JP2001358727A - Method for managing radio network, method for controlling radio transmission and radio transmitting device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radio network managing method, a radio transmission control method and a radio transmitting device capable of effectively deciding a connection link in a network. SOLUTION: When the opposite communication station recognizes information transmitted by a self station by utilizing local map information collected by each communication station as connection link information among communication stations constituting a radio network, this radio network managing method can grasp the relation to other communication stations egg around the self- station simply by receiving the connection link information of the other communication stations around the self-station by reporting information including whether or not the opposite communication station recognizes the self-station because of deciding that two-way communication is available, providing two-way connection link information bit in the connection link information 72-1 to 72-4 of a station sync packet, performing feedback and reporting.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a radio network management method, a radio transmission control method, and a radio transmission method which are suitably applied to, for example, a case where various devices are wirelessly connected by a radio transmission apparatus to form a radio network. It concerns the device.

[0002]

2. Description of the Related Art In recent years, there has been proposed a method of constructing a wireless network using a plurality of wireless transmission devices and wirelessly transmitting various digital information in the wireless network.

As a first conventional method for determining a connection link, as disclosed in Japanese Patent Application Laid-Open No. H11-251992, other methods exist in the vicinity of each wireless communication station (transmission apparatus) at predetermined intervals. Connection information with a communication station (transmission device)
When various types of information are transmitted using the topology map information of the entire network which is reported to the control station of the network and broadcasted (broadcast) transmitted from the control station, the corresponding communication station (transmission device) directly transmits the information. A wireless transmission method has been proposed in which transmission is possible or an optimal relay destination communication station is designated.

In this connection link information determination method, although the own station recognizes the other party's communication station by using the topology map information of the whole network broadcast from the control station, the other party's communication It was possible to easily know the existence of a connection link in a so-called half-duplex communication state that the station did not recognize.

[0005] In the second conventional method, as a method of managing only the control station without broadcasting the topology map from the control station, first, all information is transmitted from the communication station of the information transmission source to the control station. A method has been generally considered in which the information is transmitted, and then the control station repeatedly transmits the information to the information receiving destination communication station.

Further, as a third conventional method, when information is transmitted from a certain communication station (transmission apparatus), before transmitting the information, an inquiry is made to a control station for topology map information, and the information is obtained therefrom. A method of confirming the necessity of relay transmission and identifying a more optimal relay station with reference to the map information may be considered.

[0007]

However, in the connection link determination method according to the first conventional method, since it is necessary to broadcast the topology map information of the entire network at a predetermined period, the number of communication stations constituting the network is limited. However, there is a disadvantage that the amount of information becomes enormous when the number of information increases.

Further, even if the topology map information of the entire network is broadcast-transmitted as in the conventional method, each communication station determines the relay designation based on the connection information between the neighboring communication stations in proximity to the local station and the communication station ahead of it. Is necessary to specify the communication station that performs the communication, and the information of the other communication stations that cannot perform direct communication becomes unnecessary information, which is disadvantageous in that the efficiency is low.

In the second conventional method, two times of information transmission must be performed via the control station for such information transmission. Therefore, the radio transmission of about half the maximum transmission rate is required. However, there is a disadvantage that only the operation can be performed.

Therefore, even when the source communication station and the destination communication station are in a short distance where direct communication is possible, it is necessary to transmit information to the control station once, and the control station must transmit information again. Therefore, there is a disadvantage that the wireless transmission path cannot be used efficiently.

In addition, even when the third conventional method is used, processing before obtaining topology map information from a control station is required prior to information transmission, which complicates the processing and requires a wireless transmission path. There was a disadvantage that it could not be used efficiently.

[0012] Moreover, since a large amount of topology map information obtained from the control station is used only for specifying an actual information transmission destination, there is a disadvantage that waste is generated.

Further, since the topology map information is exchanged as matrix information between the communication stations constituting the network, there is a disadvantage that the information portion of the own station becomes redundant.

Although a method of removing and replacing the redundant matrix portion is also conceivable, there is an inconvenience that it is not suitable for high-speed processing since processing must be performed on the receiving side.

The present invention has been made in view of the above circumstances, and provides a wireless network management method, a wireless transmission control method, and a wireless transmission device capable of efficiently determining a connection link in a network. As an issue.

[0016]

Here, the present invention relates to information transmitted by a local station using local map information collected by each communication station as connection link information between communication stations constituting a wireless network. Wireless network management method and a wireless transmission device that determine that two-way communication is possible when the communication station of the other party recognizes this, and feeds back and reports the connection link information.

Thus, when a wireless network is configured using a plurality of wireless transmission devices, one communication station includes information on a connection link with another nearby communication station in a communication station of the other communication station. By reporting including information as to whether or not it recognizes its own station, it does not need topology map information of the entire network, just receives connection link information of other communication stations existing in the vicinity, It is possible to grasp the relationship with other communication stations existing around the own station.

Further, the present invention provides a radio transmission control method for directly permitting or not permitting direct transmission when performing information transmission using connection link information between communication stations constituting the radio network, and a radio transmission apparatus. is there.

Thus, by referring to the bidirectional connection link information (local map information) obtained as described above, the connection state with the communication station that is further ahead of the communication station of the other party can be determined. You can figure out.

Further, the present invention provides a method for designating an optimum relay communication station when relay transmission is required when information is transmitted using connection link information from a communication station capable of direct transmission. And a wireless transmission device.

Thus, the relay transmission to the communication station located further ahead of the destination communication station by referring to the bidirectional connection link information (local map information) obtained as described above. In this case, an optimum relay station can be easily designated.

Further, the present invention uses a portion corresponding to the connection link information of its own station as a connection link information between communication stations constituting a wireless network, and transmits the information to a control station and peripheral communication stations. A wireless transmission control method for reporting the operation status of the own station, and a wireless transmission device. In addition, the wireless transmission device is configured to acquire connection link information from a wireless transmission device existing in the vicinity, feed back information from a partner transmission device, and transmit the information from its own transmission device.

Thus, the structure of the network can be grasped using a small amount of information.

[0024]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A radio transmission control method and a radio transmission apparatus according to the present invention are described. In a radio network system, each communication station transmits bidirectional connection link information with a peripheral communication station. By receiving the above information, a communication station capable of direct transmission and a communication station requiring relay transmission are determined, and an optimum relay communication station is specified.

The embodiment will be described below. FIG. 1 is a diagram illustrating a configuration example of a network system to which the wireless transmission control method according to the present embodiment is applied. For example, as shown in FIG. 1, a personal computer 1 and a printer output device 2 are connected to the wireless transmission device 11 via a cable or the like by wire. A VTR (video tape recorder) 3 is similarly connected to the wireless transmission device 12 via a cable or the like. Similarly, the telephone device 5 and the set-top box 4 are connected to the wireless transmission device 13 via a cable or the like. Similarly, the television receiver 6 and the game device 7 are connected to the wireless transmission device 14 via a cable or the like by wire. In this way, each device is connected to each wireless transmission device, and each wireless transmission device forms a network 15.

FIG. 2 is a diagram showing an example in which a one-way connection link exists. In FIG. 2, the communication station (# 1) 21 indicated by a white circle
Is a communication station (# 2) 2 in the vicinity indicated by a white circle.
2. Bidirectional connection link 25 with communication station (# 3) 23, 2
6 are secured.

The communication station (# 2) 22 is connected to a nearby communication station (# 2).
1) 21, bidirectional connection link 2 with communication station (# 3) 23
5 and 27 are reserved, but since the information from the communication station (# 4) 24 can be identified, the one-way connection link 28 is reserved.

The communication station (# 3) 23 is connected to a nearby communication station (# 3).
1) 21, a communication station (# 2) 22, and a communication station (# 4) 24 are secured with bidirectional connection links 26, 27, and 29.

The communication station (# 4) 24 is connected to the communication station (# 3) 2
3, a bidirectional connection link 29 is secured, but due to the influence of a noise source (N) 20 present in the vicinity, the communication station (#
2) The state where the information from 22 cannot be identified is depicted.

FIG. 3 is a diagram showing an example in which a topology map of the entire network is constructed from the connection link status shown in FIG.

In the figure, the communication station (# 1)
Indicates that information can be received from the communication station (# 2) and the communication station (# 3) indicated by white circles from the transmission side 32.

In the communication station (# 2) on the receiving side 31,
The communication station (# 1) and the communication station (#
3) indicates that information can be received from the communication station (# 4).

At the communication station (# 3) on the receiving side 31,
The communication station (# 1) and the communication station (#
2) indicates that information can be received from the communication station (# 4).

In the communication station (# 4) on the receiving side 31,
It indicates that information can be received from the communication station (# 3) indicated by a white circle from the transmitting side 32.

That is, in the conventional management method using the network topology, the communication station (# 2) and the communication station (##
The one-way connection link between 4) could be determined.

FIG. 4 is a diagram showing a configuration example of local map information of each communication station for realizing the network management method according to the present embodiment. In the drawing, the local link map (# 1) 42 as the local map information of the communication station (# 1) shown as the connection link target communication station 41 includes the communication station (# 2) and the communication station indicated by double circles ◎. This indicates that a bidirectional connection link with (# 3) is secured.

In the local link map (# 2) 43 as the local map information of the communication station (# 2) shown as the connection link target communication station 41, the communication station (#
This indicates that a bidirectional connection link between 1) and the communication station (# 3) is secured, and a one-way connection link with the communication station (# 4) indicated by white circles is secured.

In the local link map (# 3) 44 as the local map information of the communication station (# 3) shown as the connection link target communication station 41, the communication station (#
1) indicates that a bidirectional connection link with the communication station (# 2) and the communication station (# 4) is secured.

In the local link map (# 4) 45 as the local map information of the communication station (# 4) indicated by the connection link target communication station 41, the communication station (#
This indicates that a bidirectional connection link with 3) is secured.

That is, each communication station can obtain all necessary information only by acquiring the local map information from the adjacent communication station.

In the local map information of each communication station, the information portion of the own station indicated by * is not necessary for constructing a map of the entire network. Can be sent and received.

FIG. 5 shows a configuration example of the radio transmission devices 11 to 14 constituting each communication station. Here, each of the wireless transmission devices 11 to 14 basically has a common configuration, and includes an antenna 51 that performs transmission and reception, and a wireless transmission and reception processing unit 52 that is connected to the antenna 51 and performs wireless transmission processing and wireless reception processing. And wireless transmission with other transmission devices is possible.

In this case, as a transmission system in which transmission and reception are performed by the wireless transmission / reception processing unit 52 of this embodiment, for example, O
FDM (Orthogonal Frequency)
A transmission method using a multicarrier signal called a Division Multiplex (orthogonal frequency division multiplexing) method is applied, and as a frequency used for transmission and reception, for example, a very high frequency band (for example, a 5 GHz band)
Is used.

In the case of this example, a relatively weak output is set for the transmission output. For example, when used indoors, wireless transmission over a relatively short distance of about several meters to several tens of meters can be performed. There is as much output.

A data converter 53 is provided for performing data conversion of a signal received by the radio transmission / reception processor 52 and data conversion of a signal transmitted by the radio transmission / reception processor 52.

The data converted by the data conversion unit 53 is supplied to the connected device 58 via the interface unit 54, and the data supplied from the connected device 58 is supplied via the interface unit 54. The configuration is such that the data can be supplied to the data conversion unit 53 and converted.

Here, as an external interface of the interface unit 54 of the wireless transmission device, for example, IE
High-speed serial bus 5 such as EE1394 format
7, audio / video information or various data information can be transmitted / received to / from the connected device 58.

Alternatively, these wireless transmission devices may be built in the main body of the device 58 to be connected.

Each unit in each wireless transmission device is configured to execute processing based on control of a control unit 55 constituted by a microcomputer or the like.

In this case, if the signal received by the wireless transmission / reception processing unit 52 of each wireless transmission device is a signal in the management area, the received signal is supplied to the control unit 55 via the data conversion unit 53. The control unit 55 sets each unit to a state indicated by the received information.

Further, the control unit 55 has an internal memory 56.
Is connected to the internal memory 56, which transmits data required for communication control, information on the number of communication stations constituting a network, information on a frame cycle for transmitting a station synchronization signal, and transmits a station synchronization signal at a predetermined frame cycle. It is configured to temporarily store information on the communication station, information on how to use the transmission path such as the number of reserved bands, and the value of an information update counter.

Further, in the radio transmission apparatus serving as the control station 14 of the network, the control unit 55 sends a cycle start (C
S) The signal is supplied to the wireless transmission / reception processing unit 52 via the data conversion unit 53 and wirelessly transmitted.

In the transmission devices 11 to 13 other than the control station of the network, when the received signal is a cycle start (CS) signal, the received signal is transmitted to the control unit 55 via the data conversion unit 53. And the control unit 55 determines the timing of receiving the synchronization signal, sets a frame cycle based on the synchronization signal, and executes communication control processing in the frame cycle.

FIG. 6 is a diagram showing a configuration example of a radio transmission frame according to the present embodiment. Here, a frame is defined and shown for convenience, but it is not always necessary to adopt such a frame structure. In the figure, a transmission frame arriving at a fixed transmission frame period 61 is defined in a wireless transmission path 60, and a management information transmission area 62 and an information transmission area 63 are provided therein.

At the beginning of the frame, a downlink management information transmission section 64 (cycle start (CS: Cycle Sta.)) For synchronizing frame and notifying network common information is provided.
rt)) section is arranged, followed by the time information correction transmission section 65 (cycle report (CR:
Cycle Report), and a station synchronization signal transmission / reception section 66 (station sync (SS: S
station Sync)).

The downlink management information transmission section (CS) is used for transmitting information that needs to be shared by the network from the control station, and is composed of a fixed length area and a variable length area.

In the fixed length area, in order to specify the length of the variable length area, the number of communication stations transmitted in the station synchronization signal transmission / reception section (SS) is specified, and the number of band reservation transmission areas (RSV) is specified. Designation is performed, and in the variable length area, a communication station to be transmitted in the station synchronous transmission / reception section (SS) and a bandwidth reservation transmission area (RSV) are specified.

The station synchronization signal transmission / reception section (SS) has a predetermined length, and the communication station transmitting the communication station has a certain period according to the downlink management information for each communication station constituting the network. A configuration that can be assigned by using this is considered.

For example, in this station synchronization signal transmission / reception section (SS)
By receiving everything except the transmission part of the own station,
It is possible to grasp the state of a connection link with a communication station existing around the own station.

Further, the next own station is in the station synchronous transmission / reception section (S
By reporting the connection link status in the information transmitted in S), the network connection status can be determined by each communication station.
There is a configuration that allows each to be grasped.

The information transmission area 63 is a bandwidth reservation transmission area (RSV: Reserve) 67 set as needed.
A centrally managed asynchronous transmission area (ASY: Asynchronous) 68 in which the control station performs transmission control, and an unused area (NUA: distributed control) in which the control station does not perform transmission control.
Not Using Area) 69.

In other words, if there is no need for bandwidth reservation transmission (RSV) or unused area (NUA), the entire information transmission area can be transmitted as centrally managed asynchronous transmission area (ASY).

By adopting such a frame structure, for example, in the band reservation transmission area (RSV), IEEE
Isochronous (Isochronous) transmission specified by the 1394 format is performed. In an asynchronous transmission area (ASY), asynchronous (Asynchronous) transmission is performed.
ou) transmission is preferable.

FIG. 7 is a diagram showing a configuration example of a station sync packet. This station sync packet is transmitted from the station (communication station) designated by the station information of the CSP to the control station and peripheral communication stations in the station synchronization information transmission / reception section (SS) 66 shown in FIG. Information.

The structure of this packet is to notify the control station that it will enter a dormant state: a request 71-1 for a sleep mode, and the priority of an access control right is specified: an access control priority 71-2. Represents the information processing capability of this station: station capability 71-3, and connection link information with other stations (here, four stations are shown): station (# 1) reception quality 7
2-1, station (# 2) reception quality 72-2, station (# 3) reception quality 72-3, station (#
4) Reception quality 72-4 and CRC 73 for error detection
It is composed of

In the present embodiment, this can be realized by providing a bidirectional connection link information bit in the connection link information.

In this configuration, the station (# 1) reception quality 72-1 transmitted from the communication station (# 1),
Station (# 2) reception quality 72-2 transmitted from communication station (# 2), station (# 3) reception quality 72-3 transmitted from communication station (# 3), communication station (# 4)
(# 4) reception quality 72-4 transmitted from
Since the connection link information part of the own station is arranged for the part, it becomes redundant, so by using this part, the operating state of the own station and various requests to the control station and the surrounding communication stations are used. It can be used for information transmission.

FIG. 8 is a diagram showing a configuration example of a station sync packet of the communication station 1. As the structure of this packet, the sleep state is notified to the control station: a request 81-1 for the sleep mode, and the priority of the access control right is specified: the access control priority 81-.
2. Represents information processing capability of this station: station capability 81-3, and management information of communication station 1 of the present embodiment and connection link information to other stations:
The management information 82-1 of the communication station (1), the station (#
2) reception quality 82-2, station (# 3) reception quality 82-3, station (# 4) reception quality 82-4,
It is composed of a CRC 83 for error detection.

In the figure, the management information of the communication station 1 is transmitted using the information part of the reception quality of the station (# 1).

FIG. 9 is a diagram showing a configuration example of a station sync packet of the communication station 2. As the structure of this packet, the control station is notified of entering a hibernation state: a request 91-1 for a sleep mode, and the priority of an access control right is specified: an access control priority 91-.
2. Represents information processing capability of this station: station capability 91-3, and management information of communication station 2 of the present embodiment and connection link information with other stations:
Station (# 1) reception quality 92-1; communication station (2)
Management information 92-2, station (# 3) reception quality 9
2-3, a station (# 4) reception quality 92-4, and a CRC 93 for error detection.

In the figure, the management information of the communication station 2 is transmitted using the information part of the reception quality of the station (# 2).

FIG. 10 is a diagram showing a configuration example of a station sync packet of the communication station 3. As the structure of this packet, the sleep state is notified to the control station: a sleep mode request 101-1 and the priority of the access control right is specified: the access control priority 10
1-2, indicating the information processing capability of this station: station capability 101-3, and management information of the communication station 3 of the present embodiment and connection link information with other stations: station (# 1) reception quality 102 -1, station (# 2) reception quality 102-2, communication station (3) management information 102-3, station (# 4) reception quality 1
02-4 and a CRC 103 for error detection.

In the figure, it is shown that the management information of the communication station 3 is transmitted using the information part of the reception quality of the station (# 3).

FIG. 11 is a diagram showing a configuration example of a station sync packet of the communication station 4. As the structure of this packet, the sleep state is notified to the control station: a sleep mode request 111-1, and the priority of the access control right is specified: the access control priority 11
1-2, indicating the information processing capability of this station: station capability 111-3, and management information of the communication station 4 according to the present embodiment and connection link information with another station: station (# 1) reception quality 112 -1, station (# 2) reception quality 112-2, station (# 3) reception quality 112-3, management information 112-4 of communication station (4), and CRC 113 for error detection.

In the figure, it is shown that the management information of the communication station 4 is transmitted using the information part of the station (# 4) reception quality.

FIG. 12 is a diagram showing a configuration example of a cycle start packet. This cycle start packet is information transmitted from the network control station to all stations on the network in the downlink management information transmission section (CS) 64 shown in FIG.

The packet structure indicates the disclosure time of this frame: cycle time information 121-1 and network ID 1 for identifying this network.
21-2, an information update counter 121-3 indicating the timing up to simultaneous updating of the information included in the cycle start packet (CSP), and indicating the order of the information included in the station sync packet (SSP): SS
P counter 121-4, indicating SSP transmission cycle: SS
P period 122-1, indicating the number of SSPs present in the frame: SSP number 122-2, indicating the current number of band reservation information: band reservation information number 122-3, indicating the end position of the frame: frame end pointer 122-4, indicating an arbitrary number of information: variable-length frame information size 122-5, and CRC (Cyclic Redu) for error detection
The information is arranged as fixed-length information according to the NDN 123.

In addition, the length becomes variable according to the number of SSPs:
Station information (# 1) 124-1, station information (# 2) 124-2, station information (# 3) 12
5-1, station information (# 4) 125-2, and variable length according to the number of bandwidth reservations: bandwidth reservation information (# 1) 126, and CRC12 for error detection
7 are arranged as variable-length information.

FIG. 13 is a flowchart showing an operation of transmitting a CSP (cycle start information) in the communication station of the control station. First, in step S1, it is determined whether or not it is a downlink management information transmission section (cycle start: CS). In step S1, a downlink management information transmission section (C
If not, the process exits.

If it is the downlink management information transmission section (CS) in step S1, SSP (station sync packet) cycle information is set in step S2, and SSP counter information is set in step S3. In S4, SSP transmission communication station information (station information # 1 to station information # 4) is set, and in step S5, cycle start CS (packet) information is transmitted.

FIG. 14 is a diagram showing CS in each communication station other than the control station.
It is a flowchart which shows the receiving operation of P (cycle start information). In step S11, it is determined whether or not it is a downlink management information transmission section (cycle start: CS). If it is not a downlink management information transmission section (CS) in step S11, the process exits.

If it is the downlink management information transmission section (CS) in step S11, it is determined in step S12 whether or not the cycle start CS (packet) information has been successfully received.

In step S2, cycle start C
If the S (packet) information has been successfully received, SSP (station sync packet) cycle information is obtained in step S13 from the YES branch, and step S1 is performed.
At S4, SSP counter information is registered, and step S
At 15, the SSP transmitting communication station information (station information #
1 to station information # 4) are registered.

In step S2, cycle start C
If the S (packet) information cannot be received, the SSP counter information is estimated in step S16 from the NO branch, and in step S17, the SSP counter information is stored in advance based on the estimated SSP counter information. The SSP transmission communication station information (station information # 1 to station information # 4) that has been obtained is obtained.

FIG. 15 is a flowchart showing a network management operation in each communication station. In step S21, the station synchronization signal transmission / reception section (station sync: SS)
Is determined, and if it is not the station synchronization signal transmission / reception section (SS) in step S21, the process exits.

If it is the station synchronization signal transmission / reception section (SS) in step S21, in step S22 the SSP (station sync packet) in the corresponding frame period is sent.
Obtain transmission station information.

Then, in step S23, it is determined whether or not the transmission area of the own station has arrived. If it is not the transmission area of the own station in step S23,
In step S24, station sync information is received from the corresponding communication station, and in step S25, it is determined whether the information has been successfully decoded.

If the information can be decoded in step S25, local map information from the corresponding communication station is obtained in step S26, and in step S27, whether the corresponding communication station recognizes itself is determined. Is determined.

If the corresponding communication station recognizes itself in step S27, it means that a bidirectional connection link has been established in step S30, and step S3
Move to 1.

If it is determined in step S27 that the communication station concerned has not recognized itself, then in step S29,
Since only one-way connection links exist, the process proceeds to step S31.

If the information cannot be decoded in step S25, there is no connection link from the corresponding communication station in step S28, and the process shifts to step S31.

In step S31, such information is registered as local map information of the own station.

If it is determined in step S23 that the transmission area is that of the own station, the local branch information of the own station is obtained in step S32 from the YES branch, and step S3 is executed.
At 3, the station sync information is configured and transmitted.

Although the above-described embodiment has been described with reference to an example in which the present invention is applied to the wireless 1394, it is needless to say that the present invention is not limited to this and can be applied to other wireless networks.

[0095]

According to the radio network management method of the present invention, the bidirectional connection link information indicating whether or not a nearby communication station recognizes itself is included in the local map information transmitted and received by each communication station. By sending together, without needing a network topology map,
This has the effect that the network connection status can be ascertained with only minimal information.

Further, according to the radio transmission method of the present invention, by analyzing the local map information sent from another communication station existing in the vicinity, the connection state with the communication station existing further is analyzed. Therefore, it is possible to directly determine whether or not transmission is possible without using a topology map of the entire network.

Further, according to the radio transmission method of the present invention, by analyzing local map information sent from other nearby communication stations, even when relay transmission is required, the optimum relay communication station can be obtained. This has the effect that it is possible to specify

Further, according to the radio transmission control method of the present invention, the operation status of the own station is reported by using the portion corresponding to the connection link information of the own station in the network management information. There is an effect that information to be transmitted can be transmitted wirelessly efficiently.

According to the wireless transmission device of the present invention, when the connection link information transmitted by the own station is recognized by the wireless transmission device of the transmission partner, the information is fed back,
By transmitting the information as the bidirectional connection link information, it is possible to provide a wireless transmission device capable of grasping the wireless network structure with a small amount of information.

Further, according to the wireless transmission apparatus of the present invention, the operation status of the own station is transmitted by using the portion corresponding to the connection link information of the own station, so that the status of the own station can be reduced with less information. There is an effect that a wireless transmission device capable of reporting to a transmission device of a nearby communication station can be provided.

[Brief description of the drawings]

FIG. 1 is a diagram illustrating an example of a wireless network configuration to which a transmission control method according to an embodiment is applied.

FIG. 2 is a diagram showing an example in which a one-way connection link exists.

FIG. 3 is a diagram illustrating an example of a network topology map.

FIG. 4 is a diagram showing a configuration example of a local map according to the present embodiment.

FIG. 5 is a diagram illustrating a configuration example of a wireless transmission device forming each communication station.

FIG. 6 is a diagram illustrating a configuration example of a wireless transmission frame.

FIG. 7 is a diagram illustrating a configuration example of a station sync packet.

FIG. 8 is a diagram illustrating a configuration example of a station sync packet of the communication station 1.

FIG. 9 is a diagram showing a configuration example of a station sync packet of the communication station 2.

FIG. 10 is a diagram illustrating a configuration example of a station sync packet of the communication station 3.

11 is a diagram illustrating a configuration example of a station sync packet of the communication station 4. FIG.

FIG. 12 is a diagram illustrating a configuration example of a cycle start packet.

FIG. 13 is a flowchart showing an operation of transmitting a CSP (cycle start information) in a communication station of a control station.

FIG. 14 is a flowchart showing an operation of receiving a CSP (cycle start information) in each communication station other than the control station.

FIG. 15 is a flowchart showing a network management operation in each communication station.

[Explanation of symbols]

11, 12, 13, 14 ... wireless transmission device, 15 ... network, 20 ... noise source (N), 21 (# 1),
22 (# 2), 23 (# 3), 24 (# 4) ... communication station, 25, 26, 27 ... bidirectional connection link, 28 ...
One-way connection link, 41 ... Connection link target communication station, 4
2 local link map (# 1), 43 local link map (# 2), 44 local link map (# 3), 45 local link map (# 4),
51: antenna, 52: wireless transmission / reception processing unit, 53:
... Data conversion unit, 54 ... External interface unit, 5
5: control unit, 56: internal memory, 57: serial bus, 58: connected equipment, 64: downlink management information transmission section (CS) 66: station synchronization signal transmission / reception section (S
S), 82-1 ... information of communication station 1, 92-2 ... management information of communication station 2, 102-3 ... management information of communication station 3,
112-4... Management information of communication station 4

Continued on the front page (51) Int.Cl. ⁷ Identification symbol FI Theme coat II (reference) H04Q 7/30

Claims (6)

[Claims] 1. A wireless network management method for configuring a network using a plurality of transmission devices serving as communication stations and managing connection link information of the corresponding network. Reporting as the connection link information of the own station, and including the bidirectional connection link information of whether or not the communication station of the transmission partner recognizes the self station, as the connection link information of the own station. Characteristic wireless network management method. 2. A wireless transmission control method for configuring a network by using a plurality of communication station transmission apparatuses and transmitting information, comprising the steps of: connecting a connection link from another communication station existing around the own station during transmission; Acquiring the information, and referring to the connection link information with the own station, which is included in the connection link information, to determine whether direct transmission with the corresponding communication station is possible. Wireless transmission control method. 3. A wireless transmission control method for configuring a network by using a plurality of transmission stations serving as communication stations and transmitting information, comprising the steps of: connecting a connection link from another communication station existing around the own station during transmission; Information, and with reference to the connection link information with the third communication station other than the transmission partner station included in the connection link information, relay transmission to the corresponding third communication station is performed. A wireless transmission control method characterized by determining whether or not it is possible. 4. A wireless transmission control method for configuring a network using a plurality of transmission devices as communication stations and transmitting information related to the network, wherein a portion corresponding to the connection link information of the own station is used during transmission. And transmitting information on the operation status of the own station in the network. 5. A wireless transmission apparatus for forming a network using a plurality of wireless transmission apparatuses serving as communication stations and transmitting information, wherein at the time of transmission, a connection is established from another wireless transmission apparatus existing around the own station. Information receiving means for receiving link information; first information transmitting means for transmitting, as connection link information, information of another wireless transmission device which can be received by the wireless transmission apparatus of the own station; connection link information transmitted by the own station And a second information transmitting means for transmitting the information as bidirectional connection link information when the wireless transmission device is recognized by the transmission destination wireless transmission device. 6. A wireless transmission device for forming a network using a plurality of wireless transmission devices serving as communication stations and transmitting information related to the network, wherein a portion corresponding to connection link information of the own station is used during transmission. And transmitting information on the operation status of the own station in the network.