment will be described with reference to FIG. In FIG. 1, a wireless LAN system includes wireless terminals 10a and 10b, a base station 20
a, 20b, and 20c. The base stations 20a to 20c are connected to each other by a wired LAN 30. There are one or more wireless terminals. There may be a plurality of base stations. The wireless terminals 10a and 10b are wireless communication devices according to an embodiment.

The wireless terminals 10a and 10b are collectively referred to as a wireless terminal 10. An arbitrary wireless terminal that does not specify one of the wireless terminals 10a and 10b may be referred to as a wireless terminal 10. Base stations 20a-20
c is collectively referred to as base station 20. An arbitrary base station that does not specify any of the base stations 20a to 20c may be referred to as a base station 20.

The radio wave emitted from each of the base stations 20a to 20c is a radio wave reachable range indicated by a one-dot chain line.
Assume that 200a, 200b, and 200c are reached. In the example shown in FIG. 1, the radio terminal 10a
The wireless terminal 10b is in only the radio wave reachable range 200b.
In the following description, it is assumed that the radio terminal 10a is connected to the base station 20a, and the radio terminal 10b is connected to the base station 20b.

FIG. 2 shows a specific internal configuration of the wireless terminal 10. The wireless terminal 10 includes a wireless communication unit 101
, Base station information acquisition unit 102, base station search unit 103, beacon reception processing unit 104, beacon synchronization processing unit 105, and base station information management unit 106.

The wireless communication unit 101 processes data transmission / reception with the base station 20 by wireless. The base station information acquisition unit 102 requests and acquires information of other base stations 20 connected to the connected base station 20 via the wired LAN 30. At this time, the base station information acquisition unit 102 generates another base station information request message to be transmitted to the connected base station 20. The base station search unit 103 executes processing for searching for a base station 20 other than the connected base station 20.

The beacon reception processing unit 104 executes processing for receiving a beacon transmitted by the base station 20. The beacon is information necessary for the wireless terminal 10 to start a connection with the base station 20.

The beacon synchronization processing unit 105 determines the timing for searching for the base station 20 based on the transmission timing of the beacon transmitted by the base station 20 using the frequency for executing the search. The base station information management unit 106 manages the information on the base station 20 acquired by the base station search unit 103.

FIG. 3 shows a specific internal configuration of the base station 20. The base station 20 includes a wireless communication unit 201, a base station information processing unit 202, a base station information management unit 203, a base station search response unit 204, a beacon transmission processing unit 205, and a beacon synchronization processing unit 206.

The wireless communication unit 201 processes data transmission / reception with the wireless terminal 10 by wireless. The base station information processing unit 202 receives the other base station information request message transmitted from the wireless terminal 10 and transmits the other base station information request message to the other base station 20 through the wired LAN 30. The base station information processing unit 202 receives the information of the other base station 20 transmitted from the other base station 20 in response to the other base station information request message.

The base station information management unit 203 accumulates and manages information on other base stations 20 received by the base station information processing unit 202. The base station information management unit 203 has a base station database (base station DB).

The base station search response unit 204 processes the probe request message transmitted from the wireless terminal 10. The beacon transmission processing unit 205 executes processing for transmitting a beacon. The beacon synchronization processing unit 206 manages beacon transmission timing.

In order to search for the base station 20, the wireless terminal 10 acquires in advance information about the base station 20 connected to the wired LAN 30 via the currently connected base station 20. FIG. 4 shows the base station 20a.
2 shows a message flow in which the wireless terminal 10a connected to the terminal acquires base station information of the base stations 20b and 20c.

In FIG. 4, the radio terminal 10a transmits another base station information request message M01r generated by the base station information acquisition unit 102 to the base station 20a by the radio communication unit 101. In each transmission / reception message shown in FIG. 4, the message with the subscript “r” indicates that the message is a wireless message, and the message with the subscript “w” indicates a wired LAN.
30 indicates that the message is transmitted / received via 30.

The radio communication unit 201 in the base station 20a receives the other base station information request message M01r, and the base station information processing unit 202 processes the other base station information request message M01r. FIG. 5 is a configuration example of the other base station information request message M01r. As shown in FIG. 5, the other base station information request message M01r includes another base station information request ID 011, a request frequency 012, a request SSID 013, and a cache flag 014.

The other base station information request message M01r may be transmitted in the form of an IP packet or may be transmitted as probe request data. When transmitting as probe request data, it may be transmitted as an information element included in probe request data. The message is transmitted in the form of an IP packet or an information element as well as other messages.

The other base station information request ID 011 indicates that the message is another base station information request message. The required frequency 012 indicates the frequency of the base station 20 from which information is to be acquired. The base station 20 designated by the required frequency 012 may have only one frequency or a plurality of frequencies.

The request SSID 013 indicates the SSID of the base station 20 from which information is to be acquired. There may be only one SSID of the base station 20 specified by the request SSID 013, or a plurality of SSIDs. The cache flag 014 indicates the base station information held by the base station 20a to the other base station information request message M01r.
Is a flag that specifies whether or not to reply as a response.

FIG. 6 shows processing executed by the base station information processing unit 202 when the base station 20a receives the other base station information request message M01r. The base station information processing unit 202 performs step S
At 101, another base station information request message M01r is received. In step S102, the base station information processing unit 202 determines whether or not a cache is requested by checking the cache flag 014. The cache request is that the wireless terminal 10a requests the base station information already held by the base station 20a as a response.

If the cache is not requested (NO), the base station information processing unit 202 performs step S103.
Then, as shown in FIG. 4, a base station information request message M02w is transmitted to the base station 20b, and a base station information request message M03w is transmitted to the base station 20c.

FIG. 7 is a configuration example of the base station information request messages M02w and M03w. As shown in FIG. 7A, the base station information request message M02w includes a base station information request ID 021 and a request frequency 022.
, Request SSID 023. As shown in FIG. 7B, the base station information request message M03w includes a base station information request ID 031, a request frequency 032, and a request SSID 033.

Base station information request ID021,031 indicates that the message is a base station information request message. The requested frequencies 022 and 032 indicate the frequencies of the base station 20 from which information is to be acquired. Each of the base stations 20 designated by the required frequencies 022 and 032 may have only one frequency or a plurality of frequencies.

The request SSIDs 023 and 033 indicate the SSID of the base station 20 from which information is to be acquired. Request SSID02
Each SSID of the base station 20 designated by 3,033 may be only one or plural.

In FIG. 6, the base station information processing unit 202 determines whether or not the base station information response messages M04w and M05w shown in FIG. 4 have been received in step S104.

FIG. 8 is a configuration example of the base station information response messages M04w and M05w. As shown in FIG. 8A, the base station information response message M04w includes a base station information response ID041, a base station IP address 042, a base station frequency 043, a base station SSID044, and a base station BSSID045. As shown in FIG. 8B, the base station information response message M05w includes a base station information response ID051, a base station IP address 052, a base station frequency 053, a base station SSID054, and a base station BSSID055.
including.

Base station information response ID041,051 shows that a message is a base station information response message. Base station IP addresses 042 and 052 indicate the IP addresses of the base stations 20b and 20c, respectively. Base station frequencies 043 and 053 are respectively base stations 20b and 20c.
Indicates the frequency used.

Base station SSID 044, 054 indicates the SSID of base station 20. Base station SSID is base station 20a ~
20c is common. Base stations BSSID045 and 055 are respectively base stations 20b and 20c.
Indicates the BSSID. The base station BSSID is different for each of the base stations 20a to 20c. The base station BSSID corresponds to the MAC address of the base station 20.

Returning to FIG. 6, the base station information processing unit 202 performs the base station information response message M in step S104.
If 04w and M05w are received (YES), the base station information processing unit 202 generates base station information Ibs04 and Ibs05 shown in FIG. 9 based on the base station information response messages M04w and M05w in step S105. It is transferred to the information management unit 203 for storage. FIG. 9 is a configuration example of the base station information Ibs04 and Ibs05.

The base station information management unit 203 stores the base station information Ibs04 and Ibs05 in the base station DB. The base station DB can store one or a plurality of base station information.

As shown in FIG. 9A, the base station information Ibs04 generated based on the base station information response message M04w includes a base station IP address 142, a base station frequency 143, a base station SSID 144, a base station BSSID 145, and neighboring base stations. Candidates 146 are included. The base station IP address 142, the base station frequency 143, the base station SSID 144, and the base station BSSID 145 are respectively the base station IP address 042, the base station frequency 043, the base station SSID044, and the base station BSSID04 shown in FIG.
The same contents as 5.

As shown in FIG. 9B, the base station information Ibs05 generated based on the base station information response message M05w includes a base station IP address 152, a base station frequency 153, a base station SSID 154, a base station BSSID 155, and neighboring base stations. Candidates 156 are included. The base station IP address 152, the base station frequency 153, the base station SSID 154, and the base station BSSID 155 are respectively the base station IP address 052, the base station frequency 053, the base station SSID 054, and the base station BSSID 05 shown in FIG.
The same contents as 5.

The neighboring base station candidates 146 and 156 are data indicating base stations that are candidates for base stations arranged in the vicinity of the base station 20a.

Returning to FIG. 6 again, in step S106, the base station information processing unit 202 transmits the acquired list of base station information Ibs04 and Ibs05 to the radio terminal 10a as another base station information response message M06r as shown in FIG. To finish the process.

On the other hand, if the cache is requested in step S102 (YES), the base station information processing unit 20
2 determines in step S107 whether or not the base station DB exists in the base station information management unit 203. If the base station DB exists (YES), the base station information processing unit 202 shifts the process to step S106, and if the base station DB does not exist (NO), shifts the process to step S103.

If the base station information processing unit 202 does not receive the base station information response messages M04w and M05w in step S104 (NO), the base station information processing unit 202 shifts the processing to step S106.

FIG. 10 shows processing executed by the base station information processing unit 202 when the base stations 20b and 20c receive the base station information request messages M02w and M03w. In FIG. 10, the base station information processing unit 202 of the base stations 20b and 20c receives base station information request messages M02w and M03w in step S201.

In step S202, the base station information processing unit 202 performs base station information request messages M02w and M03.
It is determined whether or not the conditions specified by the request frequencies 022 and 032 and the request SSIDs 023 and 033 included in w match. If the condition is met (YES), the base station information processing unit 202 transmits base station information response messages M04w and M05w to the base station 20a in step S203, and ends the processing. If the condition is not met (NO), the base station information processing unit 202 ends the process as it is.

FIG. 11 shows an operation in which the radio terminal 10a searches for the base station 20. Wireless terminal 10a
In step S301, the base station information acquisition unit 102 transmits another base station information request message M01r to the base station 20a to request acquisition of other base station information. In step S302, the base station information acquisition unit 102 receives the other base station information response message M06r and determines whether the base station information has been acquired.

If the base station information is not acquired (NO), the base station information acquisition unit 102 determines whether or not to transmit another base station information request message M01r in step S310. If it is set to transmit the other base station information request message M01r not only once but multiple times, it is further determined in step S310 that the other base station information request message M01r is further transmitted (YES).
In this case, the base station information acquisition unit 102 returns the process to step S301.

If the other base station information request message M01r is set to be transmitted only once,
In step S310, it is further determined that the other base station information request message M01r is not transmitted (NO). In this case, the base station information acquisition unit 102 ends the process. The number of times of transmitting the other base station information request message M01r may be set to a predetermined number.

If the base station information is acquired in step S302 (YES), the base station search unit 103 determines in step S303 whether the base station search method is set to active scan.
Whether the base station search method is set to active scan or passive scan can be set by software. If the active scan is set (YES), the base station search unit 103 executes the processes of steps S304 to S307.

The processes in steps S304 and S305 indicate an operation of searching for a base station 20 other than the base station 20a by active scanning when the wireless terminal 10a is connected to the base station 20a. The base station search unit 103 uses the acquired base station information to execute processing for searching for a base station 20 other than the base station 20a as follows.

In step S304, the base station search unit 103 searches for the probe request message M10 shown in FIG.
r is transmitted at the frequency used by the base station 20c. FIG. 13 shows a probe request message M
This is a configuration example of 10r. As shown in FIG. 13, the probe request message M10r includes a search redundancy request ID 1001, a slave unit IP address 1002, and a redundancy response flag 1003.

The search redundancy request ID 1001 indicates that the base station 20 is a probe request message including a flag that specifies whether or not to transmit a probe response message to the probe request message M10r not only wirelessly but also via the wired LAN 30. Remote device IP address 1002 is wireless terminal 1
Indicates the IP address of 0a. The redundant response flag 1003 indicates whether the wireless terminal 10a requests reception of the probe response message via the currently connected base station 20a using the wired LAN 30 as well as wireless.

The wireless terminal 10a exists within the radio wave reachable range 200c of the base station 20c. Therefore, base station 2
The base station search response unit 204 of 0c performs the probe request message M1 by the process shown in FIG.
0r is received, and a probe response message M11r is transmitted to the wireless terminal 10a.

In FIG. 14, the base station search response unit 204 receives a probe request message M10r which is a base station search request in step S401. The base station search response unit 204 executes step S40.
At 2, a probe response message M11r, which is a base station search response, is transmitted to the wireless terminal 10a.

In step S403, the base station search response unit 204 receives the received probe request message M10.
If the redundant response flag 1003 is set in r (YES), in step S404, the probe redundant response message M12 shown in FIG. 12 is wirelessly transmitted as a base station search redundant response via the base station 20a using the wired LAN 30. It transmits to the terminal 10a.

At this time, the base station search response unit 204 transmits the probe redundancy response message M12 to the radio terminal 10a without retransmitting the probe response message M11r even if the confirmation response message of the probe response message M11r is not received.

As shown in FIG. 12, the probe redundancy response message M12 is transmitted from the base station 20c to the base station 2
It consists of a wired transmission message M12w via the wired LAN 30 to 0a and a wireless wireless transmission message M12r from the base station 20a to the wireless terminal 10a.

In step S403, if the redundant response flag 1003 is not set in the received probe request message M10r (NO), the base station search response unit 204 ends the process.

FIG. 15 is a configuration example of the probe redundancy response message M12. As shown in FIG. 15, the probe redundancy response message M12 includes the received signal level 121 and the probe response message 12.
2 is encapsulated in the IP packet 120. The reception signal level 121 is a reception signal level when the base station 20c receives the probe request message M10r. The probe response message 122 has the same content as the probe response message M11r.

Returning to FIG. 11, in step S305, the base station search unit 103 searches for the probe response message M.
It is determined whether 11r or the probe redundancy response message M12 (wireless transmission message Mr12) has been received. If any of these is received (YES), the base station search unit 103, in step S306, receives the received probe response message M11r or probe redundant response message M12.
Based on the above, base station information Ibs10 shown in FIG. 16 is generated and stored in the base station DB.

As shown in FIG. 16, the base station information Ibs10 includes a base station frequency 1013, a base station SSID 1014, a base station BSSID 1015, and a signal level history 1017.

The base station frequency 1013, the base station SSID 1014, and the base station BSSID 1015 are the base station frequency 15 of the base station information Ibs05 shown in FIG. 9B acquired by the other base station information response message M06r in FIG.
3, base station SSID 154 and base station BSSID 155. The signal level history 1017 is a value obtained from the signal level when the probe response message M11r is received or the received signal level 121 included in the probe redundant response message M12. There may be one signal level history 1017 or a plurality of signal level histories 1017.

Even if the wireless terminal 10a does not receive the probe response message M11r by wireless, the priority L
By receiving the probe redundancy response message M12 sent via AN30,
The base station information of the base station 20c can be acquired. Therefore, since the radio terminal 10a can return to the original frequency in use in communication with the base station 20a without waiting for the probe response message M11r, the radio terminal 10a can operate at the frequency of the base station 20c. It can be shortened.

If the probe redundant response message M12 is received first and the probe response message M11r is received later, the probe response message M11 is sent in response to the probe redundant response message M12.
You can overwrite r.

  Step S307 following step S306 will be described later.

On the other hand, in FIG. 11, if the base station search method is not set to active scan in step S303 (NO), the base station search unit 103 performs steps S308, S309, S306, S3.
The process of 07 is executed.

The processes in steps S308 and S309 indicate an operation of searching for a base station 20 other than the base station 20a by passive scanning when the wireless terminal 10a is connected to the base station 20a. The base station search unit 103 uses the acquired base station information to execute processing for searching for a base station 20 other than the base station 20a as follows.

The beacon synchronization processing unit 105 of the wireless terminal 10a executes beacon synchronization reception processing in step S308. As shown in FIG. 17, the beacon synchronization processing unit 105 transmits a beacon transmission timing request message M20 to the base station 20c via the base station 20a.

The beacon transmission timing request message M20 includes a wireless transmission message M20r from the wireless terminal 10a to the base station 20a and a wired LAN 3 from the base station 20a to the base station 20c.
It consists of a wired transmission message M20w via 0.

As shown in FIG. 18, the beacon transmission timing request message M20 includes a beacon transmission timing request ID 2001.

Specifically, the beacon synchronization processing unit 105 executes the process shown in FIG. 19 in step S308. In FIG. 19, the beacon synchronization processing unit 105 transmits a beacon transmission timing request message M20 in step S501. When the base station 20c receives the beacon transmission timing request message M20, the beacon synchronization processing unit 206 transmits a beacon transmission response message M21 to the wireless terminal 10a as shown in FIG.

The beacon transmission response message M21 is transmitted from the base station 20c to the base station 20a via the wired LAN 3
A wired transmission message M21w passing through 0 and a wireless transmission message M21r by radio from the base station 20a to the wireless terminal 10a.

In step S502, the beacon synchronization processing unit 105 receives the beacon transmission response message M21 transmitted by the base station 20c.

FIG. 20 is a configuration example of the beacon transmission response message M21. As shown in FIG. 20, beacon transmission response message M21 includes beacon transmission timing response ID 2101, beacon transmission timing candidate (1) 2102, and beacon transmission timing candidate (2) 2103.

The beacon transmission timing response ID 2101 indicates that the response message includes a beacon transmission timing candidate. A beacon transmission timing candidate (1) 2102 and a beacon transmission timing candidate (2) 2103 indicate timing candidates at which the base station 20c transmits a beacon.
Here, the beacon transmission response message M21 includes two beacon transmission timing candidates, but it may be one or three or more.

When the base station 20c transmits a beacon, as an access control method, Point Coordina
tion Function (PCF) or Hybrid Coordination Function Controlled Channel
Use Access (hereinafter referred to as HCCA). Beacon transmission timing candidates are Contention Free Peri
It is a transmission timing of a beacon transmitted within an od (hereinafter referred to as CFP) period, and a beacon to be selected is other than a beacon that starts CFP.

When the beacon synchronization processing unit 105 receives the beacon transmission response message M21 in step S502, in step S503, the radio terminal 10a selects a transmission timing for attempting to receive a beacon at a frequency used by the base station 20c.

In step S504, beacon synchronization processing section 105, as shown in FIG.
The selected beacon transmission timing notification message M22 is transmitted to c. The selected beacon transmission timing notification message M22 includes a wireless wireless transmission message M22r from the wireless terminal 10a to the base station 20a and a wired transmission message M22w via the wired LAN 30 from the base station 20a to the base station 20c.

FIG. 21 is a configuration example of the selected beacon transmission timing notification message M22. As shown in FIG. 21, the selected beacon transmission timing notification message M22 includes a selective transmission timing notification ID 2201 and a selected beacon transmission timing 2202.

The base station 20c transmits a message indicating data transmission permission to the wireless terminal 10 (not shown in FIG. 1) connected to the base station 20c. When the access control method is PCF, a message indicating transmission permission is called CF-Poll. When the access control method is HCCA, a message indicating transmission permission is called QoS CF-Poll.

However, the base station 20c does not end communication with the wireless terminal 10 connected to the base station 20c by the beacon transmission timing specified by the selected beacon transmission timing 2202 included in the selected beacon transmission timing notification message M22. If it is determined that the beacon is transmitted, a message indicating transmission permission is not transmitted.

Whether communication is completed depends on the time until the beacon transmission timing.
It may be determined whether or not it (hereinafter referred to as MPDU) is shorter than the time required for transmitting one it. If the time until the beacon transmission timing is shorter than the time required to transmit one MPDU,
Communication with the wireless terminal 10 is not completed before the beacon transmission timing.

As shown in FIG. 22, the base station 20c determines whether or not 1 MPDU or more can be transmitted by the beacon transmission timing in step S601. If it is possible to transmit 1 MPDU or more (YES), the base station 20c transmits a message indicating transmission permission (CF-Poll or QoS CF-Pol) in step S602.
l) is transmitted to the wireless terminal 10. If it is not possible to transmit 1 MPDU or more, the base station 20c ends the process.

As described above, the base station 20c transmits the radio terminal 10 connected to the base station 20c at the beacon transmission timing specified by the selected beacon transmission timing 2202 included in the received selected beacon transmission timing notification message M22. Send a beacon.

When transmitting the selected beacon transmission timing notification message M22, the wireless terminal 10a waits until the beacon is received by changing the frequency according to the beacon transmission timing selected by the beacon synchronization processing unit 105.

Returning to FIG. 11, beacon synchronization processing section 105 determines whether or not a beacon is received in step S309. If beacon reception processing section 104 has received a beacon in step S308, it is determined that a beacon has been received in step S309 (YES). Step S308
In step S309, it is determined that a beacon has not been received (NO) if a timeout has occurred and the beacon reception processing unit 104 has not received a beacon.

If it is determined in step S309 that a beacon has been received (YES), the wireless terminal 10a shifts the process to step S306. The base station search unit 103 performs steps S301, S302, S310.
On the basis of the base station information Ibs05 acquired by the above process, the base station information Ibs10 shown in FIG. 16 is acquired and stored in the base station DB. The signal level history 1017 here is a signal level when a beacon is received.

If it is determined in step S309 that a beacon has not been received (NO), the wireless terminal 10a
Terminates the process.

Since the radio terminal 10a knows in advance the timing at which the base station 20c transmits a beacon, the radio terminal 10a can receive the beacon transmitted by the base station 20c with a minimum waiting time.

As described above, when the base station search unit 103 acquires base station information by active scan or passive scan and stores the base station information in step S306 of FIG.
The base station information management unit 106 executes the process of step S307.

In step S307, the base station information management unit 106 transmits a neighboring base station information notification message M13r shown in FIG. 23 to the base station 20a. The neighboring base station information notification message M13r includes a neighboring base station information notification ID 1301, a base station frequency 1303, a base station SSID 1304, a base station BSSID 1305, and a signal level 1307.

The base station frequency 1303, the base station SSID1304, and the base station BSSID1305
This is information acquired when a probe redundancy response message M12 (or probe response message M11r) or a beacon is received from 0c. The signal level 1307 is the received signal level 121 included in the probe redundancy response message M12 when the wireless terminal 10a receives the probe redundancy response message M12 from the base station 20c. The signal level 1307 is the received signal level when the probe response message M11r or the beacon is received.

FIG. 24 shows processing when the radio base station 20a receives the neighboring base station information notification message M13r. In FIG. 24, the base station information management unit 203 receives the neighboring base station information notification message M13r in step S701. The base station information management unit 203 executes step S70.
At 2, it is determined whether or not the base station 20 that matches the condition exists in the base station DB.

Matching the conditions here means matching with the base station frequency 1303, base station SSID1304, and base station BSSID1305 included in the neighboring base station information notification message M13r.

If information on the base station 20 that matches the condition exists in the base station DB (YES), the base station information management unit 203 updates the base station DB in step S703. At this time, base station information I in FIG.
A signal level 1307 is added to the neighboring base station candidates 146 and 156 in bs04 and Ibs05.
The information to be added to the neighboring base station candidates 146 and 156 is not limited to the signal level 1307, and may be the time when the neighboring base station information notification message M13r is received.

After the process of step S703, the base station information management unit 203 shifts the process to step S704. If the information of the base station 20 that matches the condition does not exist in the base station DB in step S702 (NO), the base station information management unit 203 shifts the processing to step S704.

In step S704, the base station information processing unit 202 transmits a neighboring base station information response message M31r to the wireless terminal 10a and ends the process.

FIG. 25 is a configuration example of the neighboring base station information response message M31r. The neighboring base station information response message M31r includes a neighboring base station information response ID 3101 and a received signal level 3102. The neighboring base station information response ID 3101 indicates that the message is a neighboring base station information response message.
The received signal level 3102 indicates the received signal level when the neighboring base station information response message M31r is received.

By registering a neighboring base station of the base station 20a obtained by the wireless terminal 10a in the base station 20a, another wireless terminal 10 connected to the base station 20a or newly connected to the base station 2
When searching for 0, the information of the base station DB can be used. As a result, the certainty that the wireless terminal 10 finds the base station 20 can be improved.

By the way, the signal level when the wireless terminal 10a receives data from the base station 20c in step S305 when the active scan is set as described above is shown in FIG.
If the received signal level 121 included in the probe redundancy response message M12 shown in FIG. 5 is used as it is, there is a possibility that it is different from the signal level when data is actually received from the base station 20c.

Therefore, it is preferable that the radio terminal 10a corrects the value indicated by the received signal level 121 and determines the corrected received signal level as a signal level when data is received from the base station 20c.

The value indicated by the received signal level 121 is L1, and the signal level when the base station 20a receives data from the radio terminal 10a is L2. The signal level when the wireless terminal 10a receives data from the base station 20a is L3, and the signal level when the wireless terminal 10a receives data from the base station 20c is Lx. The signal level Lx can be estimated by (L1 × L3) / L2.

The signal level L2 when the base station 20a receives data from the radio terminal 10a is shown in FIG.
The received signal level 3102 included in the neighboring base station information response message M31r of the first base station can be used.

Also, the radio terminal 10a transmits the signal level request message M32r shown in FIG. 26 to the base station 20a, and the base station 20a transmits the signal level response message M33r shown in FIG. 27 to the radio terminal 10a. It is also possible to obtain the signal level L3 when data is received from the base station 20a.

The signal level request message M32r includes a signal level request ID 3201. Signal level request I
D3201 indicates that the message is a signal level request message. The signal level response message M33r includes a signal level response ID 3301 and a received signal level 3302. The signal level response ID 3301 indicates that the message is a signal level response message. The received signal level 3302 indicates the received signal level when the base station 20a receives the signal level response message M33r from the wireless terminal 10a.

As can be seen from the above description, the wireless LAN system of one embodiment includes the wireless terminal 10 and
And a plurality of base stations 20 connected to each other via a wired LAN 30. For example, paying attention to the radio terminal 10a in FIG. 1, the plurality of base stations 20 are connected to the radio terminal 10a by radio using the first frequency and the radio terminal 10a by radio. Base station 20c not included.

The base station 20a wirelessly connected to the radio terminal 10a is defined as a connection base station, and the radio terminal 10a
A base station 20c that is not wirelessly connected to the base station 20 is defined as a non-connected base station.

When the wireless terminal 10a is set to active scan, the wireless terminal 10a, the connected base station 20a, and the unconnected base station 20c have the following configurations, respectively.

The radio terminal 10a switches the frequency from the first frequency to the second frequency used by the unconnected base station 20c, and transmits a probe request message transmission unit that transmits a probe request message M10r to the unconnected base station 20c. Have.

The unconnected base station 20c responds to the reception of the probe request message M10r, and the wireless terminal 10
a has a first probe response message transmitting means for transmitting a probe response message M11r (first probe response message) wirelessly using the second frequency. Also,
The unconnected base station 20c responds to the reception of the probe request message M10r, and the wired LAN 30
And a second probe response message transmitting means for transmitting a probe redundant response message M12 (second probe response message) by wire to the connecting base station 20a.

The connecting base station 20a has third probe response message transmission means for transmitting the probe redundancy response message M12 wirelessly to the wireless terminal 10a using the first frequency.
Since the second probe response message is transmitted as the IP packet 120, the connecting base station 20a simply transmits the IP packet 120 to the wireless terminal 10a as normal communication data. The third probe response message transmission means need only transmit the IP packet 120 to the wireless terminal 10a as normal communication data.

Regardless of whether or not the wireless terminal 10a receives the probe response message M11r,
The probe response message receiving means for switching the frequency from the first frequency to the first frequency and receiving the probe redundant response message M12 transmitted by the third probe response message transmitting means.

The wireless terminal 10a as a wireless communication device is wirelessly connected to the connecting base station 20a using the first frequency, is not connected wirelessly, and is connected to the connecting base station 20a and the wired LA.
Probe request message transmitting means for switching the frequency to the second frequency used by the non-connected base station 20c connected at N30 and transmitting a probe request message M10r to the non-connected base station 20c is provided.

In response to the reception of the probe request message M10r, the wireless terminal 10a receives the probe response message M11r (first probe response message) transmitted wirelessly using the second frequency in response to the reception of the probe request message M10r. First probe response message receiving means is included.

Further, the radio terminal 10a switches the frequency from the second frequency to the first frequency regardless of whether or not the first probe response message receiving unit receives the probe response message M11r. In response to receiving the probe request message M10r, 20c
Probe redundant response message wired to the connecting base station 20a via the wired LAN 30
M12 (second probe response message) is transmitted, and the connecting base station 20a has second probe response message receiving means for receiving the probe redundancy response message M12 transmitted wirelessly using the first frequency.

According to the wireless LAN system and the wireless communication apparatus of the embodiment having the above configuration, the search time for searching for another base station (non-connected base station 20c) different from the connected base station (connected base station 20a). Can be shortened.

The second probe response message transmission means includes a probe redundant response message M12.
It is preferable to transmit a message including the received signal level when the unconnected base station 20c receives the probe request message M10r.

The wireless terminal 10a has signal level determining means for determining a signal level for performing wireless communication between the wireless terminal 10a and the unconnected base station 20c based on the received signal level included in the probe redundancy response message M12. Is preferred.

The signal level determination means receives the received signal level included in the probe redundancy response message M12, the signal level when the connecting base station 20a receives data from the wireless terminal 10a, and the wireless terminal 10a receives data from the connecting base station 20a. And an estimation unit that estimates a signal level when the wireless terminal 10a receives data from the unconnected base station 20c by correcting using the signal level at the time based on the signal level estimated by the estimation unit It is preferable to determine a signal level when wireless communication is performed between the wireless terminal 10a and the unconnected base station 20c.

According to the wireless LAN system and the wireless communication apparatus of the embodiment having the above configuration, even if the wireless terminal 10a cannot receive a wireless message from the unconnected base station 20c, wireless communication with the unconnected base station 20c is performed. The signal level when performing can be determined.

Since the wireless terminal 10a includes an estimation unit that estimates a signal level when data is received from the unconnected base station 20c, the signal level when the wireless terminal 10a performs wireless communication with the unconnected base station 20c is appropriately set. It becomes possible to decide.

On the other hand, when the wireless terminal 10a is set to the passive scan, the wireless terminal 10a
The connected base station 20a and the non-connected base station 20c have the following configurations, respectively.

The wireless terminal 10a includes a beacon transmission timing request message transmission unit that transmits a beacon transmission timing request message M20 to the unconnected base station 20c via the connected base station 20a.

In response to reception of the beacon transmission timing request message M20, the unconnected base station 20c sends a beacon transmission response message M21 including one or more beacon transmission timing candidates to the wireless terminal 10a via the connected base station 20a. Beacon transmission response message transmission means for transmitting the message.

In response to the reception of the beacon transmission response message M21, the wireless terminal 10a transmits the connected base station 2
Selected beacon transmission timing notification message transmission for transmitting a selected beacon transmission timing notification message M22 including a beacon transmission timing candidate selected from among beacon transmission timing candidates as a selected beacon transmission timing 2202 to the unconnected base station 20c via 0a. Have means.

The unconnected base station 20c includes a determination unit that determines whether or not communication with the wireless terminal 10a is completed by the beacon transmission timing specified by the selected beacon transmission timing 2202.

The unconnected base station 20c uses the determination unit to transmit the wireless terminal 1 before the beacon transmission timing.
When it is determined that the communication with 0a ends, the wireless terminal 1 connected to the unconnected base station 20c
When a message indicating data transmission permission is transmitted to 0 and it is determined not to end, a message indicating data transmission permission is not transmitted to the wireless terminal 10 connected to the unconnected base station 20c. It has selective transmission means for preferentially transmitting a beacon.

According to the wireless LAN system and the wireless communication apparatus of the embodiment having the above configuration, the search time for searching for another base station (non-connected base station 20c) different from the connected base station (connected base station 20a). Can be shortened. According to the wireless LAN system and the wireless communication device of one embodiment, since the frequency is switched when a beacon is output, the reliability can be improved as compared with the case where the transmission timing of the beacon and the search timing are not synchronized. it can.

Since the unconnected base station 20c has the selective transmission means, the beacon can be transmitted at the timing when the wireless terminal 10a is waiting to receive the beacon.

10a, 10b Wireless terminal (wireless communication device)
20a to 20c Base station 30 Wired LAN
101, 201 Wireless communication unit 102 Base station information acquisition unit 103 Base station search unit 104 Beacon reception processing unit 105, 206 Beacon synchronization processing unit 106, 203 Base station information management unit 202 Base station information processing unit 204 Base station search response unit 205 Beacon transmission processor

Claims (2)

In response to receiving the probe request message from the wireless terminal, a first request is sent to the wireless terminal.
And transmitting a second probe response message to the wireless terminal via another transmitting device. The transmission apparatus according to claim 1, wherein the second probe response message is transmitted at a frequency different from that of the transmission of the first probe response message.

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