JP3735340B2 - Wireless communication system, wireless communication setting method, program, and recording medium - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to a wireless communication system used for constructing a network using a plurality of wireless base stations without interposing a wired communication line., Wireless communication setting method, program for realizing the wireless communication setting method, and recording mediumAbout.
[0002]
[Prior art]
The prior art related to the present invention is disclosed in the following Patent Document 1.
[Patent Document 1]
Special table 2001-503235 gazette
In a conventional public network or LAN (Local Area Network), a backbone network using a wired communication line is prepared as a main communication line, and a wireless communication system is used as a branch line system or an auxiliary communication medium.
[0003]
Currently, as in the wireless communication system disclosed in Patent Document 1, because of the need for freedom from wiring design and the flexibility of changing the network topology (network connection form), a wired communication line is not used temporarily. A wireless communication system capable of constructing a simple network has also been proposed.
Such a wireless communication system is such that a plurality of wireless terminals owned by an individual such as a notebook computer or a PDA can directly communicate with each other only with a wireless communication medium without interposing a wired communication line with each other. Is assumed to be able to communicate with.
[0004]
Therefore, there arises a routing problem as to how to carry the message and a problem as to how to allocate a channel so that radio waves transmitted from a plurality of devices do not interfere as much as possible.
As a system for forming a temporary network using only a wireless communication medium, Bluetooth is widely used. It is assumed that the Bluetooth system is mainly used for short-distance communication connection between devices.
[0005]
Therefore, in the Bluetooth system, in order to solve the problems related to routing and channel assignment, all wireless terminals that communicate are synchronized with each other and used for wireless connection of 8 terminals or less within a limited area of about 10 m. There are restrictions to do so.
[0006]
However, the Bluetooth system is said to be unsuitable for accommodating highly mobile radio terminals and large-capacity communications.
Actually, in order to accommodate highly mobile radio terminals and realize large-capacity communications, radio base stations are used to control access of radio terminals, such as mobile phones and PHS (Personal Handyphone System). Is considered necessary.
[0007]
Also, in order to ensure the mobility and high-capacity communication of wireless terminals, it is necessary for semi-fixed wireless base stations using multiple channels to have access control functions of wireless terminals and routing functions between wireless base stations. .
By the way, a network composed only of wireless communication media is regarded as an effective communication means even in the event of a disaster. Therefore, it should not happen that the line breaks and does not become useful, or that the power does not turn on in the first place, even in situations where it is difficult to use infrastructure such as power supply facilities or wired communication networks It is desirable that the network can be used simply by installing a radio base station.
[0008]
Such a wireless communication system is expected to be an effective tool when performing simultaneous broadcast communication necessary for disasters and image transmission related to the situation at the disaster site.
[0009]
[Problems to be solved by the invention]
In order to build a network using only wireless communication media as described above, realize mobility and high-capacity communication of wireless terminals, and realize a wireless network that supports broadcast communication to multiple wireless terminals. Frequency resources (communication channels) need to be effectively allocated.
[0010]
Further, when a network is constructed using portable radio base stations, the network topology changes depending on the position where the radio base stations are arranged. However, in order to efficiently use the communication channel, it is necessary to redesign the channel assignment every time the network topology changes. Designing such channel assignment is a laborious task and requires a high level of knowledge regarding wireless connectivity and security.
[0011]
  The present invention facilitates determination of operation parameters of each radio base station for realizing desirable allocation of a radio communication channel in the radio communication system as described above, or has a problem with some radio base stations on the network. Wireless communication system and wireless communication setting method capable of promptly recovering from occurrence of failureAnd wireless communication setting method, andAn object is to provide a program and a recording medium.
[0012]
[Means for Solving the Problems]
  According to the first aspect of the present invention, a plurality of radio base stations that are connected to and relayed to adjacent radio base stations via a radio channel, and a server connected to the plurality of radio base stations via a communication channel A wireless communication system capable of constructing a communication network without interposing a wired communication line, and performing access control of wireless terminals located in wireless areas individually controlled by the plurality of wireless base stations, The server allocates radio channels to the plurality of radio base stations based on the following procedure (hereinafter referred to as “first procedure”).
  Among the plurality of radio base stations, a radio base station having an odd number of hops of the relay for a specific radio base station to which channel C is assigned in advance as a radio channel used for the access control is used for the relay. Radio channels A and B are allocated when the number of radio base stations that have been previously set for connection to the specific radio base station are even and odd, respectively.
  For radio base stations having an even number of hops, radio channels B and A are used as radio channels used for the relay when the number of radio base stations previously set for connection is even and odd. Radio channels that are assigned to the radio base stations that have an even number and an odd number of hops are radio channels C and radio channels D that are different from the radio channels A, B, and C, respectively. Assign as.
  According to a second aspect of the present invention, a plurality of radio base stations that are connected to and relayed to adjacent radio base stations via a radio channel, and a server connected to the plurality of radio base stations via a communication channel A wireless communication system capable of constructing a communication network without interposing a wired communication line, and performing access control of wireless terminals located in wireless areas individually controlled by the plurality of wireless base stations, The server allocates radio channels to the plurality of radio base stations based on the following procedure (hereinafter referred to as “second procedure”).
  A specific radio channel D is assigned to the plurality of radio base stations as a radio channel used for the access control, and channel C is assigned as a radio channel used for the relay among the plurality of radio base stations. The radio base station having the relay hop count of “1” with respect to the radio base station has a radio channel used for the relay as a radio channel that has been previously set for connection to the specific radio base station. Radio channels A and B are allocated when the number is even and odd, respectively, and the first radio channel allocated as the radio channel used for the relay in advance with the hop number being “2” is A wireless base station that is a wireless channel A and that has the connection settings made in advance and has an even number and an odd number, and the hop number is “ And the first radio channel is the radio channel B and the number of radio base stations for which the connection setting has been made in advance is an even number and an odd number. Radio channels C, B, C, and A are allocated as the second radio channels to be used.
  The number of radio base stations for which the connection setting has been made in advance is an integer N ( ≧ 0 ) And the number of hops is (3N-1), and the number of hops is (3N-1). As a radio channel used for relaying to a base station that is 3N-2), among the radio channels A, B, and C, the radio in which the number of hops is (3N-1) and (3N-2) Radio channels other than those used for relaying between base stations and between base stations having the number of hops of (3N-2) and (3N-3) are allocated.
  The number of radio base stations that have been previously set for connection is 3N, and the number of radio base stations that have been previously set for connection to the radio base station whose number of hops is (3N-1) is an odd number. In this case, among the radio channels A, B, and C, the hop count is (3N−) as a radio channel used for relaying to the radio base station having the hop count (3N−2). 2) and (3N-3) are assigned the same radio channel as that used for relaying between the radio base stations.
  The number of radio base stations for which the connection setting has been made in advance is (3N + 1), and the hot When the number of radio base stations that have been set up for connection to a radio base station with a 3N number is an even number, the radio used for relaying to the radio base station with a 3N hop count is used. Among the wireless channels A, B, and C, the wireless base stations having the hop numbers (3N-1) and (3N-2), and the hop numbers 3N and (3N-1) A radio channel other than the radio channel used for relaying between the radio base stations is assigned.
  The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station with 3N hops is an odd number. In this case, among the wireless channels A, B, and C, the number of hops is (3N−1) and (3N−) as a wireless channel used for relaying to a wireless base station having the number of hops of 3N. 2) and the same radio channel as that used for relaying between radio base stations.
  The number of radio base stations that have been previously set for connection is (3N + 2), and the number of radio base stations that have been previously set for connection to a radio base station whose number of hops is (3N + 1) is an even number. In this case, among the wireless channels A, B, and C, the number of hops is 3N and (3N−) as the wireless channel used for relaying to the wireless base station having the number of hops (3N + 1). 1) and wireless channels other than those used for relaying between the wireless base stations having the number of hops of 3N and (3N + 1) are allocated.
  The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station with 3N hops is an odd number. In this case, among the wireless channels A, B, and C, the number of hops is 3N and (3N-1) as a wireless channel used for relay to the wireless base station having the number of hops (3N + 1). The same radio channel as that used for relaying between the radio base stations is assigned.
  According to a third aspect of the present invention, a plurality of radio base stations that are connected to and relayed to adjacent radio base stations via a radio channel, and a server connected to the plurality of radio base stations via a communication channel A wireless communication system capable of constructing a communication network without interposing a wired communication line, and performing access control of wireless terminals located in wireless areas individually controlled by the plurality of wireless base stations, The server, when the average value of the number of the wireless terminals in the plurality of wireless base stations exceeds and below a predetermined threshold, respectively, based on the first procedure and the second procedure, respectively Allocate a radio channel to a radio base station.
  According to a fourth aspect of the present invention, a plurality of radio base stations that are connected to and relayed to adjacent radio base stations via a radio channel, and a server connected to the plurality of radio base stations via a communication channel A wireless communication system capable of constructing a communication network without interposing a wired communication line, and performing access control of wireless terminals located in wireless areas individually controlled by the plurality of wireless base stations, The server compares, for each of the plurality of radio base stations, the first traffic in the radio channel used for the connection and the second traffic in the radio channel used for the relay, and the first traffic is the first traffic. Wireless traffic to the plurality of radio base stations based on the first procedure and the second procedure described above respectively when the traffic exceeds or falls below the second traffic. Assign Le.
  According to a fifth aspect of the present invention, a plurality of radio base stations connected to a server via a communication line perform connection and relay with adjacent radio base stations via a radio line, and the plurality of radio base stations Is a wireless communication setting method for performing access control of a wireless terminal located in a wireless area individually controlled and capable of constructing a communication network without interposing a wired communication line, wherein the server is configured as described above. A radio channel is allocated to the plurality of radio base stations based on one procedure.
  According to a sixth aspect of the present invention, a plurality of radio base stations connected to a server via a communication line connect and relay to adjacent radio base stations via a radio line, and the plurality of radio base stations Is a wireless communication setting method capable of building a communication network without intervening a wired communication line, while performing access control of wireless terminals located in wireless areas individually controlled The server allocates radio channels to the plurality of radio base stations based on the second procedure described above.
  According to a seventh aspect of the present invention, a plurality of radio base stations connected to a server via a communication line perform connection and relay with adjacent radio base stations via a radio line, and the plurality of radio base stations Is a wireless communication setting method for performing access control of wireless terminals located in wireless areas individually controlled by each other and capable of constructing a communication network without interposing a wired communication line, wherein the server includes the plurality of wireless devices When the average value of the number of the radio terminals in the base station exceeds or falls below a predetermined threshold, radio channels are assigned to the plurality of radio base stations based on the first procedure and the second procedure described above. Assign.
  According to an eighth aspect of the present invention, a plurality of radio base stations connected to a server via a communication line perform connection and relay with adjacent radio base stations via a radio line, and the plurality of radio base stations Is a wireless communication setting method for performing access control of wireless terminals located in wireless areas individually controlled by each other and capable of constructing a communication network without interposing a wired communication line, wherein the server includes the plurality of wireless devices For each base station, the first traffic in the radio channel used for the connection is compared with the second traffic in the radio channel used for the relay, and the first traffic exceeds the second traffic In the case where the number is below, a radio channel is allocated to the plurality of radio base stations based on the first procedure and the second procedure described above, respectively.
  A program according to a ninth aspect causes a computer to realize the wireless communication setting method according to any one of the fifth to eighth aspects.
  A recording medium according to a tenth aspect stores a program for causing a computer to implement the wireless communication setting method according to any one of the fifth to eighth aspects, and is readable by a computer.
  No. related to the present invention1TechnologyIs provided with a plurality of radio base stations, each radio base station having a function of connecting to a plurality of radio base stations and relaying communication, and a function of performing access control of radio terminals in a radio area under its jurisdiction. In a wireless communication system capable of building a communication network without interposing a wired communication line, a management server is connected to the plurality of wireless base stations via a predetermined wired communication line or a wireless communication line, The management server is provided with a setting information transmission function for transmitting setting information determined in correspondence with a connection form of a radio communication network constituted by the plurality of radio base stations to each radio base station. At least the network address of each radio base station, the administrator authentication word required to access the management system of each radio base station, and the affiliation of each radio base station Network authentication word, radio packet encryption key, radio channel used by each radio base station for connection to other radio base stations, and radio used by each radio base station for connection to radio terminals in the jurisdiction area The channel is included.
[0013]
  No. related to the present invention1TechnologyIn the configuration, the management server can transmit setting information to each radio base station to determine the operation of each radio base station. In addition, since the setting information transmitted by the management server is determined in association with the connection form (topology) of the wireless communication network, a wireless channel or the like can be appropriately assigned according to the connection form.
[0014]
  Further, since the management server transmits the administrator authentication word, the belonging network authentication word, and the wireless packet encryption key as the setting information, it is possible to solve the security problem.
  No. related to the present invention2TechnologyIsThe first technology described above was appliedIn the radio communication system, the management server includes a standby radio base station to be exchanged with a radio base station in which a fault has occurred, in case a fault occurs in any radio base station on the radio communication network. A function of transmitting and holding a network address and a device address of a station to each radio base station is provided, and each radio base station has, as a parameter other than the network address and the device address, the spare radio base station. And a function of transmitting and holding setting information having the same content as the radio base station in which the problem occurred.
[0015]
  No. related to the present invention2TechnologyIn this case, since the network address and device address of the standby radio base station are transmitted from the management server to each radio base station, each radio base station searches for the spare radio base station or accesses the spare radio base station. Is possible.
In addition, when a failure occurs in any of the wireless base stations on the wireless communication network, the wireless base station from the wireless base station to the standby wireless base station has failed as a parameter other than the network address and the device address. Since the setting information having the same contents as the base station is transmitted, the standby radio base station can be used in place of the radio base station in which the problem has occurred.
[0016]
  No. related to the present invention3TechnologyIsThe first technology described above was appliedIn the wireless communication system, the management server includes a user interface that prompts an administrator to select from a plurality of predetermined connection forms as a connection form of the wireless communication network configured by a plurality of wireless base stations. Is provided.
  No. related to the present invention3TechnologyIn this case, the administrator can select one connection form from a plurality of types of connection forms (topologies) by controlling the user interface of the management server. Therefore, it is possible to construct a network having a connection form reflecting the administrator's selection input.
[0017]
  No. related to the present invention4TechnologyIsThe first technology described above was appliedIn the radio communication system, the management server includes a first radio channel used when one radio base station transmits to another adjacent radio base station and a reception from another adjacent radio base station. Radio channel allocating means for controlling each radio base station so that the second radio channel used for communication and the third radio channel used for communication connection with radio terminals in the jurisdiction area are different from each other. Is provided.
[0018]
  No. related to the present invention4TechnologyIn each wireless base station, different channels are assigned to a transmission channel for relay, a reception channel, and a communication channel between wireless terminals, so that the problem of radio wave interference can be solved.
  No. related to the present invention5TechnologyIsThe second technology described above was appliedIn a radio communication system, each radio base station has a fault detection means for detecting the presence or absence of a fault of another radio base station connected via a radio communication line, and when a fault of the radio base station is detected, Failure information notifying means for notifying a wireless terminal of information related to a troubled radio base station, and a spare radio base station detecting means for detecting the spare radio base station that can be used in place of the troubled radio base station And a backup radio base station joining means for adding the detected backup radio base station to the radio communication network.
[0019]
  No. related to the present invention5TechnologyWhen a problem occurs in any one of the wireless base stations connected to the wireless communication network, the problem is detected by another wireless base station, and information on the troubled wireless base station is notified to the wireless terminal. Further, an available spare radio base station is detected, and the radio communication network is reconfigured to add the detected spare radio base station.
[0020]
  Therefore, the radio base station in which a problem has occurred can be replaced with a backup radio base station, and the radio communication network can be maintained in a state free from the problem.
  No. related to the present invention6TechnologyIs provided with a plurality of radio base stations, each radio base station having a function of connecting to a plurality of radio base stations and relaying communication, and a function of performing access control of radio terminals in a radio area under its jurisdiction. In a wireless communication setting method for controlling a wireless communication system capable of establishing a communication network without interposing a wired communication line and determining the operation of each wireless base station, each wireless communication from a predetermined management server Inquires the base station about the setting information including the network address and the device address assigned to the radio base station, manages the setting information including the result of the inquiry for each radio base station on the management server, and In addition to displaying on the management server, it prompts the administrator to enter additional or modified setting information, and configures each radio base station managed by the management server. It characterized in that transmitting information from the management server to each radio base station to determine the functionality of each wireless base station.
[0021]
  No. related to the present invention6TechnologyIn this case, the management server inquires the setting information to each radio base station, grasps the current setting state, and displays the state on the management server, so that the administrator can grasp the network setting state. When the administrator additionally inputs or corrects setting information, setting information reflecting the result is generated and transmitted to each radio base station. Therefore, it becomes easy to change the setting state of the network.
[0022]
  No. related to the present invention7TechnologyIsThe sixth technique described above was appliedIn the wireless communication setting method, when a problem occurs in any one of the wireless base stations on the wireless communication network, the network address and device address of the standby wireless base station prepared in advance are transmitted from the management server to each wireless base station. And transmitting the setting information having the same content as that of the failed radio base station as a parameter other than the network address and the device address from any one of the radio base stations to the standby radio base station. Features.
[0023]
  No. related to the present invention7TechnologyIn, the radio base station can access the standby radio base station by information transmitted from the management server. Further, the backup radio base station can perform the same operation as that of the radio base station in which a problem has occurred, based on information transmitted from the radio base station to the backup radio base station.
[0024]
  No. related to the present invention8TechnologyIsThe seventh technique described above was appliedIn the wireless communication setting method, each of the wireless base stations monitors the presence or absence of other wireless base stations connected via a wireless communication line, and the wireless base station that detects the failure of the other wireless base station is Information on the radio base station in which the malfunction has occurred is notified to the radio terminal, the existence of the spare radio base station that can be used instead of the radio base station in which the malfunction has occurred is searched, and the detected spare radio base station is detected Is added to the wireless communication network.
[0025]
  No. related to the present invention8TechnologyWhen a problem occurs in a radio base station, the problem is detected by another radio base station, and information on the radio base station in which the problem is detected is notified to the radio terminal. Further, an available spare radio base station is detected, and the radio communication network is reconfigured to add the detected spare radio base station.
  No. related to the present invention9TechnologyIs provided with a plurality of radio base stations, each radio base station having a function of connecting to a plurality of radio base stations and relaying communication, and a function of performing access control of radio terminals in a radio area under its jurisdiction. A wireless communication setting server capable of connecting to each wireless base station for controlling a wireless communication system capable of constructing a communication network without interposing a wired communication line and determining the operation of each wireless base station; In addition, for each radio base station, setting information inquiry means for inquiring each radio base station about setting information including a network address and a device address assigned to the radio base station, and setting information including a result of the inquiry for each radio base station. Setting information editing means for managing and displaying and prompting the administrator to add or modify setting information, and settings for each managed radio base station Characterized in that a setting information update means for determining a function of each radio base station transmits to the wireless base station broadcast.
[0026]
  No. related to the present invention9Technology, By using the wireless communication setting server, grasp the setting information of each wireless base station, accept the additional input or correction input from the administrator, update the setting information, the result of the setting of each wireless base station Can be reflected in information. Therefore, it becomes easy to change the setting state of the network.
[0027]
  No. related to the present invention10TechnologyIs provided with a plurality of radio base stations, each radio base station having a function of connecting to a plurality of radio base stations and relaying communication, and a function of performing access control of radio terminals in a radio area under its jurisdiction. In a base station apparatus used as each of the wireless base stations in a wireless communication system capable of constructing a communication network without interposing a wired communication line, other wireless base stations connected via the wireless communication line A trouble monitoring means for monitoring the presence or absence of a trouble, a trouble notifying means for notifying a wireless terminal of information relating to a troubled radio base station when a trouble of another wireless base station is detected, and a trouble occurred Search means for searching for a spare radio base station that can be used instead of the radio base station, and a network for adding the spare radio base station detected by the search to the communication network Characterized by providing a re-constructing means.
[0028]
  No. related to the present invention10TechnologyIn, when a problem occurs in a radio base station connected to the communication network, the problem is detected by another radio base station, and information on the problem radio base station is notified to the radio terminal. Further, an available spare radio base station is detected, and the communication network is reconfigured so as to add the detected spare radio base station.
[0029]
  No. related to the present invention11TechnologyIs provided with a plurality of radio base stations, each radio base station having a function of connecting to a plurality of radio base stations and relaying communication, and a function of performing access control of radio terminals in a radio area under its jurisdiction. And a program executable by a computer of a wireless communication setting server connectable to each of the wireless base stations for determining an operation of a wireless communication system capable of constructing a communication network without interposing a wired communication line. A setting information inquiry procedure for inquiring setting information including a network address and a device address assigned to the wireless base station from the wireless communication setting server to each wireless base station, and setting information including a result of the inquiry. Setting information editing that prompts the administrator to input or modify setting information while managing and displaying each radio base station And a setting information update procedure for determining the function of each radio base station by transmitting the setting information of each radio base station managed on the radio communication setting server to each radio base station. And
[0030]
  No. related to the present invention11TechnologyBy executing this program on the computer of the wireless communication setting server,The first mentioned9TechnologyThe same operation is realized.
  No. related to the present invention12TechnologyIs provided with a plurality of radio base stations, each radio base station having a function of connecting to a plurality of radio base stations and relaying communication, and a function of performing access control of radio terminals in a radio area under its jurisdiction. In a wireless communication system capable of constructing a communication network without interposing a wired communication line, the program can be executed by a computer of each wireless base station, and each wireless base station is connected via a wireless communication line. Defect monitoring procedure for monitoring the presence or absence of defects in other connected radio base stations, and when each radio base station detects a defect in another radio base station, information on the radio base station in which the malfunction occurred A failure notification procedure to be notified to, a search procedure to search for a spare radio base station that can be used instead of the radio base station in which the failure has occurred, and the spare radio detected by the search Characterized in that the provided and procedures network reconfiguration to add to the communication network Chikyoku.
[0031]
  No. related to the present invention12TechnologyBy executing the program on each wireless base station computer,The first mentioned10TechnologyThe same operation is realized.
  No. related to the present invention13TechnologyIsNo. mentioned above11TechnologyThis is a computer-readable recording medium on which the program is recorded.
  No. related to the present invention13TechnologyBy executing the program recorded on the recording medium in the computer of the wireless communication setting server,The first mentioned9TechnologyThe same operation is realized.
[0032]
  No. related to the present invention14TechnologyIsThe first mentioned12TechnologyThis is a computer-readable recording medium on which the program is recorded.
  No. related to the present invention14TechnologyBy executing the program recorded on the recording medium in each wireless base station computer,The first mentioned10TechnologyThe same operation is realized.
[0033]
DETAILED DESCRIPTION OF THE INVENTION
Embodiments of a wireless communication system, a wireless communication setting method, a wireless communication setting server, a base station apparatus, a program, and a recording medium according to the present invention will be described with reference to FIGS. This form corresponds to all the claims.
[0034]
FIG. 1 is a block diagram illustrating a configuration example of a communication system. FIG. 2 is a flowchart showing the operation of the management server. FIG. 3 is a sequence diagram showing an example of setting operation of the communication system. FIG. 4 is a front view showing a display example of the setting state display screen. FIG. 5 is a front view showing a display example of a detailed setting screen. FIG. 6 is a front view showing a display example of the topology selection screen.
[0035]
FIG. 7 is a flowchart showing the operation of the GUI of the management server. FIG. 8 is a flowchart showing communication channel assignment processing (1). FIG. 9 is a flowchart showing communication channel assignment processing (2). FIG. 10 is a schematic diagram showing a communication channel assignment example (1). FIG. 11 is a schematic diagram showing a communication channel allocation example (2).
[0036]
FIG. 12 is a front view showing a display example of the determined topology. FIG. 13 is a front view showing a display example of the wireless terminal device address registration screen. FIG. 14 is a sequence diagram illustrating a setting operation example of the communication system. FIG. 15 is a flowchart showing the operation (1) of the radio base station. FIG. 16 is a flowchart showing the operation (2) of the radio base station.
[0037]
  FIG. 17 is a schematic diagram showing an example of information related to the backup base station. 18 and 19 are block diagrams illustrating an operation example of the communication system. 20 and 21 are sequence diagrams illustrating an operation example of the communication system.
  In this form,In the first technique related to the present inventionThe management server, the radio base station, and the setting information transmission function correspond to the management server 20, the radio base station 10, and step S33, respectively. Also,In the fourth technique related to the present inventionThe wireless channel assignment means corresponds to step S18.
[0038]
  Also,In the fifth technique related to the present inventionThe defect detection means, the defect information notification means, the backup radio base station detection means, and the backup radio base station subscription means correspond to steps S72, S76, S81, and S86, respectively.In the ninth technique related to the present inventionSetting information inquiry means, setting information editing means, and setting information updating means correspond to steps S31, (S13, S16, S17) and S33, respectively.In the tenth technology related to the present inventionThe trouble monitoring means, trouble notification means, search means, and network restructuring means correspond to steps S72, S76, S81, and S86, respectively.
[0039]
In this embodiment, it is assumed that a wireless communication network is configured using a plurality of wireless base stations 10 (1), 10 (2), 10 (3),... As in the communication system shown in FIG. Yes.
In the example of FIG. 1, the management server 20 is connected to each wireless base station 10 via the hub 21 and the wired communication line 22. However, in the normal communication operation, the management server 20, the hub 21 and the wired communication line are connected. No. 22 is unnecessary.
[0040]
That is, a communication network can be configured using only wireless communication lines formed by a plurality of wireless base stations 10. A pre-registered wireless terminal (not shown) can access this communication network via the wireless line of any wireless base station 10.
As shown in FIG. 1, all the radio base stations 10 are provided with a control unit 11, a terminal access radio transmission / reception unit 12, and relay radio transmission / reception units 13 and 14. The terminal access wireless transmission / reception unit 12 and the relay wireless transmission / reception units 13 and 14 each form a wireless line.
[0041]
A network address is assigned to each of the control unit 11, the terminal access wireless transmission / reception unit 12, and the relay wireless transmission / reception units 13 and 14. Of course, only one network address is assigned to each radio base station 10, and the control unit 11, the terminal access radio transmission / reception unit 12, and the relay radio transmission / reception units 13 and 14 control communication so that each is distinguished by a port number. You can also.
[0042]
The radio channel formed by the terminal access radio transmission / reception unit 12 is used for radio communication with the radio terminal, and the radio channel formed by the relay radio transmission / reception unit 13 and the relay radio transmission / reception unit 14 is another adjacent radio base. Used for communication with the station 10.
Since each radio base station 10 is provided with two relay radio transmission / reception units 13 and 14, each radio base station 10 receives and relays a signal transmitted from the other first radio base station 10 to receive a second signal. It is also possible to transmit to the wireless base station 10. Therefore, a communication network can be configured without using a wired communication line.
[0043]
However, for example, when each radio base station 10 is first installed or when the position of each radio base station 10 is changed, a limited radio communication channel is used effectively and interference is prevented. In addition, it is necessary to change the allocation of wireless communication channels and the like to be used in response to changes in the network environment.
In order to centrally manage the setting information for determining the operation of each radio base station 10, a management server 20 is connected in the communication system of FIG. A wireless line can be used instead of the wired communication line 22 for connection between the management server 20 and each wireless base station 10. However, when a wireless line is used, it is necessary to prevent unauthorized operation by using a predetermined authentication procedure.
[0044]
The control unit 11 of each radio base station 10 has the following functions.
(1) Routing function in communication between radio base stations
(2) Functions for registering and deleting wireless terminals that use the network
(3) Communication frame generation and conversion functions
(4) Communication function with the management server 20
(5) Function to store and update files that record various setting data
The selection of the radio channel and the determination of the radio base station to be connected in the relay radio transmitting / receiving units 13 and 14 of each radio base station 10 are in accordance with instructions from the control unit 11. The terminal access wireless transmission / reception unit 12 follows the instructions of the control unit 11 for selection of a wireless channel and determination of a wireless terminal permitted to access.
[0045]
The management server 20 can simultaneously send signals to the plurality of radio base stations 10 via the hub 21 and change the settings of all the radio base stations 10 at the same time.
An outline of the operation of the management server 20 will be described with reference to FIG.
In step S <b> 11, a predetermined search process related to the radio base station 10 is performed to check what radio base station 10 is connected to the hub 21. Further, the management server 20 requests each radio base station 10 connected to the hub 21 to acquire unit information.
[0046]
In response to this request, each radio base station 10 transmits its unit information to the management server 20. The unit information is composed of the following information.
(1) Network address (IP address etc.)
(2) Device-specific address (MAC address, etc.)
(3) Radio channel used by each radio transceiver unit (12-14)
(4) Transmission speed
(5) Communication method
In step S12, the management server 20 displays information as shown in FIG. 4 on the display so that a predetermined administrator can grasp the current setting state of the network. That is, for each radio base station 10, a unit ID (a number for distinguishing the radio base station), a network address and a device address relating to each of the terminal access radio transmission / reception unit 12 and the relay radio transmission / reception units 13 and 14 And information on the wireless channel used by the device.
[0047]
Further, by operating the “detailed setting” portion in the screen shown in FIG. 4 (clicking with the mouse, etc.), it is possible to shift to a detailed setting screen for each radio base station as shown in FIG.
For example, when trying to change the network address or the like from the initial state determined when shipped from the factory, the administrator is in a state where the detailed setting screen (FIG. 5) is displayed on the management server 20, The contents can be changed by performing an input operation on the corresponding item.
[0048]
When the management server 20 receives the change of the network address and the input of the administrator authentication word from the administrator on the detailed setting screen (FIG. 5), the information is stored in step S13.
In step S14, with the change input in step S13, the management server 20 creates an address correspondence table and stores it as a file. This correspondence table represents a correspondence relationship between a network address in each radio base station 10 and a unique device address given to each device such as a MAC (Media Access Control) address.
[0049]
This correspondence table is used for determining a routing route and managing security between the radio base stations 10.
The management server 20 uses the gateway address and routing protocol input from the administrator on the detailed setting screen (FIG. 5) or their specified values in step S15 to determine the gateway address and routing protocol of each radio base station 10. Set up.
[0050]
The gateway address corresponds to the address of a router built in the control unit 11 of each radio base station 10.
In step S16, the setting of each radio base station 10 is changed using the network authentication word and the encryption key or their specified values input from the administrator on the detailed setting screen (FIG. 5). The network authentication word and the encryption key in wireless communication are information commonly assigned to all the wireless base stations 10 on the corresponding network.
[0051]
In step S17, the management server 20 determines the topology of the network to be formed, that is, the connection form of the plurality of radio base stations 10, according to the input from the administrator.
[0052]
In step S18, the management server 20 transmits a setting request to each radio base station 10 so that the contents of each parameter determined in steps S13, S15, S16, and S17 are reflected in each radio base station 10. To do.
Since each radio base station 10 responds to the request transmitted by the management server 20 in step S18, when the response is received, the management server 20 reflects the content of the response (setting status) on the screen display.
[0053]
If there is an item that has not been successfully set in the display on the management server 20, the setting relating to the failed item is redone. If the settings for all items are completed normally, the process proceeds to the next step S20.
In step S <b> 20, the management server 20 registers device addresses and user names for wireless terminals that can participate in the wireless network via the terminal access wireless transmission / reception unit 12 of each wireless base station 10. By using the device address uniquely assigned to each wireless terminal, unauthorized wireless terminals can be excluded from the network.
[0054]
When registering the device address and user name of the wireless terminal, input is performed using a screen as shown in FIG.
With the operation of the management server 20 as described above, it is possible to easily and quickly set the parameters of the respective radio base stations 10 constituting the radio communication network.
A more specific operation of the management server 20 will be described below.
[0055]
When searching for the radio base station 10 in step S11 in FIG. 2, the management server 20 transmits a unit information acquisition request to each radio base station 10 via the hub 21 by multicast (S31 in the figure).
In this case, the control unit 11 of each radio base station 10 responds in step S32 of FIG. 3 and transmits unit information to the management server 20.
[0056]
By the way, the parameters in steps S13, S15, and S16 in FIG. 2 can be manually input by the administrator using the detailed setting screen as shown in FIG. 5, but for the management as described below. It can also be determined automatically by the autonomous operation of the server 20.
As for the network address, for example, the management server 20 can assign a unique network address to each radio base station 10 by using a well-known DHCP (Dynamic Host Configuration Protocol).
[0057]
For the administrator authentication word, for example, any number of authentication words can be automatically generated by selecting a number or alphabet sequentially in a random number from a number in the range of 0 to 9 and an alphabet in the range of A to Z. it can.
In this form, according to the topology determined in step S17 of FIG. 2, control is performed so that connection is not permitted unless the wireless base station or wireless base stations have the permitted network address and device address. When this control is performed, the correspondence table created in step S14 is used.
[0058]
That is, since the network address and the device address are used to identify whether or not connection is possible, the security function is improved.
A specified value may be assigned as the routing protocol or default gateway. For example, as a routing protocol, a commonly used RIP (Routing Information Protocol) or a unique protocol suitable for wireless communication (for example, http://mitre.org/tech_transfer/mobilemesh/_Routing) can be used.
[0059]
The network authentication word set in step S16 is used to distinguish from other wireless networks, and is controlled so as to refuse participation of wireless base stations and wireless terminals that do not use the same network authentication word into the network. .
The encryption key set in step S16 is used to encrypt the wireless communication packet.
[0060]
As for the network authentication word and the encryption key, common values are assigned to all the radio base stations 10 belonging to the same network segment. Thereby, communication on the same wireless network can be distinguished from communication on another wireless network, and the security level is improved.
The network authentication word and the encryption key are also composed of an arbitrary number of characters by sequentially selecting numbers or alphabets with random numbers from among numbers in the range of 0 to 9 and alphabets in the range of A to Z, for example. An authentication word can be automatically generated.
[0061]
The process of step S17 in FIG. 2 will be specifically described.
When performing this process, a topology selection screen as shown in FIG. 6 is displayed by a GUI (graphical user interface) process on the management server 20, and the administrator performs an input operation on this screen. Thus, the topology of the network is determined.
[0062]
In the screen of FIG. 6, there is an operation unit for selecting a topology type (shape) at the top. In this example, one of three topology types prepared in advance can be selected. . The selected topology type is displayed surrounded by a selection frame.
In the central part of the screen of FIG. 6, each of a plurality of radio base stations 10 (units) belonging to the same network segment is displayed as a round icon together with the number.
[0063]
In addition, the “determined topology” is greatly displayed at the bottom of the screen of FIG. This “determined topology” reflects the pattern of the topology type selected in the upper selection frame, and is composed of a group of blank round icons.
The icon of each radio base station 10 in the center of the screen can be moved to the position of a blank icon in the “determined topology” by an input operation from the administrator.
[0064]
In the example of FIG. 6, the icon of the first radio base station is arranged at the center of the “determined topology”, and the icon of the second radio base station is arranged on the upper side adjacent to the icon.
The operation of the GUI for controlling the topology selection screen as shown in FIG. 6 will be described with reference to FIG.
[0065]
In step S41, the icons of all the radio base stations 10 detected in step S11 described above are displayed in the center of the screen. The number of each icon is the same as the unit ID.
In step S42, a topology pattern selection input from the administrator is accepted. In step S43, an input of icon movement by the administrator is accepted. That is, the administrator can operate the mouse or the like to move each icon in the center of the screen to a blank icon position in the “determined topology” below.
[0066]
In step S43, the GUI automatically identifies whether the icon can be moved. For example, if an icon is moved by an administrator's input operation and a space is created between the icons in the “determined topology” (excluding the center of the topology and the initial position), it is considered that the icon cannot be moved. Return the moved icon to its original position.
[0067]
Actually, when a setting command is transmitted to the radio base station 10 having no connection partner, the parameter related to the connection partner becomes null and an error is returned from the radio base station 10 to the management server 20, so that it is possible to identify whether or not movement is possible.
If it cannot be moved, an input error is displayed as a message in step S44, and the process returns to step S43.
[0068]
In step S45, a channel selection pattern selection input is accepted. This input is reflected in the assignment of the radio channel used by each radio base station 10. Details of this processing will be described later.
After the above process is completed, if it is detected in step S46 that a predetermined transmission button has been pressed, the process proceeds to the next step S47. In steps S47 and S48, it is confirmed whether or not there is a problem with the content of the “determined topology”.
[0069]
That is, in step S47, it is identified whether or not an icon is assigned to the initial position (topology center or start point = root node). In step S48, all the coordinates on the GUI where the icons are arranged are searched in addition to the root node, and it is checked whether a route to the initial position is established in order from the initial position.
If there is no problem in the content of the “determined topology”, the process proceeds to step S49, and the radio channel used by each radio base station 10 is assigned. Thereby, for example, assignment as shown in FIG. 10 or FIG. 11 is performed.
[0070]
In step S50, the management server 20 transmits a setting command to each radio base station 10 (S33 in FIG. 3).
The setting command transmitted by the management server 20 is received by the control unit 11 in each radio base station 10. In this case, the control unit 11 transmits a setting command to the terminal access wireless transmission / reception unit 12 and the relay wireless transmission / reception units 13 and 14 (S34 in FIG. 3).
[0071]
Next, a specific example in which a communication channel (radio channel) is assigned to each radio base station 10 configuring the network will be described. In this example, each radio base station 10 includes a terminal access radio transmission / reception unit 12 and relay radio transmission / reception units 13 and 14 as shown in FIG. It is assumed that one or more channels are used for each base station.
[0072]
Also, the number of available wireless channels is usually limited. Here, assuming a case where the network having the topology shown in FIG. 12 is configured with a 2.4 GHz band wireless LAN having a high penetration rate, four channels (cA, cB, cC, cD) in which interchannel interference does not occur are illustrated. 10, each radio base station 10 is assigned.
[0073]
The unit numbers in FIG. 10 correspond to the icon numbers shown in FIG.
When assigning radio channels as shown in FIG. 10, since all radio base stations 10 use the same two radio channels (cA, cB) for relay, each radio base station 10 has two radio channels. Any one of (cA, cB) is used to connect to an adjacent radio base station.
[0074]
Also, for example, the radio base station 10 (1) with the unit number 1 relays the communication packet transmitted from the radio base station 10 (2) with the unit number 2 to the radio base station 10 (3) with the unit number 3. In this case, the radio base station 10 (1) receives a communication packet from the radio base station 10 (2) using the radio channel (cA), and simultaneously uses the radio channel (cB). Since it can transmit to (3), efficient relay can be performed.
[0075]
Furthermore, even if the area of the service provided by the radio base station 10 (1) to the radio terminal and the areas of the radio base stations 10 (2) to 10 (4) are spatially overlapped, the radio base station 10 (1) The radio channel (cC) used for access is different from the radio channel (cD) used by the radio base stations 10 (2) to 10 (4) for access. Efficient communication is realized without occurrence.
[0076]
As described above, the wireless base stations 10 adjacent to each other use the same wireless channel of two or more channels and wirelessly use different access wireless channels among the adjacent wireless base stations 10. By allocating channels, efficient communication is realized.
By automatically performing such channel assignment, the network administrator need not perform troublesome channel design. Even when the topology changes, the communication efficiency can be improved by reassigning the channel.
[0077]
Actual channel assignment can be automatically performed by the following procedure. Here, it is assumed that four radio channels (cA, cB, cC, cD) are used in total, and the radio channel (cA, cB) is assigned to the relay system in the radio base station (root node) at the initial position, and access is made. It is assumed that a radio channel (cC) is assigned to the system.
[0078]
(Relay system)
(1) Assign radio channels (cA, cB) to the relay systems of all radio base stations 10.
(2) When allocating a base station having a hop count of 1 from a radio base station (root node) at the initial position, the number of units (number of base stations) already set to connect to the root node is set to an even number (0 If the number of hops is 1 and the number of already set units is an odd number, the wireless channel (cB) is assigned.
[0079]
(3) When allocating to a base station with 2 hops from the root node, the number of hops is 1 when the number of units for which the channel setting for connection with the base station with 1 hop is completed is even If the number of units for which the channel setting for connection with the base station with one hop is completed is odd, the base with one hop is assigned. It allocates so that it may connect with a station by a radio channel (cA).
[0080]
(4) Thereafter, when allocating for an even number of base stations, the allocation is performed in the same manner as when the number of hops is 2, and when allocating for an odd number of hops, the number of hops is 1. Assign in the same way as in the case of.
(Access system)
(1) When the number of hops from the root node is an odd number, a radio channel (cD) different from that of the root node is assigned to the access system.
[0081]
(2) When the number of hops from the root node is an even number, the same radio channel (cC) as that of the root node is assigned to the access system.
Another specific example relating to radio channel allocation will be described below.
Here, it is assumed that three or more radio channels are allocated to communication between the radio base stations 10. Further, assuming that the network having the topology shown in FIG. 12 is configured with a 2.4 GHz band wireless LAN having a high penetration rate, four channels (cA, cB, cC, cD) that do not cause interchannel interference are shown in FIG. Assigned to each radio base station 10 as shown in FIG.
[0082]
That is, of the four channels (cA, cB, cC, cD), one channel (cD) is fixedly allocated for wireless terminal access, and the remaining three channels (cA, cB, cC) are used as relay bases. Assign to communication between stations.
When channel assignment as shown in FIG. 11 is performed, since the access channel of the wireless terminal is fixed to one channel (cD), the wireless terminal moves between a plurality of service areas each time the wireless channel moves. There is no need to switch between and roaming control becomes easy.
[0083]
In this example, since each radio base station 10 includes two relay radio transmission / reception units 13 and 14, each radio base station 10 is assigned two relay radio channels. Actually, the radio channel is assigned by the following procedure.
(01) When the number of hops from the root node is 1, if the number of base stations for which connection setting to the root node is completed is an even number (including 0), the root node is used using the radio channel (cA). If the number of base stations that have been set for connection to the root node is an odd number, the wireless channel (cB) is used to connect to the root node.
[0084]
(02) When the number of hops from the root node is 2 and the connection channel with the root node is (cA), the wireless communication is performed if the number of base stations connected to the base station with the hop number of 1 is an even number. A channel (cC) is assigned, and a radio channel (cB) is assigned if the number of hops is one and the number of base stations that are already connected is set.
[0085]
(03) When the number of hops from the root node is 2 and the connection channel with the root node is (cB), the radio is used if the number of base stations connected to the base station with the hop number of 1 is an even number. A channel (cC) is allocated, and a radio channel (cA) is allocated if the number of hops is one and the number of base stations that are already connected is set.
(04) Thereafter, allocation is performed in the following manner for each hop base station.
[0086]
(1) When the number of hops of the corresponding base station is 3N (N: real number):
(1-1) When the number of base stations connected to the base station with the number of hops of (3N-1) is an even number, the base station with the number of hops of (3N-1) and the number of hops of (3N- 2) The connection channel with the base station and the base station with the number of hops (3N-2) and the wireless channel other than the connection channel with the base station with the number of hops (3N-3), the number of hops is (3N -2) to be connected to the base station.
[0087]
(1-2) When the number of base stations that have already been connected to the base station with the number of hops of (3N-1) is an odd number, the base station with the number of hops of (3N-2) and the number of hops of (3N- The connection channel with the base station in 3) is allocated so as to connect to the base station with the number of hops of (3N-2).
(2) When the number of hops of the corresponding base station is 3N + 1 (N: real number):
(2-1) When the number of base stations connected to the base station with the number of hops of (3N) is an even number, the base station with the number of hops of (3N-1) and the number of hops of (3N-2) A base station with a connection channel and a base station with a hop count of (3N) other than a connection channel with a base station with a hop count of (3N) and a base station with a hop count of (3N-1) Assign to connect with.
[0088]
(2-2) When the number of base stations connected to the base station with the number of hops of (3N) is an odd number, the base station with the number of hops of (3N-1) and the number of hops of (3N-2) Is allocated so as to connect to a base station having a number of hops of (3N) using a connection channel with the base station.
(3) When the number of hops of the corresponding base station is 3N + 1 (N: real number):
(3-1) When the number of base stations that have already been connected to the base station with the number of hops of (3N + 1) is an even number, the base station with the number of hops of (3N) and the base with the number of hops of (3N-1) Connect to the base station with the number of hops (3N + 1) on the other radio channels except the connection channel with the station and the base station with the number of hops (3N) and the base station with the number of hops (3N + 1) Assign to.
[0089]
(3-2) When the number of base stations connected to the base station with the number of hops of (3N + 1) is an odd number, the base station with the number of hops of (3N) and the base with the number of hops of (3N-1) It allocates so that it may connect with the base station whose number of hops is (3N + 1) using the connection channel with a station.
The radio channel assignment as shown in FIG. 11 provides a favorable result when the number of radio terminals in one area of the radio base station 10 is small and the traffic of the relay system between the radio base stations is large.
[0090]
Further, when the number of wireless terminals per area of the wireless base station 10 is large or when the traffic of the relay system between the wireless base stations is small, it is desirable to assign the wireless channel as shown in FIG.
Therefore, in this embodiment, the management server 20 performs the processing shown in FIG. 8 or FIG. 9 and selects a desired radio channel assignment from two types of assignment methods.
[0091]
In this form, it is possible to select whether the assignment method is automatically selected or manually input by the administrator. That is, in step S61 of FIG. 8, it is identified whether it is automatic or manual.
In the case of automatic, (Nt / Nb) and the threshold value N1 are compared in step S62 of FIG. As the number of registered terminals Nt, the total number of wireless terminals registered by the process of step S18 in FIG. 2 may be used. The number of radio base stations Nb may be the number of radio base stations 10 assigned to the topology determined in step S17. If the condition ((Nt / Nb)> N1) is satisfied, the number of terminals is considered to be large, and the process proceeds to step S63. In step S63, radio channel allocation as shown in FIG. 10 is performed.
[0092]
On the other hand, if the condition ((Nt / Nb)> N1) is not satisfied, the number of terminals is considered to be small, and the process proceeds to step S64. In step S64, radio channel assignment as shown in FIG. 11 is performed.
When the assignment method is manually selected, input from the administrator is accepted in step S66, and the magnitude of the number of wireless terminals is identified according to the input. If the number of wireless terminals is large, the process proceeds to step S63, and if small, the process proceeds to step S64.
[0093]
The process shown in FIG. 9 is a modification of FIG. 8 and is the same as FIG. 8 except for step S62B.
In step S62B of FIG. 9, the traffic Ta of the access system is compared with the traffic Tr of the relay system. These pieces of information Ta and Tr can be acquired, for example, by monitoring traffic in an actual network.
[0094]
If the condition of (Ta> Tr) is satisfied, the process proceeds from step S62B to S63, and radio channel assignment as shown in FIG. 10 is performed. If the condition of (Ta> Tr) is not satisfied, the process proceeds from step S62B to S64, and radio channel assignment as shown in FIG. 11 is performed.
The radio channel can be appropriately allocated to each radio base station 10 by the processing as described above.
[0095]
On the other hand, when the setting of the radio base station 10 is completed, the process proceeds to step S20 in FIG. Here, a screen as shown in FIG. 13 is displayed on the management server 20. On this screen, the administrator can register wireless terminals that can participate in the wireless network.
[0096]
That is, when the administrator inputs a new wireless terminal name and device address to be registered on the screen and presses the new registration button, the wireless terminal is added to the wireless terminal registration list at the bottom of the screen. If the delete button in the list is pressed, the registration of the corresponding wireless terminal can be deleted.
Since information on each wireless terminal registered on this screen can be used to distinguish between a registered wireless terminal and an unregistered wireless terminal, access of an unregistered wireless terminal can be denied.
[0097]
By the way, after operating a wireless network, the case where a malfunction generate | occur | produces in the one part wireless base station 10 which comprises the wireless network is also considered. When a malfunction of the radio base station 10 occurs, the radio network does not operate normally.
Therefore, it is desirable to prepare in advance a radio base station 10 that serves as a spare for replacement, that is, a spare radio base station, in preparation for the occurrence of a problem. In addition, when a standby radio base station can be prepared, it is desirable that the network state can be recovered only by autonomous control of the radio base station 10 when a problem occurs.
[0098]
Therefore, a setting operation as shown in FIG. 14 can be considered. In the example of FIG. 14, when the management server 20 sets each radio base station 10, information regarding the backup radio base station is transmitted together with the setting command (S91). The information regarding the backup radio base station needs to include the network address and device address of the backup radio base station.
[0099]
That is, in order to ensure the security of the wireless network, it is necessary to specify the wireless base stations that can participate in the network, and therefore, it is possible to specify the backup wireless base station using the network address and the device address.
When receiving the information on the backup radio base station from the management server 20, the control unit 11 of each radio base station 10 stores the information and notifies the management server 20 that the registration of the backup radio base station is completed. (S94).
[0100]
Actually, for example, information shown in FIG. 17 is registered in each radio base station 10 in accordance with an instruction from the management server 20.
By such an operation, the radio base station 10 can detect the network address, the device address, the device address, and the like from the registered spare radio base station information even when any of the radio base stations on the network is replaced with the spare radio base station. The spare radio base station can be authenticated using some of the authentication word, encryption key, and the like.
[0101]
In preparation for a case where a problem occurs in any of the radio base stations 10 constituting the radio network, in this embodiment, each radio base station 10 performs the processing shown in FIGS. 15 and 16.
That is, the radio base station 10 can be used in place of a function for detecting the occurrence of a fault in another radio base station, a function for notifying a designated terminal that a fault has occurred, and a radio base station in which a fault has occurred. A function of detecting a spare radio base station and a function of reconstructing a radio network by adding the spare radio base station are provided.
[0102]
First, the operation shown in FIG. 15 will be described.
All the wireless base stations 10 connected to the wireless network keep the KeepAlive in order to inform the adjacent wireless base stations that they are operating normally and that a link with the adjacent wireless base station is maintained. A signal called information is periodically broadcast to other radio base stations (S71).
[0103]
The wireless base station that has received the KeepAlive information transmits a confirmation response message to the transmission source of the KeepAlive information, and the wireless base station of the transmission source confirms the response (S72).
When the confirmation of the response is completed, a standby state for a predetermined time is entered (S73).
[0104]
If the confirmation of the response cannot be obtained, the number of transmissions is confirmed (S74). If the number of retransmissions is less than a predetermined number, it is determined that there is no abnormality, the process returns to step S71, and KeepAlive information is transmitted again.
When the number of retransmissions reaches a predetermined number, the process proceeds from step S74 to S75, and it is considered that a problem has occurred in an adjacent radio base station.
[0105]
In the next step S76, the radio terminal (designated terminal) existing in the designated area is notified that a problem has occurred in the adjacent radio base station.
In the next step S77, it is identified whether or not there is another radio base station adjacent to the own station. If there is another adjacent radio base station, the process proceeds to the next step S78, and information on the failure related to the other radio base station in which the failure has occurred is notified to the detected adjacent radio base station.
[0106]
Thereafter, a standby state for a predetermined time is entered (S79), and the process proceeds to a standby radio base station detection process. That is, the process proceeds to the process of FIG.
The operation of FIG. 15 will be described assuming the wireless network shown in FIG. In the example of FIG. 18, when the base station (A, B, C, D) exists as the radio base station 10 and there are six radio terminals (a1, a2, a3, c1, d1, d2), It is assumed that a problem occurs in the base station (B).
[0107]
In this case, due to the malfunction of the base station (B), the base station (B) cannot respond to the adjacent base stations (A, C) as shown in FIG.
In addition, the base stations (A, C) repeat transmission of KeepAlive information a predetermined number of times, but no response is obtained.
Therefore, each of the base stations (A, C) considers that a failure has occurred in the base station (B), and information indicating that a failure has occurred in the base station (B) is transmitted to the wireless terminals in the area designated in advance. Transmit (S102, S104).
[0108]
In the example of FIG. 18, since only the base station (B) is adjacent to the base station (A), the notification of the occurrence of the trouble ends. On the other hand, since the base station (C) is adjacent to the base station (D) in addition to the base station (B), the base station (C) has a problem with the base station (B). The occurrence is notified (S105).
By this notification, the base station (D) notifies a designated terminal (for example, d1) in the area that a problem has occurred in the base station (B) (S106). Further, since only the base station (C) is adjacent to the base station (D), the notification of the occurrence of the malfunction in the base station (D) is terminated.
[0109]
By such control, when a problem occurs in any one of the radio base stations 10, the radio terminal in the area or another radio base station 10 can grasp that the problem has occurred in a specific base station.
Next, the operation of the radio base station 10 will be described with reference to FIG.
When the occurrence of a malfunction in any one of the radio base stations 10 is detected by the process of FIG. 15, the backup radio base station is detected in step S81 of FIG. That is, information on the standby radio base stations (preliminary radio base station list as shown in FIG. 17) notified in advance from the management server 20 and held on the radio base station 10 is searched and registered at the beginning of the list. The wireless base station information including the information about the network address and the device address is periodically transmitted to the network address of the standby wireless base station that has been set (S32).
[0110]
If there is no response from the other radio base station (standby radio base station) to the transmission of this radio base station information, the spare radio base station list is searched again, and the spare registered second in the list. Radio base station information is transmitted to the network address of the radio base station.
Thereafter, transmission is performed to all the spare radio base stations registered in the list, and if no response is obtained at all, transmission is repeated in order from the first spare radio base station registered.
[0111]
If there is actually an available spare radio base station, the spare radio base station responds to the transmission in step S82. This response includes a network address, a device address, a network authentication word, and an encryption key in the standby radio base station.
When receiving a response from the backup radio base station to the transmission in step S82, the radio base station 10 receives the network address, device address, network authentication word, and encryption key of the backup radio base station included in the response. All are authenticated against the contents of the backup radio base station list.
[0112]
If the authentication is successful, the radio base station 10 registers the backup radio base station in the topology information representing the network state so that the other radio base station in which the problem has occurred is replaced with the backup radio base station ( S86).
In next step S87, the radio base station 10 broadcasts a response request to all the other radio base stations 10 included in the radio network, and waits for a response from the other radio base station 10.
[0113]
If the radio base station 10 confirms responses from all other radio base stations in step S88, it is assumed that the radio network has been restored, and the operation before the occurrence of the malfunction is resumed.
A specific operation example will be described with reference to FIG. Here, a communication system as shown in FIGS. 18 and 19 is assumed. Further, it is assumed that information as shown in FIG. 17 is transmitted from the management server 20 in advance and stored as a backup radio base station list on each radio base station 10.
[0114]
In this example, a malfunction occurs in the base station (B) shown in FIG. 18, and the standby radio base station (F) is arranged in place of the base station (B). As a result, a communication system as shown in FIG. It is assumed that
In FIG. 21, the base station (B) where the problem occurred and the adjacent base stations (A, C) search for the spare radio base station by referring to the spare radio base station list (S111, S117).
[0115]
In the example of FIG. 17, since the base station (E) is registered at the head of the backup radio base station list, the base station (A, C) transmits its own radio base station information to the base station (E). And waits for a response from the base station (E).
However, in this example, the base station (E) does not actually exist, and the base station (F) is installed as a backup radio base station.
[0116]
Therefore, a response from the base station (E) cannot be obtained. Therefore, the base station (A, C) refers to the standby radio base station list again, finds the base station (F) registered second in the list, and makes its own radio base station with respect to the base station (F). Information is transmitted, and a response from the base station (F) is awaited (S112, S118).
Here, the base station (F), which is an actual standby radio base station, returns response information including its network address, device address, authentication word, and encryption key (S115).
[0117]
In this case, the base station (A, C) confirms (authenticates) the response information from the base station (F), and after the confirmation is completed, the base station (F) Instead, it is registered in the network topology information.
In this case, since the base station (F) is arranged instead of the base station (B), the parameters relating to the base station (F) are the same as those of the base station (B) where the problem occurred except for the network address and the device address. The same value is assigned.
[0118]
When the registration of the base station (F) is completed, the base station (A, C) broadcasts a response request and a normal operation start command to all the radio base stations (S113, S119).
On the other hand, when all the radio base stations respond, the base stations (A, C) resume normal operation. As a result, the entire wireless network is normally restored from the state where the problem has occurred.
[0119]
The operation described above can be realized by dedicated hardware, or can be realized by using a program that runs on the management server 20 or the computer of the radio base station 10. The program can be recorded on a recording medium such as a CD-ROM and moved.
[0120]
【The invention's effect】
As described above, according to the present invention, when a network is constructed using only a wireless medium as a communication line, parameter assignment of each wireless base station can be easily performed. In addition, it is possible to appropriately assign radio channels according to the topology of the network to be formed, the number of radio terminals to be used, and the like. Furthermore, it is possible to simplify the settings related to security such as an authentication word and an encryption key. In addition, when a problem occurs in some of the radio base stations on the network, the network can be restored more quickly.
[Brief description of the drawings]
FIG. 1 is a block diagram illustrating a configuration example of a communication system.
FIG. 2 is a flowchart showing the operation of the management server.
FIG. 3 is a sequence diagram showing an example of setting operation of the communication system.
FIG. 4 is a front view showing a display example of a setting state display screen.
FIG. 5 is a front view showing a display example of a detail setting screen.
FIG. 6 is a front view showing a display example of a topology selection screen.
FIG. 7 is a flowchart showing a GUI operation of the management server.
FIG. 8 is a flowchart showing communication channel assignment processing (1).
FIG. 9 is a flowchart showing communication channel assignment processing (2).
FIG. 10 is a schematic diagram showing a communication channel assignment example (1).
FIG. 11 is a schematic diagram showing a communication channel allocation example (2).
FIG. 12 is a front view showing a display example of the determined topology.
FIG. 13 is a front view showing a display example of a wireless terminal device address registration screen.
FIG. 14 is a sequence diagram illustrating an example of a setting operation of the communication system.
FIG. 15 is a flowchart showing an operation (1) of the radio base station.
FIG. 16 is a flowchart showing an operation (2) of the radio base station.
FIG. 17 is a schematic diagram illustrating an example of information related to a backup base station.
FIG. 18 is a block diagram illustrating an operation example of a communication system.
FIG. 19 is a block diagram illustrating an operation example of a communication system.
FIG. 20 is a sequence diagram illustrating an operation example of the communication system.
FIG. 21 is a sequence diagram illustrating an operation example of the communication system.
[Explanation of symbols]
10 radio base stations
11 Control unit
12 Radio transceiver for terminal access
13, 14 Relay wireless transceiver
20 Management server
21 Hub
22 Wired communication lines

Claims (10)

A plurality of radio base stations that are connected to and relayed to adjacent radio base stations via a radio line; and a server connected to the plurality of radio base stations via a communication line, the plurality of radio base stations In a wireless communication system capable of building a communication network without intervening a wired communication line while performing access control of a wireless terminal located in a wireless area individually controlled by a station,
The server
Among the plurality of radio base stations, a radio base station having an odd number of hops of the relay for a specific radio base station to which channel C is assigned in advance as a radio channel used for the access control is used for the relay. Radio channels A and B are assigned when the number of radio base stations that have been previously set to connect to the specific radio base station is even and odd, and the number of hops is even. The radio base stations are assigned radio channels B and A as the radio channels used for the relay when the number of radio base stations previously set for connection is even and odd, and the number of hops For radio base stations having an even number and an odd number, the radio channel C and a radio channel D different from the radio channels A, B, and C are respectively accessed. Allocating a radio channel used to control
A wireless communication system. A plurality of radio base stations that are connected to and relayed to adjacent radio base stations via a radio line; and a server connected to the plurality of radio base stations via a communication line, the plurality of radio base stations In a wireless communication system capable of building a communication network without intervening a wired communication line while performing access control of a wireless terminal located in a wireless area individually controlled by a station,
The server
A specific radio channel D is assigned to the plurality of radio base stations as a radio channel used for the access control, and channel C is assigned as a radio channel used for the relay among the plurality of radio base stations. The radio base station having the relay hop count of “1” with respect to the radio base station has a radio channel used for the relay as a radio channel that has been previously set for connection to the specific radio base station. Radio channels A and B are allocated when the number is even and odd, respectively, and the first radio channel allocated as the radio channel used for the relay in advance with the hop number being “2” is A wireless base station that is a wireless channel A and that has the connection settings made in advance and has an even number and an odd number, and the hop number is “ And the first radio channel is the radio channel B and the number of radio base stations for which the connection setting has been made in advance is an even number and an odd number. Assign radio channels C, B, C, A as the second radio channels to be used,
The number of radio base stations for which the connection setting has been made in advance is an integer N ( ≧ 0 ) And the number of hops is (3N-1), and the number of hops is (3N-1). As a radio channel used for relaying to a base station that is 3N-2), among the radio channels A, B, and C, the radio in which the number of hops is (3N-1) and (3N-2) Allocating radio channels other than radio channels used for relaying between base stations and between base stations having the number of hops of (3N-2) and (3N-3),
The number of radio base stations that have been previously set for connection is 3N, and the number of radio base stations that have been previously set for connection to the radio base station whose number of hops is (3N-1) is an odd number. In this case, among the radio channels A, B, and C, the hop count is (3N−) as a radio channel used for relaying to the radio base station having the hop count (3N−2). 2) and (3N-3) are allocated the same radio channel as the radio channel used for relaying between the radio base stations,
The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station whose number of hops is 3N is an even number. In this case, among the wireless channels A, B, and C, the number of hops is (3N-1) and (as a wireless channel used for relaying to a wireless base station having a hop number of 3N. 3N-2) and a wireless channel other than the wireless channel used for relaying between the wireless base stations whose number of hops is 3N and (3N-1),
The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station with 3N hops is an odd number. In this case, among the wireless channels A, B, and C, the number of hops is (3N−1) and (3N−) as a wireless channel used for relaying to a wireless base station having the number of hops of 3N. 2) and assign the same radio channel as the radio channel used for relaying between radio base stations,
The number of radio base stations that have been previously set for connection is (3N + 2), and the number of radio base stations that have been previously set for connection to the radio base station whose number of hops is (3N + 1) is an even number. In this case, among the wireless channels A, B, and C, the number of hops is 3N and (3N−) as the wireless channel used for relaying to the wireless base station having the number of hops (3N + 1). 1) and a wireless channel other than the wireless channel used for relaying between the wireless base stations between which the number of hops is 3N and (3N + 1), and
The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station with 3N hops is an odd number. In this case, among the wireless channels A, B, and C, the number of hops is 3N and (3N-1) as a wireless channel used for relay to the wireless base station having the number of hops (3N + 1). Assign the same radio channel as that used for relaying between radio base stations
A wireless communication system. A plurality of radio base stations that are connected to and relayed to adjacent radio base stations via a radio line; and a server connected to the plurality of radio base stations via a communication line, the plurality of radio base stations In a wireless communication system capable of building a communication network without intervening a wired communication line while performing access control of a wireless terminal located in a wireless area individually controlled by a station,
The server
When the average value of the number of radio terminals in the plurality of radio base stations exceeds or falls below a predetermined threshold, radio is transmitted to the plurality of radio base stations based on the first procedure and the second procedure, respectively. Assign channels,
In the first procedure,
Among the plurality of radio base stations, a radio base station having an odd number of hops of the relay for a specific radio base station to which channel C is assigned in advance as a radio channel used for the access control is used for the relay. Radio channels A and B are allocated when the number of radio base stations that have been previously set to connect to the specific radio base station are even and odd, and the number of hops is even. A radio base station is assigned radio channels B and A as radio channels used for the relay when the number of radio base stations that have been previously set for connection is even and odd, respectively, and Radio base stations with even and odd hop counts include the radio channel C and radio channels D different from the radio channels A, B, and C, respectively. Assigned as the radio channel used serial access control,
In the second procedure,
A specification in which a common radio channel D is allocated to the plurality of radio base stations as a radio channel used for the access control, and channel C is allocated as a radio channel used for the relay among the plurality of radio base stations The radio base station having the relay hop count of “1” with respect to the radio base station of the radio base station in which connection setting to the specific radio base station has been made in advance as a radio channel used for the relay When the number of is even and odd Radio channels A and B are assigned to the first radio channel, and the first radio channel assigned as the radio channel used for the relay in advance is the radio channel A, and the number of hops is “2”. And the number of radio base stations for which the connection setting has been made is even and odd, the number of hops is “2”, and the first radio channel is the radio channel B, and Radio channels C, B, C, and A are used as the second radio channels used for the relay, respectively, for the radio base stations in which the number of radio base stations that have been set in advance is even and odd. Assigned,
The number of radio base stations for which the connection setting has been made in advance is an integer N ( ≧ 0 ) And the number of hops is (3N-1), and the number of hops is (3N-1). As a radio channel used for relaying to a base station that is 3N-2), among the radio channels A, B, and C, the radio in which the number of hops is (3N-1) and (3N-2) Radio channels other than those used for relaying between the base stations and between the base stations having the number of hops of (3N-2) and (3N-3) are allocated,
The number of radio base stations that have been previously set for connection is 3N, and the number of radio base stations that have been previously set for connection to the radio base station whose number of hops is (3N-1) is an odd number. In this case, among the radio channels A, B, and C, the hop count is (3N−) as a radio channel used for relaying to the radio base station having the hop count (3N−2). 2) and (3N-3) are assigned the same radio channel as the radio channel used for relaying between the radio base stations,
The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station whose number of hops is 3N is an even number. In this case, among the wireless channels A, B, and C, the number of hops is (3N−1) and (3N−) as a wireless channel used for relaying to a wireless base station having the number of hops of 3N. 2) and a radio channel other than the radio channel used for relaying between the radio base stations between which the number of hops is 3N and (3N-1) are allocated,
The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station with 3N hops is an odd number. In this case, among the wireless channels A, B, and C, the number of hops is (3N−1) and (3N−) as a wireless channel used for relaying to a wireless base station having the number of hops of 3N. 2) and the same radio channel as that used for relaying between radio base stations is allocated,
The number of radio base stations that have been previously set for connection is (3N + 2), and the number of radio base stations that have been previously set for connection to the radio base station whose number of hops is (3N + 1) is an even number. In this case, among the wireless channels A, B, and C, the number of hops is 3N and (3N−) as the wireless channel used for relaying to the wireless base station having the number of hops (3N + 1). 1) and a wireless channel other than the wireless channel used for relaying between the wireless base stations between which the number of hops is 3N and (3N + 1) are allocated,
The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station with 3N hops is an odd number. In this case, among the wireless channels A, B, and C, the number of hops is 3N and (3N-1) as a wireless channel used for relay to the wireless base station having the number of hops (3N + 1). The same radio channel as that used for relaying between radio base stations is assigned.
A wireless communication system. A plurality of radio base stations that are connected to and relayed to adjacent radio base stations via a radio line; and a server connected to the plurality of radio base stations via a communication line, the plurality of radio base stations Wireless that can control the access of wireless terminals located in the wireless area individually controlled by the station and can construct a communication network without intervening wired communication lines In a communication system,
The server
For each of the plurality of radio base stations, the first traffic in the radio channel used for the connection is compared with the second traffic in the radio channel used for the relay, and the first traffic is the second traffic. Assigning radio channels to the plurality of radio base stations based on the first procedure and the second procedure, respectively, when exceeding and below
In the first procedure,
Among the plurality of radio base stations, a radio base station having an odd number of hops of the relay for a specific radio base station to which channel C is assigned in advance as a radio channel used for the access control is used for the relay. Radio channels A and B are allocated when the number of radio base stations that have been previously set to connect to the specific radio base station are even and odd, and the number of hops is even. A radio base station is assigned radio channels B and A as radio channels used for the relay when the number of radio base stations that have been previously set for connection is even and odd, respectively, and Radio base stations with even and odd hop counts include the radio channel C and radio channels D different from the radio channels A, B, and C, respectively. Assigned as the radio channel used serial access control,
In the second procedure,
A specification in which a common radio channel D is allocated to the plurality of radio base stations as a radio channel used for the access control, and channel C is allocated as a radio channel used for the relay among the plurality of radio base stations The radio base station having the relay hop count of “1” with respect to the radio base station of the radio base station in which connection setting to the specific radio base station has been made in advance as a radio channel used for the relay Radio channels A and B are allocated when the number of the first and second channels are even and odd, respectively, and the first radio channel is allocated as the radio channel used for the relay with the number of hops being “2” in advance Is the radio channel A, and the number of radio base stations for which the connection setting has been made in advance is an even number and an odd number; A radio base station in which the number is “2”, the first radio channel is the radio channel B, and the number of radio base stations for which the connection setting has been made in advance is an even number and an odd number. , Radio channels C, B, C, and A are allocated as the second radio channels used for the relay,
The number of radio base stations for which the connection setting has been made in advance is an integer N ( ≧ 0 ) And the number of hops is (3N-1), and the number of hops is (3N-1). As a radio channel used for relaying to a base station that is 3N-2), among the radio channels A, B, and C, the radio in which the number of hops is (3N-1) and (3N-2) Radio channels other than those used for relaying between the base stations and between the base stations having the number of hops of (3N-2) and (3N-3) are allocated,
The number of radio base stations that have been previously set for connection is 3N, and the number of radio base stations that have been previously set for connection to the radio base station whose number of hops is (3N-1) is an odd number. In this case, among the radio channels A, B, and C, the hop count is (3N−) as a radio channel used for relaying to the radio base station having the hop count (3N−2). 2) and (3N-3) are assigned the same radio channel as the radio channel used for relaying between the radio base stations,
The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station whose number of hops is 3N is an even number. In this case, among the wireless channels A, B, and C, the number of hops is (3N−1) and (3N−) as a wireless channel used for relaying to a wireless base station having the number of hops of 3N. 2) and a radio channel other than the radio channel used for relaying between the radio base stations between which the number of hops is 3N and (3N-1) are allocated,
The number of radio base stations for which the connection setting has been made in advance is (3N + 1), and the hot If the number of radio base stations that have been set up for connection to a radio base station with a 3N number is an odd number, the radio used for relaying to the radio base station with a 3N hop count is used. Of the radio channels A, B, and C, the same radio channel as the radio channel used for relaying between the radio base stations having the number of hops (3N-1) and (3N-2) is allocated as the channel. And
The number of radio base stations that have been previously set for connection is (3N + 2), and the number of radio base stations that have been previously set for connection to the radio base station whose number of hops is (3N + 1) is an even number. In this case, among the wireless channels A, B, and C, the number of hops is 3N and (3N−) as the wireless channel used for relaying to the wireless base station having the number of hops (3N + 1). 1) and a wireless channel other than the wireless channel used for relaying between the wireless base stations between which the number of hops is 3N and (3N + 1) are allocated,
The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station with 3N hops is an odd number. In this case, among the wireless channels A, B, and C, the number of hops is 3N and (3N-1) as a wireless channel used for relay to the wireless base station having the number of hops (3N + 1). The same radio channel as that used for relaying between radio base stations is assigned.
A wireless communication system. A plurality of radio base stations connected to a server via a communication line connect and relay to adjacent radio base stations via a radio line, and the radio base stations are individually controlled within a radio area. A wireless communication setting method capable of establishing a communication network without intervening a wired communication line while performing access control of a located wireless terminal,
The server
Among the plurality of radio base stations, a radio base station having an odd number of hops of the relay for a specific radio base station to which channel C is assigned in advance as a radio channel used for the access control is used for the relay. Radio channels A and B are assigned when the number of radio base stations that have been previously set to connect to the specific radio base station is even and odd, and the number of hops is even. The radio base stations are assigned radio channels B and A as the radio channels used for the relay when the number of radio base stations previously set for connection is even and odd, and the number of hops Radio base stations having an even number and an odd number are assigned to the radio channel C and the radio channel D different from the radio channels A, B, and C, respectively. Allocating a radio channel used Seth control
A wireless communication setting method. A plurality of radio base stations connected to a server via a communication line connect and relay to adjacent radio base stations via a radio line, and the radio base stations are individually controlled within a radio area. A wireless communication setting method capable of establishing a communication network without intervening a wired communication line while performing access control of a located wireless terminal,
The server
A specific radio channel D is assigned to the plurality of radio base stations as a radio channel used for the access control, and channel C is assigned as a radio channel used for the relay among the plurality of radio base stations. The radio base station having the relay hop count of “1” with respect to the radio base station has a radio channel used for the relay as a radio channel that has been previously set for connection to the specific radio base station. Radio channels A and B are allocated when the number is even and odd, respectively, and the first radio channel allocated as the radio channel used for the relay in advance with the hop number being “2” is A wireless base station that is a wireless channel A and that has the connection settings made in advance and has an even number and an odd number, and the hop number is “ And the first radio channel is the radio channel B and the number of radio base stations for which the connection setting has been made in advance is an even number and an odd number. Radio channels C, B, as the second radio channel used Assign C and A respectively.
The number of radio base stations for which the connection setting has been made in advance is an integer N ( ≧ 0 ) And the number of hops is (3N-1), and the number of hops is (3N-1). As a radio channel used for relaying to a base station that is 3N-2), among the radio channels A, B, and C, the radio in which the number of hops is (3N-1) and (3N-2) Allocating radio channels other than radio channels used for relaying between base stations and between base stations having the number of hops of (3N-2) and (3N-3),
The number of radio base stations that have been previously set for connection is 3N, and the number of radio base stations that have been previously set for connection to the radio base station whose number of hops is (3N-1) is an odd number. In this case, among the radio channels A, B, and C, the hop count is (3N−) as a radio channel used for relaying to the radio base station having the hop count (3N−2). 2) and (3N-3) are allocated the same radio channel as the radio channel used for relaying between the radio base stations,
The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station whose number of hops is 3N is an even number. In this case, among the wireless channels A, B, and C, the number of hops is (3N−1) and (3N−) as a wireless channel used for relaying to a wireless base station having the number of hops of 3N. 2) and a wireless channel other than the wireless channel used for relaying between the wireless base stations between which the number of hops is 3N and (3N-1), and
The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station with 3N hops is an odd number. In this case, among the wireless channels A, B, and C, the number of hops is (3N−1) and (3N−) as a wireless channel used for relaying to a wireless base station having the number of hops of 3N. 2) and assign the same radio channel as the radio channel used for relaying between radio base stations,
The number of radio base stations that have been previously set for connection is (3N + 2), and the number of radio base stations that have been previously set for connection to the radio base station whose number of hops is (3N + 1) is an even number. In this case, among the wireless channels A, B, and C, the number of hops is 3N and (3N−) as the wireless channel used for relaying to the wireless base station having the number of hops (3N + 1). 1) and a wireless channel other than the wireless channel used for relaying between the wireless base stations between which the number of hops is 3N and (3N + 1), and
The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station with 3N hops is an odd number. In this case, among the wireless channels A, B, and C, the number of hops is 3N and (3N-1) as a wireless channel used for relay to the wireless base station having the number of hops (3N + 1). Assign the same radio channel as that used for relaying between radio base stations
A wireless communication setting method. A plurality of radio base stations connected to a server via a communication line connect and relay to adjacent radio base stations via a radio line, and the radio base stations are individually controlled within a radio area. A wireless communication setting method capable of establishing a communication network without intervening a wired communication line while performing access control of a located wireless terminal,
The server
When the average value of the number of radio terminals in the plurality of radio base stations exceeds or falls below a predetermined threshold, radio is transmitted to the plurality of radio base stations based on the first procedure and the second procedure, respectively. Assign channels,
In the first procedure,
Of the plurality of radio base stations, a channel is used as a radio channel used for the access control. For a radio base station that has an odd number of hops for the relay to a specific radio base station to which C is assigned in advance, a connection setting to the specific radio base station is set in advance as a radio channel used for the relay. Radio channels A and B are assigned when the number of radio base stations that are made even and odd, respectively, and radio base stations that have an even number of hops are preceded as radio channels used for the relay. The wireless channels B and A are assigned when the number of wireless base stations for which the connection setting has been made is even and odd, and the wireless base stations with the even and odd hop numbers are assigned to the wireless base stations. A channel C and a radio channel D different from the radio channels A, B, and C are allocated as radio channels used for the access control,
In the second procedure,
A specification in which a common radio channel D is allocated to the plurality of radio base stations as a radio channel used for the access control, and channel C is allocated as a radio channel used for the relay among the plurality of radio base stations The radio base station having the relay hop count of “1” with respect to the radio base station of the radio base station in which connection setting to the specific radio base station has been made in advance as a radio channel used for the relay Radio channels A and B are allocated when the number of the first and second channels are even and odd, respectively, and the first radio channel is allocated as the radio channel used for the relay with the number of hops being “2” in advance Is the radio channel A, and the number of radio base stations for which the connection setting has been made in advance is an even number and an odd number; A radio base station in which the number is “2”, the first radio channel is the radio channel B, and the number of radio base stations for which the connection setting has been made in advance is an even number and an odd number. , Radio channels C, B, C, and A are allocated as the second radio channels used for the relay,
The number of radio base stations for which the connection setting has been made in advance is an integer N ( ≧ 0 ) And the number of hops is (3N-1), and the number of hops is (3N-1). As a radio channel used for relaying to a base station that is 3N-2), among the radio channels A, B, and C, the radio in which the number of hops is (3N-1) and (3N-2) Radio channels other than those used for relaying between the base stations and between the base stations having the number of hops of (3N-2) and (3N-3) are allocated,
The number of radio base stations that have been previously set for connection is 3N, and the number of radio base stations that have been previously set for connection to the radio base station whose number of hops is (3N-1) is an odd number. In this case, among the radio channels A, B, and C, the hop count is (3N−) as a radio channel used for relaying to the radio base station having the hop count (3N−2). 2) and (3N-3) are assigned the same radio channel as the radio channel used for relaying between the radio base stations,
The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station whose number of hops is 3N is an even number. In this case, among the wireless channels A, B, and C, the number of hops is (3N−1) and (3N−) as a wireless channel used for relaying to a wireless base station having the number of hops of 3N. 2) and a radio channel other than the radio channel used for relaying between the radio base stations between which the number of hops is 3N and (3N-1) are allocated,
The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station with 3N hops is an odd number. In this case, among the wireless channels A, B, and C, the number of hops is (3N−1) and (3N−) as a wireless channel used for relaying to a wireless base station having the number of hops of 3N. 2) and the same radio channel as that used for relaying between radio base stations is allocated,
The number of radio base stations that have been previously set for connection is (3N + 2), and the number of radio base stations that have been previously set for connection to a radio base station whose number of hops is (3N + 1) is an even number. In the case where the number of hops is (3N + 1) Among the radio channels A, B, and C, the radio channels used are between radio base stations having the hop count of 3N and (3N-1), and the hop count of 3N and (3N + 1). Radio channels other than those used for relaying between radio base stations are allocated,
The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station with 3N hops is an odd number. In this case, among the wireless channels A, B, and C, the number of hops is 3N and (3N-1) as a wireless channel used for relay to the wireless base station having the number of hops (3N + 1). The same radio channel as that used for relaying between radio base stations is assigned.
A wireless communication setting method. A plurality of radio base stations connected to a server via a communication line connect and relay to adjacent radio base stations via a radio line, and the radio base stations are individually controlled within a radio area. A wireless communication setting method capable of establishing a communication network without intervening a wired communication line while performing access control of a located wireless terminal,
The server
For each of the plurality of radio base stations, the first traffic in the radio channel used for the connection is compared with the second traffic in the radio channel used for the relay, and the first traffic is the second traffic. Assigning radio channels to the plurality of radio base stations based on the first procedure and the second procedure, respectively, when exceeding and below
In the first procedure,
Among the plurality of radio base stations, a radio base station having an odd number of hops of the relay for a specific radio base station to which channel C is assigned in advance as a radio channel used for the access control is used for the relay. Radio channels A and B are allocated when the number of radio base stations that have been previously set to connect to the specific radio base station are even and odd, and the number of hops is even. A radio base station is assigned radio channels B and A as radio channels used for the relay when the number of radio base stations that have been previously set for connection is even and odd, respectively, and Radio base stations having even and odd hops include radio channel C and radio channel D different from radio channels A, B, and C, respectively. Assigned as the radio channel used for the access control,
In the second procedure,
A specification in which a common radio channel D is allocated to the plurality of radio base stations as a radio channel used for the access control, and channel C is allocated as a radio channel used for the relay among the plurality of radio base stations The radio base station having the relay hop count of “1” with respect to the radio base station of the radio base station in which connection setting to the specific radio base station has been made in advance as a radio channel used for the relay Radio channels A and B are allocated when the number of the first and second channels are even and odd, respectively, and the first radio channel is allocated as the radio channel used for the relay with the number of hops being “2” in advance Is the radio channel A, and the number of radio base stations for which the connection setting has been made in advance is an even number and an odd number; A radio base station in which the number is “2”, the first radio channel is the radio channel B, and the number of radio base stations for which the connection setting has been made in advance is an even number and an odd number. , Radio channels C, B, C, and A are allocated as the second radio channels used for the relay,
The number of radio base stations for which the connection setting has been made in advance is an integer N ( ≧ 0 ) And the number of hops is (3N-1), and the number of hops is (3N-1). As a radio channel used for relaying to a base station that is 3N-2), among the radio channels A, B, and C, the radio in which the number of hops is (3N-1) and (3N-2) Other than the radio channel used for relaying between base stations and between base stations with the number of hops of (3N-2) and (3N-3) Radio channel is assigned,
The number of radio base stations that have been previously set for connection is 3N, and the number of radio base stations that have been previously set for connection to the radio base station whose number of hops is (3N-1) is an odd number. In this case, among the radio channels A, B, and C, the hop count is (3N−) as a radio channel used for relaying to the radio base station having the hop count (3N−2). 2) and (3N-3) are assigned the same radio channel as the radio channel used for relaying between the radio base stations,
The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station whose number of hops is 3N is an even number. In this case, among the wireless channels A, B, and C, the number of hops is (3N−1) and (3N−) as a wireless channel used for relaying to a wireless base station having the number of hops of 3N. 2) and a radio channel other than the radio channel used for relaying between the radio base stations between which the number of hops is 3N and (3N-1) are allocated,
The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station with 3N hops is an odd number. In this case, among the wireless channels A, B, and C, the number of hops is (3N−1) and (3N−) as a wireless channel used for relaying to a wireless base station having the number of hops of 3N. 2) and the same radio channel as that used for relaying between radio base stations is allocated,
The number of radio base stations that have been previously set for connection is (3N + 2), and the number of radio base stations that have been previously set for connection to a radio base station whose number of hops is (3N + 1) is an even number. In this case, among the wireless channels A, B, and C, the number of hops is 3N and (3N−) as the wireless channel used for relaying to the wireless base station having the number of hops (3N + 1). 1) and a wireless channel other than the wireless channel used for relaying between the wireless base stations between which the number of hops is 3N and (3N + 1) are allocated,
The number of radio base stations that have been previously set for connection is (3N + 1), and the number of radio base stations that have been previously set for connection to a radio base station with 3N hops is an odd number. In this case, among the wireless channels A, B, and C, the number of hops is 3N and (3N-1) as a wireless channel used for relay to the wireless base station having the number of hops (3N + 1). The same radio channel as that used for relaying between radio base stations is assigned.
A wireless communication setting method. A program for causing a computer to implement the wireless communication setting method according to any one of claims 5 to 8. A computer-readable recording medium storing a program for causing a computer to implement the wireless communication setting method according to any one of claims 5 to 8.

Images